SERKET COS ys

The Arachnological Bulletin
of the Middle East and North Africa

Volume 20 Part 1
December, 2023 Cairo, Egypt

HS 18 oR oS oo 2 eo oe

ISSN: 1110-502X

SERKET

Volume 20 Part 1
December, 2023 Cairo, Egypt
Contents
Page
The remarkable micro-scorpion genus Microbuthus Kraepelin, 1898 in North
Africa; description of a new species with comments on its biogeography and
ecology (Scorpiones: Buthidae)

Wilson R. Louren¢go ]
Plexippus C.L. Koch, 1846: a new genus for the Moroccan araneofauna (Araneae:
Salticidae)

Mohamed Mousaid & Hicham Bouithouline 1]

Stegodyphus semadohensis Deshmukh, 2013 is a nomen nudum (Araneae: Eresidae)
Danniella Sherwood & Hisham K. El-Hennawy 18

Harpactea umay sp. n., a new spider species from Turkiye (Araneae: Dysderidae)
Kadir BoSac Kunt, Ersen Aydin YaSmur & Recep Sulhi Ozkiittik 20

Spiders as a bio-agent factor in a Mango greenhouse at Giza Governorate, Egypt
Doaa M.A. Abdel-Ghani, Mourad F. Hassan & Gihan M.E. Sallam 26

DNA barcode and phylogenetic analysis for the araneid spider Neoscona theisi
(Walckenaer, 1841) (Arachnida: Araneae: Araneidae) from India
Sachin R. Patil 39

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ok 2k 2k ok 2 2s 2k 2k ok ok ok

ISSN: 1110-502X

Serket (2023) vol. 20(1): 1-10.

The remarkable micro-scorpion genus Microbuthus Kraepelin,
1898 in North Africa; description of a new species with
comments on its biogeography and ecology
(Scorpiones: Buthidae)

Wilson R. Lourenco
Muséum national d’Histoire naturelle, Sorbonne Universités, Institut de Systématique,
Evolution, Biodiversité (ISYEB), UMR7205-CNRS, MNHN, UPMC, EPHE, CP 53, 57
rue Cuvier, 75005 Paris, France; e-mail: wilson.lourenco@ mnhn.fr

Abstract

A new species, Microbuthus saharicus sp. n., is described from the inland deserts
of Mauritania; it represents the first exception to the general coastal distribution observed
in the species of this genus. With this new description, the total number of known species
in Africa is increased to five. The disrupted peri-Saharan pattern of distribution presented
by the group is however confirmed. Some comments are also added on the biogeography
and ecology of the species.

Keywords: Scorpion, Microbuthus, Buthidae, new species, Mauritania.

Introduction

As previously summarized in earlier publications (Vachon, 1952; Loureng¢o, 2002,
2011; Lourengo & Duhem, 2007) the genus Microbuthus was originally described by
Kraepelin (1898), with the type species being Microbuthus pusillus Kraepelin, 1898
which was collected from the region of Tadjura Bay (= Tadscharabay) in the Gulf of
Aden (= Yemen). Subsequently, a second species Butheolus litoralis Pavesi, 1885 from
Assab, on the Red Sea coast of Eritrea was transferred to the genus Microbuthus by
Birula (1905). The genus Microbuthus was represented exclusively by these two species
until the description of Microbuthus fagei by Vachon (1949) based on specimens
collected at Nouakchott in the coastal region of the Atlantic Ocean in the South of
Mauritania. More recently, Lourengo (2002) studied a larger sample of specimens from

both Mauritania and Morocco and proposed the description of a subspecies for
Microbuthus fagei for the region of Tan-Tan in South Morocco as Microbuthus fagei
maroccanus Lourengo, 2002. Subsequently, Microbuthus maroccanus was raised to the
rank of species (Lourengco & Duhem, 2007).

The unexpected discovery of a quite particular specimen of Microbuthus in Egypt
led to the description of a new species, Microbuthus flavorufus Lourengo & Duhem, 2007
(Fig. 1). This marked the first record of the genus Microbuthus for the country. In the
subsequent years, there were no new contributions to the African Microbuthus. However,
studies conducted in the Middle East, resulted in the description of new species, namely
Microbuthus gardneri Lowe, 2010, Microbuthus kristensenorum Lowe, 2010 and
Microbuthus satyrus Lowe, Kovarik, Stockmann & Stahlavsky, 2018 from Oman and
Yemen (Lowe, 2010; Lowe et al., 2018). Some difficulties for the study of the species of
the genus arise from the fact that most species are rare, and some original types have been
mislaid. This was the case for the type of Butheolus litoralis (= Microbuthus litoralis)
which could not be found in any Italian Museum, what led to the proposition of a neotype
for this species (Lourenco, 2011). In this same occasion the synonym of Microbuthus
pusillus Kraepelin, 1898 with Microbuthus litoralis (Pavesi, 1885) was confirmed
(Lourengo, 2011). While the type material of Microbuthus fagei, consisting of two
specimens, remains misplaced in the collections of the Muséum in Paris, the
characterisation of topotypes of this species allows for its accurate definition.

Among the wide array of known genera of Buthidae scorpions, Microbuthus
remains enigmatic. The reasons for this are associated not only with the several unique
morphological features of the different species, but are also due to the scarcity of
available material for study. At present, a new species is described from the inland
deserts of Mauritania, escaping therefore to the previous observed pattern of distribution
along coastal zones. This discovery marks the fifth species documented in Africa. The
disrupted peri-Saharan pattern of distribution observed among the species of the genus
appears to be reaffirmed once more.

~~ “PoE

-

Fig. 1. Female holotype of Microbuthus flavorufus alive in the natural habitat in Egypt.

Material and Methods

Illustrations and measurements were produced using a Wild M5 stereo-
microscope with a drawing tube and an ocular micrometre. Measurements follow Stahnke
(1970) and are given in mm. Trichobothrial notations follow Vachon (1974),
morphological terminology mostly follows Vachon (1952) and Hjelle (1990), and
chelicerae dentition follows Vachon (1963). The type material described in this paper will
be deposited in the collections of the ‘Museu Nacional’, Rio de Janeiro, Brazil.

The recognized species of Microbuthus Kraepelin, 1898 (African species in bold)

M. litoralis (Pavesi, 1885)

M. fagei Vachon, 1949

M. maroccanus Lourenco, 2002

M. flavorufus Lourenco & Duhem, 2007

M. gardneri Lowe, 2010

M. kristensenorum Lowe, 2010

M. satyrus Lowe, Kovarik, Stockmann & Stahlavsky, 2018
M. saharicus sp. nov.

Taxonomic treatment

Family Buthidae C.L. Koch, 1837
Genus Microbuthus Kraepelin, 1898
Microbuthus saharicus sp. n. (Figs. 2-10)

Type material: Male holotype, Mauritania, Bivouac de Tinterkat (near to Wadane),
20°56°39.45” N, 11°33°36.69” W; 4/XI/2001 (P. Lluch). The holotype will be deposited
in the Museu Nacional, Rio de Janeiro, RJ, Brazil, as a contribution to the reposition of
the collections destroyed by fire in 2018.

Etymology: Specific name refers to the Sahara Desert where the new species was found.

Diagnosis. A rather small species of scorpion; the total length reaches only 17.80 mm.
Colouration dark as in some other species of the genus; the body is globally dark while
the appendages are almost entirely yellow. Pectinal tooth count 12-13. Metasomal
segment I wider than long; segments II to V longer than wide. Tibial spurs on leg III
reduced; well developed on leg IV. Trichobothrial pattern: minorante neobothriotaxy;
chela (hand + fixed finger) with the absence of trichobothria est, Esb, Eb3; patella with
trichobothria dy absent and ds in a proximal position; seven external trichobothria, but
with trichobothrium em strongly reduced; femur with the absence of trichobothria d2, and
a reduced ds. Tibial spurs moderate on leg III and well developed on leg IV.

Relationships: By its general morphology the new species shows some affinities to both
Microbuthus maroccanus from Morocco and Microbuthus fagei from Mauritania.
However, the new species can be readily distinguished by its overall darker pigmentation
on the tergites and sternites and a distinct number of trichobothria equally disposed in
distinct positions.

Description based on male holotype (measurements following the description).

Figs. 2-3. Microbuthus saharicus sp. n. Male holotype. Habitus, dorsal and ventral
aspects.

Colouration (Figs. 2-3). Body dark brown with appendages yellow to pale yellow; only
coxa and trochanter of pedipalps are dark. Prosoma: carapace dark brown; eyes intensely
marked with a black pigmentation. Mesosomal tergites dark brown; tergite VII slightly
paler with some yellowish zones. Metasomal segments I to V brown to dark brown with
some yellowish zones; segments IV and V darker than I to III. Vesicle reddish-yellow;
aculeus yellowish at the base and reddish at the tip. Venter, coxapophysis, sternum,
genital operculum and pectines yellowish; pectines paler than the other structures;
sternites yellowish with marked brownish zones; sternite VII darker than the others.
Chelicerae yellow with some dark reticulated spots at the base of fingers; fingers
yellowish with reddish teeth. Pedipalps pale yellow with coxa and trochanter dark brown,
including proximal zone of femur; granulations on cutting edge of fingers slightly reddish.
Legs pale yellow without any spots.

Morphology. Carapace strongly narrowed anteriorly, almost triangular; anterior margin
with a vestigial median concavity; almost straight. Carinae weakly marked; granulations
moderately to strongly marked by pearl-like granules. Furrows weak. Median ocular
tubercle only slightly anterior to the centre of the carapace; median eyes separated by one
and half ocular diameters. Three pairs of lateral eyes; the third pair reduced. Sternum
triangular, longer than wide. Mesosomal tergites moderately to strongly granular. Median
carina moderate and present in all tergites; the two lateral carinae vestigial. Tergite VII
pentacarinate, moderately crenulate. Venter: genital operculum of moderate to large size
divided longitudinally and wider than the sternum. Pectines: pectinal tooth count 12-13;
basal middle lamellae of the pectines not dilated; fulcra moderate. Sternites III-VI with
thin granulations; granules on VII stronger with four vestigial carinae; two lateral furrows
present on sternites III-VI. Short slit-like spiracles. Metasoma: segments rounded with ten

4

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Figs. 4-10. Microbuthus saharicus sp. n. Male holotype. 4. Metasomal segments HI-V
and telson, lateral aspect. 5. Chelicera, dorsal aspect. 6-10. Trichobothrial pattern.
6-7. Chela dorso-external and ventral aspects. 8-9. Patella, dorsal and external aspects.
10. Femur, dorsal aspect. (Scale bars: 4: 2 mm, 5: 0.5 mm, 6-10: 1 mm).

Carinae moderately marked on segments I to HI; carinae on segment III partially fused
with the granulations; segments IV and V with only vestigial dorsal carinae and with
numerous punctuations. Intercarinal spaces moderately granular. Telson slightly
punctuated, with two small lateral furrows and one ventral carina with a serrula shape;
aculeus very short and strongly curved; subaculear tooth absent. Cheliceral dentition
characteristic of the family Buthidae (Fig. 5): the basal teeth in the movable finger are
almost fused (Vachon, 1963). Pedipalps: femur pentacarinate; patella with seven weak
carinae and the internal face without any spinoid granule; chela with vestigial carinae; all
faces with thin but intense granulation. Fixed and movable fingers with one linear row of
granules divided by some stronger accessory granules; extremity of the fingers with one
strong accessory granule giving the shape of forceps to the fingers. Trichobothriotaxy
(Figs. 6-10): minorante neobothriotaxy; A-B (beta) for the disposition of the dorsal
trichobothria of the femur (Vachon, 1974, 1975); chela (hand + fixed finger) with the
absence of trichobothria est, Esb, Eb3; patella with trichobothria dy absent and d3 in a
proximal position; seven external trichobothria, but with trichobothrium em strongly
reduced; femur with the absence of trichobothria d2, and a reduced ds. Legs: tarsus with a
few median fine setae ventrally; pedal spurs moderate on legs HI and IV; tibial spurs
moderate on leg III and well developed on leg IV.

Morphometric values (in mm) of the new species. Total length, 17.80*. Carapace: length,
2.41; anterior width, 1.54; posterior width, 2.87. Mesosoma length, 3.94. Metasomal
segments (Fig. 4). I: length, 1.34; width, 1.47; II: length, 1.62; width, 1.34; III: length,
1.74; width, 1.62; IV: length, 2.21; width, 1.74; V: length, 2.47; width, 1.87; depth, 1.54.
Telson length 2.07; vesicle: width, 0.87; depth, 0.84. Pedipalp: femur length, 2.21, width,
0.67; patella length, 2.27, width, 0.87; chela length, 4.21, width, 0.87, depth, 0.81;
movable finger length, 2.54 (* including telson).

Biogeography of the genus Microbuthus

The description of the new species, although collected in more inland deserts of
Mauritania, suggests a potential disrupted peri-Saharan distribution pattern for African
Microbuthus species (Fig. 11). This pattern was initially proposed by Vachon (1952) and
subsequently re-affirmed by Lourengo (2002, 2011) and Lourengo & Duhem (2007).
However, it was rejected by Lowe (2010) and Lowe et al. (2018) who stated as follows:
‘The apparent widely disjunct distribution of Microbuthus in eastern and western coastal
locations of North Africa was proposed to reflect a fragmentation or regression of
ancient mesic faunas that were unable to adapt to xeric conditions that accompanied
advent of the Sahara Desert’. In addition, they also stated ‘The fact that the few available
museum specimens of Microbuthus were collected near coastal areas may reflect a bias
in the sampling of small cryptic faunas for more densely populated and easily traveled
coastal routes. ’

400 km

_ 014°00 W

q

é

" Ca, r ot Ey:
~~ MAURITANIA

® Microbuthus fagei

ees

Nouakchott @
® Microbuthus maroccanus

@ Microbuthus saharicus sp. n. - SENEGAL

Fig. 11. Map of Occidental North Africa with the type localities of Microbuthus species
known from this area.

These statements involve some degree of speculation. In fact, intense collecting
predominantly occurred in what was formerly the ‘Afrique Occidentale Frangaise’ field
trips have been conducted not only over coastal areas, but very often in the inland regions
(see Lourengo, 2019). Besides, Microbuthus is not the only genus presenting a particular
pattern of distribution. Another example is the distribution pattern of the genus

6

Butheoloides Hirst, 1925. This genus is globally absent from the Central compartment of
the Sahara Desert with all its species distributed in more mesic environments surrounding
the Desert areas (see Lourengo, 2013). Consequently, the earlier hypothesis (Lourenco,
2002; Lourenco & Duhem, 2007) may still hold until new evidence emerges from the
central portion of North Africa. I summarize here again some aspects of what was
suggested before.

Furon (1951) suggested that the flora and fauna now present in the Sahara region
may have ancient origins. Their present pattern is not solely the consequence of
palaeogeographic factors, but is also significantly shaped by various palaeoclimatic
events. These palaeoclimatic events had an important impact during the Quaternary
period when Europe (and North America) underwent glaciation cycles. Meanwhile,
Africa experienced periods of heightened rainfall and a notable increase in ice
accumulation on its mountains, particularly in Eastern Africa. The most recent wet period
in the Sahara occurred very recent, only some 5,000 years BP.

Qi & Lourengo (2007) emphasized that the current composition of the Saharan
fauna likely represents the legacy of ancient faunas that have been present in North
Africa since the early Cenozoic, or at least since mid-Cenozoic times (Vachon, 1952).
North Africa has experienced numerous other palaeoclimatological vicissitudes in the last
few million years, some of which occurred in more recent Quaternary times. The Sahara
has undergone a long series of wet periods, the most recent occurring 10.000-5000 years
BP. It was not until approximately 3000 years BP that the Sahara assumed its present arid
state (Cloudsley-Thompson, 1971, 1974, 1984). Recent studies suggest that the Sahara
Desert may be much older than was previously thought (Schuster et al., 2006). It seems
reasonable, therefore, to postulate that extremely arid areas may have existed as patchy
desert enclaves for a very long time, even when the overall climate in North Africa
enjoyed more mesic conditions. Within these desert regions, a specialized scorpion fauna
would have evolved. In contrast, other lineages less well adapted to drought, and
previously present only in mesic environments, have regressed markedly in their
distribution. They have therefore experienced negative selection and are on the road to
extinction. In other cases, populations have been reduced to very limited and patchy
zones sometimes with remarkable disjunctions in their distribution patterns.

Among the patterns observed today in the distribution of North African scorpions
(Qi & Lourencgo, 2007) one of the most intriguing is the disjunction presented by the
distribution of the genus Microbuthus, with two species known in Mauritania and
Morocco in the West and two others respectively in Egypt, Eritrea and Dyibouti in the
East (and three more species in the Middle East). Vachon (195la, 1952) had already
drawn attention to this extremely localized pattern of distribution of the species of
Microbuthus and defined it as a ‘disrupted and limited territory’. Vachon also attempted
to explain the observed pattern and made reference to Braestrup (1947) who had
suggested a mechanism for exchanges through the Sahara Desert. According to this
mechanism, Southern elements (Ethiopian) were able to reach the Northern regions, and
Northern elements (Palaearctic) were able to disperse to the Southern regions of the
Sahara. However, this hypothesis primarily applies to dynamic elements with a strong
dispersal capacity. Scorpion populations, in contrast, are often stable and less adaptable to
new environments. The present distribution patterns of several scorpion groups,
particularly the one presented by the genus Microbuthus, likely reflect a broader range of
distribution in the past. The distinct palaeoclimatic vicissitudes experienced by the Sahara
have constituted an important selective factor over its scorpion populations. The reaction
of these to abiotic factors was certainly varied depending on their own ecological
strategies (Polis, 1990; Lourenco, 1991). In some cases, the populations showed a

7

significant regression in their distribution, and some populations may well have totally
vanished. These regressions led to marked disruptions in geographic distributions and
resulted in their present patchy distribution. This hypothesis offers a potential explanation
for the disrupted distribution pattern of Microbuthus species.

Ecological and biological comments

According to Vachon (1951b), Microbuthus species could be classified as
halophiles, since up to that date these were exclusively found in coastal zones, stretching
from the Red Sea to the Atlantic Ocean. This ecological particularity was further
confirmed for other species such as M. maroccanus (see Lourengo, 2002 for details).
Lowe (2010) however, rejected this ecological trait and argues that for the species found
in the Middle East this characteristic was unreliable. The new species described here,
seems to confirm in part this assumption (Fig. 12). It was collected far from coastal zones
and on an arid environment. Further discoveries should bring a more precise ecological
pattern.

Fig. 12. Typical desert formation in Central Mauritania, near to the type locality of
Microbuthus saharicus sp. n.

The fluorescence observed in Microbuthus species appears to be variable. In fact,
for some living specimens of M. litoralis it proved to be rather weak. Fluorescence was
previously considered as a global trait in scorpions, but more and more exceptions are
presently found (see Lourengo, 2012).

The reproductive biology of most micro-scorpions remains relatively unexplored,
but preliminary observations have revealed certain peculiarities. For instance, limited
observations on M. fagei demonstrated that broods are composed of very small numbers,
ranging from 3 to 4 (Lourengo, 2002, 2007). In contrast, pro-juveniles at birth are very
large at birth. Female body length averages 8.4 mm, while pro-juveniles body length

averages 4.2 mm. No precise data, however, are available on the embryonic and
postembryonic development of the species. Nevertheless, using indirect methods and the
morphometric values of juveniles collected in nature, it can be estimated that four moults
are required to reach adulthood.

Acknowledgments

I am most grateful to Adriano B. Kury (Museu Nacional, Rio de Janeiro) and Eric
Ythier (BYG France) for useful comments to the manuscript. Thanks go also to Elise-
Anne Leguin (Muséum, Paris) for preparing the photos of the holotype, to Philippe
Geniez for authorising the use of figure (1) and the field photo (Fig. 12) and to Lucienne
Wilmé for the preparation of the map (Fig. 11).

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Microbuthus saharicus Lourenco, 2023
urn:lsid:zoobank.org:act:0F365209-468C-4436-A 1 DD-9FEF18F736A8

10

Serket (2023) vol. 20(1): 11-17.

Plexippus C.L. Koch, 1846: a new genus for the Moroccan
araneofauna (Araneae: Salticidae)

Mohamed Mousaid ' & Hicham Bouihouline ”

' Department of biology, Faculty of Sciences and Technics Fez, B.P. 2202, Morocco
* Department of biology, Faculty of Sciences and Technics Beni Mellal, 22030, Morocco
E-mail address: ' mousaid.mohamed2023 @ gmail.com, * bouihouline2@ gmail.com

Abstract

This is the first record of genus Plexippus C.L. Koch, 1846 from Morocco through
the records of two species: Plexippus devorans (O. Pickard-Cambridge, 1872) based on
three male specimens collected from Tinghir (southeastern Morocco) and Plexippus
paykulli (Audouin, 1825) based on three specimens (two males from Beni Mellal, and
one single female from Fez).

Keywords: Plexippus, Plexippus devorans, Plexippus paykulli, Morocco.

Introduction

Morocco has an important biodiversity, and this includes spiders as well. Our
knowledge about Moroccan araneofauna is very limited and needs more studies, as we
indicated in a previous study (Mousaid & Bouihouline, 2023). The jumping spiders are
diurnal animals, unlike most other spiders. And they largely live in urban areas in close
proximity to humans. Morocco has only 24 different genera of jumping spiders (Nentwig
et al., 2023). Genus Plexippus C.L. Koch, 1846 is not one of them.

Plexippus devorans (O. Pickard-Cambridge, 1872) is one of the small species of
the genus whose distribution, according to the World Spider Catalog (2023), includes
Cyprus and Palestine/Israel. According to the original description of this species, it is
characterized by the absence of the two dark bands on the cephalothorax, unlike
Plexippus paykulli (Audouin, 1825) for example (Pickard-Cambridge, 1872). The status
of this species and Plexippus strandi Spassky, 1939 (this species is very similar to
Plexippus devorans even in palp morphology) is somewhat ambiguous. Proszynski

(2003) described some specimens from Palestine/Israel as P. devorans, but later in 2017
he refuted this and described it as a new species: Plexippus gershomi Proszynski, 2017
(Proszynski, 2017). Later, Logunov (2023) proposed the synonymy of Plexippus strandi
with Plexippus gershomi and Plexippus strandi dushanbinus Andreeva, 1969, like
Nenilin (1985) who proposed the synonymy of the species name with Plexippus
coccineus Simon, 1902. The problem with Plexippus devorans is that the original
specimens are lost; there is no holotype to refer to for a new description and a genetic
test. It is possible that Plexippus devorans and Plexippus strandi are the same species.
Overall, three male specimens were collected and examined from Morocco, and we
identified them as Plexippus devorans with the help of a group of senior researchers.

Plexippus paykulli (Audouin, 1825) also known as a pantropical jumping spider,
is a cosmopolitan species of African origin and introduced to Europe, the Americas, the
Middle East, southern Asia, Australia, and the Pacific Islands (Pupin & Brescovit, 2023).
This species is recorded in all North African countries except Morocco (Nentwig et al.,
2023). However, the distribution of the species in the country remains very likely. In this
paper we also present the first record of P. paykulli from Morocco based on three
specimens.

Material and Methods

Three male specimens of Plexippus devorans were collected from Douar Achtat,
Tinghir region in July 2023. Also, two male specimens of Plexippus paykulli were
collected from the courtyard of the Beni Mellal university complex in Mghila in June
2023 and a single female specimen of P. paykulli was collected from Faculty of Sciences
and Technics Fez in October 2023 (Fig. 1). All specimens were preserved in 96% ethanol
and microscopically examined in the Functional Ecology and Environmental Engineering
laboratory in the Faculty of Sciences and Technics Fez, where the specimens were
placed.

oeMille Espagne™

i?
“Ceuta
e

Melilla
e

ecasablanca

Béni ke

Tinghir

132 km ;
mms | adil MET KoXes

Fig. 1. Map of northern Morocco showing specimens collecting stations: Plexippus
paykulli, 24 (white star), 19 (white banded star) and Plexippus devorans, 33.4 (black
star).

12

Results

Plexippus devorans (O. Pickard-Cambridge, 1872) (Figs. 2-6)
Salticus devorans O. Pickard-Cambridge, 1872: 327 (D@).
Hasarius devorans Simon, 1876a: 90.

For more synonyms, see the World Spider Catalog (2023).

Identification reference:
Proszynski (2003: 144, figs. 584-585).

Material examined: 344, Douar Achtat, Tinghir region (31°26'33.7"N, 5°26'17.6"W),
collected on 27/07/2023, examined on 02/11/2023.

hi
a
Fig. 2. Plexippus devorans (O. Pickard-Cambridge, 1872) @, alive, from Ifrane Anti-
Atlas, Morocco (© Abderahim Elaouad).

| mm

3 4

Figs. 3-4. Plexippus devorans (O. Pickard-Cambridge, 1872) 4, habitus. 3. dorsal view.
4. ventral view.

13

Description of the male (Figs. 2-4): Small spiders, 5.5 mm long, general colouration is
yellowish white, with two dark bands on the sides of the opisthosoma. Four dark spots in
the prosoma two of which are located in the position of the posterior eyes (Fig. 3). These
males are similar to the larger males of P. paykulli, but it is easy to distinguish the two
species based on the difference of size, as well as the obvious difference in the prosoma.
Unlike P. devorans, P. paykulli prosoma is yellowish white with two dark bands on sides.
Palpal organ: the sperm duct is large and prominent unlike what we see in P. paykulli
palp (Figs. 5-6).

Figs. 5-6. Plexippus devorans (O. Pickard-Cambridge, 1872), male palpal organ, ventral
view.

Description of the habitat: These specimens were collected from Douar Achtat, Tinghir
(Southeastern Morocco) (altitude: 1240 m) (Fig. 7). Generally this region is characterized
by its arid climate and special vegetation interspersed with Phoenix dactylifera (the
distinctive vegetation of the region), Vachellia tortilis subsp. raddiana, Tamarix sp.,
Ziziphus lotus, Olea europaea (planted).

Fig. 7. Arid habitat in Tinghir, southeastern Morocco.

14

Plexippus paykulli (Audouin, 1825) (Figs. 8-15)

Attus paykullii Audouin, 1825: 409, pl. 7, f. 22 (D3).
Attus ligo Walckenaer, 1837: 426, pl. 12, f. 4 (D).
Euophrys vetusta C.L. Koch, 1846: 219, f. 1264 (D&).
Salticus vaillantii Lucas, 1846: 136, pl. 5, f. 2 (D3).
Salticus culicivorus Doleschall, 1859: 14, pl. 9, f. 5 (D&).
Attus africanus Vinson, 1863: 52, 301, pl. 10, f. 3 (D&).
For more synonyms, see the World Spider Catalog (2023).

Identification references:

Metzner (1999: 255, fig. 101 a-b-c-d).
El-Hennawy et al. (2015: 132, figs. 8-11).
Pupin & Brescovit (2023: 3, figs. 1-6).

Material examined: 263, University complex (Sultan Moulay Slimane) in Mghila
(32°22'16.4"N, 6°19'02.1"W) on 17/06/2023; 12, Faculty of Sciences and Technics Fez
(33°59'58.2"N, 4°59'20.6"W) on 09/10/2023. Examined: 2¢ 4, 17/06/2023, 19°
02/11/2023.

Description of the female (Figs. 8-9): The specimen was approximately 7.5 mm long,
the colouration is dark brown with a light band in the middle of both the prosoma and the
opisthosoma with two light spots in the posterior third of the opisthosoma (Fig. 8).
Epigynum: mainly covered by semitransparent brown waxy secretion (Figs. 10, 15) as
Proszynski (2003) indicated in his description of the species.

l mm

10

Figs. 8-10. Plexippus paykulli (Audouin, 1825) 2. 8-9. Habitus. 8. dorsal view.
9. ventral view. 10. Epigynum, ventral view (S = spermatheca).

15

Description of the male (Figs. 11-12): Body length 8 mm, general colouration yellowish
white with two dark bands on either sides of prosoma and opisthosoma (mostly with two
light spots in the posterior third) (Fig. 11). Ventrally, the body is yellowish white or
brownish white with a clear dark area at the opisthosoma (Fig. 12). Palpal organ:
dorsally, hairy and somewhat earthy in its colouration; with a white spot in the middle;
ventrally, dark with light tibia and long rather white-yellow hair, with a small sperm duct
compared to Plexippus devorans palp (Figs. 13-14).

Figs. 11-13. Plexippus paykulli (Audouin, 1825) @. 11-12. Habitus. 11. dorsal view.
12. ventral view. 13. Palpal organ, ventral view.

Figs. 14-15. Plexippus paykulli (Audouin, 1825). 14. ¢ palp, ventral view.
15. 9 epigynum, ventral view.

16

Discussion

The possibility that Plexippus strandi is a synonym of Plexippus devorans is very
high, and unfortunately without the examination of the holotype of P. devorans, it will be
difficult to resolve the problem decisively. Therefore, we must rely to the identical
descriptions given for both species which indicate a very great similarity.

Acknowledgments

We present this work first to our friend Abderahim Elaouad, who allowed us to
use the picture he took, and second to Dr. Lahsen El Ghadraoui the head of Functional
Ecology and Environmental Engineering laboratory for his valuable assistance. We
would like to express our sincere thanks to Dr. Robert Bosmans, Dr. Youcef Alioua, and
our friend Ghassen Kmira for their valuable assistance to identify Plexippus devorans
specimens.

References

El-Hennawy, H.K., Mohafez, M.A. & El-Gendy, A.A. 2015. The first record of Plexippus
clemens (QO. P.-Cambridge, 1872) (Araneae: Salticidae) in Egypt. Serket, 14(3): 128-133.

Logunov, D.V. 2023. On the jumping spiders (Araneae: Salticidae) from Iran collected by
Antoine Senglet (1927—2015). Arachnology, 19(4): 732-768.

Metzner, H. 1999. Die Springspinnen (Araneae, Salticidae) Griechenlands. Andrias, 14: 1-279.

Mousaid, M. & Bouihouline, H. 2023. First record of Hersilia caudata Savigny, 1825, Tama
edwardsi (Lucas, 1846) (Hersiliidae) and Mimetus laevigatus (Keyserling, 1863) (Mimetidae)
from Morocco. Serket, 19(4): 391-397.

Nenilin, A.B. 1985. Materials on the fauna of the spider family Salticidae of the USSR. II.
Results of the study in the USSR. Trudy Zoologicheskogo Instituta Akademii Nauk SSSR,
Leningrad, 139: 129-134.

Nentwig, W., Blick, T., Bosmans, R., Gloor, D., Hanggi, A. & Kropf, C. 2023. Spiders of Europe.
Version 11.2023. Online at https://www.araneae.nmbe.ch, accessed on 25.11.2023.

Pickard-Cambridge, O. 1872. General list of the spiders of Palestine and Syria, with descriptions
of numerous new species, and characters of two new genera. Proceedings of the Zoological
Society of London, 40(1): 212-354, pl. 13-16.

Proszynski, J. 2003. Salticidae (Araneae) of the Levant. Annales Zoologici, Warszawa, 53: 1-180.

Proszynski, J. 2017. Remarks on the genus Plexippus C. L. Koch, 1846 (Araneae: Salticidae).
Ecologica Montenegrina, 13: 39-69.

Pupin, G.B. & Brescovit, A.D. 2023. The alien synanthropic Salticidae in Brazil (Araneae).
Theringia, Série Zoologia, 113(e2023002): 1-16.

Simon, E. 1902. Etudes arachnologiques. 32e Mémoire. LI. Descriptions d'espéces nouvelles de
la famille des Salticidae (suite). Annales de la Société Entomologique de France, 71(1-2): 389-
421.

Spassky, S.A. 1939. Araneae palaearcticae novae. IV. Folia Zoologica et Hydrobiologica, Riga,
9: 299-308.

World Spider Catalog 2023. World Spider Catalog. Version 24.5. Natural History Museum Bern,
online at http://wsc.nmbe.ch, accessed on 25.11.2023.

17

Serket (2023) vol. 20(1): 18-19.

Stegodyphus semadohensis Deshmukh, 2013 is a nomen nudum
(Araneae: Eresidae)

Danniella Sherwood |” & Hisham K. El-Hennawy :
! Arachnology Research Association, London, United Kingdom
? Fundacion Ariguanabo, San Antonio de los Bafios, Cuba
41 El-Mantega El-Rabia St., Heliopolis, Cairo 11341, Egypt
j Corresponding author e-mail address: danni.sherwood @ hotmail.com

Ujjwala Shivaji Deshmukh described Stegodyphus semadohensis based on a
holotype female from the village of Semadoh in the state of Maharashtra, India
(Deshmukh, 2013; note: the surname of the author is Deshmukh not Shivaji). The
description is very short, and several of the figures are of poor quality. Nonetheless, the
illustrations of the epigyne and vulva are sufficient enough to recognise that it is an adult
female of Stegodyphus pacificus Pocock, 1900. This was subsequently proposed by El-
Hennawy (2016), who synonymised S. semadohensis with S. pacificus. Since both sexes
of §. pacificus were described and illustrated in an extensive revision of Stegodyphus
Simon, 1873 by Kraus & Kraus (1989), it is hard to understand why Deshmukh (2013)
only diagnosed the female of S. semadohensis from the more distantly related
Stegodyphus mirandus Pocock, 1899, and failed to recognise it as a specimen of S.
pacificus.

Regardless, it has been overlooked by El-Hennawy (2016) and the World Spider
Catalog from 2015 to the present day (see World Spider Catalog, 2023) that the name
Stegodyphus semadohensis Deshmukh, 2013 was, in any case, unavailable. Nowhere in
the original description can be found a statement that the type material has been deposited
in a specific collection, nor the name and location of a collection (Deshmukh, 2013).
Therefore, the name is unavailable per Article 16.4.2 of the International Code of
Zoological Nomenclature (ICZN, 1999). The purpose of this short note is to state that
Stegodyphus semadohensis Deshmukh, 2013 is anomen nudum.

Of note, Deshmukh (2013) was, initially, seemingly not fully accessible or widely
known to the arachnological community. It was not until 2015 that it was first indexed in
the World Spider Catalog, at that time still maintained by Norman I. Platnick at the
American Museum of Natural History. In this entry (Platnick, 2015) is an accompanying

note stating “only abstract seen”, indicating the full work (as “Shivaji, 2013”) was not
able to be accessed. In version 15.5 of the Catalog — maintained from thereafter (and until
the present day) by the Naturhistorisches Museum Bern following Platnick’s retirement —
the note added previously was omitted, and a portable document file of the work added,
without recognition S. semadohensis was a nomen nudum (World Spider Catalog, 2015).

Acknowledgment

We would like to thank Theo Blick (World Spider Catalog) for commenting on
this note.

References

Deshmukh, U.S. [not Shivaji, D.U.] 2013. Stegodyphus semadohensis: a new species from family
Eresidae, recorded from Satpuda, Maharashtra, India (Arachnida: Araneae: Eresidae).
Environment Conservation Journal, 14(3): 109-111.

El-Hennawy, H.K. 2016. Stegodyphus tibialis (O. Pickard-Cambridge, 1869) in Central India
(Araneae: Eresidae), with notes on Indian Stegodyphus species. Indian Journal of Arachnology,
5(1-2): 28-35.

ICZN 1999. International Code of Zoological Nomenclature. Fourth edition. International Trust
for Zoological Nomenclature, 106 pp.

Kraus, O. & Kraus, M. 1989. The genus Stegodyphus (Arachnida, Araneae). Sibling species,
species groups, and parallel origin of social living. Verhandlungen des Naturwissenschaftlichen
Vereins in Hamburg (NF), 30: 151-254.

Platnick, N.I. 2015. Eresidae. In: World Spider Catalog. Version 15.0. Archived version available
online at: https://wsc.nmbe.ch/resources/archive/catalog_15.0/ERESIDAE.html.

Pocock, R.I. 1899. Diagnoses of some new Indian Arachnida. Journal of the Bombay Natural
History Society, 12(4): 744-753.

Pocock, R.I. 1900. The fauna of British India, including Ceylon and Burma. Arachnida. Taylor
and Francis, London, 279 pp.

Simon, E. 1873. Etudes arachnologiques. 2e Mémoire. III. Note sur les espéces européennes de la
famille des Eresidae. Annales de la Société Entomologique de France, (5) 3: 335-358, pl. 10.

World Spider Catalog 2015. Eresidae. In: World Spider Catalog. Version 15.5. Archived version
online at: https://wsc.nmbe.ch/resources/archive/catalog_15.5/Eresidae.html.

World Spider Catalog 2023. World Spider Catalog. Version 24.5. Natural History Museum Bern,
online at http://wsc.nmbe.ch, accessed on 14.11.2023.

19

Serket (2023) vol. 20(1): 20-25.

Harpactea umay sp. n., a new spider species from Turkiye
(Araneae: Dysderidae)

Kadir Bogac Kunt ', Ersen Aydin Yagmur ~ & Recep Sulhi Ozkiitiik °
' Cyprus Wildlife Research Institute, Taskent, Kyrenia, Cyprus
* Alasehir Vocational School, Manisa Celal Bayar University, TR-45600 Alasehir,
Manisa, Tiirkiye
* Department of Biology, Faculty of Science, Eskisehir Technical University, TR-26470
Eskisehir, Ttirkiye
* Corresponding author e-mail address: chaetopelma@ gmail.com

Abstract

Harpactea umay sp. n. is described based on both sexes from Tiirkiye. The new
species belongs to the rubicunda species group as defined by Deeleman-Reinhold in 1993
and is closely related to H. bilecenoglui Kunt & Ozkiitiik, 2023, H. elvericii Kunt &
Ozkiitiik, 2023 and H. sanctaeinsulae Brignoli, 1978.

Keywords: Fauna, Harpacteinae, Mediterranean, Anatolia, Tiirkiye.

Introduction

Harpactea Bristowe, 1939, one of the 25 known genera of the family Dysderidae,
consists of 208 species generally distributed in the Mediterranean basin (World Spider
Catalog, 2023).

Recently, studies on the genus Harpactea in and around Tiirkiye and the new
species described have attracted attention (Bosmans & Gavalas, 2023; Kunt & Ozkiitiik,
2023). Every newly discovered species contributes to our understanding of the species
diversity of the genus, even if it has long been said that the genus requires a drastic
revision (see Chatzaki & Arnedo, 2006).

The aim of this study is to describe a new species of Harpactea from Tiirkiye. The
general appearance of the holotype of the new species and photographs detailing the male
and female copulatory organs are here presented.

Material and Methods

All specimens were collected by pitfall traps from Konya province of Tiirkiye.
The samples were preserved in 96% ethanol. The descriptions of the samples were made
from alcohol samples caught in pitfall traps. Digital images of the pedipalp were taken
with a Leica DFC295 digital camera attached to a Leica S8APO stereomicroscope and 5-
15 photographs were taken in different focal planes and combined. All measurements are
in millimetres (mm). Terminology for the body measurements follows Chatzaki &
Arnedo (2006). Terminology for the copulatory organs is adapted from Deeleman-
Reinhold (1993) and Platania et al. (2020).

The following abbreviations are used in the text and figures:

Carapace and abdomen: AL = abdominal length, CL = carapace length, Clh =
clypeus height, CWmax = maximum carapace width, CWmin = minimum carapace
width, TL = Total lenght. Chelicera: ChF = length of cheliceral fang, ChG = length of
cheliceral groove, ChL = total length of chelicera (lateral external view). Eyes: AE =
anterior eyes, AEd = diameter of anterior eyes, 1AE = interdistance of anterior eyes, PLE
= posterior lateral eyes, PLEd = diameter of posterior lateral eyes, PME = posterior
median eyes, PMEd = diameter of posterior median eyes. Legs: Cx = coxa, Fe = femur,
Me = metatarsus, Pa = patella, Ta = tarsus, Ti = tibia. Spination: d = dorsal, pl =
prolateral, rl = retrolateral, v = ventral. Male copulatory bulb: E = embolus, T =
tegulum. Vulva: AA = Anterior margin of the anterior arch, AC = anterior arc, PD =
posterior diverticulum, RS = roundish structure, S = spermatheca, SK = spermathecal
keel, TB = transversal bar. Depository: AZMM = Alasehir Zoological Museum, Manisa,
Turkiye.

Taxonomy
Family Dysderidae C.L. Koch, 1837
Genus Harpactea Bristowe, 1939

Harpactea umay sp.n. (Figs. 1-2)

Material examined: Holotype 14 (AZMM), Tiirkiye, Konya Prov., Seydisehir Dist.,
Geyik Mountains (37°27'24.00"N, 31°43'0.50"E), asl c. 1644 m, 22 Nov. 2016-26 Oct.
2017, Leg. E.A. Ya&mur. Paratypes 720’, 32 9 (AZMM) same data as holotype.

Etymology: Umay is the goddess of fertility in Turkic mythology.

Diagnosis: Males of H. umay sp. n. resemble those of H. bilecenoglui Kunt & Ozkiitiik,
2023, H. elvericii Kunt & Ozkiitiik, 2023 and H. sanctaeinsulae Brignoli, 1978 by the in
terms of the general structure of the bulb, lack of a conductor, and spiniform embolus. In
addition, there is a significant difference between the average lengths of H. umay sp. n.
and the aforementioned species. Namely, the total length of the holotype male of H. umay
sp. n. is 2.55, while the total lengths of the holotype males of the other species are 3.50,
4.35, and 3.87, respectively. There are also slight differences in the morphology of the
bulb and embolus. In H. bilecenoglui, H. elvericii, and H. sanctaeinsulae the bulb is more
spherical, while in H. umay sp. n. it is more oval and the embolus is more delicate (see
Brignoli (1978) and Kunt & Ozkiitiik (2023)). The vulva of H. umay sp. n. resembles that
of H. bilecenoglui in the general structure of the anterior arc. However, there are
proportional differences between the anterior, central, and posterior parts of the
spermatheca between species. In H. bilecenoglui, the anterior part of the spermatheca is
usually longer than the posterior part, whereas in H. umay sp. n., the lengths of both parts
are almost equal (see Kunt & Ozkiitiik (2023)).

21

Description: Measurements: [Holotype < / Paratype 2] TL 2.55/3.60; AL 1.40/2.25;
CL 1.15/1.35; Clh 0.02/0.03; CWmax 1.00/1.10; CWmin 0.50/0.60; AEd 0.07/0.08; iAE
0.02/0.02; PLEd 0.05/0.07; PMEd 0.05/0.05; ChF 0.23/0.29; ChG 0.11/0.16; ChL
0.52/0.62.

Small-sized harpacteine spiders. Male and female individuals do not differ
morphologically from one another. Leg length does not significantly differ between the
sexes, despite the fact that females’ body parts are clearly larger. Carapace hexagonal,
brown. Fovea longitudinal and distinct. AE, PLE and PME arranged annularly. AE and
PLE in contact with each other. The distance between the AE is approximately one-
quarter of the diameter of the anterior eye.

Fig. 1. Harpactea umay sp. n. A-B. Habitus of holotype male. A. dorsal view. B. ventral
view. C. Chelicerae, ventral view (red dots, promarginal; white dots, retromarginal teeth).

22

Sternum, labium and gnathocoxae brown. Chelicerae dark brown. Cheliceral groove with
four teeth (Fig. 1C). Promarginal teeth are more strongly developed than retromarginal
teeth. Of the promarginal teeth, the one at the base of the cheliceral groove is
approximately twice as large as the one in the centre. The distance between the two is
close to the base length of the larger one. Of the retromarginal teeth, the one in the centre
of the cheliceral groove is larger than the one at the base. The distance between them is
about three times their basal length.

Fig. 2. Harpactea umay sp. n. A-B. Bulb (right). A. prolateral view. B. retrolateral view.
C-D. Vulva. C. dorsal view. D. ventral view.

Abbreviations: AA = anterior margin of the anterior arch; AC = anterior arc; E = embolus;
PD = posterior diverticulum; RS = roundish structure; S = spermatheca; SK = spermathecal keel;
T = tegulum; 7B = transversal bar.

23

Legs brownish. The anterior tarsi have very weak scopulae, while the posterior tarsi and
metatarsi have weak scopulae. Prolateral side of the posterior coxae with spines. Leg
formula: IV, I, II, HI. Detailed leg spination and measurements are given in Tables (1-2,
respectively). Abdomen and spinnerets greyish yellow.

Palp (Figs. 2A-B): palpal tarsus (0.27) slightly longer than tibia (0.23). Tegulum oval,
longer than wide. Narrowing towards distally. Embolus spiniform. Tegulum (0.27) longer
than embolus (0.21). Conductor and median apophysis absent.

Vulva (Figs. 2C-D): tip of spermathecal keel straight. Centre of spermatheca large,
quadrangular (Fig. 2C). Posterior part of spermatheca more strongly sclerotized than
anterior part. Anterior part is also longer than posterior one. Anterior margin of the
anterior arch shorter than transversal bar (Fig. 2C). In dorsal view, roundish structures
prominent, chevron-shaped (Fig. 2D). Transversal bar slightly concave. Posterior
diverticulum distinct, membranous, approximately equal in width to length (Fig. 2C).

Table 1. Leg spination of Harpactea umay sp. n. (Holotype & / Paratype &).

Eas

SE a a 0 |
Mea 0 | Oo | tp UTC SS
Se Sa aS SSS a

mea || a pliddni,t2v | 2pli,id3nii,2v |
| Me | 0 | 0 | 3pl3ri2v_ | 3plid3rii,1,2v__|
ae eee ee ees

-
Micmm 0 | Oo | ip | ip |
2 a a a a ae
Moe || pliddrltj2v | Splijid3nit2v |
| Me | 0 | 0 | 3pl3r2v | 3pliid3rli,1,2v_|

Table 2. Leg measurements of Harpactea umay sp. n. (Holotype ¢ / Paratype °).

| Pa | 0.65/0.65 | —0.60/0.60_ | 0.30/0.25 | 0.44/0.58

0.65/0.60 0.65/0.65 0.65/0.63 1.00/1.10
0.30/0.30 0.30/0.30 0.30/0.28 0.40/0.30
3.45/3.30 3.30/3.14 2.60/2.44 3.92/4.16

Distribution: Known only from type locality.

Notes

Deeleman-Reinhold (1993) divided the genus Harpactea into 4 groups according
to the characteristics of the copulatory organs of both sexes. Based on her classification,
H. umay sp. n. should be included in the rubicunda (D) group based on the structure of
the male copulatory organ and the 3rd patellae and 4th coxae with spines.

This species increases the number of Harpactea species known from Tiirkiye to
36; 29 of them are endemic.

24

Acknowledgments

We are grateful to Dr. Sinan Anlas, Dr. Semih Orgel, and Serkan Yaman (Manisa,
Ttirkiye) for their help in field trips.

References

Bosmans, R. & Gavalas, I. 2023. The spiders (Araneae) of the tiny Greek island Iraklia
(Kiklades), with the descriptions of 5 new Harpactea species (Araneae: Dysderidae), 3 species
new to Europe and 8 new to Greece. Parnassiana Archives, 11 (Supplementum 1): 1-91.

Brignoli, P.M. 1978. Ragni di Turchia V. Specie nuove o interessanti, cavernicole ed epigee, di
varie famiglie (Araneae). Revue Suisse de Zoologie, 85(3): 461-541.

Chatzaki, M. & Arnedo, M.A. 2006. Taxonomic revision of the epigean representatives of the
spider subfamily Harpacteinae (Araneae: Dysderidae) on the island of Crete. Zootaxa, 1169: 1-32.

Deeleman-Reinhold, C.L. 1993. The genus Rhode and the harpacteine genera Stalagtia, Folkia,
Minotauria, and Kaemis (Araneae, Dysderidae) of Yugoslavia and Crete, with remarks on the
genus Harpactea. Revue Arachnologique, 10(6): 105-135.

Kunt, K.B., Ozkiitiik, R.S. 2023. New data on the Harpacteinae of Turkey (Araneae, Dysderidae).
Zootaxa, 5375(3): 379-408.

Platania, L., Pavlek, M. & Arnedo, M. 2020. Testing the monophyly of the ground-dweller spider
genus Harpactea Bristowe, 1939 (Araneae, Dysderidae) with the description of three new
species. Systematics and Biodiversity, 18(7): 688-707.

World Spider Catalog 2023. World Spider Catalog. Version 24.5. Natural History Museum Bern,
online at http://wsc.nmbe.ch, accessed on 09.12.2023.

Harpactea umay Kunt, Yagmur & Ozkiitiik, 2023
urn:lsid:zoobank.org:act:B8B8613A-178C-44C 1-AEB2-A42B467F60F0

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Serket (2023) vol. 20(1): 26-38.

Spiders as a bio-agent factor in a Mango greenhouse at Giza
Governorate, Egypt

Doaa M.A. Abdel-Ghani ais Mourad F. Hassan * & Gihan MLE. Sallam '

' Plant Protection Research Institute, Agriculture Research Center, Dokki, Giza, Egypt
* Department of Zoology and Agriculture Nematology, Faculty of Agriculture, Cairo
University, Giza, Egypt
* Corresponding author e-mail address: doaamahmoud18 @ gmail.com

Abstract

Spiders were collected from Mango greenhouse at Giza Governorate. There were
27 species belonging to 13 families found on ground and 11 species belonging to 6
families found on foliage. There were 22 species recorded as new locality records of Giza
governorate and one species as a new record in Egypt, i.e. Theridion hannoniae. From
these species, there are two _ species in terms’ of _ toxicity: Loxosceles
rufescens and Latrodectus geometricus. Most families found on mango trees do not spin
webs to catch their prey, they are active hunter spiders: Dysderidae, Gnaphosidae,
Lycosidae, Oonopidae, Philodromidae, Salticidae, and Cheiracanthiidae. These families
play an important role in reducing the pest below the economic threshold level, whereas
their predators are more specialised and good hunters. Photos of external genitalia of
several species are added to facilitate identification.

Keywords: Foliage habitat, ground-dwelling habitat, greenhouse, Mango, Theridion
hannoniae, Giza, Egypt.

Introduction

Greenhouse system is one of the protected cultivation types used to produce
vegetables and flowers. High-density planting is a way to get high yield in short time.
The increase in area, easier harvest and pest management, and high yield in short time for
high profit can be listed for the reasons to approach high-density planting (Cary, 1981).

High density culture, which allows for a greater yield in less time than traditional
cultivation, is becoming more and more common in the fruit industry. By using various
applications, this strategy has promoted the development of dwarf trees under controlled
culture. Fruit production in greenhouses has the potential to improve fruit crops' output,
quality, off-season cultivation, and exportability. In the greenhouses, you may now grow
a variety of fruit trees while maintaining environmental control to guarantee a bountiful
harvest. In brief, if you start with a clean greenhouse and plants, bugs shouldn't be an
issue while managing insect and mite pests in greenhouses.

Stability in predator-prey systems is achieved by density-dependent responses of
the predator to the prey. As prey populations increase, predation pressure should increase,
and predation pressure should lessen as prey population decreases (Morin, 1999).

All spiders are predaceous and insects constitute their primary prey (Turnbull,
1973). They are generalist predators that may be of importance in reducing and even
preventing outbreaks of insect pests in agriculture (Sunderland et al., 1986). A diverse
group of spiders may be effective in biological control because they differ in hunting
strategies, habitat preferences, and active periods (Marc et al., 1999). Numerous
researchers have stressed that an assemblage of spider species is more effective at
reducing prey densities than a single species of spider (Greenstone, 1999).

Spiders can be very helpful in controlling greenhouse pests and are important
general predators. For that reason we should consider allowing them to coexist with our
plants (Smith, 2000).

Material and Methods
Methods of collecting

Spiders were collected from Mango (cultivar Keitt) greenhouse. Abundance was carried
out during December 2017 to May 2018 in greenhouses at Giza governorate, twice a
month, by two collecting methods: a. Beating net (branch shaking), b. Hand sorting. The
hand sorting method was used to pick the spider individuals around each plant or on the
ground. After collecting, the specimens were picked up and kept individually in plastic
vials.

Fig. 1. Mango trees inside greenhouse at Giza Governorate.

2}

Identification and preservation of spiders

After counting the individuals of spiders, they were preserved in 70% ethyl alcohol in
glass vials. Adult males and females were used to recognize the different species, while
immature stages were used to recognize only the families. Genitalia of females were
carefully separated and mounted in Berlese medium on microscopic glass slides for
identification by using light microscope.

Table 1. Spider families found on ground below Mango trees.

Dysderidae Dysdera crocata C.L. Koch, 1838

Berlandina venatrix (O. Pickard-Cambridge, 1874)
Micaria dives (Lucas, 1846)
Gnaphosidae Poecilochroa pugnax (O. Pickard-Cambridge, 1874)

Setaphis subtilis (Simon, 1897)
Synaphosus syntheticus (Chamberlin, 1924)
Zelotes laetus (O. Pickard-Cambridge, 1872)

Hogna ferox (Lucas, 1838)
, |
Lycosidae Do not spinweb 7, chosa urbana O. Pickard-Cambridge, 1876
Active hunter spider | Wodgicosa fidelis (O. Pickard-Cambridge, 1872)
Obnonid Dysderina scutata (O. Pickard-Cambridge, 1876)
ia ania Opopaea santschii Brignoli, 1974

Philodromus sp.
Philodromidae Pulchellodromus glaucinus (Simon, 1870)

Thanatus fabricii (Audouin, 1825)
Heliophanillus fulgens (O. Pickard-Cambridge, 1872)
Salticidae

: Phlegra bresnieri (Lucas, 1846)
Plexippus paykulli (Audouin, 1825)

Scytodidae Do not spin web Scytodes velutina Heineken & Lowe, 1832
Passive spider Loxosceles rufescens (Dufour, 1820)

Uroctea limbata (C.L. Koch, 1843)
Synaphridae Spin web Sinai ee eer ae
ape | Steatoda erigoniformis (O. Pickard-Cambridge, 1872) __
Theridiidae Theridion hannoniae Denis, 1945

Nurscia albomaculata (Lucas, 1846)

Results and Discussion

Linyphiidae Agyneta rurestris (C.L. Koch, 1836)

Dominance and occurrence of spider species on Mango trees in greenhouses in Giza
governorate

The physiognomy or structural features of habitats has an important influence on
habitat selection, and ultimately on spider species composition of habitats (Uetz, 1991).
Vegetation structure, diversity, and architecture all play significant roles in habitat
selection and residency (Jennings et al., 1990).

During the present work, it was found that 38 spider species belonging to 17
families were collected among mango trees in greenhouses in Giza governorate.

28

The spiders of 14 species of seven families that spin webs were found
(Dictynidae, Linyphiidae, Oecobiidae, Synaphridae, Theridiidae, Titanoecidae, and
Uloboridae). The most abundant family was Theridiidae, which included eight spider
species.

The spider families that do not spin webs were divided into:

a) Active hunter spiders, which included 21 species of seven families (Cheiracanthiidae,
Dysderidae, Gnaphosidae, Lycosidae, Oonopidae, Philodromidae, and Salticidae). The
most abundant family was Gnaphosidae which included six spider species.

b) Passive hunter spiders, which included three species of three families (Scytodidae,
Sicariidae, and Thomisidae) (Table 1).

In foliage, there are six families, of which the dominant family that does not spin
web, active hunter is Cheiracanthiidae, represented by one species, followed by
Theridiidae, represented by six species that spin web in Table (2).

In two different habitats, there are different behaviours of these families. On the
ground, there are 13 families; the dominant family that does not spin a web and is an
active hunter is Salticidae, represented by three species, followed by Lycosidae,
represented by four species, and the lowest family is Dysderidae represented by one
species in Table (1).

From these species, there are 20 species recorded as new locality records at Giza
governorate, i.e. Agyneta rurestris, Berlandina venatrix, Dysdera crocata, Dysderina
scutata, Heliophanillus fulgens, Latrodectus geometricus, Loxosceles rufescens, Micaria
dives, Nigma conducens, Opopaea santschii, Phlegra bresnieri, Poecilochroa pugnax,
Setaphis subtilis, Steatoda erigoniformis, Synaphosus syntheticus, Thanatus fabricii,
Trochosa urbana, Uloborus plumipes, Wadicosa fidelis, and Zelotes laetus.

A new record in Egypt is Theridion hannoniae. The dominant spider species that
do not spin webs as active hunter spiders, 21 species of them are good searchers to find
their prey.

Table 2. Spider families found on foliage of Mango trees.

ae Do not spin web Cheiracanthium isiacum O. Pickard-Cambridge, 1874

Salticidae Active hunter spider | Thyene imperialis (Rossi, 1846) | Thyene imperialis (Rossi, 1846) imperialis (Rossi, 1846)

Do not spin web
Thomisidae Thomisus citrinellus Simon, 1875
Passive spider

|Dictynidae | Nigma conducens (O. Pickard- ee 1876)

i | Euryopis episinoides (Walckenaer, 1847) (Walckenaer, 1847)

Kochiura aulica ee L. Koch, 1838)

Latrodectus fae C.L. Koch, 1841
Theridiidae Spin web

Se incanescens Simon, 1890

Theridion | Theridion jordanense Levy & Amitai, 1982 ae es ee ee & Amitai, 1982

Theridion melanostictum O. Pickard- eerie ae 1876

|Uloboridae |

Uloborus | Uloborus plumipes Lucas, 1846. Lucas, 1846

Seventeen spider families were recorded in mango cultivars (Keitt) (Table 3).
Their dominances ranged from 0.2% to 20.6%. Cheiracanthiidae and Theridiidae are the

29

dominant families at 18.3% and 20.6%, respectively, while Dictynidae 2.1%, Dysderidae
0.2%, Linyphiidae 1.7%, Oecobiidae 0.6%, Oonopidae 1.2%, Philodromidae 4.2%,
Scytodidae 2.9%, Sicariidae 1%, Thomisidae 1.7%, and Titanoecidae 0.4% are the
accidental families. Gnaphosidae 10.2%, Lycosidae 9.1%, Salticidae 13.1%, Synaphridae
5.6%, and Uloboridae 7.1% are accessory families. These results are consistent with
(Mohafez et al., 2010) that in the collected samples of spiders from orchards of mango in
Tahta district, the dominant families were Lycosidae, Gnaphosidae, and Theridiidae. In
Temma district the dominant families were Lycosidae and Miturgidae (now
Cheiracanthiidae).

Table 3. Dominance of spider families on Mango in greenhouse.

FOccobiidue «|S

|
ne
Accessory
|

Data given in Table (4) indicated that the family Cheiracanthiidae was the most
abundant on mango in the greenhouse (100), followed by the family Theridiidae (74) as
juveniles. Both spider families Dysderidae and Oonopidae were collected as adult female
specimens only. And the lowest families abundant were Titanoecidae, Oecobiidae, and
Linyphiidae (1, 4, 7), respectively.

One hundred twenty-five adult individuals (49 @, 76 9) were collected,
representing 35 species belonging to 15 families. The family Theridiidae, with eight
species: Euryopis episinoides, Kochiura aulica, Latrodectus geometricus, Steatoda
erigoniformis, Theridion incanescens, T. jordanense, T. melanostictum, and
T. hannoniae, was the most frequent family, followed by Synaphridae with one species,
Synaphris letourneuxi, and the family Salticidae with four species, Heliophanillus
fulgens, Phlegra bresnieri, Plexippus paykulli, and Thyene imperialis. Even if collecting
was not strictly standardised, some differences in abundance and frequency were obvious.
The most frequent species in mango greenhouse was Synaphris letourneuxi, but the most
abundant species were Kochiura aulica and Theridion incanescens. The two most

important species of spiders in terms of toxicity are Loxosceles rufescens and Latrodectus
geometricus, which were recorded in Giza governorate as a new locality.

30

Table 4. Occurrence of spider families as juveniles and adults of Mango trees in
greenhouse during six months.

Months of collecting Total Number

on "amie |efadus
[cheats | 22 [2 [we [asi | 0 | 7
Dewnidee [i [> [2[1]1[o > [«
[empties [3 [a [«>o[s> «| « [3
Linpiae [0 [i [s[1]i[a [7 [2
izes [sf [+ fr [s> | a [8
foxes [1 [1 [ofr fifo] « [0
fruicdromites [4 [5 [2 [3 [ipo] is [4
suiiae | [4 [wl folo | # | 6
sqtwae [1 [s[ols]«>o] 3 | s_
siariaae fo [a fif«fsps | 2 [0
there [fu fs [ful s | | 2
Fmomisive [1 [0 [ola [s>s [wo | +
Tiimeeane [1 [0 [olo}olo [1 [1
furteiae [a [s[i [ol] » [+

Taxonomical characters of male and female genitalia

The external sexual organ is often so specific to a species that systematists use
them as decisive characters for species identification. In the haplogyne male spiders the
simplest form of a palp is seen. The tarsus of the palp (cymbium) carries an extension in
the form of pear-shaped bulb, or palpal organ. The male palps are much more complex in
entelegyne spiders because the wall of the palpal organ consists of hard, sclerotized parts
and soft area; both can bear special protrusions which play an essential role during
copulation.

In haplogyne female spiders, the spermathecae are typically blind sacks connected
to a duct or stalk, in entelegynes at least one spermatheca on each side connects to both
the copulatory and the fertilization ducts. Entelegynes usually have two pairs of ball-
shaped receptacles, the primary and secondary spermathecae (Foelix, 1996).

During the present study several families were collected, males and females
genitalia were separated to identify spider species. Photos of external genitalia of several
species are added below to facilitate identification.

Haplogyne families

Here, there are three families of this group of spiders: Dysderidae, Oonopidae, and
Scytodidae (Figs. 1-4).

31

x all

Figs. 1-3. 2 genitalia. 1. Family Dysderidae, Dysdera crocata. 2-3. Family Oonopidae,
2. Dysderina scutata. 3. Opopaea santschii.

Fig. 4a-b. Family Scytodidae, Scytodes velutina. a. 2 genitalia. b. 3 palp, lateral views.

Entelegyne families

In this work, there are 12 families of this group of spiders: Cheiracanthiidae, Dictynidae
Gnaphosidae, Linyphiidae, Lycosidae, Philodromidae, Salticidae, Synaphridae,
Theridiidae, Thomisidae, Titanoecidae, and Uloboridae (Figs. 5-29).

=,

— |

bE

Fig. 5a-b. Family Cheiracanthiidae, Cheiracanthium isiacum. a. 9° epigynum, ventral
view. b. 3 palp, lateral views.

Fig. 6a-b. Family Dictynidae, Nigma conducens. a. 2 epigynum, ventral view. b. 3 palp,
retrolateral and ventral views.

32

Figs. 7-11. Family Gnaphosidae

Fig. 11. Zelotes laetus. a. 9° epigynum, dorsal view. b. @ palp, mesoventral and
retrolateral views.

33

Fig. 12. Family Linyphiidae, A gyneta rurestris, ° epigynum, ventral view.

Figs. 13-15. Family Lycosidae

Figs. 14-15. ¢ palp, lateral and ventral views. 14. Trochosa urbana. 15. Wadicosa fidelis.

Fig. 16. Family Philodromidae, Pulchellodromus glaucinus, 8 epigynum, dorsal view.

34

Figs. 17-18. Family Salticidae

Fig. 17. Heliophanillus fulgens. a. 2 epigynum, dorsal view. b. @ palp, retrolateral and
mesoventral views.

Fig. 19. Family Synaphridae, Synaphris letourneuxi. a. 9 genitalia, dorsal view. b. 3
palp, retrolateral and ventral views.

Figs. 20-26. Family Theridiidae

Fig. 20. Euryopis episinoides. a. ° genitalia, dorsal view. b. @ palp, retrolateral view.

35

Fig. 22. Theridion hannoniae
mesoventral views.

24

Figs. 24-25. ° genitalia, dorsal view. 24. Theridion jordanense. 25. Theridion
melanostictum.

36

a b

Fig. 26. Latrodectus geometricus. a. 2 epigynum, dorsal view. b. 3 palp, retrolateral
view.

Fig. 27. Family Thomisidae, Thomisus citrinellus [T. spinifer]. a. 2° genitalia, dorsal
view. b. 3 palp, ventral and retrolateral views.

Fig. 28. Family Titanoecidae, Nurscia albomaculata. a. 9 genitalia, ventral view. b. 3
palp, lateral views.

Fig. 29. Family Uloboridae, Uloborus plumipes. a. 2 genitalia, dorsal view. b. @ palp,
retrolateral and ventral views.

3h

Acknowledgments

Sincere thanks are due to late Dr. Mohamed Abd El-Aziz Zaher professor of
Acarology, faculty of Agriculture, Cairo University for his supervision of the thesis of the
first author and his help. Grateful appreciation to Colonel Hisham Kamal El-Din El-
Hennawy (Arachnid Collection of Egypt) for helping in identification of some spider
samples.

References

Cary, P.R. 1981. Citrus tree density and pruning practices for the 21st century. In: Proceedings of
the International society of Citriculture, pp. 165-168.

Foelix, R.F. 1996. Biology of spiders. 2nd Ed. Oxford University Press, 330 pp.

Greenstone, M.H. 1999. Spider predation: how and why we study it. Journal of Arachnology,
27(1): 333-342.

Jennings, D.T., Vander Haegen, W.M. & Narahara, A.M. 1990. A sampling of forest-floor
spiders (Araneae) by expellant, Moosehorn National Wildlife Refuge, Maine. Journal of
Arachnology, 18(2): 173-179.

Marc, P., Canard, A. & Ysnel, F. 1999. Spiders (Araneae) useful for pest limitation and
bioindication. Agriculture, Ecosystems & Environment, 74: 229-273.

Mohafez, M.A., Al-Akraa, T.M.M. & El-Danasory, M.A.M. 2010. Incidence and seasonal
fluctuation of true spiders inhabiting different orchard trees at Sohag governorate. Mansoura
University Journal of Plant Protection and Pathology, 1(15): 241-250.

Morin, P.J. 1999. Community ecology. Blackwell Science, Inc., Malden, MA. 424 pp.

Smith, S. 2000. Greenhouse gardener's companion: Growing food and flowers in your
greenhouse or sunspace. Fulcrum Publishing. 497 pp.

Sunderland, K.D., Fraser, A.M. & Dixon, A.F.G. 1986. Field and laboratory studies on money
spiders (Linyphiidae) as predators of cereal aphids. Journal of Applied Ecology, 23(2): 433-447.

Turnbull, A.L. 1973. Ecology of the true spiders (Araneomorphae). Annual Review of
Entomology, 18(1): 305-348.

Uetz, G.W. 1991. Habitat structure and spider foraging. In: Bell, S.S., McCoy, E.D., Mushinsky,
H.R., eds. Habitat structure: the physical arrangement of objects in space. London, England:
Chapman and Hall. pp. 325-348.

38

Serket (2023) vol. 20(1): 39-57.

DNA barcode and phylogenetic analysis for the araneid spider
Neoscona theisi (Walckenaer, 1841) (Arachnida: Araneae:
Araneidae) from India

Sachin R. Patil
Zoological Survey of India (ZSI), Western Regional Centre (WRC), Pune 411044, India
E-mail: srpatil17 @ gmail.com

Abstract

Present study reports the orb-weaver spider Neoscona theisi (Walckenaer, 1841)
from the Northern Western Ghats, India with its DNA barcode studies and a preliminary
phylogenetic analysis. Although the species is taxonomically well established with wide
range of distribution, DNA barcode with verifiable voucher specimen in a National
Repositories are wanting. In the data driven era and metabarcoding, DNA barcode library
with verifiable voucher specimens are crucial. In the present account taxonomic account
of the species is revisited, along with DNA barcode and discussion are made on the utility
of DNA barcodes and reference barcode library.

Keywords: Araneidae, Neoscona theisi, DNA Barcode library, Phylogeny, northern
Western Ghats, India.

Introduction

Spiders constitute a varied group of invertebrates with archaeological records
dating back to the Devonian period and having ancient evolutionary history (Tyagi et al.,
2019). Araneid spiders, also known as orb-weaving spiders, are a family of spiders
classified under the family Araneidae. These spiders are known for their intricate,
circular-shaped webs that they use to capture prey. These spiders are generally nocturnal
and rebuild their webs each night. They exhibit a remarkable ability to sense vibrations
on their webs, allowing them to detect prey or potential threats.

Araneid spiders are found worldwide, except in extremely cold regions. The
current world count of spiders has 51,784 species of 136 families (World Spider Catalog,
2023). They typically prefer areas with vegetation and places where their webs are less
likely to be disturbed.

Neoscona Simon 1864 is a genus of spiders belonging to the family Araneidae.
These spiders are commonly known as "spotted orb-weavers" or "spotted garden spiders."
The genus Neoscona has a wide distribution across various regions, including North
America, Europe, Asia, Africa, and Australia (World Spider Catalog, 2023). These
spiders are medium to large-sized orb-weavers. They typically have a round abdomen
with a range of colours, including shades of brown, yellow, or grey. One distinctive
feature of Neoscona spiders is the presence of spots or markings on their abdomen called
sigilla which can vary in pattern and colouration among different species. Genus
Neoscona is represented by 32 species known from India (Table 1).

Pioneer studies on spider’s documentation from India has been by Tikader from
1980’s and since then the number of species recorded till date has increased from 1067
species in 1987 to present day reported diversity comprised in 61 families, 495 genera
with 1954 species (Caleb & Sankaran, 2023). The present diversity of 1954 species may
be under representation of the group from India, as most of the studies are limited to
morphology-based reports or checklists with poor representation of the group on genetic
scale from India. In the present era of DNA barcoding there are marginal studies
encompassing the genetic studies on this diverse class of arachnids. Despite of being a
megadiverse country harbouring rich diversity of life forms, the rate of species
documentation from India is slow which needs to be paced up in the immediate future for
which DNA barcodes represent a handy tool.

DNA barcodes having the potential of species delimitation will help in filling the
gaps of faunal documentation and improve our current understanding of faunal diversity,
distribution, and related aspects, additionally it will aid in future in identification and
other studies when actual specimen collection may be a limitation. DNA barcoding
studies from a taxonomically identified voucher specimens in India are still in upcoming
stages in many groups especially among arthropods including spiders (Tyagi et al., 2019).
Only countable studies exist at present (Dinesh et al., 2023; Tyagi et al., 2019; Gaikwad
et al., 2017) in context to spiders documentation in aid with DNA barcodes from India,
while spider’s documentation from the global biodiversity hotspot, the Western Ghats
outlining the western peninsula of India is negligible and remains poorly explored. As
suggested by Robinson et al. (2009) DNA barcodes not only assist in species identity
confirmation but also plays a significant role in resolving taxonomic uncertainties. Hence
it becomes necessary to have DNA barcode data in a group as vast as that of spiders from
the Western Ghats which is substantially reported to inhabit endemic and unique lineages.

DNA barcoding is a valuable tool for specimen identification and species
discovery of Indian spiders by detection of cryptic species and species complex (Tyagi et
al., 2019). The morphological identification and analysis are tedious and time-consuming
tasks due to sexual dimorphism, polymorphism, morphological variations and lack of
identification keys for juveniles (Coddington & Levi, 1991; Magalhaes er al., 2017).
DNA barcoding is a very useful and emerging technique to overcome these hurdles for
identification (Hebert et al., 2003). This tool is widely used in biodiversity research, as it
provides accurate species identification (Hebert et al., 2003). DNA barcoding has
emerged as an additional tool for taxonomy and as an aid to taxonomic impediments
(Gaikwad et al., 2017). Gaikwad et al. (2017) had conducted DNA barcoding study of
spiders from India which included 17 morphologically identical species. Wheeler et al.

40

(2017) studied the spider tree of life, phylogeny of Araneae based on target-gene analyses
from an extensive taxon sampling.

The present study is an attempt to report a species of Neoscona from the Northern
Western Ghats (NWG) with its DNA barcode, and the phylogeny of Neoscona 1s
provided to affirm the genetic identity and discussion are made on the utility of DNA
barcodes and reference barcode library.

Material and Methods

Specimens Collecting: The specimens were collected from the campus of Zoological
Survey of India (ZSI), Western Regional Centre (WRC), Pune (18.648 N, 73.760 E;
altitude 580 m) as a part of training under Green Skill Development Program (GSDP) on
06.09.2018 by Shazia Quasin. The specimens are deposited in the National Zoological
Collection (NZC) of ZSI, WRC, Pune (ID. Register No. Ar/715).

Molecular studies: DNA isolation was performed from a single leg using DNeasy Blood
and Tissue Kit (Qiagen) as per the manufacturer’s protocol, followed by quantitation
utilizing the HS dsDNA assay kit on Qubit 2.0 fluorometer. Amplification of the mt COI
gene was performed using Folmer’s universal primer, LCO1490 and HCO2198 (Folmer
et al., 1994) in 25uL reaction volume constituted by 12.5 uL of 2X Go Taq Hot Start
Master Mix (Promega), 0.4uM of each forward and reverse primer along with 50mg of
template DNA and Nuclease free water up to Q.S. Thermal cycling profile included one
cycle of denaturation at 95°C for 2 mins, followed by 35 cycles of initial denaturation at
95°C for 0.5 minutes, annealing at 47-49°C for 45 secs, and extension at 72°C for one
min; and final extension at 72°C for 5 minutes. Amplified PCR product was confirmed by
Gel Electrophoresis stained by SYBR safe DNA gel stain (Invitrogen), and visualized
under UV by Gel Documentation system. Amplified PCR products were purified by
Invitrogen’s Pure Link PCR Purification Kit. Purified PCR product was outsourced for
bidirectionally Sanger’s sequencing to Barcode Biosciences Pvt Ltd, Bangalore.

Obtained chromatograms were manually checked for quality and _ corrections.
Additionally, 784 mt COI sequences of Neoscona were downloaded from the GenBank,
of which only two sequences per species were kept, except for the species of our interest
while rest of the sequences were excluded from the analysis. Sequence alignment, name
editing, and translation checking were performed in MEGA XI software (Tamura et al,
2021). Maximum Likelihood analysis was built in IQ tree webserver with 1000 ultrafast
bootstraps and SH-aLRT branch test under TIM2+F+I+G4 model auto selected according
to Bayesian Information Criterion (BIC) with 220 sequences (Appendix 1). Resultant tree
was visualized by Fig Tree v1.4.0 treating species Araneus as out group following Xu et
al. (2019) and Tyagi et al. (2019).

The present collection from Pune was identified as Neoscona theisi based on the
literature studies as well as DNA barcode studies.

Abbreviations used in the text: AL = abdomen length, ALE = anterior lateral eye,
AME = anterior median eye, AW = abdomen width, CL = carapace length, CW =
carapace width, PLE = posterior lateral eye, PME = posterior median eye, sps. = group of
different species of the same genus, TL = total length. Leg measurements: TL (Femur,
Patella, Tibia, Metatarsus, Tarsus). All measurements are in millimetres (mm).

4]

Results
Systematic Account

Kingdom Animalia
Phylum Arthropoda
Subphylum Chelicerata
Class Arachnida
Order Araneae
Infraorder Araneomorphae
Family Araneidae
Genus Neoscona
Species Neoscona theisi (Walckenaer, 1841)

Epeira theis Walckenaer, 1841
For all synonyms, see the World Spider Catalog (2023).

Material Examined: ID. Reg. No. Ar/715 (NZC: ZSI WRC Pune), 1 female, ZSI
Akurdi Campus, 06.09.2018, Coll. S. Quasin.

Measurements (female): TL 7.57, CL 2.79, CW 2.64, AL 4.79, AW 3.86.

Interocular distance: AME-AME 0.36, ALE-AME 0.50, ALE-ALE 1.21, PME-PME
0.21, PLE-PME 0.57, PLE-PLE 1.25, ALE-PLE 0.11, AME-PME 0.18 Legs: I 12.57
(3.29, 1.43, 3.00, 3.71, 1.14); Il 9.57 (1.86, 1.14, 2.71, 3.00, 0.86); III 6.43 (1.71, 1.00,
1.29, 1.57, 0.86); IV 12.29 (3.43, 1.43, 2.86, 3.57, 1.00). Leg formula 1423.

Morphological Description

Diagnostic Characters (Fig. 1)

Colouration: Cephalothorax and legs yellowish brown, abdomen brownish white.
Cephalothorax: longer than wide, narrowing in front, clothed with pubescence and hairs,
provided with two lateral and one rnedian longitudinal dark brown bands; thoracic region
provided with distinct longitudinal groove. Ocular quad longer than wide and wider in
front than behind. Anterior median eyes larger than posterior medians; lateral eyes close;
both rows of eyes slightly recurved. Sternum heart-shaped, pointed behind, clothed with
pubescence and hairs, dark brown, provided with a conspicuous mid-longitudinal bar.
Labium wider than long, dark brown. Maxillae longer than wide, dark brown in colour
but anterior border pale, distal end provided with scapulae. Chelicerae strong, light brown
with prominent boss. Legs long and strong, clothed with hairs and spines, provided with
transverse black bands.

Abdomen: Sub-oval, longer than wide, anterior end wider than posterior end, clothed
with pubescence and hairs, overlapping on the cephalothorax. Dorsum of abdomen
provided with a conspicuous mid-longitudinal chalk white bar having four pairs of lateral
projections. Four pairs of sigilla present on the dorsum, arranged mid-longitudinally.
Ventral side light brownish, mid-ventrally having a deep brown broad patch in between
epigastric furrow and the spinnerets, lateral sides of this patch guarded by chalk white
patches.

Field Ecology: Very common spider generally found below fresh leaves during the day
and sits in an inverted position in the orb web during evenings. Generally, it builds fresh
web in evenings indicates that this species is more active in darkness to hunt on nocturnal
flying insects. The most preferred habitat for the species is grasslands and gardens with
marshy habitats. It is one of the predominant spiders in the homestead areas.

42

Fig. 1. Neoscona theisi (Walckenaer, 1841) a-b, d-f. female. a. dorsal view. b. ventral
view. c. subadult male, ventral view. d. cephalothorax, dorsal view. e. eyes, frontal view.
f. abdomen, ventral view showing epigyne.

Distribution: India: Gujarat, Madhya Pradesh, Maharashtra, Orissa, and West Bengal;
Mediterranean to South-East Asia and Australia (Tikader, 1982; Biswas & Biswas, 1992;
Barrion & Litsinger, 1995; Gajbe, 2004; World Spider Catalogue, 2023).

DNA Barcode studies: The mt DNA barcodes generated in our study were matching
with sequences of Neoscona theisi in the NCBI Blast searches (Appendix 1). To check
the monophyly of our generated N. theisi sequence and those available in the NCBI
database, a preliminary mt COI phylogenetic tree was built which confirmed the
monophyly of N. theisi. On the tree, N. theisi has representation from nine countries other
than ours namely, Australia, China, French Polynesia, Germany, Japan, Oman, Pakistan,
South Korea, and Spain (Fig. 2). Although Gaikwad et al. (2017) have published an

43

article on spiders from the Western Ghats, India, the same is not updated in the NCBI and
as per GenBank they are unpublished. Most of the sequences of N. theisi in the GenBank
are from different regions of Pakistan according to the studies of Ashfaq et al. (2019)
generating a comprehensive DNA barcode library for N. theisi. Overall genetic distance
ranged from 0.6 to 2.5% showing the genetic heterogeneity among the populations of
N. theisi.

Neoscona adianta
88 Neoscona adianta
99 Bees || Neoscona theisi
93 a Neoscona pseudonautica
98 Neoscona nautica
4 Neoscona scylla
Neoscona tianmenensis
7 | Neoscona arabesca
Neoscona multiplicans

89 Neoscona crucifera
100

92 | Neoscona sps.
70 Neoscona pratensis

Neoscona polyspinipes
99 : £4,
Neoscona vigilans

95 ( Neoscona mukerjei

64 99
a 93 Neoscona sps.

- —— Neoscona sps.

100 Neoscona subfusca

—— Neoscona punctigera
Neoscona sps.

Araneus bicentenarius
OUT GROUP .
Araneus bicentenarius

0.04

Fig. 2. Maximum Likelihood (ML) tree for the species of Neoscona based on 650 bp of
mt COI DNA.

Discussion

In India, the species being wide range distributed their DNA barcode studies are
very limited when compared to the DNA barcode studies from Pakistan which is reliable
and comprehensive (Ashfaq et al., 2019). Among the reported diversity of 125 species of
Neoscona represented globally (World Spider Catalogue, 2023) we could include 19
lineages in our analysis occurring as separate clades on the tree. The Indian diversity of
the genus Neoscona is reported to be 29 species of which five are represented on the
phylogenetic tree while for rest of the 24 species DNA barcode data doesn’t exist
suggesting a poor reference library for the genus Neoscona from India. More studies for
Neoscona from India are warranted inclusive of genetic data for building comprehensive
reference library from the country. The authentic DNA barcode library from India will
reinforce thorough documentation of species from diverse geographic ranges cementing
the gap in Wallacean and Darwinian shortfalls of biodiversity documentation. The
present study is expected to have utility not only for species identification in the future
but also in other applied aspects where taxonomy remains fundamental.

44

Table 1. Checklist of species under genus Neoscona Simon, 1864 known from India.

Species name Type locality information

Neoscona achine (Simon, 1906) Deposited at M.N.H.N., Paris, Regd.

No. 21732 B 2551

Neoscona bengalensis Tikader & Bal, 1981

Neoscona bihumpi Patel, 1988 Gadhada, 72 Kms south west of

Bhavnagar, Gujrat, India

Neoscona biswasi Bhandari & Gajbe, 2001 | Vijaynagar, Jabalpur, Madhya

Pradesh, India

Neoscona bomdilaensis B. Biswas & K. Bomdila Circuit House, Dist.

Biswas, 2006 Tawang, Alt. 8.400' ft., Arunachal
Pradesh, India

Neoscona chrysanthusi Tikader & Bal, 1981 | Mangan, near Singhik, Bhutan, India

N

ow
ie

Neoscona dhruvai Patel & Nigam, 1994
Pradesh, India

Neoscona dhumani Patel & Reddy, 1993
Vishakhapatnam, Andhra Pradesh

Neoscona dyali Gajbe, 2004
Pradesh, India

Neoscona elliptica Tikader & Bal, 1981 ee eee |
Neoscona enucleata (Karsch, 1879)
Neoscona molemensis Tikader & Bal, 1981
Neoscona mukerjei Tikader, 1980

Neoscona murthyi Patel & Reddy, 1990 Bhavnagar University Campus, Dist.

Bhavnagar, Gujrat, India

Neoscona nautica (L. Koch, 1875) African coast of the Red Sea near

Suakin

Neoscona odites (Simon, 1906) deposited at M.N.H.N., Paris, Regd.

No. 6499 B 2551

Neoscona parambikulamensis Patel, 2003 Karianshola, Parambikulam Wildlife
Sanctuary, Dist. Palakkad, Kerala,
India

Neoscona pavida (Simon, 1906) deposited at M.N.H.N., Paris, Regd.

No. 11562 B 2551

Neoscona platnicki Gajbe & Gajbe, 2001 Sanjivaninagar, Jabalpur, Madhya
Pradesh, India

OQ | Neoscona punctigera (Doleschall, 1857)
1 | Neoscona raydakensis Saha, Biswas,
Majumder & Raychaudhuri, 1995 Jalpaiguri, West Bengal, India
2 | Neoscona sanghi Gajbe, 2004
Pradesh, India

0
1

3
4

5

6

i)

18

9

i)

3 | Neoscona sanjivani Gajbe, 2004 Sanjivani Nagar, Jabalpur, Madhya

4

Neoscona shillongensis Tikader & Bal, 1981 | Shillong, Meghalaya, India
Neoscona sinhagadensis (Tikader, 1975) Sinhagad Fort, Pune, Maharashtra

Neoscona theisi (Walckenaer, 1841) Guam, Mariana Island, South New
Guinea

45

Pradesh, India

6

Nn

| 27 | Neoscona triangula (Keyserling, 1864) [--- Cid
Neoscona ujavalai Reddy & Patel, 1992 Tadikalapudi, Dist. West Godavari,
Andhra Pradesh, India
29 | Neoscona usbonga Barrion & Litsinger, Hinaplanan, Claveria, Misamis
1995 Oriental Province, Mindanao Island,
Philippines
3

8
0 | Neoscona vigilans (Blackwall, 1865) Shire River Basin- Zambesi, East of
Central Africa

31 | Neoscona xishanensis Yin, Wang, Xie &
Peng, 1990

32 | Neoscona yptinika Barrion & Litsinger, Magsaysay, Siniloan, Luzon Island,
1995 Laguna Province, Philippines

Acknowledgments

The author is grateful to the Director, Zoological Survey of India, Kolkata and the
Officer-in-Charge, Zoological Survey of India, Western Regional Centre, Pune. He is
also grateful to Shazia Quasin for her help in collecting samples and taxonomic studies
and Mehrun Raje for the support in wet lab studies. Special thanks to my colleagues A.
Shabnam and K.P. Dinesh (ZSI, WRC). Thanks are due to two anonymous reviewers
whose comments improved this manuscript.

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Appendix 1. Sequences details of ~650 bp of mt COI gene used for ML phylogenetic
~~

ie
ea 1 | Pakistan: Punjab, Sargodha, Neoscona theisi_ | Ashfaq et al.
Mateela Kotmomin Sargodha, (2019)
Citrus field
MK154964.1 | Pakistan: Punjab, Sargodha, Neoscona theisi_ | Ashfaq et al.
Chak No. 33 S.B. Sargodha, (2019)
Citrus field

3 MK154497.1 | Pakistan: Punjab, NIBGE, Neoscona theisi_ | Ashfaq et al.
Faisalabad (2019)

JN306190.1 Unpublished

5 MK154760.1 | Pakistan: Punjab, JHELUM, | Neoscona theisi | Ashfaq et al.
P.D KHAN (2019)

| 6 | JN306330.1_| Pakistan | Neoscona theisi_| Unpublished _
Bahawalpur, Multan Bypass (2019)

a
ee (2019) _

-9_{ IN306030.1__ /Pakistan
Bahawalpur Lodhara (2019)
Rasheedabad (2019)

JN306039.1 Unpublished

13. | MK154992.1 | Pakistan: Punjab, Neoscona theisi_ | Ashfaq et al.
Chichawatni, Chichawatni (2019)
Forest
PARS (2019)

Bahawalpur, Bakkar Pur (2019)
17 | MK154040.1 | Pakistan: Punjab, Sargodha, Neoscona theisi_ | Ashfaq et al.
a ila Chak No. 90 S.B. Sargodha, (2019)
Citrus field

48

HQ991602.1 Unpublished

MK154897.1 | Pakistan: Punjab, Multan, Neoscona theisi_ | Ashfaq et al.
Ch (2019)

19
| 20 | JF884433.1 | Pakistan | Unpublished

21 | MK154599.1 | Pakistan: Punjab, Neoscona theisi_ | Ashfaq et al.
Bahawalpur, Multan Bypass (2019)

22 | MK154931.1 | Pakistan: Punjab, Neoscona theisi_ | Ashfaq et al.
Chichawatni, Chichawatni (2019)
Forest
bhagtanwala, Citric field (2019)
Bahawalpur, Channan Walla (2019)

25 | MK154526.1 | Pakistan: Punjab, Sargodha, Neoscona theisi_ | Ashfaq et al.

ea Chak No. 90 S.B. Sargodha, (2019)

Citrus field
Rasheedabad (2019)
Saliawalpus Lodhara (2019)
a Garhi (2019)

| 30 | HQ991605.1 /Pakistan Unpublished
JN306149.1 Unpublished

32 | MK154674.1 | Pakistan: Punjab, Lahore, Neoscona theisi_ | Ashfaq et al.
Punjab University, Maize (2019)
Field
Khokhara Basti (2019)
Punjab University, Rice field (2019)
Bahawalpur, Bakkar Pur (2019)
Naag Shah (2019)
P.D KHAN (2019)

38 | MK154656.1 | Pakistan: Punjab, Jhang, Neoscona theisi_ | Ashfaq et al.
Shorkot City, Basti Haider (2019)
Abad, Trifolium Field
P.D KHAN (2019)

JN306120.1 Unpublished
JF884424.1 Unpublished

42 | KT383679.1 | India: Maharashtra, Pune Neoscona theisi_ | Gaikwad et
al. (2017)
KT383768.1 | India: Maharashtra, Pune
al. 2017

49

44 | MK154156.1 | Pakistan: Punjab, Neoscona theisi_ | Ashfaq et al.

Chichawatni, Chichawatni (2019)
Forest
island, mount pohue (2017)

French Polynesia: raiatea Neoscona theisi_ | Ramage et al.
island, pension croix du sud (2017)
faaroa bay gardens
island, Marae taputapuatea (2017)
island, motu maeva (2017)
island, marae taputapuatea (2017)
island, Mount mauru dike (2017)
island, Vaiare paopee track (2017)
ie faie river area (2017) _

Australia

54 MK154469.1 Pakistan: Punjab, Nescone theisi_ | Ashfaq et al.
eee ae Lodharan Road (2019)

| 55 | HQ991597.1 /Pakistan Unpublished

Tober ally (2019)
Faisalabad (2019)
o_o (201 2)

Pakistan
Khokhara Basti. (2019)

a7 Pakistan: Punjab, Jhang, Neoscona theisi_ | Ashfaq et al.
Shorkot City, Basti Haider (2019)
Abad, Trifolium Field
Rasheedabad (2019)

63 | MK154417.1 | Pakistan: Punjab, Sargodha, Neoscona theisi_ | Ashfaq et al.

Chak No. 34 S.B. Sargodha, (2019)
Citrus field
P.D Khan (2019)

ied nadia PN mei
Bahawalpur, Channan Walla (2019)
Sujaabad (2019)

| 68 MK153933.1 | Pakistan: Punjab, Faisalabad, Ashfaq et al.

50

po PARS 09)

eee ee en me
Khokhara Basti (2019)
Bahawalpur, Channan Walla (2019)
Naag Shah (2019)
Bahawalpur, Channan Walla (2019)
Bahawalpur, Multan Bypass (2019)
Bahawalpur, Bakkar Pur (2019)

Sujaabad (2019)
Khewra (2019)

JF884361.1 Unpublished

id ison = —Saetanill amnaad | ol
Suj aabad (2019)

er ee
Saliabad (201 Jie

/Pakistan
Valley, jhalar, vegetation (2019)
Khewra (2019)

MK950521.1 Unpublished
| 86_| MK950520.1 Unpublished
JN306320.1 Unpublished

88 | MK154346.1 | Pakistan: Punjab, Sargodha, Neoscona theisi_ | Ashfaq et al.
Chak No. 33 S.B. Sargodha, (2019)
Citrus field
| 89 | JN306199.1 [Pakistan | Necoscona theisi_| Unpublished _|
bal aie sale nemo! aa
Naag Shah (2019)
Khokhara Basti (2019)
92 | MK154377.1 | Pakistan: Punjab, Sargodha, Neoscona theisi_ | Ashfaq et al.
Mateela Kotmomin Sargodha, (2019)
Citrus field
lilah road (2019)
Khewra (2019)
Sujaabad (2019)

51

Gal end aa
Bahawalpur, Multan Bypass (2019)
Rajana Forest (2019)
Sal abs lel mmc al
Kasba Marral (2019)
rs
dhap shareef, vegetation (2019)
Bahawalpur, Lodhara (2019)
Sujaabad (2019)
Rasheedabad (2019)
Bahawalpur, Channan Walla (2019)
PARS (2019)
Bahawalpur, Bakkar Pur (2019)
Pakistan: Punjab, Sargodha, Neoscona theisi_ | Ashfaq et al.
Chak No. 37 S.B. Sargodha, (2019)
Citrus field
Pakistan: Punjab, Lahore, Neoscona theisi_ | Ashfaq et al.
Punjab University, Maize (2019)
Field
Sujaabad (2019)
Sadiqabad (2019)
Faisalabad (2019)
lilah road (2019)

Bahawalpur, Bakkar Pur (2019)
Bahawalpur, Multan Bypass (2019)
bhagtanwala, Citrus field (2019)
119 | MK153925.1 | Pakistan: Punjab, Sargodha, Neoscona theisi_ | Ashfaq et al.
i Chak No. 87 N.B. Sargodha, (2019)
Citrus field
Tober valley (2019)

mye

bhagtanwala, Citrus field (2019)
Sujaabad (2019)
Bolail Wala (2019)

JN306319.1 Unpublished

125 | MK153996.1 | Pakistan: Punjab, Jhelum, Neoscona theisi_ | Ashfaq et al.
Khewra (2019)

JF884306. 1 Unpublished
JN306297.1 Unpublished
JN306141.1 Unpublished

Pakistan: Punjab, Lahore, Neoscona theisi_ | Ashfaq et al.
Punjab University, Maize (2019)
field
Rajana Forest (2019)

JN306278.1 Unpublished

Sujaabad (2019)
Multan (2019)
Rajanpur (2019)
P.D KHAN (2019)
Naag Shah (2019)
Bahawalpur, Bakkar Pur (2019)
Faisalabad (2019)
139 | MK154386.1 | Pakistan: Punjab, Sargodha, Neoscona theisi_ | Ashfaq et al.

Mateela Kotmomin Sargodha, (2019)
Citrus field

Pune.

Pune.

Sujaabad (2019)
Pun) ab University, Rice field (2019)
jana Forest Forest (2019)

| 146 _ MK559320. 1 ‘India a sti—<isSSCSY Unpublished

147 | MK154465.1 | Pakistan: Punjab, Multan, Neoscona theisi_ | Ashfaq et al.
Sujaabad (2019)

53

JN306334.1 Unpublished

149 | MK154297.1 | Pakistan: Punjab, Jhelum, Neoscona theisi_ | Ashfaq et al.
Tober a | (2019)

| 150. | JN306161.1 Pakistan Unpublished
HQ991607.1 Unpublished
JN306119.1 Unpublished

Sujaabad (2019)
Rajana Forest (2019)
Pakistan: Punjab, Jhang, Neoscona theisi_ | Ashfaq et al.
Shorkot City, Basti Haider (2019)
Abad, Trifolium Field
Bahawalpur, Channan Walla (2019)
Bahawalpur, Lodhara (2019)
Basti Jalalabad (2019)
Pakistan: Punjab, Jhang, Neoscona theisi_ | Ashfaq et al.
Shorkot City, Basti Haider (2019)
Abad, Trifolium Field
Faisalabad (2019)
Sargodha (2019)
Tober valle (2019)
Beggar Garhi (2019)
164 | MK154385.1 | Pakistan: Punjab, Sargodha, Neoscona theisi_ | Ashfaq et al.
Chak No. 34 S.B. Sargodha, (2019)
Citrus field
Bahawalpur, Bakkar Pur (2019)

HQ991599.1 Unpublished
JN306322.1 pPakistan aes

P.D KHAN (2019)

170 | MK153853.1 | Pakistan: Punjab, Neoscona theisi_ | Ashfaq et al.
Chichawatni, Chichawatni (2019)
Forest

JN306228. 1 Unpublished

Khewra (2019)

173. | MK154224.1 | Pakistan: Punjab, Sargodha, Neoscona theisi_ | Ashfaq et al.
Chak No. 37 S.B. Sargodha, (2019)
Citrus field

54

JN306215.1 Unpublished
AB969823.1 | Japan: Okinawa, Onna Unpublished
JN817155.1 Unpublished

(2017)
(2017)

179 | KP100667.1 | Guo Xiang Qiao Zhong Lu, Neoscona theisi_ | Unpublished
ha el Yu Yao Shi, Ning Bo Shi,
Zhe Jing Sheng, China
(2017)
Bahawalpur, Chandi Garh (2019)

182 | KX054026.1 | French Polynesia: moorea Neoscona theisi_ | Ramage et al.
island, Opunohu three (2017)
coconut ridge

183 | MT607826.1 | Spain: Castilla-La Mancha, Neoscona Macias-

i | laa Ciudad Real, Alcoba, La adianta Hernandez et
Quesera al. (2020)
Germany: Saxony, Dresdener | Neoscona Astrin et al.
Heller, Umgebung Dresdener | adianta (2016)
Heller
pseudonautica
pseudonautica

nautica
nautica

Punjab, Sargodha, Chak No. | Neoscona sps. Ashfaq et al.
87 N.B. Sargodha, Citrus (2019)
field
190 | MK155031.1 | Pakistan: Khyber Neoscona scylla_ | Ashfaq et al.
Pakhtunkhwa, Kaghan, (2019)
SARS, Summer Agri Res.St
191 | MK154903.1 | Pakistan: Khyber Neoscona scylla_ | Ashfaq et al.
Pakhtunkhwa, Shogran, (2019)
Shogran
tianmenensis
arabesca
arabesca a et al. (2009)
multiplicans

FI525327.1

55

a
(2009)
crucifera (2020)
198 | KC662168.1 | New York, Cold Spring Neoscona sps. Lu et al.
Harbor, Cold Spring Harbor (2013)
Laboratory Bay
Canada: Ontario, Point Pelee | Neoscona sps. Unpublished
National Park, Woodland
Trail
200 | MF812071.1 | Canada: Ontario, Point Pelee | Neoscona sps. Unpublished
National Park, Woodland
Trail
201 | MF813442.1 | Canada: Ontario, Point Pelee | Neoscona sps. Unpublished
National Park, Woodland
Trail
Canada: Ontario, Point Pelee | Neoscona sps. Unpublished
National Park, Woodland
Trail
203 | KM840069.1 | Canada: Saskatchewan, Neoscona Blagoev et al.
io Grasslands NP, Grasslands pratensis (2016)
Nat. Park Butte trail
204 | KM837328.1 | Canada: Saskatchewan, Neoscona Blagoev et al.
aie Grasslands NP, Grasslands pratensis (2016)
Nat. Park Butte trail
argenteoalba (2019)
punctigera
punctigera
shahpur, Citrus field (2019)
subfusca
subfusca
Khewra polyspinipes (2019)
Khewra polyspinipes (2019)
vigilans
Khewra vigilans (2019)
mukerjei
mukerjei

56

(2015)

KT383727.1 | India: Maharashtra, Pune Unpublished

Kejimkujik, Kejimkuyik bicentenarius al. (2019)
bicentenarius (2020)

57