Revision and cladistic analysis of the Afrotropical endemic genus Smeringopus Simon, 1890 (Araneae: Pholcidae)
Author
HUBER, BERNHARD A.
text
Zootaxa
2012
2012-09-07
3461
1
1
138
http://dx.doi.org/10.11646/zootaxa.3461.1.1
journal article
53629
10.11646/zootaxa.3461.1.1
664d9cee-5b75-4788-a394-6b35a37de652
11755334
6415657
0704C43A-73D8-4A28-915A-7FF8611C8606
Smeringopus
Simon, 1890
Smeringopus
Simon 1890: 94
;
type
species by original designation:
Pholcus elongatus
Vinson, 1863
=
Pholcus pallidus
Blackwall, 1858
.
Simon 1893: 476
.
Kraus 1957: 217
.
Timm 1976: 70–72
.
Diagnosis. Relatively large pholcids (body length usually about
5–8 mm
) with elongate abdomen (
Figs. 2–13
), usually with vivid dark pattern, deep thoracic pit (
Figs. 82
,
414
), male palpal femur usually with deep retrolateral furrow with distinct proximal rim (
Figs. 344
,
411
; absent in
S. mpanga
,
S. ruhiza
, and
chogoria
group), cymbium with macrotrichia (
Figs. 158
,
797
), legs usually with curved hairs on tibiae and metatarsi (absent in
thomensis
group and
cylindrogaster
group), without spines on male femora (present in
S. saruanle
). Distinguished from
Smeringopina
by absence of proximal lateral apophyses on male chelicerae, by barely modified male palpal trochanter, and by low number of modified hairs on male chelicerae (usually one on each side, rarely zero). Distinguished from other
Smeringopinae
genera by male gonopore with only two epiandrous spigots (
Figs. 159
,
347
) and by absence of stridulatory ridges on chelicerae.
Description. Male: Total body length ~3.5–10 (usually ~5–8); carapace width 1.2–3.3 (usually 1.5–2.5). Carapace with deep pit; ocular area weakly raised, eye triads relatively close together (distance PME-PME usually about same as PME diameter), each secondary eye accompanied by more or less distinct elevation (
Figs. 215
,
539
; ‘pseudo-lenses’; cf.
Huber 2009
), AME relatively large, in low position. Clypeus high, never modified, usually with pair of dark stripes (
Figs. 179
,
570
). Chelicerae never with stridulatory ridges, usually with pair of small apophyses near fang-joints, each provided with one modified hair (
Figs. 213
,
417
); representatives of the
rubrotinctus
group with larger apophyses and without modified hairs (
Figs. 87
,
106
). Palpal coxa with or without retrolateral apophysis, trochanter barely modified, femur usually with deep retrolateral furrow with distinct proximal rim (
Figs. 344
,
411
; absent in
S. mpanga
,
S. ruhiza
, and
chogoria
group), cymbium always with macrotrichia (
Figs. 158
,
797
), sometimes with process near palpal tarsal organ (
Figs. 357
,
367
; very long in
S. chogoria
and
S. bujongolo
:
Figs. 131, 132
), palpal, tarsal organ capsulate (
Figs. 395
,
421
), procursus never with hinge, tip usually with spine-like process and membranous structures, bulb with usually rather complex embolus and one or two processes arising from embolus or fused proximally to embolus.
Legs long and thin, leg 1 length ~25–80 (usually ~35–60), tibia 1 ~6–20 (
Fig. 14
; usually ~7–15), tibia 2 usually shorter than tibia 4 (
Fig. 16
), especially in small species (
S. saruanle
,
S. oromia
). Tibia 1 L/d usually ~40–70, higher only in leaf-dwelling species (
cylindrogaster
group: ~80–95). Legs usually without spines on femora (present in
S. saruanle
), with curved hairs on tibiae and metatarsi (absent in
thomensis
group and
cylindrogaster
group), retrolateral trichobothrium very proximal (at 1.5–3.0%), prolateral trichobothrium always present (also on tibiae 1;
Fig. 644
). Tarsal pseudosegments very indistinct, apparently never regular rings but rather irregular platelets (
Figs. 89
,
346
).
Abdomen elongate, posteriorly rather pointed, never elevated above spinnerets, usually with distinct dark pattern dorsally, oblique lines or marks laterally, and distinctive ventral pattern usually consisting of dark epigastric area, two or three black lines in median part and two lines in posterior part (
Figs. 559, 567
). Male gonopore always with two spigots (
Figs. 159
,
347
), each ALS with large widened spigot, pointed spigot, and 5–6 cylindrically shaped spigots (
Figs. 419
,
665
;
S. thomensis
with only two small cylindrically shaped spigots:
Fig. 737
; other species of the
thomensis
group also with reduced number but not studied with SEM).
Female usually very similar to male, no sexual dimorphism in PME-PME distance, chelicerae unmodified, legs usually slightly shorter than in males, only in
S. natalensis
on average longer (
Fig. 15
). Epigynum either a simple plate (
Figs. 168
,
399
) or provided with pair of pockets (
Figs. 666, 672
), very derived in
S. isangi
(with additional pair of pockets on lateral membranous processes;
Fig. 542
). Internal genitalia with frontal valve that is sometimes widened and divided medially (e.g.
Figs. 616
,
790
); pores of pore plates either homogeneously distributed (
Figs. 99
,
114
) or in groups (
Figs. 349
,
397
); rarely with internal pockets in female genitalia (
Figs. 342
,
361
).
Monophyly. In this monograph, I follow a conservative approach, keeping
S. rubrotinctus
and close relatives (the
rubrotinctus
species group) in
Smeringopus
even though preliminary molecular data (Dimitrov, Astrin & Huber, in press) suggest that these taxa (together with the two species comprising the
chogoria
group) may be more closely related with
Smeringopina
than with
Smeringopus
. Following this conservative delimitation of
Smeringopus
, all cladistic analyses above agree on two synapomorphies for the genus: (1) the presence of curved hairs on the legs (char. 20); and (2) the presence of macrotrichia on the male palpal cymbium (char. 24). The analyses using equal and implied character weighting at K=6 identify one or two further synapomorphies, none of them convincing (char. 25: presence of process on cymbium near palpal tarsal organ; char. 35: epigynum with large posterior indentation). A re-delimited
Smeringopus
(as suggested by molecular data, i.e. excluding the
rubrotinctus
group and the
chogoria
group) would also be supported by two morphological characters: (1) male palpal femur with retrolateral furrow (char. 23); and (2) pore plates in female internal genitalia with pores arranged in groups (char. 36). Further analyses (including a more complete sample of
Smeringopina
and DNA sequences of more species) are needed to decide if the
rubrotinctus
and
chogoria
groups belong either to
Smeringopus
or to
Smeringopina
.
FIGURES 14–16.
Scatter diagram and histograms of specific measurements in
Smeringopus
. 14. Representatives of the
cylindrogaster
group have relatively slender legs in relation to their length. 15. Of the 26 species with at least 5 males and 5 females measured, only
S. natalensis
has shorter male than female legs. 16. In most species, tibia 2 is shorter than tibia 4, which is unusual in long-legged pholcids; rather usual values are found in representatives of the
cylindrogaster
group (
c
) and the
thomensis
group (
t
).
Generic relationships. All analyses, under all weighting regimes used, agree on a sister group relationship between
Smeringopus
and
Smeringopina
. Three morphological characters support this relationship: (1) an elongated abdomen (char. 3); (2) the unique (among
Pholcidae
) reduction of epiandrous spigots from 4 to 2 (char. 8); (3) the loss of cheliceral stridulation (char. 9). Preliminary molecular data support this close relationship (Dimitrov, Astrin & Huber, in press), but the details need further investigation (especially regarding the positions of the
rubrotinctus
and
chogoria
groups; see Monophyly above).
The outgroup sample is too small to allow well-founded conclusions about relationships among the other
Smeringopinae
, but it is noteworthy that
Cenemus
(which is endemic to the
Seychelles
) consistently groups with these other genera (which are geographically restricted to northern Africa, the Mediterranean, and the Middle East) rather than with
Smeringopus
and
Smeringopina
(the two sub-Saharan genera).
Cenemus
shares with these northern genera the reduction of ALS spigots from 7–8 to 2, but it also shares a derived character with the two sub-Saharan genera (the elongated abdomen, char. 3).
Specific relationships. Based on the cladistic analyses above and partly also on superficial similarity and geographic closeness,
Smeringopus
is here divided into twelve operational species groups, three of them monospecific. Some of these groups are likely monophyletic (e.g.,
rubrotinctus
group,
chogoria
group,
cylindrogaster
group,
thomensis
group), one may be monophyletic even though the cladograms suggest otherwise (
hypocrita
group), and at least one is very probably not monophyletic (
peregrinus
group). This grouping, even though preliminary and not strictly cladistic, structures the existing diversity and reflects biogeographic patterns. In the descriptive section below, species are ordered according to species groups in the order used here (which in turn is derived from the cladogram in
Fig. 1
).
1.
rubrotinctus
group. This group includes five species (
S. rubrotinctus
,
S. mgahinga
,
S. bwindi
,
S. ruhiza
,
S. mpanga
) with an epigynum with posterior indentation (
Figs. 38–57
; char. 35). In the analyses above, the group is always sister to all other
Smeringopus
, but molecular data (Dimitrov, Astrin & Huber, in press) suggest a closer relationship with the
chogoria
group than with other groups. These two groups also share a rather dark, almost purplish coloration (
Figs. 18–23
,
115–118
) and the geographic distribution (
Fig. 58
).
2.
chogoria
group. This group includes two species that are extremely similar in most respects and share a very long process on the male palpal cymbium (
Figs. 131
,
157
; char. 26).
3.
S. ngangao
. This species appears very isolated morphologically, especially by the absence of curved hairs on legs and by the absence of a distal apophysis on the procursus.
4.
arambourgi
group. Three species (
S. arambourgi
,
S. oromia
,
S. turkana
) of this largely Ethiopian group share a transversal dark band ventrally on the abdomen (
Figs. 170, 172, 174
; char. 6). In two species (
S. lineiventris
,
S. saruanle
) the ventral abdominal pigment is largely or entirely reduced and the transversal band is thus barely visible or absent. Two further species are very likely part of this group but the
types
are lost and no new material is known to me (
S. affinitatus
,
S. zonatus
).
5.
natalensis
group. Most species of this large southern African group (
S. natalensis
,
S. koppies
,
S. badplaas
,
S. florisbad
,
S. lesnei
,
S. harare
,
S. blyde
,
S. hanglip
,
S. lydenberg
) are characterized by three (rather than one or two) processes arising from the genital bulb (
Figs. 302, 307
; char. 32). Two species (
S. mlilwane
,
S. ndumo
) have only two processes arising from the genital bulb but are tentatively assigned to this group because of other specific similarities (e.g., ventrally strongly curved procursus; female genitalia) and geographic closeness.
6.
S. pallidus
. The
type
species of the genus appears very similar to representatives of the
arambourgi
group above but shares with the following groups a distinct retrolateral apophysis on the male palpal coxa (
Figs. 413
,
732
,
802
; char. 21).
7.
S. lesserti
. This species shares with all the following groups the presence of epigynal pockets (
Figs. 423
,
666, 672
; char. 33) but otherwise (bulbal apophyses, procursus tip) it appears very isolated.
8.
hypocrita
group. This group is restricted to southern Africa but in contrast to the
natalensis
group rather to the western than to the eastern side (
Fig. 475
). The cladistic analyses never resolved this group as monophyletic, but apart from their geographic distribution, the species share a procursus tip that is strongly bent towards prolateral (
Figs. 477, 484
; char. 18). The cladistic analyses separate the group into a more southern clade (
S. hypocrita
,
S. sederberg
,
S. dehoop
; probably also
S. lotzi
and
S. ubicki
that were not included in the matrix) and a more northern clade (
S. atomarius
,
S. uisib
,
S. tombua
).
9.
cylindrogaster
group. This group is unique (among
Smeringopus
) in its pale coloration, resulting from its unique biology (high in the vegetation rather than near the ground; see Natural history below). The three species (
S. luki
,
S. isangi
,
S. cylindrogaster
) share a distinctive color pattern (abdomen dorsally monochromous, ventrally with black spots), an elongated cymbium, and a prominent proximal ventral process of the procursus. Two species occur in central Africa; the third is the only
Smeringopus
(other than
S. pallidus
) that also occurs in western Africa.
10.
peregrinus
group. Representatives of this large group share with the two following groups a distinctive structure in the female internal genitalia (part of the valve appears medially widened and divided;
Figs. 616
,
790
; char. 37) but the group itself is probably not monophyletic. It is widely distributed in central and eastern Africa (
S. peregrinus
,
S. peregrinoides
,
S. katanga
,
S. butare
,
S. dundo
) but reaches further south until
Namibia
(
S. similis
),
Zimbabwe
, and
Mozambique
(
S. kalomo
,
S. chibububo
).
S. moxico
is tentatively assigned to this group even though the cladistic analysis suggests otherwise.
11.
thomensis
group. The three species of this group (
S. thomensis
,
S. principe
,
S. mayombe
) share the loss of curved hairs on the legs (char. 20) and the reduction of ALS spigots (char. 7; in
S. thomensis
two tiny cylindrically shaped spigots are still present:
Fig. 737
; in the other two species the spinnerets were studied in the light microscope only and it remains unknown if the spigots are entirely reduced or if two tiny spigots are still present too). They also share a distinctive pattern dorsally on the abdomen (
Figs. 699, 701, 703
; not coded) and the geographic distribution (
São Tomé and Príncipe
Islands and western
Congo
D.R.).
12.
roeweri
group. The four species of this group (
S. roeweri
,
S. lubondai
,
S. carli
,
S. sambesicus
) share rounded light projections proximally on the male chelicerae (
Figs. 771
,
779
; char. 10). The group is widely distributed in central and eastern Africa.
Natural history. Even though
S. pallidus
is a pantropical species, very few studies have been dedicated to exploring its biology in any detail.
Jackson (1992)
and
Jackson
et al.
(1992)
studied whirling behavior as a defense mechanism against predators such as web-invading jumping spiders. It is remarkable that in many places
S. pallidus
seems to have been largely replaced by other synanthropic species such a
Physocyclus globosus
. For example,
Sánchez Roig (1911)
cites
S. pallidus
(under
Pholcus tipuloides
) as “una de las especies más vulgares de
Cuba
”, but this does no longer seem to be the case (A. Pérez G. & B. A. Huber, unpubl. obs.); also,
Mello-Leitão (1918
,
1946
) reports the species (under
S. geniculatus
) to occur in “todo o
Brazil
, no littoral” and to be “muito comum no interior das habitações” in
Rio de Janeiro
, but the species does no longer seem to be common along the Brazilian coast (B.A. Huber, unpubl. obs.).
For most other species, label data and observations by the author in
South Africa
,
Kenya
,
Uganda
,
Cameroon
,
Gabon
, and
Guinea
are the only sources of information. Most species prefer the same
type
of shady, protected habitat that is typical for pholcid spiders: holes and caverns, undersides of overhangs, dark spaces under logs and rocks and between buttresses. Here the spiders build their sheet webs that are more or less domed, with the animal hanging from the apex of the dome. Unlike most other pholcids but like many other
Smeringopinae
, several species of
Smeringopus
seem to be fairly tolerant against aridity. This may explain to some degree the fact that several species have invaded human constructions and it is thus remarkable that only one species has spread all over the world.
Smeringopus
occurs from sea level to over
3700 m
, but only representatives of the
rubrotinctus
species group have been found beyond
2300 m
. Most species of the
rubrotinctus
group appear restricted to high altitudes, and
S. bujongolo
is currently the pholcid spider with the highest known record in Africa (at
3780 m
).
Most exceptional both in its morphology and behavior is
S. cylindrogaster
(its two close relatives share the morphology but their behavior has not been studied).
Smeringopus cylindrogaster
has shifted its microhabitat to the undersides of alive (green) leaves where it rests in an unusual lamp-shade web in an inverted position (
Fig. 13
;
Huber 2009
). The entire spider has changed to a pale whitish coloration with black spots that break the contours. Only the dorsal side of the abdomen (that is pressed against the leaf) is monochromous (cf.
Figs. 530, 534
). Unlike other
Smeringopus
species
that whirl or vibrate their bodies when disturbed,
S. cylindrogaster
remains tightly pressed against the leaf.
The facultative construction of silk balls that are attached to the domed webs appears to be plesiomorphic for
Smeringopus
(see Cladistic analysis, char. 40), but only in a few species have such silk balls actually been observed: in
S. pallidus
(
Japyassú & Macagnan 2004
)
,
S. cylindrogaster
(
Huber 2009
)
,
S. peregrinus
(
Figs. 8
,
623–625
) and
S. ngangao
(
Fig. 7
). Silk balls also occur in other genera of
Smeringopinae
(
Hoplopholcus
,
Holocnemus
;
Wiehle 1933
;
Sedey & Jakob 1998
; J. &. F. Murphy, unpubl. obs.), but they have been studied in more detail in only two species (
Hajer & Řeháková 2003
;
Japyassú & Macagnan 2004
). The conditions under which such structures are incorporated into the web seem to vary among taxa.
Distribution. With the exception of the pantropical
S. pallidus
,
Smeringopus
is largely restricted to central, eastern, and southern Africa (
Fig. 17
). Other than
S. pallidus
, only two species occur outside Africa: (1)
S. natalensis
(originally from southern Africa) has been able to establish stable populations in Western Australia and New South Wales (
Huber 2001
); (2)
S. lineiventris
is only known from
Yemen
. Only two species occur in western Africa (
S. pallidus
and
S. cylindrogaster
), where
Smeringopus
is largely replaced by
Smeringopina
. The two genera have a wide range of overlap in central Africa. The same occurs with
Crossopriza
in the Sahel and in north-eastern Africa. At least four species occur on
Madagascar
(
S. pallidus
,
S. carli
,
S. peregrinus
,
S. kalomo
), but none of them is endemic to the island and it is likely that at least three of them are recent (possibly human) introductions.
FIGURE 17.
Known distribution of
Smeringopus
. Excluded is
Smeringopus pallidus
which has a worldwide distribution and whose distribution in Africa is shown in Fig 386.
Composition. As delimited here,
Smeringopus
now includes 55 described species, 36 of which are newly described below. The collections seen include about 20 further undescribed species that are not treated for various reasons: some are very similar to species treated herein; some are only represented by poorly preserved specimens; most are represented by only one sex. Considering the patchiness of collecting efforts and known distribution patterns in the genus, it appears likely that 50% of the actual species may remain undescribed.