Spiderling emergence in the tarantula Grammostola mollicoma (Ausserer 1875): an experimental approach (Araneae, Theraphosidae).
In mygalomorphs, Coyle & Icenogle (1994) suggested from indirect evidence that spiderlings of the antrodiaetid Aliatypus spp. may need the mother's assistance to emerge, while Marechal (1994) observed that spiderlings of the diplurid Ischnotele guianensis (Walckenaer 1837) are able to hatch by themselves from the cocoon without external help. No other reports about spiderling emergence are available for most mygalomorph families.
Members of the family Theraphosidae are usually large and long-lived and in the last decades they have become popular as pets in many countries. Although several papers report different aspects of their biology (Petrunkevitch 1911, 1934; Baerg 1928, 1958; Gerhardt 1929, 1933; Bucherl 1952; Melchers 1964; Galiano 1969, 1973a & b, 1984, 1992; Stradling 1978, 1994; Minch 1979; Celerier 1981; Kotzman 1990; Costa & Perez Miles 1992, 2002; Perez-Miles & Costa 1992; Marshall & Uetz 1993; Schillington & Verrell 1997; Huber 1998; Janowsky-Bell & Horner 1999; Locht et al. 1999; Punzo & Henderson 1999; Yariez et al. 1999), none describes spiderling emergence in detail. Although we observe mother care of cocoons and spiderlings in several theraphosids, including Grammostola mollicoma (Ausserer 1875), spiderling emergence remains obscure.
Usually the eclosion of the spider from the egg determines the transition from the embryonic to postembryonic life (Foelix 1996). However, the characteristics in which the spiders hatch varies in different species (Holm 1940; Vachon 1957; Peck & Whitcomb 1970; Ramousse & Wurdak 1984), contributing to a confusion in the terms and descriptions of developmental instars in spiders (Foelix 1996). As Galiano has provided a comprehensive study of theraphosid development (1969, 1973a & b, 1984), we followed her terms and concepts. Using her terms, instar A is the 1st intrachorional state and consequently instar B is the first instar out ofthe egg. Although in instar B the spider is completely free of the egg, the body is bent and the legs are extended but do not contact with substratum and are not functional for locomotion. In addition, the eyes and several kinds of setae are absent. These instars as well as instars C and D are completed within the cocoon in Grammostola pulchripes (Simon 1891). More intra-cocoon instars and less development in the early instars was considered as a derived characteristic for Theraphosidae in comparison with other mygalomorphs (Galiano 1969).
In this study we experimentally tested if spiderlings of the theraphosine G. mollicoma are able to emerge from cocoons without the assistance of their mothers. We additionally compared the instars of emergence with predictions from previous postembryonic studies (Galiano 1969, 1973), discussing their possible adaptive value.
We used 46 cocoons of G. mollicoma (northern form) obtained through the Uruguayan mail and confiscated from illegal trade. All were presumably collected at a site near Achar, Tacuarembo, Uruguay [32[degrees]23'60"S, 56[degrees]04'57"W] considering police evidence, habitat description and known distribution of this species. In addition, 800 adults of G. mollicoma were simultaneously confiscated in another mailing by the same person from the same locality.
Cocoons were maintained in plastic containers (83 mm diam. X 105 mm high). Observations took place from 24 January to 7 March 2007. We divided the cocoons into two experimental groups with 23 cocoons in each one. In one of these groups (treatment group) we made a cut 5 mm long with scissors in the cocoon wall on the first day of observation (this cut was approximately of the same size as natural orifices made by spiderlings); in the other group (control), the cocoons remained closed. During the experimental period the room temperature varied between 26.6 [+ or -] 1.4[degrees] c and 24.2 [+ or -] 1.4[degrees] C, and photoperiod was natural (approximately 14 h day:10 h night).
We examined the cocoons daily to monitor the spiderlings'emergence. When the spiderlings emerged, we counted them and determined the postembryonic instars (following Galiano 1969). Instar A is the last intracorional instar and B is the first extracorional instar; we did not observe these instars in our study. Instar C characteristics include: bent body, absence of body pigments, absence of eyes (only maculas), legs not completely functional. Instar D has cephalothorax and abdomen in the same plane, pigments present, eyes present, absence of tarsal scopulae and claw tufts, slow locomotion. Instar E shows body densely hirsute, scopula and claw tufts present and normal locomotion. When more than 50 spiderlings emerged, the remaining progeny was preserved in ethanol and examined, the cocoon was measured (major and minor axis) and its natural openings were counted. At the end of the experiment, the cocoons that remained closed were opened and examined. Voucher spiderlings and opened cocoons were deposited in the arachnology collection of Facultad de Ciencias, Montevideo, Uruguay.
Spiderlings successfully emerged from 22 cocoons in the treatment group and 19 in the control group (non-treatment). No significant differences were found in the frequency of spiderling emergence between groups ([chi square] = 2.02, P = 0.15). The mean number of spiderlings born alive per cocoon in the treatment group was (mean [+ or -] SD) 91.5 [+ or -] 46.8 and in the control 102.0 6 38.4, again with no significant differences between groups (t = 0.78, P = 0.45).
The spiderlings emerged from their cocoons in instars C, D, and E, both in the treatment and control groups. Very few spiderlings emerged in instar C: one and six from each of two cocoons of the treatment group and one from a cocoon of the control group. Curiously, in some cocoons spiderlings emerged simultaneously in two different instars (Table 1). No additional teeth on the chelicerae nor bifurcated cheliceral tips or other structures related to cocoon opening were found in the emerged spiderlings. Table 1 shows how the pattern of instar emergence was distributed among the cocoons. The distribution of mean numbers of spiderlings emerged in instars D and E by cocoon group are shown in Fig. 1. All the spiderlings that emerged in instar D molted to instar E within 24 h after emergence.
Of the four cocoons from which spiderlings did not emerge, we found eggs infected with fungus in two of them, dry eggs in another, and nine spiderlings alive (three of them molting), seven dead, and several unhatched eggs in the last cocoon.
The period from the beginning of the observation to the emergence of spiderlings from the cocoons took 12.9 [+ or -] 8.2 days in the treatment group and 10.1 [+ or -] 5.9 days in the control group, with no significant difference between these periods (t = 1.25, P = 0.23).
Cocoons averaged 43.3 [+ or -] 6.8 mm and 39.6 [+ or -] 7.4 mm (major and minimum axes) in the treatment group and 43.8 [+ or -] 5.8 mm and 41.6 [+ or -] 5.8 mm in the control group, showing no significant differences in cocoon size between the groups (major axis: t = 0.28, P = 0.78; minimum axis: t = 0.96, P = 0.34). The number of natural perforations, if we do not consider the experimental cut, was 0.55 [+ or -] 0.60 in the treatment group and 1.53 [+ or -] 0.61 in the control group. Significant differences were found between groups (t = 5.19; P < 0.0001).
Our results clearly showed that spiderlings of G. mollicoma are able to emerge from the cocoon without the assistance of their mother as was reported by Marechal (1994) for the diplurid I. guianensis. Coyle & Icenogle (1994) did not observe direct evidence for the mother's assistance in the antrodiaetid Aliatypus spp. Their indirect observations provided weak support for the hypothesis that the mother's help is required. The small number of natural perforations found in the cocoons of the treatment group suggests that spiderlings could utilize pre-existent holes.
[FIGURE 1 OMITTED]
Copulation during egg sac care was reported recently for this species (Postiglioni 2007). The ability of spiderlings to emerge without assistance might be an important trait that permits the mother to be receptive and exposed to the risks (i.e., predation) of courtship and copulation without jeopardizing the success of her spiderlings.
The mean number of spiderlings per cocoon (or clutch) for G. mollicoma was moderately low in comparison with most Theraphosidae (Table 2). This characteristic could be interpreted as plesiomorphic if compared with the sister family Barychelidae with 20-80 eggs (Raven 1994). Other theraphosids as Aphonopelma joshua Prentice 1997, Plesiopelma longisternale (Schiapelli & Gerschman 1942), Theraphosa blondi (Latreille 1804) and some avicularines share with G. mollicoma a low clutch size.
Galiano (1969) observed a bifurcated tip on the cheliceral fang in instars B and C of G. pulchripes (in synonymy with G. mollicoma by Perez-Miles et al. 1996), which we found to be absent in instar C of G. mollicoma. Galiano also indicated the presence of maxillary cuspules and the scarcity of hairs on tarsi and tibiae in instar C of G. pulchripes but we found no such cuspules and several tibial and tarsal hairs, which causes us to question the synonymy of these species. The absence of special structures in spiderlings related to cocoon opening suggests that they open the cocoon with the chelicerae. The experimental perforation seemed not to affect the normal development of the cocoons nor the number of spiderlings born alive, considering the absence of significant differences between the groups. Instar C seems to be a pre-emergence instar because few individuals emerged in this instar, and only in the treatment group. The absence of eyes and pigments and the bent body, which impedes locomotion (Galiano 1969), also agree with a pre-emergence instar.
Galiano (1969) incubated isolated eggs of G. pulchripes outside the cocoon, and based on morphological evidence during development, proposed that spiderlings emerge in instar E. Our results partially agree with this author because we found that half of G. mollicoma spiderlings emerged in instars D, molting to E outside the cocoon within about 24 h. The emergence in two different instars also indicates a slight asynchrony of molting between instars D and E. However, instar E seems to be the first in which the spiderlings are independent enough and ready for their free life (Galiano 1969). Instar E is the first instar where urticating hairs develop (Perez-Miles 2002) and the spiderlings are able to feed by themselves (occasional observations). It is not clear what the advantages are for the spiders to emerge in the precocious instar D. Probably in this instar spiderlings are not able to open the cocoon by themselves and instead use the openings made by spiderlings in instar E to emerge. Prentice (1997) reported that spiderlings of Aphonopelma joshua Prentice 1997 emerge in the fourth or fifth instar probably homologous with D and E, which is similar to our findings in G. mollicoma.
Galiano (1969), following Holm (1956), indicated that a low quantity of yolk and an increased degree of organization in early extracorional instars imply a few number of instars intracocoon and a plesimorphic condition, as in Telechoris striatipes (Simon 1889) [(ex Ischnothele karschi (Bosenberg & Lenz 1895)]. Galiano (1969) has stressed the importance of having four instars intra-cocoon in G. mollicoma and consequently considered this characteristic as derived in comparison with most mygalomorphs and other Araneae. For example the Mesothelae Heptathela kimurai (Kishida 1920) and other mygalomorphs such us Atypus karschi Donitz 1887 and Telechoris striatipes, have only two or three states intra-cocoon (Yoshikura 1952, 1958 and Holm 1956; cited by Galiano 1969). In H. kimurai and T. striatipes, spiderlings have two instars inside the cocoon while A. karschi has three. Stradling (1994) reported only one intra-cocoon postembryonic instar in Avicularia avicularia (Linnaeus 1758), which seems to be a record in Theraphosidae. Our findings in G. mollicoma with three instars intra-cocoon question the indirect evidence of Galiano (1969) and consequently the evolutionary interpretation of Galiano.
We thank Anita Aisenberg, Fernando G. Costa and Carmen Viera for their valuable comments on an early draft of this paper; and two anonymous reviewers for their suggestions.
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Manuscript received 13 December 2007, revised 24 July 2008.
Alejandra Panzera, Cintya Perdomo and Fernando Perez-Miles: Seccion Entomologia, Facultad de Ciencias, Igua 4225, 11400 Montevideo, Uruguay. E-mail: email@example.com
Table 1.--Number of cocoons and distribution of instars in which spiderlings emerged in treatment and control groups. See methods for explanation of abbreviations for different instars (C-E). Instars of emerged C C + D D E D + E Not spiderlings registered No. of Cocoons 2 0 6 2 8 4 Treatment group No. of Cocoons 0 1 3 1 12 3 Control group Table 2.--Reports of number of spiderlings * or eggs per cocoon and cocoon size in Theraphosidae taken from the literature. Species Number of Cocoon Size spiderlings (major axis) * or eggs Avicularia avicularia 103-145 * -- Avicularia metallica 178-182 -- Avicularia versicolor 12-221 -- Pachistopelma rufonigrum 30, 30 * -- Acanthoscurria gigantea 600 -- Aphonopelma chalcodes 454-555 -- Aphonopelma hentzi 206-911 -- Aphonopelma joshua 51 * 12 mm Ceropelma longisternale 16-111 -- Dugesiella crinita 800-1000 -- Dugesiella hentzi 500-1000 -- Euathlus smithii > 700 -- Eurypelma californica 621-1018 -- Grammostola burzaquensis 100-120 30 mm Grammostola mollicoma 43.5 mm Phamphobetus roseus 1200 -- Theraphosa blondi 36, 44 * 60 mm Theraphosa blondi 78 [+ or -] 5.57 -- Species Author Avicularia avicularia Stradling 1994 Avicularia metallica Charpentier 1992 Avicularia versicolor Charpentier 1992 Pachistopelma rufonigrum Dias & Brescovit 2003 Acanthoscurria gigantea Ibarra Grasso 1961 Aphonopelma chalcodes Minch, 1978 Aphonopelma hentzi Punzo, 1999 Aphonopelma joshua Prentice 1997 Ceropelma longisternale Costa et al. 1992 Dugesiella crinita Baerg 1958 Dugesiella hentzi Baerg 1958 Euathlus smithii Clarke 1991 Eurypelma californica Baerg 1938 Grammostola burzaquensis Ibarra Grasso 1961 Grammostola mollicoma this study Phamphobetus roseus Ibarra Grasso 1961 Theraphosa blondi Lambert & Dupre 1992 Theraphosa blondi Marshall & Uetz 1993
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|Author:||Panzera, Alejandra; Perdomo, Cintya; Perez-Miles, Fernando|
|Publication:||The Journal of Arachnology|
|Date:||Jan 1, 2009|
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