Translator Disclaimer
1 April 2004 Neotenic formation in laboratory colonies of the termite Coptotermes gestroi after orphaning
Author Affiliations +
Abstract

The termite Coptotermes gestroi (Wasmann 1896) (Rhinotermitidae: Coptotermitinae) is an exotic species in Brazil and information concerning its reproductive developmental biology is scarce. We induced the formation of neotenics in laboratory colonies through orphaning experiments. Orphaning experiments were conducted in three-year old colonies of C. gestroi kept under laboratory conditions. After three months, eight nymphoid neotenics were observed in one colony after queen removal. Histological analysis showed that these neotenics were non-functional. The results suggest that these individuals may have arisen from the first nymphal instar (N1) or from an early N1 instar after one or two larval moults. Neotenics also were recorded on two incipient colonies of C. gestroi that lost the queen naturally.

Introduction

Termites are hemimetabolous insects with colonies constituted of reproductive and immature individuals. The plasticity of the caste system in termite societies is essential for neotenic reproductive formation, mainly in lower termites. Neotenic reproductives are individuals with juvenile characters that may replace the primary reproductives (king and queen) in a colony (Noirot 1969; Roisin 2000). According to Thorne (1996) the term neotenic reproductive refers to any reproductive termite that is not derived from an alate. These individuals can develop from a variety of instars and from individuals with or without wing buds (Thorne 1997).

The subterranean termite C. gestroi is a native species of Asia, but it was accidentally introduced into the southeast region of Brazil from marine cargo, probably at the beginning of the 20th century (Araujo 1958). This species has been misidentified as C. havilandi (Kirton & Brown, 2003) and is responsible for extensive damage in urban areas of São Paulo State (Lelis 1999; Costa-Leonardo et al. 1999). C. gestroi form large field colonies, which produce all-year-round nymphs and non-functional neotenics, even in the presence of the imaginal pair (Costa-Leonardo et al. 1999; Costa-Leonardo 2002; Costa-Leonardo & Arab, 2004). Furthermore, functional neotenics were also found in colonies of this species (Lelis 1999). Functional neotenics are neotenics that have mature gonads and, sometimes, the neotenic females develop physogastry (Lenz & Barrett 1982; Lelis 1999); however, the physogastry of neotenics is less developed than that of the primary queens. On the other hand, the knowledge of the fecundity of functional neotenics is limited. The incidence of neotenics varies greatly among Coptotermes species, being mainly of the nymphoid type (Myles 1999). Thus, in order to understand some aspects of the secondary reproduction in Coptotermes gestroi, we followed the neotenic induction in laboratory colonies after orphaning.

Materials and Methods

Male and female alates of Coptotermes gestroi were collected after dispersal flights in August in the city of Rio Claro, São Paulo State, Brazil (22° 23′ S, 47° 32′ W). Individuals were sexed and each couple was placed in a Petri dish (6 cm diameter) containing sawdust as food source. One hundred couples were used to set up the colonies. After five months, the new-formed incipient colonies were transferred to 250 ml plastic containers filled with decayed sawdust of Pinus sp. and Eucalyptus sp. moistened with distilled water. Sawdust and water were added periodically during the study period. After three years, the colonies were dismantled and the neotenics were collected and subjected to morphometric analysis. We measured the head width and the first wing bud length because these body parts are the most affected by growth at each molt in the imaginal pathway of C. gestroi (Barsotti 2001). The number of antennal segments, body color, fresh weight, body length, posterior tibia length, and the presence of body injuries in these individuals were also recorded. The measurements were performed according to Roonwal (1969). The data were compared to those obtained for nymphal instars mentioned in early studies (Costa-Leonardo et al. 1999; Barsotti 2001) with the purpose of establishing the developmental origin of the neotenics.

Orphaning experiment

Twenty colonies of Coptotermes gestroi were set up from an imago couple collected during the swarming season in Rio Claro city. These colonies were first placed in Petri dishes (6 cm of diameter) and transferred twice to larger containers. Three years later, the queen was removed from ten of these young colonies and the king from the other ten remaining colonies. All the orphaned colonies contained eggs, larvae, workers, soldiers and both primary reproductives at the time of orphaning. To minimize disturbance, the first examination of the orphaned colonies was performed after three months. Afterward, the colonies were examined after 5, 8, and 12 months following the removal of the primary reproductives. Neotenics were subjected to the same morphometric analysis described previously. Mann-Whitney U test (p=0.05) (Sokal & Rohlf 1995) was performed to analyze median differences of head width and wing bud length between neotenics obtained in the laboratory colonies (described above) that lost the queen naturally (control group) and from orphaning experiments.

Histological analysis

Histological analysis was used to determine reproductive functionality of the neotenics individuals. The neotenics obtained from both natural and orphaned colonies were fixed in FAA fluid (formalin: acetic acid: alcohol =1:1:3) and embedded in JB4 resin. The material was sectioned and stained with hematoxylineosin and toluidine blue. The sections were then analyzed and photographed under a Zeiss light microscope. The results were compared to those obtained for primary queens from laboratory colonies.

Results

Nymphoid neotenics were obtained naturally only in two colonies (A and B) of C. gestroi each formed from a single pair of alates and kept under laboratory conditions for three years. These colonies contained workers, soldiers, and the king, however the primary queens were absent. The neotenics collected were all females, showing a thin body, a slightly yellow color, and 14 antennal segments. Ten neotenics were obtained from colony A, with a fresh weight ranging from 3.1 – 4.4 mg, head width ranging from 0.94 – 1.01 mm, wing bud ranging from 0.31 – 0.47 mm in length, and hind tibia ranging from 0.78 – 0.94 mm in length. In colony B we found only one neotenic that showed smaller wing buds (Table 1). All the neotenics found in colonies A and B had slightly yellow pigmentation and lacked compound eyes. Some of these individuals were missing some antennal segments, legs, and had injuries at the genital plates. The other 98 colonies did not produce neotenics and the royal pair was present.

Neotenics were also observed three months after removal of the primary reproductives in young colonies of C. gestroi. The histological analysis showed that the female neotenics were non-functional because the ovaries of these individual showed only primary oocytes (Fig.1A) and the spermatheca were always empty (Fig. 1B). Male neotenics showed slight developed testicles with indistinct lobes (Costa-Leonardo unpublished). Conversely, ovaries of queens of laboratory colonies showed ovarioles containing both primary and terminal oocytes, and spermatheca containing spermatozoa. Non-functional neotenics were recorded in eight queen-orphaned colonies. The number of neotenic females ranged from 1 to 28 and from 2 to 8 for neotenic males (Table 2). Colony 4 was the only one showing non-functional neotenics of both sexes (Table 2). The highest number of these individuals was recorded 8 months after queen orphaning. The number of non-functional neotenics decreased after twelve months of queen removal. All the individuals showed 14 antennal segments and a white or light yellow body color (Table 2). Some of the individuals had injuries on their body. On the other hand, only one non-functional male neotenic was observed in one of the king-orphaned colonies. This individual had a fresh weight of 3.8 mg, a head width of 0.94 mm, a body length of 3.98 mm, a wing bud length of 0.16 mm, and a hind tibia length of 0.70 mm. Other individuals observed at the time of orphaning included the king or queen, larvae, workers, and soldiers. Neotenics were not registered when larvae were not present in the colonies at the time of orphaning (Table 2).

The fresh weight of the neotenics from orphaned colonies ranged from 2.4 to 5.5 mg and the mean wing bud length appeared to be smaller for the individuals of colonies examined after three months of orphaning (Table 3). Nevertheless, some colonies showed neotenics with different wing bud length (Fig. 2). Comparison of head width and wing bud length between neotenics obtained naturally (after queen death) and those from orphaning experiments showed that the median head-width was significantly larger for neotenics obtained naturally (Mann-Whitney U-test, U= 68.00, p< 0.0001); however, there were no differences of wing bud length medians between these individuals (Mann-Whitney U-test, U= 446.00, p= 0.6722). Analysis of the head width and wing bud length obtained from nymphs of field colonies revealed that there were six instars in the nymph developmental pathway of C. gestroi. During nymph differentiation, both the head width and wing bud length increased (Fig. 3). The plot of head width versus wing bud length also showed non-functional neotenics as a cluster of points close to the first nymphal instar (N1), suggesting that these individuals may have originated from N1 or any precursor of this instar (Fig. 3).

Discussion

Colonies of C. gestroi can readily replace primary reproductives with neotenics, which developed from nymphs as deduced from the presence of wing buds. Larvae available at the time of orphaning could possibly develop into nymphs and hence provide a supply of neotenics, as has been reported for Coptotermes acinaciformis (Lenz et al. 1988). Non-functional neotenics obtained in this study presented juvenile morphological characters, such as wing buds and absence of eyes. Conversely, neotenics recorded from field colonies of C. gestroi had compound eyes and 15 to 17 antennal segments (Costa-Leonardo et al. 1999). These individuals were distinguishable from the other castes by a strong yellow pigmentation (Costa-Leonardo et al. 1999), different from the white or light yellow color of the neotenics that appeared after the orphaning manipulations. Neotenics obtained after orphaning in these nymphless, three year old colonies, appeared to have been induced from precursor larvae that first transformed into N1 nymphs and then, through a second molt, into non-functional nymphoid neotenics. Therefore, because of their premature development, they failed to acquire pigmentation and compound eyes and had fewer antennal segments than the neotenics found in field colonies.

All nymphal instars of C. gestroi have compound eyes, which are white in N1 nymphs and become darker during the nymphal development that precede imagoes (5th and 6th nymph instar) (Barsotti 2001). The non-functional neotenics obtained in this study probably originated from N1 or from an early potential precursor nymph. The variation in wing bud length among the neotenics found in the same colony indicates that these individuals may have had different developmental origins. Neotenics can arise after one or two molts from N4-N6 in the Reticulitermes genera (Buchli 1956; Vieau 2001). At the orphaning time, the young laboratory colonies did not contain nymphs, and larvae may have originated an early nymphal instar after one or two molts.

According to Myles (1999), nymphoid and ergatoid neotenics in the Rhinotermitidae may serve either as replacement reproductives, or as supplementary reproductives. Several species of the genus Coptotermes are known by produce neotenic reproductives: C. acinaciformis, C. amani, C. curvignathus, C. formosanus, C. frenchi, C. heimi, C. intermedius, C. lacteus, C. niger, C. sjostedt, and C. vastator (Lenz & Barrett 1982; Lenz et al. 1986; Lenz et al. 1988; Lenz & Runko 1993; Myles 1999) and the rate of neotenic development varies greatly among Coptotermes species (Lenz et al. 1988). All the orphaned colonies with neotenics of C. gestroi contained larvae. Larvae in colonies of lower termites are capable of precocious reproductive development (neoteny) at some point of their life cycle (Grassé & Noirot 1960). In this study, neotenic development varied among replicate groups of orphaned colonies. This difference of neotenic production may be attributed to sex, instar, and age within the instar of the larvae present in the colonies (Greenberg & Stuart 1982) at the moment of orphaning.

The sex ratio of neotenics is closer to 1:1 in lower termites (Myles 1999). In C. gestroi, neotenics of both sexes are produced at the same time, however, neotenic males were less numerous than females. The data suggest that the differential production of females occurred after queen removal. It is possible that there is gender-specific inhibition in combination with a stronger tendency of females to respond quickly to absence of inhibition, which may induce more female larvae to develop into neotenic reproductives. On the other hand, it is possible that neotenics take more time to appear in king orphaned colonies. The decrease in the number of neotenics registered in the orphaned colonies of C. gestroi and the injuries sustained by neotenics indicate that agonistic behavior may act either among neotenics or between neotenics and individuals of other castes. Two alternative hypotheses may explain this; 1) a process of competition among reproductives (Lenz et al. 1986; Myles, 1999), or 2) elimination by workers due to limited available resources in the colony. Cannibalism has been reported in Kalotermitidae (Lenz et al. 1982) and Termopsidae (Lenz et al. 1988). Gender-specific inhibitory mechanisms regulated by semiochemicals of primary reproductives may explain the female biased population of neotenics found in colonies where the queen was removed; however, these compounds have not been yet identified in termites.

Three-year-old, laboratory reared colonies of C. gestroi developed non-functional neotenics from N1 precursor larvae within three months after the colony was orphaned. In view of the rapid development of nymphoids in this species, neotenics may be used to build up termite numbers in situations of food abundance or for propagation in areas of accidental introduction, as has been documented for C. formosanus (Lenz & Barrett 1982). Little information is available on C. gestroi biology and effective management of this species does not yet exist in Brazil. Thus, studies concerning the reproductive biology of C. gestroi may be helpful in developing control measures and to determine the colonizing potential of this species.

Acknowledgments

Financial support was provided by the Conselho Nacional de Pesquisas (CNPq). The authors wish to thank Johana Rincones for reviewing the grammar and syntax of the text and three anonymous reviewers for valuable comments.

References

1.

R. L. Araújo 1958. Contribuição à biogeografia dos térmitas de São Paulo, Brasil. Insecta – Isoptera. Arquivos do Instituto Biológico de São Paulo 25:185–217. Google Scholar

2.

R. C. Barsotti 2001. Desenvolvimento pós-embrionário de Coptotermes gestroi (Isoptera, Rhinotermitidae): Análise biométrica e morfológica. PhD thesis, Instituto de Biociências, Universidade Estadual Paulista, Rio Claro-SP. 140. p. Google Scholar

3.

H. Buchli 1956. Die Neotenie bei Reticulitermes. Insectes Sociaux 3:132–143. Google Scholar

4.

A. M. Costa-Leonardo, R. C. Barsotti, and C. R. R. Camargo-Dietrich . 1999. Review and Update on the Biology of Coptotermes gestroi (Isoptera, Rhinotermitidae). Sociobiology 33:3339–356. Google Scholar

5.

A. M. Costa-Leonardo 2002. Cupins-praga: morfologia, biologia e controle. Rio Claro – SP. 128. p. Google Scholar

6.

A. M. Costa-Leonardo and A. Arab . 2004. Reproductive strategy of Coptotermes gestroi (Isoptera: Rhinotermitidae). Sociobiology 44.1in press. Google Scholar

7.

P. P. Grassé and Ch Noirot . 1960. Rôle respectif des mâles et des femelles dans la formation des sexués néoténiques chez Calotermes flavicollis. Insectes Sociaux 7:109–123. Google Scholar

8.

S. L. W. Greenberg and A. M. Stuart . 1982. Precocious reproductive development (neoteny) by larvae of a primitive termite. Insectes Sociaux 29:535–547. Google Scholar

9.

L. G. Kirton and V. K. Brown . 2003. The taxonomic status of pest species of Coptotermes in Southeast Asia: resolving the paradox in the pest status of the termites, Coptotermes gestroi, C. havilandi and C. travians (Isoptera: Rhinotermitidae). Sociobiology 42:143–63. Google Scholar

10.

A. T. Lelis 1999. Primeiro registro no Brasil de rainha de substituição de Coptotermes gestroi e sua implicação no controle desse cupim. Vetores & Pragas 4:119–23. Google Scholar

11.

M. Lenz and R. A. Barrett . 1982. Neotenic formation in field colonies of Coptotermes lacteus (Froggatt) in Australia, with comments on the roles of neotenics in the genus Coptotermes (Isoptera: Rhinotermitidae). Sociobiology 7:147–59. Google Scholar

12.

M. Lenz, E. A. McMahan, and E. R. Williams . 1982. Neotenic production in Cryptotermes brevis (Walker): influence of geographical origin, group composition, and maintenance conditions (Isoptera: Kalotermitidae). Insectes Sociaux 29:2148–163. Google Scholar

13.

M. Lenz, R. A. Barrett, and L. R. Miller . 1986. The capacity of colonies of Coptotermes acinaciformis acinaciformis from Australia to produce neotenics (Isoptera: Rhinotermitidae). Sociobiology 11:3237–244. Google Scholar

14.

M. Lenz, R. A. Barrett, and L. R. Miller . 1988. Mechanisms of colony re-establishment after orphaning in Coptotermes lacteus (Froggatt) (Isoptera; Rhinotermitidae). Sociobiology 14:1245–268. Google Scholar

15.

M. Lenz and S. Runko . 1993. Long-term impact of orphaning on field colonies of Coptotermes lacteus (Froggatt) (Isoptera: Rhinotermitidae). Insectes Sociaux 40:439–456. Google Scholar

16.

T. G. Myles 1999. Review of secondary reproduction in termites (Insecta: Isoptera) with comments on its role in termite ecology and social evolution. Sociobiology 33:11–91. Google Scholar

17.

Ch Noirot 1969. Formation of castes in the higher termites. In: Krishna K, Weesner FM, editors. Biology of termites, 311–350. New York: Academic Press. Google Scholar

18.

Y. Roisin 2000. Diversity and Evolution of caste patterns. In: Abe T, Bignell DE, Higashi M, editors. Termites: evolution, sociality, symbioses, ecology, 95–120. USA: Kluwer Academic Publishers. Google Scholar

19.

M. L. Roonwal 1969. Measurement of termites (Isoptera) for taxonomic purposes. Journal of the Zoological Society of India 21:19–66. Google Scholar

20.

R. R. Sokal and J. Rohlf . Biometry. Third edition. W.H. Freeman and Company. New York. 1995.  Google Scholar

21.

B. L. Thorne 1996. Termite terminology. Sociobiology 28:3253–263. Google Scholar

22.

B. L. Thorne 1997. Evolution of eusociality in termites. Annual Review of Ecology and Systematics 28:27–54. Google Scholar

23.

F. Vieau 2001. Comparison of the spatial distribution and reproductive cycle of Reticulitermes santonensis Feytaud and Reticulitermes lucifugus grassei Clément (Isoptera, Rhinotermitidae) suggests that they represent introduced and native species, respectively. Insectes Sociaux 48:57–62. Google Scholar

Figure 1.

A. Longitudinal section of the ovary of female neotenic obtained after queen orphaning. Note only primary oocytes (O) in the ovarioles. B. Longitudinal section of the female neotenic abdomen showing the spermatheca (S) with the empty lumen. C. Longitudinal section of a three-years old queen abdomen showing the spermatheca (S) containing spermatozoa (arrow) and a large terminal oocyte (O).

i1536-2442-4-10-1-f01.jpg

Figure 2.

Neotenics from colony 7 opened eight months after queen removal. Observe the different wing bud lengths among the individuals.

i1536-2442-4-10-1-f02.gif

Figure 3.

Wing bud length versus head width of neotenics obtained from orphaning experiments and nymphs from field colonies. Neo: neotenics; N1: 1st nymph instar; N2: 2nd nymph instar; N3: 3rd nymph instar; N4: 4th nymph instar; N5: 5th nymph instar; N6: 6th nymph instar.

i1536-2442-4-10-1-f03.gif

Table 1.

Mean ± SE of the measurements (mm) and fresh weight (mg) of Coptotermes gestroi neotenics found in two laboratory colonies after the queen's death.

i1536-2442-4-10-1-t01.gif

Table 2.

Sex and number of neotinics found in young colonies of Coptotermes gestroi after queen removal

i1536-2442-4-10-1-t02.gif

Table 3.

Range and mean ± SE (in parentheses) of the measurements (mm) and fresh weight (mg) of the neotenics that arising from queen orphaned colonies.

i1536-2442-4-10-1-t03.gif
Ana Maria Costa-Leonardo, Alberto Arab, and Fabiana Elaine Casarin "Neotenic formation in laboratory colonies of the termite Coptotermes gestroi after orphaning," Journal of Insect Science 4(10), 1-6, (1 April 2004). https://doi.org/10.1673/031.004.1001
Received: 16 September 2003; Accepted: 1 March 2004; Published: 1 April 2004
JOURNAL ARTICLE
6 PAGES


SHARE
ARTICLE IMPACT
Back to Top