Phylogeny of the families Pyuridae and Styelidae (Stolidobranchiata, Ascidiacea) inferred from mitochondrial and nuclear DNA sequences

The Order Stolidobranchiata comprises the families Pyuridae, Styelidae and Molgulidae. Early molecular data was consistent with monophyly of the Stolidobranchiata and also the Molgulidae. Internal phylogeny and relationships between Styelidae and Pyuridae were inconclusive however. In order to clarify these points we used mitochondrial and nuclear sequences from 31 species of Styelidae and 25 of Pyuridae. Phylogenetic trees recovered the Pyuridae as a monophyletic clade, and their genera appeared as monophyletic with the exception of Pyura. The Styelidae, on the other hand, appeared as a paraphyletic group split into several clades. One of them was formed by solitary oviparous species, of which the Pyuridae were a sister group. A second clade included the colonial genera Botryllus, Botrylloides and Symplegma. The remaining colonial and solitary genera formed several poorly resolved clades. One of the more species genus, Polycarpa, was shown to be polyphyletic, and the species Styela plicata grouped into two genetically distant clades suggesting the existence of two cryptic species. The internal phylogeny of Styelidae has bearings on the origin of coloniality in this family. We suggest to abandon the traditional division of colonial forms into social and compound species and use instead the categories of aggregated colonies that do not have common vascular systems, and integrated colonies, that do possess such systems. Our molecular results indicate that there have been several independent acquisitions of coloniality in the Styelidae, and that viviparity may be a pre-adaptation for a colonial life-style.     

Coloniality has evolved once in Stolidobranch Ascidians

Ascidians exhibit a rich array of body plans and life history strategies. Colonial species typically consist of zooids embedded in a common test and brood large, fully developed larvae, while solitary species live singly and usually free-spawn eggs that develop into small, undifferentiated larvae. Ascidians in the order Stolidobranchia include both colonial and solitary species, as well as several species with intermediate morphologies. These include social species, which are colonial but do not live completely embedded in a common test, and a few solitary species that brood embryos and larvae until they are competent to metamorphose. We examined how many times coloniality has evolved within the Stolidobranchia, with phylogenetic analyses using full-length 18S rDNA and partial cytochrome oxidase B sequences for taxa in the families Molgulidae, Styelidae, and Pyuridae. Tunicata orders Phlebobranchia and Stolidobranchia are sister groups, and the family Molgulidae is a monophyletic group and should be raised to the subordinal level, as shown previously by analyses from this lab with partial 18S sequences. In contrast to previous studies, styelids and pyurids are separated into monophyletic groups by ML and Bayesian analyses. We show a single clade within the family Styelidae that contains two colonial (compound) botryllid species, a Symplegma (colonial compound), a colonial (social) species Metandrocarpa taylori, as well as four solitary species, thus confirming that the botryllids are a subfamily of the Styelidae. These results suggest that the ancestor of the Stolidobranchia was solitary and that coloniality has evolved only once within this clade of ascidians. Further phylogenetic analyses of aplousobranch and phlebobranch ascidians will be necessary to understand the number of times that coloniality has evolved within the class Ascidiacea.     

Antibodies with the cell-type specificity to the morula cells of the solitary ascidians Styela rustica and Boltenia echinata

The separation of the blood cells of Styela rustica (Styelidae, Stolidobranchiae) in discontinuous Percoll gradient showed 4 fractions. The 4th and bottom most fraction contained 90-100% of morula cells. The protein composition of the morula cell fraction revealed on SDS-PAGE showed two major proteins with m.w. 47 and 26 kDa. These proteins were heavily positively charged. Polyclonal antiserums against these proteins were raised. Each antiserum reacted with both proteins only in morula cells on the blot after SDS-PAGE and stained the proper protein without crossreaction on the blot after AU-PAGE. The only type of cells stained with antibodies in circulating blood, in the tunic and on the tunic wound surface in paraffin sections of another species Boltenia echinata (Pyuridae, Stolidobranchiae) were morula cells. The morula-type specific antibodies obtained recognized major positively charged proteins which were apparently structural substrates for the phenoloxidase tanning.     

Ascidian tunic cells: morphology and functional diversity of free cells outside the epidermis

Abstract. Tunic cells are free cells distributed in the tunic, the integumentary matrix of tunicates. In ascidians, various types of tunic cells have been described both in solitary and in colonial species. Many of them are functionally specialized and are related to the protection of the animal, such as phagocytosis to prevent infection, acid storage to avoid predation, and pigmentation to protect against solar radiation. While some tunic cells are known to play a role in colonial allorecognition, bioluminescence, and algal symbiosis, the functional roles of many cell types still remain to be determined. The composition of tunic-cell types varies among ascidian species, most likely reflecting the functional requirements of the tunic in each species. Although some cell types, e.g., tunic net cells and tunic bladder cells, are restricted to particular taxa of ascidians, tunic phagocytes are found in all known ascidians. Therefore, tunic phagocytes are hypothesized to be basal and shared with ancestral tunicates. In some ascidians, phagocytic cells are involved in other functions, such as pigmentation, intracellular photosymbiosis, and bioluminescence. These specialized phagocytic cells are hypothesized to be derived from tunic phagocytes, suggesting that tunic cells have a high potential to diversify and evolve a wide variety of cellular functions.     

Global diversity of Ascidiacea

The class Ascidiacea presents fundamental opportunities for research in the fields of development, evolution, ecology, natural products and more. This review provides a comprehensive overview of the current knowledge regarding the global biodiversity of the class Ascidiacea, focusing in their taxonomy, main regions of biodiversity, and distribution patterns. Based on analysis of the literature and the species registered in the online World Register of Marine Species, we assembled a list of 2815 described species. The highest number of species and families is found in the order Aplousobranchia. Didemnidae and Styelidae families have the highest number of species with more than 500 within each group. Sixty percent of described species are colonial. Species richness is highest in tropical regions, where colonial species predominate. In higher latitudes solitary species gradually contribute more to the total species richness. We emphasize the strong association between species richness and sampling efforts, and discuss the risks of invasive species. Our inventory is certainly incomplete as the ascidian fauna in many areas around the world is relatively poorly known, and many new species continue to be discovered and described each year.     

An evaluation of chemical and physical defenses against fish predation in a suite of seagrass-associated ascidians

The palatability of two solitary and three colonial species of ascidians commonly found in sub-tropical seagrass meadows was evaluated using the abundant, sympatric, omnivorous pinfish Lagodon rhomboides as a model predator. Bite-sized pieces of fresh tissues of both solitary and one of the three colonial ascidian species were unpalatable to fish. Lipophilic and hydrophilic extracts of the three unpalatable species did not cause feeding deterrence indicating that secondary metabolites are not responsible for the lack of palatability. Distaplia bermudensis, the one colonial ascidian that was unpalatable to fish, had a highly acidified outer tunic (pH = 1.5). We tested the ability of acidified agar food pellets (pH = 1.5) to deter pinfish and found that the fish readily ingested acidified pellets. The toughness of the tunic of all five ascidian species was evaluated by measuring the Force (N) required to penetrate the tunic using a penetrometer. Tunic toughness is likely to explain the lack of palatability of the solitary ascidians Styela plicata and Molgula occidentalis as their tunics required a force of > 34 N to penetrate. Tunic toughness may be a particularly effective adaptation for ascidian defense in seagrass habitats where fish with strong crushing jaws, such as those that commonly occur in coral reef systems, are rare.     

Resource allocation in ascidians: reproductive investment vs. other life-history traits

Abstract. To determine patterns of resource allocation among ascidians, we studied 16 colonial and solitary species. We measured investment in reproductive vs. structural material (tunic) both in terms of weight and caloric content, as well as fecundity and degree of larval complexity in the colonial species. Measurements in weight and caloric content were highly correlated in the species studied. A wide range of investment in reproduction was found. Tunic production was related to the growth form of the species, stolonic and solitary species investing less in tunic than massive species, but no significant relationship was found between investment in tunic production vs. reproduction. In colonial species we found that in species with small zooid size, the reproductive investment per zooid was significantly higher. There was a significant negative relationship between investment in reproduction and fecundity. We also found a significant relationship between reproductive investment and larval complexity. The overall trend was that species with low fecundity had large complex larvae and invested the most energy in reproduction.     

Larval Tunic and the Function of the Test Cells in Ascidians

Abstract In normal ascidian development, cuticular fins begin to form at the late tailbud stage and are fully formed at hatching. When one or several neurulae were manually demembranated (follicle cells, vitelline coat and test cells removed) and cultured in seawater they failed to form caudal fins. Fins were normal when the follicle cells alone were removed. The shape of the fins was normal when demembranation was delayed to the late tailbud stage. Does demembranation cause the loss of an essential factor produced by the embryos themselves or do the test cells provide a factor for fin morphogenesis? Demembranated neurulae of Ascidia callosa were cultured in groups ranging in size from 2 to 80 in 1 ml volumes of seawater. The mean lengths of the caudal fins increased with group size. In larger groups, some embryos developed fins that were normal in shape and as long as undemembranated controls. Results were similar with Corella inflata. These experiments suggest that a diffusible substance from the embryos facilitates fin morphogenesis and that test cells are not required. Test cells deposit ‘ornaments’ on the tunic in some species. In other species no ornaments are produced. Ten families are compared. It is proposed that the test cells make the tunic hydrophilic.     

The acrosome in ascidians. I. Pleurogona

Summary

A vesicle which contains moderately electron-dense material has been found at the apex of mature spermatozoa in all representatives of three pleurogonan families: in Styela clava, Cnemidocarpa finmarkiensis and Botryllus schlosseri (family Styelidae), in Boltenia villosa and Herdmania momus (family Pyuridae), and in Molgula manhattensis (family Molgulidae). The vesicle described here resembles the acrosome of Ciona intestinalis spermatozoa. The Ciona acrosome shows structural changes at fertilization (Fukumoto, M., J. Ultrastruct. Res., 87 (1984) 252–262). This suggests that pleurogonan spermatozoa also have an acrosome. Some speculations are presented on ascidian fertilization.     

Convergent evolution of the vertical transmission mode of the cyanobacterial obligate symbiont Prochloron distributed in the tunic of colonial ascidians

In chordates, obligate photosynthetic symbiosis has been reported exclusively in some colonial ascidians of the family Didemnidae. The vertical transmission of the symbionts is crucial in establishing the obligate symbiosis between the cyanobacteria and the host ascidians. The results of comparative surveys on the morphological processes of cyanobacterial transmission suggest the occurrence of convergent evolution of the vertical transmission in the host species harboring symbionts in the cloacal cavity. In Trididemnum species harboring cyanobacterial cells in the tunic, the symbiont cells are transported by the tunic cells to the tunic of embryos brooded in the tunic of the parent colony. The present study examined whether the mode of symbiont transmission is the same in host species harboring the symbionts in the tunic, regardless of host genera, or whether non-Trididemnum hosts have a different vertical transmission mode. Our results showed that the vertical transmission process in Lissoclinum midui was almost the same as in the Trididemnum species, supporting the occurrence of convergent evolution in the two distinct didemnid genera, that is, Trididemnum and Lissoclinum. High plasticity of the embryogenic process in didemnid ascidians may be important in developing the mechanism of vertical transmission; this assumption may also explain why the obligate cyanobacterial symbiosis has been exclusively established in didemnid ascidians among chordates.     

A comparative study of the non-acidic chemically mediated antifoulant properties of three sympatric species of ascidians associated with seagrass habitats

The present study investigated aspects of the antifoulant properties of three sympatric species of ascidians found in seagrass habitats of the Gulf of Mexico, Southern Atlantic Ocean, and Caribbean. Field observations in Saint Joseph Bay, Florida indicate that all three species are common and that the tunic of the solitary ascidian Molgula occidentalis is often heavily fouled, while the outer surfaces of both the colonial ascidians Amaroucium stellatum and Botryllus planus are free of fouling organisms. Antifoulant activities of a suite of increasing hydrophilic organic extracts prepared from the tunic of M. occidentalis and whole colonies of A. stellatum and B. planus were measured using both sympatric microbial (bacteria) and macroinvertebrate (cyprid larvae of Balanus amphitrite) fouling organisms in laboratory bioassays. In addition, field antifoulant assays were conducted by combining organic extracts with controlled-release resin and subsequently coating this material on to acrylic rods deployed in the field for a 72 h period. Extracts of the tunic of M. occidentalis generally did not inhibit bacterial growth. The exception was the methanol extract, which inhibited growth in one of the six marine bacteria tested. Moreover, only the highest concentrations of hexane and methanol tunic extracts tested prevented attachment of cyprid larvae. Field assays revealed no antifoulant activity on rods coated with resin containing extracts of M. occidentalis. Inhibition of both microbial growth and cyprid settlement were much more pronounced in whole-organism extracts of the two colonial ascidians. Most potent were the aqueous methanol extracts of colonies of B. planus and A. stellatum which inhibited growth in five of the six marine bacteria tested. In addition, hydrophilic and lipophilic extracts of the colonial ascidians significantly inhibited attachment of cyprid larvae, in many instances across a wide range of extract concentrations. Field antifoulant assays indicated that extracts of both colonial ascidians inhibited settlement of bryozoans and barnacles. The findings indicate that the colonial ascidians B. planus and A. stellatum possess chemical antifoulant properties. In contrast, the solitary ascidian M. occidentalis appears to either tolerate fouling or possess other non-chemical mechanisms to cope with the risks associated with epibiont overgrowth.     

Nervous system of ascidian larvae: Caudal primary sensory neurons

Summary In larvae of Diplosoma macdonaldi one sensory nerve extends along the dorsal midline of the tail and another extends along the ventral midline. Each nerve is composed of 50–70 naked axons lying in a groove in the base of the epidermis, and each projects to the visceral ganglion. The cell bodies of the caudal sensory neurons occur in pairs within the epidermis, and are situated along the courses of the nerves. A single cilium arises from an invagination in the soma of each neuron, passes through the inner cuticular layer of the tunic and enters a tail fin formed by the outer cuticular layer. We propose that these cells are mechanoreceptors. The caudal sensory system is similar in representative species of ten families of ascidians.Abbreviations a axial complex of the tail - ac accessory centriole - ax axon - bb basal body - bl basal lamina - c cilium - cep common epidermal cells - cs ciliary sheath - dcv dense-cored vesicles - dsn dorsal sensory nerve - ec ependymal cells - ep epidermis - gj gap junction - h hemocoel - hc hemocoelic chamber - icl inner cuticular layer of the tunic - m caudal muscle - nc dorsal nerve cord - ncl neurocoel - no notochord - ocl outer cuticular layer of the tunic - sc sensory cell - sn sensory nerve - sv sensory vesicle - vg visceral ganglion - vsn ventral sensory nerve     

Tunic abnormalities of the urochordate Halocynthia pyriformis

This paper reports lesions of the tunicate Halocynthia pyriformis, which either grossly resembled supernumerary siphons or appeared as elongate protrusions on the surface of the tunic. The lesions were present on freshly collected animals; they did not develop during maintenance in the laboratory. The siphon-like structures were doughnut-shaped thickenings of noncellular tunic material around a vertical core of necrotic debris; the elongate protrusions were also tubular thickenings of tunic material surrounding a necrotic core. Both types of lesions were extensively infiltrated with blood cells and possibly exfoliated epidermal cells proximal to the necrotic cores, suggestive of an inflammatory response. Bacteria were seen within the debris of the elongate protrusions. These lesions were interpreted as injury and repair responses of the tunic rather than developmental anomalies or neoplasia. Their etiology could not be precisely determined. The bacteria associated with the intracystic debris of the elongate lesions could have been causative or only secondary invaders. Possibly the postulated injury resulted from a chance abrasion, puncture, contact with toxic material, or from a parasite. An intimate association of numerous hydrozoids around the base of the animal and a few on the upper portion of the tunic suggested a plausible explanation of at least some of these lesions. Occasionally, one observed the hydrorhiza of a hydrozoan embedded in the tunic itself; living hydranths were seen extending from these structures. The tunic was thickened in the region of the hydrorhiza, and histological examination of these thickenings showed details quite similar to those reported above. There was a core of necrotic debris and considerable cellular infiltration of the tunic. Probably these lesions represent the result of a primitive cellular immune response of the tunicate against the hydrozoans, or against secondary bacterial infections associated with the presence of the hydrozoans in the tunic.     

Microbial community associated with the colonial ascidian Cystodytes dellechiajei

The ascidian Cystodytes dellechiajei (Della Valle, 1877) (phylum Chordata, class Ascidiacea, family Polycitoridae) is a colonial tunicate that inhabits benthic rock environments in the Atlantic, Pacific and Indian Oceans, as well as the Mediterranean Sea. Its life cycle has two phases, the adult sessile colony and the free-living larva. Both adult zooids and larvae are surrounded by a protective tunic that contains several eukaryotic cell lines, is composed mainly of acidic mucopolysacharides associated with collagen and elastin-like proteins, and is covered by a thin cuticle. The microbiota associated with the tunic tissues of adult colonies and larva of C. dellechiajei has been examined by optical, confocal and electron microscopy and by fluorescence in situ hybridization (FISH), denaturing gradient gel electrophoresis (DGGE), and 16S rRNA gene clone library analysis. Microscopy analyses indicated the presence inside the tunic, both for the adult and the larva, of a dense community of Bacteria while only the external surface of colony cuticle was colonized by diatoms, rodophyte algae and prokaryotic-like epiphytes. Transmission electron microscopy showed tunic eukaryotic cells that were engulfing and lysing bacteria. 16S rRNA gene analyses (DGGE and clone libraries) and FISH indicated that the community inside the tunic tissues of the adults and larvae was dominated by Alphaproteobacteria. Bacteria belonging to the phyla Gammaproteobacteria and Bacteroidetes were also detected in the adults. Many of the 16S rRNA gene sequences in the tunic tissues were related to known aerobic anoxygenic phototrophs (AAP), like Roseobacter sp. and Erythrobacter sp. In order to check whether the gene pufM, coding for the M subunit of the reaction centre complex of aerobic anoxygenic photosynthesis, was being expressed inside the ascidian tissues, two libraries, one for an adult colony and one for larva, of cDNA from the expressed pufM gene were also constructed. The sequences most frequently (64% for colony and 67% for larva) retrieved from these libraries presented > 90% aa identity with the pufM gene product of the Roseobacter-like group, a cluster of AAP widely detected in marine planktonic environments.     

Scanning Electron Microscopy of Developmental Stages of Malpighamoeba mellificae Prell in the Honey Bee

Primary trophozoites of Malpighamoeba mellificae Prell in the process of penetrating the cell membrane were found among the brush border of epithelial cells of the midgut of Apis mellifera L. They were long and slender with an average diameter of 3.68 μm. Their surfaces had some wrinkles and the cytoplasm contained some vesicles. Secondary trophozoites were found in the lumen of Malpighian tubules. Their size was variable and their shapes were highly irregular; some had pseudopodia. The smooth surface of trophozoites possessed numerous small protrusions and pits. Mature cysts were small and oval-shaped; they measured from 2.65 times 3.62-3.4 times 4.6 μm. Their surface was usually smooth but some had wrinkles.     

Tunic phagocytes are involved in allorejection reaction in the colonial tunicate Aplidium yamazii (Polyclinidae, Ascidiacea)

The colonial ascidian Aplidium yamazii exhibited an allorejection reaction when two allogeneic colonies were brought into contact at their growing edges or at artificial cut surfaces. This species has no vascular network in the tunic, unlike the botryllid ascidians, which have a vascular network throughout the colony's common tunic. In the allorejection reaction induced by contact at the growing edges, some small, hard-packed tunic masses were formed at the contact points. Histological and electron microscopic investigation of these tunic masses revealed that they contained aggregates of tunic cells, with tunic phagocytes being the major cell type present. Some of the tunic phagocytes in these tunic masses appeared to be disintegrating. When allogeneic colonies were placed in contact at their artificial cut surfaces, the colonies partially fused, then separated. In this allorejection reaction, some loosely packed tunic masses remained in the gap between the two withdrawn colonies. These results strongly suggest that the tunic phagocytes are likely to be the major effector cells in the allorejection reaction. We also propose that the tunic phagocytes are not only the effector cells in the allorejection reaction but also bear the sites of allorecognition.     

Positive and negative effects of a dominant competitor on the settlement, growth, and survival of competing species in an epibenthic community

Because dominant competitors can monopolize resources, any positive effects they have on other species can have large community impacts. The solitary tunicate Ascidia ceratodes is a dominant competitor in the fouling community in Bodega Harbor, CA. This tunicate preempts primary substratum from competitors, but its thick tunic also allows other species to grow on its surface. The net effect of Ascidia on the community as a whole therefore depends on the balance between competitive and facilitative effects. In this study we evaluate the facilitative effects of Ascidia on different life stages of common competing species. We quantified larval settlement onto Ascidia compared to unoccupied space; we quantified the growth rate on Ascidia of small colonies of two common species; and we measured whether established colonies could escape overgrowth by Ascidia by growing onto its tunic. We found evidence for high rates of settlement on Ascidia, with some species showing higher and others lower settlement relative to that observed on free space. The growth rate of settlers was generally lower on Ascidia compared to primary substratum. We also found that colonial species established on primary space commonly escape overgrowth from Ascidia by growing onto Ascidia, as this occurs in about half of all encounters. This study indicates that the total effect of Ascidia on the community will depend on species-specific and life stage-specific effects, with likely long-term consequences for the diversity and composition of the community.     

Diversity of intratunical bacteria in the tunic matrix of the colonial ascidian Diplosoma migrans

This paper provides the first information on diversity based on sequence data of the 16S rDNA of intratunical bacteria in the colonial ascidian Diplosoma migrans and its embryonic offspring. Ascidians were collected from waters near Helgoland (German Bight, North Sea). Sample material comprised tunic tissue, bacteria collected from tunic tissue, eggs with single embryos at different developmental stages, and free-swimming larvae. Bacterial 16S rDNA from D. migrans was directly amplified using PCR. DNA species were separated using denaturing gradient gel electrophoresis (DGGE). DGGE profiles generated ca. ten different distinguishable operational taxonomic units. Eleven bands from different sample materials were successfully re-amplified and sequenced. Sequence data generated five different subgroups of intratunical proteobacteria. The dominant band, detected in all of the samples tested, showed a low degree of relationship (84–86%) to Ruminococcus flavefaciens (-subgroup). A weaker band, located above, which was not detected in all of the samples, was also similarly related to R. flavefaciens. Other bands derived from tunic material and embryonic stages showed closer relationship (ca. 97–99%) to Pseudomonas saccherophilia, a knallgas bacterium, and Ralstonia pickettii, a pathogen bacterium (both members of the -subgroup). A solitary band generated from tunic material was assigned to a typical marine Flavobacterium symbiont (95%). Finally, a band from isolated bacteria was related (96%) to pathogen Arcobacter butzleri (-subgroup). At this state of the investigation, a reliable interpretation of the ecological functions of intratunical bacteria cannot yet be given. This is due to the low degree of relationship of some of the bacteria and the fact that not all of the characteristic bands were successfully sequenced. However, the intratunical bacteria represent a unique bacterial community. Their DGGE profiles do not correspond to the profiles of the planktonic bacteria generated from surface seawater close to the ascidian habitat. The allocation of DNA sequences to the different morphotypes, their isolation and culturing, and the elucidation of the physiological functions of intratunical bacteria are in progress.     

污损性海鞘的生态特点研究展望

海鞘生长快,繁殖迅速,能产生大量在短时间内附着的幼虫,是海洋污损生物群落中的重要成员,对海上人工设施会产生严重危害。污损性海鞘主要由悉尼海鞘(Ascidia sydneiensis)、史氏菊海鞘(Botryllus schlosseri)、米氏小叶鞘(Diplosoma listerianum)、柄瘤海鞘(Styela clava)、红贺海鞘(Herdmania momus)等9科29属103种组成,其中在太平洋海域64种、印度洋23种、大西洋44种,而北冰洋海域仅3种;另外,其附着污损具有明显的地域性和季节特点,并与深度有关。今后应加强污损性海鞘的生态调查和分类研究,阐明深海及两极海域附着污损特点,揭示幼虫附着变态过程的分子调控机理,完善幼虫采集培养技术,以期更好地掌握海鞘生物学特性与生态特点,丰富和发展海洋生态学内容,并为海洋污损生物的防除奠定基础,促进海洋经济产业的发展。     

Nestmate recognition and temporal modulation in the patterns of cuticular hydrocarbons in natural colonies of japanese carpenter antCamponotus japonicus mayr (hymenoptera: formicidae)

Camponotus japonicus workers can discriminate nestmates from alien individuals. In the field, freeze-killed alien workers received significantly more attacks than nestmate carcasses. Gas chromatography (GC) analysis showed that the compositions of cuticular hydrocarbons of foraging workers from different colonies were the same, but the relative proportions of some compounds were colony-specific. These compounds are thus likely to function as colonial signatures. Characterization of the cuticular hydrocarbons by GC for 2 natural colonies at an interval of about 30 days over 4 months revealed that the patterns of cuticular hydrocarbon of foraging workers were not fixed but changed with time. The significant temporal modulation in term of proportions occurred in 5 of the 6 compounds that seemed to be the potential colonial signatures. The biological significance of temporal modulation in colonial signature is also discussed.