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 In this allorejection reaction, some loosely packed tunic masses remained in the gap between the two withdrawn colonies.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.     

Comparative studies on the circulatory system of the compound ascidians,Botryllus, Botrylloides and Symplegma

The circulatory systems of four polystyelids, Botryllus schlosseri, B. primigenus, Botrylloides violaceus and Symplegma reptans, were compared. The palleal buds are connected to the parent zooid by a peduncle and to the colonial vascular system by connecting vessels. The peduncle of S. reptans disappears at an earlier stage of bud development than in B. primigenus; it survives the dissolution of the parent zooid in B. schlosseri and B. violaceus. The connecting vessel is formed by anastomosis between an epidermal outgrowth from the bud and a neighboring colonial vessel, and is characterized by the presence of a sphincter. The number of connecting vessels formed in a palleal bud is three in S. reptans, two in B. primigenus and one each in B. schlosseri and B. violaceus. In each species, the larva has eight rudiments of ampullae. In B. primigenus, the original ampullae degenerate soon after metamorphosis and new ampullae extend from the ventral epidermis of the oozooid. In the other species, the colonial vascular system is derived from the original ampullae. The whole colonial vascular system contracts and expands periodically, with regionally different phases. During each expansion cycle, the sphincter contracts once in B. primigenus and twice in S. reptans. The correlation may be due to blood pressure and the propagation of excitation through the colonial vascular system.     

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.     

Localization of symbiotic cyanobacteria in the colonial ascidian Trididemnum miniatum (Didemnidae, Ascidiacea)

Trididemnum miniatum is a colonial ascidian harboring the photosymbiotic prokaryote Prochloron sp. These bacterial cells are located in the tunic of the host animal. The present study revealed, by ultrastructural analysis, that the Prochloron cells were exclusively distributed and proliferated in the tunic. They were shown to be embedded in the tunic matrix and to have no direct contact with ascidian cells. Some tunic cells of the ascidians, however, did phagocytize and digest the symbiont. Round cell masses were sometimes found in the tunic and appeared to consist of disintegrating cyanobacterial cells. The thoracic epidermis of ascidian zooids was often digitated, and the epidermal cells extended microvilli into the tunic. Since there were no Prochloron cells in the alimentary tract of the ascidian zooids, the photosymbionts would not be considered part of the typical diet of the host ascidians. Thin layer chromatography showed that the symbionts possessed both chlorophyll a and b, while a 16S rRNA gene phylogeny supported the identification of the photosymbiont of T. miniatum as Prochloron sp.     

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.     

Rhythmic contractions of the ampullar epidermis during metamorphosis of the ascidian Molgula occidentalis

Summary The ampullae of Molgula occidentalis are hollow, tubular extensions of the epidermis. They are ensheathed by a secreted tunic. When they grow out shortly after settlement, the ampullae spread the tunic over the substratum to form a firm attachment for the sessile juvenile. A simple squamous epithelium forms the thin ampullar walls. A glandular, simple columnar epithelium forms the distal tip of each ampulla. The glandular cells probably secrete the adhesive that attaches the tunic to the substratum.Repetitive, peristaltic contractions pass from the base to the distal end of each ampulla. Microsurgery, time-lapse cinemicrography and TEM have been used to analyze this phenomenon. The contractions are mediated by a layer of 4–8 nm microfilaments in the base of the ampullar epithelium.Each juvenile has 7–9 ampullae which contract at different frequencies. Isolated ampullae continue to contract normally for several days. Thus each ampulla has an intrinsic rhythm. Microsurgical experiments suggest that there is no specific region within an ampulla with unique pacemaker properties. It is proposed that communication via gap junctions allows the coordination of ampullar cells into a well organized peristaltic wave.     

A new mode of colony multiplication by modified budding in the ascidian Clavelina gemmae n. sp. (Clavelinidae)

Abstract. A new mechanism of asexual multiplication of colonies is described in a colonial ascidian of the genus Clavelina (Aplousobranchiata). The mechanism consisted of the production of star-shaped buds that originate from a basal vessel that bends anteriorly and extends along the dorsal region of the zooids. Once they are well developed, the buds detached easily and were dispersed by water movement. Analysis of the fine structure of the buds revealed that they were a modification of the stolonic budding common in this genus. Time-lapse video recordings showed that released buds required several days to develop, allowing for a potentially significant dispersal range. The buds underwent organogenesis during which the central part gave rise to a new blastozooid with a defined polarity; the arms of the star gave rise to stolons. A new species is defined based on the presence of this type of budding and on other morphological features. The significance of these findings, which adds to the known mechanisms of asexual reproduction in ascidians, is discussed in relation to the biology and distribution of the species.     

Cell types, microsymbionts, and pyridoacridine distribution in the tunic of three color morphs of the genus Cystodytes (Ascidiacea, Polycitoridae)

Abstract. The tunic of colonial ascidians of the genus Cystodytes is a dynamic and complex system where a variety of cell types and microsymbionts are found. The tunic is also the site where pyridoacridine alkaloids involved in chemical defense are found. We wanted to explore the composition of symbionts and tunic cell types and their relationship with localization of alkaloids in three color morphs (usually attributed to the species Cystodytes dellechiajei ). Tunic morphology was studied by means of transmission electron microscopy, and energy-dispersive X-ray microanalysis was performed for indirect localization of the bioactive alkaloids produced by these morphotypes. The main cell types identified are bladder cells, pigment cells, amebocytes, phagocytes, and morula cells. Amebocytes include several subtypes that may correspond to a sequence of ontogenetic stages; these cells also seem to give rise to other cell types. In the three morphotypes, the morphology of the tunic and tunic cells is basically the same. The alkaloids are localized in the pigment cells. At least three types of bacteria are present in the tunic, but they are scarce and do not store the targeted bioactive alkaloids. Our results indicate that, although pyridoacridine alkaloids are present in these ascidians, as in a variety of animal phyla, their wide taxonomic range is not necessarily the result of production by common microsymbionts, but rather of the convergent evolution of a successful biosynthetic pathway.     

Switching of metabolic-rate scaling between allometry and isometry in colonial ascidians

The metabolic rate and its scaling relationship to colony size were studied in the colonial ascidian Botrylloides simodensis. The colonial metabolic rate, measured by the oxygen consumption rate (V(O2) in millilitres of O(2) per hour) and the colony mass (wet weight M(w) in grams) showed the allometric relationship (V(O2) = 0.0412 M(w)(0.799). The power coefficient was statistically not different from 0.75, the value for unitary organisms. The size of the zooids and the tunic volume fraction in a colony were kept constant irrespective of the colonial size. These results, together with the two-dimensional colonial shape, excluded shape factors and colonial composition as possible causes of allometry. Botryllid ascidians show a takeover state in which all the zooids of the parent generation in a colony degenerate and zooids of a new generation develop in unison. The media for connection between zooids such as a common drainage system and connecting vessels to the common vascular system experienced reconstruction. The metabolic rate during the takeover state was halved and was directly proportional to the colonial mass. The scaling thus changed from being allometric to isometric. The alteration in the scaling that was associated with the loss of the connection between the zooids strongly support the hypothesis that the allometry was derived from mutual interaction among the zooids. The applicability of this hypothesis to unitary organisms is discussed.     

Phylogenetic diversity of bacteria associated with ascidians in Eel Pond (Woods Hole, Massachusetts, USA)

Recent studies have revealed that many marine invertebrates are closely associated with diverse microorganisms, frequently resulting in the production of compounds of biomedical interest. Thus far, ascidians have not been widely examined for the presence of bacterial associations, although the production of secondary metabolites is well documented. In the present study, we examined the gonad of Molgula manhattensis and the tunic surfaces of Botryllus schlosseri, Didemnum sp., and Botrylloides violaceus for the presence of associated bacteria. These ascidians are common inhabitants of the coastal ocean of Cape Cod, Massachusetts. We used denaturing gradient gel electrophoresis (DGGE) as well as cloning and sequencing of 16S rDNA to analyze the microbial communities. There is a strong evidence that spiroplasma-like bacteria colonize the gonad of the solitary ascidian M. manhattensis. The bacteria might be vertically transmitted and may be involved in the production of secondary metabolites that deter predators of the ascidians. The bacterial communities found on the tunic surfaces of the colonial ascidians were found to be more diverse. However, in all cases the bacterial communities were predominated by alpha-proteobacteria. Alpha-proteobacteria related to the obtained sequences have been identified as symbionts in a variety of hosts, suggesting a specific role for these bacteria. However, based on our data it is difficult to differentiate between persistently and only transiently associated bacteria. Overall, this study demonstrates that ascidian species are associated with diverse bacterial populations. Future studies will aim to elucidate the precise relationships between bacteria and ascidians and to identify bioactive compounds that might be produced as a result of these relationships.     

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.     

Viviparous development in Botrylloides (Compound Ascidians)

The mode of sexual reproduction and embryogenesis was compared in 3 species of Botrylloides: B. simodensis, B. lenis, and B. violaceus. In all species, a testis and an egg (occasionally 2 eggs), the former being anterior to the latter, mature in the mantle on either side of a zooid. The egg is surrounded by 2 follicular layers and is attached by a vesicular follicle stalk (oviduct) to the atrial brood pouch. The egg is ovulated into the brood pouch, where it is fertilized and undergoes embryogenesis. The egg of B. simodensis is heavily yolked and measures about 180 μm in diameter. The course of embryogenesis in this species is that typical of ascidians. A mature tadpole larva is produced and shed in about 5 days; then, the mother zooid degenerates. The larva is smallest of the three species and has 8 ampullae. The metamorphosed oozooid bears a single bud on the right side only. Extraembryonic nutrition seems to be very limited. Both Botrylloides lenis and B. violaceus are species which display extreme examples of viviparity. Their eggs are devoid of yolk granules, measuring about 90 μm in diameter in the former species and 60 μm in the latter. The course of embryogenesis is similar in these 2 species. The neurula stage is characterized by a spherical vesicular shape owing to precocious differentiation of the embryonic pharynx, whose ectoderm becomes vacuolated. At the posterior end of the neurula, the mesodermal cells are located in a mass, from which the tail is extended later. In B. lenis, embryogenesis takes about 20 days. At the neurula stage of the embryo, the mother zooid becomes a mantle sac as a result of visceral disintegration. During further embryogenesis, the growth of buds of successive generations in the colony is characteristically arrested. A swimming larva of this species is somewhat larger than that of B. simodensis. It has 14–24 ampullae, and the oozooid carries a single bud on its right side. In B. violaceus, the gestation period lasts for more than a month. At the early gastrula stage of the embryo, the body of the mother zooid fully disintegrates. Only the brood pouch bearing the embryo survives and remains connected with the colonial vascular system. In this species, sexual reproduction does not affect the growth of buds in the colony. The swimming larva is gigantic, being furnished with 24–34 ampullae, and the oozooid always bears 3 buds, 2 on the right side and one on the left side.     

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.     

Ultraviolet-light-absorbing tunic cells in didemnid ascidians hosting a symbiotic photo-oxygenic prokaryote,Prochloron

Coral reef invertebrates that host phototrophic symbionts are thought to protect themselves and their symbionts with mycosporine-like amino acids (MAAs)-UV-absorbing substances that act as sunscreens (Dunlap, W. C., and J. M. Shick, 1998. J. Phycol. 34: 418-430). However, the histological distribution of MAAs in the host tissues has not yet been visualized. We have localized the UV-absorbing substances in the tissues of two colonial didemnid ascidians-Lissoclinum patella and Diplosoma sp.-that contain the symbiotic photo-oxygenic prokaryote Prochloron sp. Cross-sections of unfixed tissue from these ascidians were examined by UV-light microscopy at 320 or 330 nm, wavelengths at which UV light is absorbed by MAAs. Within the tunic, the gelatinous integument of the colony, UV light was exclusively absorbed by a particular type of cell, the tunic bladder cell. Tunic bladder cells with strong UV absorption were denser in the upper tunic, which lies over a colony's zooids, than in the basal tunic underlying the zooid. In the upper tunic, those cells with strong UV absorption were most dense near the surface. The tunic bladder cell is highly vacuolated, and the vacuole contains strong acid, which destabilizes MAAs. Furthermore, the UV-absorbing portion of tunic bladder cells seemed to be cup-shaped, indicating that the MAAs are not localized in the vacuole, but in the cytoplasm. These results strongly suggest that didemnid ascidians accumulate MAAs in tunic bladder cells as a protection against UV radiation.     

Exogenously applied jasmonic acid induces changes in apical meristem morphology of potato stolons

Hooked apex stolons and initial swelling stolons of potato plants were treated with 3 x 10-8 mol l-1 jasmonic acid (JA) to study the effect of this compound on histology, cell expansion and tissue differentiation. In hooked apex stolons, JA application increased the meristem thickness and reduced the length of the leaf primordia, whereas in initial swelling stolons narrowing of the apical region, absence of leaf primordia and swelling of the subapical meristem were evident. Early vascular tissue differentiation was observed in response to JA treatment, especially of xylem elements from regions proximal to the tunic. Protoxylem elements, such as tracheal elements, were present with thin primary cell walls. The cell area was measured in two zones: zone I, central mother cells situated immediately under the tunic; and zone II, rib meristem cells. JA caused a four- and six-fold increase in cell area in both zones in hooked apex stolons and initial swelling stolons, respectively. Thus, tuber formation is concluded to occur as a consequence of increased cell expansion, a reduction in the length of leaf primordia, enlargement of meristems, and early vascular tissue differentiation.     

The postbranchial digestive tract of the ascidian, Polyandrocarpa misakiensis (Tunicata: Ascidiacea). 1. Oesophagus

The organization of the oesophagus in the budding styelid ascidian, Polyandrocarpa misakiensis, is described. The oesophagus consists of external and internal epithelium, and there are loose connective tissue, blood sinuses, and a muscular layer between them. The internal epithelium is simple columnar, except for the bottom of three folds. The external epithelium is simple squamous. The internal epithelium contains four cell types, i.e., ciliated mucous cells, band cells, endocrine cells, and undifferentiated cells. The ciliated mucous cells have apical cilia and microvilli, and two types of mucous vesicle. The band cells also have apical cilia and electron-dense granules in the apical cytoplasm. The endocrine cells are bottle-shaped, and have electron-dense granules both above and below the nucleus. The undifferentiated cells form pseudostratified epithelium at the bottom of each fold, and they have nuclei with prominent nucleoli. One type of coelomic cell, which has retractile cytoplasm, often migrates in the internal epithelium. Near the stomach, there are many darkly stained round cells clustered around the posterior end of the oesophagus. These two types of coelomic cells may be involved in the defense mechanism against the invasion of foreign organisms. The basic organization of the oesophagus of P. misakiensis is similar to those of other ascidians. However, the presence of three folds is a characteristic of a solitary species, rather than of a colonial species. Although ascidians are chordate invertebrates, the organization of their oesophagus is not very complex, which might reflect their life style.     

Unconventional signalling in tunicates

The zooids in colonial tunicates do not appear to be directly interconnected by nerves, but this has not prevented the evolution of coordinated behaviour in several groups. In Botryllus and other colonial styelid asci‐dians the endothelium lining the blood vessels is excitable and transmits action potentials from cell to cell via gap junctions. These signals mediate protective contractions of the zooids and synchronize contractions of the vascular ampullae. In didemnid ascidians such as Diplosoma a network of myocytes in the tunic serves to transmit excitation and to cause contractions of the cloacal apertures. Individual zooids of Pyrosoma protect themselves by closing their siphons and arresting their branchial cilia when stimulated. At the same time a flash of light is emitted. Neighbouring zooids sense the flash with their photoreceptors and respond in turn with protective responses and light emission. Protective responses thus spread by photic signalling and propagate from zooid to zooid through the colony in a saltatory manner. In chains of Salpafusifortnis, changes in the direction and/or speed of swimming are transmitted from zooid to zooid via adhesion plaques. When a zooid is stimulated, its body‐wall epithelium conducts action potentials to the plaque connecting it to the next zooid, exciting receptor neurons in that zooid. These receptors have sensory processes that bridge the gap between the two zooids. The sensory neurons so excited in the second zooid conduct impulses to the brain where they alter the motor output pattern, and at the same time generate epithelial action potentials that travel to the next zooid in line, where the same thing happens.

It is not clear why these unconventional signalling methods have evolved but the tunic may be an inhospitable environment for nerves, making conventional nervous links impossible.     

Tunic cells in pyrosomes (Thaliacea, Urochordata): cell morphology, distribution, and motility

Abstract. Cellular components of the tunic were histologically examined in 3 pyrosome species representing all 3 genera of the order: Pyrosoma atlanticum, Pyrosomella verticillata , and Pyrostremma spinosum . Three cell types are distributed in the tunic. Tunic amebocytes, irregularly shaped and motile, often contain granules and/or phagosomes. Spherical tunic cells contain many round vesicles with eosinophilic and acidic materials. Tunic net cells form a cellular network in which their long filopodia connect with one another. The net cells are densely distributed just beneath the tunic surface lining the common cloacal cavity and may produce tension to maintain the colony shape. The presence of net cells suggests a phylogenetic relationship between pyrosomes and some aplousobranch ascidians. Test fibers are multicellular cords that run in the tunic and connect the zooids. In P. atlanticum , they are attached to they are attached to the epidermal cells of the zooids, and transverse cloacal muscles are attached to the other (proximal) side of the epidermal cells. The test fibers may mediate coordination of the zooids and control muscle contraction.     

Immuno- and histochemistry characteristics of morula and test cells in three ascidian species

One of the hypotheses suggests that test cells play a part in a larval tunic formation like morula cells in adult ascidians. It was shown that the antibodies against morula cell proteins of 26 and 48 kDa of the ascidian Styela rustica react on the paraffin sections with both the granules of morula cells and test cells of ascidians S. rustica and Boltenia echinata. Among the test cell proteins of S. rustica SDS-electrophoresis revealed at least 5 major proteins but no one with the molecular mass of 26 and 48 kDa and none of them react with the antibodies. At the same time AB26 bind the proteins with similar molecular masses in blood cells and in the probe containing test cells--27 and 28 kDa, correspondingly,--of ascidian Molgula citrina. Comparative histochemical analysis of morula and test cells of these three ascidian species was carried out. There are a lot of acid polysaccharides combined with proteins in test cells whereas morula cells contain mainly positively charged proteins. Thus it could be supposed that degree of manifestation of antigens might be different in the conditions of immunoblot and immunohistochemical analysis. The hypothesis of the similarity in morula and test cells functions and their interrelationship is discussed.     

Distribution and long-term temporal patterns of four invasive colonial ascidians in the Gulf of Maine

Invasive ascidians are a growing concern for ecologists and natural resource managers, yet few studies have documented their short- and long-term temporal patterns of abundance. This study focuses on the invasion of the Gulf of Maine by the colonial ascidians Botryllus schlosseri, Botrylloides violaceus, Diplosoma listerianum and Didemnum sp. A. We examined the time of arrival and potential vectors for these four invasive ascidians using survey data (collected from 1969 onwards) and literature documentation. We also compared the dominance and seasonal patterns of abundance of these species using data from two identical panel studies; one conducted from 1979 to 1980, the other from 2003 to 2005. Didemnum and Botrylloides were most likely first introduced into the Damariscotta River, Maine in the early 1970's through oyster aquaculture while Botryllus and Diplosoma were probably transported by commercial and recreational vessels. The overall abundance of colonial ascidians has increased since 1979 and 1980. Botryllus was the only invasive colonial ascidian present during the 1979 to 1980 study and accounted for an average of 6.16% cover on panels. From 2003 to 2005, the more recently arrived colonial ascidians Botrylloides and Didemnum accounted for 7.38% and 2.08% cover respectively, while Botryllus covered only 1.16%. Our results reveal a shift in seasonal abundance between 1979 to 1980 and 2003 to 2004. In 1979 and 1980, colonial ascidians had the highest percent cover in fall and winter while in 2003 and 2005 they had highest percent cover in summer and fall. Seasonal patterns of space occupation by colonial ascidians were correlated with seasonal changes in seawater temperature.