Junzo Tsukahara

Reconsidering Zoanthus spp. Diversity: Molecular Evidence of Conspecifity Within Four Previously Presumed Species

Abstract We have conducted the first phylogenetic study to our knowledge of Zoanthus in the northern hemisphere by sequencing and analysing the mitochondrial cytochrome oxidase subunit 1 (COI) gene. Various unidentified Zoanthus specimens and samples of what have been assumed to be four discrete species (Z. pacificus, Z. sansibaricus, Z. gnophodes, Z. erythrochloros) were collected from four field sites in Kagoshima Prefecture, Japan. Based on our obtained COI gene sequences, all but one of our collected Zoanthus samples appear to be conspecific, with nearly 100.00% base pair matching. Genetic results are further backed up by collected polyp diameter, tentacle count, and mesentary count data. These results indicate a need to reconsider and re-analyze current Zoanthus classification and identification. Possible reasons for the large morphological variation in the same genotype in Zoanthus are also discussed.

Morphological and Molecular Revision of Zoanthus (Anthozoa: Hexacorallia) from Southwestern Japan, with Descriptions of Two New Species

Abstract No clear method of identifying species in the zoanthid genus Zoanthus has been established, due in part to the morphological plasticity of this genus (e.g., in polyp and colony form, oral disk color, tentacle number). Previous research utilizing the mitochondrial cytochrome oxidase I gene (COI) as a phylogenetic marker indicated that Zoanthus spp. in Japan may consist of only one or two species, despite a bewildering variety of observed morphotypes. Here we have utilized not only COI but also mitochondrial 16S ribosomal DNA (mt 16S rDNA) in order to clarify the extent of Zoanthus species diversity in southern Japan. Our molecular genetic results clearly show the presence of three monophyletic Zoanthus species groups with varying levels of morphological plasticity, including the new species Z. gigantus n. sp. and Z. kuroshio n. sp. We describe all three species found in this study, and identify potential morphological characters (coenenchyme and polyp structure as well as polyp external surface pigmentation patterns) useful in Zoanthus species identification. A morphological dichotomous key is provided to assist in field species identification.

Molecular Evidence Suggesting Species in the Zoanthid Genera Palythoa and Protopalythoa (Anthozoa: Hexacorallia) Are Congeneric

Abstract Taxonomic status of the zoanthid genera Palythoa and Protopalythoa has been in question for almost a century. Separation of the two genera has been based on traditional morphological methods (colony and polyp form, nematocyst size and form, and number of septa), with Palythoa polyps embedded in a well developed coenenchyme and Protopalythoa polyps standing free and clear of the coenenchyme. Here we sequenced two mitochondrial regions, the cytochrome oxidase I (COI) gene and 16S ribosomal DNA (16S rDNA) genes, from Palythoa and Protopalythoa samples from various parts of the world and performed phylogenetic analyses of the sequence data. The phylogenetic trees for both COI and 16S rDNA from Palythoa and Protopalythoa show four monophyletic groups (designated Palythoa tuberculosa, Palythoa heliodiscus, Palythoa mutuki 1, and Palythoa mutuki 2), with levels of sequence divergence (COI and 16S rDNA divergence approximately 0.0~1.1%) similar to or lower than that previously found among congeneric species within the closely related genus Zoanthus. Surprisingly, sequence differences among Palythoa tuberculosa, Palythoa mutuki 1, and Palythoa mutuki 2 were negligible (0.0~0.2% for both COI and 16S rDNA), potentially indicating relationships below the species level. Our sequences align well with the few Palythoa and Protopalythoa sequences reported to date. These findings strongly indicate that our samples represent a minimum of two and possibly up to four species (the Palythoa tuberculosa -P. mutuki 1 - P. mutuki 2 group, and P. heliodiscus) within the genus Palythoa, and that the genus Protopalythoa is erroneous nomenclature.

Latitudinal and intracolony ITS-rDNA sequence variation in the symbiotic dinoflagellate genus Symbiodinium (Dinophyceae) in Zoanthus sansibaricus (Anthozoa : Hexacorallia)

We sequenced the internal transcribed spacer of ribosomal DNA (ITS‐rDNA) of Symbiodinium spp. (Freudenthal) from conspecific Zoanthus sansibaricus (Carlgren) colonies along a latitudinal gradient in Japan. Phylogenetic analysis reveals that Zoanthus in the two northern sites of Kokubu and Sakurajima harbor exclusively Symbiodinium subclade C1, whereas Yakushima Zoanthus harbors Symbiodinium subclades C1 and C15, and southernmost Amami Zoanthus Symbiodinium subclades A1 and C1, indicating holobiont flexibility. Individual Zoanthus colonies associated exclusively with one single subclade, but unexpectedly there was small variation between Symbiodinium ITS‐rDNA clone sequences obtained from within individual Zoanthus colonies. There was also a large deletion in the ITS‐2/28S rDNA boundary region in one clone sequence, and another large deletion in the 5.8S rDNA region in another clone. Our intracolony sequence heterogeneity might be a result of the presence of multiple copies of the ITS‐rDNA region within individual Symbiodinium genomes, or result from the possible presence of closely related Symbiodinium genotypes in the host.

Non‐seasonal clade‐specificity and subclade microvariation in symbiotic dinoflagellates (Symbiodinium spp.) in Zoanthus sansibaricus (Anthozoa: Hexacorallia) at Kagoshima Bay, Japan

While much work has investigated the genetic diversity of symbiotic dinoflagellate genus Symbiodinium Freudenthal in cnidarians, investigations into such diversity over temporal scales (seasonal and/or annual) remain scarce. Here, we have sequenced the internal transcribed spacer of ribosomal DNA (ITS‐rDNA) of Symbiodinium from samples of designated Zoanthus sansibaricus Carlgren (Anthozoa: Hexacorallia) colonies collected for 12 months (August 2004–July 2005) at a high latitude non‐reefal coral community at Sakurajima, Kagoshima Bay, Japan (31°35′N, 130°35′E). Our results show that despite large ocean temperature changes (15.0–29.0°C) throughout the one‐year experimental period, Z. sansibaricus colonies contained only clade C Symbiodinium from many different subclade C1/C3‐related novel types not previously reported. While no temporal changes in clade‐level associations were seen, there were consistent and extremely large amounts (145 unique sequences out of 153 total obtained sequences) of genotypic microvariation observed in our obtained sequences. Despite Z. sansibaricus acquiring Symbiodinium horizontally and the presence of various other Symbiodinium clades (A, G) and subclades (e.g. C15 and derived subclades) in the immediate environment, Z. sansibaricus at Sakurajima specifically associates with subclade C1/C3‐related Symbiodinium. While subclades C1/C3 have been found in a variety of different environments and are believed to be ancestral, ‘generalist’ types of Symbiodinium, C1/C3‐related clades such as seen here may be more adapted to specialized niches. We theorize that specific and year‐round association with many different types of subclade C1/C3‐related Symbiodinium helps Z. sansibaricus to survive in the fluctuating Sakurajima environment.

Molecular Evidence Suggesting Interspecific Hybridization in Zoanthus spp. (Anthozoa: Hexacorallia)

Abstract Interspecific hybridization has been proposed as a possible explanation for the incredible diversity seen in reef-dwelling corals, but until now little proof of such hybridization in other reef-dwelling anthozoans has been reported. Without further observation of hybridization, the question of such a phenomenon being widespread in Anthozoa remains. Here we have examined the mitochondrial cytochrome oxidase I gene (COI) and the nuclear internal transcribed spacer of ribosomal DNA (ITS-rDNA) from three species of the mass-spawning, encrusting anemone genus Zoanthus (Z. sansibaricus, Z. kuroshio, Z. gigantus) to investigate possible hybridization. The three species coexist at two of three sampling locations in southern Japan. Zoanthus spp. ITS-rDNA region spacers (ITS-1 and ITS-2) were shown to have very high rates of divergence. At locations where all three species co-existed, several of our sampled Z. sansibaricus individuals (with identical “sansi” COI sequences) possessed two very divergent (i.e., species-level difference) ITS-rDNA alleles, the expected “sansi” allele and the divergent “B” allele. Additionally, two Z. sansibaricus individuals possessed only “B” alleles despite having “sansi” COI sequences. These results indicate that Z. sansibaricus has possibly experienced interspecific hybridization at least once with a Zoanthus partner possessing the “B” allele, and that these resulting hybrids may also sexually reproduce, demonstrating potential hybridization occurring in the order Zoantharia (Hexacorallia).

High Levels of Morphological Variation Despite Close Genetic Relatedness Between Zoanthus aff. vietnamensis and Zoanthus kuroshio (Anthozoa: Hexacorallia)

Abstract Recent investigations into the encrusting anemone genus Zoanthus using molecular and morphological techniques have begun to bring order to this taxonomically neglected group. Previous studies have confirmed the existence of three distinct species present in southern Japan: Z. sansibaricus, Z. kuroshio, and Z. gigantus. Results from such studies show species of Zoanthus to be highly morphologically plastic, often incorporating morphotypes with varying oral disk color and oral disk diameter. Literature lists the species Z. aff. vietnamensis as occurring in southern Japan and throughout the western Pacific Ocean, but due to the morphological plasticity of Zoanthus species, a re-examination of Z. aff. vietnamensis using molecular techniques was needed. Here, using mitochondrial 16S rDNA and the nuclear internal transcribed spacer of ribosomal DNA (ITS-rDNA) sequences, as well as morphological data, we have examined several nominal Z. aff. vietnamensis samples collected from Kagoshima Bay and Yakushima Island, Japan. Based on polyp length and diameter, oral disk diameter, mesentery and tentacle numbers, and colony form, Z. aff. vietnamensis is easily distinguishable from Z. sansibaricus, Z. kuroshio, and Z. gigantus. However, despite these clear morphological differences, our mitochondrial and nuclear sequence-based phylogenies indicate that Z. aff. vietnamensis and Z. kuroshio are very closely related (perhaps conspecific), highlighting the morphological plasticity of this genus and the difficulty of species identification based on morphological data alone.

Reproduction of Zoanthus sansibaricus in the infra-littoral zone at Taisho Lava Field, Sakurajima, Kagoshima, Japan.

Abstract In order to obtain data on the reproductive pattern of the clonal cnidarian Zoanthus sansibaricus, polyps were sampled by scuba gear at Taisho Lava Field, Sakurajima, for 24 months between April 2000 and March 2002 (polyps collected weekly for breeding season). According to cross-sections, Zoanthus polyps were divided into three sexual types; male, female and asexual, and were found in the same colony. At Sakurajima, Zoanthus sansibaricus spawned in the middle of July, releasing oocytes and sperm. These spawning events occur synchronously with moon phase. In gametogenesis of Zoanthus sansibaricus, oocytes became recognizable in February and grew rapidly from the end of June onward. Spermatocytes became recognizable in June and matured rapidly in the middle of July. After spawning events, oocytes still remaining in the endoderm were absorbed into Zoanthus tissue quickly.

Spicule Formation‐Inducing Substance in Sea Urchin Embryo

Isolated micromeres of sea urchin produced spicules in sea water containing blastocoelic fluid (BCF) taken from embryos, or in a medium in which embryos had previously been dissociated (dissociated solution, DS). When isolated micromeres were cultured in vitro, their descendants initiated spicule formation only when BCF was added to the culture medium by the time when, in normal development, primary mesenchyme cells form two aggregates in the vegetal region. After the initiation of spicule formation, growth of spicules occurred under the continuous influence of DS. Spicule formation‐inducing (SFI) activity in DS was first detected at the mesenchme blastula stage. The activity in BCF was heat‐labile and was inactivated by trypsin.

In situ spawning of a deep-sea vesicomyid clam: Evidence for an environmental cue

Abstract Spawning of the deep-sea vesicomyid clam Calyptogena soyoae was shown to be induced by short-term changes in water temperature. It was induced in situ by artificially increasing the ambient water temperature using the submersible Shinkai 2000 off Hatsushima Island in Sagami Bay, Japan. Furthermore, we recorded in situ spawning events associated with natural changes in temperature at a deep-sea observatory on 11 occasions over a period of 1.5 years at the same site. The potential benefit of thermal regulation of reproduction in an otherwise aperiodic, dark, and unstable environment suggests that this strategy may be common for reproduction, particularly near chemosynthetic communities.