Akihito Omori

Gene expression analysis of Six3, Pax6, and Otx in the early development of the stalked crinoid Metacrinus rotundus

The stalked crinoid, Metacrinus rotundus, is one of the most basal extant echinoderms. Here, we show the expression patterns of Six3, Pax6, and Otx in the early development of M. rotundus. All three genes are highly expressed in stages from the gastrula to the auricularia larval stage. Ectodermal expression of MrOtx appears to be correlated with development of the ciliary band. These three genes are expressed sequentially along the embryonic body axis in the anterior and middle walls of the archenteron in the order of MrPax6, MrSix3, and MrOtx. The anterior, middle, and posterior parts of the archenteron in the late gastrula differentiate into the axo-hydrocoel, the enteric sac, and somatocoels at later stages, respectively. The three genes are expressed sequentially from the tip of the axo-hydrocoel to the bottom of enteric sac in the order of MrSix3, MrPax6, and MrOtx at the later stages. This suggests that these genes are involved in patterning of the larval endo-mesoderm in stalked crinoids. The present results suggest that radical alterations have occurred in the expression and function of homeobox genes in basal echinoderms.

Patterning of anteroposterior body axis displayed in the expression of Hox genes in sea cucumber Apostichopus japonicus

The presence of an anteroposterior body axis is a fundamental feature of bilateria. Within this group, echinoderms have secondarily evolved pentameral symmetric body plans. Although all echinoderms present bilaterally symmetric larval stages, they dramatically rearrange their body axis and develop a pentaradial body plan during metamorphosis. Therefore, the location of their anteroposterior body axis in adult forms remains a contentious issue. Unlike other echinoderms, sea cucumbers present an obvious anteroposterior axis not rearranged during metamorphosis, thus representing an interesting group to study their anteroposterior axis patterning. Hox genes are known to play a broadly conserved role in anteroposterior axis patterning in deuterostomes. Here, we report the expression patterns of Hox genes from early development to pentactula stage in sea cucumber. In early larval stages, five Hox genes (AjHox1, AjHox7, AjHox8, AjHox11/13a, and AjHox11/13b) were expressed sequentially along the archenteron, suggesting that the role of anteroposterior patterning of the Hox genes is conserved in bilateral larvae of echinoderms. In doliolaria and pentactula stages, eight Hox genes (AjHox1, AjHox5, AjHox7, AjHox8, AjHox9/10, AjHox11/13a, AjHox11/13b, and AjHox11/13c) were expressed sequentially along the digestive tract, following a similar expression pattern to that found in the visceral mesoderm of other bilateria. Unlike other echinoderms, pentameral expression patterns of AjHox genes were not observed in sea cucumber. Altogether, we concluded that AjHox genes are involved in the patterning of the digestive tract in both larvae and metamorphosis of sea cucumbers. In addition, the anteroposterior axis in sea cucumbers might be patterned like that of other bilateria.

A new genus and new species of family Antedonidae (Echinodermata: Crinoidea) from southern Japan

A new genus and new species of antedonid comatulid is described from southern Japan. Belonometra n. gen. has a unique appearance with ten long arms, numerous cirri, and remarkably long and crowded pinnules. The new genus shares some characters with subfamily Heliometrinae. However, the comparative length of pinnules, which is a diagnostic character to determine subfamily Antedonidae, is different. The subfamily into which the new genus should be placed is unclear.

Larval and Adult Body Axes in Echinoderms

The echinoderm body plan is amazing and unique among metazoans, with pentameral (fivefold) symmetry as adults. Fossil records indicate that most of the extinct species also had non-bilateral shapes. Five classes of extant echinoderm species show diverse morphologies incorporating the pentameral symmetry. The anterior-posterior axis of most living echinoderms is not obvious, and it appears to be radially symmetrical as well. Instead, an oral-aboral axis and a proximal-distal axis have been assigned. Moreover, the body axes are different in an embryo/larva when compared to an adult. Embryos and larvae are bilateral with animal-vegetal, anterior-posterior, left-right, dorsal-ventral (oral-aboral) axes present. The larvae metamorphose into pentameral adults, and together with the change in structure, the body axes change. This remarkable transition in morphology makes their study unique for understanding how body axes are formed and how they change in evolution. Molecular studies of the development of axes in embryos and larvae have shown that the factors and genes involved in axis formation in echinoderms are shared with other bilaterians and these mechanisms appear to be conserved. However, the development into a pentaradial adult remains a mystery. Recent findings based on analyses of hox genes suggest that the oral-aboral axis of the adult body is equivalent to the anterior-posterior axis of other bilaterians. In this chapter, we will discuss the correlation between the hox gene expression and transitions in this unique change in body axes.

Correction to: A new species of Xenoturbella from the western Pacific Ocean and the evolution of Xenoturbella

After publication of Nakano et al. (2017) [1], the authors became aware of the fact that the new species-group name erected for the two specimens of a Japanese xenoturbellid species in the article is not available because Nakano et al. (2017) [1] does not meet the requirement of the amendment of Article 8.5.3 of the International Code of Zoological Nomenclature (the Code) [2]. The authors therefore describe the two xenoturbellids as a new species again in this correction article. Methods for morphological observation, DNA extraction and sequencing were as described in Nakano et al. (2017) [1]. The holotype and paratype specimens are deposited in the National Museum of Nature and Science, Tsukuba (NSMT), Japan. The DNA sequences obtained were deposited in the International Nucleotide Sequence Database (INSD).