BackgroundReconstructing the evolutionary history of nervous systems requires an understanding of their architecture and development across diverse taxa. The spiralians encompass diverse body plans and organ systems, and within the spiralians, annelids exhibit a variety of morphologies, life histories, feeding modes and associated nervous systems, making them an ideal group for studying evolution of nervous systems.ResultsWe describe nervous system development in the annelid Capitella teleta (Blake JA, Grassle JP, Eckelbarger KJ. Capitella teleta, a new species designation for the opportunistic and experimental Capitella sp. I, with a review of the literature for confirmed records. Zoosymposia. 2009;2:25–53) using whole-mount in situ hybridization for a synaptotagmin 1 homolog, nuclear stains, and cross-reactive antibodies against acetylated α-tubulin, 5-HT and FMRFamide. Capitella teleta is member of the Sedentaria (Struck TH, Paul C, Hill N, Hartmann S, Hosel C, Kube M, et al. Phylogenomic analyses unravel annelid evolution. Nature. 2011;471:95–8) and has an indirectly-developing, lecithotrophic larva. The nervous system of C. teleta shares many features with other annelids, including a brain and a ladder-like ventral nerve cord with five connectives, reiterated commissures, and pairs of peripheral nerves. Development of the nervous system begins with the first neurons differentiating in the brain, and follows a temporal order from central to peripheral and from anterior to posterior. Similar to other annelids, neurons with serotonin-like-immunoreactivity (5HT-LIR) and FMRFamide-like-immunoreactivity (FMRF-LIR) are found throughout the brain and ventral nerve cord. A small number of larval-specific neurons and neurites are present, but are visible only after the central nervous system begins to form. These larval neurons are not visible after metamorphosis while the rest of the nervous system is largely unchanged in juveniles.ConclusionsMost of the nervous system that forms during larvogenesis in C. teleta persists into the juvenile stage. The first neurons differentiate in the brain, which contrasts with the early formation of peripheral, larval-specific neurons found in some spiralian taxa with planktotrophic larvae. Our study provides a clear indication that certain shared features among annelids - e.g., five connectives in the ventral nerve cord - are only visible during larval stages in particular species, emphasizing the need to include developmental data in ancestral character state reconstructions. The data provided in this paper will serve as an important comparative reference for understanding evolution of nervous systems, and as a framework for future molecular studies of development.Electronic supplementary materialThe online version of this article (doi:10.1186/s12983-015-0108-y) contains supplementary material, which is available to authorized users.
Background Annelids are a diverse group of segmented worms within Spiralia, whose embryos exhibit spiral cleavage and a variety of larval forms. While most modern embryological studies focus on species with unequal spiral cleavage nested in Pleistoannelida (Sedentaria + Errantia), a few recent studies looked into Owenia fusiformis, a member of the sister group to all remaining annelids and thus a key lineage to understand annelid and spiralian evolution and development. However, the timing of early cleavage and detailed morphogenetic events leading to the formation of the idiosyncratic mitraria larva of O. fusiformis remain largely unexplored. Results Owenia fusiformis undergoes equal spiral cleavage where the first quartet of animal micromeres are slightly larger than the vegetal macromeres. Cleavage results in a coeloblastula approximately 5 h post-fertilization (hpf) at 19 °C. Gastrulation occurs via invagination and completes 4 h later, with putative mesodermal precursors and the chaetoblasts appearing 10 hpf at the dorso-posterior side. Soon after, at 11 hpf, the apical tuft emerges, followed by the first neurons (as revealed by the expression of elav1 and synaptotagmin-1) in the apical organ and the prototroch by 13 hpf. Muscles connecting the chaetal sac to various larval tissues develop around 18 hpf and by the time the mitraria is fully formed at 22 hpf, there are FMRFamide+ neurons in the apical organ and prototroch, the latter forming a prototrochal ring. As the mitraria feeds, it grows in size and the prototroch expands through active proliferation. The larva becomes competent after ~ 3 weeks post-fertilization at 15 °C, when a conspicuous juvenile rudiment has formed ventrally. Conclusions Owenia fusiformis embryogenesis is similar to that of other equal spiral cleaving annelids, supporting that equal cleavage is associated with the formation of a coeloblastula, gastrulation via invagination, and a feeding trochophore-like larva in Annelida. The nervous system of the mitraria larva forms earlier and is more elaborated than previously recognized and develops from anterior to posterior, which is likely an ancestral condition to Annelida. Altogether, our study identifies the major developmental events during O. fusiformis ontogeny, defining a conceptual framework for future investigations.
Indirect development with an intermediate larva exists in all major animal lineages1, which makes larvae central to most scenarios of animal evolution2–11. Yet how larvae evolved remains disputed. Here we show that temporal shifts (that is, heterochronies) in trunk formation underpin the diversification of larvae and bilaterian life cycles. We performed chromosome-scale genome sequencing in the annelid Owenia fusiformis with transcriptomic and epigenomic profiling during the life cycles of this and two other annelids. We found that trunk development is deferred to pre-metamorphic stages in the feeding larva of O. fusiformis but starts after gastrulation in the non-feeding larva with gradual metamorphosis of Capitella teleta and the direct developing embryo of Dimorphilus gyrociliatus. Accordingly, the embryos of O. fusiformis develop first into an enlarged anterior domain that forms larval tissues and the adult head12. Notably, this also occurs in the so-called ‘head larvae’ of other bilaterians13–17, with which the O. fusiformis larva shows extensive transcriptomic similarities. Together, our findings suggest that the temporal decoupling of head and trunk formation, as maximally observed in head larvae, facilitated larval evolution in Bilateria. This diverges from prevailing scenarios that propose either co-option9,10 or innovation11 of gene regulatory programmes to explain larva and adult origins.
The causes and consequences of genome reduction in animals are unclear because our understanding of this process mostly relies on lineages with often exceptionally high rates of evolution. Here, we decode the compact 73.8-megabase genome of Dimorphilus gyrociliatus, a meiobenthic segmented worm. The D. gyrociliatus genome retains traits classically associated with larger and slower-evolving genomes, such as an ordered, intact Hox cluster, a generally conserved developmental toolkit and traces of ancestral bilaterian linkage. Unlike some other animals with small genomes, the analysis of the D. gyrociliatus epigenome revealed canonical features of genome regulation, excluding the presence of operons and trans-splicing. Instead, the gene-dense D. gyrociliatus genome presents a divergent Myc pathway, a key physiological regulator of growth, proliferation and genome stability in animals. Altogether, our results uncover a conservative route to genome compaction in annelids, reminiscent of that observed in the vertebrate Takifugu rubripes.
Animal genomes vary in size by orders of magnitude 1 . While genome size expansion relates to transposable element mobilisation 2-5 and polyploidisation 6-9 , the causes and consequences of genome reduction are unclear 1 . This is because our understanding of genome compaction relies on animals with extreme lifestyles, such as parasites 10,11 , and free-living animals with exceptionally high rates of evolution 12-15 . Here, we decode the extremely compact genome of the annelid Dimorphilus gyrociliatus, a morphologically miniature meiobenthic segmented worm 16 . With a ~68 Mb size, Dimorphilus genome is the second smallest ever decoded for a free-living animal. Yet, it retains many traits classically associated with larger and slower-evolving genomes, such as an ordered, intact Hox cluster, a generally conserved developmental toolkit, and traces of ancestral 3 bilaterian linkage. Unlike animals with small genomes, the analysis of Dimorphilus epigenome revealed canonical features of genome regulation, excluding the presence of operons and trans-splicing. Instead, the gene dense Dimorphilus genome presents divergent kynurenine and Myc pathways, key physiological regulators of growth, proliferation and genome stability in animal cells that can cause small body size when impaired 17-21 . Altogether, our results uncover a novel, conservative route to extreme genome compaction, suggesting a mechanistic relationship between genome size reduction and morphological miniaturisation in animals.Animals, and eukaryotes generally, exhibit a striking range of genome sizes across species 1 , seemingly uncorrelated with morphological complexity and gene content, which has been deemed the "C-value enigma" 22 . Animal genomes often increase in size mobilising their transposable element (TE) repertoire (e.g. in rotifers 2 , chordates 3,4 and insects 5 ) and through chromosome rearrangements and polyploidisation (e.g. in vertebrates and teleosts 6-8 , and insects 9 ), which is usually counterbalanced through TE removal 23 , DNA deletions 24,25 and rediploidisation 26 . Although the adaptive impact of these changes is complex and probably often influenced by neutral nonadaptive population dynamics 27 , genome expansions might also increase the evolvability of a lineage by providing new genetic material that can stimulate species radiation 6 and the evolution of new genome regulatory contexts 28 and gene architectures 29 . By contrast, the adaptive value of genome compaction is more debated and hypotheses are often based on correlative associations 1 , e.g. with changes in metabolic 30 and developmental rates 31 , cell sizes 1,32 , and the evolution of radically new lifestyles (e.g. powered flight in birds and bats 25,33 , and parasitism in nematodes 11 and orthonectids 10 ).Besides, extreme genomic compaction leading to minimal genome sizes, as in some freeliving species of nematodes 34 , tardigrades 35 and appendicularians 4,36 , co-occurs with 4 prominent changes in gene repertoire 37,38 , genome architecture (e.g. loss of macrosynt...
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