Endogenous circadian clocks are poorly understood within early-diverging animal
lineages. We have characterized circadian behavioral patterns and identified
potential components of the circadian clock in the starlet sea anemone,
Nematostella vectensis: a model cnidarian which lacks algal symbionts.
Using automatic video tracking we showed that Nematostella exhibits rhythmic
circadian locomotor activity, which is persistent in constant dark, shifted or
disrupted by external dark/light cues and maintained the same rate at two different
temperatures. This activity was inhibited by a casein kinase 1δ/ε
inhibitor, suggesting a role for CK1 homologue(s) in Nematostella clock.
Using high-throughput sequencing we profiled Nematostella transcriptomes over
48 hours under a light-dark cycle. We identified 180 Nematostella
diurnally-oscillated transcripts and compared them with previously established
databases of adult and larvae of the symbiotic coral Acropora millepora,
revealing both shared homologues and unique rhythmic genes. Taken together, this
study further establishes Nematostella as a non-symbiotic model organism to
study circadian rhythms and increases our understanding about the fundamental
elements of circadian regulation and their evolution within the Metazoa
Summary
The mechanisms that sustain stem cells are fundamental to the maintenance of tissues/organs. Here we identify ‘cell-islands’ (CIs) as a niche for putative germ and somatic stem cells in Botryllus schlosseri, a colonial chordate that undergoes weekly cycles of death and regeneration. Cells within CIs express markers associated with germ and somatic stem cells and gene products that implicate CIs as signaling centers for stem cells. Transplantation of CIs induced long-term germ-line and somatic chimerism, demonstrating self-renewal and pluripotency of CI-cells. Cell labeling and in-vivo time-lapse imaging of CI-cells reveal waves of migrations from degrading CIs, into developing buds, contributing to soma and germ-line development. Knockdown of cadherin, which is highly expressed within CIs, elicited the migration of CI-cells to circulation. Piwi-knockdown resulted in regeneration arrest. We suggest that repeated trafficking of stem cells allow them to escape the constraints imposed by the niche, thereby promoting their self-preservation throughout life.
BackgroundGenomic regions with repetitive sequences are considered unstable and prone to swift DNA diversification processes. A highly diverse immune gene family of the sea urchin (Strongylocentrotus purpuratus), called Sp185/333, is composed of clustered genes with similar sequence as well as several types of repeats ranging in size from short tandem repeats (STRs) to large segmental duplications. This repetitive structure may have been the basis for the incorrect assembly of this gene family in the sea urchin genome sequence. Consequently, we have resolved the structure of the family and profiled the members by sequencing selected BAC clones using Illumina and PacBio approaches.ResultsBAC insert assemblies identified 15 predicted genes that are organized into three clusters. Two of the gene clusters have almost identical flanking regions, suggesting that they may be non-matching allelic clusters residing at the same genomic locus. GA STRs surround all genes and appear in large stretches at locations of putatively deleted genes. GAT STRs are positioned at the edges of segmental duplications that include a subset of the genes. The unique locations of the STRs suggest their involvement in gene deletions and segmental duplications. Genomic profiling of the Sp185/333 gene diversity in 10 sea urchins shows that no gene repertoires are shared among individuals indicating a very high gene diversification rate for this family.ConclusionsThe repetitive genomic structure of the Sp185/333 family that includes STRs in strategic locations may serve as platform for a controlled mechanism which regulates the processes of gene recombination, gene conversion, duplication and deletion. The outcome is genomic instability and allelic mismatches, which may further drive the swift diversification of the Sp185/333 gene family that may improve the immune fitness of the species.Electronic supplementary materialThe online version of this article (doi:10.1186/s12864-016-3241-x) contains supplementary material, which is available to authorized users.
Plastic debris in the ocean form a new ecosystem, termed ‘plastisphere’, which hosts a variety of marine organisms. Recent studies implemented DNA metabarcoding to characterize the taxonomic composition of the plastisphere in different areas of the world. In this study, we used a modified metabarcoding approach which was based on longer barcode sequences for the characterization of the plastisphere biota. We compared the microbiome of polyethylene food bags after 1 month at sea to the free-living biome in two proximal but environmentally different locations on the Mediterranean coast of Israel. We targeted the full 1.5 kb-long 16S rRNA gene for bacteria and 0.4–0.8 kb-long regions within the 18S rRNA, ITS, tufA and COI loci for eukaryotes. The taxonomic barcodes were sequenced using Oxford Nanopore Technology with multiplexing on a single MinION flow cell. We identified between 1249 and 2141 species in each of the plastic samples, of which 61 species (34 bacteria and 27 eukaryotes) were categorized as plastic-specific, including species that belong to known hydrocarbon-degrading genera. In addition to a large prokaryotes repertoire, our results, supported by scanning electron microscopy, depict a surprisingly high biodiversity of eukaryotes within the plastisphere with a dominant presence of diatoms as well as other protists, algae and fungi.
Immune systems in animals rely on fast and efficient responses to a wide variety of pathogens. The Sp185/333 gene family in the purple sea urchin, Strongylocentrotus purpuratus, consists of an estimated 50 (±10) members per genome that share a basic gene structure but show high sequence diversity, primarily due to the mosaic appearance of short blocks of sequence called elements. The genes show significantly elevated expression in three subpopulations of phagocytes responding to marine bacteria. The encoded Sp185/333 proteins are highly diverse and have central effector functions in the immune system. In this study we report the Sp185/333 gene expression in single sea urchin phagocytes. Sea urchins challenged with heat-killed marine bacteria resulted in a typical increase in coelomocyte concentration within 24 h, which included an increased proportion of phagocytes expressing Sp185/333 proteins. Phagocyte fractions enriched from coelomocytes were used in limiting dilutions to obtain samples of single cells that were evaluated for Sp185/333 gene expression by nested RT-PCR. Amplicon sequences showed identical or nearly identical Sp185/333 amplicon sequences in single phagocytes with matches to six known Sp185/333 element patterns, including both common and rare element patterns. This suggested that single phagocytes show restricted expression from the Sp185/333 gene family and infers a diverse, flexible, and efficient response to pathogens. This type of expression pattern from a family of immune response genes in single cells has not been identified previously in other invertebrates.
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