Clonal animals do not sequester a germ line during embryogenesis. Instead, they have adult stem cells that contribute to somatic tissues or gametes. How germ fate is induced in these animals, and whether this process is related to bilaterian embryonic germline induction, is unknown. We show that transcription factor AP2 (Tfap2), a regulator of mammalian germ lines, acts to commit adult stem cells, known as i-cells, to the germ cell fate in the clonal cnidarian Hydractinia symbiolongicarpus. Tfap2 mutants lacked germ cells and gonads. Transplanted wild-type cells rescued gonad development but not germ cell induction in Tfap2 mutants. Forced expression of Tfap2 in i-cells converted them to germ cells. Therefore, Tfap2 is a regulator of germ cell commitment across germ line–sequestering and germ line–nonsequestering animals.
Chronic lymphocytic leukemias (CLLs) with unmutated (U-CLL) or mutated (M-CLL) IGHV have variable features of immunosuppression, possibly influenced by those CLL cells activated to produce interleukin 10 (IL-10). The two subsets differ in their levels of anergy, defined by low surface immunoglobulin M levels/signaling capacity, and in their DNA methylation profile, particularly variable in M-CLL. We have now found that levels of IL-10 produced by activated CLL cells were highly variable. Levels were higher in M-CLL than in U-CLL and correlated with anergy. DNA methylation analysis of IL10 locus revealed two previously uncharacterized 'variably methylated regions' (CLL-VMRs1/2) in the gene body, but similarly low methylation in the promoter of both U-CLL and M-CLL. CLL-VMR1/2 methylation was lower in M-CLL than in U-CLL and inversely correlated with IL-10 induction. A functional signal transducer and activator of transcription 3 (STAT3) binding site in CLL-VMR2 was confirmed by proximity ligation and luciferase assays, whereas inhibition of SYK-mediated STAT3 activation resulted in suppression of IL10. The data suggest epigenetic control of IL-10 production. Higher tumor load may compensate the reduced IL-10 production in U-CLL, accounting for clinical immunosuppression in both subsets. The observation that SYK inhibition also suppresses IL-10 provides a potential new rationale for therapeutic targeting and immunological rescue by SYK inhibitors in CLL.
Neurogenesis is the generation of neurons from stem cells, a process that is regulated by SoxB transcription factors (TFs) in many animals. Although the roles of these TFs are well understood in bilaterians, how their neural function evolved is unclear. Here, we use Hydractinia symbiolongicarpus, a member of the early-branching phylum Cnidaria, to provide insight into this question. Using a combination of mRNA in situ hybridization, transgenesis, gene knockdown, transcriptomics, and in vivo imaging, we provide a comprehensive molecular and cellular analysis of neurogenesis during embryogenesis, homeostasis, and regeneration in this animal. We show that SoxB genes act sequentially at least in some cases. Stem cells expressing Piwi1 and Soxb1, which have broad developmental potential, become neural progenitors that express Soxb2 before differentiating into mature neural cells. Knockdown of SoxB genes resulted in complex defects in embryonic neurogenesis. Hydractinia neural cells differentiate while migrating from the aboral to the oral end of the animal, but it is unclear whether migration per se or exposure to different microenvironments is the main driver of their fate determination. Our data constitute a rich resource for studies aiming at addressing this question, which is at the heart of understanding the origin and development of animal nervous systems.
Neurogenesis is the generation of neurons from stem cells, a process that is regulated by SoxB transcription factors (TFs) in many animals. Although the roles of these TFs are well understood in bilaterians, how their neural function evolved is unclear. Here, we use Hydractinia symbiolongicarpus, a member of the early-branching phylum Cnidaria, to provide insight into this question. Using a combination of mRNA in situ hybridization, transgenesis, gene knockdown, transcriptomics, and in-vivo imaging, we provide a comprehensive molecular and cellular analysis of neurogenesis during embryogenesis, homeostasis, and regeneration in this animal. We show that SoxB genes act sequentially. Stem cells expressing Piwi1 and Soxb1, which have a broad developmental potential, become neural progenitors that express Soxb2 before differentiating into mature neural cells. Knockdown of SoxB genes resulted in complex defects in embryonic neurogenesis. Hydractinia neural cells differentiate while migrating from the aboral to the oral end of the animal, but it is unclear whether migration per se or exposure to different microenvironments is the main driver of their fate determination. Our data constitute a rich resource for studies aiming at addressing this question, which is at the heart of understanding neurological disorders in all animals, including humans.
The ability to regenerate lost body parts is irregularly distributed among animals, with substantial differences in regenerative potential between and within metazoan phyla. It is widely believed that regenerative animal clades inherited some aspects of their capacity to regenerate from their common ancestors but have also evolved new mechanisms that are not shared with other regenerative animals. Therefore, to gain a broad understanding of animal regenerative mechanisms and evolution, a broad sampling approach is necessary. Unfortunately, only few regenerative animals have been established as laboratory models with protocols for functional gene studies. Here, we describe the methods to establish transgenic individuals of the marine cnidarian Hydractinia. We also provide methods for transient gene expression manipulation without modifying the genome of the animals.
An ancient evolutionary innovation of a novel cell-type, the stinging cell (cnidocyte), appeared >600 million years ago in the phylum Cnidaria (sea anemones, corals, hydroids, and jellyfish). A complex bursting nano-injector of venom, the cnidocyst, is embedded in cnidocytes and enables cnidarians paralyzing prey and predators, contributing to the evolutionary success of this phylum. In this work, we show that post-transcriptional regulation by a pan-cnidarian microRNA, miR-2022, is essential for biogenesis of these cells. By manipulation of miR-2022 levels in a transgenic reporter line of cnidocytes in the sea anemone Nematostella vectensis, followed by transcriptomics, single-cell data analysis, prey paralysis assays, and cell sorting of transgenic cnidocytes, we reveal that miR-2022 enables cnidocyte biogenesis, while exhibiting a conserved expression domain with its targets in cnidocytes of other cnidarian species. Thus, here we reveal one of the most ancient microRNA-regulated processes in nature by studying the functional basis for its conservation.
The B-cell receptor (BCR) of chronic lymphocytic leukemia (CLL) cells with unmutated (U-CLL) or mutated (M-CLL) immunoglobulin gene heavy-chain variable (IGHV) regions shows a variable degree of anergy, associated with low surface IgM (sIgM) levels and signaling capacity, more evident in M-CLL. DNA methylation is also different between M-CLL and U-CLL. Patients from both subsets are immunosuppressed from the early stages, possibly influenced by the ability of activated CLL cells to produce IL-10, a property of B10 cells. The aim of this study was to investigate associations between capacity of circulating CLL cells to differentiate into B10 cells and features of anergy. In parallel, the methylation status of the IL-10 gene locus was probed in order to investigate associations between IL-10 gene methylation and production. CLL cells were isolated and cultured +/- TLR9 activation with CpG (ODN-2006). Cytokine secretion was measured in supernatants (Luminex) and IL10 transcript was measured (RT-qPCR) from cell pellets. IL-10 production by CLL cells was measured by intracellular flow cytometry following stimulation with CpG for 24 hours. Epigenetic profiling was performed using MassARRAY and the 450K Array. We found that activation of CLL cells by CpG consistently induced production and secretion of IL-10 protein, while no or low amounts of pro-inflammatory cytokines were detected. Production of IL-10 was significantly higher in M-CLL than in U-CLL. Levels also correlated with lower sIgM levels and signaling capacity, both features of anergy. A linear correlation was present between secretion, intracellular production and transcript levels of IL-10, suggesting no aberrant post-transcriptional controls. In the absence of CpG activation, IL-10 transcript levels were also detected at low levels in M-CLL, while they were even lower in U-CLL. To identify a potential basis for the differential expression, DNA methylation analysis of IL-10 gene locus was performed. While the promoter region displayed similarly low levels of methylation in both U-CLL and M-CLL, methylation differences were detected immediately downstream of the promoter within the first intron (approximately +200 to +500 bp, differentially methylated region 1, DMR1) and in the gene body (approximately +1300 to +1800 bp, DMR2). Both DMR1 and DMR2 were markedly more hypomethylated in M-CLL than U-CLL, with the greatest difference detected at cg17067005 within DMR1. Each of these regions display histone H3 lysine 27 acetylation (H3K27ac) in B cells (GM12878 cells), thus are likely to represent functional DNA elements. Analysis of IL-10 transcript levels with methylation demonstrated a mutually exclusive pattern between expression and methylation of both DMR1 and DMR2. These data document a strong link between capacity to differentiate into B10-like cells and anergy, and suggest an epigenetic component in the regulation of IL-10 production in CLL cells. This capacity may contribute to immunosuppression. While U-CLL appears less able to produce IL-10 on a per cell basis, higher tumor load may compensate, accounting for clinical immunosuppression in both subsets. Disclosures No relevant conflicts of interest to declare.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
hi@scite.ai
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.