Localized XId3 mRNA activation in Xenopus embryos by cytoplasmic polyadenylation

Id(entifying) the inhibitor of DNA binding 3 in the brain of Nothobranchius furzeri upon aging

Inhibitors of DNA (Id) are key transcription factors (TFs) regulating neurogenic processes. They belong to the helix-loop-helix (HLH) TF family and are dominant negative regulators of basic HLH proteins (bHLHs). Specifically, they inhibit cell differentiation and enhance cell proliferation and motility. The Id family includes four members, Id1, Id2, Id3, and Id4, which have been identified in nearly all vertebrates. The transcript catalog of the African turquoise killifish, Nothobranchius furzeri, contains all four TFs and has evolved showing positive selection for Id3. N. furzeri, a teleost, is the short-lived vertebrate and is gaining increasing scientific interest as a new model organism in aging research. It is characterized by embryonic diapause, explosive sexual maturation, and rapid aging. In this study, we investigated both the expression and the role of Id3 in the brain of this model organism. Interestingly, Id3 was upregulated age-dependently along with a distribution pattern resembling that of other vertebrates. Additionally, the gene has undergone positive selection during evolution and shows a high degree of conservation relative to that of other vertebrates. These features make N. furzeri a valid tool for aging studies and a potential model in translational research.

Molecular mechanisms regulating expression and function of transcription regulator inhibitor of differentiation 3

The transcription factor antagonist inhibitor of differentiation 3 (Id3) has been implicated in many diverse developmental, physiological and pathophysiological processes. Its expression and function is subjected to many levels of complex regulation. This review summarizes the current understanding of these mechanisms and describes how they might be related to the diverse functions that have been attributed to the Id3 protein. Detailed understanding of these mechanisms should provide insights towards the development of therapeutic approaches to various diseases, including cancer and atherogenesis.

Identification and expression profile of the ID gene family in the rainbow trout (Oncorhynchus mykiss)

ID proteins are negative regulators of basic helix-loop-helix transcription factors governing growth and development in mammals. However, little is known about the ID gene function and expression in fish. We report the identification and characterization of two new rainbow trout ID genes (ID1D and ID2B) and extend our expression analyses of two previously identified ID genes (ID1A and ID2A). Phylogenetic analyses indicate an evolutionary relationship between ID1A and ID1D and between ID1B and ID1C, suggesting a mechanism of divergence throughout salmonid evolution. To access the expression of these genes in adult and developing fish, we measured the relative transcript abundance of four ID1 and two ID2 genes by real-time PCR. ID1 transcripts were expressed in a variety of tissues and the ID1 paralogues showed similar patterns of expression, whereas the ID2 paralogues were differentially expressed. To access the role of the ID genes during embryonic development, gene expression was measured at early (day 0 and day 2), mid (day 9 and day 18) and late (day 30 and day 50) embryonic development. ID1A and ID1D expression remained unchanged throughout embryonic development, while ID1B and ID1C were lowest during early, highest at mid, and decreased during late embryonic development. The ID2 transcripts revealed the highest expression in unfertilized eggs and day 2 embryos, and remained low throughout the remainder of embryonic development. The sequence analyses and gene expression patterns implicate gene and genome duplication in rainbow trout ID gene evolution and suggest an extensive role for the IDs in rainbow trout growth and development.

Inhibition of neurogenesis by SRp38, a neuroD-regulated RNA-binding protein

Although serine-arginine rich (SR) proteins have often been implicated in the positive regulation of splicing, recent studies have shown that one unusual SR protein, SRp38, serves, contrastingly, as a splicing repressor during mitosis and stress response. We have identified a novel developmental role for SRp38 in the regulation of neural differentiation. SRp38 is expressed in the neural plate during embryogenesis and is transcriptionally induced by the neurogenic bHLH protein neuroD. Overexpression of SRp38 inhibits primary neuronal differentiation at a step between neurogenin and neuroD activity. This repression of neuronal differentiation requires activation of the Notch pathway. Conversely, depletion of SRp38 activity results in a dysregulation of neurogenesis. Finally, SRp38 can interact with the peptidyltransferase center of 28S rRNA, suggesting that SRp38 activity may act, in part, via regulation of ribosome biogenesis or function. Strikingly, recent studies of several cell cycle regulators during primary neurogenesis have also revealed a crucial control step between neurogenin and neuroD. SRp38 may mediate one component of this control by maintaining splicing and translational silencing in undifferentiated neural cells.

Cloning and characterization of Xenopus Id4 reveals differing roles for Id genes

We have identified Xenopus Id4, a member of the Id (inhibitor of differentiation/DNA binding) class of helix-loop-helix proteins. Id factors dimerize with general bHLH factors, preventing their interaction with tissue-specific bHLH factors, to inhibit premature differentiation. The presence of several Id proteins could reflect simple redundancy in function, or more interestingly, might suggest different activities for these proteins. During embryonic development, Xenopus Id4 is expressed in a number of neural tissues, including Rohon-Beard neurons, olfactory placode, eye primordia, and the trigeminal ganglia. It is also expressed in other organs, such as the pronephros and liver primordium. As embryogenesis progresses, it is expressed in the migrating melanocytes and lateral line structures. We compare the expression of Id4 mRNA with that of Id2 and Id3 and find that the Id genes are expressed in complementary patterns during neurogenesis, myogenesis, kidney development, in the tailbud, and in the migrating neural crest. To examine the regulation of Id gene expression during Xenopus neural development, we show that expression of Id3 and Id4 can be induced by overexpression of BMP4 in the whole embryo and in ectodermal explants. Expression of Id2, Id3, and Id4 in these explants is unaffected by the expression of FGF-8 or a dominant-negative Ras (N17ras), suggesting that Id genes are not regulated by the FGF signaling pathway in naive ectoderm. We also show that Notch signaling can activate Id2 and Id3 expression in the whole embryo. In contrast, Id4 expression in the Rohon-Beard cells is inhibited by activated Notch and increased by a dominant-negative Delta. This may reflect an increase in Rohon-Beard cells in response to inhibition of Notch signaling rather than transcriptional regulation of Id4. Finally, to compare the activities of Id2, Id3, and Id4, we use animal cap explants and in vivo overexpression to show that Id proteins can differentially inhibit the activities of neurogenin and neuroD, both neurogenic bHLH molecules and MyoD, a myogenic bHLH protein. Id4 is able to inhibit the activity all these bHLH molecules, Id2 inhibits MyoD and neuroD, while Id3 blocks only neuroD activity in our assays.

Transcriptional regulation of the stem cell leukemia gene (SCL)--comparative analysis of five vertebrate SCL loci

The stem cell leukemia (SCL) gene encodes a bHLH transcription factor with a pivotal role in hematopoiesis and vasculogenesis and a pattern of expression that is highly conserved between mammals and zebrafish. Here we report the isolation and characterization of the zebrafish SCL locus together with the identification of three neighboring genes, IER5, MAP17, and MUPP1. This region spans 68 kb and comprises the longest zebrafish genomic sequence currently available for comparison with mammalian, chicken, and pufferfish sequences. Our data show conserved synteny between zebrafish and mammalian SCL and MAP17 loci, thus suggesting the likely genomic domain necessary for the conserved pattern of SCL expression. Long-range comparative sequence analysis/phylogenetic footprinting was used to identify noncoding conserved sequences representing candidate transcriptional regulatory elements. The SCL promoter/enhancer, exon 1, and the poly(A) region were highly conserved, but no homology to other known mouse SCL enhancers was detected in the zebrafish sequence. A combined homology/structure analysis of the poly(A) region predicted consistent structural features, suggesting a conserved functional role in mRNA regulation. Analysis of the SCL promoter/enhancer revealed five motifs, which were conserved from zebrafish to mammals, and each of which is essential for the appropriate pattern or level of SCL transcription.

Notch signaling is involved in the regulation of Id3 gene transcription during Xenopus embryogenesis

During Xenopus embryogenesis, XId3, a member of the Id helix-loop-helix protein family, is expressed in a large variety of differentiating tissues including epidermis, cement gland, brain, neural tube, neural crest cell derivatives, somites, and tailbud. Transcription of XId3 is mediated by several cis-regulatory elements including an enhancer of 440 bp located 870 bp upstream from the transcription initiation site. The enhancer activity in embryos was studied using transgenic methodology. A galactosidase reporter gene, driven by a regulatory element composed of the enhancer and a minimal promoter derived from the XId3 gene, was expressed in transgenic embryos with a profile that faithfully reproduced that of the endogenous XId3 gene. The pattern resulted from a synergistic effect between the enhancer and the promoter, and in vitro transactivation assays showed that transcription can be stimulated by Notch signaling. The presence of potential Su(H) binding sites, in both the enhancer and the promoter, suggests that these represent candidates for in vivo cis-regulatory elements. The data presented here suggest that Notch control of differentiation may involve activation of transcription of Id, a negative regulator of bHLH transcription factors.