Myogenin is a muscle-specific transcription factor that can induce myogenesis in a variety of cell types in tissue culture. To test myogenin's role in vivo, mice homozygous for a targeted mutation in the myogenin gene were generated. These mice survive fetal development but die immediately after birth and show a severe reduction of all skeletal muscle. Myogenin-mutant mice differ from mice carrying mutations in genes for the related myogenic factors Myf5 and MyoD, which have no muscle defects. Myogenin is therefore essential for the development of functional skeletal muscle.
The zinc-finger transcription factor GATA-1 (previously known as GF-1, NF-E1 or Eryf 1 binds to GATA consensus elements in regulatory regions of the alpha- and beta-globin gene clusters and other erythroid cell-specific genes. Analysis of the effects of mutations in GATA-binding sites in cell culture and in binding assays in vitro, as well as transactivation studies with GATA-1 expression vectors in heterologous cells, have provided indirect evidence that this factor is involved in the activation of globin and other genes during erythroid cell maturation. GATA-1 is also expressed in megakaryocytes and mast cells, but not in other blood cell lineages or in non-haemopoietic cells. To investigate the role of this factor in haematopoiesis in vivo, we disrupted the X-linked GATA-1 gene by homologous recombination in a male (XY) murine embryonic stem cell line and tested the GATA-1-deficient cells for their ability to contribute to different tissues in chimaeric mice. The mutant embryonic stem cells contributed to all non-haemopoietic tissues tested and to a white blood cell fraction, but failed to give rise to mature red blood cells. This demonstrates that GATA-1 is required for the normal differentiation of erythroid cells, and that other GATA-binding proteins cannot compensate for its absence.
Comparative analysis of the sea urchin genome has broad implications for the primitive state of deuterostome host defense and the genetic underpinnings of immunity in vertebrates. The sea urchin has an unprecedented complexity of innate immune recognition receptors relative to other animal species yet characterized. These receptor genes include a vast repertoire of 222 Toll-like receptors, a superfamily of more than 200 NACHT domain-leucine-rich repeat proteins (similar to nucleotide-binding and oligomerization domain (NOD) and NALP proteins of vertebrates), and a large family of scavenger receptor cysteine-rich proteins. More typical numbers of genes encode other immune recognition factors. Homologs of important immune and hematopoietic regulators, many of which have previously been identified only from chordates, as well as genes that are critical in adaptive immunity of jawed vertebrates, also are present. The findings serve to underscore the dynamic utilization of receptors and the complexity of immune recognition that may be basal for deuterostomes and predicts features of the ancestral bilaterian form.
math5 is a murine orthologue of atonal, a bHLH proneural gene essential for the formation of photoreceptors and chordotonal organs in Drosophila. The expression of math5 coincides with the onset of retinal ganglion cell (RGC) differentiation. Targeted deletion of math5 blocks the initial differentiation of 80% of RGCs and results in an increase in differentiated amacrine cells. Furthermore, the absence of math5 abolishes the retinal expression of brn-3b and the formation of virtually all brn-3b-expressing RGCs. These results imply that math5 is a proneural gene essential for RGC differentiation and that math5 acts upstream to activate brn-3b-dependent differentiation processes in RGCs. The mammalian retina is the peripheral portion of the visual system containing six major neuronal cell types and one glial cell type organized in a laminar structure. The visual information process in the retina follows a general pathway from photoreceptors to bipolar cells to retinal ganglion cells (RGCs). Horizontal cells and amacrine cells act to mediate lateral interactions among photoreceptors, bipolar cells, and RGCs. The latter serve as the sole output neurons in the retina to send the visual information down the optic nerve to the rest of brain. Both birthdating experiments using 3 H-thymidine labeling and cell lineage analysis using retroviral and tracermediated approaches demonstrate that vertebrate retinal neurons are generated from common progenitors through sequential differentiation and ordered migration to form the laminar retinal structure (Cepko et al. 1996). Current models for retinal neuron differentiation suggest that the formation of a specific retinal neuron is determined by the intrinsic properties of the retinal progenitor and the extrinsic cues from the retinal environment (Cepko et al. 1996). Among the likely intrinsic factors, the basic helix-loop-helix (bHLH) class of proneural transcription factors appears to play an essential role in regulating the differentiation of retinal neurons (Cepko 1999). In Drosophila, expression of proneural genes of the achaete-scute complex (AS-C) and atonal (ato) in proneural clusters endow cells with neural competence (Jan and Jan 1993). Loss-of-function mutation of genes in AS-C causes the cells in the would-be proneural clusters to adopt epidermal fates rather than neuronal precursor fates. Conversely, gain-of-function mutations in the proneural genes leads to the ectopic formation of sensory neurons (Campuzano and Modolell 1992). The expression of ato is found in the optic furrow of the eye-antennal disc in addition to the ectodermal proneural clusters and sensory organ precursors, which give rise to the chordotonal organs. Deletion of ato causes the absence of the chordotonal organ and the lack of photoreceptors (Jarman et al. 1995), and the reduced expression of ato results in defects in axonal pathfinding of photoreceptors (White and Jarman 2000), suggesting that ato plays dual roles in determining neuronal potential and regulating specific neuronal differentiation...
SUMMARY Maintenance of skeletal muscle structure and function requires innervation by motor neurons, such that denervation causes muscle atrophy. We show that myogenin, an essential regulator of muscle development, controls neurogenic atrophy. Myogenin is up-regulated in skeletal muscle following denervation and regulates expression of the E3 ubiquitin ligases MuRF1 and atrogin-1, which promote muscle proteolysis and atrophy. Deletion of myogenin from adult mice diminishes expression of MuRF1 and atrogin-1 in denervated muscle and confers resistance to atrophy. Mice lacking histone deacetylases (HDACs) 4 and 5 in skeletal muscle fail to up-regulate myogenin and also preserve muscle mass following denervation. Conversely, forced expression of myogenin in skeletal muscle of HDAC mutant mice restores muscle atrophy following denervation. Thus, myogenin plays a dual role as both a regulator of muscle development and an inducer of neurogenic atrophy. These findings reveal a specific pathway for muscle wasting and potential therapeutic targets for this disorder.
Vascularization is essential for tissue development and in restoration of tissue integrity after an ischemic injury. In studies of vascularization, the focus has largely been placed on vascular endothelial growth factor (VEGF), yet other factors may also orchestrate this process. Here we show that succinate accumulates in the hypoxic retina of rodents and, via its cognate receptor G protein-coupled receptor-91 (GPR91), is a potent mediator of vessel growth in the settings of both normal retinal development and proliferative ischemic retinopathy. The effects of GPR91 are mediated by retinal ganglion neurons (RGCs), which, in response to increased succinate levels, regulate the production of numerous angiogenic factors including VEGF. Accordingly, succinate did not have proangiogenic effects in RGC-deficient rats. Our observations show a pathway of metabolite signaling where succinate, acting through GPR91, governs retinal angiogenesis and show the propensity of RGCs to act as sensors of ischemic stress. These findings provide a new therapeutic target for modulating revascularization.
Summary T-brain gene-2 (Tbr2) is specifically expressed in the intermediate (basal) progenitor cells (IPCs) of the developing cerebral cortex; however, its function in this biological context has so far been overlooked due to the early lethality of Tbr2 mutant embryos. Conditional ablation of Tbr2 in the developing forebrain resulted in the loss of IPCs and their differentiated progeny in mutant cortex. Intriguingly, early loss of IPCs led to a decrease in cortical surface expansion and thickness with a neuronal reduction observed in all cortical layers. These findings suggest that IPC progeny contribute to the correct morphogenesis of each cortical layer. Our observations were confirmed by tracing Tbr2+ IPC cell fate using Tbr2∷GFP transgenic mice. Finally, we demonstrated that misexpression of Tbr2 is sufficient to induce IPC identity in ventricular radial glial cells (RGCs). Together, these findings identify Tbr2 as a critical factor for the specification of IPCs during corticogenesis.
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