Epigenetic regulation shapes normal and pathological mammalian development and physiology. Our previous work showed that Kit RNAs injected into fertilized mouse eggs can produce heritable epigenetic defects, or paramutations, with relevant loss-of-function pigmentation phenotypes, which affect adult phenotypes in multiple succeeding generations of mice. Here, we illustrate the relevance of paramutation to pathophysiology by injecting fertilized mouse eggs with RNAs targeting Cdk9, a key regulator of cardiac growth. Microinjecting fragments of either the coding region or the related microRNA miR-1 led to high levels of expression of homologous RNA, resulting in an epigenetic defect, cardiac hypertrophy, whose efficient hereditary transmission correlated with the presence of miR-1 in the sperm nucleus. In this case, paramutation increased rather than decreased expression of Cdk9. These results highlight the diversity of RNA-mediated epigenetic effects and may provide a paradigm for clinical cases of familial diseases whose inheritance is not fully explained in Mendelian terms.
Highlights d p16 High senescence is a slow process that manifests around 10-12 months of age d p16 High cells in the liver of 12-month-old mice are LSECs and macrophages d Senescent p16 High LSECs are structurally and functionally important d Elimination of p16 High senescent cells induces liver and perivascular tissue fibrosis
The formation of intramyocardial blood vessels is critical for normal heart development and tissue repair after infarction. We report here expression of the Wilms' tumor gene-1, Wt1, in coronary vessels, which could contribute to the defective cardiac vascularization in Wt1 −/− mice. Furthermore, the high-affinity neurotrophin receptor TrkB, which is expressed in the epicardium and subepicardial blood vessels, was nearly absent from Wt1-deficient hearts. Activation of Wt1 in an inducible cell line significantly enhanced TrkB expression. The promoter of NTRK2, the gene encoding TrkB, was stimulated ∼10-fold by transient cotransfection of a Wt1 expression construct. The critical DNA-binding site for activation of the NTRK2 promoter by Wt1 was delineated by DNase I footprint analysis and electrophoretic mobility shift assay. Transgenic experiments revealed that the identified Wt1 consensus motif in the NTRK2 promoter was necessary to direct expression of a reporter gene to the epicardium and the developing vasculature of embryonic mouse hearts. Finally, mice with a disrupted Ntrk2 gene lacked a significant proportion of their intramyocardial blood vessels. These findings demonstrate that transcriptional activation of the TrkB neurotrophin receptor gene by the Wilms' tumor suppressor Wt1 is a crucial mechanism for normal vascularization of the developing heart.
The size of the mammalian body is determined by genetic and environmental factors differentially modulating pre-and postnatal growth. We now report a control of growth acting in the mouse from the first cleavages to the postnatal stages. It was evidenced by a hereditary epigenetic modification (paramutation) created by injection of a miR-124 microRNA into fertilized eggs. From the blastocyst to the adult, mouse pups born after microinjection of this miRNA showed a 30% increase in size. At the blastocyst stage, frequent duplication of the inner cell mass resulted in twin pregnancies. A role of sperm RNA as a transgenerational signal was confirmed by the giant phenotype of the progeny of transgenic males expressing miR-124 during spermiogenesis. In E2.5 to E8.5 embryos, increased levels of several transcripts with sequence homology to the microRNA were noted, including those of Sox9, a gene known for its crucial role in the progenitors of several adult tissues. A role in embryonic growth was confirmed by the large size of embryos expressing a Sox9 DNA transgene. Increased expression in the paramutants was not related to a change in miR-124 expression, but to the establishment of a distinct, heritable chromatin structure in the promoter region of Sox9. While the heritability of body size is not readily accounted for by Mendelian genetics, our results suggest the alternate model of RNAmediated heritable epigenetic modifications.
Abstract. NPHS1 encodes the structural protein nephrin, which has a crucial role in the filtration barrier of the glomerular podocyte. Mutations or deregulation of NPHS1 are associated with a variety of renal diseases, including the Finnish type congenital nephrotic syndrome. This study analyzed a potential regulation of nephrin by the Wilms' tumor protein, Wt1. Using an inducible U2OS osteosarcoma cell line, it is shown that upon Wt1 induction, endogenous nephrin mRNA becomes highly upregulated. Co-transfection studies demonstrate that Wt1 can activate the nephrin promoter Ͼ10-fold. DNase footprinting and mutation analysis identify a Wt1 responsive element in the nephrin promoter, which is required for the binding of Wt1 protein. Mutations or deletion of this Wt1 responsive element completely abolished transactivation of the nephrin promoter by Wt1. Moreover, transgenic analysis demonstrates the requirement of the identified binding site to direct podocyte-specific expression of a reporter gene in transgenic mice, thus confirming the importance of this site for the regulation of nephrin in vivo. Finally, it is shown that nephrin expression is lowest in kidneys of mice that lack specifically the Wt1(ϪKTS) splice variant, but in comparison with wild-type littermates, it is also reduced in animals with disruption of the Wt1(ϩKTS) splice variant. Taken together, these data identify nephrin as a direct transcriptional target for Wt1 and underline the importance of Wt1 as a key regulator in podocyte function.
Recent reports suggest that mammalian embryonic coronary endothelium (CoE) originates from the sinus venosus and ventricular endocardium. However, the contribution of extracardiac cells to CoE is thought to be minor and nonsignificant for coronary formation. Using classic (Wt1 Cre ) and previously undescribed (G2-Gata4 Cre ) transgenic mouse models for the study of coronary vascular development, we show that extracardiac septum transversum/ proepicardium (ST/PE)-derived endothelial cells are required for the formation of ventricular coronary arterio-venous vascular connections. Our results indicate that at least 20% of embryonic coronary arterial and capillary endothelial cells derive from the ST/PE compartment. Moreover, we show that conditional deletion of the ST/PE lineage-specific Wilms' tumor suppressor gene (Wt1) in the ST/PE ofG2-Gata4 Cre mice and in the endothelium of Tie2 Cre mice disrupts embryonic coronary transmural patterning, leading to embryonic death. Taken together, our results demonstrate that ST/PE-derived endothelial cells contribute significantly to and are required for proper coronary vascular morphogenesis.T he coronary vascular system, whose function is necessary to sustain late embryonic and postnatal cardiac function, is formed by a complex network of blood vessels, including arteries, arterioles, capillaries, venules, and veins (1). Recent reports indicate that various sources of endothelial cells contribute to the mammalian embryonic coronary system (2-4). However, the specific fate and function of these different endothelial cell pools during coronary vascular morphogenesis is the subject of intense controversy (5).Two endocardial populations have been reported to participate in the building of the embryonic coronary vascular system. The first derives from the sinus venosus endocardium, which sprouts to give rise to the nascent Apelin + coronary vasculature (2). A careful analysis of this study suggests that the sinus venosus endocardium, which is able to vascularize subepicardial and myocardial heart layers, mainly provides a cellular scaffold for the development of coronary veins (CoV). Accordingly, a second source of coronary endothelium (CoE) has been identified in the ventricular endocardium (Nfatc1 + lineage), which contributes massively to coronary arterial (CoA) endothelium (3, 6).A third disputed source of CoE is the proepicardium (PE), a structure that comprises epicardial progenitor cells. The PE protrudes from the septum transversum (ST), a folding of the lateral mesoderm that initiates the separation of thoracic and abdominal cavities in mammals (7). Although in vivo cell tracing and in vitro culture of avian PE cells clearly shows that PE cells can differentiate into CoE (8, 9), data from studies in mammals claimed the contribution of PE to CoE is minor (10-12). The so-called "epicardial" Cre constructs used in these studies are based on the expression of genes such as Gata5, Tbx18, or Wilms' tumor suppressor (Wt1) ( Table S1), all of which are expressed by both PE and...
contributed equally to this workThe Wilms' tumor gene Wt1 is known for its important functions during genitourinary and mesothelial formation. Here we show that Wt1 is necessary for neuronal development in the vertebrate retina. Mouse embryos with targeted disruption of Wt1 exhibit remarkably thinner retinas than age-matched wildtype animals. A large fraction of retinal ganglion cells is lost by apoptosis, and the growth of optic nerve ®bers is severely disturbed. Strikingly, expression of the class IV POU-domain transcription factor Pou4f2 (formerly Brn-3b), which is critical for the survival of most retinal ganglion cells, is lost in Wt1 ±/± retinas. Forced expression of Wt1 in cultured cells causes an up-regulation of Pou4f2 mRNA. Moreover, the Wt1(±KTS) splice variant can activate a reporter construct carrying 5¢-regulatory sequences of the human POU4F2. The lack of Pou4f2 and the ocular defects in Wt1 ±/± embryos are rescued by transgenic expression of a 280 kb yeast arti®cial chromosome carrying the human WT1 gene. Taken together, our ®ndings demonstrate a continuous requirement for Wt1 in normal retina formation with a critical role in Pou4f2-dependent ganglion cell differentiation.
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