RNA induction and inheritance of epigenetic cardiac hypertrophy in the mouse

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.     

Non-coding RNAs and diseases

With the completion of large scale genomic sequencing, a great number of non-conding RNAs (ncRNAs) have been discovered and capture the attention of the biological sciences community. All known ncRNAs may be divided into two groups, namely: i—small ncRNAs, which comprise microRNAs (miRNAs), PIWI-interacting RNAs (piRNAs) and short interfering RNAs (siRNAs), and ii—several thousands of long ncRNAs (lncRNAs). NcRNAs were shown to be involved in eukaryotic growth and development, cell proliferation and differentiation, apoptosis, epigenetic modifications, and also the complex control and pathogenesis of various diseases. In this paper, knowledge on the ncRNAs, which functioning is associated with human diseases, has been summarized.     

TGFβ superfamily signaling and uterine decidualization

Decidualization is an intricate biological process where extensive morphological, functional, and genetic changes take place in endometrial stromal cells to support the development of an implanting blastocyst. Deficiencies in decidualization are associated with pregnancy complications and reproductive diseases. Decidualization is coordinately regulated by steroid hormones, growth factors, and molecular and epigenetic mechanisms. Transforming growth factor β (TGFβ) superfamily signaling regulates multifaceted reproductive processes. However, the role of TGFβ signaling in uterine decidualization is poorly understood. Recent studies using the Cre-LoxP strategy have shed new light on the critical role of TGFβ signaling machinery in uterine decidualization. Herein, we focus on reviewing exciting findings from studies using both mouse genetics and in vitro cultured human endometrial stromal cells. We also delve into emerging mechanisms that underlie decidualization, such as non-coding RNAs and epigenetic modifications. We envision that future studies aimed at defining the interrelationship among TGFβ signaling circuitries and their potential interactions with epigenetic modifications/non-coding RNAs during uterine decidualization will open new avenues to treat pregnancy complications associated with decidualization deficiencies.     

Inherited variation at the epigenetic level: paramutation from the plant to the mouse

In contrast with a wide definition of the 'epigenetic variation', including all changes in gene expression that do not result from the alteration of the gene structure, a more restricted class had been defined, initially in plants, under the name 'paramutation'. It corresponds to epigenetic modifications distinct from the regulatory interactions of the cell differentiation pathways, mitotically stable and sexually transmitted with non-Mendelian patterns. This class of epigenetic changes appeared for some time restricted to the plant world, but examples progressively accumulated of epigenetic inheritance in organisms ranging from mice to humans. Occurrence of paramutation in the mouse and possible mechanisms were then established in the paradigmatic case of a mutant phenotype maintained and hereditarily transmitted by wild-type homozygotes. Together with the recent findings in plants indicative of a necessary step of RNA amplification in the reference maize paramutation, the mouse studies point to a new role of RNA, as an inducer and hereditary determinant of epigenetic variation. Given the known presence of a wide range of RNAs in human spermatozoa, as well as a number of unexplained cases of familial disease predisposition and transgenerational maintenance, speculations can be extended to possible roles of RNA-mediated inheritance in human biology and pathology.     

Non-coding RNAs, epigenetics and complexity

Several aspects of epigenetics are strongly linked to non-coding RNAs, especially small RNAs that can direct the cytosine methylation and histone modifications that are implicated in gene expression regulation in complex organisms. A fundamental characteristic of epigenetics is that the same genome can show alternative phenotypes, which are based in different epigenetic states. Some of the most studied complex epigenetic phenomena including transposon activity and silencing recently exemplified by piRNAs (piwi-interacting RNAs), position effect variegation, X-chromosome inactivation, parental imprinting, and paramutation have direct or indirect participation of an RNA component. Conceivably, most of the non-coding RNAs with no described function yet, are players in epigenetic mechanisms that are still not completely understood. In that regard, RNAs were recently implicated in new mechanisms of genetic information transfer in yeast, plants and mice. In this review article, the hypothesis that non-coding RNAs might be the main component of complex organisms acquired during evolution will be explored. The question of how evolutionary theories have been challenged by these molecules in association with epigenetic mechanisms will also be discussed here.     

Epigenetic-based therapy for colorectal cancer: Prospect and involved mechanisms

Epigenetic modifications are heritable variations in gene expression not encoded by the DNA sequence. According to reports, a large number of studies have been performed to characterize epigenetic modification during normal development and also in cancer. Epigenetics can be regarded more widely to contain all of the changes in expression of genes that make by adjusted interactions between the regulatory portions of DNA or messenger RNAs that lead to indirect variation in the DNA sequence. In the last decade, epigenetic modification importance in colorectal cancer (CRC) pathogenesis was demonstrated powerfully. Although developments in CRC therapy have been made in the last years, much work is required as it remains the second leading cause of cancer death. Nowadays, epigenetic programs and genetic change have pivotal roles in the CRC incidence as well as progression. While our knowledge about epigenetic mechanism in CRC is not comprehensive, selective histone modifications and resultant chromatin conformation together with DNA methylation most likely regulate CRC pathogenesis that involved genes expression. Undoubtedly, the advanced understanding of epigenetic-based gene expression regulation in the CRC is essential to make epigenetic drugs for CRC therapy. The major aim of this review is to deliver a summary of valuable results that represent evidence of principle for epigenetic-based therapeutic approaches employment in CRC with a focus on the advantages of epigenetic-based therapy in the inhibition of the CRC metastasis and proliferation.     

Regulation of micro-RNA,epigenetic factor by natural products for the treatment of cancers: Mechanistic insight and translational association

From onset to progression, cancer is a ailment that might take years to grow. All common epithelial malignancies, have a long latency period, frequently 20 years or more, different gene may contain uncountable mutations if they are clinically detectable. MicroRNAs (miRNAs) are around 22nt non-coding RNAs that control gene expression sequence-specifically through translational inhibition or messenger degradation of RNA (mRNA). Epigenetic processes of miRNA control genetic variants through genomic DNA methylation, post-translation histone modification, rework of the chromatin, and microRNAs. The field of miRNAs has opened a new era in understanding small non-coding RNAs since discovering their fundamental mechanisms of action. MiRNAs have been found in viruses, plants, and animals through molecular cloning and bioinformatics approaches. Phytochemicals can invert the epigenetic aberrations, a leading cause of the cancers of various organs, and act as an inhibitor of these changes. The advantage of phytochemicals is that they only function on cells that cause cancer without affecting normal cells. Phytochemicals appear to play a significant character in modulating miRNA expression, which is linked to variations in oncogenes, tumor suppressors, and cancer-derived protein production, according to several studies. In addition to standard anti-oxidant or anti-inflammatory properties, the initial epigenetic changes associated with cancer prevention may be modulated by many polyphenols. In correlation with miRNA and epigenetic factors to treat cancer some of the phytochemicals, including polyphenols, curcumin, resveratrol, indole-3-carbinol are studied in this article.     

精子sncRNAs在环境暴露相关跨代遗传中的作用

哺乳动物胚胎发育受遗传和表观遗传的共同调控.精子作为重要的雄性生殖细胞,通过受精过程,将这些信息传递给卵子,进而影响子代的发育.精子中携带有丰富的表观遗传信息,其中小非编码RNAs(small noncoding RNAs,sncRNAs)在精子发育不同阶段发挥重要的作用,包括调控基因表达、介导蛋白质翻译,以及参与精子...     

Hérédité et épigénétique: un rôle inattendu pour l’ARN

Although Mendel’s first laws explain the transmission of most characteristics, there has recently been a renewed interest in the notion that DNA is not the sole determinant of our inherited phenotype. Human epidemiology studies and animal and plant genetic studies have provided evidence that epigenetic information (“epigenetic” describes an inherited effect on chromosome or gene function that is not accompanied by any alteration of the nucleotide sequence) can be inherited from parents to offspring. Most of the mechanisms involved in epigenetic “memory” are paramutation events, which are heritable epigenetic changes in the phenotype of a “paramutable” allele. Initially demonstrated in plants, paramutation is defined as an interaction between two alleles of a single locus that results in heritable changes of one allele that is induced by the other. The authors describe an unexpected example of paramutation in the mouse revealed by a recent analysis of an epigenetic variation modulating expression of theKit locus. The progeny of hétérozygote intercrosses (carrying one mutant and one wild-type allele) showed persistence of the white patches (characteristic of hétérozygotes) in the homozygous Kit^+/+ progeny. The DNA sequences of the two wild-type alleles were structurally normal, revealing an epigenetic modification. Further investigations showed that RNA and microRNA, released by sperm, mediate this epigenetic inheritance. The molecular mechanisms involved in this unexpected mode of inheritance and the role of RNA molecules in the spermatozoon head as possible vectors for the hereditary transfer of such modifications — implying that paternal inheritance is not limited to just one haploid copy of the genome — are still a matter of debate. Paramutations may be considered to be one possibility of epigenetic modification in the case of familial disease predispositions not fully explained by Mendelian analysis.     

New lessons from random X-chromosome inactivation in the mouse

X-chromosome inactivation (XCI) ensures dosage compensation in mammals. Random XCI is a process where a single X chromosome is silenced in each cell of the epiblast of mouse female embryos. Operating at the level of an entire chromosome, XCI is a major paradigm for epigenetic processes. Here we review the most recent discoveries concerning the role of long noncoding RNAs, pluripotency factors, and chromosome structure in random XCI.     

Epigenetic gene regulation by noncoding RNAs

Functional noncoding RNAs have distinct roles in epigenetic gene regulation. Large RNAs have been shown to control gene expression from a single locus (Tsix RNA), from chromosomal regions (Air RNA), and from entire chromosomes (roX and Xist RNAs). These RNAs regulate genes in cis; although the Drosophila roX RNAs can also function in trans. The chromatin modifications mediated by these RNAs can increase or decrease gene expression. These results suggest that the primary role of RNA molecules in epigenetic gene regulation is to restrict chromatin modifications to particular regions of the genome. However, given that RNA has been shown to be at the catalytic core of other ribonucleoprotein complexes, it is also possible that RNA also plays a role in modulating changes in chromatin structure.     

Differential regulation of imprinting in the murine embryo and placenta by the Dlk1-Dio3 imprinting control region

Genomic imprinting is an epigenetic mechanism controlling parental-origin-specific gene expression. Perturbing the parental origin of the distal portion of mouse chromosome 12 causes alterations in the dosage of imprinted genes resulting in embryonic lethality and developmental abnormalities of both embryo and placenta. A 1 Mb imprinted domain identified on distal chromosome 12 contains three paternally expressed protein-coding genes and multiple non-coding RNA genes, including snoRNAs and microRNAs, expressed from the maternally inherited chromosome. An intergenic, parental-origin-specific differentially methylated region, the IG-DMR, which is unmethylated on the maternally inherited chromosome, is necessary for the repression of the paternally expressed protein-coding genes and for activation of the maternally expressed non-coding RNAs: its absence causes the maternal chromosome to behave like the paternally inherited one. Here, we characterise the developmental consequences of this epigenotype switch and compare these with phenotypes associated with paternal uniparental disomy of mouse chromosome 12. The results show that the embryonic defects described for uniparental disomy embryos can be attributed to this one cluster of imprinted genes on distal chromosome 12 and that these defects alone, and not the mutant placenta, can cause prenatal lethality. In the placenta, the absence of the IG-DMR has no phenotypic consequence. Loss of repression of the protein-coding genes occurs but the non-coding RNAs are not repressed on the maternally inherited chromosome. This indicates that the mechanism of action of the IG-DMR is different in the embryo and the placenta and suggests that the epigenetic control of imprinting differs in these two lineages.