The effect of oestradiol-17β on the ribonucleases and ribonuclease inhibitor of immature rat uterus

The cytoplasmic ribonuclease inhibitor/ribonuclease system has been detected in a wide variety of tissues and species. In most of the tissues studied, cytoplasmic ribonuclease is undetectable due to the presence of excess inhibitor. The observation that tissues with high levels of RNA/protein synthesis have high levels of free inhibitor has been taken to imply some essential role for the inhibitor in the control of protein synthesis. The precise nature of this regulatory function is however unknown. Studies on the enzyme associated with the inhibitor in vivo indicated that it was similar, but not identical to secretory pancreatic RNase A. Previous studies on the inhibitor/ribonuclease system of rat uterus revealed that free inhibitor was detectable in the uteri of immature rats, but disappeared after administration of oestrogen or during normal sexual maturation of the rat. The following studies were undertaken in order to determine the mechanism whereby oestrogen decreased inhibitor activity, and to gain a better understanding of the precise function of the inhibitor/ribonuclease system. The main points to emerge from these studies were as follows (i) Antiserum raised to purified rat liver inhibitor was used to quantitate total inhibitor levels in control, oestrogen-treated, and mature rat uteri. These studies revealed that inhibitor levels increased by up to 50% after hormone-treatment and normal development. It was therefore apparent that the loss of inhibitor activity was not due to reduced synthesis of the protein. (ii) Total and free ribonuclease activity was assayed, and revealed that the total activity increased by up to eight fold after oestrogen-treatment and during normal development. Free enzyme activity became detectable in uterine cytoplasm. Taken together, these results indicated that the loss of inhibitor activity arose through saturation by endogenous ribonuclease. (iii) Activity stain analysis of the uterine cytoplasmic ribonucleases revealed the presence of at least two distinct species with approximate molecular weights of 14,000 and 18,000. The activity of both of these species appeared to increase after oestrogen-treatment and during normal development. An attempt to detect and quantitate these enzymes using antiserum raised to bovine RNase A was not successful. (iv) A cDNA clone encoding rat pancreatic RNase A mRNA was obtained, and used in an attempt to detect the mRNA encoding the endogenous uterine enzymes. It was not possible to detect a clear cut example of an RNase A like mRNA in control or oestrogen-treated uterine RNA. These results did not however rule out the possibility that the uterine enzymes were induced at the transcriptional level by oestrogen. (v) A technique was developed whereby free inhibitor and inhibitor/ribonuclease complexes could be resolved on non- denaturing polyacrylamide gels, and subsequently detected by immunoblotting. These studies confirmed that the loss of inhibitor activity was due to saturation by endogenous enzyme. Furthermore, it was found that 5-6 distinct enzyme species or enzyme variants were present in the cytoplasm of oestrogen-treated uteri. The relative levels of these enzymes were found to differ in a variety of tissues analysed. Ferguson plot analysis revealed that they differed on the basis of charge, and to a lesser extent, molecular weight. (vi) The cytoplasmic ribonucleases of rat liver and mature rat uteri were purified using a relatively rapid procedure giving high yields. The different species were resolved to some extent using chromatography on heparin-sepharose. Thus, in rat liver one major and one minor species were resolved, (RLC I and RLC II), whilst in mature rat uteri three species were resolved, (RUC I, RUC II and RUC III). RLC I was shown to be homogeneous as determined by SDS-PAGE. Insufficient quantities of the other enzymes were available for similar analyses. The relative molecular weight of each activity was determined by activity staining. These studies revealed that each activity consisted of more than one distinct species or variant. It was assumed that heparin-sepharose chromatography did not completely resolve all of the species present. Tentative analysis indicated that the species RUC II and RUC III corresponded to the oestrogen-induced species. (vii) Some of the properties of the purified enzymes were compared. The enzymes were shown to differ on the basis of pH optima, kinetic parameters, and their relative activity towards the homopolymers Poly (u) and Poly (c) relative to yeast RNA. The aforementioned results are discussed in relation to the possible function of the inhibitor/ribonuclease system

Genome Environment Browser (GEB): a dynamic browser for visualising high-throughput experimental data in the context of genome features

<p>Abstract</p> <p>Background</p> <p>There is accumulating evidence that the milieu of repeat elements and other non-genic sequence features at a given chromosomal locus, here defined as the genome environment, can play an important role in regulating chromosomal processes such as transcription, replication and recombination. The availability of whole-genome sequences has allowed us to annotate the genome environment of any locus in detail. The development of genome wide experimental analyses of gene expression, chromatin modification and chromatin proteins means that it is now possible to identify potential links between chromosomal processes and the underlying genome environment. There is a need for novel bioinformatic tools that facilitate these studies.</p> <p>Results</p> <p>We developed the Genome Environment Browser (GEB) in order to visualise the integration of experimental data from large scale high throughput analyses with repeat sequence features that define the local genome environment. The browser has incorporated dynamic scales adjustable in real-time, which enables scanning of large regions of the genome as well as detailed investigation of local regions on the same page without the need to load new pages. The interface also accommodates a 2-dimensional display of repetitive features which vary substantially in size, such as LINE-1 repeats. Specific queries for preliminary quantitative analysis of genome features can also be formulated, results of which can be exported for further analysis.</p> <p>Conclusion</p> <p>The Genome Environment Browser is a versatile program which can be easily adapted for displaying all types of genome data with known genomic coordinates. It is currently available at <url>http://web.bioinformatics.ic.ac.uk/geb/</url>.</p

Structure and expression pattern of Oct4 gene are conserved in vole Microtus rossiaemeridionalis

<p>Abstract</p> <p>Background</p> <p>Oct4 is a POU-domain transcriptional factor which is essential for maintaining pluripotency in several mammalian species. The mouse, human, and bovine <it>Oct4 </it>orthologs display a high conservation of nucleotide sequence and genomic organization.</p> <p>Results</p> <p>Here we report an isolation of a common vole (<it>Microtus rossiaemeridionalis) Oct4 </it>ortholog. Organization and exon-intron structure of vole <it>Oct4 </it>gene are similar to the gene organization in other mammalian species. It consists of five exons and a regulatory region including the minimal promoter, proximal and distal enhancers. Promoter and regulatory regions of the vole <it>Oct4 </it>gene also display a high similarity to the corresponding regions of <it>Oct4 </it>in other mammalian species, and are active during the transient transfection within luciferase reporter constructs into mouse P19 embryonic carcinoma cells and TG-2a embryonic stem cells. The vole <it>Oct4 </it>gene expression is detectable starting from the morula stage and until day 17 of embryonic development.</p> <p>Conclusion</p> <p>Genomic organization of this gene and its intron-exon structure in vole are identical to those in all previously studied species: it comprises five exons and the regulatory region containing several conserved elements. The activity of the <it>Oct4 </it>gene in vole, as well as in mouse, is confined only to pluripotent cells.</p

Prion-like domains drive CIZ1 assembly formation at the inactive X chromosome

CIZ1 forms large assemblies at the inactive X chromosome (Xi) in female fibroblasts in an Xist lncRNA-dependent manner and is required for accurate maintenance of polycomb targets genome-wide. Here we address requirements for assembly formation and show that CIZ1 undergoes two direct interactions with Xist, via independent N- and C-terminal domains. Interaction with Xist, assembly at Xi, and complexity of self-assemblies formed in vitro are modulated by two alternatively spliced glutamine-rich prion-like domains (PLD1 and 2). PLD2 is dispensable for accumulation at existing CIZ1–Xi assemblies in wild-type cells but is required in CIZ1-null cells where targeting, assembly, and enrichment for H3K27me3 and H2AK119ub occur de novo. In contrast, PLD1 is required for both de novo assembly and accumulation at preexisting assemblies and, in vitro, drives formation of a stable fibrillar network. Together they impart affinity for RNA and a complex relationship with repeat E of Xist. These data show that alternative splicing of two PLDs modulates CIZ1’s ability to build large RNA–protein assemblies

A Dual Origin of the Xist Gene from a Protein-Coding Gene and a Set of Transposable Elements

X-chromosome inactivation, which occurs in female eutherian mammals is controlled by a complex X-linked locus termed the X-inactivation center (XIC). Previously it was proposed that genes of the XIC evolved, at least in part, as a result of pseudogenization of protein-coding genes. In this study we show that the key XIC gene Xist, which displays fragmentary homology to a protein-coding gene Lnx3, emerged de novo in early eutherians by integration of mobile elements which gave rise to simple tandem repeats. The Xist gene promoter region and four out of ten exons found in eutherians retain homology to exons of the Lnx3 gene. The remaining six Xist exons including those with simple tandem repeats detectable in their structure have similarity to different transposable elements. Integration of mobile elements into Xist accompanies the overall evolution of the gene and presumably continues in contemporary eutherian species. Additionally we showed that the combination of remnants of protein-coding sequences and mobile elements is not unique to the Xist gene and is found in other XIC genes producing non-coding nuclear RNA

Jarid2 binds mono-ubiquitylated H2A lysine 119 to mediate crosstalk between Polycomb complexes PRC1 and PRC2

The Polycomb repressive complexes PRC1 and PRC2 play a central role in developmental gene regulation in multicellular organisms. PRC1 and PRC2 modify chromatin by catalysing histone H2A lysine 119 ubiquitylation (H2AK119u1), and H3 lysine 27 methylation (H3K27me3), respectively. Reciprocal crosstalk between these modifications is critical for the formation of stable Polycomb domains at target gene loci. While the molecular mechanism for recognition of H3K27me3 by PRC1 is well defined, the interaction of PRC2 with H2AK119u1 is poorly understood. Here we demonstrate a critical role for the PRC2 cofactor Jarid2 in mediating the interaction of PRC2 with H2AK119u1. We identify a ubiquitin interaction motif at the amino-terminus of Jarid2, and demonstrate that this domain facilitates PRC2 localization to H2AK119u1 both in vivo and in vitro. Our findings ascribe a critical function to Jarid2 and define a key mechanism that links PRC1 and PRC2 in the establishment of Polycomb domains

Three-dimensional super-resolution microscopy of the inactive X chromosome territory reveals a collapse of its active nuclear compartment harboring distinct Xist RNA foci

Background: A Xist RNA decorated Barr body is the structural hallmark of the compacted inactive X territory in female mammals. Using super resolution three-dimensional structured illumination microscopy (3D-SIM) and quantitative image analysis, we compared its ultrastructure with active chromosome territories (CTs) in human and mouse somatic cells, and explored the spatio-temporal process of Barr body formation at onset of inactivation in early differentiating mouse embryonic stem cells (ESCs). Results: We demonstrate that all CTs are composed of structurally linked chromatin domain clusters (CDCs). In active CTs the periphery of CDCs harbors low-density chromatin enriched with transcriptionally competent markers, called the perichromatin region (PR). The PR borders on a contiguous channel system, the interchromatin compartment (IC), which starts at nuclear pores and pervades CTs. We propose that the PR and macromolecular complexes in IC channels together form the transcriptionally permissive active nuclear compartment (ANC). The Barr body differs from active CTs by a partially collapsed ANC with CDCs coming significantly closer together, although a rudimentary IC channel system connected to nuclear pores is maintained. Distinct Xist RNA foci, closely adjacent to the nuclear matrix scaffold attachment factor-A (SAF-A) localize throughout Xi along the rudimentary ANC. In early differentiating ESCs initial Xist RNA spreading precedes Barr body formation, which occurs concurrent with the subsequent exclusion of RNA polymerase II (RNAP II). Induction of a transgenic autosomal Xist RNA in a male ESC triggers the formation of an `autosomal Barr body' with less compacted chromatin and incomplete RNAP II exclusion. Conclusions: 3D-SIM provides experimental evidence for profound differences between the functional architecture of transcriptionally active CTs and the Barr body. Basic structural features of CT organization such as CDCs and IC channels are however still recognized, arguing against a uniform compaction of the Barr body at the nucleosome level. The localization of distinct Xist RNA foci at boundaries of the rudimentary ANC may be considered as snap-shots of a dynamic interaction with silenced genes. Enrichment of SAF-A within Xi territories and its close spatial association with Xist RNA suggests their cooperative function for structural organization of Xi

Independent mechanisms target SMCHD1 to trimethylated histone H3 lysine 9-modified chromatin and the inactive X chromosome

The chromosomal protein SMCHD1 plays an important role in epigenetic silencing at diverse loci, including the inactive X chromosome, imprinted genes, and the facioscapulohumeral muscular dystrophy locus. Although homology with canonical SMC family proteins suggests a role in chromosome organization, the mechanisms underlying SMCHD1 function and target site selection remain poorly understood. Here we show that SMCHD1 forms an active GHKL-ATPase homodimer, contrasting with canonical SMC complexes, which exist as tripartite ring structures. Electron microscopy analysis demonstrates that SMCHD1 homodimers structurally resemble prokaryotic condensins. We further show that the principal mechanism for chromatin loading of SMCHD1 involves an LRIF1-mediated interaction with HP1γ at trimethylated histone H3 lysine 9 (H3K9me3)-modified chromatin sites on the chromosome arms. A parallel pathway accounts for chromatin loading at a minority of sites, notably the inactive X chromosome. Together, our results provide key insights into SMCHD1 function and target site selection

The non-canonical SMC protein SmcHD1 antagonises TAD formation and compartmentalisation on the inactive X chromosome.

The inactive X chromosome (Xi) in female mammals adopts an atypical higher-order chromatin structure, manifested as a global loss of local topologically associated domains (TADs), A/B compartments and formation of two mega-domains. Here we demonstrate that the non-canonical SMC family protein, SmcHD1, which is important for gene silencing on Xi, contributes to this unique chromosome architecture. Specifically, allelic mapping of the transcriptome and epigenome in SmcHD1 mutant cells reveals the appearance of sub-megabase domains defined by gene activation, CpG hypermethylation and depletion of Polycomb-mediated H3K27me3. These domains, which correlate with sites of SmcHD1 enrichment on Xi in wild-type cells, additionally adopt features of active X chromosome higher-order chromosome architecture, including A/B compartments and partial restoration of TAD boundaries. Xi chromosome architecture changes also occurred following SmcHD1 knockout in a somatic cell model, but in this case, independent of Xi gene derepression. We conclude that SmcHD1 is a key factor in defining the unique chromosome architecture of Xi