Function of the Mouse PIWI Proteins and Biogenesis of Their piRNAs in the Male Germline

Beyret, Ergin

January 2009

<p>PIWI proteins belong to an evolutionary conserved protein family as the sister sub-family of ARGONAUTE (AGO) proteins. While AGO proteins are functionally well-characterized and shown to mediate small-RNA guided gene regulation, the function of PIWI proteins remain elusive. Here we pursued functional characterization of PIWI proteins by studying MILI and MIWI, two PIWI proteins in the mouse.</p><p>We first show that both MIWI and MILI co-immunoprecipitate with a novel class of non-coding small RNAs from the post-natal mouse testis extract, which are named Piwi-interacting RNAs (piRNAs). Our cloning efforts identified thousands of different piRNA sequences, mostly derived from intergenic regions. Interestingly, both MILI and MIWI piRNAs correspond to the same regions on the genome and differ primarily in length. We propose piRNAs in the adult testis are produced by the processing of long, single stranded RNA precursors, based on the observation that piRNAs originate in clusters from a number of sites on the genome in a head-to-tail homology. In support, we bioinformatically predicted putative promoters, and yeast one hybrid analysis on two such regions found out that they interact with Krueppel C2H2 type zinc finger transcription factors. We did not observe the features of the "ping-pong" mechanism in their biogenesis: Both MILI and MIWI piRNAs are biased for 5` Uracil without an Adenine bias on the 10th nucleotide position, and do not significantly consist of sequences complementary to each other along their first 10nt. Moreover, MILI piRNAs are not down-regulated in Miwi-/- testis. These results indicate that the post-natal testicular piRNAs are produced independent of the ping-pong mechanism. </p><p>Although piRNAs are highly complex, PAGE and in situ analyses showed that piRNAs are germ cell-specific with predominant expression in spermatocytes and round spermatids, suggestive of a meiotic function. Correspondingly, we found that Miwi-/-; Mili-/- mice undergo only male infertility with terminal spermatogenic arrest during meiosis. piRNAs show a nucleo-cytoplasmic distribution, with enrichment in the chromatoid and dense bodies, two male germ cell-specific structures. The dense body has been implicated in synapsis and in the heterochromatinization of the sex chromosomes during male meiosis, a process known as meiotic sex chromosome inactivation (MSCI). Our histological analysis on Miwi-/-; Mili-/- testes showed that, while the overall synapsis is not affected, the sex chromosomes retain the euchromatin marker acetyl-H4K16 and lacks the heterochromatin marker H3K9-dimethyl. These observations indicate that murine PIWI proteins are necessary for MSCI. Moreover, we identified piRNA production from the X chromosome before MSCI, and propose PIWI proteins utilize piRNAs to target and silence unpaired chromosomal regions during meiosis.</p> / Dissertation

Biology, Cell

Meiotic sex chromosome inactivation

Meiotic silencing of unpaired chromosome

piRNA

Piwi

small RNA

Spermatogenesis

Characterization of AtSUVR3 functions in Arabidopsis thaliana using RNA interference

Wang, Tao

15 May 2009

Variability of transgene expression levels resulting from gene silencing is considered as ahindrance to the successful application of plant genetic engineering. Towards alleviatinggene silencing, I decided to screen for novel genes involved in transgene silencing and toinvestigate how these genes regulate plant development. Genes encoding putative chromatinremodeling factors, especially those including a SET domain, were selected as candidatetargets. A bioinformatic analysis of the Arabidopsis SET genes (AtSET) was performed andthese genes were classified into 6 groups based on the domain architecture. RNA interference (RNAi) vectors were constructed for ~ 20 AtSET genes and wereintroduced into both wild type lines and transgenic lines silenced for a GFP reporter gene.Surprisingly, altered developmental phenotypes were only observed for three constructs,raising questions as to the effectiveness of the RNAi approach for the chosen Arabidopsissystem. To assess this situation, I targeted a phytoene desaturase (PDS) gene using the sameRNAi approach. Inactivation of PDS renders plant a readily identifiable phenotype. Whereasthe RNAi penetrance in Arabidopsis can be very high, the expressivity of RNAi in varioustissues and among different plants can vary dramatically. Contradictory to previous reports,I found that there is correlation between transcript level and silencing phenotype. Possiblereasons for this discrepancy are discussed. No apparent correlation between transgene copynumber and RNAi phenotypes was observed. Among the three RNAi constructs that caused an abnormal development inArabidopsis, K-23 which targets SuvR3 has the highest expressivity and could reactivate asilenced GFP locus. SuvR3 RNAi lines were selfed for six generations and were screenedfor morphological phenotypes. Abnormal number of flower organs, loss of viability of malegametophytes, and decreased seedling germination percentage were found in SuvR3 RNAilines. A progressive increase in both severity and frequency of abnormal phenotypes wereseen in subsequent generations, suggesting an epigenetic regulatory mechanism involvedwith SuvR3. Alternative splicing of SuvR3 was also observed in most of Arabidopsis tissues.One of the protein isoforms, SuvR3, lacks 16 amino acids within the highly conserved SETdomain. Possible effects of isoform interaction are proposed.

RNA interference

RNAi penetrance

RNAi expressivity

gene silencing

SET domain

alternative splicing

The Role of Chromatin Structure and Histone Modifications in Gene Silencing at the Ribosomal DNA Locus in Saccharomyces cerevisiae

Williamson, Kelly M.

2011 May 1900

One of the fundamental questions in science is how chromatin transitions from actively transcribed euchromatin to silent heterochromatin, and what factors affect this transition. One area of my research has focused on understanding the differences in the chromatin structure of active and silent regions in the ribosomal DNA locus (rDNA), a heterochromatin region in S. cerevisiae. Secondly, I have focused on understanding a histone methyltransferase Set1, which is involved in both euchromatin and heterochromatin regions. To distinguish actively transcribed open regions of chromatin from silent and closed regions of chromatin, we have expressed a DNA methyltransferase M.CviPI in vivo to utilize its accessibility to GpC sites. We have used this technique to study changes in nucleosome positioning within the NTS2 region of the rDNA in two cases: as a result of a silencing defect caused by the loss of Sir2, a histone deacetylase involved in silencing at the rDNA, and as an indicator of active transcription by RNA Pol I. Using this technique, we observed differences between open and closed chromatin structure by changes in nucleosome positioning within NTS2. Additionally, we have observed the presence of bound factors within the 35S rRNA gene promoter that are unique to actively transcribed genes. The second area of my research focused on the protein methyltransferase Set1 that mono-, di-, and trimethylates lysine 4 of histone H3 (H3K4) utilizing the methyl group from S-adenosyl methionine (SAM). Set1 is part of a multi protein complex called COMPASS (Complex associated with Set1), and is associated with both actively transcribed and silent regions. Thirty mutants of Set1 were made within the SET domain to learn more about the catalytic mechanism of Set1. The crystal structures of human SET domain proteins, as well as sequence alignments and a random mutagenesis of yeast Set1, were used to identify conserved amino acids in the SET domain of Set1. Mutants were analyzed for their effect on histone methylation in vivo, silencing of RNA Pol II transcription within the rDNA, suppression of ipl1-2, and COMPASS complex formation. Our results show that trimethylated H3K4 is required for silencing of RNA Pol II transcription at the rDNA. Overall, we have shown the importance of tyrosine residues in SET domain proteins. To summarize, my research has strived to understand chromatin structure and the factors that affect the transition between euchromatin and heterochromatin.

histone methylation

gene silencing

ribosomal DNA locus

chromatin structure

Saccharomyces cerevisiae

Challenges to women finding their voice : a case study of speaking up against sexual assault when the perpetrator is a federal judge / Case study of speaking up against sexual assault when the perpetrator is a federal judge

Poffinbarger, Sandra Rae

10 February 2012

Examining historical ideology of women’s position within society and how that socialization has influenced historical legal cases of gender inequality is the backdrop for a modern case study of sexual harassment and sexual assault. This thesis explores how women’s voices have been, and continue to be, silenced socially and legally through ages old ideology of women’s subordination to men. By examining a 2007 legal case of ongoing sexual harassment and sexual assault perpetrated by Federal Judge Samuel Kent against women in subordinate positions working within his courthouse it is demonstrated that socialization of gender inequality is stronger and slower to change than the laws prohibiting it. / text

Sexual harassment

Gendered power

Women's voices

Silencing of women

Feminism

Federal judge

Samuel Kent

Silencing of B cell activation factor gene and its implication in treating autoimmune arthritis

Lin, Yan-kai., 林欣佳.

January 2007

published_or_final_version / Medical Sciences / Master / Master of Medical Sciences

B cells.

Arthritis.

Gene silencing.

Autoimmune diseases - Treatment.

Epigenetic Silencing of ID4 in Prostate Cancer: Mechanistic Insight

Chinaranagari, Swathi

18 May 2015

Inhibitor of DNA binding/differentiation protein 4 (ID4) is a dominant negative regulator of basic helix loop helix (bHLH) family of transcription factors. ID4 shares the homology of HLH domain with other ID proteins (ID1, ID2, and ID3) and lack the basic DNA binding region. Evidence suggested that unlike ID1, ID2 and ID3, ID4 acts as a tumor suppressor in prostate cancer by attenuating cell proliferation and promoting apoptosis. Consistent with these observations ID4 is epigenetically silenced in DU145 prostate cancer cell line. In this study we investigated whether ID4 is also epigenetically silenced in prostate cancer. We also examined association between ID4 promoter hyper-methylation and its expression in prostate cancer cell lines. ID4 protein expression was analyzed in human prostate adenocarcinoma samples by Immunohistochemistry (IHC). ID4 promoter methylation pattern on prostate cancer cell lines was examined by methylation specific PCR. In addition, we performed methylation specific PCR on the human prostate tissues and genomic DNA to correlate cell line studies with clinical studies. IHC demonstrated decreased ID4 protein expression in human prostate tissue samples, whereas higher nuclear ID4 expression was found in normal prostate tissues. ID4 methylation specific PCR (MSP) on prostate cancer cell lines, showed ID4 methylation in DU145, but not in LNCaP and C33 cells. C81 and PC3 cells showed partial methylation. Increased ID4 methylation in C81 as compared to LNCaP suggests its epigenetic silencing as cells acquire androgen independence. Tumors with ID4 promoter hyper-methylation showed distinct loss of ID4 expression. However, the underlying mechanism involved in epigenetic silencing of ID4 is currently unknown. We hypothesized that ID4 promoter methylation is initiated by an EZH2 dependent tri-methylation of histone 3 at lysine 27 (H3K27Me3). ID4 expressing (LNCaP) and non-expressing (DU145 and C81) prostate cancer cell lines were used to investigate EZH2, H3K27Me3 and DNMT1 enrichment on ID4 promoter by Chromatin immuno-precipitation (ChIP). Increased enrichment of EZH2, H3K27Me3 and DNMT1 in DU145 and C81 cell lines was compared to ID4 expressing LNCaP cell line. Knockdown of EZH2 in DU145 cell line led to re-expression of ID4 and decrease in enrichment of EZH2, H3K27Me3 and DNMT1 demonstrating that ID4 is regulated in an EZH2 dependent manner. ChIP on prostate cancer tissue specimens and cell lines suggested EZH2 occupancy and H3K27Me3 marks on the ID4 promoter. Collectively, our data indicate a PRC2 dependent mechanism in ID4 promoter silencing in prostate cancer through recruitment of EZH2 and a corresponding increase in H3K27Me3. Increased EZH2, but decreased ID4 expression in prostate cancer strongly supports this model.

ID4

Epigenetic silencing

Prostate Cancer

Biology

Cancer Biology

Cell Biology

Genetics

Other Cell and Developmental Biology

A functional approach to profiling candidate genes in non model Brassicales

Mankowski, Peter J.

Unknown Date

No description available.

virus induced gene silencing

monosymmetry

heteroarthrocarpy

Brassicales

Brassiceae

Cleome

Cleomaceae

VIGS

floral symmetry

evolutionary development

Autophagy Regulates Expression of Argonaute 2, a Critical Regulator of the MicroRNA Silencing Pathway

Sibony, Michal

15 November 2013

Genome-wide association studies have implicated autophagy in Crohn’s Disease (CD) pathogenesis. The functional relevance of autophagy in CD remains unknown. I hypothesized that autophagy is involved in microRNA silencing, another process implicated in CD pathogenesis. MicroRNAs are short non-coding RNAs that are loaded onto RNA-induced silencing complex (RISC) and promote degradation and/or repress translation of target mRNAs. RISC formation and turnover occurs on endosomal membranes. Since autophagosomes and endosomes are closely related and RISC components are downstream effectors of microRNA silencing, I hypothesized that autophagy affects RISC, hence modulates microRNA expression. Using immunoblotting and immunofluorescence, I showed that Ago2, a critical component of RISC, is increased in cells with defective autophagy. Using microarray technology, I discovered 5 microRNAs that are differentially expressed in these cells. Taken together, my results propose a compelling mechanism by which autophagy regulates Ago2, thereby affects miRNA expression, which is implicated in the development of CD.

Autophagy

microRNA

Crohn's Disease

Argonaute 2

RNA-induced Silencing Complex

0719

Autophagy Regulates Expression of Argonaute 2, a Critical Regulator of the MicroRNA Silencing Pathway

Sibony, Michal

15 November 2013

Genome-wide association studies have implicated autophagy in Crohn’s Disease (CD) pathogenesis. The functional relevance of autophagy in CD remains unknown. I hypothesized that autophagy is involved in microRNA silencing, another process implicated in CD pathogenesis. MicroRNAs are short non-coding RNAs that are loaded onto RNA-induced silencing complex (RISC) and promote degradation and/or repress translation of target mRNAs. RISC formation and turnover occurs on endosomal membranes. Since autophagosomes and endosomes are closely related and RISC components are downstream effectors of microRNA silencing, I hypothesized that autophagy affects RISC, hence modulates microRNA expression. Using immunoblotting and immunofluorescence, I showed that Ago2, a critical component of RISC, is increased in cells with defective autophagy. Using microarray technology, I discovered 5 microRNAs that are differentially expressed in these cells. Taken together, my results propose a compelling mechanism by which autophagy regulates Ago2, thereby affects miRNA expression, which is implicated in the development of CD.

Autophagy

microRNA

Crohn's Disease

Argonaute 2

RNA-induced Silencing Complex

0719

EVOLUTIONARY PERSPECTIVE OF NICOTINE TO NORNICOTINE CONVERSION, ITS REGULATION AND CHARACTERIZATION OF EIN2 MEDIATED ETHYLENE SIGNALING IN TOBACCO

Chakrabarti, Manohar

01 January 2010

Nicotine, nornicotine, anabasine and anatabine are four major alkaloids in tobacco, of which nicotine is predominant. In many tobacco cultivars and also in other Nicotiana species, nicotine is converted to nornicotine, which in turn gives rise to potent carcinogen NNN. Nicotine to nornicotine conversion via nicotine-N-demethylation is mediated by the CYP82E family of P450 enzymes. Tobacco (Nicotiana tabacum) converts in senescing leaves, while its diploid progenitors N.tomentosiformis and N.sylvestris convert in both green and senescing and only in senescing leaves, respectively. Previously it has been shown that N.tomentosiformis has different active conversion loci in green and senescing leaves. The green leaf conversion enzyme CYP82E3 is inactivated in tobacco by a single amino acid substitution, while the senescing leaf converter enzyme CYP82E4 is active in tobacco, which gave tobacco a ‘senescing leaf converter’ phenotype. In nonconverter tobacco, CYP82E4 shows transcriptional silencing. The nicotine-N-demethylase gene NsylCYP82E2 involved in nicotine to nornicotine conversion in senesced leaves of N. sylvestris was isolated. NsylCYP82E2 is active in N. sylvestris, but it has become inactivated in tobacco through mutations causing two amino acid substitutions. The conversion factor from N.sylvestris was characterized and a model for the alkaloid profile evolution in the amphidiploid N.tabacum from its diploid progenitors was proposed. Regulation of conversion phenomenon was tested under different spatio-temporal conditions and various stresses. The promoter region for NtabCYP82E4 was isolated and promoter-reporter construct was used to determine that NtabCYP82E4 is specifically induced only during senescence. This pattern correlates with the nornicotine accumulation as measured by alkaloid profiling. Thus the regulatory regions of NtabCYP82E4 represent a senescence specific promoter. In another project functional characterization of tobacco EIN2 (NtabEIN2) was undertaken. EIN2 from tobacco and N.sylvestris were cloned, their genomic structure was deduced and NtabEIN2 was silenced using RNAi approach. Silenced plants showed significant delay in petal senescence and abscission; as well as anther dehiscence, pod maturation, pod size, seed yield and defense against tobacco hornworm. Mechanism of delayed petal senescence phenotype, including possible cross-talk with Auxin Response Factor 2 and potential involvement of tasiRNA3 were also investigated.

Nicotine to nornicotine conversion

Polyploidy and gene silencing

Senescence-associated-genes

Ethylene

EIN2

Plant Sciences