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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

The transcriptional effects of the anti-oestrogen tamoxifen on the immature rat uterus

Waters, A. P. January 1982 (has links)
No description available.
2

Testis specific non-coding RNAs : Possible role in ALF regulation and piRNA production /

Patel, Bhavita H., January 2007 (has links)
Thesis (Ph.D.)--University of Texas at Dallas, 2007. / Includes vita. Includes bibliographical references (leaves 38-40)
3

Complex transcription units in Saccharomyces cerevisiae

Nguyen, Tania January 2013 (has links)
No description available.
4

Regulation of lineage specification of human embryonic stem cells by microRNAs and serum response factor

Ang, Lay Teng January 2013 (has links)
No description available.
5

Role of DNA supercoiling in genome structure and regulation

Corless, Samuel January 2014 (has links)
A principle challenge of modern biology is to understand how the human genome is organised and regulated within a nucleus. The field of chromatin biology has made significant progress in characterising how protein and DNA modifications reflect transcription and replication state. Recently our lab has shown that the human genome is organised into large domains of altered DNA helical twist, called DNA supercoiling domains, similar to the regulatory domains observed in prokaryotes. In my PhD I have analysed how the maintenance and distribution of DNA supercoiling relates to biological function in human cells. DNA supercoiling domains are set up and maintained by the balanced activity of RNA transcription and topoisomerase enzymes. RNA polymerase twists the DNA, over-winding in front of the polymerase and under-winding behind. In contrast topoisomerases relieve supercoiling from the genome by introducing transient nicks (topoisomerase I) or double strand breaks (topoisomerase II) into the double helix. Topoisomerase activity is critical for cell viability, but the distribution of topoisomerase I, IIα and IIβ in the human genome is not known. Using a chromatin immunoprecipitation (ChIP) approach I have shown that topoisomerases are enriched in large chromosomal domains, with distinct topoisomerase I and topoisomerase II domains. Topoisomerase I is correlated with RNA polymerase II, genes and underwound DNA, whereas topoisomerase IIα and IIβ are associated with each other and over-wound DNA. This indicates that different topoisomerase proteins operate in distinct regions of the genome and can be independently regulated depending on the genomic environment. Transcriptional regulation by DNA supercoiling is believed to occur through changes in gene promoter structure. To investigate DNA supercoiling my lab has developed biotinylated trimethylpsoralen (bTMP) as a DNA structure probe, which preferentially intercalates into under-wound DNA. Using bTMP in conjunction with microarrays my lab identified a transcription and topoisomerase dependent peak of under-wound DNA in a meta-analysis of several hundred genes (Naughton et al. (2013)). In a similar analysis, Kouzine et al. (2013) identified an under-wound promoter structure and proposed a model of topoisomerase distribution for the regulation of promoter DNA supercoiling. To better understand the role of supercoiling and topoisomerases at gene promoters, a much larger-scale analysis of these factors was required. I have analysed the distribution of bTMP at promoters genome wide, confirming a transcription and expression dependent distribution of DNA supercoils. DNA supercoiling is distinct at CpG island and non-CpG island promoters, and I present a model in which over-wound DNA limits transcription from both CpG island promoters and repressed genes. In addition, I have mapped by ChIP topoisomerase I and IIβ at gene promoters on chromosome 11 and identified a different distribution to that proposed by Kouzine et al. (2013), with topoisomerase I maintaining DNA supercoiling at highly expressed genes. This study provides the first comprehensive analysis of DNA supercoiling at promoters and identifies the relationship between supercoiling, topoisomerase distribution and gene expression. In addition to regulating transcription, DNA supercoiling and topoisomerases are important for genome stability. Several studies have suggested a link between DNA supercoiling and instability at common fragile sites (CFSs), which are normal structures in the genome that frequently break under replication stress and cancer. bTMP was used to measure DNA supercoiling across FRA3B and FRA16D CFSs, identifying a transition to a more over-wound DNA structure under conditions that induce chromosome fragility at these regions. Furthermore, topoisomerase I, IIα and IIβ showed a pronounced depletion in the vicinity of the FRA3B and FRA16D CFSs. This provides the first experimental evidence of a role for DNA supercoiling in fragile site formation.
6

Understanding early transcriptional events in Staphylococcus aureus infection

Lindemann, Claudia January 2017 (has links)
Staphylococcus aureus remains an important pathogen, which, due to its capability to develop antimicrobial resistance, imposes an increasing threat to human health. Developing preventive means to decrease disease burden is a major aim. However, the development of an S. aureus vaccine, which would be one strategy to achieve such goals, has been complicated through limited understanding of the bacterium's pathogenic mechanisms. This work uses four approaches to address these limitations: Firstly, a reproducible RNA sequencing based method for the determination of gene transcription by S. aureus in vivo during mammalian infection. Secondly, examination of the impact of the bacterial transcription regulator 'Rsp' on the bacterium, which shows that mutations in this gene have profound functional and transcriptional impacts. Thirdly, by examining the in vivo transcription of multiple S. aureus strains during infection, proposing a 'core in vivo transcriptome' of induced genes under the conditions tested. Some of these genes are known to be involved in pathogenesis, others are not completely characterised and may represent suitable vaccine antigens. Finally, this work addresses limited understanding of S. aureus pathogenesis through defining transcriptional changes in vivo, which are induced by an altered immune response in immunised hosts. Together, this body of work contributes to the understanding of S. aureus pathogenesis and provides candidate antigens for future vaccine development.
7

Elucidation Of Differential Role Of A Subunit Of RNA Polymerase II, Rpb4 In General And Stress Responsive Transcription In Saccharomyces Cerevisiae

Gaur, Jiyoti Verma 02 1900 (has links)
RNA polymerase II (Pol II) is the enzyme responsible for the synthesis of all mRNAs in eukaryotic cells. As the central component of the eukaryotic transcription machinery, Pol II is the final target of regulatory pathways. While the role for different Pol II associated proteins, co-activators and general transcription factors (GTFs) in regulation of transcription in response to different stimuli is well studied, a similar role for some subunits of the core Pol II is only now being recognized. The studies reported in this thesis address the role of the fourth largest subunit of Pol II, Rpb4, in transcription and stress response using Saccharomyces cerevisiae as the model system. Rpb4 is closely associated with another smaller subunit, Rpb7 and forms a dissociable complex (Edwards et al., 1991). The rpb4 null mutant is viable but is unable to survive at extreme temperatures (>34ºC and <12ºC) (Woychik and Young, 1989). This mutant has also been shown to be defective in activated transcription and unable to respond properly in several stress conditions (Pillai et al., 2001; Sampath and Sadhale, 2005). In spite of wealth of available information, the exact role of Rpb4 remains poorly understood. In the present work, we have used genetic, molecular and biochemical approaches to understand the role of Rpb4 as described in four different parts below: i) Studies on Genetic and Functional Interactions of Rpb4 with SAGA/TFIID Complex to Confer Promoter- Specific Transcriptional Control To carry out transcription, Pol II has to depend on several general transcription factors, mediators, activators, and co-activators and chromatin remodeling complexes. In the present study, we tried to understand the genetic and functional relationship of Rpb4 with some of the components of transcription machinery, which will provide some insight into the role of Rpb4 during transcription. Our microarray analysis of rpb4∆ strain suggests that down regulated genes show significant overlap with genes regulated by the SAGA complex, a complex functionally related to TFIID and involved in regulation of the stress dependent genes. The analysis of combination of double deletion mutants of either the SAGA complex subunits or the TFIID complex with rpb4∆ showed that both these double mutants are extremely slow growing and show synthetic growth phenotype. Further studies, including microarray analysis of these double mutants and ChIP (chromatin immunoprecipitation) of Rpb4 and SAGA complex, suggested that Rpb4 functions together with SAGA complex to regulate the expression of stress dependent genes. ii) Study of Genome Wide Recruitment of Rpb4 and Evidence for its Role in Transcription Elongation Biochemical studies have shown that Rpb4 associates sub-stoichiometrically with the core RNA polymerase during log phase but whether recruitment of Rpb4 is promoter context dependent or occurs only at specific stage of transcription remains largely unknown. Having discovered that Rpb4 can recruit on both TFIID and SAGA dominated promoters, it was important to study the genome wide role of Rpb4. Using ChIP on chip experiments, we have carried out a systematic assessment of genome wide binding of Rpb4 as compared to the core Pol II subunit, Rpb3. Our analysis showed that Rpb4 is recruited on coding regions of most transcriptionally active genes similar to the core Pol II subunit Rpb3 albeit to a lesser extent. This extent of Rpb4 recruitment increased on the coding regions of long genes pointing towards a role of Rpb4 in transcription elongation of long genes. Further studies showing transcription defect of long and GC rich genes, 6-azauracil sensitivity and defective PUR5 gene expression in rpb4∆ mutant supported the in vivo evidence of the role of Rpb4 in transcription elongation. iii) Genome Wide Expression Profiling and RNA Polymerase II Recruitment in rpb4∆ Mutant in Non-Stress and Stress Conditions Structural studies have suggested a role of Rpb4/Rpb7 sub-complex in recruitment of different factors involved in transcription (Armache et al., 2003; Bushnell and Kornberg, 2003). Though only few studies have supported this aspect of Rpb4/Rpb7 sub-complex, more research needs to be directed to explore this role of Rpb4/Rpb7 sub-complex. To study if Rpb4 has any role in recruitment of Pol II under different growth conditions, we have studied genome wide recruitment of Pol II in the presence and absence of Rpb4 during growth in normal rich medium as well as under stress conditions like heat shock and stationary phase where Rpb4 is shown to be indispensable for survival. Our analysis showed that absence of Rpb4 results in overall reduced recruitment of Pol II in moderate condition but this reduction was more pronounced during heat shock condition. During stationary phase where overall recruitment of Pol II also goes down in wild type cells, absence of Rpb4 did not lead to further decrease in overall recruitment. Interestingly, increased expression levels of many genes in the absence of Rpb4 did not show concomitant increase in the recruitment of Pol II, suggesting that Rpb4 might regulate these genes at a post-transcriptional step. iv) Role of Rpb4 in Pseudohyphal Growth The budding yeast S. cerevisiae can initiate distinct developmental programs depending on the presence of various nutrients. In response to nitrogen starvation, diploid yeast undergoes a dimorphic transition to filamentous pseudohyphal growth, which is regulated through cAMP-PKA and MAP kinase pathways. Previous work from our group has shown that rpb4∆ strain shows predisposed pseudohyphal morphology (Pillai et al., 2003), but how Rpb4 regulates this differentiation program is yet to be established. In the present study, we found that disruption of Rpb4 leads to enhanced pseudohyphal growth, which is independent of nutritional status. We observed that the rpb4∆/ rpb4∆ cells exhibit pseudohyphae even in the absence of a functional MAP kinase and cAMP-PKA pathways. Genome wide expression profile showed that several downstream genes of RAM signaling pathway were down regulated in rpb4∆ cells. Our detailed genetic analysis further supported the hypothesis that down regulation of RAM pathway might be leading to the pseudohyphal morphogenesis in rpb4∆ cells.
8

Study Of Rpb4, A Component Of RNA Polymerase II As A Coordinator Of Transcription Initiation And Elongation In S. Cerevisiae

Deshpande, Swati January 2013 (has links) (PDF)
RNA polymerase II (Pol II) is the enzyme responsible for the synthesis of all mRNAs in eukaryotic cells. As the central component of the eukaryotic transcription machinery, Pol II is the final target of transcription regulatory pathways. While the role for different Pol II associated proteins, co-activators and general transcription factors (GTFs) in regulation of transcription in response to different stimuli is well studied, a similar role for some subunits of the core Pol II is only now being recognized. The studies reported in this thesis address the role of the fourth largest subunit of Pol II, Rpb4, in transcription and stress response using Saccharomyces cerevisiae as the model system. Rpb4 is closely associated with another smaller subunit, Rpb7 and forms a dissociable complex (Edwards et al. 1991). The rpb4 null mutant is viable but is unable to survive at extreme temperatures (>34ºC and <12ºC) (Woychik and Young, 1989). This mutant has also been shown to be defective in activated transcription and unable to respond adequately to several stress conditions (Pillai et al. 2001; Sampath and Sadhale, 2005). In spite of wealth of available information, the exact role of Rpb4 in transcription process remains poorly understood. In the present work, we have used genetic, molecular and biochemical approaches to understand the role of Rpb4 as described in three different parts below: I. Role of Rpb4 in various pathways related to Transcription Elongation The genome-wide recruitment study of RNA pol II in presence and absence of Rpb4 has indicated role of Rpb4 in transcription elongation (Verma-Gaur et al. 2008). However, a recent proteomics based report has argued against it (Mosley et al. 2013). To address this conflict and understand Rpb4 functions, we monitored recruitment of RNA pol II on a few individual long genes in wild type and rpb4∆ cells. It was observed that RNA pol II recruitment on genes with longer coding regions is not significantly affected in rpb4∆ as compared to wild type thus ruling out role of Rpb4 in transcription elongation of these genes. However, our genetic interaction studies have shown a strong interaction (synthetic lethality) between RPB4 and the PAF1 and SPT4 genes, the products of which code for well-known transcription elongation factors. The studies based on Rpb4 overexpression in mutants for elongation factors, 6-Azauracil sensitivity of cells, effect of Dst1 overexpression in rpb4∆ cells and mitotic recombination rate in rpb4∆ cells have indicated functional interactions of Rpb4 with many of the transcription elongation factors. II. Studies on Genetic and Functional Interactions of Rpb4 with SAGA Complex in Promoter- Specific Transcription Initiation To carry out transcription, RNA pol II depends on several general transcription factors, mediators, activators, co-activators and chromatin remodeling complexes. In the present study, we explored the genetic and functional relationships between Rpb4 and the SAGA complex of transcription machinery, to gain some insight on the role of Rpb4 during transcription. Our chromatin immunoprecipitation data suggest that RNA pol II does not associate with promoters of heat shock genes during transcription activation of these heat stress induced genes in absence of Rpb4. SAGA coactivator complex is required for RNA pol II recruitment and transcription activation of these genes (Zanton and Pugh, 2004). However, recruitment of the SAGA complex at promoters of these heat shock genes was not affected in rpb4∆ cells after heat stress. Our genetic interaction analysis between RPB4 and components of SAGA complex (spt20∆) showed synthetic lethality indicating that fully functional Rpb4 and SAGA complex are required for cellular functions in the absence of heat stress and the simultaneous deletion of factors in the two complexes leads to cell death. III. Role of Rpb4 in phosphorylation cycles of Rpb1-CTD The C-Terminal Domain (CTD) of Rpb1 protein of RNA pol II undergoes several rounds of phosphorylation cycles at Ser-2 and Ser-5 residues on its heptad repeats during transcription. These phosphorylation marks are to be erased before the start of next round of transcription. Using protein pull down assay, we observed that hyperphosphorylated form of Rpb1 is reduced in rpb4∆ as compared to that seen in wild type cells among the free RNA pol II molecules. The level of Rpb2 protein was unaffected in both wild type and rpb4∆. These preliminary data hints at role of Rpb4 in the regulation of Rpb1 phosphorylation.
9

Podjednotka delta bakteriální RNA polymerázy a její role v regulaci genové exprese u Bacillus subtilis / delta subunit of bacterial RNA pol and its role in regulation of gene expression in B. subtilis

Dvořáček, Lukáš January 2010 (has links)
Delta subunit of bacterial RNA pol and its role in regulation of gene expression in B. subtilis. In this work I focus on regulation of eubacterial gene expression. First, I describe recent knowledge about a key stage of gene expression - transcription, focusing on regulation of trancription iniciation via small effector molecules (guanosine tetraphosphate, initiating nucleoside triphosphate) that are important for the regulation of ribosomal RNA. Second, in the experimental part of my work, I focus on the role of the _ protein, a subunit of RNA polymarase in gram positive bacteria, in transcription iniciation and its effects on regulation of RNA polymerase by the concentration of initiating nucleoside triphosphates.
10

Design and Application of Temperature Sensitive Mutants in Essential Factors of RNA Splicing and RNA Interference Pathway in Schizosaccharomyces Pombe

Nagampalli, Vijay Krishna January 2014 (has links) (PDF)
Gene deletions are a powerful method to uncover the cellular functions of a given gene in living systems. A limitation to this methodology is that it is not applicable to essential genes. Even for non-essential genes, gene knockouts cause complete absence of gene product thereby limiting genetic analysis of the biological pathway. Alternatives to gene deletions are mutants that are conditional, for e.g, temperature sensitive (ts) mutants are robust tools to understand temporal and spatial functions of genes. By definition, products of such mutants have near normal activity at a lower temperature or near-optimal growth temperature which is called as the permissive temperature and reduced activity at a higher, non-optimal temperature called as the non-permissive temperature. Generation of ts alleles in genes of interest is often time consuming as it requires screening a large population of mutants to identify those that are conditional. Often many essential proteins do not yield ts such alleles even after saturation mutagenesis and extensive screening (Harris et al., 1992; Varadarajan et al., 1996). The limited availability of such mutants in many essential genes prompted us to adopt a biophysical approach to design temperature-sensitive missense mutants in an essential gene of fission yeast. Several studies report that mutations in buried or solvent-inaccessible amino acids cause extensive changes in the thermal stability of proteins and specific substitutions create temperature-sensitive mutants (Rennell et al., 1991; Sandberg et al., 1995). We used the above approach to generate conditional mutants in the fission yeast gene spprp18+encoding an essential predicted second splicing factor based on its homology with human and S. cerevisiae proteins. We have used a missense mutant coupled with a conditional expression system to elucidate the cellular functions of spprp18+. Further, we have employed the same biophysical principle to generate a missense mutant in spago1+ RNA silencing factor that is non-essential for viability but has critical functions in the RNAi pathway of fission yeast. Fission yeast pre-mRNA splicing: cellular functions for the protein factor SpPrp18 Pre-mRNA splicing is an evolutionarily conserved process that excises introns from nascent transcripts. Splicing reactions are catalyzed by the large ribonuclear protein machinery called the spliceosome and occur by two invariant trans-esterification reactions (reviewed in Ruby and Abelson, 1991; Moore et al., 1993). The RNA-RNA, RNA–protein and protein-protein interactions in an assembly of such a large protein complex are numerous and highly dynamic in nature. These interactions in in vitro splicing reactions show ordered recruitment of essential small nuclear ribonucleic particles snRNPs and non–snRNP components on pre-mRNA cis-elements. Further these trans acting factors recognize and poise the catalytic sites in proximity to identify and excise introns. The precision of the process is remarkable given the diversity in architecture for exons and introns in eukaryotic genes (reviewed in Burge et al., 1999; Will and Luhrmann, 2006). Many spliceosomal protein components are conserved across various organisms, yet introns have diverse features with large variations in primary sequence. We hypothesize that co-evolution of splicing factor functions occurs with changes in gene and intron architectures and argue for alternative spliceosomal interactions for spliceosomal proteins that thus enabling splicing of the divergent introns. In vitro biochemical and genetic studies in S. cerevisiae and biochemical studies with human cell lines have indicated that ScPRP18 and its human homolog hPRP18 function during the second catalytic reaction. In S. cerevisiae, ScPrp18 is non-essential for viability at growth temperatures <30°C (Vijayraghavan et al., 1989; Vijayraghavan and Abelson, 1990; Horowitz and Abelson, 1993b). The concerted action of ScSlu7 - ScPrp18 heteromeric complex is essential for proper 3’ss definition during the second catalytic reaction (Zhang and Schwer, 1997; James et al., 2002). These in vitro studies also hinted at a possible intron -specific requirement for ScPrp18 and ScSlu7 factors as they were dispensable for splicing of intron variants made in modified ACT1 intron containing transcripts (Brys and Schwer, 1996; Zhang and Schwer, 1997). A short spacing distance between branch point adenosine to 3’splice site rendered the substrate independent of Prp18 and Slu7 for the second step (Brys and Schwer, 1996; Zhang and Schwer, 1997). Extensive mutational analyses of budding yeast ScPrp18 identified two functional domains and suggested separate roles during splicing (Bacikova and Horowitz, 2002; James et al., 2002). Fission yeast with its genome harboring multiple introns and degenerate splice signals has recently emerged as a unique model to study relationships between splicing factors and their role in genomes with short introns. Previously, studies in our lab had initiated genetic and mutational analysis of S. pombe Prp18, the predicted homolog of budding yeast Prp18. Genetic analysis showed its essentiality, but a set of missense mutants based on studies of budding yeast ScPrp18 (Bacikova and Horowitz, 2002) gave either inactive null or entirely wild type phenotype for the fission yeast protein. In this study, we have extended our previous mutational analysis of fission yeast Prp18 by adopting biophysical and computational approaches to generate temperature-sensitive mutants. A missense mutant was used to understand the splicing functions and interactions of SpPrp18 and the findings are summarized below. Fission yeast SpPrp18 is an essential splicing factor with transcript-specific functions and links efficient splicing with cell cycle progression We initiated our analysis of SpPrp18 by adopting a biophysical approach to generate ts mutants. We used the PREDBUR algorithm to predict a set of buried residues, which when mutated could result in a temperature-sensitive phenotype that complements the null allele at permissive temperature. These predictions are based upon two biophysical properties of amino acids: 1) Hydrophobicity, which is calculated in a window of seven amino acids 2) Hydrophobic moment, which is calculated in a sliding window of nine amino acids in a given protein sequence. Several studies correlate these properties to protein stability and function (Varadarajan et al., 1996). One of the buried residue mutants V194R, in helix 1 of SpPrp18 conferred weak temperature- sensitivity and strong cold-sensitivity even when the protein was over expressed from a plasmid. Through semi-quantitative RT-PCR we showed splicing-defects for tfIId+ intron1 in these cells even when grown at permissive temperature. The primary phenotype was the accumulation of pre-mRNA. Further, we showed this splicing arrest is co-related with reduced levels of SpPrp18 protein, linking protein stability and splicing function. Next we examined the effects of this mutation on function by further reduction of protein levels. This was done by integrating the expression cassette nmt81:spprp18+/spprp18V194R at the leu1 chromosomal locus and by metabolic depletion of the integrated allele. Through RT-PCRs we demonstrated that depletion of wild type or missense protein has intron specific splicing defects. These findings showed its non-global and possibly substrate-specific splicing function. In the affected introns, precursor accumulation is the major phenotype, confirming prior data from our lab that hinted at its likely early splicing role. This contrasts with the second step splicing role of the human or budding yeast Prp18 proteins. Previous data from our lab showed loss of physical interaction between SpPrp18 and SpSlu7 by co-immunoprecipitation studies. This again differs from the strong and functionally important ScPrp18 and ScSlu7 interaction seen in budding yeast. We show the absence of charged residues in SpSlu7 interaction region formed by SpPrp18 helix1 and helix2 which can explain the altered associations for SpPrp18 in fission yeast. Importantly, as the V194R mutation in helix 1 shows splicing defects even at permissive temperature, the data indicate a critical role for helix 1 for splicing interactions, possibly one that bridges or stabilizes the proposed weak association of SpPrp18-SpSlu7 with a yet unknown splicing factor. We also investigated the effects of mutations in other helices; surprisingly we recovered only mutations with very subtle growth phenotypes and very mild splicing defects. Not surprisingly, stop codon at L239 residue predicted to form a truncated protein lacking helices 3, 4 and 5 conferred recessive but null phenotype implicating essential functions for other helices. Other amino acid substitutions at L239 position had near wild type phenotype at 30°C and 37°C. Helix 3 buried residue mutant I259A conferred strong cold-sensitivity when over expressed from plasmid, but semi quantitative analysis indicated no splicing defects for intron1 in the constitutively expressed transcript tfIId+. These findings indicate cold sensitivity either arises due to compromised splicing of yet unknown transcripts or that over-expressed protein has near wild type activity. We find mutations in the helix 5 buried residues L324 also conferred near WT phenotype. Earlier studies in the lab found that substitution of surface residues KR that are in helix 5 with alanine lead to null phenotypes (Piyush Khandelia and Usha Vijayraghavan unpublished data). We report stable expression of all of these mutant proteins; L239A, L239P, L239G, I259A, I259V, L324F, L324A as determined by our immunoblot analysis at 30°C and 37°C. The mild phenotypes of many buried residues can be attributed to orientation of their functional groups into a protein cavity between the helices. Lastly, our microscopic cellular and biochemical analysis of cellular phenotypes of spprp18 mutant provided a novel and direct role of this factor in G1-S transition of cell cycle. Our RT-PCR data suggest spprp18+ is required for efficient splicing of several intron containing transcripts involved in G1-S transition and subsequent activation of MBF complex (MluI cell cycle box-binding factor complex) during S-phase and shows a mechanistic link between cell cycle progression and splicing. A tool to study links between RNA interference, centromeric non-coding RNA transcription and heterochromatin formation S.pombe possesses fully functional RNA interference machinery with a single copy for essential RNAi genes ago1+, dcr1+ and rdp1+. Deletion of any of these genes causes loss of heterochromatinzation with abnormal cytokinesis, cell-cycle deregulation and mating defects (Volpe et al., 2002). In S.pombe, exogenous or endogenously generated dsRNA’s from transcription of centromeric repeats are processed by the RNaseIII enzyme dicer to form siRNA. These siRNA’s are loaded in Ago1 to form minimal RNA induced silencing complex (RISC) complex or specialized transcription machinery complex RNA induced transcriptional silencing (RITS) complex and target chromatin or complementary mRNAs for silencing. Thus as in other eukaryotes, fission yeast cells deploy RNAi mediated silencing machinery to regulate gene-expression and influence chromatin status. Several recent studies point to emerging new roles of RNAi and its association with other RNA processes (Woolcock et al., 2011; Bayane et al., 2008; Kallgren et al., 2014). Many recent reports suggest physical interactions of RISC or RITS and RNA dependent RNA polymerase complex (RDRC) with either some factors of the spliceosomal machinery, heterochromatin machinery (CLRC complex) and the exosome mediated RNA degradation machinery (Bayne et al., 2008 and Chinen et al., 2010 ; Hiriart et al., 2012; Buhler et al., 2008; Bayne et al., 2010 ). Thus we presume conditional alleles in spago1+ will facilitate future studies to probe the genetic network between these complexes as most analyses thus far rely on ago1∆ allele or have been based on proteomic pull down analyses of RISC or RITS complexes. In this study, we employed biophysical and modeling approaches described earlier to generate temperature sensitive mutants in spago1+ and spdcr1+. We tested several mutants for their ability to repress two reporter genes in a conditional manner. Our modeling studies on SpAgo1 PAZ domain indicated structural similarities with human Ago1 PAZ domain. We created site-directed missense mutants at predicted buried residues or in catalytic residues. We also analyzed the effects of random amino acid replacements in specific predicted buried or catalytic residues of SpAgoI. These ago1 mutants were screened as pools for their effects on silencing of GFP or of ura4+ reporter genes. These assays assessed post transcriptional gene silencing (PTGS) or transcriptional gene silencing (TGS) activity of these mutants. We obtained three temperature sensitive SpAgo1 mutants V324G, V324S and L215V while the V324E replacement was a null allele. Based upon our modeling, a likely explanation for the phenotype of these mutants is structural distortion or mis-orientation of the functional groups caused due to these mutations, which affect activity in a temperature dependent manner. This distortion in the PAZ domain may affect binding of siRNA and thereby lead to heterochromatin formation defects that we observed. Our data on the SpAgo1 V324 mutant shows conditional centromeric heterochromatin formation confirmed by semi quantitative RT-PCR for dh transcripts levels that shows temperature dependent increase in these transcripts. We find reduced H3K9Me2 levels at dh locus by chromatin immunoprecipitation (ChIP) assay, linking the association of siRNAs for establishment of heterochromatin at this loci. The data on PTGS of GFP transcripts show SpAgo1 V324G mutation has decreased slicing activity as semi-quantitative RT-PCR for GFP transcripts show increased levels at non permissive temperature. These studies point out the importance of siRNA binding to the PAZ domain and its effect on slicing activity of SpAgo1. The mutations in Y292 showed residue loss of centromeric heterochromatin formation phenotype. Thus, we ascribe critical siRNA binding and 3’ end recognition functions to this residue of SpAgo1. These studies point out functional and structural conservation across hAgo1 and SpAgo1. Adopting the aforementioned biophysical mutational approach, we generated mutants in spdcr1+ and screened for those with conditional activity. Our modeling studies on SpDcr1 helicase domain shows it adopts the conserved helicase domain structure seen for other DEAD Box helicases. Our data on mutational analysis of a conserved buried residue I143 in the walker motif B created inactive protein. The data confirm critical functions for dicer in generation of siRNAs and also in recognition of dsRNA ends. Mutants in buried residues L1130 and I1228 of RNase IIIb domain were inactive and the proximity of these residues to the catalytic core suggest that the critical structural alignment of catalytic residues is indispensable for carrying out dsRNA cleavage to generate siRNAs. We also attribute critical catalytic functions to SpDcr1 D1185 residue for generation of siRNA and heterochromatin formation as measured by our transcriptional gene silencing assay. Our studies employing biophysical and computational approaches to design temperature-sensitive mutants have been successfully applied to an essential splicing factor SpPrp18, which was refractory for ts mutants by other methods. Using a missense mutant, we showed its intron-specific splicing function for subsets of transcripts and deduced that its ubiquitous splicing role is arguable. We have uncovered a link between the splicing substrates of SpPrp18 and direct evidence of splicing based cell cycle regulation, thus providing a mechanistic link to the cell cycle arrest seen in some splicing factor mutants. The same methodology was applied to another important biological pathway, the RNAi machinery, where central factors SpAgoI and SpDcrI were examined We report the first instance of conditional gene silencing tool by designing Ago1 ts mutants which will be useful for future studies of the global interaction network between RNAi and other RNA processing events.

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