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Subunit interactions in regulation and catalysis of site-specific recombinationWenwieser, Sandra Verena Corinna Tina January 2001 (has links)
No description available.
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The interneurons and their synaptic organisations in the rat nucleus accumbensHidaka, Seiko January 2000 (has links)
No description available.
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Sistema de Pago de la Pensión Básica SolidariaLlanos Bravo, Roberto Enrique 15 January 2010 (has links)
Ingeniero Civil en Computación / El trabajo consiste del desarrollo de un sistema para el pago de algunos beneficios otorgados en la Reforma Previsional de la Ley 20.255 del 2008, por el Instituto de Previsión Social, IPS (ex INP). En este proyecto, realizado por la empresa Synapsis, participan aproximadamente 12 personas. Mi rol fue de Líder de Proyecto a cargo del equipo de analistas y programadores.
El trabajo fue realizado con una Metodología de Desarrollo basada en Unified Process (UP), identificando las fases, actividades, roles y productos o artefactos del proyecto. Paralelamente se define una arquitectura de desarrollo e implementación, la que describe los patrones de diseño de la aplicación, basada en estándares abiertos. Para las interfaces de usuario se acuerda un manual de usabilidad y estilos, orientado a los funcionarios del IPS, donde se describen los estándares que deben poseer las páginas Web para las funciones básicas de búsqueda, edición e impresión de informes, entre otras funcionalidades.
Finalmente, se define un plan de puesta en producción, donde se acuerdan pasos a seguir para la aceptación del producto, para la capacitación de los funcionarios, para la migración de los datos, para la instalación en producción de los programas y para el seguimiento de su funcionamiento en cuanto a reporte de fallas.
El sistema se desarrolla y se pone en producción en las fechas acordadas, definidas en la Ley. El proyecto está en producción hace más de un año, período en el cual los beneficiarios han recibido sus pagos en forma regular, sin ningún contratiempo.
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Investigating chromosome pairing in bread wheat using ASYNAPSIS I.Boden, Scott Andrew January 2008 (has links)
Pairing and synapsis of homologous chromosomes are required for normal chromosome segregation and the exchange of genetic material during meiosis. Pairing is defined as the recognition and alignment of chromosomes that occurs either pre-meiotically or during early prophase I to ensure that associations via synapsis and recombination occur only between homologues. Synapsis is the intimate juxtaposition of homologous chromosomes that is complete at pachytene following formation of a tri-partite proteinaceous structure known as the synaptonemal complex (SC). In yeast, HOP1 is an essential component of the SC that localises along chromosome axes during prophase I and promotes homologous chromosome interactions. Homologues in Arabidopsis (AtASY1), Brassica (BoASY1) and rice (OsPAIR2) have been isolated through analysis of mutants that display decreased fertility due to severely reduced synapsis of homologous chromosomes. Analysis of these genes has indicated that they play a similar role to HOP1 in pairing and formation of the SC through localisation to axial/lateral elements of the SC. In this study, we have characterised the bread wheat homologue of HOP1, TaASY1, and its encoded protein. The full length cDNA and genomic DNA clones of TaASY1 have been isolated, sequenced and characterised. TaASY1 is located on chromosome group 5 and the open reading frame displays significant similarity to OsPAIR2 (84%) and AtASY1 (63%). In addition to OsPAIR2 and AtASY1, the deduced amino acid sequence also displays sequence similarity to ScHOP1, with all four proteins containing a HORMA domain. Transcript and protein analysis showed that expression is largely restricted to meiotic tissue, with elevated levels during the stages of prophase I when pairing and synapsis of homologous chromosomes occurs. Antibodies specific to TaASY1 were used in immuno-fluorescence microscopy and immuno-gold transmission electron microscopy to investigate the localisation of TaASY1 in meiotic cells. Immuno-fluorescence analysis initially detected ASY1 in pollen mother cells (PMCs) during meiotic interphase as foci randomly distributed over the chromatin. The ASY1 signal became increasingly continuous during leptotene, reflecting the changes occurring in chromosome morphology. Throughout zygotene, the signal became progressively more continuous, localising along the entire length of the axial elements as chromosomes synapsed. This signal appeared to persist until pachytene, before disappearing from the chromatin as the SC disassociated through late pachytene and early diplotene. The immuno-gold based electron microscopy displayed that TaASY1 localises to chromatin that is associated with both axial elements before SC formation as well as chromatin of lateral elements within formed SCs. Analysis of RNAi Taasy1 mutants was performed to further define the role of ASY1 in bread wheat meiosis. ASY1 localisation was disrupted in these mutants, with a diffuse and non-continuous signal observed through leptotene and zygotene. Feulgen staining of meiotic chromosomes displayed reduced synapsis during prophase I, as well as multivalents at metaphase I and abnormal chromosome segregation during anaphase I. These observations are consistent with the presence of homoeologous chromosome interactions. TaASY1 expression and localisation was also investigated in the bread wheat pairing mutant, ph1b. Quantitative real-time PCR (Q-PCR) revealed that TaASY1 is significantly up-regulated in ph1b, with greater then 20-fold expression compared to wild-type Chinese Spring, while maintaining the same pattern of expression as wild-type through progressive stages of meiosis. ASY1 localisation was significantly disrupted in ph1b, with irregular loading on axial elements during mid to late zygotene, indicative of abnormal chromatin remodelling and multiple axial element associations that have previously been reported in ph1b. Taken together, these results indicate that TaASY1 is essential for promoting homologous chromosome interactions during meiosis, and that impairment of ASY1 function in bread wheat meiosis results in reduced restriction of chromosome associations to homologues. / http://proxy.library.adelaide.edu.au/login?url= http://library.adelaide.edu.au/cgi-bin/Pwebrecon.cgi?BBID=1340087 / Thesis (Ph.D.) -- University of Adelaide, School of Agriculture, Food and Wine, 2008
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Dissecting the meiotic defects of Tex19.1-/- mouse spermatocytesCrichton, James Hugh January 2015 (has links)
The maintenance of genomic stability through suppression of retrotransposon activity is vital for the avoidance of potentially mutagenic genomic disruption caused by retrotransposition. Germline development is a particularly important phase for retrotransposon silencing as retrotransposition events here have the potential for transmission to the entire embryo, threatening the health of offspring. A collection of germline genome defence genes are required for the suppression of retrotransposons in the developing germline of male mice (e.g. Tex19.1, Dazl, Mili, Miwi2, Gasz, Mov10l1, Mael, Dnmt3l), all of which trigger meiotic prophase arrest when mutated. I have analysed the meiotic defects which arise in Tex19.1-/- male mice to contribute to the understanding of the fundamental mechanisms required for successful completion of meiosis and to investigate the involvement of retrotransposon silencing in this process. The absence of TEX19.1 in male mice causes infertility; with failed chromosome synapsis in ~50% of pachytene nuclei and associated apoptosis, as well as individual univalent chromosomes in 67% of remaining nuclei progressing to metaphase I. Where studied, failed chromosome synapsis is a common feature of germline genome defence mutant spermatocytes. One aim of my studies has been to better understand the mechanism responsible for this failed chromosome synapsis. I have demonstrated that unlike Mael-/- spermatocytes, additional SPO11-independent DNA damage potentially attributable to retrotransposition is not detectable in Tex19.1-/- spermatocytes. Rather, the formation of meiotic DNA double strand breaks (DSBs) is dramatically reduced in early prophase to around 50%, resulting in a reduction in nuclear γH2AX signal, production of SPO11- oligonucleotide complexes and foci formation by early recombination proteins RPA, DMC1 and RAD51. Despite this early reduction, DSB frequency recovers to more normal levels shortly after in zygotene. I have shown that defective pairing of homologous chromosomes by meiotic recombination is likely responsible for the asynapsis previously reported. The initial reduction in DSB frequency could be sufficient to cause failed chromosome synapsis in this mutant, assuming that late-forming DSBs cannot participate effectively in promoting homologous pairing. Alternative hypotheses include altered positioning of DSBs in response to altered chromatin organisation relating to retrotransposon upregulation, misguiding the pairing of homologous chromosomes. Such a model of disruption could also extend to other germline genome defence mutants. I have demonstrated that despite successful pairing of homologous chromosomes in a sub-population of Tex19.1-/- spermatocytes, subsequent progression of these cells through pachytene is delayed. Numerous diverse features of progression are all delayed, including recombination, ubiquitination on autosomes and sex chromosomes, expression of the mid-pachytene marker H1t, and chromosome organisation. The delay identified is related to recombination therefore this feature is likely to stem from the initial defect in DSB formation early in prophase. While some delayed features are probably directly related to recombination, others are not. The coordinated delay observed may suggest the presence of a recombination-sensitive cell-cycle checkpoint operating to regulate progression through pachytene. My research has also aimed to establish the cause of elevated univalent chromosomes not connected by chiasmata in metaphase I Tex19.1-/- spermatocytes. I have demonstrated that that absence of chiasmata is not due to failed crossover formation between synapsed chromosomes. Rather, the frequent observation of individual unsynapsed chromosomes during crossover formation suggests that some spermatocytes with low-level asynapsis are leaking through meiotic checkpoints and are unable to form a crossover before reaching metaphase. Therefore, again this later meiotic defect appears to stem from the initial defect in meiotic DSB formation, the consequences of which vary widely in severity. Remarkably the unsynapsed chromosomes present during crossover formation include both sex chromosomes, and autosomes. Tolerance of an unsynapsed autosome from pachytene into metaphase is an unusual observation in mice and this observation may aid the understanding of spermato cyte quality control mechanisms during this progression. Together these findings have greatly advanced the understanding of the infertility incurred during meiosis in Tex19.1-/- male mice. These findings may also extend to benefit the understanding of other germline genome defence mutants. Diverse observations made during my investigations also reveal a potential system of coordinated progression through pachytene relating to meiotic recombination. The variable severity of the synapsis defects incurred in this mutant appears to have variable effects on spermatocyte survival and could also inform the understanding of meiotic checkpoint sensitivity.
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ELUCIDATION OF FACTORS IMPACTING HOMOLOGOUS RECOMBINATION IN MAMMALIAN MEIOSISCherry, Sheila M. January 2007 (has links)
No description available.
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The Mammalian Process of Meiotic SynapsisBrown, Petrice Wynaka January 2007 (has links)
No description available.
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The Elucidation of the Mechanism of Meiotic Chromosome Synapsis in Saccharomyces Cerevisiae : Insights into the Function of Synaptonemal Complex, Hop1 and Red1, Proteins and the Significance of DNA Quadruplex StructuresKshirsagar, Rucha January 2016 (has links) (PDF)
Meiosis is a specialized type of cell division where two rounds of chromosome segregation follow a single round of DNA duplication resulting in the formation of four haploid daughter cells. Once the DNA replication is complete, the homologous chromosomes pair and recombine during the meiotic prophase I, giving rise to genetic diversity in the gametes. The process of homology search during meiosis is broadly divided into recombination-dependent (involves the formation of double-strand breaks) and recombination-independent mechanisms. In most eukaryotic organisms, pairing of homologs, recombination and chromosome segregation occurs in the context of a meiosis-specific proteinaceous structure, known as the synaptonemal complex (SC). The electron microscopic visualization of SC has revealed that the structure is tripartite with an electron-dense central element and two lateral elements that run longitudinally along the entire length of paired chromosomes. Transverse filaments are protein structures that connect the central region to the lateral elements. Genetic analyses in budding yeast indicate that mutations in SC components or defects in SC formation are associated with chromosome missegregation, aneuploidy and spore inviability. In humans, defects in SC assembly are linked to miscarriages, birth defects such as Down syndrome and development of certain types of cancer.
In Saccharomyces cerevisiae, genetic screens have identified several mutants that exhibit defects in SC formation culminate in a decrease in the frequency of meiotic recombination, spore viability and improper chromosome segregation. Ten meiosis-specific proteins, viz. Hop1, Red1, Mek1, Hop2, Pch2, Zip1, Zip2, Zip3, Zip4 and Rec8, have been shown to be the bona fide components of SC and/or associated with SC function. S. cerevisiae HOP1 (HOmolog Pairing) gene was isolated in a genetic screen for mutants that showed defects in homolog pairing and, consequently, reduced levels of interhomolog recombination (10% of wild-type). Amino acid sequence alignment together with genetic and biochemical analyses revealed that Hop1 is a 70 kDa protein with a centrally embedded essential zinc-finger motif (Cys2/Cys2) and functions in polymeric form. Previous biochemical studies have also shown that Hop1 is a structure-specific DNA binding protein, which exhibits high affinity for the Holliday junction (HJ) suggesting a role of this protein in branch migration of the HJ.
Furthermore, Hop1 displays high affinity for G-quadruplex structures (herein after referred to as GQ) and also promotes the formation of GQ from unfolded G-rich oligonucleotides. Strikingly, Hop1 promotes pairing between two double-stranded DNA molecules via G/C-rich sequence as well as intra- and inter-molecular pairing of duplex DNA molecules. Structure-function analysis suggested that Hop1 has a modular organization consisting of a protease-sensitive N-terminal, HORMA domain (characterized in Hop1, Rev7, Mad2 proteins) and protease-resistant C-terminal domain, called Hop1CTD.
Advances in the field of DNA quadruplex structures suggest a significant role for these structures in a variety of biological functions such as signal transduction, DNA replication, recombination, gene expression, sister chromatid alignment etc. GQs and i-motif structures that arise within the G/C-rich regions of the genome of different organisms have been extensively characterized using biophysical, biochemical and cell biological approaches. Emerging studies with guanine- and cytosine-rich sequences of several promoters, telomeres and centromeres have revealed the formation of GQs and i-motif, respectively. Although the presence of GQs within cells has been demonstrated using G4-specific antibodies, in general, the in vivo existence of DNA quadruplex structures is the subject of an ongoing debate. However, the identification and isolation of proteins that bind and process these structures support the idea of their in vivo existence.
In S. cerevisiae, genome-wide survey to identify conserved GQs has revealed the presence of ~1400 GQ forming sequences. Additionally, these potential GQ forming motifs were found in close proximity to promoters, rDNA and mitosis- and meiosis-specific double-strand break sites (DSBs). Meiotic recombination in S. cerevisiae as well as humans occurs at meiosis-specific double-strand break (DSBs) sites that are embedded within the G/C-rich sequences. However, much less is known about the structural features and functional significance of DNA quadruplex motifs in sister chromatid alignment N during meiosis. Therefore, one of the aims of the studies described in this thesis was to investigate the relationship between the G/C-rich motif at a meiosis-specific DSB site in S. cerevisiae and its ability to form GQ and i-motif structures.
To test this hypothesis, we chose a G/C-rich motif at a meiosis-specific DSB site located between co-ordinates 1242526 to 1242550 on chromosome IV of S. cerevisiae. Using multiple techniques such as native gel electrophoresis, circular dichroism spectroscopy, 2D NMR and chemical foot printing, we show that G-rich motif derived from the meiosis-specific DSB folds into an intramolecular GQ and the complementary C-rich sequence folds into an intramolecular i-motif, the latter under acidic conditions. Interestingly, we found that the C-rich strand folds into i-motif at near neutral pH in the presence of cell-mimicking molecular crowding agents. The NMR data, consistent with our biochemical and biophysical analyses, confirmed the formation of a stable i-motif structure. To further elucidate the impact of these quadruplex structures on DNA replication in vitro, we carried out DNA polymerase stop assay with a template DNA containing either the G-rich or the C-rich sequence. Primer extension assays carried out with Taq polymerase and G-rich template blocked the polymerase at a site that corresponded to the formation of an intramolecular GQ. Likewise, primer extension reactions carried out with KOD-Plus DNA polymerase and C-rich template led to the generation of a stop-product at the site of the formation of intramolecular I -motif under acidic conditions (pH 4.5 and pH 5.5). However, polymerase stop assay performed in the presence of single-walled carbon nanotubes (SWNTs) that stabilize I -motif at physiological pH blocked the polymerase at the site of intramolecular I -motif formation, indicating the possible existence of i-motif in the cellular context. Taken together, these results revealed that the G/C-rich motif at the meiosis-specific DSB site folds into GQ and i-motif structures in vitro. Our in vitro analyses were in line with our in vivo analysis that examined the ability of the G/C-rich motif to fold into quadruplex structures in S. cerevisiae cells. Qualitative microscopic analysis and quantitative analysis with plasmid constructs that harbour the GQ or i-motif forming sequence revealed a significant decrease in the GFP expression levels in comparison to the control. More importantly, all the assays performed with the corresponding mutant sequences under identical experimental conditions did not yield any quadruplex structures, suggesting the involvement of contagious guanine and cytosine residues in the structure formation.
Prompted by our earlier results that revealed high binding affinity of Hop1 for GQ, we wished to understand the role of the GQ and i-motif structures during meiosis by analysing their interaction with Hop1 and its truncated variants (HORMA and Hop1CTD). In agreement with our previous observations, Hop1 and Hop1CTD associated preferentially with GQ DNA. Interestingly, whereas the full-length Hop1 showed much weaker binding affinity for i-motif DNA, Hop1 C-terminal fragment but not its N-terminal fragment exhibited robust i-motif DNA binding activity. We have previously demonstrated that Hop1 promotes intermolecular synapsis between synthetic duplex DNA molecules containing a G/C-rich sequence. Hence, to understand the functional role of the quadruplex structures formed at the meiosis-specific G/C-rich motif, we examined the ability of Hop1 to promote pairing between linear duplex DNA helices containing the G/C-rich motif. DNA pairing assay indicated that binding of Hop1 to the G/C-rich duplex DNA resulted in the formation of a side-by-side synapsis product. Under similar conditions, Hop1 was unable to pair mutant duplex DNA molecules suggesting the involvement of the G/C-rich motif in the formation of the synapsis product. Our results were substantiated by the observation that yeast Rad17 failed to promote pairing between duplex DNA molecules with a centrally embedded G/C-rich motif. Altogether, these results provide important structural and functional insights into the role of quadruplex structures in meiotic pairing of homologous chromosomes.
The second part of the thesis focuses on the biochemical and functional properties of Red1 protein, a component of S. cerevisiae lateral element. RED1 was identified in a screen for meiotic lethal, sporulation proficient mutants. Genetic, biochemical and microscopic analyses have demonstrated the physical interaction between Hop1 and Red1. Given this, hop1 and red1 mutants display similar phenotypes such as chromosome missegregation and spore inviability and thus are placed under the same epistasis group. However, unlike hop1 mutants, red1 mutants show complete absence of SC. RED1 overexpression suppressed certain non-null hop1 phenotypes, indicating that these proteins may have partially overlapping functions. Further, although the functional significance is unknown, chromatin immunoprecipitation studies have revealed the localization of Red1 to the GC-rich regions (R-bands) in the genome, considered to be meiotic recombination hotspots.
Although the aforementioned genetic studies suggest an important role for Red1 in meiosis, the exact molecular function of Red1 in meiotic recombination remains to be elucidated. To explore the biochemical properties of Red1, we isolated the S. cerevisiae RED1 gene, cloned, overexpressed, and purified the protein to near homogeneity. Immunoprecipitation assays using meiotic cells extracts suggested that Red1 exists as a Homodimer linked by disulphide-bonds under physiological conditions. We characterized the DNA binding properties of Red1 by analysing its interaction with recombination intermediates that are likely to form during meiotic recombination. Protein-DNA interaction assays revealed that Red1 exhibits binding preference for the Holliday junction over replication fork and other recombination intermediates. Notably, Red1 displayed ~40-fold higher binding affinity for GQ in comparison with HJ. The observation that Red1 binds robustly to GQs prompted us to examine if Red1 could promote pairing between duplex DNA helices with the G/C-rich sequences similar to Hop1. Interestingly, we found that Red1 failed to promote pairing between dsDNA molecules but potentiated Hop1 mediated pairing between duplex DNA molecules. Our AFM studies with linear and circular DNA molecules along with Red1 suggested a possible role of Red1 in DNA condensation, bridging and pairing of double-stranded DNA helices.
Bioinformatics analysis of Red1 indicated the lack of sequence or structural similarity to any of the known proteins. To elucidate structure-function relationship of Red1, we generated several N- and C-terminal Red1 truncations and studied their DNA binding properties. Our results indicated that the N-terminal region comprising of 678 amino acid residues constitutes the DNA-binding region of Red1. The N-terminal region, called RNTF-II, displayed similar substrate specificity comparable to that of full-length Red1. Interestingly, site-directed mutagenesis studies with the Red1 C-terminal region revealed the involvement of two cysteine residues at position 704 and 707 in the disulfide bond mediated intermolecular dimer formation. Finally, to understand the functional significance of Red1 truncations we analyzed the subcellular localization of Red1 and its truncations. We made translation fusions of RED1 and its truncations by placing their corresponding nucleotide sequences downstream of GFP coding sequence in yeast expression vector. Confocal microscopy studies with S. cerevisiae cells transformed with the individual plasmid constructs indicated that the N-terminal variants localized to the nucleus, whereas the C-terminal variants did not localize to the nucleus. These results suggest that NLS-like motifs are embedded in the N-terminal region of the protein. Furthermore, other results indicated that the N-terminal region contains functions such as DNA-binding and intermolecular bridging of non-contiguous DNA segments. Altogether, these findings, on the one hand, provide insights into the molecular mechanism underlying the functions of Hop1 and Red1 proteins and, on the other, support a role for DNA quadruplex structures in meiotic chromosome synapsis and recombination.
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Structure-Function Relationships of Saccharomyces Cerevisiae Meiosis Specific Hop 1 Protein : Implications for Chromosome Condensation, Pairing and Spore FormationKhan, Krishnendu January 2012 (has links) (PDF)
Meiosis is a specialized type of cell division essential for the production of four normal haploid gametes. In early prophase I of meiosis, the intimate synapsis between homologous chromosomes, and the formation of chiasmata, is facilitated by a proteinaceous structure known as the synaptonemal complex (SC). Ultrastructural analysis of germ cells of a number of organisms has disclosed that SC is a specialized tripartite structure composed of two lateral elements, one on each homolog, and a central element, which, in turn, are linked by transverse elements. Genetic studies have revealed that defects in meiotic chromosome alignment and/or segregation result in aneuploidy, which is the leading cause of spontaneous miscarriages in humans, hereditary birth defects such as Down syndrome, and are also, associated with the development and progression of certain forms of cancer. The mechanism(s) underlying the alignment/pairing of chromosomes at meiosis I differ among organisms. These can be divided into at least two broad pathways: one is independent of DNA double-strand breaks (DSB) and other is mediated by DSBs. In the DSB-dependent pathway, SC plays crucial roles in promoting homolog pairing and disjunction. On the other hand, the DSB-independent pathway involves the participation of telomeres, centromeres and non-coding RNAs in the pre-synaptic alignment, pre-meiotic pairing as well as pairing of homologous chromosomes. Although a large body of literature highlights the central role of SC in meiotic recombination, the possible role of SC components in homolog recognition and alignment is poorly understood.
Genetic screens for Saccharomyces cerevisiae mutants defective in meiosis and sporulation lead to the isolation of genes required for interhomolog recombination, including those that encode SC components. In S. cerevisiae, ten meiosis-specific proteins viz., Hop1, Red1, Mek1, Hop2, Pch2, Zip1, Zip2, Zip3, Zip4 and Rec8 have been recognized as bona fide constituents of SC or associated with SC function. Mutations in any of these genes result in defective SC formation, thus leading to reduction in the rate of recombination. HOP1 (Homolog Pairing) encodes a ̴ 70 kDa structural protein, which localizes to the lateral elements of SC. It was found to be essential for the progression of meiotic recombination. In hop1Δ mutants, meiosis specific DSBs are reduced to 10% of that of wild type level and it fails to produce viable spores. It also displays relatively high frequency of inter-sister recombination over inter-homolog recombination. Bioinformatics analysis suggests that Hop1 comprises of an N-terminal HORMA domain (Hop1, Rev7 and Mad2), which is conserved among Hop1 homologs from diverse organisms. This domain is also known to be present in proteins involved in processes like chromosome synapsis, repair and sex chromosome inactivation. Additionally, Hop1 harbors a 36-amino acid long zinc finger
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motif (CX2CX19CX2C) which is critical for DNA binding and meiotic progression, and a putative nuclear localization signal corresponding to amino acid residues from 588-594. Previous studies suggested that purified Hop1 protein exists in multiple oligomeric states in solution and displays structure specific DNA binding activity. Importantly, Hop1 exhibited higher binding affinity for the Holliday junction (HJ), over other early recombination intermediates. Binding of Hop1 to the HJ at the core resulted in branch migration of the junction, albeit weakly. Intriguingly, Hop1 showed a high binding affinity for G4 DNA, a non-B DNA structure, implicated in homolog synapsis and promotes robust synapsis between double-stranded DNA molecules.
Hop1 protein used in the foregoing biochemical studies was purified from mitotically dividing S. cerevisiae cells containing the recombinant plasmid over-expressing the protein where the yields were often found to be in the low-microgram quantities. Therefore, one of the major limitations to the application of high resolution biophysical techniques, such as X-crystallography and spectroscopic analyses for structure-function studies of S. cerevisiae Hop1 has been the non-availability of sufficient quantities of functionally active pure protein. In this study, we have performed expression screening in Escherichia coli host strains, capable of high level expression of soluble S. cerevisiae Hop1 protein. A new protocol has been developed +2 for expression and purification of S. cerevisiae Hop1 protein, using Ni-NTA and double-stranded DNA-cellulose chromatography. Recombinant S. cerevisiae Hop1 protein thus obtained was >98% pure and exhibited DNA binding activity with high-affinity for Holliday junction. The availability of the bacterial HOP1 expression vector and functionally active Hop1 protein has enabled us to glean and understand several vital biological insights into the structure-function relationships of Hop1 as well as the generation of appropriate truncated mutant proteins.
Mutational analyses in S. cerevisiae has shown that sister chromatid cohesion is required for proper chromosome condensation, including the formation of axial elements, SC assembly and recombination. Consistent with these findings, homolog alignment is impaired in red1hop1 strains and associations between homologs are less stable. red1 mutants fail to make any discernible axial elements or SC structures but exhibit normal chromosome condensation, while hop1 mutants form long fragments of axial elements but without any SCs, are defective in chromosome condensation, and produce in-viable spores. Using single molecule and ensemble assays, we found that S. cerevisiae Hop1 organizes DNA into at least four major distinct DNA conformations:
(i) a rigid protein filament along DNA that blocks access to nucleases; (ii) bridging of non-contiguous segments of DNA to form stem-loop structures; (iii) intra-and intermolecular long range synapsis between double-stranded DNA molecules; and (iv) folding of DNA into higher order nucleoprotein structures. Consistent with B. McClintock’s proposal that “there is a tendency for chromosomes to associate 2-by-2 in the prophase of meiosis involving long distance recognition of homologs”, these results to our knowledge provide the first evidence that Hop1 mediates the formation of tight DNA-protein-DNA nucleofilaments independent of homology which might help in the synapsis of homologous chromosomes during meiosis.
Although the DNA binding properties of Hop1 are relatively well established, comparable knowledge about the protein is lacking. The purification of Hop1 from E. coli, which was functionally indistinguishable from the protein obtained from mitotically dividing S. cerevisiae cells has enabled us to investigate the structure-function relationships of Hop1, which has provided important insights into its role in meiotic recombination. We present several lines of evidence suggesting that Hop1 is a modular protein, consisting of an intrinsically unstructured N-terminal domain and a core C-terminal domain (Hop1CTD), the latter being functionally equivalent to the full-length Hop1 in terms of its in vitro activities. Importantly, however, Hop1CTD was unable to rescue the meiotic recombination defects of hop1null strain, indicating that synergy between the N-terminal and C-terminal domains of Hop1 protein is essential for meiosis and spore formation. Taken together, our findings provide novel insights into the molecular functions of Hop1, which has profound implications for the assembly of mature SC, homolog synapsis and recombination.
Several lines of investigations suggest that HORMA domain containing proteins are involved in chromatin binding and, consequently, have been shown to play key roles in processes such as meiotic cell cycle checkpoint, DNA replication, double-strand break repair and chromosome synapsis. S. cerevisiae encodes three HORMA domain containing proteins: Hop1, Rev7 and Mad2 (HORMA) which interact with chromatin during diverse chromosomal processes. The data presented above suggest that Hop1 is a modular protein containing a distinct N-terminal and C-terminal (Hop1CTD) domains. The N-terminal domain of Hop1, which corresponds to the evolutionarily conserved HORMA domain, although, discovered first in Hop1, its precise biochemical functions remain unknown. In this section, we show that Hop1-HORMA domain expressed in and purified from E. coli exhibits preferential binding to the HJ and G4 DNA, over other early recombination intermediates. Detailed functional analyses of Hop1-HORMA domain, using mobility shift assays, DNase I footprinting and FRET, have revealed that HORMA binds at the core of Holliday junction and induces marked changes in its global conformation. Further experimental evidence also suggested that it causes DNA stiffening and condensation. However, like Hop1CTD, HORMA domain alone failed to rescue the meiotic recombination defects of hop1 null strain, indicating that synergy between the N-and C-terminal domains of Hop1 is essential for meiosis as well as for the formation of haploid gametes. Moreover, these results strongly implicate that Hop1 protein harbours a second DNA binding motif, which resides in the HORMA domain at its N-terminal region. To our knowledge, these findings also provide the first insights into the biochemical mechanism underlying HORMA domain activity. In summary, it appears that the C-terminal (CTD) and N-terminal (HORMA) domains of Hop1 may perform biochemical functions similar (albeit less efficiently) to that of the full-length Hop1. However, further research is required to uncover the functional differences between these domains, their respective interacting partners and modulation of the activity of these domains.
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