The Role of Eukaryotic Recombinase Loop L1 During Homologous Recombination

Steinfeld, Justin Benjamin

January 2018

Within the life of an organism, its deoxyribonucleic acid (DNA) is constantly bombarded with damaging agents from exogenous and endogenous sources. One of the most deleterious types of damage is the double-stranded break (DSB) in which a continuous strand of DNA is broken in two. As a result, the information stored in their connection is lost. If improperly repaired, a cell will either not survive or transform into a neoplasm. Homologous recombination (HR) is a mechanism by which the cell processes these broken ends and uses proteins called recombinases to search for an undamaged homologous DNA template for repairing the break, the homology search. Generally for eukaryotes, the recombinase, Rad51, performs the homology search. Without it, cells cannot repair spontaneous DSBs by recombination and instead, must use alternative, less efficacious pathways. This type of reparative homologous recombination generally occurs during mitosis and is thus called mitotic recombination. In addition to its role in repair, HR is employed by eukaryotes during the first stage of meiosis to create crossover events, or chiasmata, between DNA homologs. The formation of these chiasmata is necessary for proper segregation of the chromosomes, preventing aneuploidy in the haploid cells destined for sexual reproduction. These crossover events have an added evolutionary benefit of mixing genes between the parental chromosomes, creating allelic diversity in the haploid cells. Eukaryotes have evolved a subset of meioticallyexpressed proteins to mediate this process. Dmc1 is a meiosis-specific, second recombinase that eukaryotes require to properly form these crossover events between homologs. It is not entirely understood why most eukaryotes require a second recombinase specifically designed for meiotic HR. A potential reason for this second recombinase may lie in the preferred templates for recombination that Rad51 and Dmc1 seek. Rad51 is employed mitotically to repair spontaneous DSBs and thus searches for the perfect undamaged copy, the sister chromatid, to prevent the loss of genetic information. Conversely, Dmc1 is employ meiotically to purposely form crossover events between homologs, which carry single-nucleotide polymorphisms (SNPs) between parental chromosomes. Thus, Dmc1 must be able to anneal DNA strands that aren’t perfectly the same. This work uses the single-molecule technique of DNA curtains to understand the factors that effect Rad51 and Dmc1 homologous DNA-capture stability. The first part of Chapter 1 is a historical exploration of homologous recombination research and a review of the current understanding of the pathway. The second part of Chapter 1 discusses human diseases that are associated with the failure to properly repair double-strand breaks. Chapter 2 will explain the single-molecule DNA curtain technique used throughout this work. Chapter 3 will show that Dmc1 is more tolerant of mismatches in captured DNA than Rad51. Chapter 4 will test the limits of Dmc1’s tolerance to imperfect DNA and attempts understand how it accomplishes this tolerance. Chapter 5 will demonstrate that this tolerance of mismatches is mediated by a specific structural element in recombinases, loop L1, and a chimeric Rad51 with a Dmc1-like L1 can tolerate mismatches in vitro and in vivo. Chapter 6 will explore how recombinase mediators such as BARD1 and BRCA1 enhance RAD51’s ability to capture DNA during the homology search.

Biophysics

Biochemistry

Genetics

Genetic recombination

Eukaryotic cells

Characterization of the eukaryotic translation termination sequence element

Cridge, Andrew Graham, n/a

January 2005

Termination of protein synthesis occurs in response to the translocation of a stop codon (UAA, UAG or UGA) into the A site of the ribosome. Unlike sense codons, stop signals in the mRNA are recognized by two classes of specialized proteins called release factors (RFs): the class I or decoding RF, which recognizes the stop codon and promotes peptidyl-tRNA hydrolysis and class II RF, a G-protein that promotes the dissociation of the decoding RF from the ribosome. The discovery that stop codons are decoded by a protein factor rather than a specific tRNA opened up the possibility that the signal for termination of protein synthesis might extend beyond the stop codon itself. Biochemical and genetic experiments in prokaryotes confirmed that bias in nucleotide usage around stop codons correlates with translation termination efficiency. The objective of the current investigation was to define the eukaryotic termination signal by determining the bias in the nucleotide sequence surrounding eukaryotic stop codons and to identify whether this was a determinant of translation termination efficiency. Bioinformatic analysis of five diverse eukaryotic genomes was undertaken to identify potential eukaryotic translation termination signal elements. Significant nucleotide bias was identified both 5� and 3� of the stop codon in all the genomes investigated. Correlations were identified between nucleotide bias and gene expression levels, and between nucleotide bias and natural recoding sites predicting that nucleotides 5� and 3� of the stop codon affect termination efficiency. These correlations were common to all organisms investigated and suggested the existence of a eukaryotic termination signal. Termination signals identified from the bioinformatic analysis were assayed to determine the efficiency of termination in an in vitro dual luciferase reporter assay. Results indicated that nucleotides both 5� and 3� of the stop codon could significantly alter termination signal efficiency, although readthrough did not vary by greater than 1%. The effect of nucleotides 3� to the stop codon on termination efficiency was investigated further in mammalian cultured cells using the dual luciferase reporter assay. Results showed a significant relationship between the identity of these nucleotides and observed termination efficiencies with nucleotides at positions +4 and +8 giving the strongest correlation. Termination sequence elements of the form UGA CUN NCN mediated up to 5% readthrough in cultured cells. Investigations into the underlying mechanisms that were responsible for the variation in termination efficiency were also undertaken. Co-transfection of specific suppressor tRNAs enhanced but did not change the pattern of observed termination efficiency, indicating that the mechanisms mediated by the termination signal element was not mediated through suppressor tRNA binding. Alignments of 18S rRNA sequences indicated potential extensive interactions between the rRNA and the mRNA termination signal element. Experiments that assessed the effect of eRF1 levels on termination at inefficient termination signals in vitro revealed that increased levels of eRF1 could improve termination efficiency. These results indicate that, as in prokaryotes, specific nucleotides beyond the stop codon modulate translation termination efficiency in eukaryotes, and that the translation termination signal should be considered a sequence element.

Eukaryotic cells

protein synthesis

RNA protein interactions

A novel role of the E3 ubiquitin ligase as a transcription regulation in eukaryotic cell nucleus

Tam, Chun-yee.

January 2009

Thesis (M. Phil.)--University of Hong Kong, 2010. / Includes bibliographical references (leaves 47-53). Also available in print.

DARM distance-based association rule mining.

Icev, Aleksandar.

January 2003

Thesis (M.S.)--Worcester Polytechnic Institute. / Keywords: spatial data mining; distance-based association rules; distance-based Apriori algorithm. Includes bibliographical references (p. 51-54).

Evaluation of eIF-2α phosphorylation in patients with Alzheimer's disease

Chen, Lu-hua., 陳璐華.

January 2007

published_or_final_version / Medical Sciences / Master / Master of Medical Sciences

Alzheimer's disease.

Phosphorylation.

Eukaryotic cells.

Proteins - Synthesis.

Genome-wide mapping of DNA-protein interactions in eukaryotes

Kim, Jonghwan

28 August 2008

Not available / text

Eukaryotic cells

DNA-protein interactions

Genetic transcription

Nmd3p, the nuclear export adapter for the 60S ribosomal subunit: characterization of its recycling mechanism and novel interaction with the nuclear pore complex in yeast

West, Matthew Blaine

28 August 2008

Not available / text

Ribosomes

Proteins--Physiological transport

Eukaryotic cells

A computational study of transcriptional regulation in eukaryotes on a genomic scale

Cavalli, Florence Marie Géraldine

January 2011

No description available.

570.285

Studies on the coupling of DNA to low density lipoproteins (LDL) and the interaction of these complexes with eukaryotic cells.

Khan, Zainub.

09 October 2013

The application of Molecular Biochemistry for transfection studies in eukaryotic systems is well documented. Of the numerous methods employed for the introduction of foreign DNA into eukaryotic cells, the use of low density lipoproteins (LDL) as carriers of DNA into cells has not been reported. LDL was isolated, characterized with respect to its protein and lipid components, and then variously modified in an attempt to enhance its affinity for DNA. It was found that both unmodified and modified LDL could interact with DNA, at physiological pH. The carbodiimide modified LDL (ECDI - LDL) showed the greatest affinity for DNA. LDL and ECDI - LDL were used to study LDL receptor binding in skin fibroblasts. This was followed by a study of receptor binding activities of both unmodified LDL and ECDI - LDL complexed to DNA (pBR322). Although the extent of binding of ECDI - LDL and ECDI - LDL - DNA complexes to plasma membranes was greater, the internalization and degradation of both modified and unmodified LDL complexes were equivalent. This additional binding was attributed to non - receptor - specific affinity of the carbodiimide modified complexes for the plasma membrane. The transfection of foreign DNA into eukaryotic cells in culture was monitored by assaying for the expression of the cloning vector, pSV2cat, complexed to LDL or ECDI - LDL and introduced into the cells by LDL receptor - mediated endocytosis. Of the cell lines in which the expression of the pSV2cat recombinant DNA was monitored, the human lung fibroblasts showed the greatest activity of the expressed chloramphenicol acetyl transferase enzyme. Although transfection efficiency was lower than that of the calcium phosphate - DNA coprecipitation procedure, the LDL receptor - mediated transfection of eukaryotic cells was carried out under physiological conditions and may be applicable in vivo. / Thesis (Ph.D)-University of Durban-Westville, 1987.

Lipoproteins.

Deoxyribonucleic acid.

Theses--Biochemistry.

Eukaryotic cells.

Characterization of the eukaryotic translation termination sequence element

Cridge, Andrew Graham, n/a

January 2005

Termination of protein synthesis occurs in response to the translocation of a stop codon (UAA, UAG or UGA) into the A site of the ribosome. Unlike sense codons, stop signals in the mRNA are recognized by two classes of specialized proteins called release factors (RFs): the class I or decoding RF, which recognizes the stop codon and promotes peptidyl-tRNA hydrolysis and class II RF, a G-protein that promotes the dissociation of the decoding RF from the ribosome. The discovery that stop codons are decoded by a protein factor rather than a specific tRNA opened up the possibility that the signal for termination of protein synthesis might extend beyond the stop codon itself. Biochemical and genetic experiments in prokaryotes confirmed that bias in nucleotide usage around stop codons correlates with translation termination efficiency. The objective of the current investigation was to define the eukaryotic termination signal by determining the bias in the nucleotide sequence surrounding eukaryotic stop codons and to identify whether this was a determinant of translation termination efficiency. Bioinformatic analysis of five diverse eukaryotic genomes was undertaken to identify potential eukaryotic translation termination signal elements. Significant nucleotide bias was identified both 5� and 3� of the stop codon in all the genomes investigated. Correlations were identified between nucleotide bias and gene expression levels, and between nucleotide bias and natural recoding sites predicting that nucleotides 5� and 3� of the stop codon affect termination efficiency. These correlations were common to all organisms investigated and suggested the existence of a eukaryotic termination signal. Termination signals identified from the bioinformatic analysis were assayed to determine the efficiency of termination in an in vitro dual luciferase reporter assay. Results indicated that nucleotides both 5� and 3� of the stop codon could significantly alter termination signal efficiency, although readthrough did not vary by greater than 1%. The effect of nucleotides 3� to the stop codon on termination efficiency was investigated further in mammalian cultured cells using the dual luciferase reporter assay. Results showed a significant relationship between the identity of these nucleotides and observed termination efficiencies with nucleotides at positions +4 and +8 giving the strongest correlation. Termination sequence elements of the form UGA CUN NCN mediated up to 5% readthrough in cultured cells. Investigations into the underlying mechanisms that were responsible for the variation in termination efficiency were also undertaken. Co-transfection of specific suppressor tRNAs enhanced but did not change the pattern of observed termination efficiency, indicating that the mechanisms mediated by the termination signal element was not mediated through suppressor tRNA binding. Alignments of 18S rRNA sequences indicated potential extensive interactions between the rRNA and the mRNA termination signal element. Experiments that assessed the effect of eRF1 levels on termination at inefficient termination signals in vitro revealed that increased levels of eRF1 could improve termination efficiency. These results indicate that, as in prokaryotes, specific nucleotides beyond the stop codon modulate translation termination efficiency in eukaryotes, and that the translation termination signal should be considered a sequence element.

Eukaryotic cells

protein synthesis

RNA protein interactions