Discovery and characterization of small non-coding RNAs in Vibrio cholerae that contribute to gene regulation during infection

Bradley, Evan

20 August 2014

<p> Small non-coding RNAs (sRNAs) are being increasingly recognized as critical regulators of a wide variety of processes in bacteria. To investigate the contribution of unknown sRNAs to virulence gene regulation in <i>Vibrio cholerae,</i> we undertook a screen to identify previously uncharacterized sRNAs under the control of the major virulence gene activator in <i> V. cholerae,</i> ToxT. Using a combination of direct sRNA cloning and sequencing together with a genome-wide ToxT <i>in vitro</i> binding assay, we identified 18 putative ToxT-regulated sRNAs. Two of these ToxT regulated sRNAs were located within the <i>Vibrio</i> Pathogenicity Island-1 (VPI-1), the genetic element that encodes ToxT and the Toxin Co-regulated Pilus (TCP). We verified regulation of these sRNAs by ToxT and showed that deletion of one of them, now designated <i>tarB</i>, caused a variable colonization phenotype when competed against the parental strain in an infant mouse model of <i>V. cholerae</i> infection. Infections progressing for 18 hours or less showed the &Delta;<i>tarB</i> strain was out-competed by the wild type strain, while those carried out longer, showed &Delta;<i> tarB</i> out-competing the wild type. Additionally, if inoculated from a resource poor environment the &Delta;<i>tarB</i> strain also showed decreased colonization relative to wild type. Using a bioinformatic approach, we identified that <i>tarB</i>-mediated regulation of the gene <i> tcpF</i> was primarily responsible for the <i>tarB</i> mutant's <i> in vivo</i> colonization phenotype. Further investigation of genes regulated by <i>tarB</i> using genome-wide transcriptional profiling of a <i> tarB</i> over-expressing strain revealed that <i>tarB</i> also directly regulates genes involved in iron and amino acid uptake. We determined that <i>tarB</i> has a repressive effect on many genes within the VPI-1, but has an activating effect on <i>tcpP/tcpH,</i> encoding regulators upstream of ToxT. Taken together, the data suggest that <i> tarB</i> plays an important role in regulating virulence and metabolic genes early after <i>V. cholerae</i> infection, but that this repressive effect on virulence genes later in infection may lead to reduced replication <i> in vivo.</i></p>

Biology, Molecular|Biology, Microbiology

Characterization of RTEL/PCNA interaction in the maintenance of genomic stability

Nabi, Md. Zinnatun

14 September 2010

Previously, we have demonstrated that a DNA helicase-like protein, termed RTEL (regulator of telomere length) is essential for the maintenance of genomic stability. RTEL deficiency induced telomere loss and genomic instability, leading to embryonic lethality. However, the role of RTEL in these biological pathways is largely unknown. To uncover RTEL’s function(s), we applied several approaches to identify the proteins that could interact with RTEL. Proliferating Cell Nuclear Antigen (PCNA), the key regulator of the replication fork, was found to be a strong candidate. In this study, we have demonstrated the interaction between RTEL and PCNA. Further characterization of the interaction between RTEL and PCNA revealed that the interaction is important for maintaining genomic stability. Due to the essential role of PCNA in nucleic acid metabolism as a component of the replication and repair machinery, its interaction with RTEL could be the key to the role of RTEL in the maintenance of genomic stability and mouse development. Along with a bioinformatics approach, we have employed several biochemical approaches to identify the interaction of PCNA with RTEL. Using co-immunoprecipitation, we have demonstrated that RTEL can specifically interact with PCNA. A PCR-based mutagenesis method was used to mutate the PCNA-interacting motif (PIP) in RTEL. Further we have demonstrated that several key amino acids in the PIP motif are responsible for mediating RTEL/PCNA interaction by using co-immunoprecipitation and immunofluorescence studies. Using a gene-targeting approach, we have specifically knocked-in a mutant RTEL with a mutation in PIP motif into mouse genome. Thus we have developed a transgenic mouse model to study the significance of the interaction between RTEL/PCNA in vivo. This study not only validated the interaction of RTEL with PCNA, via the PIP box, but also generated the RTEL PIP mutant alleles for further functional analysis by transgenic approaches. We have employed biochemical and cytogenetic studies to characterize the phenotypes in RtelI1169A/I1169A mouse. This is the first direct genetic approach to address whether PCNA is an important downstream mediator of RTEL’s function in the regulation of genomic integrity

Molecular Biology

Transgenic model

Susceptibility of parkinson's disease following mild blast traumatic brain injury

Acosta, Glen Howel G.

31 January 2015

<p> Blast injury-induced neurotrauma (BINT) is steadily increasing in prevalence due to escalated terror activity and constitutes the signature injury associated with current military conflicts. BINT produces significant neurological deficiencies and there is a growing concern that the injury may produce long-term consequences that affect the resilience and the performance of soldiers. One of the potential consequences is an increased susceptibility to Parkinson's disease (PD). A vital goal aimed at curtailing the post-deployment long-term consequences of blast injury-induced neurotrauma is to further our knowledge of pathogenic mechanisms responsible for the escalation of post injury diseases. <i> The purpose of this project is to investigate the molecular mechanism underlying the susceptibility of PD in post-blast rats.</i> We have identified acrolein, a highly reactive aldehyde that persists days to weeks following brain-injury and perpetuates oxidative insult, as a potential therapeutic target to curtail chemically mediated damage, a common feature of BINT and PD. <b>Our hypothesis is that acrolein is a key pathological factor linking BINT and the development of PD in our rat model.</b></p>

Biology, Molecular|Biology, Neuroscience

Doc of bacteriophage P1 is an enzyme that inhibits translation and phosphorylates a protein target

Cale, Stephanie

31 December 2014

<p> Doc induces cell death by inhibiting translation; however, the mechanism of Doc-induced cell death and the cellular target of the toxin were unknown. One theory suggested that Doc inhibits translation elongation by binding directly to the 30S ribosomal subunit. Later evidence showed catalytic activity in distant homologs of Doc. These homologs contain a Fic-domain that has been shown to modify target GTPases by AMPylation and phosphocholination. Therefore, [³⁵S] &ndash; Met, &alpha;[³²P] &ndash; ATP, and &gamma;[³²P] &ndash; ATP were used in conjunction with an S30 extract to confirm that Doc inhibits translation, to assess the mechanism of modification, and to identify the modified target. The results showed that Doc is an enzyme that inhibits translation and phosphorylates a protein target.</p>

Biology, Molecular|Biology, Microbiology

Investigating the Hippo Signaling Pathway using High-throughput Protein-protein Interaction LUMIER Screens

Shiban, Ahmed

17 July 2013

The Hippo pathway plays a key role in controlling organ growth and size. In mammals, core pathway components include the Lats1/2 and Mst1/2 kinases, which phosphorylate the transcriptional regulators, Taz and Yap. To identify novel upstream pathway regulators high throughput protein-protein interaction screens, called LUMIER (LUminescence-based Mammalian IntERactome) were performed together with a functional screen using a luciferase reporter that examines Hippo pathway responses. The screens revealed 1103 protein-protein interactions and 227 transcriptional regulators, which were particularly enriched in cytoskeletal regulators. A subset of these hits including BTK, Dvl1, Dvl2, Dvl3, Ing2, Magi2, Mark4 and Trip6 were validated by manual LUMIER assays and co-immunoprecipitation (Co-IP). Of particular interest was the microtubule dynamics regulatory protein MARK4. Loss of Mark4 prevents Taz activity demonstrating its role as a potential negative regulator of the Hippo pathway. Further studies could help decipher mechanisms of how Mark4 and the other cytoskeletal hits act to modulate the Hippo pathway.

Biochemistry

Molecular Biology

0487

Investigation of Activated Tyrosine Kinases in Myeloproliferative Neoplasms

Marit, Michael

17 December 2012

Myeloproliferative neoplasms (MPNs) are a group of disorders characterized by an excess production of a specific, fully functional blood cell type. Many cases involve deregulation of a protein tyrosine kinase. JAK2 is one such kinase, involved in a subset of MPNs. JAK2-selective inhibitors are currently being evaluated in clinical trials. In order to identify inhibitor-resistant JAK2 mutations before they appear in the clinic, we utilized TEL-JAK2 to conduct an in vitro random mutagenesis screen for JAK2 alleles resistant to JAK Inhibitor-I. Isolated mutations were evaluated for their ability to sustain cellular growth, stimulate downstream signalling pathways, and phosphorylate a novel JAK2 substrate in the presence of inhibitor. When testing the panel of mutations in the context of the Jak2 V617F allele, we observed that a subset of mutations conferred resistance to inhibitor. These results demonstrate that small-molecule inhibitors select for JAK2 inhibitor-resistant alleles. Chronic myeloid leukemia is an MPN characterized by the presence of the BCR-ABL fusion gene. We determined that a specific cohort bearing deletions near the ABL gene, which is associated with poor prognosis, do not suffer from genomic instability. We also examined the role of a putative tumour suppressor gene EXOSC2 as an explanation for the reduced survival time, and suggest it may have a role in disease progression.

Cancer

Molecular Biology

0992

Investigating the Hippo Signaling Pathway using High-throughput Protein-protein Interaction LUMIER Screens

Shiban, Ahmed

17 July 2013

The Hippo pathway plays a key role in controlling organ growth and size. In mammals, core pathway components include the Lats1/2 and Mst1/2 kinases, which phosphorylate the transcriptional regulators, Taz and Yap. To identify novel upstream pathway regulators high throughput protein-protein interaction screens, called LUMIER (LUminescence-based Mammalian IntERactome) were performed together with a functional screen using a luciferase reporter that examines Hippo pathway responses. The screens revealed 1103 protein-protein interactions and 227 transcriptional regulators, which were particularly enriched in cytoskeletal regulators. A subset of these hits including BTK, Dvl1, Dvl2, Dvl3, Ing2, Magi2, Mark4 and Trip6 were validated by manual LUMIER assays and co-immunoprecipitation (Co-IP). Of particular interest was the microtubule dynamics regulatory protein MARK4. Loss of Mark4 prevents Taz activity demonstrating its role as a potential negative regulator of the Hippo pathway. Further studies could help decipher mechanisms of how Mark4 and the other cytoskeletal hits act to modulate the Hippo pathway.

Biochemistry

Molecular Biology

0487

The Roles of Swe1p Localization and Feedback in the Regulation of the Morphogenesis Checkpoint

King, Kindra

January 2012

<p>Saccharomyces cerevisiae cells exposed to a variety of physiological stresses transiently delay bud emergence or bud growth. To maintain coordination between bud formation and the cell cycle in such circumstances, the morphogenesis checkpoint delays nuclear division via the mitosis-inhibitory Wee1-family kinase, Swe1p. Swe1p is degraded during G2 in unstressed cells, but is stabilized and accumulates following stress. Degradation of Swe1p is preceded by its recruitment to the septin scaffold at the mother-bud neck, mediated by the Swe1p-binding protein Hsl7p. Following osmotic shock or actin depolymerization, Swe1p is stabilized, and previous studies suggested that this was because Hsl7p was no longer recruited to the septin scaffold following stress. However, we now show that Hsl7p is in fact recruited to the septin scaffold in stressed cells. Using a CDK mutant that is immune to checkpoint-mediated inhibition, we show that Swe1p stabilization following stress is an indirect effect of CDK inhibition. These findings demonstrate the physiological importance of a positive feedback loop in which Swe1p activity inhibits the CDK, which then ceases to target Swe1p for degradation. They also highlight the difficulty in disentangling direct checkpoint pathways from the effects of positive feedback loops active at the G2/M transition.</p> / Dissertation

Genetics

Molecular biology

Aptamers to the hepatitis C virus polymerase

Jones, Louisa Alice School of Biotechnology And Biomolecular Sciences, UNSW

January 2005

Treatments for the hepatitis C virus (HCV) are currently only partially effective. Research into antivirals directed at HCV viral proteins are commonly based and tested on a single genotype, namely genotype 1. This is despite the high level of variability of the RNA virus and the frequency of infection with genotypes other than 1. The systematic evolution of ligands by exponential enrichment (SELEX) is a novel in vitro approach for the isolation of antiviral agents. SELEX allows rapid screening of vast nucleic acid libraries to isolate sequences (termed aptamers) that bind to target proteins with high affinity. The SELEX approach was used in the present study to isolate DNA aptamers to the RNAdependent RNA polymerase (RdRp) [non-structural protein B (NS5B)] protein of HCV subtype 3a, with the aim of inhibiting polymerase activity. Ten rounds of selection were performed using a Biacore 2000 and resultant aptamers cloned from rounds 2, 4, 8 and 10. Sequences of aptamers were aligned to elucidate common motifs and a proportion of the aptamers from rounds 8 and 10 (29/48) were screened for binding ability using the Biacore. The five ???best binding??? aptamers were investigated for inhibition of 3a polymerase activity in an in vitro polymerase assay. Two aptamers, r10/43 and r10/47, were chosen for further studies based on their ability to inhibit polymerase activity. The inhibition constants (Ki) of r10/43 and r10/47 were estimated to be 1.4 + 2.4 nM and 6.0 + 2.3 nM respectively. The affinity (Kd) of these aptamers for the 3a polymerase was estimated to be 1.3 + 0.3 nM (r10/43) and 23.5 + 6.7 nM (r10/47). The estimated inhibition and dissociation constants of these two aptamers are among the best for inhibitory aptamers of the HCV enzymes (polymerase and protease). Inhibition of HCV 3a polymerase appeared to be specific for r10/47, whilst r10/43 also had some inhibitory effect on norovirus and ??6 polymerase activity. This study is the first description of an inhibitor to the HCV subtype 3a polymerase that investigates genotypic specificity of targeted antivirals.

Molecular biology

RNA polymerases

Denaturation of deoxyribonucleic acid / Ross B. Inman.

Inman, Ross Banks

January 1959

Typewritten / 117 leaves, [28] leaves of plates : ill. ; 27 cm. / Title page, contents and abstract only. The complete thesis in print form is available from the University Library. / Thesis (Ph.D.)--University of Adelaide, Dept. of Physical & Inorganic Chemistry,1960

DNA.

Molecular biology.