A site directed mutagenic analysis of the regulatory flovoprotein NifL from Azotobacter vinelandii

Perry, Susan Elizabeth

January 2002

No description available.

579

Mutant proteins

Role of RecQ helicases in maintenance of genome integrity

Levitt, Nicola C.

January 2003

No description available.

572

Mutant proteins

Generation and characterization of an attenuated mutant in a response-regulator gene of Francisella tularensis live vaccine strain (LVS)

Sammons, Wendy L.

January 2007

Dissertation (Ph.D.)--University of South Florida, 2007. / Includes vita. Includes bibliographical references. Also available online.

Generation and characterization of an attenuated mutant in a response-regulator gene of Francisella tularensis live vaccine strain (LVS)

Sammons, Wendy L.

January 2007

Dissertation (Ph.D.)--University of South Florida, 2007. / Title from PDF of title page. Document formatted into pages; contains 93 pages. Includes vita. Includes bibliographical references.

The Study of Two Strategies for Decreasing Mutant Huntingtin: Degradation by Puromycin Sensitive AminoPeptidase and RNA Interference: A Dissertation

Chaurette, Joanna

22 May 2013

Huntington’s disease (HD) is a fatal neurodegenerative disease caused by a CAG repeat expansion in exon 1 of the huntingtin gene, resulting in an expanded polyglutamine (polyQ) repeat in the huntingtin protein. Patients receive symptomatic treatment for motor, emotional, and cognitive impairments; however, there is no treatment to slow the progression of the disease, with death occurring 15-20 years after diagnosis. Mutant huntingtin protein interferes with multiple cellular processes leading to cellular dysfunction and neuronal loss. Due to the complexity of mutant huntingtin toxicity, many approaches to treating each effect are being investigated. Unfortunately, addressing one cause of toxicity might not result in protection from other toxic insults, necessitating a combination of treatments for HD patients. Ideally, single therapy targeting the mutant mRNA or protein could prevent all downstream toxicities caused by mutant huntingtin. In this work, I used animal models to investigate a potential therapeutic target for decreasing mutant huntingtin protein, and I apply bioluminescent imaging to investigate RNA interference to silence mutant huntingtin target sites. The enzyme puromycin sensitive aminopeptidase (PSA) has the unique property of degrading polyQ peptides and been implicated in the degradation of huntingtin. In this study, we looked for an effect of decreased PSA on the pathology and behavior in a mouse model of Huntington’s disease. To achieve this, we crossed HD mice with mice with one functional PSA allele and one inactivated PSA allele. We found that PSA heterozygous HD mice develop a greater number of pathological inclusion bodies, representing an accumulation of mutant huntingtin in neurons. PSA heterozygous HD mice also exhibit worsened performance on the raised-beam test, a test for balance and coordination indicating that the PSA heterozygosity impairs the function of neurons with mutant huntingtin. In order to test whether increasing PSA expression ameliorates the HD phenotype in mice we created an adeno-associated virus (AAV) expressing the human form of PSA (AAV-hPSA). Unexpectedly, testing of AAV-hPSA in non-HD mice resulted in widespread toxicity at high doses. These findings suggest that overexpression of PSA is toxic to neurons in the conditions tested. In the second part of my dissertation work, I designed a model for following the silencing of huntingtin sequences in the brain. Firefly luciferase is a bioluminescent enzyme that is extensively used as a reporter molecule to follow biological processes in vivo using bioluminescent imaging (BLI). I created an AAV expressing the luciferase gene containing huntingtin sequences in the 3'-untranslated region (AAV-Luc-Htt). After co-injection of AAV-Luc-Htt with RNA-silencing molecules (RNAi) into the brain, we followed luciferase activity. Using this method, we tested cholesterol-conjugated siRNA, un-conjugated siRNA, and hairpin RNA targeting both luciferase and huntingtin sequences. Despite being able to detect silencing on isolated days, we were unable to detect sustained silencing, which had been reported in similar studies in tissues other than the brain. We observed an interesting finding that co-injection of cholesterol-conjugated siRNA with AAV-Luc-Htt increased luminescence, findings that were verified in cell culture to be independent of serotype, siRNA sequence, and cell type. That cc-siRNA affects the expression of AAV-Luc-Htt reveals an interesting interaction possibly resulting in increased delivery of AAV into cells or an increase in luciferase expression within the cell. My work presents a method to follow gene silencing of huntingtin targets in the brain, which needs further optimization in order to detect sustained silencing. Finally, in this dissertation I continue the study of bioluminescent imaging in the brain. We use mice that have been injected in the brain with AAV-Luciferase (AAV-Luc) to screen 34 luciferase substrate solutions to identify the greatest light-emitting substrate in the brain. We identify two substrates, CycLuc1 and iPr-amide as substrates with enhanced light-emitting properties compared with D-luciferin, the standard, commercially available substrate. CycLuc1 and iPr-amide were tested in transgenic mice expressing luciferase in dopaminergic neurons. These novel substrates produced luminescence unlike the standard substrate, D-luciferin which was undetectable. This demonstrates that CycLuc1 and iPr-amide improve the sensitivity of BLI in low expression models. We then used CycLuc1 to test silencing of luciferase in the brain using AAV-shRNA (AAV-shLuc). We were unable to detect silencing in treated mice, despite a 50% reduction of luciferase mRNA. The results from this experiment identify luciferase substrates that can be used to image transgenic mice expressing luciferase in dopaminergic neurons. My work contributes new data on the study of PSA as a modifier of Huntington’s disease in a knock-in mouse model of Huntington’s disease. My work also makes contributions to the field of bioluminescent imaging by identifying and testing luciferase substrates in the brain to detect low level of luciferase expression.

Aminopeptidases

Huntington Disease

Mutant Proteins

Nerve Tissue Proteins

RNA Interference

Dissertations, UMMS

Genetics and Genomics

Nervous System Diseases

Neuroscience and Neurobiology

Development of Highly Potent LIMK2 Inhibitors and Identification of Most Important Cysteine Residues in Formation of LIMK2 Dimer

Michael Andreas Tandiary (9029354)

16 May 2024

Sulfonamide derivatives have been designed and synthesized for LIMK2 inhibitors. The inhibition activities of the sulfonamide derivatives were tested against LIMK2. The best sulfonamide derivative was three times more potent than the best sulfonamide inhibitors previously published based on MTT assay results.<br>Two LIMK2 single mutants, LIMK2-365 and LIMK2-549, and a LIMK2 double mutant (LIMK2-DM) were cloned, and their phosphorylation activities were measured and compared against normal LIMK2. LIMK2-365, LIMK2-549, and LIMK2-DM all showing lower activities than the normal LIMK2, with the LIMK2-DM showing even lower activity than each of the single mutant LIMK2, suggesting the importance of these amino acid residues in phosphorylation and in the formation of dimer LIMK2.<p></p>

Organic chemical synthesis

LIMK2 Inhibitors

Cloning of LIMK2 Mutant Proteins

Biochemistry

Organic Chemical Synthesis

Distinct functions of POT1 at telomeres.

Barrientos, KS, Kendellen, MF, Freibaum, BD, Armbruster, BN, Etheridge, KT, Counter, CM

09 1900

The mammalian protein POT1 binds to telomeric single-stranded DNA (ssDNA), protecting chromosome ends from being detected as sites of DNA damage. POT1 is composed of an N-terminal ssDNA-binding domain and a C-terminal protein interaction domain. With regard to the latter, POT1 heterodimerizes with the protein TPP1 to foster binding to telomeric ssDNA in vitro and binds the telomeric double-stranded-DNA-binding protein TRF2. We sought to determine which of these functions-ssDNA, TPP1, or TRF2 binding-was required to protect chromosome ends from being detected as DNA damage. Using separation-of-function POT1 mutants deficient in one of these three activities, we found that binding to TRF2 is dispensable for protecting telomeres but fosters robust loading of POT1 onto telomeric chromatin. Furthermore, we found that the telomeric ssDNA-binding activity and binding to TPP1 are required in cis for POT1 to protect telomeres. Mechanistically, binding of POT1 to telomeric ssDNA and association with TPP1 inhibit the localization of RPA, which can function as a DNA damage sensor, to telomeres. / Dissertation

Cell Line

DNA Damage

DNA, Single-Stranded

Humans

Models, Biological

Mutant Proteins

Mutation

Protein Binding

Protein Transport

Replication Protein A

Telomere

Telomere-Binding Proteins

Telomeric Repeat Binding Protein 2