Global ETD Search

21	Protein Profiling of Wild-type <i>Neurospora crassa</i> Grown on Various Carbon Sources Allen, Katie 09 March 2011 (has links) No description available. Biochemistry Biology Molecular Biology Neurospora crassa Quinic acid (qa) gene cluster Protein profile Carbon source
22	Induction of the qa-y and qa-1F Genes in Neurospora crassa at Differing Times of Quinic Acid Exposure George, Kory 03 June 2016 (has links) No description available. Biochemistry Bioinformatics Biology Cellular Biology Molecular Biology Neurospora crassa RT-qPCR quinic acid gene cluster
23	Investigating R gene evolution by meiotic recombination using synthetic gene clusters in Arabidopsis Sun, Jian 06 June 2008 (has links) Plant gene families organized as linked clusters are capable of evolving by a process of unequal crossing-over. This results in the formation of chimeric genes that may impart a novel function. However, the frequency and functional consequences of these unequal cross-over events are poorly characterized. Plant disease resistance genes (R genes) genes are frequently organized as gene clusters. In this study, I constructed an elaborately designed reconfigurable synthetic RPP1 (for resistance to Paranospora parasitica) gene cluster (synthRPP1) to model R gene evolution by meiotic recombination. This experimental design utilizes gain-of-luciferase phenotype (luc+) to identify and isolate recombinant R genes and uses two alternatively marked alleles to distinguish and measure different types of meiotic recombination (intra- vs. inter-chromosomal). Two putative single copy transgenic plants containing the synthRPP1 gene cluster were generated. These synthRPP1 gene clusters were reconfigured in vivo by two kinds of site-specific recombination systems (CRE/Lox, FLP/FRT) to generate two alternative versions of the synthRPP1 gene clusters in vivo. These lines, as well as others being developed, will be used in future genetic crosses to identify and characterize plants expressing chimeric RPP1 genes. My second area of research was to use a previously developed synthetic RBCSB gene cluster (synthRBCSB) gene cluster to investigate the relative frequency of meiotic unequal crossing over between paralogous genes located on either homologous chromosomes (homozygous lines) or sister chromatids (hemizygous lines). In contrast to published somatic recombination frequencies using a different reporter gene system, no statistically significant difference of meiotic unequal crossing over was observed between homo- and hemi-zygous synthRBCSB lines. This result suggests that meiotic unequal crossing-over between paralogs located on homologous chromosomes occurs at about the same frequency as paralogs located on sister chromatids. To investigate the rate of somatic recombination in synthRBCSB lines, a QRT-PCR method was developed to estimate the frequency of somatic recombination. Preliminary results suggest that the somatic recombination frequency was about 10,000 fold higher than meiotic recombination in the same generation. Moreover, two of five cloned chimeric genes that formed by somatic recombination indicated a different distribution of resolution sites than those observed in meiotic recombination. This finding suggests there are significant differences in both the frequency and character of somatic versus meiotic unequal crossing-over between paralogous genes in Arabidopsis. / Ph. D. synthetic gene cluster meiotic evolution R gene recombination unequal crossing-over somatic
24	Molecular characterisation of the EAS gene cluster for ergot alkaloid biosynthesis in epichloë endophytes of grasses : a thesis presented in partial fulfilment of the requirements for the degree of Doctor of Philosophy in Molecular Genetics at Massey University, Palmerston North, New Zealand Fleetwood, Damien James January 2007 (has links) Clavicipitaceous fungal endophytes of the genera Epichloë and Neotyphodium form symbioses with grasses of the family Pooideae in which they can synthesise an array of bioprotective alkaloids. Some strains produce the ergot alkaloid ergovaline, which is implicated in livestock toxicoses caused by ingestion of endophyteinfected grasses. Cloning and analysis of a plant-induced non-ribosomal peptide synthetase (NRPS) gene from Neotyphodium lolii and analysis of the E. festucae E2368 genome sequence revealed a complex gene cluster for ergot alkaloid biosynthesis. The EAS cluster contained a single-module NRPS gene, lpsB, and other genes orthologous to genes in the ergopeptine gene cluster of Claviceps purpurea and the clavine cluster of Aspergillus fumigatus. Functional analysis of lpsB confirmed its role in ergovaline synthesis and bioassays with the lpsB mutant unexpectedly suggested that ergovaline was not required for black beetle (Heteronychus arator) feeding deterrence from epichloë-infected grasses. Southern analysis showed the cluster was linked with previously identified ergot alkaloid biosynthetic genes, dmaW and lpsA, at a subtelomeric location. The ergovaline genes are closely associated with transposon relics, including retrotransposons, autonomous DNA transposons and miniature inverted-repeat transposable elements (MITEs), which are very rare in other fungi. All genes in the cluster were highly expressed in planta but expression was very low or undetectable in mycelia from axenic culture, including under nitrogen-, carbonor phosphate-limited conditions. Comparative analysis of the EAS gene cluster in four different epichloë strains showed marked differences in gene expression and ergot alkaloid synthesis. Gene order is conserved in each strain although evidence for recombination between two MITEs and expansion or reduction of a simple sequence repeat (SSR) at a single intergenic region was observed. Heterologous expression of a candidate regulatory gene, laeA, from Aspergillus nidulans, which is a global regulator of secondary metabolism in aspergilli, did not affect eas gene expression. This, along with phylogeny and microsynteny analysis, suggests there is not an orthologue of this gene in epichloë. This work provides a genetic foundation for elucidating biochemical steps in the ergovaline pathway, the ecological role of individual ergot alkaloid compounds, and the regulation of their synthesis in planta. EAS gene cluster molecular characterisation epichloe endophytic fungi of grasses ergot alkaloid biosynthesis
25	TRANSCRIPTIONAL AND POST-TRANSLATIONAL REGULATION OF TERPENOID INDOLE ALKALOID BIOSYNTHESIS IN <em>CATHARANTHUS ROSEUS</em> Paul, Priyanka 01 January 2017 (has links) Catharanthus roseus (Madagascar periwinkle) is the exclusive source of an array of terpenoid indole alkaloids (TIAs) that are used in the treatments of hypertension and certain types of cancer. TIA biosynthesis is under stringent spatiotemporal control and is induced by jasmonate (JA) and fungal elicitors. Tryptamine, derived from the indole branch, and secologanin from the iridoid branch are condensed to form the first TIA, strictosidine. Biosynthesis of TIA is regulated at the transcriptional level and several transcription factors (TFs) regulating the expression of genes encoding key enzymes in the pathway have been isolated and characterized. The JA-responsive APETALA2/ETHYLENE RESPONSE FACTOR (AP2/ERF), ORCA3, and the basic helix-loop-helix (bHLH) factor, CrMYC2, are the key activators of the TIA biosynthesis. Recently, two other TFs, the bHLH IRIDOID SYNTHESIS 1 (BIS1) and BIS2 were also identified as regulators of TIA pathway. Analysis of C. roseus genome sequence has revealed that ORCA3 forms a physical cluster with two uncharacterized AP2/ERFs, ORCA4 and ORCA5. In plants, physically linked clusters of TFs are less characterized. Moreover, the regulation of TF clusters is relatively unexplored. My research uncovered that the ORCA gene cluster is differentially regulated. ORCA4 and ORCA5, while functionally overlapping with ORCA3, regulate an additional set of TIA pathway genes. ORCA4 or ORCA5 overexpression has resulted in significant increase of TIA accumulation in C. roseus hairy roots. In addition, ORCA5 directly regulates the expression of ORCA4 and indirectly regulates ORCA3, likely via unknown factor(s). Interestingly, ORCA5 also activates the expression of ZCT3, a negative regulator of the TIA pathway. In addition CrMYC2 is capable of activating ORCA3 and co-regulating pathway genes concomitantly with ORCA3. Several lines of evidence suggest that, in addition to the transcriptional control, biosynthesis of TIAs is also controlled at the posttranslational level, such as protein phosphorylation. Available literature indicates that a mitogen-activated protein kinase (MAPK) cascade is involved in this process. Analysis of C. roseus MAP kinome, identified two independent MAPK cascades regulating the indole and iridoid branches of the TIA pathway. We showed that the ORCA cluster and CrMYC2 act downstream of a MAP kinase cascade consisting of CrMAPKK1, CrMAPK3 and CrMAPK6. Overexpression of CrMAPKK1 in C. roseus hairy roots upregulates TIA pathway genes expressions and boosts TIA accumulation. The other cascade, consisting of CrMAPKK6 and CrMAPK13, mostly regulates the iridoid branch of the TIA pathway. Overexpression of CrMAPK13 in C. roseus hairy roots significantly upregulates iridoid pathway genes and boosts tabersonine accumulation. Moreover, we recently identified the third MAPK cascade, consisting of CrMAPKK1 and CrMAPK20, that negatively regulates the indole branch of the TIA pathway. Overexpression of CrMAPK20 in C. roseus hairy roots represses the genes regulated by CrMYC2-ORCAs and reduces catharanthine accumulation. These findings significantly advance our understanding of transcriptional and post-translational regulatory mechanisms that govern TIA biosynthesis in C. roseus. AP2/ERF gene cluster Catharanthus roseus MAP kinome terpenoid indole alkaloids Biotechnology Physiology Plant Biology
26	SURE PROTEIN FOR PEPTIDE CYCLIZATION Brianne S Nunez (11185875) 26 July 2021 (has links) <div>Cyclic peptides are important sources of medicines. </div><div>They are advantageous compared to linear peptides because they possess lower flexibility, which allows for high-affinity target binding and enhanced proteolytic stability. Unfortunately, achieving head-to-tail cyclization of peptides is quite challenging, as it is hard to control efficiency and regiospecificity of peptide macrocyclization. Many have attempted to improve peptide cyclization, including the use of different synthetic reagents as well as synthetic techniques to allow amide-bond formation and promote cyclization. While these strategies have offered great potential solutions, the aim of this study is to explore an alternative strategy that utilizes biocatalysis as a method of achieving successful peptide cyclization. Biocatalysis is the use of enzymes as natural process catalysts under artificial in vitro conditions. Biocatalysis is often more environmentally friendly and safer compared to traditional organic synthesis methods. Non-ribosomal peptide synthetases (NRPSs) are one of the major sources of cyclic peptides in nature. These are systems of large multifunctional proteins are organized into functional domains that act as an assembly line to generate peptide natural products. Normally, the thioesterase domain is responsible for hydrolysis and cyclization of the peptide. Recently, a novel cyclase (SurE) that is physically discrete from the NRPS was discovered. Based on this unique quality, we hypothesized that SurE would be easier to express compared to thioesterase domains and, for this reason, SurE could be a fantastic biocatalyst for the cyclization of peptides. To test this, we designed and generated an expression vector for SurE. We then expressed and purified the SurE protein. We also synthesized three linear peptides of varying lengths. To test for SurE activity, we attempted to add N-acetylcysteamine (SNAC) to mimic its native substrate. Unfortunately, we were unable to successfully attach the SNAC to our linear peptide. To combat this issue, a new synthesis strategy is currently being developed. This work is currently ongoing in the Parkinson lab, with the aim being to test the SurE protein, as well as other PBP-like cyclases, on other modified linear peptides and demonstrate whether the protein has the ability to cyclase a wide scope of peptides.</div><div><br></div> Biochemistry Organic Chemistry Proteins and Peptides Protein expression peptide synthesis Thioesterase NRPS biosynthetic gene cluster Peptide Cyclization cyclic peptides SNAC Surugamide
27	Computational, Evolutionary and Functional Genetic Characterization of Fungal Gene Clusters Adapted to Degrade Plant Defense Chemicals Gluck Thaler, Emile 04 September 2019 (has links) No description available. Plant Pathology metabolic gene cluster genome evolution genome architecture resistance plant-fungal interactions horizontal gene transfer fungal ecology
28	Environmental Pseudomonas are a source of Novel Antibiotics that inhibit Cystic fibrosis derived pathogenic Pseudomonas aeruginosa Chatterjee, Payel 14 November 2017 (has links) No description available. Microbiology Biology Cystic fibrosis antibiotic multi-drug resistance antibiotic resistance Pseudomonas aeruginosa biosynthetic gene cluster antagonistic mutant transposon
29	BIOSYNTHETIC PATHWAY OF THE AMINORIBOSYL COMPONENT OF LIPOPEPTIDYL NUCLEOSIDE ANTIBIOTICS Chi, Xiuling 01 January 2013 (has links) Several lipopeptidyl nucleoside antibiotics that inhibit bacterial translocase I (MraY) involved in peptidoglycan cell wall biosynthesis contain an aminoribosyl moiety, an unusual sugar appendage in natural products. A-90289 and muraminomicin are the two representative antibiotics that belong to this family. Bioinformatic analysis of the biosynthetic A-90289 gene clusters revealed that five enzymes are likely involved in the assembly and attachment of the aminoribosyl unit. These enzymes of A-90289 are functionally assigned by in vitro characterization. The results reveal a unique ribosylation pathway that highlighted by uridine-5′-monophosphate as the source of the sugar, a phosphorylase strategy to generate a sugar-1-phosphate, and a primary amine-requiring nucleotidylyltransferase that generates the NDP-sugar donor. Muraminomicin, which has a structure similar to A-90289, holds the distinction in that both ribose units are 2-deoxy sugars. The biosynthetic gene cluster of muraminomicin has been identified, cloned and sequenced, and bioinformatic analysis revealed a minimum of 24 open reading frames putatively involved in the biosynthesis, resistance, and regulation of muraminomicin. Similar to the A-90289 pathway, fives enzymes are still likely involved in the assembly of the 2,5-dideoxy-5-aminoribose saccharide unit, and two are now functionally assigned and characterized: Mra20, a 5′-amino-2′,5′-dideoxyuridine phosphorylase and Mra23, a UTP:5-amino-2,5-dideoxy-α-D-ribose-1-phosphate uridylyltransferase. The cumulative results are consistent with the incorporation of the ribosyl appendage of muraminomicin via the archetypical sugar biosynthetic pathway that parallels A-90289 biosynthesis Aminoribosyl unit lipopeptidyl nucleoside antibiotics peptidoglycan cell wall biosynthetic gene cluster ORF enzymes Amino Acids, Peptides, and Proteins Enzymes and Coenzymes
30	Evolution of Genes and Gene Networks in Filamentous Fungi Greenwald, Charles Joaquin 2010 August 1900 (has links) The Pezizomycotina, commonly known as the filamentous fungi, are a diverse group of organisms that have a major impact on human life. The filamentous fungi diverged from a common ancestor approximately 200 – 700 million years ago. Because of the diversity and the wealth of biological and genomic tools for the filamentous fungi it is possible to track the evolutionary history of genes and gene networks in these organisms. In this dissertation I focus on the evolution of two genes (lolC and lolD) in the LOL secondary metabolite gene cluster in Epichloë and Neotyphodium genera, the evolution of the MAP kinase-signaling cascade in the filamentous fungi, the regulation of the gene networks involved in asexual development in Neurospora crassa, and the identification of two genes in the N. crassa asexual development gene network, acon-2 and acon-3. I find that lolC and lolD originated as an ancient duplication in the ancestor of the filamentous fungi, which were later recruited in the LOL gene cluster in the fungal endophyte lineage. In the MAP kinase-signaling cascade, I find that the MAPK component is the most central gene in the gene network. I also find that the MAPK signaling cascade originated as three copies in the ancestor to eukaryotes, an arrangement that is maintained in filamentous fungi. My observations of gene expression profiling during N. crassa asexual development show tissue specific expression of genes. Both the vegetative mycelium and the aerial hyphae contribute to the formation of macroconidiophores. Also, with the help of genomic tools recently developed by researchers in the filamentous fungal community, I identified NCU00478 and NCU07617 as the genes with mutations responsible for two aconidial strains of N. crassa, acon-2 and acon-3 respectively. Gene networks Pezizomycotina Neurospora crassa macroconidiation acon-2 acon-3 map kinase evolution loline lold lolD gene cluster conidiation asexual development

Search results