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Towards the synthesis of ubiquitinGreen, Jeremy January 1987 (has links)
No description available.
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Electric DNA arrays for determination of pathogenic Bacillus cereusLiu, Yanling January 2007 (has links)
<p>Silicon-based electric chip arrays were developed for characterization of Bacillus</p><p>cereus with respect to the capacity to produce toxins involved in food poisoning and foodborne infections. Bacteria of the B. cereus group contain different sets of four toxins encoded by eight genes. The purpose of this work was to develop a fast method for determination of the presence of these genes in colonies from primary enrichment cultures. The specific DNA detection was based on immobilization of DNA capture probes, which hybridize to specific sites on the target genes. Biotin-labeled detection probes were designed to hybridize with the target DNA adjacent to the capture probes. An extravidin - alkaline phosphatase complex was subsequently bound to the hybridized detection probes. Finally, p-aminophenyl phosphate was added as substrate for the enzyme, and the product p-aminophenol was brought in contact with the interdigitated gold electrode on the silicon chips surface. The p-aminophenol was oxidized at the anode to quinoneimine, which was then reduced back to paminophenol at the cathode. This redox recycling generates a current that was used as the DNA-chip response to the target DNA. Two versions of the assay were used. In the first version the capture probes were immobilized on magnetic beads and all</p><p>chemical reactions until and including the enzymatic reaction took place in an</p><p>eppendorf tube while the redox recycling was used to measure the amount of paminophenol produced after transfer from the tube to the silicon chip surface. In the second version a silicon chip array was used with 16 parallel electrode positions, each activated by immobilization of one type of capture probes on the gold electrodes. With this system all chemical reactions took place at the chip surface. The kinetics of cell disruption and DNA fragmentation from B. cereus by ultrasonication was determined. Maximum cell disruption was achieved within 5 min and the chip response increased in proportion to the ultrasonic time. Further ultrasonication up to 10 min resulted in further increasing current although no further cell disruption was observed. If the sonication time was extended above 10 min the signal declined. Based on analysis of the DNA size distribution by early end-point PCR and gel electrophoresis, it is suggested that the first 5 min ultrasonication increased the signal by increasing the release of target DNA molecules. Thereafter the signal was increased by fragmentation of target DNA which increases the diffusion rate and also the accessibility of the hybridization site. Finally, the DNA fragment sizes approached that of the hybridization site (51-bp) which may reduce the signal because of cleavage of the target DNA in the hybridization region. These studies were performed with the bead-based hybridization assay. The assay was highly specific to the target gene (hblC) of both B. cereus and B. thuringiensis with no response from negative control</p><p>cells of B. subtilis. The 16 positions of the silicon chip array were activated by</p><p>immobilization of all known toxin-coding genes of B. cereus and also included both a positive control and a negative control electrode positions. When these chips were exposed to ultrasonicated B. cereus, the gold electrodes were fouled by some component in DNA cell lysates. To circumvent this, the released large DNA was first extracted and then ultrasonicated again, since the extract mainly contains large molecular weight DNA. This DNA extract was applied to characterize one “diarrheal” and one “emetic” strain of B. cereus with the DNA chip arrays. The results agreed with PCR control analysis which means that these electric DNA chip arrays can be used to characterize bacterial colonies with respect to the genes coding of all known toxins of B. cereus: haemolysin (hblA, hblC, hblD), non-haemolytic enterotoxin (nheA, nheB, nheC), cytotoxin K-2 (cytK-2), and cereulide (ces). The chip assay required about 30 min after application of DNA samples. Due to the generic properties of the chips, this technique should also be applicable for characterization of the pathogenicity potential of many other organisms. Keywords: Bacillus cereus, haemolysin, non-haemolytic enterotoxin, cytotoxin K-2, cereulide, toxin-coding genes, bacterial colony, electric DNA chip, ultrasonication, DNA fragmentation.</p>
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Electric DNA arrays for determination of pathogenic Bacillus cereusLiu, Yanling January 2007 (has links)
Silicon-based electric chip arrays were developed for characterization of Bacillus cereus with respect to the capacity to produce toxins involved in food poisoning and foodborne infections. Bacteria of the B. cereus group contain different sets of four toxins encoded by eight genes. The purpose of this work was to develop a fast method for determination of the presence of these genes in colonies from primary enrichment cultures. The specific DNA detection was based on immobilization of DNA capture probes, which hybridize to specific sites on the target genes. Biotin-labeled detection probes were designed to hybridize with the target DNA adjacent to the capture probes. An extravidin - alkaline phosphatase complex was subsequently bound to the hybridized detection probes. Finally, p-aminophenyl phosphate was added as substrate for the enzyme, and the product p-aminophenol was brought in contact with the interdigitated gold electrode on the silicon chips surface. The p-aminophenol was oxidized at the anode to quinoneimine, which was then reduced back to paminophenol at the cathode. This redox recycling generates a current that was used as the DNA-chip response to the target DNA. Two versions of the assay were used. In the first version the capture probes were immobilized on magnetic beads and all chemical reactions until and including the enzymatic reaction took place in an eppendorf tube while the redox recycling was used to measure the amount of paminophenol produced after transfer from the tube to the silicon chip surface. In the second version a silicon chip array was used with 16 parallel electrode positions, each activated by immobilization of one type of capture probes on the gold electrodes. With this system all chemical reactions took place at the chip surface. The kinetics of cell disruption and DNA fragmentation from B. cereus by ultrasonication was determined. Maximum cell disruption was achieved within 5 min and the chip response increased in proportion to the ultrasonic time. Further ultrasonication up to 10 min resulted in further increasing current although no further cell disruption was observed. If the sonication time was extended above 10 min the signal declined. Based on analysis of the DNA size distribution by early end-point PCR and gel electrophoresis, it is suggested that the first 5 min ultrasonication increased the signal by increasing the release of target DNA molecules. Thereafter the signal was increased by fragmentation of target DNA which increases the diffusion rate and also the accessibility of the hybridization site. Finally, the DNA fragment sizes approached that of the hybridization site (51-bp) which may reduce the signal because of cleavage of the target DNA in the hybridization region. These studies were performed with the bead-based hybridization assay. The assay was highly specific to the target gene (hblC) of both B. cereus and B. thuringiensis with no response from negative control cells of B. subtilis. The 16 positions of the silicon chip array were activated by immobilization of all known toxin-coding genes of B. cereus and also included both a positive control and a negative control electrode positions. When these chips were exposed to ultrasonicated B. cereus, the gold electrodes were fouled by some component in DNA cell lysates. To circumvent this, the released large DNA was first extracted and then ultrasonicated again, since the extract mainly contains large molecular weight DNA. This DNA extract was applied to characterize one “diarrheal” and one “emetic” strain of B. cereus with the DNA chip arrays. The results agreed with PCR control analysis which means that these electric DNA chip arrays can be used to characterize bacterial colonies with respect to the genes coding of all known toxins of B. cereus: haemolysin (hblA, hblC, hblD), non-haemolytic enterotoxin (nheA, nheB, nheC), cytotoxin K-2 (cytK-2), and cereulide (ces). The chip assay required about 30 min after application of DNA samples. Due to the generic properties of the chips, this technique should also be applicable for characterization of the pathogenicity potential of many other organisms. Keywords: Bacillus cereus, haemolysin, non-haemolytic enterotoxin, cytotoxin K-2, cereulide, toxin-coding genes, bacterial colony, electric DNA chip, ultrasonication, DNA fragmentation. / QC 20101111
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Transcriptional and Posttranscriptional Regulation of the Tumor Suppressor CDC73 in Oral Squamous Cell Carcinoma : Implications for Cancer TherapeuticsRather, Mohammad Iqbal January 2013 (has links) (PDF)
CDC73, also known as HRPT2, is a tumour suppressor gene whose expression is lost or downregulated in parathyroid, renal, breast, uterine and gastric cancers. However, the reports regarding the role of CDC73 in oral squamous cell carcinoma (OSCC) are lacking. As part of the Paf1 complex, it remains associated with ribonucleic acid (RNA) polymerase II and is involved in transcript site selection, transcriptional elongation, histone H2B ubiquitination, histone H3 methylation, poly(A) length control and, coupling of transcriptional and posttranscriptional events. It has been reported to negatively regulate cellularproliferation by targeting oncogenes CCND1 (cyclin D1) and MYC (c-Myc). Moreover, it has also been indicated to inhibitβ-catenin-mediated transcription. Taken together, these findings strongly suggest that it contributes to the expression of genes whose products have an important role in the suppression of tumor development and cell death. In this study, we have attempted to study the transcriptional and posttranscriptional regulation of CDC73 and its role in OSCC.
The main findings of the present study are listed below.
1. To begin with, the expression analysis of CDC73 was performed both at the RNA and the protein levels by qRT-PCR and IHC, respectively. As expected, a majority of the OSCC samples showed downregulation of CDC73 both at the RNA and the protein levels compared to their normal oral tissues.
2. Loss-of-heterozygosity (LOH), mutation and promoter methylation are the hallmarks of a tumor suppressor gene (TSG). Therefore, to characterize CDC73 as a TSG in OSCC and to look into the mechanisms that could be the cause of CDC73 downregulation in OSCC, LOH, mutation and promoter methylation of CDC73 were studied. The results showed that LOH, mutation and promoter methylation are not the major causes of CDC73 downregulation in OSCC.
3. To identify the alternate mechanisms as the cause of CDC73 downregulation in OSCC, a combination of bioinformatics and molecular approaches were used. The results showed that the upregulation of an inhibitory transcription factor WT1 (Wilms tumor protein 1) and an oncogenic microRNA-155 are the major causes of its downregulation in OSCC.
4. The luciferase reporter assay of SCC131 cells co-transfected with a WT1 construct and a CDC73 promoter construct showed that WT1 over expression represses CDC73 expression in a dose-dependent manner.
5. Due to the presence of zinc fingers in its C-terminal half, WT1 has been found to be a potent transcriptional regulator of genes. Therefore, to determine if WT1 down regulates CDC73 via binding its promoter, the chromatin immunoprecipitation (ChIP) assay was performed. The results showed the binding of WT1 to the CDC73 promoter in vivo. Binding of WT1 to the CDC73 promoter was further confirmed in vitro by the electrophoretic mobility shift assay (EMSA).
6. The 5-aza-2’-deoxycytidine (AZA) treatment of SCC131 cells led to upregulation of WT1 with a concomitant downregulation of CDC73. The COBRA technique demonstrated that the upregulation of WT1 upon the 5-AZA treatment was due to its promoter methylation.
7. To determine if the WT1-mediated reduction of CDC73 expression has a functional relevance in cell growth and proliferation, we knocked down CDC73 expression by transient over expression of WT1 in SCC131 cells and quantitated cell proliferation by the MTT assay. As expected, the results demonstrated that the reduced CDC73 level was associated with an increased cell proliferation. Cotransfection of CDC73 with WT1 in SCC131 cells attenuated the pro-oncogenic effect of WT1 by apoptosis induction.
8. After validating CDC73 as the target of WT1 by bioinformatics and in vitro assays, we quantitated the expression levels of WT1 and CDC73 by qRT-PCR in OSCC samples and their matched normal oral tissue samples. The results showed an inverse correlation between the expression levels of WT1 and CDC73 in a majority of the samples. To exclude the possibility of alternate mechanisms as the cause of CDC73 downregulation in OSCC, we selected a subset of OSCC samples with downregulated level of CDC73 and analysed them for LOH at the CDC73 locus and promoter methylation. Further, some of these OSCC samples were also analyzed for mutations in CDC73. The results showed that these OSCC samples did not have LOH, promoter methylation or any mutation, again validating the fact that CDC73 is a biological target of oncogenic WT1, and the transcriptional repression of CDC73 by WT1 could be a major mechanism for CDC73 downregulation in OSCC.
9. Recent studies have shown that a growing class of noncoding RNAs called microRNAs (miRNAs) is involved in posttranscriptional regulation of genes. There is a growing body of literature supporting the potential role of miRNAs in tumorigenesis. The importance of CDC73 in orchestration of several cellular functions and its role in tumorigenesis make it an attractive candidate for miRNA-mediated regulation of cell growth and proliferation. Using bioinformatics approaches, we identified an oncogenic microRNA-155 (miR-155) that could posttranscriptionally regulate CDC73 expression.
10. Consistent with its oncogenic role, miR-155 was found dramatically upregulated in OSCC samples and was found to be another mechanism for downregulation of CDC73 in a panel of human cell lines and a subset of OSCC samples in the absence of LOH, mutations and promoter methylation.
11. miRNAs regulate posttranscriptional gene expression generally via binding to their cognate sites in the 3’UTR. Therefore, a luciferase reporter construct was made by cloning the 3’UTR of CDC73 downstream to the luciferase reporter gene and the reporter assay was performed. Our experiments clearly indicated that the mature miR-155 regulates CDC73 expression by interacting with its 3’UTR in a site specific manner.
12 Ectopic expression of miR-155 in HEK293 cells dramatically reduced CDC73 levels, enhanced cell viability and decreased apoptosis. Conversely, the delivery of a miR-155 antagonist (antagomir-155) to KB cells over expression miR-155 resulted in increased CDC73 level, decreased cell viability, increased apoptosis and marked regression of engrafts in nude mice. Cotransfection of miR-155 with CDC73 in HEK293 cells abrogated its pro-oncogenic effect. Reduced cell proliferation and increased apoptosis of KB cells were dependent on the presence or absence of the 3’UTR in CDC73.
In nutshell, the knockdown of CDC73 expression due to over expression of WT1 and miR-155 not only adds a novelty to the list of mechanisms responsible for its downregulation in different tumors, but the restoration of CDC73 levels by the use of inhibitors to WT1 and antagomir-155 may also have an important role in therapeutic intervention of cancers, including OSCC.
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