Carbon catabolite repression in A. nidulans is a regulatory system which allows the organism to utilize the most preferable carbon source by repressing the expression of genes encoding enzymes utilizing alternative carbon sources. A ubiquitination pathway was shown to be one of the key mechanisms which regulate carbon source utilization, when creB was found to encode a deubiquitinating enzyme. Strains containing mutations in creB show loss of repression for some metabolic pathways in carbon catabolite repressing conditions, and also grow very poorly on several sole carbon sources such as quinate and proline, suggesting CreB plays multiple roles in the cell. This work describes the analysis of the interaction of CreB with CreA, and with PrnB and QutD. Various epitope-tagged versions of CreA were expressed in A. nidulans, and an internally located HA-epitope tag was found to allow detection of CreA using Western analysis. A diploid strain was constructed between strains containing HA-tagged CreA and FLAG-tagged CreB. When CreB was immunoprecipitated, HA-tagged CreA was also precipitated in the diploid, indicating that CreA and CreB are present in a complex in vivo. To determine whether CreA is a ubiquitinated protein, a version of CreA that was tagged with both an HA epitope and a His-tag was expressed in A. nidulans, and protein extracts were precipitated with an UbiQaptureâ„¢-Q matrix. Western analysis was used to show that CreA was present in the precipitate. These findings suggest that CreA is a ubiquitinated protein, and a target of the CreB deubiquitination enzyme. To determine whether the proline permease (PrnB) is a direct substrate of CreB, plasmids to express epitope-tagged versions of PrnB were constructed and introduced into the prnB mutant strain. No tagged protein could be detected by Western analysis, even when these constructs were over-expressed from the gpdA promoter. However, a construct to express an HA epitope tagged version of quinate permease (QutD) fully complemented the qutD mutant strain, and HA-tagged QutD could be easily detected in Western analysis when probed with the anti-HA monoclonal antibody. A diploid strain was made between a complementing transformant and a strain expressing a FLAG-tagged CreB construct. When QutDHA was immunoprecipitated, CreBFLAG was detected in the immunoprecipitate of the diploid. A proportion of QutDHA was also co-precipitated in the diploid when CreBFLAG was immunoprecipitated. Thus, CreB is present in a complex with QutD in vivo. Further results showed that the concentration of QutD in the cell is lower in a creB null mutant background than in the wild-type background, indicating that deubiquitination is required to prevent protein turnover. Northern analysis of mRNA showed that the failure of creB mutant strains to grow on quinate medium was not due to a failure of transcriptional induction of qutD, as the amount of mRNA was not lower in a creB1937 mutant background compared to the wild-type. Furthermore, experiments were undertaken that showed that QutD is a ubiquitinated protein. These findings suggest that quinate permease is regulated through deubiquitination involving the CreB deubiquitination protein in A. nidulans. In addition to the candidate protein approach asking whether CreA is a substrate of CreB, a proteomics approach was also used to identify proteins that interact with CreA. However, no clear interacting proteins were identified using this approach. / Thesis (Ph.D.) -- University of Adelaide, School of Molecular and Biomedical Science, 2008
| Identifer | oai:union.ndltd.org:ADTP/280309 |
| Date | January 2008 |
| Creators | Kamlangdee, Niyom |
| Source Sets | Australiasian Digital Theses Program |
| Detected Language | English |
Page generated in 0.0056 seconds