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Investigation of the Growth Rate Change in Recombinant BCG which was cloned Mycobacterium tuberculosis Adenylate Kinase Mutation Gene or Human Muscle-type Adenylate Kinase Synthetic Gene  

Lee, Seung-Heon (Department of Molecular Biology, Korean Institute of Tuberculosis)
Kim, Hyo-Joon (Department of Biochemistry, Hanyang University College of Biotechnology)
Park, Young-Kil (Department of Molecular Biology, Korean Institute of Tuberculosis)
Bai, Gill-Han (Department of Molecular Biology, Korean Institute of Tuberculosis)
Publication Information
Tuberculosis and Respiratory Diseases / v.60, no.2, 2006 , pp. 187-193 More about this Journal
Abstract
Background : Normal cell proliferation and viability is strongly depends on the availability of metabolic energy and the maintenance of the appropriate adenylate-nucleotide pools. Hypothetically, changes in adenylate kinase (AK) expression could therefore be associated with adaptation to altered growth characteristics or inversely altered growth characteristics of proliferating cells could drive the changes in the metabolic profile. This study investigated whether the expression of either AK1 or a Mycobacterium tuberculosis adenylate kinase mutant which has the same catalytic activity of AK1 could affect the growth rate of slow-growing BCG. Method : Recombinant BCGs, which were cloned the human muscle-type adenylate kinase synthetic gene (AK1) and adenylate kinase mutation gene (AKmtDM) of Mycobacterium tuberculosis into the Mycobacterium/E.coli expression vectors, were constructed. Recombinant BCGs and wild-type BCG were cultured in 7H9 media and the optical density at 600nm was measured at intervals of 2-3 days. Result : There wasn't the growth rate change induced by AK1 or AKmtDM expression in recombinant BCGs. Conclusion : The expression of AK1 or Mycobacterium tuberculosis adenylate kinase mutant in BCG does not affect the growth rate of BCG.
Keywords
Adenylate kinase; Mutation; Growth rate; BCG;
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