Expression, purification, and characterization of human acetyl-CoA carboxylase 2.

The full-length human acetyl-CoA carboxylase 1 (ACC1) was expressed and purified to homogeneity by two separate groups (Y.G. Gu, M. Weitzberg, R.F. Clark, X. Xu, Q. Li, T. Zhang, T.M. Hansen, G. Liu, Z. Xin, X. Wang, T. McNally, H. Camp, B.A. Beutel, H.I. Sham, Synthesis and structure-activity relationships of N-{3-[2-(4-alkoxyphenoxy)thiazol-5-yl]-1-methylprop-2-ynyl}carboxy derivatives as selective acetyl-CoA carboxylase 2 inhibitors, J. Med. Chem. 49 (2006) 3770-3773; D. Cheng, C.H. Chu, L. Chen, J.N. Feder, G.A. Mintier, Y. Wu, J.W. Cook, M.R. Harpel, G.A. Locke, Y. An, J.K. Tamura, Expression, purification, and characterization of human and rat acetyl coenzyme A carboxylase (ACC) isozymes, Protein Expr. Purif., in press). However, neither group was successful in expressing the full-length ACC2 due to issues of solubility and expression levels. The two versions of recombinant human ACC2 in these reports are either truncated (lacking 1-148 aa) or have the N-terminal 275 aa replaced with the corresponding ACC1 region (1-133 aa). Despite the fact that ACC activity was observed in both cases, these constructs are not ideal because the N-terminal region of ACC2 could be important for the correct folding of the catalytic domains. Here, we report the high level expression and purification of full-length human ACC2 that lacks only the N-terminal membrane attachment sequence (1-20 and 1-26 aa, respectively) in Trichoplusia ni cells. In addition, we developed a sensitive HPLC assay to analyze the kinetic parameters of the recombinant enzyme. The recombinant enzyme is a soluble protein and has a K(m) value of 2 microM for acetyl-CoA, almost 30-fold lower than that reported for the truncated human ACC2. Our recombinant enzyme also has a lower K(m) value for ATP (K(m)=52 microM). Although this difference could be ascribed to different assay conditions, our data suggest that the longer human ACC2 produced in our system may have higher affinities for the substrates and could be more similar to the native enzyme.

The Escherichia coli biotin regulatory system: a transcriptional switch.

The ability of any organism to survive depends, in part, on mechanisms that enable it to modify its patterns of gene expression in response to extra- and intracellular signals. In the classical response mechanisms, a small molecule signal impinges on either an extra- or intracellular receptor, and through a series of events the signal is ultimately transmitted to transcription regulatory proteins. An alternative to this classical mechanism is provided by multi-functional transcription factors. These proteins function directly in transcription as well as in at least one additional cellular process. An example of this class of proteins includes the dimerization cofactor of hepatocyte nuclear factor (DcoH), which serves as an enzyme involved in regeneration of the tetra-hydrobiopterin cofactor and as a factor that stabilizes the dimerization of the hepatocyte nuclear transcription factor (Mendel DB, Khavari PA, Conley PB, Graves MK, Hansen LP, Admon A, et al. Characterization of a cofactor that regulates dimerization of a mammalian homeodomain protein. Science 1991;254:1762-7; Citron BA, Davis MD, Milstien S, Gutierrez J, Mendel DB, Crabtree GR. Identity of 4a-carbinolamine dehydratase, a component of the phenylalanine hydroxylation system, and DCoH, a transregulator of homeodomain proteins. Proc Natl Acad Sci U S A 1992;89:11891-4). Another example is the protein PutA, a redox enzyme involved in proline utilization and a regulator of transcription of the genes involved in proline utilization (Ostrovsky de Spicer P, Maloy S. Puta protein, a membrane-associated flavin dehydrogenase, acts as a redox-dependent transcriptional regulator. Proc Natl Acad Sci U S A 1993;90:4295-8). While several proteins of this class have been identified, their mechanisms of functional switching remain to be elucidated.

Fatty acid synthesizing enzyme activity of cultured Mycobacterium lepraemurium.

In comparing the specific activity of enzymes pertaining to the biosynthesis of fatty acids in crude extracts of cultivated M. lepraemurium and M. smegmatis, it was found that: 1. The activity of acetyl CoA carboxylase of the former organism was undetectable and that of de novo fatty acid synthetase was too weak to measure exactly, under the condition used, whereas both activities of the latter organism were comparable to those already reported by other authors. 2. The activity of acetyl CoA dependent acyl CoA elongation system of M. lepraemurium was relatively high and close to that of M. smegmatis. 3. The activities of acetyl CoA synthetase and acyl CoA synthetase of M. lepraemurium were moderately lower than those of M. smegmatis. The relation between this peculiar fatty acid synthesizing enzyme system of M. lepraemurium and its extremely sluggish growth is discussed.