9973348

pubmed:Citation

4

In many bacteria, including the enteric species Salmonella typhimurium and Escherichia coli, heme is synthesized starting from glutamate by a pathway in which the first committed step is catalyzed by the hemA gene product, glutamyl-tRNA reductase (HemA). We have demonstrated previously that when heme limitation is imposed on cultures of S. typhimurium, HemA enzyme activity is increased 10- to 25-fold. Western (immunoblot) analysis with monoclonal antibodies reactive with HemA revealed that heme limitation results in a corresponding increase in the abundance of the enzyme. Similar regulation was also observed for E. coli. The near absence of regulation of hemA-lac operon fusions suggested a posttranscriptional control. We report here the results of pulse-labeling and immunoprecipitation studies of this regulation. The principal mechanism that contributes to elevated HemA abundance is protein stabilization. The half-life of HemA protein is approximately 20 min in unrestricted cells but increases to >300 min in heme-limited cells. Similar regulation was observed for a HemA-LacZ hybrid protein containing almost all of the HemA protein (416 residues). Sodium azide prevents HemA turnover in vivo, suggesting a role for energy-dependent proteolysis. This was confirmed by the finding that HemA turnover is completely blocked in a lon clpP double mutant of E. coli. Each single mutant shows only a small effect. The ClpA chaperone, but not ClpX, is required for ClpP-dependent HemA turnover. A hybrid HemA-LacZ protein containing just 18 amino acids from HemA is also stabilized in the lon clpP double mutant, but this shorter fusion protein is not correctly regulated by heme limitation. We suggest that the 18 N-terminal amino acids of HemA may constitute a degradation tag, whose function is conditional and modified by the remainder of the protein in a heme-dependent way. Several models are discussed to explain why the turnover of HemA is promoted by Lon-ClpAP proteolysis only when sufficient heme is available.

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http://linkedlifedata.com/resource/pubmed/journal/2985120R

http://linkedlifedata.com/resource/pubmed/chemical/ATP-Dependent Proteases, http://linkedlifedata.com/resource/pubmed/chemical/Adenosine Triphosphatases, http://linkedlifedata.com/resource/pubmed/chemical/Aldehyde Oxidoreductases, http://linkedlifedata.com/resource/pubmed/chemical/ClpA protease, E coli, http://linkedlifedata.com/resource/pubmed/chemical/Endopeptidase Clp, http://linkedlifedata.com/resource/pubmed/chemical/Escherichia coli Proteins, http://linkedlifedata.com/resource/pubmed/chemical/Heat-Shock Proteins, http://linkedlifedata.com/resource/pubmed/chemical/Heme, http://linkedlifedata.com/resource/pubmed/chemical/Lon protein, E coli, http://linkedlifedata.com/resource/pubmed/chemical/Molecular Chaperones, http://linkedlifedata.com/resource/pubmed/chemical/Protease La, http://linkedlifedata.com/resource/pubmed/chemical/Recombinant Fusion Proteins, http://linkedlifedata.com/resource/pubmed/chemical/Serine Endopeptidases, http://linkedlifedata.com/resource/pubmed/chemical/glutamyl tRNA reductase

Feb

pubmed-author:ElliottMM, pubmed-author:ElliottTT, pubmed-author:WangLL

181

Y

2009-11-18

1999

West Virginia University Health Sciences Center, Morgantown, West Virginia 26506, USA.