The bet regulon allows Escherichia coli to synthesize the osmoprotectant glycine betaine from choline. It comprises a regulatory gene, betI, and three structural genes: betT (choline porter), betA (choline dehydrogenase), and betB (betaine aldehyde dehydrogenase). The bet genes are regulated by oxygen, choline, and osmotic stress. Primer extension analysis identified two partially overlapping promoters which were responsible for the divergent expression of the betT and betIBA transcripts. The transcripts were initiated 61 bp apart. Regulation of the promoters was investigated by using cat (chloramphenicol acetyltransferase) and lacZ (-galactosidase) operon fusions. Mutation of betI on plasmid F2 revealed that BetI is a repressor which regulates both promoters simultaneously in response to the inducer choline. Both promoters remained inducible by osmotic stress in a betI mutant background. On the basis of experiments with hns and hns rpoS mutants, we conclude that osmoregulation of the bet promoters was hns independent. The bet promoters were repressed by ArcA under anaerobic growth conditions. An 89-bp promoter fragment, as well as all larger fragments tested, which included both transcriptional start points, displayed osmotic induction and BetI-dependent choline regulation when linked with a cat reporter gene on plasmid pKK232-8. Flanking DNA, presumably on the betT side of the promoter region, appeared to be needed for ArcA-dependent regulation of both promoters.Hyperosmotically stressed cells of Escherichia coli build up the cytoplasmic osmolarity by accumulation of potassium glutamate and various osmoprotectants (12). The highest osmotolerance is achieved by the accumulation of glycine betaine (hereafter called betaine) (49). Betaine can either be taken up by the ProU and ProP systems (7,8,37) or be synthesized by the Bet system, i.e., the choline-to-betaine pathway (31). Synthesis of betaine requires an external supply of choline or the intermediate metabolite betaine aldehyde. At low external concentrations, choline is mainly taken up by the high-affinity choline porter BetT (K m ϭ 8 M), whereas at higher concentrations choline is also taken up by ProU (K m ϭ 1.5 mM) (30, 50). Oxygen-dependent choline dehydrogenase (BetA) catalyzes both steps in the oxidation of choline to betaine by the way of betaine aldehyde, whereas NAD-dependent betaine aldehyde dehydrogenase (BetB) is specific for the last step (1, 31).Biochemical data have previously revealed that expression of the Bet system is reduced under anaerobic conditions. For aerobic cells, osmotic stress gives a partial induction, but for full expression, the cells also need an external supply of choline (31). Experiments with lacZ fusions showed that the regulation occurs at the level of transcription (16).The DNA sequence of the bet region has revealed that in addition to the structural genes, the bet system encodes a regulatory protein called BetI. Albeit BetI shares some sequence homology with the TetR family of bacterial regulatory proteins (29), Bet...
