From the sequence alignment of GadX binding sites on btuB, gadA,

From the sequence alignment of GadX binding sites on btuB, gadA, and gadBC regulatory regions[42], we found that sequence in the region I (the 31 nucleotides) has 62.5% identity (+52-AGCGGTAAGGAAAGGTGCGATGATTGCGTTAT-+82, underlined nucleotides indicate the protected region) with gadBC and sequence in the region III (the 26 nucleotides) has 60.7% identity (+106-AAGTCATCATCTCTTAGTATCTTAGATA-+133, underlined nucleotides indicate the protected region)

with gadA regulatory region. From the footprinting result, the GadX binding sites on 5′ untranslated region of btuB share only partial homology with the 42 nucleotides consensus sequence which was reported by Tramonti et. al.[42]. #Doramapimod in vivo randurls[1|1|,|CHEM1|]# The sequence analysis also revealed the btuB expression was regulated by the binding of GadX on its 5′ untranslated region. Binding of transcriptional regulator to the 5′ untranslated region to regulate gene expression is also seen in the glp regulon of E. coli, in which four repressor binding sites are located at -41 to -60, -9 to -28, +12 to -8, and +52 to +33 of the glpACB genes MK-8931 supplier [43]. In addition, two

IHF binding sites are present downstream from the glpT transcriptional start site at positions +15 to +51 and +193 to +227 [44]. In the btuB promoter assay experiment, different lengths of DNA fragments containing btuB promoter were fused to lacZ. The minimum length of DNA fragment with btuB promoter activity was 461 bp spanning -219 to + 242 nucleotides relative to the translation initiation site of btuB. No significant difference in promoter activity was observed when the 5′ end of these fragments was extended to -671. However, a 6 fold (37.5 vs. 6.4 β-galactosidase units, Table 2) increase in promoter activity was detected when the DNA fragment was extended to -1043 with a total length of 1,285 bp as compared to that of the 461-bp fragment. It is very likely that a certain transcription regulator binds to the region between -1043 and -671 and enhances the expression of btuB. The β-galactosidase activity in these assays

was not very high because the lacZ fusions were constructed ZD1839 cost using the single copy plasmid vector pCC1Bac™ (Epicentre). The purpose of using the single copy number plasmid in this experiment was to mimic the natural state of btuB expression in E. coli. In fact, the promoter activity of btuB is lower than other membrane protein, we have determined the ompC promoter activity, under the same test condition the Miller’s Units of lacZ driven by ompC promoter is 8 folds higher than that of btuB (data not shown). Although the results of footprinting and reporter assay revealed that the GadX binding sites on btuB 5′ untranslated region share only partial homology with the GadX binding consensus sequence[42] and showing 50% down regulation in the reporter assay, the expression of btuB was indeed controlled by GadX.

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