Transcriptional control, translation and function of the products of the five open reading frames of the Escherichia coli nir operon

Five open reading frames designated nirB, nirD, nirE, nirC and cysG have been identified from the DNA sequence of the Escherichia coli nir operon. Complementation experiments established that the NirB, NirD and CysG polypeptides are essential and sufficient for NADH-dependent nitrite reductase activity (EC 1.6.6.4). A series of plasmids has been constructed in which each of the open reading frames has been fused in-phase with the beta-galactosidase gene, lacZ. Rates of beta-galactosidase synthesis during growth in different media revealed that nirB, -D, -E and -C are transcribed from the FNR-dependent promoter, p-nirB, located just upstream of the nirB gene: expression is co-ordinately repressed by oxygen and induced during anaerobic growth. Although the nirB, -D and -C open reading frames are translated into protein, no translation of nirE mRNA was detected. The cysG gene product is expressed from both p-nirB and a second, FNR-independent promoter, p-cysG, located within the nirC gene. No NADH-dependent nitrite reductase activity was detected in extracts from bacteria lacking either NirB or NirD, but a mixture of the two was as active as an extract from wild-type bacteria. Reconstitution of enzyme activity in vitro required stoichiometric quantities of NirB and NirD and was rapid and independent of the temperature during mixing. NirD remained associated with NirB during the initial stages of purification of the active enzyme, suggesting that NirD is a second structural subunit of the enzyme.     

On the binding of tRNA to Escherichia coli RNA polymerase. Interactions between the core enzyme, DNA and tRNA

We have investigated the interplay between the binding of tRNA and DNA to core RNA polymerase. We show that the monomer core enzyme can bind stably to either DNA or tRNA, whereas the dimer core can fix both DNA and tRNA in a stable ternary complex. We have examined the kinetics of the exchange between DNA and tRNA bound to the core enzyme. DNA bound to monomer core can be rapidly displaced by tRNA without prior dissociation of the core from the DNA. Similarly tRNA bound to the core can be displaced by DNA without prior dissociation of the tRNA. We confirm the result of Hinkle and Chamberlin [J. Mol. Biol. 70, 157-185 (1972)] that, in contrast, the core enzyme must first dissociate from one DNA molecule before it can transfer to another DNA. As this dissociation is very slow we suggest that, in vivo, the tRNA can act as a 'porter' providing the core enzyme with a more kinetically favourable path to transfer from one DNA site to another.     

Molecular genetic analysis of an FNR-dependent anaerobically inducible Escherichia coli promoter

From the effects of 13 deletions and three linker-scanner mutations at the Escherichia coli nirB promoter we have located sequences necessary for FNR-dependent induction of activity by anaerobiosis and further nitrite-dependent stimulation of expression. We describe a nirB promoter derivative that allows the cloning of 'cassettes' carrying different FNR-binding sequences and experiments in which a number of point mutations were introduced into these sequences. FNR-dependent stimulation of expression from the nirB promoter is critically dependent on the location of the FNR-binding site, and deletion or insertion of one base pair is sufficient to disrupt promoter function. We have transferred a number of cassette FNR-binding sequences from the nirB promoter to the unrelated melR promoter. The insertion of FNR-binding sequences at the melR promoter is sufficient to confer fnr-dependency on expression. However expression from these hybrid promoters is not as efficiently repressed during aerobic growth, suggesting that the function of bound FNR is dependent on the sequence context of the FNR-binding sequence.     

Domain structure, stability, and interactions of human complement C1s-: characterization of a derivative lacking most of the B chain

A better understanding of the structure and function of C1 requires knowledge of the regions (domains) of the subcomponents that are responsible for Ca2+-dependent assembly. Toward this end, C1-s was digested with trypsin in the presence of Ca2+, a treatment that rapidly degraded the B chain, leaving a 56-kDa fragment comprised of a complete A chain disulfide linked to a small (less than 4-kDa) residual piece of the B chain. The purified fragment, referred to as C1-s-A, was shown by fast exclusion chromatography to be similar to C1-s in its ability to (1) reversibly dimerize in the presence of Ca2+, (2) substitute for C1-s in the formation of C1-r2-s2 tetramers, and (3) associate with C1-r and C1q to form macromolecular C1. Although C1-s-A was itself catalytically and hemolytically inactive, it competitively inhibited the expression of the hemolytic activity of C1-s in a reconstitution assay. When heated in the absence of Ca2+, C1-s exhibited a low-temperature transition (LTT) near 31 degrees C and a high-temperature transition (HTT) near 51 degrees C, similar to those previously observed in the homologous protein C1-r [Busby, T. F., & Ingham, K. C. (1987) Biochemistry 26, 5564-5571]. The midpoint of the LTT was shifted to 58 degrees C in 5 mM Ca2+ whereas the HTT was unaffected by Ca2+. C1-s-A exhibited only a LTT whose midpoint and Ca2+ dependence were similar to those of the LTT in C1-s. The HTT, which was accompanied by a loss of esterolytic activity, was reproduced in a plasmin-derived fragment representing the catalytic domain. These results provide strong support for the structural and functional independence of the catalytic and interaction domains of C1-s and strengthen current models regarding the role of these domains in various interactions. They also provide direct proof for the occurrence of Ca2+ binding sites on the A chain and demonstrate that all or most of the sites on C1-s that are responsible for its interaction with C1-r and C1q are located on the A chain.