Single-molecule imaging reveals molecular coupling between transcription and DNA repair machinery in live cells

The Escherichia coli transcription-repair coupling factor Mfd displaces stalled RNA polymerase and delivers the stall site to the nucleotide excision repair factors UvrAB for damage detection. Whether this handoff from RNA polymerase to UvrA occurs via the Mfd-UvrA2-UvrB complex or alternate reaction intermediates in cells remains unclear. Here, we visualise Mfd in actively growing cells and determine the catalytic requirements for faithful recruitment of nucleotide excision repair proteins. We find that ATP hydrolysis by UvrA governs formation and disassembly of the Mfd-UvrA2 complex. Further, Mfd-UvrA2-UvrB complexes formed by UvrB mutants deficient in DNA loading and damage recognition are impaired in successful handoff. Our single-molecule dissection of interactions of Mfd with its partner proteins inside live cells shows that the dissociation of Mfd is tightly coupled to successful loading of UvrB, providing a mechanism via which loading of UvrB occurs in a strand-specific manner.

Diarylquinolines target subunit c of mycobacterial ATP synthase

The diarylquinoline R207910 (TMC207) is a promising candidate in clinical development for the treatment of tuberculosis. Though R207910-resistant mycobacteria bear mutations in ATP synthase, the compound's precise target is not known. Here we establish by genetic, biochemical and binding assays that the oligomeric subunit c (AtpE) of ATP synthase is the target of R207910. Thus targeting energy metabolism is a new, promising approach for antibacterial drug discovery.

Structure and Function of Subunit a of the ATP Synthase of Escherichia coli

The structure of subunit a of the Escherichia coli ATP synthase has been probed by construction of more than one hundred monocysteine substitutions. Surface labeling with 3-N-maleimidyl-propionyl biocytin (MPB) has defined five transmembrane helices, the orientation of the protein in the membrane, and information about the relative exposure of the loops connecting these helices. Cross-linking studies using TFPAM-3 (N-(4-azido-2,3,5,6-tetrafluorobenzyl)-3-maleimido-propionamide) and benzophenone-4-maleimide have revealed which elements of subunit a are near subunits b and c. Use of a chemical protease reagent, 5-(-bromoacetamido)-1,10-phenanthroline-copper, has indicated that the periplasmic end of transmembrane helix 5 is near that of transmembrane helix 2.

ATP Synthases With Novel Rotor Subunits: New Insights into Structure, Function and Evolution of ATPases

ATPases with unusual membrane-embedded rotor subunits were found in both F(1)F(0) and A(1)A(0) ATP synthases. The rotor subunit c of A(1)A(0) ATPases is, in most cases, similar to subunit c from F(0). Surprisingly, multiplied c subunits with four, six, or even 26 transmembrane spans have been found in some archaea and these multiplication events were sometimes accompanied by loss of the ion-translocating group. Nevertheless, these enzymes are still active as ATP synthases. A duplicated c subunit with only one ion-translocating group was found along with "normal" F(0) c subunits in the Na(+) F(1)F(0) ATP synthase of the bacterium Acetobacterium woodii. These extraordinary features and exceptional structural and functional variability in the rotor of ATP synthases may have arisen as an adaptation to different cellular needs and the extreme physicochemical conditions in the early history of life.

Photo-induced proton gradients and ATP biosynthesis produced by vesicles encapsulated in a silica matrix

Sol-gel immobilization of soluble proteins has proven to be a viable method for stabilizing a wide variety of proteins in transparent inorganic matrices. The encapsulation of membrane-bound proteins has received much less attention, although work in this area suggests potential opportunities in microarray technology and high-throughput drug screening. The present paper describes a liposome/sol-gel architecture in which the liposome provides membrane structure and protein orientation to two transmembrane proteins, bacteriorhodopsin (bR) and F(0)F(1)-ATP synthase; the sol-gel encapsulation converts the liposomal solution into a robust material without compromising the intrinsic activity of the incorporated proteins. Here we report on two different proteoliposome-doped gels (proteogels) whose properties are determined by the transmembrane proteins. Proteogels containing bR proteoliposomes exhibit a stable proton gradient when irradiated with visible light, whereas proteogels containing proteoliposomes with both bR and F(0)F(1)-ATP synthase couple the photo-induced proton gradient to the production of ATP. These results demonstrate that materials based on the liposome/sol-gel architecture are able to harness the properties of transmembrane proteins and enable a variety of applications, from power generation and energy storage to the powering of molecular motors, and represent a new technology for performing complex chemical synthesis in a solid-state matrix.

Subunit A of the E. coli ATP synthase: reconstitution and high resolution NMR with protein purified in a mixed polarity solvent

Subunit a of the Escherichia coli ATP synthase, a 30 kDa integral membrane protein, was purified to homogeneity by a novel procedure incorporating selective extraction into a monophasic mixture of chloroform, methanol and water, followed by Ni-NTA chromatography in the mixed solvent. Pure subunit a was reconstituted with subunits b and c and phospholipids to form a functional proton-translocating unit. Nuclear magnetic resonance (NMR) spectra of the pure subunit a in the mixed solvent show good chemical shift dispersion and demonstrate the potential of the solvent mixture for NMR studies of the large membrane proteins that are currently intractable in aqueous detergent solutions.

Mutation of the mitochrondrially encoded ATPase 6 gene modeled in the ATP synthase of Escherichia coli

Defects of respiratory chain protein complexes and the ATP synthase are becoming increasingly implicated in human disease. Recently, mutations in the ATPase 6 gene have been shown to cause several different neurological disorders. The product of this gene is homologous to the a subunit of the ATP synthase of Escherichia coli. Here, mutations equivalent to those described in humans have been introduced into the a subunit of E. coli by site-directed mutagenesis, and the effects of these mutations on the ATPase activity, ATP synthesis and ability of the enzyme to pump protons studied in detail. The effects of the mutations varied considerably. The mutation L262P (9185 T-C equivalent) caused a 70% loss of ATP synthesis activity, reduced DCCD sensitivity, and lowered proton pumping activity. The L207P (8993 T-C equivalent) reduced ATP synthesis by 50%, affected DCCD sensitivity, while proton pumping was only marginally affected when measured by the standard AMCA quenching assay. The other mutations studied affected the functioning of the ATP synthase much less. The results confirm that modeling of these point mutations in the E. coli enzyme is a useful approach to determining how alterations in the ATPase 6 gene affect enzyme function and, therefore, how a pathogenic effect can be exerted.

Amino acid substitutions in the a subunit affect the epsilon subunit of F1F0 ATP synthase from Escherichia coli

Amino acid substitutions at many positions in the a subunit of F1F0 ATP synthase result in impaired proton translocation and altered catalytic activity. In this work, we demonstrate that amino acid substitutions in the a subunit affect the epsilon subunit. In mutant F1F0 ATP synthases, the epsilon subunit was studied by determining its sensitivity to proteolysis and by chemical crosslinking under conditions of active turnover and in quiescent enzyme. Like native F1F0 ATP synthase, the epsilon subunit in enzymes carrying either the aarg-210-->ile or agly-218-->asp substitutions proved resistant to trypsin digestion during ATP hydrolysis. In each case, the epsilon subunit was rapidly digested in the presence of a nonhydrolyzable ligand, but this did not result in the activation of hydrolytic activity typically seen in wild-type enzyme. In enzyme carrying the aala-217-->arg substitution, the trypsin digestion of the epsilon subunit occurred regardless of ligand and was accompanied by a limited hydrolytic activation. Relative to the native F1F0 ATP synthase, the aala-217-->arg substitution resulted in reduced efficiency of crosslinking between the epsilon and beta subunits using 1-ethyl-3-[3-(dimethylamino)propyl]carbodiimide. These observations indicate that the structural changes resulting from amino acid substitutions in the a subunit are propagated to the epsilon subunit and are specific to the individual substitutions.

Deletions in the second stalk of F1F0-ATP synthase in Escherichia coli

In Escherichia coli F1F0-ATP synthase, the two b subunits form the second stalk spanning the distance between the membrane F0 sector and the bulk of F1. Current models predict that the stator should be relatively rigid and engaged in contact with F1 at fixed points. To test this hypothesis, we constructed a series of deletion mutations in the uncF(b) gene to remove segments from the middle of the second stalk of the subunit. Mutants with deletions of 7 amino acids were essentially normal, and those with deletions of up to 11 amino acids retained considerable activity. Membranes prepared from these strains had readily detectable levels of F1-ATPase activity and proton pumping activity. Removal of 12 or more amino acids resulted in loss of oxidative phosphorylation. Levels of membrane-associated F1-ATPase dropped precipitously for the longer deletions, and immunoblot analysis indicated that reductions in activity correlated with reduced levels of b subunit in the membranes. Assuming the likely alpha-helical conformation for this area of the b subunit, the 11-amino acid deletion would result in shortening the subunit by approximately 16 A. Since these deletions did not prevent the b subunit from participating in productive interactions with F1, we suggest that the b subunit is not a rigid rodlike structure, but has an inherent flexibility compatible with a dynamic role in coupling.

Identification of an intragenic ribosome binding site that affects expression of the uncB gene of the Escherichia coli proton-translocating ATPase (unc) operon

The uncB gene codes for the a subunit of the Fo proton channel sector of the Escherichia coli F1 Fo ATPase. Control of expression of uncB appears to be exerted at some step after translational initiation. Sequence analysis by the perceptron matrices (G. D. Stormo, T. D. Schneider, L. Gold, and A. Ehrenfeucht, Nucleic Acids Res. 10:2997-3011, 1982) identified a potential ribosome binding site within the uncB reading frame preceding a five-codon reading frame which is shifted one base relative to the uncB reading frame. Elimination of this binding site by mutagenesis resulted in a four- to fivefold increase in expression of an uncB'-'lacZ fusion gene containing most of uncB. Primer extension inhibition (toeprint) analysis to measure ribosome binding demonstrated that ribosomes could form an initiation complex at this alternative start site. Two fusions of lacZ to the alternative reading frame demonstrated that this site is recognized by ribosomes in vivo. The results suggest that expression of uncB is reduced by translational frameshifting and/or a translational false start at this site within the uncB reading frame.

Identification of an uncoupling mutation affecting the b subunit of F1F0 ATP synthase in Escherichia coli

A specific b subunit arginine, b(Arg-36) in Escherichia coli, displays evolutionary conservation among bacterial F1F0 ATP synthases. Site-directed mutagenesis was used to generate a collection of mutations affecting b(Arg-36). The phenotype differed depending upon the substitution, and the b(Arg-36-Glu) and b(Arg-36-Ile) substitutions virtually abolished enzyme function. Although the total amounts of F1F0 ATP synthase present in the membranes prepared from mutant strains were reduced, the primary effect of the b(Arg-36) substitutions was on the activities of the intact enzyme complexes. The most interesting result was that the b(Arg-36-Glu) substitution results in the uncoupling of a functional F0 from F1 ATP hydrolysis activity.

Cloning and nucleotide sequence analysis of the Streptococcus mutans membrane-bound, proton-translocating ATPase operon

The function of the membrane-bound ATPase in S. mutans is to regulate cytoplasmic pH values for the purpose of maintaining delta pH. Previous studies have shown that as part of its acid-adaptive ability, S. mutans is able to increase H(+)-ATPase levels in response to acidification. As part of the study of ATPase regulation in S. mutans, we have cloned the ATPase operon and determined its genetic organization. The structural genes from S. mutans were found to be in the order: c, a, b, delta, alpha, gamma, beta, and epsilon; where c and a were reversed from the more typical bacterial organization. The operon contained no I gene homologue but was preceded by a 239-bp intergenic space. Deduced aa sequences from open reading frames indicated that genes encoding homologues of glycogen phosphorylase and nonphosphorylating, NADP-dependent glyceraldehyde-3-phosphate dehydrogenase flank the H(+)-ATPase operon, 5' and 3' respectively. Sequence analysis indicated the presence of three inverted-repeat nt sequences in the glgP-uncE intergenic space. Primer extension analysis of mRNAs prepared from batch-grown or steady-state cultures demonstrated that the transcriptional start site did not change as a function of culture pH value. The data suggest that potential stem-and-loop structures in the promoter region of the operon do not function to alter the starting position of ATPase-specific mRNA transcription.

Degradation of Escherichia coli uncB mRNA by multiple endonucleolytic cleavages

The mechanism of segmental decay of the uncB sequence near the 5' end of the 7-kb Escherichia coli unc operon mRNA was investigated. Northern (RNA) blots of mRNA expressed from a plasmid carrying the uncBE portion of the operon revealed that the uncB message was rapidly degraded by multiple internal cleavages which resulted in the formation of at least five discrete species having a common 3' end. Turnover studies indicated that processing rapidly converted all species to the smallest. Identification of the 5' ends by primer extension analysis revealed that the cleavages were made either in the uncB coding region or in the intercistronic region between uncB and uncE, the latter being the most 3' cleavage. An rne mutant strain contained much higher levels of the uncBE message, implying that RNase E, the product of the rne gene, is essential for the normal degradation of uncB, and a number of the 5' ends were not detected in the rne mutant. The cleavage sites in chromosomally encoded unc mRNA were also identified by primer extension. These studies reveal that the segmental decay of the uncB region of unc mRNA occurs rapidly through a series of endonucleolytic cleavages. The rapid decay of uncB is expected to play a role in limiting expression of this gene relative to that of the other genes of the operon.

Expression of subunits a and c of the sodium-dependent ATPase of Propionigenium modestum in Escherichia coli

The aim of the present study was to construct functional hybrid ATPases consisting of all Escherichia coli ATPase subunits excepts the F0 subunits a or c which were replaced by the respective subunits of the Propionigenium modestum ATPase. This would give valuable information on the subunit(s) conferring the coupling ion specificity. Plasmids were constructed that carried the gene for subunit c (uncE) or subunit a (uncB) behind a tac promoter. These plasmids were transformed into E. coli strains which differed with respect to the unc operon and the expression of the P. modestum genes was verified biochemically. Enhanced expression of the P. modestum genes led to strong growth inhibition of all E. coli strains tested. However, the expressed P. modestum proteins could not functionally complement E. coli strains that lacked the homologous subunit.

Mutagenic analysis of the a subunit of the F1F0 ATP synthase in Escherichia coli: Gln-252 through Tyr-263

The a subunit of F1F0 ATP synthase contains a highly conserved region near its carboxyl terminus which is thought to be important in proton translocation. Cassette site-directed mutagenesis was used to study the roles of four conserved amino acids Gln-252, Phe-256, Leu-259, and Tyr-263. Substitution of basic amino acids at each of these four sites resulted in marked decreases in enzyme function. Cells carrying a subunit mutations Gln-252-->Lys, Phe-256-->Arg, Leu-259-->Arg, and Tyr-263-->Arg all displayed growth characteristics suggesting substantial loss of ATP synthase function. Studies of both ATP-driven proton pumping and proton permeability of stripped membranes indicated that proton translocation through F0 was affected by the mutations. Other mutations, such as the Phe-256-->Asp mutation, also resulted in reduced enzyme activity. However, more conservative amino acid substitutions generated at these same four positions produced minimal losses of F1F0 ATP synthase. The effects of mutations and, hence, the relative importance of the amino acids for enzyme function appeared to decrease with proximity to the carboxyl terminus of the a subunit. The data are most consistent with the hypothesis that the region between Gln-252 and Tyr-263 of the a subunit has an important structural role in F1F0 ATP synthase.

Regulation of the Escherichia coli uncH gene by mRNA secondary structure and translational coupling

The uncH gene is one of the most poorly-expressed genes of the proton-translocating ATPase (unc) operon of Escherichia coli. We constructed in-frame lacZ fusions to uncH and used site-directed mutagenesis to decrease the stability of the putative mRNA secondary structure in the Shine and Dalgarno region for this gene. These mutations significantly increased the expression of uncH. We also used the unc-lac fusions to show that the insertion of stop codons and a frameshift mutation in uncF, the gene preceding uncH, caused a 10-fold reduction in uncH expression. Hybridization of total cellular RNA with a lacZ-specific probe indicated that transcriptional polarity could not account for the observed decrease in gene expression. These results demonstrate that uncH expression is controlled by mRNA sequences around the translational initiation region, and is translationally coupled to uncF, even in cases where the putative mRNA secondary structure is weakened or eliminated.

Effects of inducing expression of cloned genes for the F0 proton channel of the Escherichia coli F1F0 ATPase

To evaluate whether expression of cloned genes for the F0 proton channel of the Escherichia coli F1F0 ATPase is sufficient to cause membrane proton permeability, plasmids carrying different combinations of the uncB, E, and F genes, encoding the a, c, and b subunits of the F0 sector, cloned behind the inducible lac promoter in pUC9 or pUC18, were constructed. The effects of inducing F0 synthesis in an unc deletion strain were monitored by measuring cell growth rate, quantitating F0 subunits by immunoblotting, and measuring the ability of membranes to maintain a respiration-induced proton gradient and to bind F1 and carry out energy-coupling reactions. The levels of functional reconstitutable F0 in membranes could be increased four- to sixfold with no change in cellular growth rate or membrane proton permeability (assayed by fluorescence quenching). These results were obtained in uninduced cultures, so the F0 genes were presumably being transcribed from some promoter besides lac. Induction of transcription of all three F0 genes produced increased amounts of F0 subunits in membranes as determined by immunoblot and F1-binding assays, but, when reconstituted with F1, the F0 in membranes isolated from induced cultures was significantly less functional than the F0 in membranes isolated from uninduced cultures. Such induction did result in growth inhibition, but there was no correlation between growth inhibition and either increased membrane proton permeability or the presence of functional, reconstitutable F0.