Site-directed alterations in the ATP-binding domain of rho protein affect its activities as a termination factor

Identification and subcellular localization of splicing factor arginine/serine-rich 10 in the microsporidian Nosema bombycis

Splicing factors are important components of RNA editing in eukaryotic organisms and can produce many functional and coding genes, which is an indispensable step for the correct expression of corresponding proteins. In this study, we identified splicing factor arginine/serine-rich 10 protein in the microsporidian Nosema bombycis and named it NbSRSF10. The NbSRSF10 gene contains a complete ORF of 1449 bp in length that encodes a 482-amino acid polypeptide. The isoelectric point (pI) of the protein encoded by NbSRSF10 gene was 4.94. NbSRSF10 has a molecular weight of 54.6 k_D and has no signal peptide. NbSRSF10 is comprised of arginine (11.41%), glutamic acid (11.41%) and serine (9.54%) among the total amino acids, and 7 α-helix, 7 β-sheet and 15 random coils in secondary structure, and contains 71 phosphorylation sites, 22 N-glycosylation sites and 20 O-glycosylation sites. The three-dimensional structure of NbSRSF10 is similar to that of transformer-2 beta of Homo sapiens (hTra2-β). Indirect immunofluorescence showed that the NbSRSF10 is localized in the cytoplasm of the dormant microsporidian spore and is transferred to the nuclei when N. bombycis develops into the proliferative and sporogonic phase. qPCR revealed that the relative expression of NbSRSF10 increased in the meronts stage and was found at a relatively low level in the sporogonic phase of development of N. bombycis, and was up-regulated again during infection in the host cell and early proliferative phase of second life cycle. These results suggested that the NbSRSF10 may participate in the whole life cycle and play an important role in transcription regulation of N. bombycis.

Regulated chloroplast transcription termination

Transcription termination by the RNA polymerase (RNAP) is a fundamental step of gene expression that involves the release of the nascent transcript and dissociation of the RNAP from the DNA template. However, the functional importance of termination extends beyond the mere definition of the gene borders. Chloroplasts originate from cyanobacteria and possess their own gene expression system. Plastids have a unique hybrid transcription system consisting of two different types of RNAPs of dissimilar phylogenetic origin together with several additional nuclear encoded components. Although the basic components involved in chloroplast transcription have been identified, little attention has been paid to the chloroplast transcription termination. Recent identification and functional characterization of novel factors in regulating transcription termination in Arabidopsis chloroplasts via genetic and biochemical approaches have provided insights into the mechanisms and significance of transcription termination in chloroplast gene expression. This review provides an overview of the current knowledge of the transcription termination in chloroplasts.

Rho Protein: Roles and Mechanisms

At the end of the multistep transcription process, the elongating RNA polymerase (RNAP) is dislodged from the DNA template either at specific DNA sequences, called the terminators, or by a nascent RNA-dependent helicase, Rho. In Escherichia coli, about half of the transcription events are terminated by the Rho protein. Rho utilizes its RNA-dependent ATPase activities to translocate along the mRNA and eventually dislodges the RNAP via an unknown mechanism. The transcription elongation factor NusG facilitates this termination process by directly interacting with Rho. In this review, we discuss current models describing the mechanism of action of this hexameric transcription terminator, its regulation by different cis and trans factors, and the effects of the termination process on physiological processes in bacterial cells, particularly E. coli and Salmonella enterica Typhimurium.

The role of recombination in evolutionary adaptation of Escherichia coli to a novel nutrient

The benefits and detriments of recombination for adaptive evolution have been studied both theoretically and experimentally, with conflicting predictions and observations. Most pertinent experiments examine recombination's effects in an unchanging environment and do not study its genomewide effects. Here, we evolved six replicate populations of either highly recombining R⁺ or lowly recombining R^- E. coli strains in a changing environment, by introducing the novel nutrients L-arabinose or indole into the environment. The experiment's ancestral strains are not viable on these nutrients, but 130 generations of adaptive evolution were sufficient to render them viable. Recombination conferred a more pronounced advantage to populations adapting to indole. To study the genomic changes associated with this advantage, we sequenced the genomes of 384 clones isolated from selected replicates at the end of the experiment. These genomes harbour complex changes that range from point mutations to large-scale DNA amplifications. Among several candidate adaptive mutations, those in the tryptophanase regulator tnaC stand out, because the tna operon in which it resides has a known role in indole metabolism. One of the highly recombining populations also shows a significant excess of large-scale segmental DNA amplifications that include the tna operon. This lineage also shows a unique and potentially adaptive combination of point mutations and DNA amplifications that may have originated independently from one another, to be joined later by recombination. Our data illustrate that the advantages of recombination for adaptive evolution strongly depend on the environment and that they can be associated with complex genomic changes.

RecA K72R filament formation defects reveal an oligomeric RecA species involved in filament extension

Using an ensemble approach, we demonstrate that an oligomeric RecA species is required for the extension phase of RecA filament formation. The RecA K72R mutant protein can bind but not hydrolyze ATP or dATP. When mixed with other RecA variants, RecA K72R causes a drop in the rate of ATP hydrolysis and has been used to study disassembly of hydrolysis-proficient RecA protein filaments. RecA K72R filaments do not form in the presence of ATP but do so when dATP is provided. We demonstrate that in the presence of ATP, RecA K72R is defective for extension of RecA filaments on DNA. This defect is partially rescued when the mutant protein is mixed with sufficient levels of wild type RecA protein. Functional extension complexes form most readily when wild type RecA is in excess of RecA K72R. Thus, RecA K72R inhibits hydrolysis-proficient RecA proteins by interacting with them in solution and preventing the extension phase of filament assembly.

The nuts and bolts of ring-translocase structure and mechanism

Ring-shaped, oligomeric translocases are multisubunit enzymes that couple the hydrolysis of Nucleoside TriPhosphates (NTPs) to directed movement along extended biopolymer substrates. These motors help unwind nucleic acid duplexes, unfold protein chains, and shepherd nucleic acids between cellular and/or viral compartments. Substrates are translocated through a central pore formed by a circular array of catalytic subunits. Cycles of nucleotide binding, hydrolysis, and product release help reposition translocation loops in the pore to direct movement. How NTP turnover allosterically induces these conformational changes, and the extent of mechanistic divergence between motor families, remain outstanding problems. This review examines the current models for ring-translocase function and highlights the fundamental gaps remaining in our understanding of these molecular machines.

Mutagenesis-based evidence for an asymmetric configuration of the ring-shaped transcription termination factor Rho

Transcription termination factor Rho is an ATP-dependent ring-shaped molecular motor that tracks along RNA to dissociate RNA-DNA duplexes and transcription complexes in its path. The Rho hexamer contains two distinct sites for interaction with RNA. The primary binding site is composed of pyrimidine-specific binding clefts that are located in the N-terminal domains and anchor Rho to transcripts at C-rich Rut (Rho utilization) sites. Components of the secondary binding site (SBS) in the C-terminal domains directly couple RNA binding to ATP hydrolysis in order to translocate RNA through the Rho ring. Published crystal structures of RNA-bound Rho display distinct architectures ('trimer-of-dimers' or asymmetric hexamer) and SBS-RNA interaction networks that suggested conflicting models of RNA "handoff" or "escort" by the Rho subunits. To probe the mechanism of mechanochemical transduction in Rho, we have mutated into alanines (or glycines) the residues that make SBS contacts with RNA in the 'trimer-of-dimers' structure supporting the "handoff" model. We find that the resulting single-point mutants have similar RNA binding affinities but exhibit significantly different ATP hydrolysis, transcription termination, and RNA-DNA unwinding activities that are more compatible with the asymmetric Rho structure than with the 'trimer-of-dimers' structure and the resulting "handoff" model. We discuss our findings in connection with specific features of the asymmetric Rho structure yet argue that a simple RNA "escort" model is insufficient to account for all experimental evidence.

Evidence for amino acid roles in the chemistry of ATP hydrolysis in Escherichia coli Rho

Many proteins that hydrolyze ATP or GTP have comparable amino acid residues for which specific roles have been proposed in a mechanism for the chemistry of hydrolysis. These roles include polarization by a glutamate residue of a water molecule for the attack on the γ-phosphoryl group of the nucleotide, stabilization of the transition state by an arginine finger, discrimination between bound nucleoside triphosphate and diphosphate by a γ sensor residue, and coordination by an aspartate of the Mg(2+) that accompanies the substrate nucleotide. We mutated four candidate residues for these roles in the Escherichia coli transcription termination factor Rho, E211, R366, R212, and D265, and characterized the resulting proteins for oligomerization state, ligand binding, RNA-dependent ATP hydrolysis, and, in rapid mix/chemical quench experiments, achievement of the chemistry step of hydrolysis. All four mutant proteins behaved as expected for Rhos lacking the proposed mechanistic roles. The results provide firm biochemical evidence in support of the proposed model for hydrolysis chemistry.

A superfamily 3 DNA helicase encoded by plasmid pSSVi from the hyperthermophilic archaeon Sulfolobus solfataricus unwinds DNA as a higher-order oligomer and interacts with host primase

Replication proteins encoded by nonconjugative plasmids from the hyperthermophilic archaea of the order Sulfolobales show great diversity in amino acid sequence. We have biochemically characterized ORF735, a replication protein from pSSVi, an integrative nonconjugative plasmid from Sulfolobus solfataricus P2. We show that ORF735 is a DNA helicase of superfamily 3. It unwound double-stranded DNA (dsDNA) in a 3'-to-5' direction in the presence of ATP over a wide range of temperatures, from 37 degrees C to 75 degrees C, and possessed DNA-stimulated ATPase activity. ORF735 existed in solution as a salt-stable dimer and was capable of assembling into a salt-sensitive oligomer that was significantly larger than a hexamer in the presence of a divalent cation (Mg(2+)) and an adenine nucleotide (ATP, dATP, or ADP) or its analog (ATPgammaS or AMPPNP). Both N-terminal and C-terminal portions of ORF735 (87 and 160 amino acid residues, respectively, in size) were required for protein dimerization but dispensable for the formation of the higher-order oligomer. The protein unwound DNA only as a large oligomer. Yeast two-hybrid and coimmunoprecipitation assays revealed that ORF735 interacted with the noncatalytic subunit of host primase. These findings provide clues to the functional role of ORF735 in pSSVi DNA replication.

How integration of positive and negative regulatory signals by a STAND signaling protein depends on ATP hydrolysis

The role of nucleotide hydrolysis in signaling by signal transduction ATPases with numerous domains (STAND) is poorly understood. Here we use MalT, the transcription activator of the Escherichia coli maltose regulon, as a model system to address this question. We have constructed the MalT-D129A variant that binds ATP but does not hydrolyze it and have characterized it in vivo and in vitro. ATP hydrolysis is not essential for transcription activation but is crucial in controlling MalT activity. MalT cycles between an ADP-bound, resting form that is the target of negative effectors and an ATP-bound, active form, which oligomerizes. Conversion to the active form involves nucleotide exchange and depends on maltotriose binding, whereas resetting to the inactive state relies on ATP hydrolysis, which ensues MalT multimerization. Such a controlled binary switch most likely applies to the other STAND NTPases, including Apaf-1 and the human innate immunity proteins NOD2, and CIAS1.

Structural insights into RNA-dependent ring closure and ATPase activation by the Rho termination factor

Hexameric helicases and translocases are required for numerous essential nucleic-acid transactions. To better understand the mechanisms by which these enzymes recognize target substrates and use nucleotide hydrolysis to power molecular movement, we have determined the structure of the Rho transcription termination factor, a hexameric RNA/DNA helicase, with single-stranded RNA bound to the motor domains of the protein. The structure reveals a closed-ring "trimer of dimers" conformation for the hexamer that contains an unanticipated arrangement of conserved loops required for nucleic-acid translocation. RNA extends across a shallow intersubunit channel formed by conserved amino acids required for RNA-stimulated ATP hydrolysis and translocation and directly contacts a conserved lysine, just upstream of the catalytic GKT triad, in the phosphate-binding (P loop) motif of the ATP-binding pocket. The structure explains the molecular effects of numerous mutations and provides new insights into the links between substrate recognition, ATP turnover, and coordinated strand movement.

Bismuth–dithiol inhibition of the Escherichia coli rho transcription termination factor

Bismuth-dithiol mixtures are proven antimicrobial agents with unknown mechanism(s) of action. We show that select bismuth-dithiol solutions inhibit the Escherichia coli rho transcription termination factor. Rho is an essential enzyme in most Gram-negative prokaryotes and without rho function the cells are not viable. Bismuth complexes with 2,3-dimercapto-1-propanol (BiBAL) (3:1 solutions) functioned as a noncompetitive inhibitor with respect to ATP in the rho poly(C)-dependent ATPase assay (I50=60 microM) and as a competitive inhibitor with respect to ribo(C)10 in the poly(dC)-ribo(C)10-dependent ATPase assay. The minimum inhibitory concentration (MIC) of bacterial growth for BiBAL (3:1) in the liquid culture assay using E. coli W3350 was 16 microM. Using the tnaA/lacZ fusion reporter assay we showed that sublethal amounts (3 microM) of BiBAL (3:1 solution) led to a small increase (37%) in in vivo beta-galactosidase activity in E. coli SVS1144, which corresponds to antitermination of the tna operon as a result of rho inhibition. We concluded that BiBAL was a potent in vitro rho inhibitor but its effect on in vivo rho processes was modest indicating that other mechanisms contributed to the antibacterial activity of BiBAL. Our study suggests that structural changes in the dithiol unit that provide greater bismuth binding may improve rho specificity, a macromolecular target not previously recognized for bismuth therapy.

The binding of C10 oligomers to Escherichia coli transcription termination factor Rho

The binding of C10 RNA oligomers to wild type and mutant Escherichia coli transcription termination factor Rho provides a model for the enzyme-RNA interactions that lead to transcription termination. One surprising finding is that wild type Rho binds between five and six C10 oligomers per hexamer with KD = 0.3 microm, and five to six additional C10 molecules with KD = 7 microm. Previously, approximately half this number of oligomer-binding sites was reported (Wang, Y., and von Hippel, P. H. (1993) J. Biol. Chem. 268, 13947-13955); however, the E155K mutant form of Rho, thought at the time to be wild type, was used in that work. The present results with E155K Rho agree with the earlier work. C10 binding with mutant forms of Rho that are altered in RNA interactions, bearing amino acid changes F62S, G99V, F232C, T286A, or K352E, indicate that the higher affinity binding sites constitute what has been termed the primary RNA site, and the lower affinity sites constitute the secondary sites. The binding data together with the crystal structures for wild type Rho (Skordalakes, E., and Berger, J. M. (2003) Cell 114, 135-146) support structurally distinct locations on Rho for the two classes of C10-binding sites. The results are consistent with participation of residues 33 A apart in secondary site RNA interactions. The data further indicate that not all RNA sites on Rho must be filled for full ATPase and transcription termination activity, and suggest a model in which RNA binding to the higher affinity sites leads to a protein conformation change that exposes the previously hidden lower affinity sites.

Structure and function of hexameric helicases

Helicases are motor proteins that couple the hydrolysis of nucleoside triphosphate (NTPase) to nucleic acid unwinding. The hexameric helicases have a characteristic ring-shaped structure, and all, except the eukaryotic minichromosomal maintenance (MCM) helicase, are homohexamers. Most of the 12 known hexameric helicases play a role in DNA replication, recombination, and transcription. A human genetic disorder, Bloom's syndrome, is associated with a defect in one member of the class of hexameric helicases. Significant progress has been made in understanding the biochemical properties, structures, and interactions of these helicases with DNA and nucleotides. Cooperativity in nucleotide binding was observed in many, and sequential NTPase catalysis has been observed in two proteins, gp4 of bacteriophage T7 and rho of Escherichia coli. The crystal structures of the oligomeric T7 gp4 helicase and the hexamer of RepA helicase show structural features that substantiate the observed cooperativity, and both are consistent with nucleotide binding at the subunit interface. Models are presented that show how sequential NTP hydrolysis can lead to unidirectional and processive translocation. Possible unwinding mechanisms based on the DNA exclusion model are proposed here, termed the wedge, torsional, and helix-destabilizing models.

MgATP binding and hydrolysis determinants of NtrC, a bacterial enhancer-binding protein

When phosphorylated, the dimeric form of nitrogen regulatory protein C (NtrC) of Salmonella typhimurium forms a larger oligomer(s) that can hydrolyze ATP and hence activate transcription by the sigma(54)-holoenzyme form of RNA polymerase. Studies of Mg-nucleoside triphosphate binding using a filter-binding assay indicated that phosphorylation is not required for nucleotide binding but probably controls nucleotide hydrolysis per se. Studies of binding by isothermal titration calorimetry indicated that the apparent K(d) of unphosphorylated NtrC for MgATPgammaS is 100 microM at 25 degrees C, and studies by filter binding indicated that the concentration of MgATP required for half-maximal binding is 130 microM at 37 degrees C. Filter-binding studies with mutant forms of NtrC defective in ATP hydrolysis implicated two regions of its central domain directly in nucleotide binding and three additional regions in hydrolysis. All five are highly conserved among activators of sigma(54)-holoenzyme. Regions implicated in binding are the Walker A motif and the region around residues G355 to R358, which may interact with the nucleotide base. Regions implicated in nucleotide hydrolysis are residues S207 and E208, which have been proposed to lie in a region analogous to the switch I effector region of p21(ras) and other purine nucleotide-binding proteins; residue R294, which may be a catalytic residue; and residue D239, which is the conserved aspartate in the putative Walker B motif. D239 appears to play a role in binding the divalent cation essential for nucleotide hydrolysis. Electron paramagnetic resonance analysis of Mn(2+) binding indicated that the central domain of NtrC does not bind divalent cation strongly in the absence of nucleotide.

Identifying the bicyclomycin binding domain through biochemical analysis of antibiotic-resistant rho proteins

Mutations M219K, S266A, and G337S in transcription termination factor Rho have been shown to confer resistance to the antibiotic bicyclomycin (BCM). All three His-tagged mutant Rho proteins exhibited similar Km values for ATP; however, the Vmax values at infinite ATP concentrations were one-fourth to one-third that for the His-tagged wild-type enzyme. BCM inhibition kinetics of poly(C)-dependent ATPase activity for the mutant proteins were non-competitive with respect to ATP (altering catalytic function but not ATP binding) and showed increased Ki values compared with His-tagged wild-type Rho. M219K and G337S exhibited increased ratios of poly(U)/poly(C)-stimulated ATPase activity and lower apparent Km values for ribo(C)10 in the poly(dC).ribo(C)10-dependent ATPase assay compared with His-tagged wild-type Rho. The S266A mutation did not show an increased poly(U)/poly(C) ATPase activity ratio and maintained approximately the same Km for ribo(C)10 in the poly(dC). ribo(C)10-dependent ATPase assay. The kinetic studies indicated that M219K and G337S altered the secondary RNA binding domain in Rho whereas the S266A mutation did not. Transcription termination assays for each mutant showed different patterns of Rho-terminated transcripts. Tyrosine substitution of Ser-266 led to BCM sensitivity intimating that an OH (hydroxyl) moiety at this position is needed for BCM (binding) inhibition. Our results suggest BCM binds to Rho at a site distinct from both the ATP and the primary RNA binding domains but close to the secondary RNA-binding (tracking) site and the ATP hydrolysis pocket.

The quaternary geometry of transcription termination factor rho: assignment by chemical cross-linking

Transcription termination factor rho from Escherichia coli is a ring-shaped homohexamer of 419 amino acid subunits and catalyzes an ATP-dependent release of nascent RNA transcripts. Previous chemical cross-linking studies suggested that the rho hexamer might have D3 symmetry with three isologous dimers as protomers. However, our recent mutational analysis of rho alongside its putative structural homology to F1-ATPase rather argued for C6 symmetry. To resolve this discrepancy, we have re-investigated the pattern of cross-linking of rho using various cross-linkers with different functional groups and spacer lengths. Upon reaction with dimethyl suberimidate followed by SDS-polyacrylamide gel electrophoresis, rho protein generated a series of cross-linked oligomers up to hexamers, of which dimers migrated as distinct doublet bands of approximately equal intensities. However, the lower band became much stronger than the upper one with dimethyl adipimidate and difluorodinitrobenzene, and vice versa with disuccinimidyl glutarate, disuccinimidyl suberate and disulfosuccinimidyl tartarate. Furthermore, the trimeric products also produced doublet bands, whose relative intensities were again variable with cross-linkers, but in an inverse correlation with those of the dimer bands. These results combined with theoretical considerations support a C6 symmetry model in which cross-linking is assumed to occur stochastically at one of two alternative sites within each subunit interface with variable relative frequencies depending on cross-linkers. The D3 symmetry is excluded, for the putative trimeric subspecies should always retain mutually equal intensities in that case. Detailed inspections of the cross-linking kinetics further revealed a moderate characteristic of C3 symmetry for the rho hexamer such that the collective as well as relative rates of cross-linking at the two available sites could fluctuate between alternating interfaces. The final model designated as C3/6 is also compatible with other functional and structural properties known for rho.

The antibiotic bicyclomycin affects the secondary RNA binding site of Escherichia coli transcription termination factor Rho

The interaction of Rho and the antibiotic bicyclomycin was probed using in vitro transcription termination reactions, poly(C) binding assays, limited tryptic digestions, and the bicyclomycin inhibition kinetics of ATPase activity in the presence of poly(dC) and ribo(C)10. The approximate I50 value for the bicyclomycin inhibition of transcription termination at Rho-dependent sites within a modified trp operon template was 5 microM. At antibiotic concentrations near the I50 value, bicyclomycin inhibition of Rho-dependent transcripts was accompanied by the appearance of a new set of transcripts whose size was midway between the Rho-dependent transcripts and the readthrough transcripts. Bicyclomycin did not inhibit poly(C) binding to Rho. In the presence of poly(dC), bicyclomycin showed a reversible mixed inhibition of the ribo(C)10-stimulated ATPase activity. The extrapolated Ki for bicyclomycin was 2.8 microM without ribo(C)10 and increased to 26 microM in the presence of ribo(C)10. Correspondingly, the Km(app) for ribo(C)10 without bicyclomycin was 0.8 microM and with bicyclomycin was 5 microM at infinite inhibitor concentration. The data suggested that the antibiotic binds to Rho, influencing the secondary RNA binding (tracking) site on Rho and slows the tracking of Rho toward the bound RNA polymerase.

The Rhodobacter sphaeroides 2.4.1 rho gene: expression and genetic analysis of structure and function

The gene which encodes transcription termination factor Rho from Rhodobacter sphaeroides 2.4.1, the gram-negative facultative photosynthetic bacterium, has been cloned and sequenced. The deduced protein shows a high level of sequence similarity to other bacterial Rho factors, especially those from proteobacteria. However, several amino acid substitutions in the conserved ATP-binding site have been identified. When expressed in Escherichia coli, the R. sphaeroides rho gene relieves Rho-dependent polarity of the trp operon, indicating interference with the transcription termination machinery of E. coli. A truncated version of R. sphaeroides Rho (Rho') is toxic to a bacterium related to R. sphaeroides, Paracoccus denitrificans, and is lethal to R. sphaeroides. We suggest that toxicity is due to the ability of Rho' to form inactive heteromers with the chromosomally encoded intact Rho. We localized a minimal amino acid sequence within Rho which appears to be critical for its toxic effect and which we believe may be involved in protein-protein interactions. This region was previously reported to be highly conserved and unique among various Rho proteins. The lethality of rho' in R. sphaeroides together with our inability to obtain a null mutation in rho suggests that Rho-dependent transcription termination is essential in R. sphaeroides. This is analogous to what is observed for gram-negative E. coli and contrasts with what is observed for gram-positive Bacillus subtilis. The genetic region surrounding the R. sphaeroides rho gene has been determined and found to be different compared with those of other bacterial species. rho is preceded by orf1, which encodes a putative integral membrane protein possibly involved in cytochrome formation or functioning. The gene downstream of rho is homologous to thdF, whose product is involved in thiophene and furan oxidation.

A mutation in the ATP binding domain of rho alters its RNA binding properties and uncouples ATP hydrolysis from helicase activity

The Escherichia coli mutant rho201 was originally isolated in a genetic screen for defects in rho-dependent termination. Cloning and sequencing of this gene reveals a single phenylalanine to cysteine mutation at residue 232 in the ATP binding domain of the protein. This mutation significantly alters its RNA binding properties so that it binds trp t', RNA 100-fold weaker than the wild type protein, with a Kd of approximately 1.3 nM. Rho201 binds nonspecific RNA only 3-4-fold less tightly than it binds trp t', while the wild type differential for these same RNAs is 10-20-fold. Curiously, rho201 displays increased secondary site RNA activation, with a Km for ribo(C)10 of 0.6 microM, compared to the wild type value of 3-4 microM. Although rho201 and the wild type protein hydrolyze ATP similarly with poly(C), or trp t' RNA, as cofactors, rho201 has a higher ATPase activity when activated by nonspecific RNA. Physically, rho201 displays an abnormal conformation detectable by mild trypsin digestion. Despite effective ATP hydrolysis, the rho201 mutant is a poor RNA:DNA helicase and terminates inefficiently on trp t'. The single F232C mutation thus appears to uncouple the protein's ATPase activity from its helicase function, so rho can no longer harness available energy for use in subsequent reactions.

An essential virulence protein of Agrobacterium tumefaciens, VirB4, requires an intact mononucleotide binding domain to function in transfer of T-DNA

The 11 gene products of the Agrobacterium tumefaciens virB operon, together with the VirD4 protein, are proposed to form a membrane complex which mediates the transfer of T-DNA to plant cells. This study examined one putative component of that complex, VirB4. A deletion of the virB4 gene on the Ti plasmid pTiA6NC was constructed by replacing the virB4 gene with the kanamycin resistance-conferring nptII gene. The virB4 gene was found to be necessary for virulence on plants and for the transfer of IncQ plasmids to recipient cells of A. tumefaciens. Genetic complementation of the deletion strain by the virB4 gene under control of the virB promoter confirmed that the deletion was nonpolar on downstream virB genes. Genetic complementation was also achieved with the virB4 gene placed under control of the lac promoter, even though synthesis of the VirB4 protein from this promoter is far below wild-type levels. Having shown a role for the VirB4 protein in DNA transfer, lysine-439, found within the conserved mononucleotide binding domain of VirB4, was changed to a glutamic acid, methionine, or arginine by oligonucleotide-directed mutagenesis. virB4 genes bearing these mutations were unable to complement the virB4 deletion for either virulence or for IncQ transfer, showing that an intact mononucleotide binding site is necessary for the function of VirB4 in DNA transfer. The necessity of the VirB4 protein with an intact mononucleotide binding site for extracellular complementation of virE2 mutants was also shown. In merodiploid studies, lysine-439 mutations present in trans decreased IncQ plasmid transfer frequencies, suggesting that VirB4 functions within a complex to facilitate DNA transfer.

DPY-27:a chromosome condensation protein homolog that regulates C. elegans dosage compensation through association with the X chromosome

dpy-27 is an essential dosage compensation gene that acts to reduce expression of both hermaphrodite X chromosomes. The DPY-27 protein becomes specifically localized to the X chromosomes of wild-type XX embryos, but remains diffusely distributed throughout the nuclei of male (XO) embryos. In xol-1 mutant XO embryos that activate the XX mode of dosage compensation and die from inappropriately low X chromosome transcript levels, DPY-27 becomes localized to X. Therefore, sex specificity of the dosage compensation process is regulated at the step of DPY-27 X chromosome localization. DPY-27 exhibits striking similarity to proteins required for assembly and structural maintenance of Xenopus chromosomes in vitro and for segregation of yeast chromosomes in vivo. These findings suggest a link between global regulation of gene expression and higher order chromosome structure. We propose that DPY-27 implements dosage compensation by condensing the chromatin structure of X in a manner that causes general reduction of X chromosome expression.

Phylogenetic analysis of sequences from diverse bacteria with homology to the Escherichia coli rho gene

Genes from Pseudomonas fluorescens, Chromatium vinosum, Micrococcus luteus, Deinococcus radiodurans, and Thermotoga maritima with homology to the Escherichia coli rho gene were cloned and sequenced, and their sequences were compared with other available sequences. The species for all of the compared sequences are members of five bacterial phyla, including Thermotogales, the most deeply diverged phylum. This suggests that a rho-like gene is ubiquitous in the Bacteria and was present in their common ancestor. The comparative analysis revealed that the Rho homologs are highly conserved, exhibiting a minimum identity of 50% of their amino acid residues in pairwise comparisons. The ATP-binding domain had a particularly high degree of conservation, consisting of some blocks with sequences of residues that are very similar to segments of the alpha and beta subunits of F1-ATPase and of other blocks with sequences that are unique to Rho. The RNA-binding domain is more diverged than the ATP-binding domain. However, one of its most highly conserved segments includes a RNP1-like sequence, which is known to be involved in RNA binding. Overall, the degree of similarity is lowest in the first 50 residues (the first half of the RNA-binding domain), in the putative connector region between the RNA-binding and the ATP-binding domains, and in the last 50 residues of the polypeptide. Since functionally defective mutants for E. coli Rho exist in all three of these segments, they represent important parts of Rho that have undergone adaptive evolution.

Analysis of functional domains of the packaging proteins of bacteriophage T3 by site-directed mutagenesis

Intracellular phage T3 DNA is synthesized as a concatemer in which unit-length molecules are jointed together in head-to-tail fashion through terminally redundant sequences. The concatemeric DNA is processed and packaged into the prohead with the aid of non-capsid proteins, gp18 and gp19. We have developed a defined system, composed of purified gp18, gp19 and proheads, and a crude system, composed of lysates of T3 infected cells, for in vitro packaging of T3 DNA. The defined system displays an ATPase activity which is composed of DNA packaging-dependent and -independent ATPases (pac- and nonpac-ATPases, respectively). In the crude system, DNA is packaged by a way of concatemer as an intermediate. gp19 has ATP binding activity and three ATP binding and two Mg2+ binding consensus motifs in its amino acid sequence. We have expanded the previous studies on the roles of these domains in the DNA packaging reaction by more extensive analysis by site-directed mutagenesis. gp19 mutants, including the previously isolated four mutants, were divided into four groups according to the DNA packaging activity in the defined and crude systems: group 1 mutants were defective in both systems (gp19-G61D, which is a gp19 mutant with Gly to Asp at amino acid 61 and so on, and gp19-H344D); the group 2 mutant had decreased activity in both systems (gp19-G429R); group 3 mutants were active in the defined system but defective in the crude system (gp19-G63D, gp19-H347R, gp19-G367D, gp19-G369D, gp19-G424E); group 4 mutants had almost the same activity as gp19-wt (gp19-K64T, gp19-K370I, gp19-G429L, gp19-K430T and gp19-H553L). Group 1 mutants had an altered conformation, resulting in defective interaction with ATP and in abortive binding to the prohead, and lost specifically the pac-ATPase activity. The group 2 mutant had an increased pac-ATPase activity in spite of the decreased DNA packaging activity, indicating that this mutant is inefficient in coupling of ATP hydrolysis to DNA translocation. The inability of the group 3 mutants except gp19-H347R to package DNA in the crude system would be due to a defect in processing of concatemer DNA. gp19-H347R would be a mutant defective in the initiation event(s) of DNA packaging.

Characterization of the rho genes of Neisseria gonorrhoeae and Salmonella typhimurium

We have cloned and sequenced the genomic regions encompassing the rho genes of Neisseria gonorrhoeae and Salmonella typhimurium. Rho factor of S. typhimurium has only three amino acid differences with respect to the Escherichia coli homolog. Northern (RNA) blots and primer extension experiments were used to characterize the N. gonorrhoeae rho transcript and to identify the transcription initiation and termination elements of this cistron. The function of the Rho factor of N. gonorrhoeae was investigated by complementation assays of rho mutants of E. coli and S. typhimurium and by in vivo transcription assays in polar mutants of S. typhimurium.

Functional interactions of ligand cofactors with Escherichia coli transcription termination factor rho. I. Binding of ATP

Escherichia coli transcription termination factor rho is an RNA-dependent ATPase, and ATPase activity is required for all its functions. We have characterized the binding of ATP to the physiologically relevant hexameric association state of rho in the absence of RNA and have shown that there are six ATP binding sites per rho hexamer. This stoichiometry has been verified by a number of different techniques, including ultracentrifugation, ultrafiltration, and fluorescence titration studies. We have also shown that ATP can bind to isolated monomers of rho when the hexamer is dissociated with the mild denaturant myristyltrimethylammonium bromide, demonstrating that each promoter of rho carries an ATP binding site. The six binding sites that we observe in the rho hexamer are not equivalent; the hexamer contains three strong (Ka approximately 3 x 10(6) M-1) and three weak (Ka approximately 10(5) M-1) binding sites for ATP. The binding constant of the weak binding site is just the reciprocal of the enzymatic Km for ATP as a substrate; thus these weak sites, as well as the strong sites, can, in principle, take part in the catalytic cycle. The asymmetry induced (or manifested) by ATP binding reduces the symmetry of the rho hexamer from a D3 to a pseudo-D3 state. This "breakage" of symmetry has implications for the molecular mechanism of rho, because an asymmetric structure can lead to directional helicase activity by invoking directionally distinct RNA binding and release reactions (see Geiselmann, J., Yager, T.D., & von Hippel, P.H., 1992c, Protein Sci. 1, 861-873).

Structure and assembly of the Escherichia coli transcription termination factor rho and its interactions with RNA. II. Physical chemical studies

Transcription termination factor rho from Escherichia coli is comprised of a hexamer of identical protein monomers. Hydrodynamic and light-scattering studies have shown the fully assembled rho to be a doughnut-shaped structure. Semi-denaturing gels, protein crosslinking, and spectroscopic studies, as well as other functional and binding determinations have established that the rho hexamer displays D3 symmetry (i.e. it exists as a trimer of dimers). In the accompanying paper we visualize rho directly in the absence of cofactor and show that binding of RNA it into the hexameric form. In this paper we examine the pathway and association constants involved in rho oligomer assembly. Sedimentation and fluorescence-detected size exclusion chromatography are used to demonstrate three steps in the assembly process. These steps can be differentiated by subunit association affinity and kinetic properties. The kinetics of the monomer-dimer equilibrium are fast and an apparent association constant of 1.3 x 10(6) M-1 is measured for this process. In contrast, the dimer-tetramer and tetramer-hexamer association processes appear to be slower (of the order of seconds) and to involve association constants that are smaller than that of the monomer-dimer reaction. This behaviour is consistent with a hexamer of D3 symmetry. Such a particle displays two kinds of subunit interactions; one associated with an intra-dimer A:A interface and the other with an inter-dimer B:B interface. The closure of the circular hexamer does not appear to contribute additional free energy to the assembly process. Fluorescence and sedimentation studies show the association steps to be sensitive to salt concentration. Consistent with earlier work, we find that assembly to the hexameric state is driven by RNA binding.

Identification of two genes, kpsM and kpsT, in region 3 of the polysialic acid gene cluster of Escherichia coli K1

The polysialic acid capsule of Escherichia coli K1, a causative agent of neonatal septicemia and meningitis, is an essential virulence determinant. The 17-kb kps gene cluster, which is divided into three functionally distinct regions, encodes proteins necessary for polymer synthesis and expression at the cell surface. The central region, 2, encodes products required for synthesis, activation, and polymerization of sialic acid, while flanking regions, 1 and 3, are thought to be involved in polymer assembly and transport. In this study, we identified two genes in region 3, kpsM and kpsT, which encode proteins with predicted sizes of 29.6 and 24.9 kDa, respectively. The hydrophobicity profile of KpsM suggests that it is an integral membrane protein, while KpsT contains a consensus ATP-binding domain. KpsM and KpsT belong to a family of prokaryotic and eukaryotic proteins involved with a variety of biological processes, including membrane transport. A previously described kpsT chromosomal mutant that accumulates intracellular polysialic acid was characterized and could be complemented in trans. Results of site-directed mutagenesis of the putative ATP-binding domain of KpsT are consistent with the view that KpsT is a nucleotide-binding protein. KpsM and KpsT have significant similarity to BexB and BexA, two proteins that are essential for polysaccharide capsule expression in Haemophilus influenzae type b. We propose that KpsM and KpsT constitute a system for transport of polysialic acid across the cytoplasmic membrane.

Site-specific mutagenesis of conserved residues within Walker A and B sequences of Escherichia coli UvrA protein

UvrA is the ATPase subunit of the DNA repair enzyme (A)BC excinuclease. The amino acid sequence of this protein has revealed, in addition to two zinc fingers, three pairs of nucleotide binding motifs each consisting of a Walker A and B sequence. We have conducted site-specific mutagenesis, ATPase kinetic analyses, and nucleotide binding equilibrium measurements to correlate these sequence motifs with activity. Replacement of the invariant Lys by Ala in the putative A sequences indicated that K37 and K646 but not K353 are involved in ATP hydrolysis. In contrast, substitution of the invariant Asp by Asn in the B sequences at positions D238, D513, or D857 had little effect on the in vivo activity of the protein. Nucleotide binding studies revealed a stoichiometry of 0.5 ADP/UvrA monomer while kinetic measurements on wild-type and mutant proteins showed that the active form of UvrA is a dimer with 2 catalytic sites which interact in a positive cooperative manner in the presence of ADP; mutagenesis of K37 but not of K646 attenuated this cooperativity. Loss of ATPase activity was about 75% in the K37A, 86% in the K646A mutant, and 95% in the K37A-K646A double mutant. These amino acid substitutions had only a marginal effect on the specific binding of UvrA to damaged DNA but drastically reduced its ability to deliver UvrB to the damage site. We find that the deficient UvrB loading activity of these mutant UvrA proteins results from their inability to associate with UvrB in the form of (UvrA)2(UvrB)1 complexes. We conclude that UvrA forms a dimer with two ATPase domains involving K37 and K646 and that the work performed by ATP hydrolysis is the delivery of UvrB to the damage site on DNA.

A consensus motif common to all Rho-dependent prokaryotic transcription terminators

We have characterized at the molecular level several polar mutations in four different cistrons of the his operon of S. typhimurium. An analysis of the his-specific transcripts produced in vivo in the mutant strains, together with in vitro transcription assays, led to the identification of several cryptic Rho-dependent transcription termination elements within the his operon that are activated by the uncoupling of transcription and translation. Common features of these elements were sought and found with a computer program. We have identified a consensus motif, consisting of a cytosine-rich and guanosine-poor region, that is located upstream of the heterogeneous 3' endpoints of the prematurely terminated in vivo transcripts and that is present in all the Rho-dependent transcription terminators described thus far.

Dissection of functional domains of the packaging protein of bacteriophage T3 by site-directed mutagenesis

Intracellular phage T3 DNA is synthesized as a concatemer in which unit-length molecules are joined together in head-to-tail fashion through terminally redundant sequences. During packaging of DNA, mature monomers are cut from the concatemer. The cutting is obligatorily coupled to DNA packaging. The packaging of phage DNA is under the control of a pair of noncapsid proteins, called packaging proteins, gp 18 and gp19. gp19 is an ATP-binding protein that plays multiple roles in DNA packaging. gp19 is predicted, from the sequence of its gene, to contain 586 amino acids, and has consensus sequences for an ATP binding site. To dissect structure-function relationships of gp19, mutations were introduced into the ATP binding domain and the mutant proteins were overproduced, purified and characterized. Mutant gp19 with a Gly-to-Asp mutation at amino acid 61 (gp19 G61D) was defective in DNA packaging due to an altered interaction with ATP. Gp19 G424E, with a change in another putative ATP binding domain, was active in DNA packaging but was defective in DNA cutting. A second mutation in the latter domain, gp19 K430T, and a mutation at 553 (to give gp19 H553L), within a putative Mg2+ binding domain, had only minor effects on gp19 activities.

DNA helicases of Escherichia coli

A great deal has been learned in the last 15 years with regard to how helicase enzymes participate in DNA metabolism and how they interact with their DNA substrates. However, many questions remain unanswered. Of critical importance is an understanding of how NTP hydrolysis and hydrogen-bond disruption are coupled. Several models exist and are being tested; none has been proven. In addition, an understanding of how a helicase disrupts the hydrogen bonds holding duplex DNA together is lacking. Recently, helicase enzymes that unwind duplex RNA and DNA.RNA hybrids have been described. In some cases, these are old enzymes with new activities. In other cases, these are new enzymes only recently discovered. The significance of these reactions in the cell remains to be clarified. However, with the availability of significant amounts of these enzymes in a highly purified state, and mutant alleles in most of the genes encoding them, the answers to these questions should be forthcoming. The variety of helicases found in E. coli, and the myriad processes these enzymes are involved in, were perhaps unexpected. It seems likely that an equally large number of helicases will be discovered in eukaryotic cells. In fact, several helicases have been identified and purified from eukaryotic sources ranging from viruses to mouse cells (4-13, 227-234). Many of these helicases have been suggested to have roles in DNA replication, although this remains to be shown conclusively. Helicases with roles in DNA repair, recombination, and other aspects of DNA metabolism are likely to be forthcoming as we learn more about these processes in eukaryotic cells.

Mutations in the ATP-binding domain of Escherichia coli rho factor affect transcription termination in vivo

Five mutant rho proteins, representing alterations at three different locations in the Escherichia coli rho gene that affect ATP hydrolytic activity but not RNA binding, were examined in vivo for function at the rho-dependent IS2 and bacteriophage lambda tR1 terminators. The altered amino acids in rho are located at highly conserved residues near the beta 1 and beta 4 strands of the hydrophobic ATP-binding pocket that is structurally similar to the F1-type ATPases and adenylate kinase. The RNA-dependent ATPase activities of the mutant rho proteins were previously shown to range from undetectable to a twofold increase over wild-type rho in vitro. Analysis of these proteins within the environment of the cell confirmed that transcription termination in vivo is indeed related to the ability of rho factor to properly hydrolyze nucleoside triphosphates, as would be predicted from results in vitro. The relative efficiency of termination at lambda tR1, as judged by lambda N= plating efficiency and by suppression of polarity of IS2 upstream of galK, was closely linked to the level of RNA-dependent ATPase activity observed in vitro for each protein. Moreover, the termination efficiency of four of the altered rho proteins at IS2 and lambda tR1 in vivo corresponded directly to the effect of these mutations on rho function at the E. coli trp t' terminator in vitro. We conclude that determinations of rho function in vitro accurately reflect its behavior in intracellular termination events.

Mutant rho factors with increased transcription termination activities. II. Identification and functional dissection of amino acid changes

We have determined the nucleotide sequences of three mutant rho genes encoding hyperfunctional rho proteins (rho S) together with their parent allele, rho-ts702. These mutant rho factors contain the following amino acid changes as deduced from their sequences: (1) the thermo-labile mutant, rho-ts702, has Thr304 substituting for Ala; (2) rho S-77 and rho S-81, which are selectively altered in the primary polynucleotide binding site, share an identical mutation, Leu3----Phe; (3) rho S-82, which is altered in both the primary and secondary polynucleotide binding sites, carries three amino acid substitutions together, Leu3----Phe, Asp156----Asn and Thr323----Ile. Dissection and functional characterization of each mutation in rho S-82 have revealed that Ile323 alone is responsible for alterations in both the secondary RNA interaction and the terminator selectivity observed with the original mutant, rho S-82. Taken together, these results not only confirm our proposal in the accompanying paper that the primary and secondary RNA binding sites differently contribute in determining the overall efficiency and site-specificity of termination, respectively, but also support the possibility that these binding sites exist as structurally distinct domains in rho protein. In contrast, Asn156 was shown to cause decreased termination efficiency, though it had no influence on RNA interactions. Thus, this amino acid residue appears to be associated with still another rate-determining step of termination, for instance, interactions between rho and RNA polymerase. On the basis of Chou-Fasman secondary structure predictions as well as amino acid sequence comparison with F1-ATPase, we discuss how the proposed domains are structurally and functionally related to the putative ATPase reactive center of rho protein.