Distinct functions of N and C-terminal domains of GreA, an Escherichia coli transcript cleavage factor

Bacillus subtilis stress-associated mutagenesis and developmental DNA repair

SUMMARYThe metabolic conditions that prevail during bacterial growth have evolved with the faithful operation of repair systems that recognize and eliminate DNA lesions caused by intracellular and exogenous agents. This idea is supported by the low rate of spontaneous mutations (10-9) that occur in replicating cells, maintaining genome integrity. In contrast, when growth and/or replication cease, bacteria frequently process DNA lesions in an error-prone manner. DNA repairs provide cells with the tools needed for maintaining homeostasis during stressful conditions and depend on the developmental context in which repair events occur. Thus, different physiological scenarios can be anticipated. In nutritionally stressed bacteria, different components of the base excision repair pathway may process damaged DNA in an error-prone approach, promoting genetic variability. Interestingly, suppressing the mismatch repair machinery and activating specific DNA glycosylases promote stationary-phase mutations. Current evidence also suggests that in resting cells, coupling repair processes to actively transcribed genes may promote multiple genetic transactions that are advantageous for stressed cells. DNA repair during sporulation is of interest as a model to understand how transcriptional processes influence the formation of mutations in conditions where replication is halted. Current reports indicate that transcriptional coupling repair-dependent and -independent processes operate in differentiating cells to process spontaneous and induced DNA damage and that error-prone synthesis of DNA is involved in these events. These and other noncanonical ways of DNA repair that contribute to mutagenesis, survival, and evolution are reviewed in this manuscript.

Mutational analysis of Escherichia coli GreA protein reveals new functional activity independent of antipause and lethal when overexpressed

There is a growing appreciation for the diverse regulatory consequences of the family of proteins that bind to the secondary channel of E. coli RNA polymerase (RNAP), such as GreA, GreB or DksA. Similar binding sites could suggest a competition between them. GreA is characterised to rescue stalled RNAP complexes due to its antipause activity, but also it is involved in transcription fidelity and proofreading. Here, overexpression of GreA is noted to be lethal independent of its antipause activity. A library of random GreA variants has been used to isolate lethality suppressors to assess important residues for GreA functionality and its interaction with the RNA polymerase. Some mutant defects are inferred to be associated with altered binding competition with DksA, while other variants seem to have antipause activity defects that cannot reverse a GreA-sensitive pause site in a fliC::lacZ reporter system. Surprisingly, apparent binding and cleavage defects are found scattered throughout both the coiled-coil and globular domains. Thus, the coiled-coil of GreA is not just a measuring stick ensuring placement of acidic residues precisely at the catalytic centre but also seems to have binding functions. These lethality suppressor mutants may provide valuable tools for future structural and functional studies.

Involvement of Transcription Elongation Factor GreA in Mycobacterium Viability, Antibiotic Susceptibility, and Intracellular Fitness

There is growing evidence that GreA aids adaptation to stressful environments in various bacteria. However, the functions of GreA among mycobacteria remain obscure. Here, we report on cellular consequences following deletion of greA gene in Mycobacterium spp. The greA mutant strain (ΔgreA) was generated in Mycobacterium smegmatis, Mycobacterium tuberculosis (MTB) H37Ra, and M. tuberculosis H37Rv. Deletion of greA results in growth retardation and poor survival in response to adverse stress, besides rendering M. tuberculosis more susceptible to vancomycin and rifampicin. By using RNA-seq, we observe that disrupting greA results in the differential regulation of 195 genes in M. smegmatis with 167 being negatively regulated. Among these, KEGG pathways significantly enriched for differentially regulated genes included tryptophan metabolism, starch and sucrose metabolism, and carotenoid biosynthesis, supporting a role of GreA in the metabolic regulation of mycobacteria. Moreover, like Escherichia coli GreA, M. smegmatis GreA exhibits a series of conservative features, and the anti-backtracking activity of C-terminal domain is indispensable for the expression of glgX, a gene was down-regulated in the RNA-seq data. Interestingly, the decrease in the expression of glgX by CRISPR interference, resulted in reduced growth. Finally, intracellular fitness significantly declines due to loss of greA. Our data indicates that GreA is an important factor for the survival and resistance establishment in Mycobacterium spp. This study provides new insight into GreA as a potential target in multi-drug resistant TB treatment.

The Mechanisms of Substrate Selection, Catalysis, and Translocation by the Elongating RNA Polymerase

Multi-subunit DNA-dependent RNA polymerases synthesize all classes of cellular RNAs, ranging from short regulatory transcripts to gigantic messenger RNAs. RNA polymerase has to make each RNA product in just one try, even if it takes millions of successive nucleotide addition steps. During each step, RNA polymerase selects a correct substrate, adds it to a growing chain, and moves one nucleotide forward before repeating the cycle. However, RNA synthesis is anything but monotonous: RNA polymerase frequently pauses upon encountering mechanical, chemical and torsional barriers, sometimes stepping back and cleaving off nucleotides from the growing RNA chain. A picture in which these intermittent dynamics enable processive, accurate, and controllable RNA synthesis is emerging from complementary structural, biochemical, computational, and single-molecule studies. Here, we summarize our current understanding of the mechanism and regulation of the on-pathway transcription elongation. We review the details of substrate selection, catalysis, proofreading, and translocation, focusing on rate-limiting steps, structural elements that modulate them, and accessory proteins that appear to control RNA polymerase translocation.

Transcription Elongation Factor GreA Plays a Key Role in Cellular Invasion and Virulence of Francisella tularensis subsp. novicida

Francisella tularensis is a facultative intracellular Gram-negative bacterium that causes the zoonotic disease tularemia. We identified the transcription elongation factor GreA as a virulence factor in our previous study, but its role was not defined. Here, we investigate the effects of the inactivation of the greA gene, generating a greA mutant of F. tularensis subsp. novicida. Inactivation of greA impaired the bacterial invasion into and growth within host cells, and subsequently virulence in mouse infection model. A transcriptomic analysis (RNA-Seq) showed that the loss of GreA caused the differential expression of 196 bacterial genes, 77 of which were identified as virulence factors in previous studies. To confirm that GreA regulates the expression of virulence factors involved in cell invasion by Francisella, FTN_1186 (pepO) and FTN_1551 (ampD) gene mutants were generated. The ampD deletion mutant showed reduced invasiveness into host cells. These results strongly suggest that GreA plays an important role in the pathogenesis of Francisella by affecting the expression of virulence genes and provide new insights into the complex regulation of Francisella infection.

Wolbachia transcription elongation factor "Wol GreA" interacts with α2ββ'σ subunits of RNA polymerase through its dimeric C-terminal domain

OBJECTIVES

Wolbachia, an endosymbiont of filarial nematode, is considered a promising target for therapy against lymphatic filariasis. Transcription elongation factor GreA is an essential factor that mediates transcriptional transition from abortive initiation to productive elongation by stimulating the escape of RNA polymerase (RNAP) from native prokaryotic promoters. Upon screening of 6257 essential bacterial genes, 57 were suggested as potential future drug targets, and GreA is among these. The current study emphasized the characterization of Wol GreA with its domains.

METHODOLOGY/PRINCIPAL FINDINGS

Biophysical characterization of Wol GreA with its N-terminal domain (NTD) and C-terminal domain (CTD) was performed with fluorimetry, size exclusion chromatography, and chemical cross-linking. Filter trap and far western blotting were used to determine the domain responsible for the interaction with α2ββ'σ subunits of RNAP. Protein-protein docking studies were done to explore residual interaction of RNAP with Wol GreA. The factor and its domains were found to be biochemically active. Size exclusion and chemical cross-linking studies revealed that Wol GreA and CTD exist in a dimeric conformation while NTD subsists in monomeric conformation. Asp120, Val121, Ser122, Lys123, and Ser134 are the residues of CTD through which monomers of Wol GreA interact and shape into a dimeric conformation. Filter trap, far western blotting, and protein-protein docking studies revealed that dimeric CTD of Wol GreA through Lys82, Ser98, Asp104, Ser105, Glu106, Tyr109, Glu116, Asp120, Val121, Ser122, Ser127, Ser129, Lys140, Glu143, Val147, Ser151, Glu153, and Phe163 residues exclusively participates in binding with α2ββ'σ subunits of polymerase.

CONCLUSIONS/SIGNIFICANCE

To the best of our knowledge, this research is the first documentation of the residual mode of action in wolbachial mutualist. Therefore, findings may be crucial to understanding the transcription mechanism of this α-proteobacteria and in deciphering the role of Wol GreA in filarial development.

A transcript cleavage factor of Mycobacterium tuberculosis important for its survival

After initiation of transcription, a number of proteins participate during elongation and termination modifying the properties of the RNA polymerase (RNAP). Gre factors are one such group conserved across bacteria. They regulate transcription by projecting their N-terminal coiled-coil domain into the active center of RNAP through the secondary channel and stimulating hydrolysis of the newly synthesized RNA in backtracked elongation complexes. Rv1080c is a putative gre factor (MtbGre) in the genome of Mycobacterium tuberculosis. The protein enhanced the efficiency of promoter clearance by lowering abortive transcription and also rescued arrested and paused elongation complexes on the GC rich mycobacterial template. Although MtbGre is similar in domain organization and shares key residues for catalysis and RNAP interaction with the Gre factors of Escherichia coli, it could not complement an E. coli gre deficient strain. Moreover, MtbGre failed to rescue E. coli RNAP stalled elongation complexes, indicating the importance of specific protein-protein interactions for transcript cleavage. Decrease in the level of MtbGre reduced the bacterial survival by several fold indicating its essential role in mycobacteria. Another Gre homolog, Rv3788 was not functional in transcript cleavage activity indicating that a single Gre is sufficient for efficient transcription of the M. tuberculosis genome.

Transcription factor GreA contributes to resolving promoter-proximal pausing of RNA polymerase in Bacillus subtilis cells

Bacterial Gre factors associate with RNA polymerase (RNAP) and stimulate intrinsic cleavage of the nascent transcript at the active site of RNAP. Biochemical and genetic studies to date have shown that Escherichia coli Gre factors prevent transcriptional arrest during elongation and enhance transcription fidelity. Furthermore, Gre factors participate in the stimulation of promoter escape and the suppression of promoter-proximal pausing during the beginning of RNA synthesis in E. coli. Although Gre factors are conserved in general bacteria, limited functional studies have been performed in bacteria other than E. coli. In this investigation, ChAP-chip analysis (chromatin affinity precipitation coupled with DNA microarray) was conducted to visualize the distribution of Bacillus subtilis GreA on the chromosome and to determine the effects of GreA inactivation on core RNAP trafficking. Our data show that GreA is uniformly distributed in the transcribed region from the promoter to coding region with core RNAP, and its inactivation induces RNAP accumulation at many promoter or promoter-proximal regions. Based on these findings, we propose that GreA would constantly associate with core RNAP during transcriptional initiation and elongation and resolves its stalling at promoter or promoter-proximal regions, thus contributing to the even distribution of RNAP along the promoter and coding regions in B. subtilis cells.

Transcription factor dynamics

Gene expression is a fundamental process that is highly conserved from humans to bacteria. The first step in gene expression, transcription, is performed by structurally conserved DNA-dependent RNA polymerases (RNAPs), which results in the synthesis of an RNA molecule from a DNA template. In bacteria, a single species of RNAP is responsible for transcribing both stable RNA (i.e. t- and rRNA) and protein-encoding genes (i.e. mRNA), unlike eukaryotic systems, which use three distinct RNAP species to transcribe the different gene classes (RNAP I transcribes most rRNA, RNAP II transcribes mRNA, and RNAP III transcribes tRNA and 5S rRNA). The versatility of bacterial RNAP is dependent on both dynamic interactions with co-factors and the coding sequence of the template DNA, which allows RNAP to respond appropriately to the transcriptional needs of the cell. Although the majority of the research on gene expression has focused on the initiation stage, regulation of the elongation phase is essential for cell viability and represents an important topic for study. The elongation factors that associate with RNAP are unique and highly conserved among prokaryotes, making disruption of their interactions a potentially important target for antibiotic development. One of the most significant advances in molecular biology over the last decade has been the use of green fluorescent protein (GFP) and its spectral variants to observe the subcellular localization of proteins in live intact cells. This review discusses transcription dynamics with respect to RNAP and its associated transcription elongation factors in the two best-studied prokaryotes, Escherichia coli and Bacillus subtilis.

Crystal structure of Escherichia coli Rnk, a new RNA polymerase-interacting protein

Sequence-based searches identified a new family of genes in proteobacteria, named rnk, which shares high sequence similarity with the C-terminal domains of the Gre factors (GreA and GreB) and the Thermus/Deinococcus anti-Gre factor Gfh1. We solved the X-ray crystal structure of Escherichia coli regulator of nucleoside kinase (Rnk) at 1.9 A resolution using the anomalous signal from the native protein. The Rnk structure strikingly resembles those of E. coli GreA and GreB and Thermus Gfh1, all of which are RNA polymerase (RNAP) secondary channel effectors and have a C-terminal domain belonging to the FKBP fold. Rnk, however, has a much shorter N-terminal coiled coil. Rnk does not stimulate transcript cleavage in vitro, nor does it reduce the lifetime of the complex formed by RNAP on promoters. We show that Rnk competes with the Gre factors and DksA (another RNAP secondary channel effector) for binding to RNAP in vitro, and although we found that the concentration of Rnk in vivo was much lower than that of DksA, it was similar to that of GreB, consistent with a potential regulatory role for Rnk as an anti-Gre factor.

Effects of DksA, GreA, and GreB on transcription initiation: insights into the mechanisms of factors that bind in the secondary channel of RNA polymerase

Escherichia coli DksA, GreA, and GreB have similar structures and bind to the same location on RNA polymerase (RNAP), the secondary channel. We show that GreB can fulfil some roles of DksA in vitro, including shifting the promoter-open complex equilibrium in the dissociation direction, thus allowing rRNA promoters to respond to changes in the concentration of ppGpp and NTPs. However, unlike deletion of the dksA gene, deletion of greB had no effect on rRNA promoters in vivo. We show that the apparent affinities of DksA and GreB for RNAP are similar, but the cellular concentration of GreB is much lower than that of DksA. When over-expressed and in the absence of competing GreA, GreB almost completely complemented the loss of dksA in control of rRNA expression, indicating its inability to regulate rRNA transcription in vivo results primarily from its low concentration. In contrast to GreB, the apparent affinity of GreA for RNAP was weaker than that of DksA, GreA affected rRNA promoters only modestly in vitro and, even when over-expressed, GreA did not affect rRNA transcription in vivo. Thus, binding in the secondary channel is necessary but insufficient to explain the effect of DksA on rRNA transcription. Neither Gre factor was capable of fulfilling two other functions of DksA in transcription initiation: co-activation of amino acid biosynthetic gene promoters with ppGpp and compensation for the loss of the omega subunit of RNAP in the response of rRNA promoters to ppGpp. Our results provide important clues to the mechanisms of both negative and positive control of transcription initiation by DksA.

Subcellular partitioning of transcription factors in Bacillus subtilis

RNA polymerase (RNAP) requires the interaction of various transcription elongation factors to efficiently transcribe RNA. During transcription of rRNA operons, RNAP forms highly processive antitermination complexes by interacting with NusA, NusB, NusG, NusE, and possibly several unidentified factors to increase elongation rates to around twice those observed for mRNA. In previous work we used cytological assays with Bacillus subtilis to identify the major sites of rRNA synthesis within the cell, which are called transcription foci. Using this cytological assay, in conjunction with both quantitative native polyacrylamide gel electrophoresis and Western blotting, we investigated the total protein levels and the ratios of NusB and NusG to RNAP in both antitermination and mRNA transcription complexes. We determined that the ratio of RNAP to NusG was 1:1 in both antitermination and mRNA transcription complexes, suggesting that NusG plays important regulatory roles in both complexes. A ratio of NusB to RNAP of 1:1 was calculated for antitermination complexes with just a 0.3:1 ratio in mRNA complexes, suggesting that NusB is restricted to antitermination complexes. We also investigated the cellular abundance and subcellular localization of transcription restart factor GreA. We found no evidence which suggests that GreA is involved in antitermination complex formation and that it has a cellular abundance which is around twice that of RNAP. Surprisingly, we found that the vast majority of GreA is associated with RNAP, suggesting that there is more than one binding site for GreA on RNAP. These results indicate that transcription elongation complexes are highly dynamic and are differentially segregated within the nucleoid according to their functions.

Crystal structure of Thermus aquaticus Gfh1, a Gre-factor paralog that inhibits rather than stimulates transcript cleavage

Transcription elongation in bacteria is promoted by Gre-factors, which stimulate an endogenous, endonucleolytic transcript cleavage activity of the RNA polymerase. A GreA paralog, Gfh1, present in Thermus aquaticus and Thermus thermophilus, has the opposite effect on elongation complexes, inhibiting rather than stimulating transcript cleavage. We have determined the 3.3 angstroms-resolution X-ray crystal structure of T.aquaticus Gfh1. The structure reveals an N-terminal and a C-terminal domain with close structural similarity to the domains of GreA, but with an unexpected conformational change in terms of the orientation of the domains with respect to each other. However, structural and functional analysis suggests that when complexed with RNA polymerase, Gfh1 adopts a conformation similar to that of GreA. These results reveal considerable structural flexibility for Gfh1, and for Gre-factors in general, as suggested by structural modeling, and point to a possible role for the conformational switch in Gre-factor and Gfh1 regulation. The opposite functional effect of Gfh1 compared with GreA may be determined by three structural characteristics. First, Gfh1 lacks the basic patch present in Gre-factors that likely plays a role in anchoring the 3'-fragment of the back-tracked RNA. Second, the loop at the tip of the N-terminal coiled-coil is highly flexible and contains extra acidic residues compared with GreA. Third, the N-terminal coiled-coil finger lacks a kink in the first alpha-helix, resulting in a straight coiled-coil compared with GreA. The latter two characteristics suggest that Gfh1 chelates a magnesium ion in the RNA polymerase active site (like GreA) but in a catalytically inactive configuration.

Transcript cleavage factors GreA and GreB act as transient catalytic components of RNA polymerase

Prokaryotic transcription elongation factors GreA and GreB stimulate intrinsic nucleolytic activity of RNA polymerase (RNAP). The proposed biological role of Gre-induced RNA hydrolysis includes transcription proofreading, suppression of transcriptional pausing and arrest, and facilitation of RNAP transition from transcription initiation to transcription elongation. Using an array of biochemical and molecular genetic methods, we mapped the interaction interface between Gre and RNAP and identified the key residues in Gre responsible for induction of nucleolytic activity in RNAP. We propose a structural model in which the C-terminal globular domain of Gre binds near the opening of the RNAP secondary channel, the N-terminal coiled-coil domain (NTD) protrudes inside the RNAP channel, and the tip of the NTD is brought to the immediate vicinity of RNAP catalytic center. Two conserved acidic residues D41 and E44 located at the tip of the NTD assist RNAP by coordinating the Mg2+ ion and water molecule required for catalysis of RNA hydrolysis. If so, Gre would be the first transcription factor known to directly participate in the catalytic act of RNAP.

Combinatorial control of human RNA polymerase II (RNAP II) pausing and transcript cleavage by transcription factor IIF, hepatitis delta antigen, and stimulatory factor II

When RNA polymerase II (RNAP II) is forced to stall, elongation complexes (ECs) are observed to leave the active pathway and enter a paused state. Initially, ECs equilibrate between active and paused conformations, but with stalls of a long duration, ECs backtrack and become sensitive to transcript cleavage, which is stimulated by the EC rescue factor stimulatory factor II (TFIIS/SII). In this work, the rates for equilibration between the active and pausing pathways were estimated in the absence of an elongation factor, in the presence of hepatitis delta antigen (HDAg), and in the presence of transcription factor IIF (TFIIF), with or without addition of SII. Rates of equilibration between the active and paused states are not very different in the presence or absence of elongation factors HDAg and TFIIF. SII facilitates escape from stalled ECs by stimulating RNAP II backtracking and transcript cleavage and by increasing rates into and out of the paused EC. TFIIF and SII cooperate to merge the pausing and active pathways, a combinatorial effect not observed with HDAg and SII. In the presence of HDAg and SII, pausing is observed without stimulation of transcript cleavage, indicating that the EC can pause without backtracking beyond the pre-translocated state.

Structure and function of the transcription elongation factor GreB bound to bacterial RNA polymerase

Bacterial GreA and GreB promote transcription elongation by stimulating an endogenous, endonucleolytic transcript cleavage activity of the RNA polymerase. The structure of Escherichia coli core RNA polymerase bound to GreB was determined by cryo-electron microscopy and image processing of helical crystals to a nominal resolution of 15 A, allowing fitting of high-resolution RNA polymerase and GreB structures. In the resulting model, the GreB N-terminal coiled-coil domain extends 45 A through a channel directly to the RNA polymerase active site. The model leads to detailed insights into the mechanism of Gre factor activity that explains a wide range of experimental observations and points to a key role for conserved acidic residues at the tip of the Gre factor coiled coil in modifying the RNA polymerase active site to catalyze the cleavage reaction. Mutational studies confirm that these positions are critical for Gre factor function.

Promoting elongation with transcript cleavage stimulatory factors

Transcript elongation by RNA polymerase is a dynamic process, capable of responding to a number of intrinsic and extrinsic signals. A number of elongation factors have been identified that enhance the rate or efficiency of transcription. One such class of factors facilitates RNA polymerase transcription through blocks to elongation by stimulating the polymerase to cleave the nascent RNA transcript within the elongation complex. These cleavage factors are represented by the Gre factors from prokaryotes, and TFIIS and TFIIS-like factors found in archaea and eukaryotes. High-resolution structures of RNA polymerases and the cleavage factors in conjunction with biochemical investigations and genetic analyses have provided insights into the mechanism of action of these elongation factors. However, there are yet many unanswered questions regarding the regulation of these factors and their effects on target genes.

Transcript cleavage by Thermus thermophilus RNA polymerase. Effects of GreA and anti-GreA factors

All known multisubunit RNA polymerases possess the ability to endonucleolytically degrade the nascent RNA transcript. To gain further insight into the conformational changes that govern transcript cleavage, we have examined the effects of certain anions on the intrinsic transcript cleavage activity of Thermus thermophilus RNA polymerase. Our results indicate that the conformational transitions involved in transcript cleavage, and therefore backtracking, are anion-dependent. In addition to characterizing the intrinsic cleavage activity of T. thermophilus RNA polymerase, we have identified, cloned, and expressed a homolog of the prokaryotic transcript cleavage factor GreA from the extreme thermophiles, T. thermophilus and Thermus aquaticus. The thermostable GreA factors contact the 3'-end of RNA, stimulate the intrinsic cleavage activity of T. thermophilus RNA polymerase, and increase the k(app) of the cleavage reaction 25-fold. In addition, we have identified a novel transcription factor in T. thermophilus and T. aquaticus that shares a high degree of sequence similarity with GreA, but has several residues that are not conserved with the N-terminal "basic patch" region of GreA. This protein, Gfh1, functions as an anti-GreA factor in vitro by reducing intrinsic cleavage and competing with GreA for a binding site on the polymerase.

Interim report on genomics of Escherichia coli

We present a summary of recent progress in understanding Escherichia coli K-12 gene and protein functions. New information has come both from classical biological experimentation and from using the analytical tools of functional genomics. The content of the E. coli genome can clearly be seen to contain elements acquired by horizontal transfer. Nevertheless, there is probably a large, stable core of >3500 genes that are shared among all E. coli strains. The gene-enzyme relationship is examined, and, in many cases, it exhibits complexity beyond a simple one-to-one relationship. Also, the E. coli genome can now be seen to contain many multiple enzymes that carry out the same or closely similar reactions. Some are similar in sequence and may share common ancestry; some are not. We discuss the concept of a minimal genome as being variable among organisms and obligatorily linked to their life styles and defined environmental conditions. We also address classification of functions of gene products and avenues of insight into the history of protein evolution.

Structural basis for the species-specific activity of TFIIS

Many proteins involved in eukaryotic transcription are similar in function and in sequence between organisms. Despite the sequence similarities, there are many factors that do not function across species. For example, transcript elongation factor TFIIS is highly conserved among eukaryotes, and yet the TFIIS protein from Saccharomyces cerevisiae cannot function with mammalian RNA polymerase II and vice versa. To determine the reason for this species specificity, chimeras were constructed linking three structurally independent regions of the TFIIS proteins from yeast and human cells. Two independently folding domains, II and III, have been examined previously using NMR (). Yeast domain II alone is able to bind yeast RNA polymerase II with the same affinity as the full-length TFIIS protein, and this domain was expected to confer the species selectivity. Domain III has previously been shown to be readily exchanged between mammalian and yeast factors. However, the results presented here indicate that domain II is insufficient to confer species selectivity, and a primary determinant lies in a 30-amino acid highly conserved linker region connecting domain II with domain III. These 30 amino acids may physically orient domains II and III to support functional interactions between TFIIS and RNA polymerase II.

The functional role of basic patch, a structural element of Escherichia coli transcript cleavage factors GreA and GreB

The transcript cleavage factors GreA and GreB of Escherichia coli are involved in the regulation of transcription elongation. The surface charge distribution analysis of their three-dimensional structures revealed that the N-terminal domains of GreA and GreB contain a small and large basic "patch," respectively. To elucidate the functional role of basic patch, mutant Gre proteins were engineered in which the size and charge distribution of basic patch were modified and characterized biochemically. We found that Gre mutants lacking basic patch or carrying basic patch of decreased size bind to RNA polymerase and induce transcript cleavage reaction in minimally backtracked ternary elongation complex (TEC) with the same efficiency as the wild type factors. However, they exhibit substantially lower readthrough and cleavage activities toward extensively backtracked and arrested TECs and display decreased efficiency of photocross-linking to the RNA 3'-terminus. Unlike wild type factors, basic patch-less Gre mutants are unable to complement the thermosensitive phenotype of GreA(-):GreB(-) E. coli strain. The large basic patch is required but not sufficient for the induction of GreB-type cleavage reaction and for the cleavage of arrested TECs. Our results demonstrate that the basic patch residues are not directly involved in the induction of transcript cleavage reaction and suggest that the primary role of basic patch is to anchor the nascent RNA in TEC. These interactions are essential for the readthrough and antiarrest activities of Gre factors and, apparently, for their in vivo functions.

Comparative genome analysis of the pathogenic spirochetes Borrelia burgdorferi and Treponema pallidum

A comparative analysis of the predicted protein sequences encoded in the complete genomes of Borrelia burgdorferi and Treponema pallidum provides a number of insights into evolutionary trends and adaptive strategies of the two spirochetes. A measure of orthologous relationships between gene sets, termed the orthology coefficient (OC), was developed. The overall OC value for the gene sets of the two spirochetes is about 0.43, which means that less than one-half of the genes show readily detectable orthologous relationships. This emphasizes significant divergence between the two spirochetes, apparently driven by different biological niches. Different functional categories of proteins as well as different protein families show a broad distribution of OC values, from near 1 (a perfect, one-to-one correspondence) to near 0. The proteins involved in core biological functions, such as genome replication and expression, typically show high OC values. In contrast, marked variability is seen among proteins that are involved in specific processes, such as nutrient transport, metabolism, gene-specific transcription regulation, signal transduction, and host response. Differences in the gene complements encoded in the two spirochete genomes suggest active adaptive evolution for their distinct niches. Comparative analysis of the spirochete genomes produced evidence of gene exchanges with other bacteria, archaea, and eukaryotic hosts that seem to have occurred at different points in the evolution of the spirochetes. Examples are presented of the use of sequence profile analysis to predict proteins that are likely to play a role in pathogenesis, including secreted proteins that contain specific protein-protein interaction domains, such as von Willebrand A, YWTD, TPR, and PR1, some of which hitherto have been reported only in eukaryotes. We tentatively reconstruct the likely evolutionary process that has led to the divergence of the two spirochete lineages; this reconstruction seems to point to an ancestral state resembling the symbiotic spirochetes found in insect guts.

Mapping interactions of Escherichia coli GreB with RNA polymerase and ternary elongation complexes

Escherichia coli GreA and GreB modulate transcription elongation by interacting with the ternary elongation complex (containing RNA polymerase, DNA template, and RNA transcript) to induce hydrolytic cleavage of the transcript and release of the 3'-terminal fragment. Hydroxyl radical protein footprinting and alanine-scanning mutagenesis were used to investigate the interactions of GreB with RNA polymerase alone and in a ternary elongation complex. A major determinant for binding GreB to both RNA polymerase and the ternary elongation complex was identified. In addition, the hydroxyl radical footprinting indicated major conformational changes of GreB, in terms of reorientations of the N- and C-terminal domains with respect to each other, particularly upon interactions with the ternary elongation complex.

Visualization of the binding site for the transcript cleavage factor GreB on Escherichia coli RNA polymerase

The structure of Escherichia coli core RNA polymerase (RNAP) complexed with the transcript cleavage factor GreB was determined from electron micrographs of negatively stained, flattened helical crystals. A binding assay was developed to establish that GreB was incorporated into the RNA polymerase crystals with high occupancy through interactions between the globular C-terminal domain and the RNA polymerase. Comparison of the core RNAP:GreB structure with the previously determined structure of core RNAP located the GreB binding site on one face of the RNA polymerase, next to but not in the 25 A-diameter channel of RNA polymerase.