Nascent RNA in transcription complexes interacts with CspE, a small protein in E. coli implicated in chromatin condensation

Y-box Binding Protein 1: Looking Back to the Future

Y-box binding protein 1 is a member of the cold shock domain (CSD) protein family and one of the most studied proteins associated with a large number of human diseases. This review aims to critically reassess the growing number of pathological functions ascribed to YB-1 in the past decades. The focus is given on the important role of YB-1 and related CSD proteins in the physiology of normal cells. The functional significance of these proteins is highlighted by their high evolutionary conservation from bacteria to men, where they are ubiquitously expressed and involved in coordinating all steps of mRNA biogenesis, including transcription, translation, storage, and degradation. Their activities are especially important under conditions requiring rapid change in the gene expression programs, such as early embryonic development, differentiation, stress, and adaptation to new environments. Therefore, to define a precise role of YB-1 in tumorigenic transformation and in other pathological conditions, it is important to understand its basic properties and functions in normal cells, and how they are interrupted in complex diseases including cancer.

Coupled Transcription-Translation in Prokaryotes: An Old Couple With New Surprises

Coupled transcription-translation (CTT) is a hallmark of prokaryotic gene expression. CTT occurs when ribosomes associate with and initiate translation of mRNAs whose transcription has not yet concluded, therefore forming "RNAP.mRNA.ribosome" complexes. CTT is a well-documented phenomenon that is involved in important gene regulation processes, such as attenuation and operon polarity. Despite the progress in our understanding of the cellular signals that coordinate CTT, certain aspects of its molecular architecture remain controversial. Additionally, new information on the spatial segregation between the transcriptional and the translational machineries in certain species, and on the capability of certain mRNAs to localize translation-independently, questions the unanimous occurrence of CTT. Furthermore, studies where transcription and translation were artificially uncoupled showed that transcription elongation can proceed in a translation-independent manner. Here, we review studies supporting the occurrence of CTT and findings questioning its extent, as well as discuss mechanisms that may explain both coupling and uncoupling, e.g., chromosome relocation and the involvement of cis- or trans-acting elements, such as small RNAs and RNA-binding proteins. These mechanisms impact RNA localization, stability, and translation. Understanding the two options by which genes can be expressed and their consequences should shed light on a new layer of control of bacterial transcripts fate.

RNA localization in prokaryotes: Where, when, how, and why

Only recently has it been recognized that the transcriptome of bacteria and archaea can be spatiotemporally regulated. All types of prokaryotic transcripts-rRNAs, tRNAs, mRNAs, and regulatory RNAs-may acquire specific localization and these patterns can be temporally regulated. In some cases bacterial RNAs reside in the vicinity of the transcription site, but in many others, transcripts show distinct localizations to the cytoplasm, the inner membrane, or the pole of rod-shaped species. This localization, which often overlaps with that of the encoded proteins, can be achieved either in a translation-dependent or translation-independent fashion. The latter implies that RNAs carry sequence-level features that determine their final localization with the aid of RNA-targeting factors. Localization of transcripts regulates their posttranscriptional fate by affecting their degradation and processing, translation efficiency, sRNA-mediated regulation, and/or propensity to undergo RNA modifications. By facilitating complex assembly and liquid-liquid phase separation, RNA localization is not only a consequence but also a driver of subcellular spatiotemporal complexity. We foresee that in the coming years the study of RNA localization in prokaryotes will produce important novel insights regarding the fundamental understanding of membrane-less subcellular organization and lead to practical outputs with biotechnological and therapeutic implications. This article is categorized under: RNA Export and Localization > RNA Localization Regulatory RNAs/RNAi/Riboswitches > Regulatory RNAs RNA Interactions with Proteins and Other Molecules > Protein-RNA Interactions: Functional Implications.

Interplay of cold shock protein E with an uncharacterized protein, YciF, lowers porin expression and enhances bile resistance in Salmonella Typhimurium

Bacterial cold shock proteins (CSPs) function as RNA chaperones. To assess CSP's roles in the intracellular human pathogen Salmonella Typhimurium, we analyzed their expression in varied stress conditions. We found that cold shock protein E (cspE or STM14_0732) is up-regulated during bile salt-induced stress and that an S. Typhimurium strain lacking cspE (ΔcspE) displays dose-dependent sensitivity to bile salts, specifically to deoxycholate. We also found that an uncharacterized gene, yciF (STM14_2092), is up-regulated in response to bile stress in WT but not in the ΔcspE strain. Complementation with WT CspE, but not with a F30V CspE variant, abrogated the bile sensitivity of ΔcspE as did multicopy overexpression of yciF. Northern blotting experiments with rifampicin disclosed that the regulation of yciF expression is, most likely, due to the RNA-stabilizing activity of CspE. Importantly, electrophoretic mobility shift assays indicated that purified CspE, but not the F30V variant, directly binds yciF mRNA. We also observed that the extra-cytoplasmic stress-response (ESR) pathway is augmented in the bile-treated ΔcspE strain, as judged by induction of RpoE regulon genes (rpoE, degP, and rybB) and downstream ESR genes (hfq, rne, and PNPase). Moreover, the transcript levels of the porin genes, ompD, ompF, and ompC, were higher in bile salts-stressed ΔcspE and correlated with higher intracellular accumulation of the fluorescent DNA stain bisBenzimide H 33258, indicating greater cell permeability. In conclusion, our study has identified YciF, a CspE target involved in the regulation of porins and in countering bile stress in S. Typhimurium.

The structure, function and evolution of proteins that bind DNA and RNA

Proteins that bind both DNA and RNA typify the ability of a single gene product to perform multiple functions. Such DNA- and RNA-binding proteins (DRBPs) have unique functional characteristics that stem from their specific structural features; these developed early in evolution and are widely conserved. Proteins that bind RNA have typically been considered as functionally distinct from proteins that bind DNA and studied independently. This practice is becoming outdated, in partly owing to the discovery of long non-coding RNAs (lncRNAs) that target DNA-binding proteins. Consequently, DRBPs were found to regulate many cellular processes, including transcription, translation, gene silencing, microRNA biogenesis and telomere maintenance.

RNA remodeling and gene regulation by cold shock proteins

One of the many important consequences that temperature down-shift has on cells is stabilization of secondary structures of RNAs. This stabilization has wide-spread effects, such as inhibition of expression of several genes due to termination of their transcription and inefficient RNA degradation that adversely affect cell growth at low temperature. Several cold shock proteins are produced to counteract these effects and thus allow cold acclimatization of the cell. The main RNA modulating cold shock proteins of E. coli can be broadly divided into two categories, (1) the CspA family proteins, which mainly affect the transcription and possibly translation at low temperature through their RNA chaperoning function and (2) RNA helicases and exoribonucleases that stimulate RNA degradation at low temperature through their RNA unwinding activity.

The Cold Shock Response

This review focuses on the cold shock response of Escherichia coli. Change in temperature is one of the most common stresses that an organism encounters in nature. Temperature downshift affects the cell on various levels: (i) decrease in the membrane fluidity; (ii) stabilization of the secondary structures of RNA and DNA; (iii) slow or inefficient protein folding; (iv) reduced ribosome function, affecting translation of non-cold shock proteins; (v) increased negative supercoiling of DNA; and (vi) accumulation of various sugars. Cold shock proteins and certain sugars play a key role in dealing with the initial detrimental effect of cold shock and maintaining the continued growth of the organism at low temperature. CspA is the major cold shock protein of E. coli, and its homologues are found to be widespread among bacteria, including psychrophilic, psychrotrophic, mesophilic, and thermophilic bacteria, but are not found in archaea or cyanobacteria. Significant, albeit transient, stabilization of the cspA mRNA immediately following temperature downshift is mainly responsible for its cold shock induction. Various approaches were used in studies to detect cold shock induction of cspA mRNA. Sugars are shown to confer protection to cells undergoing cold shock. The study of the cold shock response has implications in basic and health-related research as well as in commercial applications. The cold shock response is elicited by all types of bacteria and affects these bacteria at various levels, such as cell membrane, transcription, translation, and metabolism.

Functional characterization of two cold shock domain proteins from Oryza sativa

Two novel rice cold shock domain (CSD) proteins were cloned and characterized under different stress treatments and during various stages of development. OsCSP1 and OsCSP2 (Oryza sativa CSD protein) encode putative proteins consisting of an N-terminal CSD and glycine-rich regions that are interspersed by 4 and 2 CX(2)CX(4)HX(4)C (CCHC) retroviral-like zinc fingers, respectively. In vivo functional analysis confirmed that OsCSPs can complement a cold-sensitive bacterial strain which lacks four endogenous cold shock proteins. In vitro ssDNA binding assays determined that recombinant OsCSPs are capable of functioning as nucleic acid-binding proteins. Both OsCSP transcripts are transiently up-regulated in response to low-temperature stress and rapidly return to a basal level of gene expression. Protein blot analysis determined that OsCSPs are maintained at a constant level subsequent to a cold treatment lasting over a period of several days. Both the transcript and protein data are in sharp contrast to those previously obtained for winter wheat WCSP1. A time-coursed study through various stages of rice development confirmed that both OsCSP proteins and transcripts are highly accumulated in reproductive tissues and tissues which exhibit meristematic activity.

Cold shock proteins aid coupling of transcription and translation in bacteria

Transcription and translation are tightly coupled in bacterial cells. However, the transcription machinery and ribosomes generally occupy different subcellular regions in bacteria such as Escherichia coli and Bacillus subtilis, indicating the need for (a) mechanism(s) coupling these processes. A prime function of this mechanism(s) would be ensuring the transfer of unfolded mRNA from the nucleoid to ribosomes, which require linear mRNA for the initiation of translation. During conditions of a sudden decrease in temperature (cold shock), secondary structures in mRNA would pose an even greater problem for the initiation process. Two conserved classes of proteins, cold shock proteins (CSPs) and cold induced RNA helicases (CSHs), appear to be major players in the prevention of secondary mRNA structures and in transcription/translation coupling. CSPs are general mRNA-binding proteins, and like CSH-type RNA helicases, the presence of at least one csp gene in the cell is essential for viability. Members of both protein families have recently been shown to interact, suggesting that a two-step process achieves the coupling process, removal of secondary mRNA structures through CSHs and prevention of reformation through CSPs.

Specificity of DNA binding and dimerization by CspE from Escherichia coli

The CspE protein from Escherichia coli K12 is a single-stranded nucleic acid-binding protein that plays a role in chromosome condensation in vivo. We report here that CspE binds to single-stranded DNA containing 6 or more contiguous dT residues with high affinity (K(D) < 30 nM). The interactions are predominantly through base-specific contacts. When an oligonucleotide contains fewer than 6 contiguous dT residues, the CspE interactions with single-stranded DNA are primarily electrostatic. The minimal length of single-stranded DNA to which CspE binds in a salt-resistant manner is eight nucleotides. We also show that CspE exists as a dimer in solution. We present a possible mechanism to explain the role of CspE in chromosome condensation in vivo by CspE binding to distant DNA regions in the chromosome and dimerizing, thereby condensing the intervening DNA.

Functional conservation of cold shock domains in bacteria and higher plants

In Escherichia coli, a family of cold shock proteins (CSPs) function as transcription antiterminators or translational enhancers at low temperature by destabilizing RNA secondary structure. A wheat nucleic acid-binding protein (WCSP1) was found to contain a cold shock domain (CSD) bearing high similarity to E. coli cold shock proteins. In the present study, a series of mutations were introduced into WCSP1, and its functionality was investigated by using in vivo and in vitro assays in the context of functional conservation with E. coli CSPs. Constitutive expression of WT WCSP1 in an E. coli cspA, cspB, cspE, cspG quadruple deletion mutant complemented its cold-sensitive phenotype, suggesting that WCSP1 shares a function with E. coli CSPs for cold adaptation. In addition, transcription antitermination activity was demonstrated for WCSP1 by using an E. coli strain that has a hairpin loop upstream of a chloramphenicol resistance gene. In vitro dsDNA melting assays clearly demonstrated that WCSP1 melts dsDNA, an activity that was positively correlated to the ability to bind ssDNA. When mutations were introduced at critical residues within the consensus RNA binding motifs (RNP1 and RNP2) of WCSP1, it failed to melt dsDNA. Studies with WCSP1-GFP fusion proteins documented patterns that are consistent with ER and nuclear localization. In vivo and in vitro functional analyses, coupled with subcellular localization data, suggest that WCSP1 may function as a RNA chaperone to destabilize secondary structure and is involved in the regulation of translation under low temperature.

Analysis of Escherichia coli global gene expression profiles in response to overexpression and deletion of CspC and CspE

The Escherichia coli cold shock protein CspA family consists of nine proteins (CspA to CspI), of which two, CspE and CspC, are constitutively produced at 37 degrees C and are involved in regulation of expression of genes encoding stress response proteins but can also perform an essential function during cold acclimation. In this study, we analyzed global transcript profiles of cells lacking cspE and cspC as well as cells individually overexpressing these proteins or a CspE mutant that is unable to melt nucleic acids and is defective in cold acclimation. The analysis reveals sets of genes whose expression (i) is regulated by CspC and CspE at physiological temperature or cold shock conditions and (ii) depends on the nucleic acid melting function of CspE. Bioinformatic analysis of the latter group reveals that many of those genes contain promoter-proximal sequences that can block transcript elongation and may be targeted by the nucleic acid melting function of CspE.

Cold-induced putative DEAD box RNA helicases CshA and CshB are essential for cold adaptation and interact with cold shock protein B in Bacillus subtilis

The nucleic acid binding cold shock proteins (CSPs) and the cold-induced DEAD box RNA helicases have been proposed separately to act as RNA chaperones, but no experimental evidence has been reported on a direct cooperation. To investigate the possible interaction of the putative RNA helicases CshA and CshB and the CSPs from Bacillus subtilis during cold shock, we performed genetic as well as fluorescence resonance energy transfer (FRET) experiments. Both cshA and cshB genes could be deleted only in the presence of a cshB copy in trans, showing that the presence of one csh gene is essential for viability. The combined gene deletion of cshB and cspD resulted in a cold-sensitive phenotype that was not observed for either helicase or csp single mutants. In addition to the colocalization of the putative helicases CshA and CshB with CspB and the ribosomes in areas surrounding the nucleoid, we detected a strong FRET interaction in vivo between CshB and CspB that depended on active transcription. In contrast, a FRET interaction was not observed for CshB and the ribosomal protein L1. Therefore, we propose a model in which the putative cold-induced helicases and the CSPs work in conjunction to rescue misfolded mRNA molecules and maintain proper initiation of translation at low temperatures in B. subtilis.

Nucleic acid melting by Escherichia coli CspE

Escherichia coli contains nine members of the CspA family. CspA and some of its homologues play critical role in cold acclimation of cells by acting as RNA chaperones, destabilizing nucleicacid secondary structures. Disruption of nucleic acid melting activity of CspE led to loss of its transcription antitermination activity and consequently its cold acclimation activity. To date, the melting activity of Csp proteins was studied using partially double-stranded model nucleic acids substrates forming stem–loop structures. Here, we studied the mechanism of nucleic acid melting by CspE. We show that CspE melts the stem region in two directions, that CspE-induced melting does not require the continuity of the substrate's loop region, and CspE can efficiently melt model substrates with single-stranded overhangs as short as 4 nt. We further show that preferential binding of CspE at the stem–loop junction site initiates melting; binding of additional CspE molecules that fully cover the single-stranded region of a melting substrate leads to complete melting of the stem.

Sequence-specific Rho-RNA interactions in transcription termination

The bacteriophage lambda tR1 terminator encodes a region of the nascent cro transcript containing RNA residues recognized by termination factor Rho. To identify ribonucleotide-protein interactions contributing to termination, a library of reporter gene plasmids was constructed containing predominantly single-nucleotide substitutions in a 24 nt region previously shown to be critical for efficient termination. Screening 16 822 bacterial transformants identified 110 terminator mutants, most of which contained two or more nucleotide substitutions. Although the vast majority of single base changes did not reduce tR1 function, 11 specific single-nucleotide substitutions at eight positions interspersed in the upstream part of the target region (5'-ATAACCCCGCTCTT ACACATTCCA-3') did reduce termination. About half of these substitutions also reduced Rho-dependent termination on cro gene templates transcribed by purified RNA polymerase, indicating specific residues critical for optimal terminator function. Other termination defects were not reproduced in these in vitro assays, and likely resulted from indirect effects of altering interactions between tR1 and additional cellular factors capable of attenuating Rho function. Our results indicate that while Rho is able to recognize a wide variety of similar rut site sequences by interacting with alternate nucleotides at critical positions, interactions with specific individual ribonucleotides of the tR1 transcript provide highly efficient Rho-dependent termination.

The mechanism of nucleic acid melting by a CspA family protein

Cold-shock proteins of the CspA family help bacterial cells to acclimate to low temperatures. Some Csps bind single-stranded nucleic acids and destabilize nucleic acid secondary structures in vitro, and act as transcription antiterminators in vivo and in vitro. Nucleic acid melting by Escherichia coli CspE is critical for its ability to support low-temperature survival of the cell. Here, we explore the molecular mechanism of nucleic acid melting using CspE mutants harboring substitutions in surface-exposed residues critical for this function. Analysis of the mutants identifies two intermediates of the melting pathway and shows that CspE Phe17 and Phe30 act at the earliest stages of melting, while His32 acts later and is necessary for the propagation of melting. The results allow us to orient a CspE molecule relative to the melting substrate and to put forward a mechanistic model of nucleic acid melting by Csps.

CspB and CspL, thermostable cold-shock proteins from Thermotoga maritima

BACKGROUND

Cold-shock proteins (Csps) are important for cellular adaptation to low temperature. Csps help cells adapt to low-temperature growth through their RNA-binding and nucleic acid melting abilities, which lead to anti-termination of transcription.

RESULTS

We studied the two most thermostable Csps known to date, TmCspB and TmCspL from Thermotoga maritima, a hyperthermophilic eubacterium for which no cold-shock response has been demonstrated so far. For comparison, we used a well-characterized Escherichia coli CspE protein. TmCspB and TmCspL are able to bind RNA at both low and high temperatures. They are also able to 'melt' nucleic acids secondary structures and as a result decrease E. coli RNA polymerase transcription termination in vivo and E. coli and T. maritima RNA polymerases transcription termination in vitro. Over-expression of TmCsps allowed E. coli cold-sensitive mutant cells to acclimate to the low temperatures of 15 degrees C.

CONCLUSIONS

TmCspB and TmCspL (i) are able to perform essential functions of E. coli Csps in vitro and in vivo, 50-65 degrees C below the temperature optimum of T. maritima and (ii) can anti-terminate transcription by T. maritima RNA polymerase at 55 degrees C, the lower limit of temperature range for growth of T. maritima. We propose that the observed properties of TmCsps are physiologically relevant and that TmCsps are important for adaptation of T. maritima to physiologically low temperatures.

Transcriptional and post-transcriptional control of cold-shock genes

A mesophile like Escherichia coli responds to abrupt temperature downshifts (e.g. from 37 degrees C to 10 degrees C) with an adaptive response that allows cell survival and eventually resumption of growth under the new unfavorable environmental conditions. During this response, bulk transcription and translation slow or come to an almost complete stop, while a set of about 26 cold-shock genes is preferentially and transiently expressed. At least some of the proteins encoded by these genes are essential for survival in the cold, but none plays an exclusive role in cold adaptation, not even the "major cold-shock protein" CspA and none is induced de novo. The majority of these proteins binds nucleic acids and are involved in fundamental functions (DNA packaging, transcription, RNA degradation, translation, ribosome assembly, etc.). Although cold-induced activation of specific promoters has been implicated in upregulating some cold-shock genes, post-transcriptional mechanisms play a major role in cold adaptation; cold stress-induced changes of the RNA degradosome determine a drastic stabilization of the cold-shock transcripts and cold shock-induced modifications of the translational apparatus determine their preferential translation in the cold. This preferential translation at low temperature is due to cis elements present in the 5' untranslated region of at least some cold-shock mRNAs and to trans-acting factors whose levels are increased substantially by cold stress. Protein CspA and the three translation initiation factors (IF3 in particular), whose stoichiometry relative to the ribosomes is more than doubled during the acclimation period, are among the trans elements found to selectively stimulate cold-shock mRNA translation in the cold.

Phenotypic characterization of overexpression or deletion of the Escherichia coli crcA, cspE and crcB genes

The authors have previously shown that overexpression of the Escherichia coli K-12 crcA, cspE and crcB genes protects the chromosome from decondensation by camphor. In this study they examine the phenotypic consequences of deleting or overexpressing crcA, cspE and crcB. Overexpressing crcA, cspE and crcB increases supercoiling levels of plasmids in wild-type cells and in temperature-sensitive (Ts) gyrase mutants, suppresses the sensitivity of gyrase and topoisomerase IV (topo IV) Ts mutants to nalidixic acid, makes gyrase and topo IV Ts mutants more resistant to camphor and corrects the nucleoid morphology defects in topo IV Ts mutants. Overexpression of crcA, cspE and crcB results in a slight (2.2-fold) activation of the rcsA gene. Deleting crcA, cspE and crcB is not lethal to cells but results in an increase in sensitivity to camphor. Deletion of crcA, cspE and crcB exacerbates the nucleoid morphology defects of the topo IV Ts mutants. When the individual crcA, cspE or crcB genes were tested for their effects on camphor resistance and regulation of rcsA, cspE alone conferred 10-fold camphor resistance and 1.7-fold activation of rcsA. These activities were augmented when crcB was overexpressed with cspE (100-fold camphor resistance and 2.1-fold induction of rcsA).

Bacterial cold shock responses

As a measure for molecular motion, temperature is one of the most important environmental factors for life as it directly influences structural and hence functional properties of cellular components. After a sudden increase in ambient temperature, which is termed heat shock, bacteria respond by expressing a specific set of genes whose protein products are designed to mainly cope with heat-induced alterations of protein conformation. This heat shock response comprises the expression of protein chaperones and proteases, and is under central control of an alternative sigma factor (sigma 32) which acts as a master regulator that specifically directs RNA polymerase to transcribe from the heat shock promotors. In a similar manner, bacteria express a well-defined set of proteins after a rapid decrease in temperature, which is termed cold shock. This protein set, however, is different from that expressed under heat shock conditions and predominantly comprises proteins such as helicases, nucleases, and ribosome-associated components that directly or indirectly interact with the biological information molecules DNA and RNA. Interestingly, in contrast to the heat shock response, to date no cold-specific sigma factor has been identified. Rather, it appears that the cold shock response is organized as a complex stimulon in which post-transcriptional events play an important role. In this review, we present a summary of research results that have been acquired in recent years by examinations of bacterial cold shock responses. Important processes such as cold signal perception, membrane adaptation, and the modification of the translation apparatus are discussed together with many other cold-relevant aspects of bacterial physiology and first attempts are made to dissect the cold shock stimulon into less complex regulatory subunits. Special emphasis is placed on findings concerning the nucleic acid-binding cold shock proteins which play a fundamental role not only during cold shock adaptation but also under optimal growth conditions.

Three amino acids in Escherichia coli CspE surface-exposed aromatic patch are critical for nucleic acid melting activity leading to transcription antitermination and cold acclimation of cells

Cold-shock proteins of the CspA family of Escherichia coli help the cells to acclimate to low temperature conditions through an unknown mechanism. In vitro, these proteins bind to single-stranded nucleic acids and destabilize nucleic acid secondary structures. An unusual surface-exposed patch of 6 evolutionarily conserved aromatic amino acids is thought to be involved in RNA binding by the cold-shock proteins. Here we investigated the functional role of the aromatic patch in E. coli CspE by substituting individual aromatic residues with positively charged Arg residues. These substitutions do not affect the RNA binding activity of the CspE mutants. We show that substitutions of three centrally located aromatic patch amino acid residues, Phe(17), Phe(30), and His(32), abolish the ability of the mutant CspE to acclimatize cells to cold, antiterminate transcription and melt nucleic acids but have no effect on RNA binding. On the other hand, peripherally located Trp(10), Phe(19), and Phe(33) can be substituted with Arg without loss of any of the in vivo and in vitro CspE functions tested. The results thus indicate that these aromatic patch residues have clearly distinct functional roles and further extend the correlation between the essential function of CspA homologues in cold acclimation and their ability to antiterminate transcription.

Coping with the cold: the cold shock response in the Gram-positive soil bacterium Bacillus subtilis

All organisms examined to date, respond to a sudden change in environmental temperature with a specific cascade of adaptation reactions that, in some cases, have been identified and monitored at the molecular level. According to the type of temperature change, this response has been termed heat shock response (HSR) or cold shock response (CSR). During the HSR, a specialized sigma factor has been shown to play a central regulatory role in controlling expression of genes predominantly required to cope with heat-induced alteration of protein conformation. In contrast, after cold shock, nucleic acid structure and proteins interacting with the biological information molecules DNA and RNA appear to play a major cellular role. Currently, no cold-specific sigma factor has been identified. Therefore, unlike the HSR, the CSR appears to be organized as a complex stimulon rather than resembling a regulon. This review has been designed to draw a refined picture of our current understanding of the CSR in Bacillus subtilis. Important processes such as temperature sensing, membrane adaptation, modification of the translation apparatus, as well as nucleoid reorganization and some metabolic aspects, are discussed in brief. Special emphasis is placed on recent findings concerning the nucleic acid binding cold shock proteins, which play a fundamental role, not only during cold shock adaptation but also under optimal growth conditions.

The nucleic acid melting activity of Escherichia coli CspE is critical for transcription antitermination and cold acclimation of cells

Members of bacterial Csp (cold-shock protein) family promote cellular adaptation to low temperature and participate in many other aspects of gene expression regulation through mechanisms that are not yet fully elucidated. Csp proteins interact with single-stranded nucleic acids and destabilize nucleic acid secondary structures. Some Csp proteins also act as transcription antiterminators in vivo and in vitro. Here, we selected a mutation in the cloned cspE gene that abolished CspE-induced transcription antitermination. In vitro, mutant CspE showed RNA binding activity similar to that of the wild-type CspE but was unable to destabilize nucleic acid secondary structures. Thus, nucleic acid melting ability of CspE and its transcription antitermination activity are correlated. In vivo, mutant cspE was functional with respect to up-regulation of expression of rpoS, but, unlike the wild-type cspE, it did not complement the cold-sensitive phenotype of the quadruple DeltacspADeltacspBDeltacspGDeltacspE deletion strain. Thus, the nucleic acid-melting activity of Csp is critical for its prototypical function of supporting low temperature survival of the cell.

Localization of cold shock proteins to cytosolic spaces surrounding nucleoids in Bacillus subtilis depends on active transcription

Using immunofluorescence microscopy and a fusion of a cold shock protein (CSP), CspB, to green fluorescent protein (GFP), we showed that in growing cells Bacillus subtilis CSPs specifically localize to cytosolic regions surrounding the nucleoid. The subcellular localization of CSPs is influenced by the structure of the nucleoid. Decondensed chromosomes in smc mutant cells reduced the sizes of the regions in which CSPs localized, while cold shock-induced chromosome compaction was accompanied by an expansion of the space in which CSPs were present. As a control, histone-like protein HBsu localized to the nucleoids, while beta-galactosidase and GFP were detectable throughout the cell. After inhibition of translation, CspB-GFP was still present around the nucleoids in a manner similar to that in cold-shocked cells. However, in stationary-phase cells and after inhibition of transcription, CspB was distributed throughout the cell, indicating that specific localization of CspB depends on active transcription and is not due to simple exclusion from the nucleoid. Furthermore, we observed that nucleoids are more condensed and frequently abnormal in cspB cspC and cspB cspD double-mutant cells. This suggests that the function of CSPs affects chromosome structure, probably through coupling of transcription to translation, which is thought to decondense nucleoids. In addition, we found that cspB cspD and cspB cspC double mutants are defective in sporulation, with a block at or before stage 0. Interestingly, CspB and CspC are depleted from the forespore compartment but not from the mother cell. In toto, our findings suggest that CSPs localize to zones of newly synthesized RNA, coupling transcription with initiation of translation.

Escherichia coli poly(A)-binding proteins that interact with components of degradosomes or impede RNA decay mediated by polynucleotide phosphorylase and RNase E

The multifunctional ribonuclease RNase E and the 3'-exonuclease polynucleotide phosphorylase (PNPase) are major components of an Escherichia coli ribonucleolytic "machine" that has been termed the RNA degradosome. Previous work has shown that poly(A) additions to the 3' ends of RNA substrates affect RNA degradation by both of these enzymes. To better understand the mechanism(s) by which poly(A) tails can modulate ribonuclease action, we used selective binding in 1 m salt to identify E. coli proteins that interact at high affinity with poly(A) tracts. We report here that CspE, a member of a family of RNA-binding "cold shock" proteins, and S1, an essential component of the 30 S ribosomal subunit, are poly(A)-binding proteins that interact functionally and physically, respectively, with degradosome ribonucleases. We show that purified CspE impedes poly(A)-mediated 3' to 5' exonucleolytic decay by PNPase by interfering with its digestion through the poly(A) tail and also inhibits both internal cleavage and poly(A) tail removal by RNase E. The ribosomal protein S1, which is known to interact with sequences at the 5' ends of mRNA molecules during the initiation of translation, can bind to both RNase E and PNPase, but in contrast to CspE, did not affect the ribonucleolytic actions of these enzymes. Our findings raise the prospect that E. coli proteins that bind to poly(A) tails may link the functions of degradosomes and ribosomes.

Specific polar localization of ribosomes in Bacillus subtilis depends on active transcription

The large subunit of ribosomes in Bacillus subtilis was tagged by generation of a fusion of ribosomal protein L1 to blue fluorescent protein (BFP). The fusion was fully active and localized around the nucleoids, predominantly close to the cell poles, in growing cells. However, in stationary phase cells, and in growing cells treated with rifampicin, L1-BFP was distributed throughout the cells, in contrast to cells treated with chloramphenicol, in which ribosomes still localized around nucleoids. These data show that specific localization of ribosomes is not due to nucleoid exclusion, but is a dynamic process due to active synthesis of RNA. Dual labelling of ribosomes and cold shock proteins (CSPs) tagged with green fluorescent protein (GFP) revealed colocalization of both protein classes. CSPs are implicated in coupling of transcription with translation and may bridge the spatial separation of ribosomes and nucleoid-associated RNA polymerase.

Acquirement of cold sensitivity by quadruple deletion of the cspA family and its suppression by PNPase S1 domain in Escherichia coli

Escherichia coli contains a large CspA family, CspA to CspI. Here, we demonstrate that E. coli is highly protected against cold-shock stress, as these CspA homologues existed at approximately a total of two million molecules per cell at low temperature and growth defect was not observed until four csp genes (cspA, cspB, cspE and cspG) were deleted. The quadruple-deletion strain acquired cold sensitivity and formed filamentous cells at 15 degrees C although chromosomes were normally segregated. The cold-sensitivity and filamentation phenotypes were suppressed by all members of the CspA family except for CspD, which causes lethality upon overexpression. Interestingly, the cold sensitivity of the mutant was also suppressed by the S1 domain of polynucleotide phosphorylase (PNPase), which also folds into a beta-barrel structure similar to that of CspA. The present results show that cold-shock proteins and S1 domains share not only the tertiary structural similarity but also common functional properties, suggesting that these seemingly distinct protein categories may have evolved from a common primordial RNA-binding protein.

Dynamic localization of bacterial and plasmid chromosomes

Plasmid-encoded partition genes determine the dynamic localization of plasmid molecules from the mid-cell position to the 1/4 and 3/4 positions. Similarly, bacterial homologs of the plasmid genes participate in controlling the bidirectional migration of the replication origin (oriC) regions during sporulation and vegetative growth in Bacillus subtilis, but not in Escherichia coli. In E. coli, but not B. subtilis, the chromosomal DNA is fully methylated by DNA adenine methyltransferase. The E. coli SeqA protein, which binds preferentially to hemimethylated nascent DNA strands, exists as discrete foci in vivo. A single SeqA focus, which is a SeqA-hemimethylated DNA cluster, splits into two foci that then abruptly migrate bidirectionally to the 1/4 and 3/4 positions during replication. Replicated oriC copies are linked to each other for a substantial period of generation time, before separating from each other and migrating in opposite directions. The MukFEB complex of E. coli and Smc of B. subtilis appear to participate in the reorganization of bacterial sister chromosomes.

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.

Role of CspC and CspE in regulation of expression of RpoS and UspA, the stress response proteins in Escherichia coli

Nine homologous proteins, CspA to CspI, constitute the CspA family of Escherichia coli. Recent studies are aimed at elucidating the individual cellular functions of these proteins. Two members of this family, CspC and CspE, are constitutively produced at 37 degrees C. In the present study, these two proteins were evaluated for their cellular role(s). The expression of three stress proteins, OsmY, Dps, and UspA, is significantly affected by the overexpression and deletion of CspC and CspE. RpoS is a regulatory element for osmY and dps. Further analysis showed a larger amount and greater stability of the rpoS mRNA as well as a higher level of RpoS itself with the overexpression of CspC and CspE. This suggests that CspC and CspE upregulate the expression of OsmY and Dps by regulating the expression of RpoS itself. Indeed, this upregulation is lost in the Delta rpoS strain. Other RpoS-controlled proteins such as ProP and KatG, are also upregulated by the overexpression of CspC. The present study suggests that CspC and CspE are the important elements involved in the regulation of the expression of RpoS, a global stress response regulator, and UspA, a protein responding to numerous stresses. In the light of these observations, it seems plausible that CspC and CspE function as regulatory elements for the expression of stress proteins in the complex stress response network of E. coli.

Changes in cspL, cspP, and cspC mRNA abundance as a function of cold shock and growth phase in Lactobacillus plantarum

An inverse PCR strategy based on degenerate primers has been used to identify new genes of the cold shock protein family in Lactobacillus plantarum. In addition to the two previously reported cspL and cspP genes, a third gene, cspC, has been cloned and characterized. All three genes encode small 66-amino-acid proteins with between 73 and 88% identity. Comparative Northern blot analyses showed that the level of cspL mRNA increases up to 17-fold after a temperature downshift, whereas the mRNA levels of cspC and cspP remain unchanged or increase only slightly (about two- to threefold). Cold induction of cspL mRNA is transient and delayed in time as a function of the severity of the temperature downshift. The cold shock behavior of the three csp mRNAs contrasts with that observed for four unrelated non-csp genes, which all showed a sharp decrease in mRNA level, followed in one case (bglH) by a progressive recovery of the transcript during prolonged cold exposure. Abundance of the three csp mRNAs was also found to vary during growth at optimal temperature (28 degrees C). cspC and cspP mRNA levels are maximal during the lag period, whereas the abundance of the cspL transcript is highest during late-exponential-phase growth. The differential expression of the three L. plantarum csp genes can be related to sequence and structural differences in their untranslated regions. It also supports the view that the gene products fulfill separate and specific functions, under both cold shock and non-cold shock conditions.

Escherichia coli CspA-family RNA chaperones are transcription antiterminators

CspA, the major cold-shock protein of Escherichia coli, is an RNA chaperone, which is thought to facilitate translation at low temperature by destabilizing mRNA structures. Here we demonstrate that CspA, as well as homologous RNA chaperones CspE and CspC, are transcription antiterminators. In vitro, the addition of physiological concentrations of recombinant CspA, CspE, or CspC decreased transcription termination at several intrinsic terminators and also decreased transcription pausing. In vivo, overexpression of cloned CspC and CspE at 37 degrees C was sufficient to induce transcription of the metY-rpsO operon genes nusA, infB, rbfA, and pnp located downstream of multiple transcription terminators. Similar induction of downstream metY-rpsO operon genes was observed at cold shock, a condition to which the cell responds by massive overproduction of CspA. The products of nusA, infB, rbfA, and pnp-NusA, IF2, RbfA, and PNP-are known to be induced at cold shock. We propose that the cold-shock induction of nusA, infB, rbfA, and pnp occurs through transcription antitermination, which is mediated by CspA and other cold shock-induced Csp proteins.

The role of cold-shock proteins in low-temperature adaptation of food-related bacteria

There is a considerable interest in the cold adaptation of food-related bacteria, including starter cultures for industrial food fermentations, food spoilage bacteria and food-borne pathogens. Mechanisms that permit low-temperature growth involve cellular modifications for maintaining membrane fluidity, the uptake or synthesis of compatible solutes, the maintenance of the structural integrity of macromolecules and macromolecule assemblies, such as ribosomes and other components that affect gene expression. A specific cold response that is shared by nearly all food-related bacteria is the induction of the synthesis so-called cold-shock proteins (CSPs), which are small (7 kDa) proteins that are involved in mRNA folding, protein synthesis and/or freeze protection. In addition, CSPs are able to bind RNA and it is believed that these proteins act as RNA chaperones, thereby reducing the increased secondary folding of RNA at low temperatures. In this review established and novel aspects concerning the structure, function and control of these CSPs are discussed. A model for bacterial cold adaptation, with a central role for ribosomal functioning, and possible mechanisms for low-temperature sensing are discussed.

Implication of gene distribution in the bacterial chromosome for the bacterial cell factory

As bacterial genome sequences accumulate, more and more pieces of data suggest that there is a significant correlation between the distribution of genes along the chromosome and the physical architecture of the cell, suggesting that the map of the cell is in the chromosome. Considering sequences and experimental data indicative of cell compartmentalisation, mRNA folding and turnover, as well as known structural features of protein and membrane complexes, we show that preliminary in silico analysis of whole genome sequences strongly substantiates this hypothesis. If there is a correlation between the genome sequence and the cell architecture, it must derive from some selection pressure in the organisms growing in the wild. As a consequence, the underlying constraints should be optimised in genetically modified organisms if one is to expect high product yields. Consequences in terms of gene expression for biotechnology are straightforward: knocking genes out and in genomes should not be randomly performed, but should follow the rules of chromosome organisation.

Interactions of the major cold shock protein of Bacillus subtilis CspB with single-stranded DNA templates of different base composition

CspB is a small acidic protein of Bacillus subtilis, the induction of which is increased dramatically in response to cold shock. Although the exact functional role of CspB is unknown, it has been demonstrated that this protein binds single-stranded deoxynucleic acids (ssDNA). We addressed the question of the effect of base composition on the CspB binding to ssDNA by analyzing the thermodynamics of CspB interactions with model oligodeoxynucleotides. Combinations of four different techniques, fluorescence spectroscopy, gel shift mobility assays, isothermal titration calorimetry, and analytical ultracentrifugation, allowed us to show that: 1) CspB can preferentially bind poly-pyrimidine but not poly-purine ssDNA templates; 2) binding to T-based ssDNA template occurs with high affinity (K(d(25 degrees C)) approximately 42 nM) and is salt-independent, whereas binding of CspB to C-based ssDNA template is strongly salt-dependent (no binding is observed at 1 M NaCl), indicating large electrostatic component involved in the interactions; 3) upon binding each CspB covers a stretch of 6-7 thymine bases on T-based ssDNA; and 4) the binding of CspB to T-based ssDNA template is enthalpically driven, indicating the possible involvement of interactions between aromatic side chains on the protein with the thymine bases. The significance of these results with respect to the functional role of CspB in the bacterial cold shock response is discussed.

Cold-shock response and cold-shock proteins

Both prokaryotes and eukaryotes exhibit a cold-shock response upon an abrupt temperature downshift. Cold-shock proteins are synthesized to overcome the deleterious effects of cold shock. CspA, the major cold-shock protein of Escherichia coli, has recently been studied with respect to its structure, function and regulation at the level of transcription, translation and mRNA stability. Homologues of CspA are present in a number of bacteria. Widespread distribution, ancient origin, involvement in the protein translational machinery of the cell and the existence of multiple families in many organisms suggest that these proteins are indispensable for survival during cold-shock acclimation and that they are probably also important for growth under optimal conditions.

Characterization of Escherichia coli cspE, whose product negatively regulates transcription of cspA, the gene for the major cold shock protein

Escherichia coli contains nine members of the CspA protein family from CspA to Cspl. To elucidate the cellular function of CspE, we constructed a delta cspE strain. CspE is highly produced at 37 degrees C. The synthesis level of CspE transiently increased during the growth lag period after dilution of stationary-phase cells into the fresh medium at 37 degrees C. This is consistent with the delta cspE phenotype of the longer growth lag period after dilution. The protein synthesis patterns of the delta cspE strain and the wild-type strain were compared using two-dimensional gel electrophoresis. In the delta cspE strain, the synthesis of a number of proteins at 37 degrees C was found to be altered and cspA was derepressed. The derepression of cspA in the delta cspE strain was at the level of transcription in a promoter-independent fashion but was not caused by stabilization of the cspA mRNA, which was shown to be a major cause of CspA induction after cold shock. In vitro transcription assays demonstrated that both CspE and CspA enhanced transcription pause at the region immediately downstream of the cold box, a putative repressor binding site on the cspA mRNA. In a cell-free protein synthesis system using S-30 cell extracts, CspA production was specifically inhibited by the addition of CspE. These results indicate that CspE functions as a negative regulator for cspA expression at 37 degrees C, probably by interacting with the transcription elongation complex at the cspA cold box region.