Identification of Bacillus subtilis genes expressed early during sporulation

Genome-wide mapping of the binding sites of proteins that interact with DNA

The coordinated regulation of the expression of a group of genes by a specific transcription factor frequently lies at the heart of the ability of a bacterium to respond to an environmental signal, or to progress through a developmental program. Thus, in many situations, it is of interest to identify all of the genes that are under the control of a particular regulatory protein. This chapter begins with a brief overview of some of the methods that have been used in attempts to identify some or all of the members of a regulon (i.e., those genes that are the targets for a transcriptional activator or repressor). Thereafter, the chapter will focus on one technique, chromatin immunoprecipitation and microarray analysis (ChIP-chip) and some of its variants. Design considerations and some protocols for ChIP-chip experiments are provided, along with some considerations related to downstream data analysis. ChIP-chip is a method for the genome-wide localization of protein-binding sites. In a typical ChIP-chip protocol, proteins are cross-linked nonspecifically to DNA in vivo. Chromatin is extracted and sheared, and specific protein-DNA complexes are immunoprecipitated with a suitable antibody. After purification, the DNA is hybridized to a microarray (after an amplification step in some protocols), together with a differentially labeled reference sample. Features on the microarray that show an elevated fluorescence ratio reveal DNA sequences that were enriched by immunoprecipitation. The corresponding genomic locations are those that were enriched, and are therefore close to sites of binding. The use of high-density tiled microarrays allows for binding site localization with quite high resolution. It is likely that ChIP-chip will soon be superseded by ChIP-seq, in which the immunoprecipitated DNA is analyzed directly by next-generation sequencing technologies. ChIP-chip and ChIP-seq applications are not confined to regulatory proteins, since they can be used with any protein that binds to DNA, either directly, or indirectly via an interaction with another protein. Thus, ChIP-chip has been used successfully to map binding sites for nucleoid proteins, and proteins involved in DNA replication.

Effects of metabolic flux on stress response pathways in Lactococcus lactis

Studies of cellular responses to stress conditions such as heat, oxygen or starvation have revealed the existence of numerous specific or interactive response pathways. We previously observed in Lactococcus lactis that inactivation of the recA gene renders the lactococcal strain sensitive not only to DNA-damaging agents but also to oxygen and heat. To further examine the stress response pathways in L. lactis, we isolated thermoresistant insertional mutants (Trm) of the recA strain. Eighteen independent trm mutations were identified and characterized. We found that mutations map in only seven genes, implicated in purine metabolism (deoB, guaA and tktA), phosphate uptake (pstB and pstS), mRNA stability (pnpA) and in one uncharacterized gene (trmA). All the trm mutations, with the exception of trmA, confer multiple stress resistance to the cell. Some of the mutations confer improved heat stress resistance not only in the recA but also in the wild-type context. Our results reveal that cellular metabolic pathways are intimately related to stress response and that the flux of particular metabolites, notably guanine and phosphate, may be implicated in stress response in lactococci.

Identification of differentially expressed mRNA in prokaryotic organisms by customized amplification libraries (DECAL): the effect of isoniazid on gene expression in Mycobacterium tuberculosis

Understanding the effects of the external environment on bacterial gene expression can provide valuable insights into an array of cellular mechanisms including pathogenesis, drug resistance, and, in the case of Mycobacterium tuberculosis, latency. Because of the absence of poly(A)+ mRNA in prokaryotic organisms, studies of differential gene expression currently must be performed either with large amounts of total RNA or rely on amplification techniques that can alter the proportional representation of individual mRNA sequences. We have developed an approach to study differences in bacterial mRNA expression that enables amplification by the PCR of a complex mixture of cDNA sequences in a reproducible manner that obviates the confounding effects of selected highly expressed sequences, e.g., ribosomal RNA. Differential expression using customized amplification libraries (DECAL) uses a library of amplifiable genomic sequences to convert total cellular RNA into an amplified probe for gene expression screens. DECAL can detect 4-fold differences in the mRNA levels of rare sequences and can be performed on as little as 10 ng of total RNA. DECAL was used to investigate the in vitro effect of the antibiotic isoniazid on M. tuberculosis, and three previously uncharacterized isoniazid-induced genes, iniA, iniB, and iniC, were identified. The iniB gene has homology to cell wall proteins, and iniA contains a phosphopantetheine attachment site motif suggestive of an acyl carrier protein. The iniA gene is also induced by the antibiotic ethambutol, an agent that inhibits cell wall biosynthesis by a mechanism that is distinct from isoniazid. The DECAL method offers a powerful new tool for the study of differential gene expression.

The isolation of novel heat shock genes in Lactococcus lactis using RNA subtractive hybridization

Lactococcus lactis is subjected to heat shock (hs) during cheese manufacturing. A number of conserved hs genes have been cloned and studied in this organism, although no regulatory gene, e.g. alternative sigma factor, has been identified. RNA subtractive hybridization was used to identify genes expressed very early when L. lactis MG1363 was shifted from 30 to 43 degrees C. 32P-labeled cDNA synthesized from RNA isolated from hs cells at 43 degrees C was mixed with an excess vegetative RNA and the mixture was directly used as a probe after a short hybridization step. Northern analysis revealed a moderate induction for the probes used, and low expression was also detected in non-hs cells, demonstrating the applicability of this technique for the detection of differentially expressed genes. The probes were used to identify genomic library clones containing the corresponding genes. Among the five clones studied, a cell division operon including a putative ftsZ homolog (pJAK2) was identified. Additionally, a putative hsp86 homolog (pJAK3), three different transposase encoding genes (pJAK1 and pJAK3), a gene coding for a deoR-like transcriptional repressor (pJAK4) and a putative regulatory gene that showed homology to an alkaline shock protein (pJAK5) were characterized.

A gene required for nutritional repression of the Bacillus subtilis dipeptide permease operon

An insertion mutation was isolated that resulted in derepressed expression of the Bacillus subtillis dipeptide transport operon (dpp) during the exponential growth phase in rich medium. DNA flanking the site of insertion was found to encode an operon (codVWXY) of four potential open reading frames (ORFs). The deduced product of the codV ORF is similar to members of the lambda Int family; CodW and CodX are homologous to HsIV and HsIU, two putative heat-shock proteins from Escherichia coli, and to LapC and LapA, two gene products of unknown function from Pasteurella haemolytica. CodX also shares homology with a family of ATPases, including ClpX, a regulatory subunit of the E. coli ClpP protease. CodY does not have any homologues in the data-bases. The insertion mutation and all previously isolated spontaneous cod mutations were found to map in codY. In-frame deletion mutations in each of the other cod genes revealed that only codY is required for repression of dpp in nutrient-rich medium. The codY mutations partially relieved amino acid repression of the histidine utilization (hut) operon but had no effect on regulation of certain other early stationary phase-induced genes, such as spoVG and gsiA.

Expression from the Clostridium perfringens cpe promoter in C. perfringens and Bacillus subtilis

Clostridium perfringens is a source of food poisoning in humans and animals because of production of a potent enterotoxin (CPE). To study the regulation of the cpe gene in C. perfringens, we cloned and sequenced the cpe promoter regions and N-terminal domains from three strains. The cpe promoter region from one strain contained a 45-bp insertion compared with previously published sequences. This insertion was also found in two (of five) other Cpe+ strains. cpe gene expression in C. perfringens was measured by using translational fusions of each promoter type to the Escherichia coli gusA gene, which codes for beta-glucuronidase. For either promoter type, cpe-gusA expression was undetectable throughout exponential growth but increased dramatically at the beginning of the stationary phase. To measure cpe expression in Bacillus subtilis, cpe-gusA fusions were integrated into the B. subtilis chromosome. Both types of promoter exhibited moderate expression during exponential growth; cpe expression increased threefold at the beginning of the stationary phase. Transcriptional start sites were determined by primer extension and in vitro transcription assays. For C. perfringens, both types of promoter gave the same 5' end, 197 bp upstream of the translation start (50 bp downstream of the 45-bp insertion). In B. subtilis, however, the 5' end was internal to the 45-bp insertion, suggesting the use of a different promoter than that utilized by C. perfringens.

Mutations that relieve nutritional repression of the Bacillus subtilis dipeptide permease operon

The Bacillus subtilis dciA operon encodes a dipeptide transport complex that is induced rapidly as cells enter stationary phase and initiate sporulation. Expression of this operon in growing cells is repressed by glucose, by a mixture of amino acids, and by the AbrB protein. A genetic screen was devised to identify mutations that allow inappropriate expression from the dciA promoter during growth. These mutations resulted in increased dciA transcription during growth in nutrient broth, in minimal amino acids medium, and in minimal glucose medium. Some of the mutations, called dcs (dciA control site), were cloned and shown by sequence analysis to cluster near the start site of dciA transcription. Primer extension and in vitro transcription analysis revealed that the dcs mutations did not create a new promoter. These mutations may therefore disrupt an operator site necessary for the binding of a negative regulator responsive to the nutritional state of the cell. The dcs mutant promoters were still subject to AbrB control, suggesting that the dciA operon is regulated by at least two proteins, AbrB and a nutritionally responsive regulator. The gene(s) for the putative nutritional regulator may be defined by the cod (control of dciA) mutations, which appeared to relieve amino acid and glucose repression of dciA by altering a diffusible factor. An abrB cod double mutant exhibited high-level expression of dciA during exponential growth phase.

Transcriptional regulation of Bacillus subtilis glucose starvation-inducible genes: control of gsiA by the ComP-ComA signal transduction system

The Bacillus subtilis glucose starvation-inducible transcription units, gsiA and gsiB, were characterized by DNA sequencing, transcriptional mapping, mutational analysis, and expression in response to changes in environmental conditions. The gsiA operon was shown to consist of two genes, gsiAA and gsiAB, predicted to encode 44.9- and 4.8-kDa polypeptides, respectively. The gsiB locus contains a single cistron which encodes a protein of unusual structure; most of its amino acids are arranged in five highly conserved, tandemly repeated units of 20 amino acids. The 5' ends of gsiA and gsiB mRNAs were located by primer extension analysis; their locations suggest that both are transcribed by RNA polymerase containing sigma A. Expression of both gsiA and gsiB was induced by starvation for glucose or phosphate or by addition of decoyinine, but only gsiA was induced by exhaustion of nutrient broth or by amino acid starvation. Regulation of gsiA expression was shown to be dependent upon the two-component signal transduction system ComP-ComA, which also controls expression of genetic competence genes. Mutations in mecA bypassed the dependency of gsiA expression on ComA. Disruption of gsiA relieved glucose repression of sporulation but did not otherwise interfere with sporulation, development of competence, motility, or glucose starvation survival. We propose that gsiA and gsiB are members of an adaptive pathway of genes whose products are involved in responses to nutrient deprivation other than sporulation.

Identification of Bacillus subtilis adaptive response genes by subtractive differential hybridization

Subtractive differential hybridization was used to identify genes in Bacillus subtilis that are induced by nutrient limitation. Several transcription units were identified. They exhibited increased transcription when cells were deprived of certain nutrients, such as glucose, ammonium, or phosphate, or when cells were treated with decoyinine. The genes have been designated dci (for decoyinine-inducible) and gsi (for glucose-starvation-inducible). Using lacZ transcriptional fusions, the dependence of dci and gsi expression on gene products of the sensor and activator classes of bacterial two-component regulatory systems was examined. Transcription of dciA was impaired by a mutation in spoOA, while expression of gsiA was dependent on the early competence genes comP and comA. The implications of these findings are discussed, and a provisional scheme for information flow during the transition phase from growth to sporulation is proposed.

Isolation of Bradyrhizobium japonicum DNA sequences that are transcribed at high levels in bacteroids

DNA sequences have been isolated that are expressed at high levels in bacteroids, the differentiated form of the soybean microsymbiont, Bradyrhizobium japonicum. Random-primed cDNA was synthesized using total RNA isolated from purified B. japonicum bacteroids or from cells grown in culture. When used directly to screen bacteriophage lambda libraries, these cDNA probes produced a high background hybridization signal due to sequence similarity between B. japonicum and E. coli ribosomal DNA (rDNA) operons. To reduce this background signal, the rDNA operon of B. japonicum was cloned and the rDNA plasmid DNA used in subtractive hybridization with the cDNA probes and as a competitor in hybridization solutions. This method greatly reduced the background signal in screening of genomic libraries and thus permitted the identification of twelve unique recombinant phage which contained sequences that are expressed at higher levels in B. japonicum bacteroids than in cells grown in culture.

Transcriptional regulation of a Bacillus subtilis dipeptide transport operon

The Bacillus subtilis dciA operon, which encodes a dipeptide transport system, was induced rapidly by several conditions that caused the cells to enter stationary phase and initiate sporulation. The in vivo start point of transcription was mapped precisely and shown to correspond to a site of transcription initiation in vitro by the major vegetative form of RNA polymerase. Post-exponential expression was prevented by a mutation in the spo0A gene (whose product is a known regulator of early sporulation genes) but was restored in a spo0A abrB double mutant. This implicated AbrB, another known regulator, as a repressor of dciA. In fact, purified AbrB protein bound to a portion of the dciA promoter region, protecting it against DNase I digestion. Expression of dciA in growing cells was also repressed independently by glucose and by a mixture of amino acids; neither of these effects was mediated by AbrB.

A Bacillus subtilis dipeptide transport system expressed early during sporulation

Two previously identified Bacillus subtilis DNA segments, dciA and dciB, whose transcripts accumulate very rapidly after induction of sporulation, were found in the same 6.2 kb transcription unit, now known as the dciA operon. Analysis of the sequence of the dciA operon showed that its putative products are homologous to bacterial peptide transport systems. The product of the fifth gene, DciAE, is similar to peptide-binding proteins from Escherichia coli and Salmonella typhimurium (DppA and OppA) and B. subtilis (OppA). A null mutation in dciAE abolished the ability of a proline auxotroph to grow in a medium containing the dipeptide Pro-Gly as sole proline source, suggesting that the dciA operon encodes a dipeptide transport system.

DegS-DegU and ComP-ComA modulator-effector pairs control expression of the Bacillus subtilis pleiotropic regulatory gene degQ

Production of a class of both secreted and intracellular degradative enzymes in Bacillus subtilis is regulated at the transcriptional level by a signal transduction pathway which includes the DegS-DegU two-component system and at least two additional regulatory genes, degQ and degR, encoding polypeptides of 46 and 60 amino acids, respectively. Expression of degQ was shown to be controlled by DegS-DegU. This expression is decreased in the presence of glucose and increased under any of the following conditions: growth with poor carbon sources, amino acid deprivation, phosphate starvation, and growth in the presence of decoyinine, a specific inhibitor of GMP synthetase. In addition, expression of degQ is shown to be positively regulated by the ComP-ComA two-component system. Separate targets for regulation of degQ gene expression by DegS-DegU and ComP-ComA were located by deletion analysis between positions -393 and -186 and between positions -78 and -40, respectively. Regulation of degQ expression by amino acid deprivation was shown to be dependent upon ComA. Regulation by phosphate starvation, catabolite repression, and decoyinine was independent of the two-component systems and shown to involve sequences downstream from position -78. The ComP-ComA and DegS-DegU two-component systems seem to be closely related, sharing several target genes in common, such as late competence genes, as well as the degQ regulatory gene. Sequence analysis of the degQ region revealed the beginning of an open reading frame directly downstream from degQ. Disruption of this gene, designated comQ, suggests that it also controls expression of degQ and is required for development of genetic competence.