Genetics and regulation of chitobiose utilization in Borrelia burgdorferi

Borrelia burgdorferi spends a significant proportion of its life cycle within an ixodid tick, which has a cuticle containing chitin, a polymer of N-acetylglucosamine (GlcNAc). The B. burgdorferi celA, celB, and celC genes encode products homologous to transporters for cellobiose and chitobiose (the dimer subunit of chitin) in other bacteria, which could be useful for bacterial nutrient acquisition during growth within ticks. We found that chitobiose efficiently substituted for GlcNAc during bacterial growth in culture medium. We inactivated the celB gene, which encodes the putative membrane-spanning component of the transporter, and compared growth of the mutant in various media to that of its isogenic parent. The mutant was no longer able to utilize chitobiose, while neither the mutant nor the wild type can utilize cellobiose. We propose renaming the three genes chbA, chbB, and chbC, since they probably encode a chitobiose transporter. We also found that the chbC gene was regulated in response to growth temperature and during growth in medium lacking GlcNAc.

DNA exchange and insertional inactivation in spirochetes

Spirochetes have complex life cycles and are associated with a number of diseases in humans and animals. Despite their significance as pathogens, spirochete genetics are in their early stages. However, gene inactivation has been achieved in Borrelia burgdorferi, Brachyspira hyodysenteriae, and Treponema denticola. Here, we review methods that have been used in spirochetes for gene inactivation and DNA exchange, with a primary focus on B. burgdorferi. We also describe factors influencing electrotransformation in B. burgdorferi. In summary, optimal transformation frequencies are obtained with log phase bacteria, large amounts of DNA (up to 50 microg per transformation), and high field strength (12.5-37.5 kV/cm). Infectious B. burgdorferi isolates transform with frequencies 100-fold lower than those found for high passage, non-infectious strains. Surface characteristics of the bacteria, which often correlate with infectivity, are among the obstacles to effective transformation by electroporation.

Efficient targeted mutagenesis in Borrelia burgdorferi

Genetic studies in Borrelia burgdorferi have been hindered by the lack of a nonborrelial selectable marker. Currently, the only selectable marker is gyrB(r), a mutated form of the chromosomal gyrB gene that encodes the B subunit of DNA gyrase and confers resistance to the antibiotic coumermycin A(1). The utility of the coumermycin-resistant gyrB(r) gene for targeted gene disruption is limited by a high frequency of recombination with the endogenous gyrB gene. A kanamycin resistance gene (kan) was introduced into B. burgdorferi, and its use as a selectable marker was explored in an effort to improve the genetic manipulation of this pathogen. B. burgdorferi transformants with the kan gene expressed from its native promoter were susceptible to kanamycin. In striking contrast, transformants with the kan gene expressed from either the B. burgdorferi flaB or flgB promoter were resistant to high levels of kanamycin. The kanamycin resistance marker allows efficient direct selection of mutants in B. burgdorferi and hence is a significant improvement in the ability to construct isogenic mutant strains in this pathogen.

Altered stationary-phase response in a Borrelia burgdorferi rpoS mutant

The homolog of the chromosomally encoded stationary-phase sigma factor RpoS in Borrelia burgdorferi was inactivated using gyrB(r) as a selectable marker. Two-dimensional nonequilibrium pH gradient electrophoresis of stationary-phase cell lysates identified at least 11 differences between the protein profiles of the rpoS mutant and wild-type organisms. Wild-type B. burgdorferi had a growth phase-dependent resistance to 1 N NaCl, similar to the stationary-phase response reported for other bacteria. The B. burgdorferi rpoS mutant strain was less resistant to osmotic stress in stationary phase than the isogenic rpoS wild-type organism. The results indicate that the B. burgdorferi rpoS homolog influences protein composition and participates in stationary-phase-dependent osmotic resistance. This rpoS mutant will be useful for studying regulation of gene expression in response to changing environmental conditions.

Temperature-regulated expression of bacterial virulence genes

Virulence gene expression in most bacteria is a highly regulated phenomenon, affected by a variety of parameters including osmolarity, pH, ion concentration, iron levels, growth phase, and population density. Virulence genes are also regulated by temperature, which acts as an 'on-off' switch in a manner distinct from the more general heat-shock response. Here, we review temperature-responsive expression of virulence genes in four diverse pathogens.

Growth of infectious and non-infectious B. burgdorferi at different salt concentrations

Borrelia burgdorferi, the causative agent of Lyme disease, grows in vitro in modified Barbour-Stoenner-Kelly (BSK-H) medium. We have studied the effect of increased osmotic strength of culture media on growth of infectious and non-infectious B. burgdorferi strains B31 and N40. Relatively small increases in the NaCl concentration of the medium significantly inhibited growth in infectious as well as non-infectious strains. Growth of low passage, infectious clone B31-4a was more sensitive to increased NaCl concentrations than high passage, non-infectious clone B31-a. Growth of two infectious N40 strains, one low passage (N40-Lp) and one high passage (N40-P31) was more resistant to increased NaCl concentration than growth of infectious B31-4a. Osmotic strength is an important physical parameter for growth of B. burgdorferi in vitro and could influence its ability to adapt and to establish an infection within ticks and mammals.

Genetic studies in Borrelia burgdorferi

Borrelia burgdorferi, the agent of Lyme disease, has recently joined a growing number of micro-organisms for which the entire genomic sequence is known. Despite this wealth of information, little is known about the contribution of specific spirochetal components to the pathogenesis of Lyme disease or their function in the normal life cycle of the organism. This discrepancy is due in part to the lack of a well-developed genetic system in B. burgdorferi, which in turn can be attributed to its relatively recent isolation and the dissimilarity of Borrelia from other genetically tractable bacteria. We are interested in several plasmid-encoded gene products in B. burgdorferi that may play a role in sensing and adaptation to the different environments the spirochete encounters as it completes an infectious cycle between the tick vector and the mammalian host. We are developing genetic tools with which to test the roles of specific B. burgdorferi gene products in the transmission cycle in an animal model of Lyme disease. We have demonstrated targeted gene inactivation by allelic exchange, using the gyrBr gene encoding coumermycin-resistant topoisomerase as a selectable marker. Spirochetes are transformed by electroporation and coumermycin-resistant colonies are screened by PCR for allelic exchange at the targeted locus. We have successfully inactivated several genes of interest in the type strain B31. We are investigating the utility of additional antibiotic resistance genes as selectable markers in B. burgdorferi. Targeted gene inactivation is a powerful tool with which to investigate the role of particular proteins in the basic biology and virulence of a pathogenic microorganism. We have made significant advances in our ability to genetically manipulate B. burgdorferi in order to address these issues. However, the available methods are incomplete and far from routine. We are currently improving existing methods as well as developing additional genetic tools with which to augment genetic studies in B. burgdorferi.

Characterization of circular plasmid dimers in Borrelia burgdorferi

We have inactivated the ospC, oppAIV, and guaB genes on the 26-kb circular plasmid of Borrelia burgdorferi (cp26) by allelic exchange. On several occasions following such transformations, the cp26 of transformants had an aberrant mobility through agarose gels. Characterization of these cp26 molecules showed that the plasmid had dimerized. These dimers were quite stable during either selective or nonselective passage. Subsequent transformations with dimer DNA supported the hypothesis that in B. burgdorferi, transforming cp26 DNA most likely does not displace the resident homologous plasmid but rather must recombine in order to donate sequences that it carries. These serendipitous findings provide a mechanism for obtaining heterozygous complemented control strains when mutant phenotypes are characterized.

Transformation of the Lyme disease spirochete Borrelia burgdorferi with heterologous DNA

Studies of the spirochete Borrelia burgdorferi have been hindered by the scarcity of genetic tools that can be used in these bacteria. For the first time, a method has been developed by which heterologous DNA (DNA without a naturally occurring B. burgdorferi homolog) can be introduced into and persistently maintained by B. burgdorferi. This technique uses integration of circular DNA into the bacterial genome via a single-crossover event. The ability to transform B. burgdorferi with heterologous DNA will now permit a wide range of experiments on the biology of these bacteria and their involvement in the many facets of Lyme disease.

Cloning and expression of the Borrelia burgdorferi lon gene

The ATP-dependent protease Lon (La) of Escherichia coli degrades abnormal proteins and is involved in the regulation of capsular polysaccharide synthesis. In addition, mutations in the E. coli lon gene suppress temperature-sensitive mutations in other genes. The lon gene of Borrelia burgdorferi, encoding a homolog of the Lon protease, has been cloned and sequenced. The gene encodes a protein of 806 amino acids. The deduced amino acid sequence of the B. burgdorferi Lon protease shares substantial sequence identity with those of other known Lon proteases. The transcription start point of the B. burgdorferi lon gene was identified by primer extension analysis and the potential promoter did not show similarities to the consensus heat-shock promoter in E. coli. The 5'-end of the B. burgdorferi lon gene appears to suppress the temperature-sensitive phenotype of an E. coli lpxA mutant.

Characterization of cp18, a naturally truncated member of the cp32 family of Borrelia burgdorferi plasmids

We have mapped the genes encoding the antigenic lipoproteins OspE and OspF to an approximately 18-kb circular plasmid in Borrelia burgdorferi N40. Sequencing and restriction mapping have revealed that this plasmid, cp18, is homologous to an 18-kb region of the cp32 circular plasmids found in the Lyme disease spirochetes. Our data show that cp18 may have arisen from an ancestral cp32 plasmid by deletion of a 14-kb region of DNA, indicating that a significant portion of the cp32 plasmid is not essential in cis for plasmid maintenance. These findings suggest that a relatively small recombinant plasmid capable of being stably maintained in B. burgdorferi could be constructed from a cp32 plasmid.

The Borrelia burgdorferi circular plasmid cp26: conservation of plasmid structure and targeted inactivation of the ospC gene

The 26 to 28kb circular plasmid of B. burgdorferi sensu lato (cp26) is ubiquitous among bacteria of this group and contains loci implicated in the mouse-tick transmission cycle. Restriction mapping and Southern hybridization indicated that the structure of cp26 is conserved among isolates from different origins and culture passage histories. The cp26 ospC gene encodes an outer surface protein whose synthesis within infected ticks increases when the ticks feed, and whose synthesis in culture increases after a temperature upshift. Previous studies of ospC coding sequences showed them to have stretches of sequence apparently derived from the ospC genes of distantly related isolates by homologous recombination after DNA transfer. We found conservation of the promoter regions of the ospC and guaA genes, which are divergently transcribed. We also demonstrated that the increase in OspC protein after a temperature upshift parallels increases in mRNA levels, as expected if regulatory regions adjoin the conserved sequences in the promoter regions. Finally, we used directed insertion to inactivate the ospC gene of a non-infectious isolate. This first example of directed gene inactivation in B. burgdorferi shows that the OspC protein is not required for stable maintenance of cp26 or growth in culture.

Homology throughout the multiple 32-kilobase circular plasmids present in Lyme disease spirochetes

We have characterized seven different 32-kb circular plasmids carried by Borrelia burgdorferi isolate B31. Restriction endonuclease recognition site mapping and partial sequencing of these plasmids indicated that all seven are probably closely related to each other throughout their lengths and have substantial relationships to cp8.3, an 8.3-kb circular plasmid of B. burgdorferi sensu lato isolate Ip21. With the addition of the seven 32-kb plasmids, this bacterial strain is known to carry at least 10 linear and 9 circular plasmids. Variant cultures of B. burgdorferi B31 lacking one or more of the 32-kb circular plasmids are viable and, at least in some cases, infectious. We have examined a number of different natural isolates of Lyme disease borreliae and found that all of the B. burgdorferi sensu stricto isolates and most of the B. burgdorferi sensu lato isolates tested appear to carry multiple 32-kb circular plasmids related to those of B. burgdorferi B31. The ubiquity of these plasmids suggests that they may be important in the natural life cycle of these organisms. They may be highly conjugative plasmids or prophage genomes, which could prove to be useful in genetically manipulating B. burgdorferi.

Directed insertion of a selectable marker into a circular plasmid of Borrelia burgdorferi

Studies of the biology of Borrelia burgdorferi and the pathogenesis of Lyme disease are severely limited by the current lack of genetic tools. As an initial step toward facile genetic manipulation of this pathogenic spirochete, we have investigated gene inactivation by allelic exchange using a mutated borrelial gyrB gene that confers resistance to the antibiotic coumermycin A1 as a selectable marker. We have transformed B. burgdorferi by electroporation with a linear fragment of DNA in which this selectable marker was flanked by sequences from a native borrelial 26-kb circular plasmid. We have identified coumermycin A1-resistant transformants in which gyrB had interrupted the targeted site on the 26-kb plasmid via homologous recombination with the flanking sequences. Antibiotic resistance conferred by the mutated gyrB gene on the plasmid is dominant, and transformed spirochetes carrying this plasmid do not contain any unaltered copies of the plasmid. Coumermycin A1 resistance can be transferred to naive B. burgdorferi by transformation with borrelial plasmid DNA from the initial transformants. This work represents the first example of a directed mutation in B. burgdorferi whereby a large segment of heterologous DNA (gyrB) has been inserted via homologous recombination with flanking sequences, thus demonstrating the feasibility of specific gene inactivation by allelic exchange.

Isolation of Borrelia burgdorferi genes encoding homologues of DNA-binding protein HU and ribosomal protein S20

Linear DNA with covalently closed ends is the predominant form of DNA in the spirochaete Borrelia burgdorferi. All bacteria examined to date have small DNA-binding proteins related to the Escherichia coli IHF and HU proteins that appear to play roles in DNA compaction and replication, but such proteins had not been isolated from bacteria with linear genomes. We found a single gene in B. burgdorferi (named hbb) whose product (named Hbb) complements the defects for gamma DNA packaging found in E. coli strains mutant in the genes for IHF and HU. The sequence of the predicted B. burgdorferi protein is similar to those of HU and IHF-like proteins in other bacteria. The gene appears to be in an operon with the order rpsT-hbb-orfH, where the rpsT gene is a homologue of the E. coli gene encoding ribosomal protein S20 and the orfH gene encodes a protein of unknown function. This operon is located upstream of the previously identified B. burgdorferi rho homologue.

A family of genes located on four separate 32-kilobase circular plasmids in Borrelia burgdorferi B31

We have identified four loci in Borrelia burgdorferi B31 that contain open reading frames capable of encoding six proteins that are related to the antigenic proteins OspE and OspF. We have designated these proteins Erp, for OspEF-related protein, and named their respective genes erp. The erpA and erpB genes are linked, as are erpC and erpD, and the pairs probably constitute two operons. The erpG and erpH genes appear to be monocistronic. The ErpA and ErpC proteins are expressed by B. burgdorferi B31 in culture and are recognized by a polyclonal antiserum raised against the OspE protein of B. burgdorferi N40. The four erp loci are each located on different 32-kb circular plasmids that contain additional DNA sequences that are homologous to each other and to an 8.3-kb circular plasmid of B. burgdorferi sensu lato Ip2l. All four 32-kb plasmids can be maintained within a single bacterium, which may provide a model for the study of plasmid replication and segregation in B. burgdorferi.

Plasmid location of Borrelia purine biosynthesis gene homologs

The Lyme disease spirochete Borrelia burgdorferi must survive in both its tick vector and its mammalian host to be maintained in nature. We have identified the B. burgdorferi guaA gene encoding GMP synthetase, an enzyme involved in de novo purine biosynthesis that is important for the survival of bacteria in mammalian blood. This gene encodes a functional product that will complement an Escherichia coli GMP synthetase mutant. The gene is located on a 26-kb circular plasmid, adjacent to and divergent from the gene encoding the outer surface protein C (OspC). The guaB gene homolog encoding IMP dehydrogenase, another enzyme in the purine biosynthetic pathway, is adjacent to guaA. In Borrelia hermsii, a tick-borne relapsing fever spirochete, the guaA and guaB genes are located on a linear plasmid. These are the first genes encoding proteins of known function to be mapped to a borrelial plasmid and the only example of genes encoding enzymes involved in the de novo purine biosynthesis pathway to be mapped to a plasmid in any organism. The unique plasmid location of these and perhaps other housekeeping genes may be a consequence of the segmented genomes in borreliae and reflect the need to adapt to both the arthropod and mammalian environments.

Linear plasmids and chromosomes in bacteria

Linear plasmids and chromosomes were unknown in prokaryotes until recently but have now been found in spirochaetes, Gram-positive bacteria, and Gram-negative bacteria. Two structural types of bacterial linear DNA have been characterized. Linear plasmids of the spirochaete Borrelia have a covalently closed hairpin loop at each end and linear plasmids of the Gram-positive filamentous Streptomyces have a covalently attached protein at each end. Replicons with similar structures are more frequent in eukaryotic cells than in prokaryotes. Linear genomic structures are probably more common in bacteria than previously recognized, however, and some replicons may interconvert between circular and linear isomers. The molecular biology of these widely dispersed elements provides clues to explain the origin of linear DNA in bacteria, including evidence for genetic exchange between prokaryotes and eukaryotes.

Isolation of dnaJ, dnaK, and grpE homologues from Borrelia burgdorferi and complementation of Escherichia coli mutants

The heat-shock proteins DnaJ, DnaK, and GrpE are involved in the replication of various species of DNA in Escherichia coli, in addition to their roles in other processes, including protein disaggregation and export. We have cloned the Borrelia burgdorferi homologues of these genes. DNA sequence analysis revealed an open reading frame encoding a protein that is 62% identical to the E. coli DnaK protein. Genes homologous to the E. coli grpE and dnaJ genes, encoding products 28% and 39% identical to their homologues, are located up- and downstream, respectively, of the B. burgdorferi dnaK gene. No obvious promoters were detected in the sequenced DNA, although a potential transcription terminator was found downstream of the dnaJ gene, so these three genes may form an operon, perhaps with a fourth gene located upstream of the grpE gene. The grpE homologue complemented an E. coli grpE mutant and the dnaJ homologue complemented an E. coli dnaJ mutant, whereas the B. burgdorferi dnaK gene did not complement dnaK mutants.

Independence of bacteriophage N15 lytic and linear plasmid replication from the heat shock proteins DnaJ, DnaK, and GrpE

The chromosome of the temperate bacteriophage N15 replicates as a linear plasmid with covalently closed ends (or hairpins) when it forms a lysogen. I found that, in contrast to the cases for lambda and the low-copy-number plasmids F and P1, both phage and plasmid replication of N15 are independent of the heat shock proteins DnaJ, DnaK, and GrpE.

Participation of the Escherichia coli heat shock proteins DnaJ, DnaK, and GrpE in autorepression of the P1 plasmid repA promoter

The replicon of the low copy number plasmid P1 uses the three Escherichia coli heat shock proteins DnaJ, DnaK, and GrpE for the efficient initiation of its DNA replication. The only P1-encoded protein required for plasmid replication is the initiator, RepA. Binding of RepA to the origin also represses the promoter for the repA gene, which is located within the origin. We found that repression is incomplete in E. coli strains with mutations in the dnaJ, dnaK, or grpE genes. Since there is no decrease in RepA concentration in the mutant strains, the mutations are likely to affect the protein-DNA or protein-protein reactions required for repression, thereby decreasing RepA binding at its promoter. We also showed that the deficit in repression can be overcome by providing excess RepA, implying that the mechanism of repression is not altered in the mutant strains. Since repression requires RepA binding to the origin, a binding deficit might account for the replication defect in the heat shock mutants.

Participation of Escherichia coli heat shock proteins DnaJ, DnaK, and GrpE in P1 plasmid replication

Low-copy-number plasmids, such as P1 prophage and the fertility factor F, require a plasmid-encoded replication protein and several host products for replication. Stable maintenance also depends on active partitioning of plasmids into daughter cells. Mini-P1 par+ and par plasmids were found to be destabilized by mutations in the dnaJ, dnaK, and grpE genes of Escherichia coli. The transformation efficiency and stability of mini-F plasmids were also reduced in the mutant strains. These results indicate that heat shock proteins DnaJ, DnaK, and GrpE play roles in the replication of plasmid P1 and probably also in of F.

Modulation of stability of the Escherichia coli heat shock regulatory factor sigma

The heat shock response of Escherichia coli is under the positive control of the sigma 32 protein (the product of the rpoH gene). We found that overproduction of the sigma 32 protein led to concomitant overproduction of the heat shock proteins, suggesting that the intracellular sigma 32 levels limit heat shock gene expression. In support of this idea, the intracellular half-life of the sigma 32 protein synthesized from a multicopy plasmid was found to be extremely short, e.g., less than 1 min at 37 and 42 degrees C. The half-life increased progressively with a decrease in temperature, reaching 15 min at 22 degrees C. Finally, conditions known previously to increase the rate of synthesis of the heat shock proteins, i.e., a mutation in the dnaK gene or expression of phage lambda early proteins, were shown to simultaneously result in a three- to fivefold increase in the half-life of sigma 32.

Homologous plant and bacterial proteins chaperone oligomeric protein assembly

An abundant chloroplast protein is implicated in the assembly of the oligomeric enzyme ribulose bisphosphate carboxylase-oxygenase, which catalyses photosynthetic CO2-fixation in higher plants. The product of the Escherichia coli groEL gene is essential for cell viability and is required for the assembly of bacteriophage capsids. Sequencing of the groEL gene and the complementary cDNA encoding the chloroplast protein has revealed that these proteins are evolutionary homologues which we term 'chaperonins'. Chaperonins comprise a class of molecular chaperones that are found in chloroplasts, mitochondria and prokaryotes. Assisted post-translational assembly of oligomeric protein structures is emerging as a general cellular phenomenon.

Heat shock regulatory gene rpoH mRNA level increases after heat shock in Escherichia coli

The Escherichia coli rpoH gene product sigma 32 is essential for the increase in heat shock gene transcription found after exposure of the bacteria to a sudden temperature increase. It is not known how the concentration of active sigma 32 is modulated. We showed that rpoH transcript levels increased after heat shock and that the magnitude of the increase in the level of mRNA was correlated with the magnitude of the temperature shift. The increase in the level of rpoH mRNA was still found in rpoH mutants so the mechanism of induction differed from that of the set of previously identified heat shock genes. The increased concentration of rpoH mRNA should result in a higher level of sigma 32, which is likely to be important for increasing heat shock gene transcription.

Purification and properties of the groES morphogenetic protein of Escherichia coli

The morphogenesis of lambda proheads is governed by the products of at least four bacteriophage-coded genes (B, C, E and Nu3) and two host-coded genes (groES (mopB) and groEL (mopA)). Earlier genetic experiments indicated that the phenotypes of some of the groES- mutations could be suppressed by mutations in the groEL gene, suggesting an interaction between the two groE proteins in vivo (Tilly, K., and Georgopoulos, C. P. (1982) J. Bacteriol. 149, 1082-1088). The Mr 15,000 groES protein was overproduced and purified to homogeneity by monitoring its presence after polyacrylamide gel electrophoresis. Both gel filtration on an AcA34 sizing column and glycerol gradient centrifugation indicate that the groES protein possesses an oligomeric structure of Mr 80,000. In agreement, electron microscopic pictures of the purified groES protein show that it possesses a symmetrical ring-like structure. The sequence of the first five amino acids and the overall composition of the purified protein match those predicted by the nucleotide sequence of the groES gene. The following results implicate a physical association between the groES and groEL proteins in vitro. The groES protein inhibits the weak ATPase activity of the groEL protein, with a maximal effect seen at a 1:1 molar ratio; the two proteins cosediment during glycerol gradient centrifugation in the presence of ATP and Mg2+; and the groES protein binds specifically to a groEL-affinity column. These results help explain why mutations in either of the groE genes exhibit similar phenotypes with respect to both lambda and bacterial growth.

Fine structure genetic analysis of a beta-globin promoter

A novel procedure for saturation mutagenesis of cloned DNA was used to obtain more than 100 single base substitutions within the promoter of the mouse beta-major globin gene. The effects of these promoter substitutions on transcription were determined by transfecting the cloned mutant genes into HeLa cells on plasmids containing an SV40 transcription enhancer, and measuring the levels of correctly initiated beta-globin transcripts after 2 days. Mutations in three regions of the promoter resulted in a significant decrease in the level of transcription: (i) the CACCC box, located between -87 and -95, (ii) the CCAAT box, located between -72 and -77, and (iii) the TATA box, located between -26 and -30 relative to the start site of transcription. In contrast, two different mutations in nucleotides immediately upstream from the CCAAT box resulted in a 3- to 3.5-fold increase in transcription. With two minor exceptions, single base substitutions in all other regions of the promoter had no effect on transcription. These results precisely delineate the cis-acting sequences required for accurate and efficient initiation of beta-globin transcription, and they establish a general approach for the fine structure genetic analysis of eukaryotic regulatory sequences.

The nucleotide sequence of the Escherichia coli K12 dnaJ+ gene. A gene that encodes a heat shock protein

The Escherichia coli dnaJ gene product is required for bacteriophage lambda DNA replication at all temperatures. It is also essential for bacterial viability in at least some conditions, since mutations in it result in temperature-sensitive bacterial growth. We have previously cloned the dnaJ gene and shown that its product migrates as a Mr 37,000 polypeptide under denaturing conditions. Here we present the primary DNA sequence of the dnaJ gene. It codes for a processed basic protein (63 basic and 51 acidic amino acids) composed of 375 amino acids totaling Mr 40,973. The predicted NH2-terminal amino acid sequence, overall amino acid composition, and isoelectric point agree well with those of the purified protein. We present evidence that the rate of expression of the dnaJ protein is increased by heat shock under the control of the htpR (rpoH) gene product.

The dnaK protein modulates the heat-shock response of Escherichia coli

E. coli bacteria respond to a sudden upward shift in temperature by transiently overproducing a small subset of their proteins, one of which is the product of the dnaK gene. Mutations in dnaK have been previously shown to affect both DNA and RNA synthesis in E. coli. Bacteria carrying the dnaK756 mutation fail to turn off the heat-shock response at 43 degrees C. Instead, they continue to synthesize the heat-shock proteins in large amounts and underproduce other proteins. Both reversion and P1 transduction analyses have shown that the failure to turn off the heat-shock response is the result of the dnaK756 mutation. In addition, bacteria that overproduce the dnaK protein at all temperatures undergo a drastically reduced heat-shock response at high temperature. We conclude that the dnaK protein is an inhibitor of the heat-shock response in E. coli.

The head genes of bacteriophage 21

Physical and genetic maps of the head genes of lambdoid phage 21 have been made and compared with the head gene map of lambda. Because 21 and lambda have partial sequence homology throughout the head genes it was expected that the head genes of 21 would be analogous to those of lambda. Eight head genes of 21 have been identified and it was found that each of the genes is analogous in position, structure, and/or function to a lambda head gene. Phage 21 genes analogous to the lambda D and FI genes were not identified by mutation. Complementation studies between phage 21 and lambda mutants indicate that only gpFII (the protein product of a gene is referred to as gp (gene product] is fully interchangeable, gpW and gpD are partially interchangeable, and the rest of the head morphogenetic proteins are phage specific. In analogy with phage lambda, it is found that the gpNu3 analog (gp6) of phage 21 is synthesized from the same reading frame as the gpC analog (gp5), resulting in a protein identical to the carboxy terminus of gp5.

Identification of the heat-inducible protein C15.4 as the groES gene product in Escherichia coli

The product of the Escherichia coli morphogenetic gene groES (mopB) was identified as the heat-inducible protein C15.4 by two-dimensional gel analysis of the products of wild-type and mutant alleles carried on the bacterial chromosome, on a hybrid plasmid, and on a transducing phage.

Evidence that the two Escherichia coli groE morphogenetic gene products interact in vivo

The Escherichia coli groEL and groES gene products are essential for both phage morphogenesis and bacterial growth. Although the gene products have been identified, their exact roles in these processes are not known. We have isolated mutations in the groEL gene that suppress defects in the groES gene. These intergenic suppressors were shown to map in the groEL gene by a variety of genetic and biochemical analyses. These results suggest that the two morphogenetic gene products interact in vivo and help to explain why mutations in either gene exhibit the same phenotype with respect to lambda head assembly and bacterial growth.

The B66.0 protein of Escherichia coli is the product of the dnaK+ gene

B66.0 is one of the most abundant proteins of Escherichia coli. Its relative rate of synthesis is highly regulated depending on temperature and the growth rate of the culture. We identified the B66.0 protein to be the dnaK+ structural gene product since dnaK756 mutant bacteria synthesized a B66.0 protein with a more acidic isoelectric point.

Identification of a second Escherichia coli groE gene whose product is necessary for bacteriophage morphogenesis

Previous work has uncovered the existence of an Escherichia coli locus, groE, that is essential for bacterial growth, lambda phage and T4 phage head morphogenesis, and T5 phage tail assembly. Our genetic and biochemical analyses of lambda groE+ transducing phages and their deletion and point mutant derivatives show that the groE locus consists of two closely linked genes. One groE gene, groEL, has been shown to encode the synthesis of a 65,000 Mr polypeptide, whereas the second, groES, codes for the synthesis of a 15,000 Mr polypeptide. About half of the groE- bacterial isolates fall into the groES complementation group. GroE mutations in either gene cause similar phenotypes, with respect to lambda phage head morphogenesis and bacterial growth at nonpermissive temperatures.