Identification and characterization of mycobacterial proteins differentially expressed under standing and shaking culture conditions, including Rv2623 from a novel class of putative ATP-binding proteins.

The environmental signals that affect gene regulation in Mycobacterium tuberculosis remain largely unknown despite their importance to tuberculosis pathogenesis. Other work has shown that several promoters, including acr (also known as hspX) (alpha-crystallin homolog), are upregulated in shallow standing cultures compared with constantly shaking cultures. Each of these promoters is also induced to a similar extent within macrophages. The present study used two-dimensional gel electrophoresis and mass spectrometry to further characterize differences in mycobacterial protein expression during growth under standing and shaking culture conditions. Metabolic labeling of M. bovis BCG showed that at least 45 proteins were differentially expressed under standing and shaking culture conditions. Rv2623, CysA2-CysA3, Gap, and Acr were identified from each of four spots or gel bands that were specifically increased in bacteria from standing cultures. An additional standing-induced spot contained two comigrating proteins, GlcB and KatG. The greatest induction was observed with Rv2623, a 32-kDa protein of unknown function that was strongly expressed under standing conditions and absent in shaking cultures. Analysis using PROBE, a multiple sequence alignment and database mining tool, classified M. tuberculosis Rv2623 as a member of a novel class of ATP-binding proteins that may be involved in M. tuberculosis's response to environmental signals. These studies demonstrate the power of combined proteomic and computational approaches and demonstrate that subtle differences in bacterial culture conditions may have important implications for the study of gene expression in mycobacteria.

Identification and characterization of a developmentally regulated protein, EshA, required for sporogenic hyphal branches in Streptomyces griseus.

To identify sporulation-specific proteins that might serve as targets of developmental regulatory factors in Streptomyces, we examined total proteins of Streptomyces griseus by two-dimensional gel electrophoresis. Among five proteins that were present at high levels during sporulation but absent from vegetative cells, two of the proteins, P3 and P4, were absent from developmental mutants that undergo aberrant morphogenesis. The deduced amino acid sequence of the gene that encodes P3 (EshA) showed extensive similarity to proteins from mycobacteria and a cyanobacterium, Synechococcus, that are abundant during nutritional stress but whose functions are unknown. Uniquely among these proteins, EshA contains a cyclic nucleotide-binding domain, suggesting that the activity of EshA may be modulated by a cyclic nucleotide. The eshA gene was strongly expressed from a single transcription start site only during sporulation, and accumulation of the eshA transcript depended on a developmental gene, bldA. During submerged sporulation, a null mutant strain that produced no EshA could not extend sporogenic hyphae from new branch points but instead accelerated septation and spore maturation at the preexisting vegetative filaments. These results indicated that EshA is required for the growth of sporogenic hyphae and localization of septation and spore maturation but not for spore viability.

Functional classification of cNMP-binding proteins and nucleotide cyclases with implications for novel regulatory pathways in Mycobacterium tuberculosis.

We have analyzed the cyclic nucleotide (cNMP)-binding protein and nucleotide cyclase superfamilies using Bayesian computational methods of protein family identification and classification. In addition to the known cNMP-binding proteins (cNMP-dependent kinases, cNMP-gated channels, cAMP-guanine nucleotide exchange factors, and bacterial cAMP-dependent transcription factors), new functional groups of cNMP-binding proteins were identified, including putative ABC-transporter subunits, translocases, and esterases. Classification of the nucleotide cyclases revealed subtle differences in sequence conservation of the active site that distinguish the five classes of cyclases: the multicellular eukaryotic adenylyl cyclases, the eukaryotic receptor-type guanylyl cyclases, the eukaryotic soluble guanylyl cyclases, the unicellular eukaryotic and prokaryotic adenylyl cyclases, and the putative prokaryotic guanylyl cyclases. Phylogenetic distribution of the cNMP-binding proteins and cyclases was analyzed, with particular attention to the 22 complete archaeal and eubacterial genome sequences. Mycobacterium tuberculosis H37Rv and Synechocystis PCC6803 were each found to encode several more putative cNMP-binding proteins than other prokaryotes; many of these proteins are of unknown function. M. tuberculosis also encodes several more putative nucleotide cyclases than other prokaryotic species.

Bayesian protein family classifier.

A Bayesian procedure for the simultaneous alignment and classification of sequences into subclasses is described. This Gibbs sampling algorithm iterates between an alignment step and a classification step. It employs Bayesian inference for the identification of the number of conserved columns, the number of motifs in each class, their size, and the size of the classes. Using Bayesian prediction, inter-class differences in all these variables are brought to bare on the classification. Application to a superfamily of cyclic nucleotide-binding proteins identifies both similarities and differences in the sequence characteristics of the five subclasses identified by the procedure: 1) cNMP-dependent kinases, 2) prokaryotic cAMP-dependent regulatory proteins, CRP-type, 3) prokaryotic regulatory proteins, FNR-type, 4) cAMP gated ion channel proteins of animals, and 5) cAMP gated ion channels of plants.

Soluble expression and complex formation of proteins required for HCMV DNA replication using the SFV expression system.

Several of the viral proteins required for human cytomegalovirus (HCMV) DNA replication have been difficult to study due to their low abundance in infected cells and low solubility in bacterial or insect-cell expression systems. Therefore we used the Semliki Forest virus expression system to express these proteins in mammalian cells. All of the recombinant proteins were soluble, on the basis of ultracentrifugation properties and their ability to be immunoprecipitated from solution with specific antibodies. Pulse-chase analysis of the 86-kDa major immediate-early protein (IE86) revealed two expressed forms-a precursor and a product-indicating that this recombinant protein, like the native HCMV protein, is posttranslationally processed. The recombinant proteins (polymerase core and accessory as well as the IE86 and pUL84) formed stable complexes similar to those known to form in HCMV-infected cells. The recombinant DNA polymerase holoenzyme also exhibited enzyme activity that was phosphonoformic acid sensitive, as is the infected-cell DNA polymerase activity. This expression system offers many advantages for the expression and study of the HCMV replication proteins, including the expression of soluble, active proteins that are able to interact to form complexes. Additionally, the relative ease with which SFV recombinants can be made lends itself to the construction and evaluation of mutants.

Identification of bldA mutants of Streptomyces griseus.

The bldA gene (encoding tRNA(UUA)Leu) from Streptomyces griseus (Sg) was cloned by hybridization with bldA from Streptomyces coelicolor (Sc). Introduction of Sg bldA into Sc bldA mutants restored sporulation and actinorhodin production. Sporulation of a subset of Sg bald mutants, which produce no aerial mycelium or spores, was restored in the presence of bldA from Sc or Sg. The nucleotide sequences of the bldA alleles from two such bald mutants revealed point mutations in the anticodon stem and the T psi C stem.

Analysis of a gene that suppresses the morphological defect of bald mutants of Streptomyces griseus.

When present in multiple copies, orf1590 restored sporulation to class IIIA bald mutants of Streptomyces griseus, which form sporulation septa and thick spore walls prematurely. The orf1590 alleles from class IIIA bald mutants restored sporulation upon introduction at a high copy number into those same mutants, and the nucleotide sequence of one of these alleles was identical to that of the wild-type strain. We conclude that overexpression of orf1590 suppresses the defect in class IIIA bald mutants. Previous nucleotide sequence and transcript analyses suggested that orf1590 could encode two related proteins, P56 and P49.5, from nested coding sequences. A mutation that prevented the synthesis of P56 without altering the coding sequence for P49.5 eliminated the function of orf1590, as did amino acid substitutions in the putative helix-turn-helix domain located at the N terminus of P56 and absent from P49.5. To determine the coding capacity of orf1590, we analyzed translational fusions between orf1590 and the neo gene from Tn5. Measurement of the expression of fusions to the wild-type and mutant alleles of orf1590 indicated that P56 was the sole product of orf1590 during vegetative growth. Attempts to generate a nonfunctional frameshift mutation in orf1590 were unsuccessful in the absence of a second-site bald mutation, suggesting that orf1590 may be required during vegetative growth by preventing early sporulation. Our results are consistent with the hypothesis that P56 at a high level delays the premature synthesis of sporulation septa and spore walls in class IIIA mutants.

The human cytomegalovirus genes and proteins required for DNA synthesis.

Although the overall picture of HCMV DNA synthesis appears typical of the herpesviruses, some novel features are emerging. Six herpesvirus-group-common genes encode proteins that likely constitute the replication fork machinery, including a two-subunit DNA polymerase, a helicas-primase complex and a single-stranded DNA-binding protein. No homolog of the herpes simplex virus origin-binding helicase is evident, but at least one additional HCMV protein of unknown function, pUL84, appears to be required for initiation. Replication initiates within or near the large and structurally complex lytic-phase replicator, ori-Lyt, near the center of UL. Recent findings suggest that ori-Lyt-mediated initiation of DNA synthesis occurs through a mechanism distinct from that employed by herpes simplex virus.

Molecular analysis of sporulation in Streptomyces griseus.

Previous evidence suggested that orf1590 from Streptomyces griseus has the potential to encode two polypeptide products from temporally regulated nested open frames (orfs) and that the longer polypeptide may be a DNA-binding protein. We have developed a hypothetical model of the role of orf1590 in sporulation of S. griseus and have begun to test this model by determining the nucleotide sequence of the orf1590 counterpart from Streptomyces coelicolor. The conservation of the helix-turn-helix domain and the two potential translation start codons is consistent with our model. Continued analysis of bald mutants of S. griseus has indicated that several prematurely synthesize sporulation septa and spore walls. One of these nonsporulating strains appears to be a bldA mutant of S. griseus. Complementation analysis suggests that at least three genetic loci are involved in the correct timing of deposition of sporulation septa and wall thickening.

Identification, expression, and deduced primary structure of transketolase and other enzymes encoded within the form II CO2 fixation operon of Rhodobacter sphaeroides.

Previous studies had indicated that the form II or B cluster of CO2 fixation structural genes is part of a large operon in Rhodobacter sphaeroides (Gibson, J. L., Chen, J.-H., Tower, P. A., and Tabita, F. R. (1990) Biochemistry 29, 8085-8093). In this investigation, we have sequenced the DNA between the prkB and rbpL genes and provide evidence for three distinct open reading frames which encode additional structural genes of the Calvin reductive pentose phosphate pathway; these genes encode the enzymes transketolase, glyceraldehyde phosphate dehydrogenase, and aldolase. Noteworthy is transketolase, which may be expressed to high levels in Escherichia coli. This study thus represents the initial description of the primary structure of bacterial transketolase, a key enzyme of the reductive and the oxidative pentose phosphate pathways. Each of the genes are separated by short stretches of intergenic sequence, consistent with earlier evidence which suggested that these genes are cotranscribed and part of a large operon controlled by sequences upstream from fbpB.