Genetic footprinting in bacteria.

In vivo genetic footprinting was developed in the yeast Saccharomyces cerevisiae to simultaneously assess the importance of thousands of genes for the fitness of the cell under any growth condition. We have developed in vivo genetic footprinting for Escherichia coli, a model bacterium and pathogen. We further demonstrate the utility of this technology for rapidly discovering genes that affect the fitness of E. coli under a variety of growth conditions. The definitive features of this system include a conditionally regulated Tn10 transposase with relaxed sequence specificity and a conditionally regulated replicon for the vector containing the transposase and mini-Tn10 transposon with an outwardly oriented promoter. This system results in a high frequency of randomly distributed transposon insertions, eliminating the need for the selection of a population containing transposon insertions, stringent suppression of transposon mutagenesis, and few polar effects. Successful footprints have been achieved for most genes longer than 400 bp, including genes located in operons. In addition, the ability of recombinant proteins to complement mutagenized hosts has been evaluated by genetic footprinting using a bacteriophage lambda transposon delivery system.

Genetic analysis of the Mycobacterium smegmatis rpsL promoter.

The DNA sequence of the promoter region of the Mycobacterium smegmatis rpsL gene, which encodes the S12 ribosomal protein, was determined. Primer extension analysis and S1 nuclease protection experiments identified the 5' end of the rpsL mRNA to be 199 bp upstream of the translation initiation codon. The rpsL promoter contained sequences upstream of this start point for transcription that were similar to the canonical hexamers found at the -10 and -35 regions of promoters recognized by Esigma70, the major form of RNA polymerase in Escherichia coli. To define the promoter of the rpsL gene, DNA fragments containing progressive deletions of the upstream region of the rpsL gene were inserted into a plasmid vector containing a promoterless xylE gene. These insertions revealed that the 200 bp of DNA sequence immediately upstream from the translation initiation codon was not essential for promoter function. In addition, 5' deletions removing all but 34 bp upstream of the transcription start point retained greater than 90% promoter activity, suggesting that the -35 hexamer was not essential for promoter activity. To determine which nucleotides were critical for promoter function, oligonucleotide-directed mutagenesis and mutagenic PCR amplification were used to produce point mutations in the region upstream of the start point of transcription. Single base substitutions in the -10 hexamer, but not in the -35 hexamer, severely reduced rpsL promoter activity in vivo. Within the -10 hexamer, nucleotide substitutions causing divergence from the E. Coli sigma70 consensus reduced promoter activity. The DNA sequence immediately upstream from the - 10 hexamer contained the TGn motif described as an extended -10 region in prokaryotic promoters. Mutations in this motif, in combination with a transition at either the -38 or -37 position within the -35 hexamer, severely reduced promoter activity, indicating that in the absence of a functional -35 region, the rpsL promoter is dependent on the TGn sequence upstream from the -10 hexamer. Comparison of the nucleotide sequence of the rpsL promoter region of M. smegmatis with the homologous sequences from Mycobacterium leprae, Mycobacterium bovis, and Mycobacterium tuberculosis showed the presence in these slowly growing mycobacterial species of conserved promoter elements a similar distance upstream of the translation initiation codon of the rpsL gene, but these other mycobacterial promoters did not contain the extended -10 motif.

Cloning and sequence analysis of the rpsL and rpsG genes of Mycobacterium smegmatis and characterization of mutations causing resistance to streptomycin.

The Mycobacterium smegmatis rpsL and rpsG genes, encoding the ribosomal proteins S12 and S7, were cloned, and their DNA sequence was determined. The third nucleotide of the S12 termination codon overlapped the first nucleotide of the S7 translation initiation codon. A collection of 28 spontaneous streptomycin-resistant mutants of M. smegmatis were isolated. All had single-base-pair substitutions in the rpsL gene which were changed to a streptomycin-sensitive phenotype by complementation with a low-copy-number plasmid carrying the wild-type M. smegmatis rpsL gene. A total of eight different mutations were found in two specific regions of the rpsL gene. Fifty-seven percent (16 of 28) altered the Lys codon at position 43. Forty-six percent of the mutations (13 of 28) were due to a transition changing an AAG Lys codon to an AGG Arg codon, with eight changes at codon 43 and five at codon 88.

Spo0A controls the sigma A-dependent activation of Bacillus subtilis sporulation-specific transcription unit spoIIE.

The spoIIE operon is a developmentally regulated transcription unit activated in the second hour of sporulation in Bacillus subtilis. Its promoter has an unusual structure, containing sequences which conform perfectly to the consensus for vegetative promoters recognized by sigma A-associated RNA polymerase (E sigma A), but with a spacing of 21 bp between the apparent -10 and -35 elements instead of the 17- or 18-bp spacing typical of promoters utilized by E sigma A. Mutations introduced into the apparent -10 element affected transcription in a manner consistent with its functioning as a polymerase recognition sequence. The deleterious effect of one -10 mutation was also suppressed in an allele-specific manner by a mutation in sigA known to suppress analogous -10 mutations in conventional vegetative promoters recognized by E sigma A. Similar suppression experiments failed to provide evidence for a direct interaction between E sigma A and the "-35-like" element, however, and DNase I protection experiments suggested instead that the Spo0A protein binds to a site overlapping this -35-like hexamer. Moreover, the effects of mutations within the -35-like hexamer on the binding of Spo0A in vitro paralleled their effects on transcription in vivo. We suggest that spoIIE belongs to a class of early-intermediate sporulation genes whose transcription by E sigma A is activated by the Spo0A protein.

Genetic evidence for interaction of sigma A with two promoters in Bacillus subtilis.

The specificity of promoter binding by RNA polymerase is governed by the sigma subunit. Recent studies, in which single-amino-acid substitutions in sigma factors have been found to suppress the effects of specific base pair substitutions in promoters, support the model that these sigma factors make sequence-specific contacts with nucleotides at the -10 and -35 regions of promoters. We found that single-amino-acid substitutions in the putative -35 region and -10 region recognition domains of sigma A specifically suppressed the effects of mutations in the -35 and -10 regions, respectively, of two promoters that are expressed in exponentially growing Bacillus subtilis. These mutations change the specificity of sigma A, the primary sigma factor in growing B. subtilis, and demonstrate that this sigma factor interacts with promoters in a manner similar to that of its homolog in Escherichia coli, sigma 70. These mutant derivatives of sigma A also provide a tool that may be useful for determining whether sigma A uses specific promoters in vivo.

Providing an integrated clinical data view in a hospital information system that manages multimedia data.

The VA's hospital information system, the Decentralized Hospital Computer Program (DHCP), is an integrated system based on a powerful set of software tools with shared data accessible from any of its application modules. It includes many functionally specific application subsystems such as laboratory, pharmacy, radiology, and dietetics. Physicians need applications that cross these application boundaries to provide useful and convenient patient data. One of these multi-specialty applications, the DHCP Imaging System, integrates multimedia data to provide clinicians with comprehensive patient-oriented information. User requirements for cross-disciplinary image access can be studied to define needs for similar text data access. Integration approaches must be evaluated both for their ability to deliver patient-oriented text data rapidly and their ability to integrate multimedia data objects. Several potential integration approaches are described as they relate to the DHCP Imaging System.

Genetic evidence that RNA polymerase associated with sigma A factor uses a sporulation-specific promoter in Bacillus subtilis.

The construction of allele-specific suppressor mutations has enabled us to demonstrate that a sporulation-specific transcription unit in Bacillus subtilis, the spoIIG operon, is transcribed by a form of RNA polymerase associated with sigma A, the principal sigma factor in vegetative cells. The spoIIG operon encodes sporulation-specific factor sigma E, and its transcription is directed from a promoter that is activated about 1 hr after the onset of endospore formation. This promoter contains sequences that are similar to those found at the -10 and -35 regions of promoters that are used by sigma A-associated RNA polymerase, but these sigma A-like recognition sequences are separated by 22 base pairs rather than the typical 17 or 18 base pairs. We have found that substitution of an arginyl residue for the glutamyl residue at position 196 of sigma A (Glu-196----Arg) suppresses the deleterious effect of a thymidine-to-cytidine base substitution at position -11 in the spoIIG promoter. This suppression was allele-specific, since it did not suppress the effects of base substitutions in other positions in the spoIIG promoter or the effects of a thymidine-to-guanosine change at -11. These results support a model in which a form of RNA polymerase containing sigma A is utilized in an unusual manner to activate the transcription of the spoIIG operon well after the onset of endospore formation.

Gene encoding sigma E is transcribed from a sigma A-like promoter in Bacillus subtilis.

Bacillus subtilis produces several RNA polymerase sigma factors. At least two of these factors are essential for endospore formation, sigma H, which is present in vegetative cells, and sigma E, which is produced exclusively after the start of endospore formation. The structural gene that encodes sigma E is part of the spoIIG operon, which is transcribed after the onset of sporulation. We have determined the starting point of transcription and the nucleotide sequence of the spoIIG promoter. This promoter contains sequences that are similar to those found at the -10 and -35 regions of promoters that are used by E sigma A, the primary form of RNA polymerase in vegetative cells. The unusual feature of this promoter is that these putative sigma A contact sites are separated by 22 base pairs, rather than the typical 17 or 18 base pairs. Single-base substitutions in the -10-like sequence reduced utilization of the spoIIG promoter in vivo. Furthermore, E sigma A, but not E sigma H and other secondary forms of RNA polymerase, accurately initiated transcription from the spoIIG promoter in an in vitro assay; therefore, we suggest that E sigma A transcribes the spoIIG operon in vivo. A base substitution in the -35-like sequence caused constitutive transcription from the promoter in vegetative cells; therefore, regulation of this sporulation-specific transcription may involve a novel mechanism.

The Bacillus subtilis spoIIG operon encodes both sigma E and a gene necessary for sigma E activation.

A sporulation-specific sigma factor of Bacillus subtilis (sigma E) is formed by a proteolytic activation of a precursor protein (P31). Synthesis of the precursor protein is shown to be abolished in B. subtilis mutants with plasmid insertions as far as 940 base pairs upstream of the P31 structural gene (sigE), and processing of P31 to sigma E is blocked by a deletion in this upstream region. These results substantiate the view that sigE is the distal member of a 2-gene operon and demonstrate that the upstream gene (spoIIGA) is necessary for sigma E formation.

Organization and regulation of an operon that encodes a sporulation-essential sigma factor in Bacillus subtilis.

Deletion of sigE, the structural gene for the sporulation-induced RNA polymerase sigma factor, sigma E, prevented endospore formation by Bacillus subtilis. The effects of integration of plasmids into the sigE region of the chromosome and the use of complementation analyses demonstrated that sigE is part of an operon that includes a promoter-proximal gene, spoIIGA, that is essential for sporulation. Gene fusions to the promoter of this operon, spoIIG, demonstrated that transcription from this promoter is induced at the beginning of sporulation and is dependent on several spoO genes.

Promoter specificity of a sporulation-induced form of RNA polymerase from Bacillus subtilis.

The program of gene expression that underlies endospore formation by Bacillus subtilis may be controlled in part by a sporulation-induced form of RNA polymerase, E sigma 29. The nucleotide sequences of four promoters, which are known to be recognized by E sigma 29, are highly conserved at two regions, 10 bp and 35 bp upstream from the start point of transcription. We have used oligonucleotide-directed mutagenesis to construct several base substitutions in the ctc promoter from B. subtilis to test the role of the highly conserved sequences in utilization of the promoter by E sigma 29. In vitro transcription analysis demonstrated that the conserved nucleotides at positions -15, -14 and -12 affect the utilization of the promoter by E sigma 29. These and previous results support a model in which E sigma 29 recognizes its cognate promoters by interacting with nucleotides near the -10 and -35 regions. We also examined the effects of these base substitutions on utilization of the promoter by two other forms of RNA polymerase from B. subtilis, E sigma 37 and E sigma 32.

Effect of cholestyramine on bile acid metabolism in normal man.

The effect of cholestyramine administration on the enterohepatic circulation of bile acids was studied in eight normal volunteers. In six subjects the metabolism of sodium taurocholate-(14)C was determined after its intravenous injection before and during the 6th wk of cholestyramine administration, 16 g/day. In two subjects, the metabolism of cholic acid-(14)C was observed before and during the 2nd wk of cholestyramine, 16 g/day. Bile acid sequestration resulted in a more rapid disappearance of the injected primary bile acid and its metabolic products. The composition of fasting bile acids was promptly altered by cholestyramine to predominantly glycine-conjugated trihydroxy bile acid. In four subjects, unconjugated bile acid-(14)C was administered during cholestyramine administration; the relative proportion of glycine-conjugated bile acid-(14)C before enterohepatic circulation was similar to the relative proportion of unlabeled glycine-conjugated bile acid present in duodenal contents after an overnight fast, indicating that a hepatic mechanism was responsible for the elevated ratios of glycine- to taurine-conjugated bile acid (G: T ratios) observed. The relative proportions of both dihydroxy bile acids, chenodeoxycholic and deoxycholic, were significantly reduced. Steatorrhea did not occur, and the total bile acid pool size determined after an overnight fast was unaltered by cholestyramine. These findings suggest that in normal man bile acid sequestered from the enterohepatic circulation by cholestyramine is replaced by an increase in hepatic synthesis primarily via the pathway leading to production of glycocholic acid.