Gene organization and primary structure of a ribosomal RNA operon from Escherichia coli

Phylogenetic analysis of a natural marine bacterioplankton population by rRNA gene cloning and sequencing

The identification of the prokaryotic species which constitute marine bacterioplankton communities has been a long-standing problem in marine microbiology. To address this question, we used the polymerase chain reaction to construct and analyze a library of 51 small-subunit (16S) rRNA genes cloned from Sargasso Sea bacterioplankton genomic DNA. Oligonucleotides complementary to conserved regions in the 16S rDNAs of eubacteria were used to direct the synthesis of polymerase chain reaction products, which were then cloned by blunt-end ligation into the phagemid vector pBluescript. Restriction fragment length polymorphisms and hybridizations to oligonucleotide probes for the SAR11 and marine Synechococcus phylogenetic groups indicated the presence of at least seven classes of genes. The sequences of five unique rDNAs were determined completely. In addition to 16S rRNA genes from the marine Synechococcus cluster and the previously identified but uncultivated microbial group, the SAR11 cluster [S. J. Giovannoni, T. B. Britschgi, C. L. Moyer, and K. G. Field. Nature (London) 345:60-63], two new gene classes were observed. Phylogenetic comparisons indicated that these belonged to unknown species of alpha- and gamma-proteobacteria. The data confirm the earlier conclusion that a majority of planktonic bacteria are new species previously unrecognized by bacteriologists.

Analysis of sequence elements important for the synthesis and control of ribosomal RNA in E coli

The regulation of the synthesis of ribosomal RNA is a key problem for the understanding of bacterial growth. Many different regulatory mechanisms involving cis and trans acting components participate in a concerted way to achieve the very efficient, flexible and coordinated production of this class of molecules. We have studied three different sequence regions within a ribosomal RNA transcription unit which are believed to control different stages of ribosomal RNA expression. In the first part of the study the function of AT-rich sequences upstream of the -35 hexamer of rRNA promoter P1 in the activation of rRNA transcription was analyzed. We confirm that a sequence dependent bend upstream of P1 is responsible for the high promoter activity. Experiments employing linker scanning mutations demonstrated that the distance as well as the angular orientation of the bent DNA is crucial for the degree of activation. In addition, the effect of the trans activating protein Fis on the transcription initiation of promoter P1 was investigated. We can show, using the abortive initiation assay, that the predominant effect of Fis is due to an increase in the affinity of RNA polymerase for the promoter (binding constant KB) while the isomerisation rate (kf) from a closed to an open RNA polymerase promoter complex is not altered significantly. We also describe the characterization of sequence determinants important for stringent regulation and growth rate control. Evidence is provided that the discriminator motif GCGC is a necessary but not sufficient element for both types of control. Furthermore we show that not simply a particular DNA primary structure but the higher order conformation of the complete promoter region is recognized and triggers the two regulatory mechanisms, both of which are apparently mediated by the effector molecule guanosine tetraphosphate (ppGpp). Finally, we have carried out a systematic mutational analysis of the rrnB leader region preceding the structural gene for 16S RNA. We could demonstrate that highly conserved sequence elements within the rrnB leader, which were believed to be involved in transcription antitermination have post-transcriptional functions. We present evidence that these sequence elements direct the biogenesis of active ribosomal particles.

Structure and organization of ribosomal DNA

Three trends are seen in the organization of ribosomal DNA genes during evolution: 1) gradual separation and separability of the regulation of transcription of 5S and larger subunit rRNAs; 2) retention of a transcription unit containing both large and small rRNAs; and 3) clustering of genes for both 5S and 18S-28S rDNAs, with the possible association of other 'non-rDNA' in the clusters of 18S-28S rDNA genes by the time mammals evolve.

Transcription of genes involved in the earliest steps of actinorhodin biosynthesis in Streptomyces coelicolor

A 170bp long BamHI-Sau3A DNA fragment from the actIII-actI intergenic region of the actinorhodin (Act) biosynthetic gene cluster of Streptomyces coelicolor A3(2) contains two promoters directing transcription in a divergent manner. One of them, the actIII promoter, is responsible for the transcription of the actIII gene and the other controls transcription of the adjacent actI region in the opposite direction. Weak activity of the actIII promoter can be detected in Streptomyces lividans and Bacillus subtilis in the absence but not in the presence of glucose. Neither promoter seems to function in Escherichia coli.

Isolation and characterization of chromosomal promoters of Streptococcus salivarius subsp. thermophilus

A promoter probe vector, pTG244, was constructed with the aim of isolating transcription initiation signals from Streptococcus thermophilus (Streptococcus salivarius subsp. thermophilus). pTG244 is based on the Escherichia coli-streptococcus shuttle vector pTG222, into which the promoterless chloramphenicol acetyltransferase gene of Bacillus pumilus (cat-86) was cloned. Random Sau3A fragments from the S. thermophilus A054 chromosomal DNA were cloned upstream of the cat-86 gene by using E. coli as the host. The pool of recombinant plasmids were introduced into S. thermophilus and Lactococcus lactis subsp. lactis in order to search for promoter activity in these hosts. For S. thermophilus, it was necessary to first select erythromycin-resistant transformants and then to screen for chloramphenicol resistance among these. Direct selection of chloramphenicol-resistant clones was, however, possible in L. lactis subsp. lactis. Six fragments exhibiting promoter activity were characterized in S. thermophilus by measuring the levels of cat-86 transcription and/or chloramphenicol acetyltransferase specific activity. Three of the promoter-carrying fragments were sequenced. The 5' ends of their corresponding mRNAs were determined by S1 mapping and shown to correspond to a purine residue in all cases. Upstream from these potential transcription start points, sequences homologous to the E. coli sigma 70 and the Bacillus subtilis vegetative sigma 43 (or sigma A) consensus promoters were identified.

Escherichia coli kgtP encodes an alpha-ketoglutarate transporter

The witA gene located between pss and rrnG on the Escherichia coli chromosome encodes a 432-amino acid protein. It is homologous to a human hepatoma glucose transporter and to E. coli membrane proteins that transport citrate (CitA), arabinose (AraE), and xylose (XylE), and, like these carrier proteins, WitA also contains 12 highly hydrophobic putative membrane-spanning regions. Gene disruption mutants constructed in two E. coli strains grew slowly or not at all, depending on genetic background, in M9 minimal medium containing alpha-ketoglutarate. Growth on alpha-ketoglutarate and uptake of alpha-[14C]ketoglutarate were restored by transformation with plasmids containing witA. These complementation studies indicate that WitA is an alpha-ketoglutarate transporter and should be renamed kgtP(alpha-ketoglutarate permease).

Transcriptional termination sequence at the end of the Escherichia coli ribosomal RNA G operon: complex terminators and antitermination

We have examined the termination region sequence of the rrnG operon and have observed its properties in vivo using a fusion plasmid test system. Transcription of rrnG terminator fragments was also studied in vitro. We found that termination of rrnG transcription is a complex process controlled by a tandem Rho-independent and Rho-dependent terminator arrangement which we designate rrnG-tt'. Together, these two elements were 98% efficient at terminating transcription initiated at the rrnG-P2 promoter. When the two elements were separated, however, we found that the Rho-independent structure was only 59% efficient while the Rho-dependent fragment alone could account for total transcriptional termination of the tandem arrangement. The rrnG termination region was resistant to rrn antitermination and, therefore, possesses some means of stopping antiterminated transcription. The distal rrnG sequence contains several additional noteworthy features; the rrnGt' fragment contains a REP (repetitive extragenic palindromic) sequence and homology with a small unidentified reading frame following rrnE. This sequence is followed by witA, which is homologous to a citrate transport gene, citB. Finally, our sequence, obtained from plasmid pLC23-30, contains a Tn1000 insertion that is absent from the E. coli chromosome. This insertion lies 975 bp beyond the 5S gene and is not involved in the termination events examined in this study.

A vector for analysis of promoters in the cyanobacterium Anabaena sp. strain PCC 7120

A plasmid vector containing a multiple-cloning site followed by a promoterless chloramphenicol acetyltransferase (cat) gene, protected by transcription terminators and mobilizable by conjugation from Escherichia coli into Anabaena sp. strain PCC 7120, was constructed. The utility of the vector was shown by deletion analysis of the promoter region of the Anabaena psbB gene.

Phylogeny of the phototrophic rhizobium strain BTAi1 by polymerase chain reaction-based sequencing of a 16S rRNA gene segment

A 260-bp segment of the DNA that encodes 16S rRNA, corresponding to positions 44 to 337 in the Escherichia coli sequence, was amplified by the polymerase chain reaction and sequenced from each of 13 bacteria (rhizobia and purple phototrophs) in the alpha subdivision of the class Proteobacteria. The phylogenetic tree calculated from differences in the sequenced segment conforms well to our expectations based on other previously published data. The sequence from BTAi1 (a recently described phototrophic symbiont of the legume Aeschynomene) and that from the free-living phototroph Rhodopseudomonas palustris both fall within the range of variation found among strains of the soybean symbiont Bradyrhizobium japonicum. This suggests that it would be appropriate to include all of these organisms in a single genus.

Molecular cloning and nucleotide sequencing of the Arthrobacter dextranase gene and its expression in Escherichia coli and Streptococcus sanguis

A bacterial strain, which assimilated dextran and water-insoluble glucan produced by Streptococcus mutans, was isolated from soil. The bacterium produced and secreted potent dextranase activity, which was identified as Arthrobacter sp. and named CB-8. The dextranase was purified and some enzymatic properties were characterized. The enzyme efficiently decomposed the water-insoluble glucan as well as dextran. A gene library from the bacteria was constructed with Escherichia coli, using plasmid pUC19, and clones producing dextranase activity were selected. Based on the result of nucleotide sequencing analysis, it was deduced that the dextranase was synthesized in CB-8 cells as a polypeptide precursor consisting of 640 amino acid residues, including 49 N-terminal amino acid residues which could be regarded as a signal peptide. In the E. coli transformant, the dextranase activity was detected mostly in the periplasmic space. The gene for the dextranase was introduced into Streptococcus sanguis, using an E. coli-S. sanguis shuttle vector that contained the promoter sequence of a gene for glucosyltransferase derived from a strain of S. mutans. The active dextranase was also expressed and accumulated in S. sanguis cells.

Cloning and characterization of the Mycobacterium leprae putative ribosomal RNA promoter in Escherichia coli

The putative promoter region of the 16S ribosomal RNA-encoding gene (rRNA) of Mycobacterium leprae was cloned and characterized in Escherichia coli. A 932-bp HaeIII restriction fragment, containing the 5' end of the 16S rRNA gene and flanking upstream region, was cloned in front of a promoterless reporter gene in the shuttle vector, pMH109, to generate the plasmid, pYA1101. This clone exhibits promoter activity both in Gram-(E. coli) and Gram+ (Bacillus subtilis) bacteria. Sequence analysis and primer extension experiments with mRNA derived from the M. leprae clone were used to determine the structure and the location of the promoter, as well as the transcription start point in E. coli. The promoter region contains sequences that resemble the -35 and -10 consensus sequences found in many bacteria. A region located 34 bp distal to the promoter is a putative rRNA processing signal, based on sequence homology with processing signals involved in the maturation of the rRNA precursor in B. subtilis and several Mycoplasma species.

The development of specific rRNA-derived oligonucleotide probes for Haemophilus ducreyi, the causative agent of chancroid

Part of a ribosomal ribonucleic acid (rRNA) cistron of Haemophilus ducreyi was enzymically amplified using conserved primers within the rRNA molecules, cloned in a plasmid vector, and sequenced. From the nucleotide sequence, eight oligonucleotides complementary to different regions in the 16S and 23S rRNA molecules were selected, chemically synthesized, and used as hybridization probes. Hybridization experiments with at least 41 H. ducreyi strains and 13 or 14 non-H. ducreyi strains revealed that all eight oligonucleotide probes were highly reliable and completely specific for H. ducreyi strains. Comparisons of 16S rRNA sequences confirm that H. ducreyi is a member of the Pasteurellaceae though not closely related to other species in this family.

Properties of human testis-specific lactate dehydrogenase expressed from Escherichia coli

The cDNA encoding the C4 isoenzyme of lactate dehydrogenase (LDH-C4) was engineered for expression in Escherichia coli. The Ldh-c open reading frame was constructed as a cassette for production of the native protein. The modified Ldh-c cDNA was subcloned into the prokaryotic expression vector pKK223-3. Transformed E. coli cells were grown to mid-exponential phase, and induced with isopropyl beta-D-thiogalactopyranoside for positive regulation of the tac promoter. Induced cells expressed the 35 kDa subunit, which spontaneously formed the enzymically active 140 kDa tetramer. Human LDH-C4 was purified over 200-fold from litre cultures of cells by AMP and oxamate affinity chromatography to a specific activity of 106 units/mg. The enzyme was inhibited by pyruvate concentrations above 0.3 mM, had a Km for pyruvate of 0.03 mM, a turnover number (nmol of NADH oxidized/mol of LDH-C4 per min at 25 degrees C) of 14,000 and was heat-stable.

Genetic structure of a soil population of nonsymbiotic Rhizobium leguminosarum

The genetic structure of a population of nonsymbiotic Rhizobium leguminosarum strains was determined by the electrophoretic mobilities of eight metabolic enzymes. Nonsymbiotic strains were isolated from the rhizosphere of bean plants and characterized by growth on differential media and at different temperatures, intrinsic antibiotic resistance, the lack of homology to a nifH probe, and their inability to form nodules on bean roots. All the isolates clustered with R. leguminosarum bv. phaseoli reference strains and did not encompass any other Rhizobium taxa. Their rRNA operon restriction fragment length polymorphisms and the nucleotide sequence of a fragment of the 16S rRNA gene were also found to be identical to those of R. leguminosarum bv. phaseoli reference strains. When complemented with an R. leguminosarum bv. phaseoli symbiotic plasmid (p42d), the nonsymbiotic isolates were able to fix nitrogen in symbiosis with bean roots at levels similar to those of the parental strain. The symbiotic isolates were found at a relative frequency of 1 in 40 nonsymbiotic R. leguminosarum strains.

Expression of a ciliate gene in Escherichia coli using a suppressor tRNA to read the UAA and UAG glutamine codons

Most ciliates use a particular genetic code where the standard stop codons UAA and UAG encode glutamine. Ciliate genes cannot therefore be expressed in heterologous systems such as Escherichia coli. To overcome this problem, we worked out a system of inducible suppression to permit efficient readthrough of UAAs and UAGs: a strong UAA tRNA suppressor that inserts glutamic acid was cloned downstream from a tac promoter whose efficiency was reduced by a transcription terminator. This system proved to be operational (1) to suppress UAG mutations by wobble pairing in an E. coli lacI-lacZ gene fusion and (2) to read through at least eight UAA glutamine codons in a Paramecium alpha-tubulin gene, as detected by Western blotting and colony hybridization. This work opens the way for cloning Ciliate genes from expression libraries and for expressing particular sequences without extended in vitro mutagenesis. A similar approach can be envisaged for expression of genes from Mycoplasma, mitochondria or other genomes that use non-standard genetic codes.

Identification and structural analysis of a ribosomal RNA gene promoter from Thiobacillus ferrooxidans

The 5'-terminus of a rRNA operon (rrnT2) from Thiobacillus ferrooxidans was characterized. The rRNA promoters from this microorganism were identified by means of a functional assay in Escherichia coli. DNA sequencing of the promoter region, upstream the 16 S rRNA gene, showed the presence of a consensus sequence for bacterial ribosomal promoters. Other features such as a 'discriminator' sequence, antiterminator elements and an upstream hexanucleotide common to several rRNA operons were also found. Two other putative transcription promoters were also identified.

A family of expression vectors based on the rrnBP2 promoter of Escherichia coli

We describe here the construction of a family of expression vectors, based on the P2 promoter of the Escherichia coli rrnB gene by removing regulatory sequences downstream of the Pribnow-box and replacing them with the lac operator. These vectors allow cloning of foreign genes in such a way that their products are synthesized either in the form of fusion proteins of different length, or without fusion partners, with or without the original translational initiation signals. One of the vectors contains a synthetic oligothreonine-coding sequence that helps to stabilize the product of the cloned gene. These vectors allow high-level regulated expression of foreign genes, even if their products are relatively short peptides.

Functional importance of the Escherichia coli ribosomal RNA leader box A sequence for post-transcriptional events

To shed more light on the controversial findings concerning the functional participation of the highly conserved nut-like leader box A sequence element in ribosomal RNA transcription antitermination we have carried out a mutational study. We have substituted the box A and combined this mutation with several deletions comprising the rRNA leader elements box B, box C and the tL region. The mutations are located within the genuine rrnB operon cloned on multicopy plasmids. We determined the effects of the mutations on cell growth, rRNA accumulation and ribosomal subunit stoichiometry. Cells transformed with the mutated plasmids were affected in their growth rate, and showed a surprising deficiency of the promoter-proximal 16S compared to the 23S RNA, indicative of a post-transcriptional degradation event. Accordingly, we could demonstrate a reduced amount of free 30S relative to 50S ribosomal subunits in exponentially growing cells. Similar stoichiometric aberrations in the ribosome pool were detected in conditionally Nus factor-defective strains. The results show that the leader box A sequence within rRNA operons has important post-transcriptional functions for 16S RNA stability and ribosomal subunit stoichiometry. A model is proposed, describing the biogenesis and quality control of ribosomes based on rRNA leader and Nus-factor interactions. It is compatible with the previously observed effects of box A in antitermination.

A single mutation in 16S rRNA that affects mRNA binding and translation-termination

A single base change in 16S rRNA (C726 to G) has previously been shown to have a dramatic effect on protein synthesis in E. coli (1). This paper more specifically details the effects of the mutation on mRNA binding and translation-termination. The in vitro technique of toeprinting (2) was used to demonstrate that 30S subunits containing the mutation 726G had an altered binding affinity for mRNA by comparison to the wild type. In addition, expression of the mutant ribosomes in vivo resulted in exclusive suppression of the UGA nonsense codon. This effect was supported by in vitro studies that showed the mutant ribosomes to have an altered binding affinity for Release Factor-2.

An improved beta-galactosidase alpha-complementation system for molecular cloning in Bacillus subtilis

The recently described beta-galactosidase alpha-complementation system for molecular cloning in Bacillus subtilis [Haima et al., Gene 86 (1990) 63-69]was optimized in several ways. First, the efficiency of translation of the lac Z delta M15 gene was improved. Second, the plasmid-borne lacZ delta M15 gene was segregationally stabilized by integration into the B. subtilis chromosome. Third, a new lacZ alpha complementing cloning vector was constructed, containing more unique target sites. It was shown that large heterologous DNA fragments (up to at least 29 kb) could be cloned with lacZ alpha-complementing vectors carrying the replication functions of the cryptic B. subtilis plasmid pTA1060, and that these inserts were structurally stably maintained for at least 100 generations of growth.

Hyperexpression of a Bacillus thuringiensis delta-endotoxin-encoding gene in Escherichia coli: properties of the product

Conditions for hyperexpression, in Escherichia coli, of the Bacillus thuringiensis var, kurstaki gene, cryIA9(c)73, encoding an insecticidal crystal protein, CryIA(c)73, were investigated by varying the promoter type, host cell, plasmid copy number, the second codon and number of terminators. The cryIA(c)73 gene was cloned into three E. coli expression vectors, pKK223-3 (Ptac promoter), pET-3a (P phi 10 promoter), and pUC19 (Ptac promoter). The level of cryIA(c)73 expression was measured by ELISA and compared to total cellular protein over growth periods of 24 and 48 h. Maximum expression levels of 284 microgram CryIA(C)73/ml (48% of cellular protein) were obtained in shake flasks with the Ptac promoter in E. coli JM103. Optimal conditions were found to be low-copy-number plasmid (pBR322 ori), 48 h of growth, in lon+ cells. A change of the gene's second codon to AAA can improve expression by two to three fold but is undetectable in the presence of a strong E. coli promoter. The cryIA(c)73 gene product, in E. coli, formed crystals with the same lattice structure as the native crystals formed in B. thuringiensis (as visualized by electron microscopy). Bioassay results (insect toxicity and specificity) of the crystal produced in E. coli were similar to that produced in B. thuringiensis.

Extraction of ribosomal RNA from soil for detection of Frankia with oligonucleotide probes

Sequences of 16S rRNA of the nitrogen-fixing Frankia strain Ag45/Mut15 and the ineffective Frankia strain AgB1.9 were used to design a genus-specific oligonucleotide probe. Hybridization experiments of this Frankia probe and a second probe, specific for Nif+-Frankia strains only, were used to detect Frankia specific target sequences in RNA isolations from soil. A method is described for direct isolation of RNA from a loamy soil and a peat. Yields of about 10 ng RNA/g wet soil are obtained without detectable contamination with humic acids. Isolation of RNA after initial extraction of bacteria from soil resulted in significantly lower RNA yields, compared to the direct isolation procedure. Hybridization with both probes against rRNA isolations from Frankia-containing soil could detect target sequences within RNA isolations from 1 g wet soil with an estimated detection limit of 10(4) cells.

A general method to generate DNA probes for microorganisms

We present a method that permits the rapid generation of DNA probes for eubacteria. In the procedure the variable regions for the 16s rRNA genes are amplified using polymerase chain reaction (PCR) technology and primers based on the conserved regions of these genes. Following sequencing of the variable regions, a choice is possible for a probe specific for that organism. No knowledge of the molecular biology of the microorganism is required prior to the application of this approach. The generality of the method is shown using Salmonella typhimurium, Staphylococcus aureus, Clostridium perfringens, Klebsiella pneumoniae, Pseudomonas fluorescens, Aeromonas salmonicida and Mycobacterium bovis. A. salmonicida was examined in detail and a DNA probe was prepared that distinguishes it from other Aeromonas species.

Single base alterations upstream of the E. coli 16S rRNA coding region result in temperature-sensitive 16S rRNA expression

We have isolated three new temperature-sensitive mutants of 16S rRNA, using the U1192 spectinomycin resistance as a selectable marker. These differ from our previously characterized ts mutants in that they map in the upstream leader region of the rRNA precursor (at positions -13, -30 and -59). The relative distribution of plasmid and chromosome-derived 16S rRNA is similar between 30S subunits, 70S ribosomes and polysomes at the permissive and restrictive temperatures. Processing of the 5' end of the RNA does not appear to be affected by the mutations. Second-site suppressors were found, and all of these except one (which is within 16S rRNA) were also due to point mutations in the upstream leader.

The influence of oligonucleotide-effector on the selectivity of sequence specific modification of 16 S rRNA

The influence of duplex stabilizing oligonucleotide-effector (oligonucleotide, carrying N-(2-hydroxyethyl)phenazinium residues on both ends), on selectivity of site-directed modification of E. coli 16 S rRNA (1542 nucleotides in length) under the conditions of its secondary structure stability was studied. The constant of cooperative binding of the reagent and the oligonucleotide-effector with 16 S rRNA was determined. The accuracy of modification was shown to double in the presence of 50 microM effector at 5 microM concentration of the reagent.

Exchange of spacer regions between rRNA operons in Escherichia coli

The Escherichia coli rRNA operons each have one of two types of spacer separating the 16S and 23S coding regions. The spacers of four operons encode tRNA(Glu2) and the other three encode both tRNA(Ile) and tRNA(Ala1B). We have prepared a series of mutants in which the spacer region of a particular rrn operon has been replaced by the opposite type. Included among these were a mutant retaining only a single copy of the tRNA(Glu2) spacer (at rrnG) and another retaining only a single copy of the tRNA(Ile)-tRNA(Ala1B) spacer (at rrnA). While both mutants grew more slowly than controls, the mutant deficient in tRNA(Glu2) spacers was more severely affected. At a frequency of 6 X 10(-5), these mutants phenotypically reverted to faster growing types by increasing the copy number of the deficient spacer. In most of these phenotypic revertants, the deficient spacer type appeared in a rrn operon which previously contained the surplus type, bringing the ratio of spacer types closer to normal. In a few cases, these spacer changes were accompanied by an inversion of the chromosomal material between the donor and recipient rrn operons. Two examples of inversion of one-half of the E. coli chromosome between rrnG and rrnH were observed. The correlation of spacer change with inversion indicated that, in these particular cases, the change was due to an intrachromatid gene conversion event accompanied by a reciprocal crossover rather than reciprocal exchange between sister chromatids.

The tL structure within the leader region of Escherichia coli ribosomal RNA operons has post-transcriptional functions

We have investigated a series of mutations within a plasmid encoded E. coli ribosomal RNA leader region. The mutations are localized within a structure known as tL, which has been shown to mediate RNA polymerase pausing in vitro, and which is assumed to have a control function in rRNA transcription antitermination. The effects of the mutated plasmids were analyzed by in vivo and in vitro experiments. Some of the base change mutations led to severely reduced cell growth. As opposed to previous results obtained with mutants where the tL structure has been deleted in part or totally, the tL base change mutations did not result in polar transcription in vivo, rather they revealed a general reduction in the amount of the promoter proximal 16S versus the distal 23S RNA. The deficiency of the 16S RNA, which was most pronounced for some of the slowly growing transformants, can only be explained by a post-transcriptional degradation. In addition, many mutants showed a defective processing after the initial RNase III cut. In line with these results a quantitative analysis of the ratio of ribosomal subunits and 70S tight couple ribosomes showed a reduced capacity to form stable 70S particles for the slowly growing mutants. Together, these findings indicate an important function of the tL structure in post-transcriptional events like processing of rRNA precursors and correct assembly of 30S subunits.

Control of gene expression in the temperate coliphage 186. VIII. Control of lysis and lysogeny by a transcriptional switch involving face-to-face promoters

The lysogenic and early lytic operons of the temperate coliphage 186 are transcribed divergently. Primer extension mapping of the 5' ends of these in vivo transcripts showed that the rightward lytic promoter, pR, and the leftward lysogenic promoter, pL, are arranged face-to-face, with their transcripts overlapping by 60 bases. We examined the control of transcription from pR and pL using galK as a reporter gene. The product of the lysogenic cI gene strongly repressed pR transcription while allowing pL transcription. The product of the lytic apl gene (formerly CP75) strongly repressed pL transcription while allowing pR transcription. Thus, the cI-pR-pL-apl region functioned as a transcriptional switch, determining whether transcription was lytic or lysogenic. Also, the cI gene product was able to stimulate pL, possibly by alleviating an inhibition of pL transcription caused by convergent transcription from pR. Other consequences of the face-to-face promoter arrangement are discussed.

Secondary structural elements exclusive to the sequences flanking ribosomal RNAs lend support to the monophyletic nature of the archaebacteria

Several sequences flanking the large rRNA genes of several transcripts from extreme thermophiles, extreme halophiles, and methanogens were aligned and analyzed for the presence of common primary and secondary structural features, which would bear on the concept of monophyletic archaebacteria. Few sequences were common to all the archaebacterial transcripts, and these were confined to short regions generally flanking putative double helices. At a secondary structural level, however, in addition to the previously characterized processing stems of the 16S and 23S RNAs, four helices were detected that were common to the archaebacterial transcripts: two in the 16S RNA leader sequence and two in the 16S-23S RNA spacer. Although all of these helices vary in size and form from organism to organism, three of them contain double helical segments that are strongly supported by compensating base changes among the three archaebacterial groups. Three extreme halophiles exhibited two additional helices in their relatively large spacers and a further helix preceding the 5S RNA, which are also supported by compensating base changes. Ribosomal RNA transcripts from eubacteria/chloroplasts and eukaryotes were also examined for secondary structural features with locations and forms corresponding to those of the archaebacteria, but none were detected. The analysis provides support for the monophyletic nature of the archaebacteria and reinforces their differences from eubacteria/chloroplasts and eukaryotes.

Regions of the Streptococcus sobrinus spaA gene encoding major determinants of antigen I

Surface protein antigen A (SpaA), also called antigen B, antigen I/II, or antigen P1, is an abundant cell envelope protein that is the major antigenic determinant of Streptococcus sobrinus and other members of the Streptococcus mutans group of cariogenic bacteria. This laboratory has previously reported the cloning and expression in Escherichia coli of a BamHI restriction fragment of S. sobrinus DNA containing most of the spaA gene (pYA726) and encoding antigen I. Regions of spaA encoding immunodeterminants of antigen I were analyzed by either deletion mapping or expressing selected restriction fragments from the trc promoter. SpaA proteins produced by mutants harboring nested deletions, constructed by BAL 31 exonuclease treatment at a unique SstI site located towards the 3' end of the gene, were examined by Western immunoblot with rabbit serum against SpaA from S. sobrinus. Only SpaA polypeptides larger than 56 kilodaltons reacted with anti-SpaA serum. Various restriction fragments of the region of spaA encoding the antigenic determinants were cloned into an expression vector. The immunoreactive properties of the polypeptides encoded by those fragments indicated that expression of the immunodominant determinant required topographically assembled residues specified by noncontiguous regions located within 0.48-kilobase PvuII-to-SstI and 1.2-kilobase SstI-to-HindIII fragments which were adjacent on the spaA map.

Cloning, in vitro transcription, and biological activity of Escherichia coli 23S ribosomal RNA

The 23S rRNA gene was excised from the rrnB operon of pKK3535 and ligated into pUC19 behind the strong class III T7 promoter so that the correct 5' end of mature 23S RNA was produced upon transcription by T7 RNA polymerase. At the 3' end, generation of a restriction site for linearization required the addition of 2 adenosine residues to the mature 23S sequence. In vitro runoff transcripts were indistinguishable from natural 23S RNA in size on denaturing gels and in 5'-terminal sequence. The length and sequence of the 3' terminal T1 fragment was also as expected from the DNA sequence, except that an additional C, A, or U residue was added to 21%, 18%, or 5% of the molecules, respectively. Typical transcription reactions yielded 500-700 moles RNA per mole template. This transcript was used as a substrate for methyl transfer from S-adenosyl methionine catalyzed by Escherichia coli cell extracts. The majority (50-65%) of activity observed in a crude (S30) extract appeared in the post-ribosomal supernatant (S100). Activities catalyzing formation of m5C, m5U, m2G, and m6A residues in the synthetic transcript were observed.

Construction of Escherichia coli amber suppressor tRNA genes. II. Synthesis of additional tRNA genes and improvement of suppressor efficiency

Using synthetic oligonucleotides, we have constructed 17 tRNA suppressor genes from Escherichia coli representing 13 species of tRNA. We have measured the levels of in vivo suppression resulting from introducing each tRNA gene into E. coli via a plasmid vector. The suppressors function at varying efficiencies. Some synthetic suppressors fail to yield detectable levels of suppression, whereas others insert amino acids with greater than 70% efficiency. Results reported in the accompanying paper demonstrate that some of these suppressors insert the original cognate amino acid, whereas others do not. We have altered some of the synthetic tRNA genes in order to improve the suppressor efficiency of the resulting tRNAs. Both tRNA(CUAHis) and tRNA(CUAGlu) were altered by single base changes, which generated -A-A- following the anticodon, resulting in a markedly improved efficiency of suppression. The tRNA(CUAPro) was inactive, but a hybrid suppressor tRNA consisting of the tRNA(CUAPhe) anticodon stem and loop together with the remainder of the tRNA(Pro) proved highly efficient at suppressing nonsense codons. Protein chemistry results reported in the accompanying paper show that the altered tRNA(CUAHis) and the hybrid tRNA(CUAPro) insert only histidine and proline, respectively, whereas the altered tRNA(CUAGlu) inserts principally glutamic acid but some glutamine. Also, a strain deficient in release factor I was employed to increase the efficiency of weak nonsense suppressors.

Isolation and characterization of the 5S rRNA gene of Leptospira interrogans

The gene encoding the 5S rRNA for Leptospira interrogans serovar canicola strain Moulton was isolated and sequenced. The 5S rRNA gene occurs as a single copy within the genome and encodes a 117-nucleotide-long RNA molecule. The 5S rRNA gene is flanked at both the 5' and 3' ends by regions of A + T-rich sequences, and the 5'-flanking region contains a promoter sequence. L. interrogans has a unique and remarkable organization of the 5S rRNA gene. The 5S rRNA molecule exhibits a strong similarity to typical eubacterial 5S rRNA in terms of overall secondary structure, while the primary sequence is conserved to a lesser degree. Restriction analysis of the 5S rRNA gene indicated that the DNA sequence including the 5S rRNA gene is highly conserved in the genomes of parasitic leptospires.

Direct involvement of IS26 in an antibiotic resistance operon

The plasmid pBWH77, originally found in an isolate of Klebsiella pneumoniae, harbors a new antibiotic resistance operon containing two resistance genes transcribed from an IS26-hybrid promoter, as shown by nucleotide sequencing, mRNA mapping, and the effect of inserting a transcription terminator within the promoter-proximal gene. The nucleotide sequence of this region revealed that the operon (IAB) is made up of three sections that are closely related to previously described genetic elements. The -35 region of the promoter, together with the adjacent sequence, is identical to sequences of the IS26 element. One of the resistance genes, aphA7, which is located next to the hybrid promoter, confers assistance to neomycin and structurally related aminoglycosides. This aphA7 gene is highly homologous to aphA1 of Tn903, with five nucleotide differences. The second gene, blaS2A, encodes an evolved SHV-type beta-lactamase with a pI of 7.6 that confers resistance to the broad-spectrum cephalosporins cefotaxime and ceftizoxime. The deduced amino acid sequence of SHV-2A shows that amino acid 238 is a serine, a residue reported to confer resistance to cefotaxime. We discuss how the operon may have evolved by a combination of insertion sequence-mediated genetic rearrangements and acquisitive evolution. Using phylogenetic parsimony, we show that aphA7 in the IAB operon evolved from an ancestral form similar to aphA1 in Tn903 and that blaS2A evolved from an ancestral form similar to blaS1.

DNA from diverse sources manifests cryptic low-level transcription in Escherichia coli

We present evidence that DNA from diverse prokaryotic and eukaryotic sources gives rise to low-level fusion expression in Escherichia coli promoter-probe vectors. This expression may be as high as approximately 10% of the E. coli lacUV5 promoter. Although expression does not correlate with the presence of obvious E. coli promoter-like sequences, it is blocked by transcriptional terminators. Furthermore, transcription across the fusion junction is detected at levels that correlate with fusion expression. We suggest that this 'low-level transcription' (LLT) results from infrequent initiation by RNA polymerase at random sites and/or weak promoters. We propose that LLT has biological significance. In some instances, it may provide an advantageous basal level of gene expression, and we suggest that this may be true for the E. coli lacY gene. In other instances, LLT may be detrimental, in which case it may be blocked by mechanisms such as RNA secondary structure or transcriptional polarity. We present evidence to show that activation of the IS10 transposase gene by LLT is blocked at the translational level.

Vectors for constructing kan gene fusions: direct selection of mutations affecting IS10 gene expression

We describe several vectors for constructing translational fusions to the kan gene of Tn5. Fusions are constructed in vitro using multi-copy vectors containing unique cloning sites situated between upstream transcriptional terminators and a downstream kan gene lacking transcriptional and translational start signals. Multi-copy fusions can be converted to single-copy chromosomal fusions by in vivo recombination with specific phage lambda vectors and vice versa. We find that kan fusions are often more suitable than lacZ fusions for the direct selection of mutations that increase fusion expression. These vectors were developed for isolating mutations that increase IS10 transposase expression; we describe strategies used to isolate such mutations, which map to IS10 or the Escherichia coli himA, himD(hip), dam or infC genes.

Antitermination of characterized transcriptional terminators by the Escherichia coli rrnG leader region

We have used a plasmid antitermination test system to examine the response of an Escherichia coli rRNA operon antiterminator to transcription through Rho-dependent and Rho-independent terminator-containing fragments. We also monitored transcription through multiple copies of a terminator to explore the mechanism of rrn antitermination. Four principal observations were made about antitermination and transcriptional terminators. (1) The rrn antiterminator mediated efficient transcription through Rho-dependent terminators. (2) Under the influence of the rrn antiterminator, RNA polymerase transcribed through two and three copies of the Rho-dependent 16 S----terminator with nearly the same efficiency as through one. (3) The antiterminator had less effect on fragments containing Rho-independent terminators; the rpoC t fragment and three fragments derived from the rrnB terminator region stopped antiterminated transcription. Four other Rho-independent terminator fragments were weakly antiterminated in our test system. (4) Surprisingly, the strength of these terminator fragments was not strongly related to properties such as the -delta G or number of trailing uridine residues of their canonical Rho-independent structures, but appears to be related to additional downstream terminators. We have drawn the following conclusions from these experiments. First, that ribosomal antitermination primarily reverses Rho-dependent termination by modifying the RNA polymerase elongation complex. Transcription through a 1700 nucleotide, multiple terminator sequence showed that the antiterminator caused persistent changes in the transcription process. Second, that fragments derived from the Rho-independent rrnB and rpoBC terminator regions can effectively stop antiterminated transcription. Third, that efficient in vivo termination may often involve regions with complex multiple terminators.

Genetic diversity in Sargasso Sea bacterioplankton

Bacterioplankton are recognized as important agents of biogeochemical change in marine ecosystems, yet relatively little is known about the species that make up these communities. Uncertainties about the genetic structure and diversity of natural bacterioplankton populations stem from the traditional difficulties associated with microbial cultivation techniques. Discrepancies between direct counts and plate counts are typically several orders of magnitude, raising doubts as to whether cultivated marine bacteria are actually representative of dominant planktonic species. We have phylogenetically analysed clone libraries of eubacterial 16S ribosomal RNA genes amplified from natural populations of Sargasso Sea picoplankton by the polymerase chain reaction. The analysis indicates the presence of a novel microbial group, the SAR11 cluster, which appears to be a significant component of this oligotrophic bacterioplankton community. A second cluster of lineages related to the oxygenic phototrophs--cyanobacteria, prochlorophytes and chloroplasts--was also observed. However, none of the genes matched the small subunit rRNA sequences of cultivated marine cyanobacteria from similar habitats. The diversity of 16S rRNA genes observed within the clusters suggests that these bacterioplankton may be consortia of independent lineages sharing surprisingly distant common ancestors.

Base changes at position 792 of Escherichia coli 16S rRNA affect assembly of 70S ribosomes

To investigate the function of base 792 of 16S rRNA in 30S ribosomes of Escherichia coli, the wild-type (adenine) residue was changed to guanine, cytosine, or uracil by oligonucleotide-directed mutagenesis. Each base change conferred a unique phenotype on the cells. Cells containing plasmid pKK3535 with G792 or T792 showed no difference in generation time in LB broth containing ampicillin, whereas cells with C792 exhibited a 20% increase in generation time in this medium. To study the effect on cell growth of a homogeneous population of mutant ribosomes, the mutations were cloned into the 16S rRNA gene on pKK3535 carrying a spectinomycin-resistance marker (thymine at position 1192), and the cells were grown with spectinomycin. Cells containing G792 or C792 showed 16% and 56% increases in generation time, respectively, and a concomitant decrease in 35S assimilation into proteins. Cells with T792 did not grow in spectinomycin-containing medium. Maxicell analyses indicated decreasing ability to form 70S ribosomes from 30S subunits containing guanine, cytosine, or uracil at position 792 in 16S rRNA. It appeared that C792-containing 30S ribosomes had lost the ability to bind initiation factor 3.

Organization and nucleotide sequence of ribosomal RNA genes on a circular 73 kbp DNA from the colourless flagellate Astasia longa

Three tandemly arranged repeats (A, B, C) of 16S and 23S rDNA, and one supplementary (S) 16S rDNA adjacent to the 16S rDNA of repeat A, are present within an 18 kbp segment of a circular 73 kbp DNA from the colourless flagellate Astasia longa. The repeat units are separated by a short region containing a 5S rRNA gene and a gene for tRNA-Val (UAC). Sequence comparisons reveal 78%, 81%, and 67% identical nucleotides of the 23S rDNA (A), the 16S rDNA (B), and the 5S rDNA (A), respectively, with the corresponding genes of the Euglena gracilis chloroplast genome. As in Euglena chloroplasts, the 3'-terminal portion of the 23S rDNA is homologous to the 4.5S rRNA gene of higher plant chloroplast genomes. These results are supportive of a common evolutionary origin for the Astasia 73 kbp DNA and the Euglena 145 kbp chloroplast DNA.

Small ribosomal subunit RNA sequences, evolutionary relationships among different life forms, and mitochondrial origins

A tree was constructed from a structurally conserved area in an alignment of 83 small ribosomal subunit sequences of eukaryotic, archaebacterial, eubacterial, plastidial, and mitochondrial origin. The algorithm involved computation and optimization of a dissimilarity matrix. According to the tree, only plant mitochondria belong to the eubacterial primary kingdom, whereas animal, fungal, algal, and ciliate mitochondria branch off from an internal node situated between the tree primary kingdoms. This result is at variance with a parsimony tree of similar size published by Cedergren et al. (J Mol Evol 28:98-112, 1988), which postulates the mitochondria to be monophyletic and to belong to the eubacterial primary kingdom. The discrepancy does not follow from the use of conflicting sequence alignments, hence it must be due to the use of different treeing algorithms. We tested our algorithm on a set of sequences resulting from a simulated evolution and found it capable of faithfully reconstructing a branching topology that involved very unequal evolutionary rates. The use of more limited or more extended areas of the complete sequence alignment, comprising only very conserved or also more variable portions of the small ribosomal subunit structure, does have some influence on the tree topology. In all cases, however, the nonplant mitochondria seem to branch off before the emergence of eubacteria, and the differences are limited to the branching pattern among different types of mitochondria.