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

Cloning and expression of a cDNA encoding human placental protein 11, a putative serine protease with diagnostic significance as a tumor marker

The placental protein 11 (PP11) can act as a tumor marker because of its specific association with various forms of cancer. A lambda gt11 cDNA library prepared from human placenta was screened with a polyclonal anti-PP11 antiserum. Out of 10(6) independent clones, only one clone reacted with the anti-PP11 antiserum. The isolated cDNA coded only for the carboxy-terminal part of PP11 and was subsequently used to rescreen a lambda gt10 placental cDNA library. Two cDNA clones out of 10(6) screened were identified encoding the entire protein of 369 amino acids, including a typical hydrophobic signal sequence of 18 amino acids. Expression of the PP11 cDNA coding sequence in Escherichia coli resulted in the synthesis of a protein with the expected size which can be specifically immunoprecipitated with anti-PP11 antiserum. Fractionation experiments revealed that two forms of the protein are present in the bacterial cell: a higher-molecular-weight form of approximately 42 kD in the cytoplasm and a smaller-molecular-weight form of approximately 42 kD in the periplasm. This result indicates that PP11 can be synthesized in E. coli and is process by removal of the hydrophobic signal sequence. Both the placental and the processed recombinant PP11 protein exhibit a protease activity.

Gene fliA encodes an alternative sigma factor specific for flagellar operons in Salmonella typhimurium

Through genetic studies, the fliA gene product has been shown to regulate positively gene expression in late operons of the flagellar regulon in Salmonella typhimurium. In the present study, the fliA gene was cloned and sequenced. The fliA coding region consisted of 717 nucleotides beginning with the GTG initiation codon and the conserved sequence specific to promoters for flagellar operons was found to exist upstream of the coding region. The fliA gene product deduced from the nucleotide sequence was a protein with 239 amino acid residues and the calculated molecular mass was 27,470 dalton. The deduced amino acid sequence was homologous with that of sigma 28, a flagellar specific sigma factor of Bacillus subtilis. The fliA gene product was identified as a protein of molecular mass 29 kDa in the in vitro transcription-translation system, while three proteins of 29 kDa, 31 kDa and 32 kDa were found in the products programmed by the fliA gene in minicells and in maxicells. The 29 kDa FliA protein was purified from the FliA overproducing strain which carried the ptac-fliA fusion. This protein activated the in vitro synthesis of flagellin, the fliC gene product. RNA polymerase containing the purified FliA protein was shown to transcribe the fliC gene. These results indicate that FliA protein functions as an alternative sigma factor specific for S. typhimurium flagellar operons.

Control of Escherichia coli superoxide dismutase (sodA and sodB) genes by the ferric uptake regulation (fur) locus

The ferric uptake regulation (fur) gene product participates in regulating expression of the manganese- and iron-containing superoxide dismutase genes of Escherichia coli. Examination of beta-galactosidase activity coded from a chromosomal phi(sodA'-'lacZ) fusion suggests that metallated Fur protein acts as a transcriptional repressor of sodA (manganese superoxide dismutase [MnSOD]). Gel retardation assays demonstrate high-affinity binding of pure, Mn2(+)-Fur protein to DNA fragments containing the sodA promoter. These data and the presence of an iron box sequence in its promoter strongly suggest that sodA is part of the iron uptake regulon. An sodB'-'lacZ fusion gene borne on either a low- or high-copy plasmid yielded approximately two- to threefold more beta-galactosidase activity in Fur+ compared with Fur- cells; the levels of activity depended only weakly on the growth phase and did not change during an extended stationary phase. Measurement of FeSOD activity in logarithmic growth phase and in overnight cultures of sodA and fur sodA backgrounds revealed that almost no FeSOD activity was expressed in Fur- strains, whereas wild-type levels were expressed in Fur+ cells. Fur+ and Fur- cells bearing the multicopy plasmid pHS1-4 (sodB+) expressed approximately sevenfold less FeSOD activity in the fur background, and staining of nondenaturing electrophoretic gels indicates that synthesis of FeSOD protein was greatly reduced in Fur- cells. Gel retardation assays show that Mn2(+)-Fur had a significantly higher affinity for the promoter fragment of sodB compared with that of random DNA sequences but significantly lower than for the promoter fragment of sodA. These observations suggest that the apparent positive regulation of sodB does not result exclusively from a direct interaction of holo (metallated) Fur itself with the sodB promoter. Nevertheless, the sodB gene also appears to be part of the iron uptake regulon but not in the classical manner of Fe-dependent repression.

The structural analysis of the mitochondrial SSUrRNA implies a close phylogenetic relationship between mitochondria from plants and from the heterotrophic alga Prototheca wickerhamii

The gene for the mitochondrial small subunit rRNA (SSUrRNA) from the heterotrophic alga Prototheca wickerhamii has been isolated from a gene library of extranuclear DNA. Sequence and structural analyses allow the determination of a secondary structure model for this rRNA. In addition, several sequence motifs are present which are typically found in SSUrRNAs of various mitochondrial origins. Unexpectedly, the Prototheca RNA sequence has more features in common with mitochondrial SSUrRNAs from plants than with that from the green alga Chlamydomonas reinhardtii. The phylogenetic relationship between mitochondria from plants and algae is discussed.

Identification of Francisella species and discrimination of type A and type B strains of F. tularensis by 16S rRNA analysis

Tularemia is a zoonotic disease, occurring throughout the Northern Hemisphere. The causative agent, the bacterium Francisella tularensis, is represented by two main types. Type A is found in North America, whereas type B is mainly found in Asia and Europe and to a minor extent in North America. No routine technique for rapid diagnosis of tularemia has been generally applied. We have partially sequenced 16S rRNAs of two F. tularensis strains, as well as the closely related Francisella novicida. Of 550 nucleotides analyzed, only one difference in 16S rRNA primary sequence was found. This 16S rRNA analysis enabled the construction of oligonucleotides to be used as genus- and type-specific probes. Such probes were utilized for the establishment of a method for rapid and selective detection of the organism. This method allowed identification of Francisella spp. at the level of genus and also discrimination of type A and type B strains of F. tularensis. The analysis also permitted the detection of F. tularensis in spleen tissue from mice infected with the bacterium. The results presented will enable studies on the epizootiology and epidemiology of Francisella spp.

Overproduction and dissection of proteins by the expression-cassette polymerase chain reaction

We report an efficient, general approach for the construction of protein-overproducing strains of Escherichia coli. The method, expression-cassette polymerase chain reaction (ECPCR), allows the insertion of virtually any contiguous coding sequence between sequences that direct high-level protein biosynthesis in E. coli. The gene expression cassettes obtained by ECPCR are inserted into a regulated overexpression plasmid, and the resulting construct is used to transform E. coli. By effecting simultaneous 5' and 3' modification of a coding sequence, ECPCR permits the facile generation of mutant proteins having N- and/or C-terminal truncations. The method is a highly efficient way to dissect a multidomain protein into its component domains. The efficiency of the ECPCR approach is demonstrated in this study by construction of permuted overexpression vectors for the first two extracellular domains of the human CD4 protein.

Escherichia coli 4.5S RNA gene function can be complemented by heterologous bacterial RNA genes

The essential 4.5S RNA gene of Escherichia coli can be complemented by 4.5S RNA-like genes from three other eubacteria, including both gram-positive and gram-negative organisms. Two of the genes encode RNAs similar in size to the E. coli species; the third, from Bacillus subtilis, specifies an RNA more than twice as large. The heterologous genes are expressed efficiently in E. coli, and the product RNAs resemble those produced by cognate cells. We conclude that the heterologous RNAs can replace E. coli 4.5S RNA and that the essential function of 4.5S RNA is evolutionarily conserved. A consensus structure is presented for the functionally related 4.5S RNA homologs.

Dominant lethal mutations in a conserved loop in 16S rRNA

The 530 stem-loop region in 16S rRNA is among the most phylogenetically conserved structural elements in all rRNAs, yet its role in protein synthesis remains mysterious. G-530 is protected from kethoxal attack when tRNA, or its 15-nucleotide anticodon stem-loop fragment, is bound to the ribosomal A site. Based on presently available evidence, however, this region is believed to be too remote from the decoding site for this protection to be the result of direct contact. In this study, we use a conditional rRNA expression system to demonstrate that plasmid-encoded 16S rRNA genes carrying A, C, and T point mutations at position G-530 confer a dominant lethal phenotype when expressed in Escherichia coli. Analysis of the distribution of plasmid-encoded 16S rRNA in ribosomal particles, following induction of the A-530 mutation, shows that mutant rRNA is present both in 30S subunits and in 70S ribosomes. Little mutant rRNA is found in polyribosomes, however, indicating that the mutant ribosomes are severely impaired at the stage of polysome formation and/or stability. Detailed chemical probing of mutant ribosomal particles reveals no evidence of structural perturbation within the 16S rRNA. Taken together, these results argue for the direct participation of G-530 in ribosomal function and, furthermore, suggest that the dominant lethal phenotype caused by these mutations is due primarily to the mutant ribosomes blocking a crucial step in protein synthesis after translational initiation.

Improved vector system for constructing transcriptional fusions that ensures independent translation of lacZ

An improved vector system has been developed for the in vitro construction of transcriptional fusions to lacZ. The principal feature is an RNaseIII cleavage site inserted between the polylinker cloning site and the promoterless lacZ gene. When these vectors are used to construct transcriptional fusions, the subsequent cleavage of the hybrid mRNA at the RNaseIII site generates an unchanging 5' end for the lacZ mRNA. In contrast to earlier vectors, this feature helps to ensure independent translation of the lacZ mRNA and, thus, the level of beta-galactosidase produced should accurately reflect the frequency of transcription of the upstream DNA sequences. Additional modifications of the vectors include removal of a weak transcriptional terminator between the cloning site and lacZ, insertion of a terminator downstream of lac, and alteration of restriction endonuclease cleavage sites to facilitate the in vitro construction of fusions. Both multicopy plasmid (pTL61T) and single-copy lambda (lambda TL61) vectors have been assembled. These vectors should be generally useful in scanning for transcriptional regulatory signals.

Comparison of proC and other housekeeping genes of Pseudomonas aeruginosa with their counterparts in Escherichia coli

In a comparative study of housekeeping genes of Pseudomonas aeruginosa and Escherichia coli, the nucleotide sequence of a proline biosynthetic gene, proC, of P. aeruginosa has been determined. The subunit molecular mass (approximately 29 kDa) and the N-terminal amino acid sequence of purified delta 1-pyrroline 5-carboxylate reductase, the proC gene product, were in agreement with the proC nucleotide sequence. A survey of pairs of isofunctional genes from P. aeruginosa and E. coli reveals that within each pair, translated genes (including proC) have diverged more strongly than have untranslated genes specifying ribosomal or transfer RNAs. The translated genes, but not the untranslated ones, have a G + C content that is typical of the respective genomic G + C contents.

Natural relationships among sulfate-reducing eubacteria

Phylogenetic relationships among 20 nonsporeforming and two endospore-forming species of sulfate-reducing eubacteria were inferred from comparative 16S rRNA sequencing. All genera of mesophilic sulfate-reducing eubacteria except the new genus Desulfomicrobium and the gliding Desulfonema species were included. The sporeforming species Desulfotomaculum ruminis and Desulfotomaculum orientis were found to be gram-positive organisms sharing 83% 16S rRNA sequence similarity, indicating that this genus is diverse. The gram-negative nonsporeforming species could be divided into seven natural groups: group 1, Desulfovibrio desulfuricans and other species of this genus that do not degrade fatty acids (this group also included "Desulfomonas" pigra); group 2, the fatty acid-degrading "Desulfovibrio" sapovorans; group 3, Desulfobulbus species; group 4, Desulfobacter species; group 5, Desulfobacterium species and "Desulfococcus" niacini; group 6, Desulfococcus multivorans and Desulfosarcina variabilis; and group 7, the fatty acid-oxidizing "Desulfovibrio" baarsii. (The quotation marks are used to indicate the need for taxonomic revision.) Groups 1 to 3 are incomplete oxidizers that form acetate as an end product; groups 4 to 7 are complete oxidizers. The data were consistent with and refined relationships previously inferred by oligonucleotide catalogs of 16S rRNA. Although the determined relationships are generally consistent with the existing classification based on physiology and other characteristics, the need for some taxonomic revision is indicated.

Superpolylinkers in cloning and expression vectors

Versatile DNA polylinkers of more than 300 bp were constructed. They contain the recognition sequences of all restriction enzymes--whether known or still to be discovered--that recognize palindromic hexamers. In addition to these 64 uninterrupted hexameric recognition sites, a number of sites containing interrupted palindromes and nonpalindromic sequences and two recognition sequences with 8 bp are present. Polylinkers (in several variants) were inserted into frequently utilized Escherichia coli cloning vectors such as pBluescript (yielding pSLJ10, pSL250, pSL260, pSL270, and pSL300), pUC18/pUC19 (yielding pSL180 and pSL190, respectively), or pUC118/pUC119 (yielding pSL1180 and pSL1190, respectively). A subtle color discrimination between presence and absence of insert in pSL300 (mid-blue to light-blue or white) was seen in a number of test ligations. The mid-blue color that is generated by pSL300 is presumably due to translational restarts. A different intergenic region for translational restarts was used in plasmids pSL251, pSL261, pSL271, and pSL301. The polylinker was also inserted into expression vector pUC120, yielding pSE1200, and into expression vector pKK233-2, yielding pSE220 and a shortened version thereof, pSE280. Finally, the polylinker was inserted into pTrc99A, resulting in pSE380, which carries a lac repressor gene. This expands the use of the expression system beyond lacIq strains to other bacterial hosts. These versatile vectors have broad applications in genetic engineering.

Expression of the insecticidal protein gene from Bacillus thuringiensis subsp. aizawai in Bacillus subtilis and in the thermophile Bacillus stearothermophilus by using the alpha-amylase promoter of the thermophile

Expression of the insecticidal protein gene from Bacillus thuringiensis subsp. aizawai IPL7 in B. subtilis MI113 and B. stearothermophilus SIC1 was examined. Production of the protein (130 kilodaltons [KDa]) was analyzed by its reaction with antibody against the insecticidal proteins of the parental B. thuringiensis. When the original gene containing its own promoter was subcloned in B. subtilis, only a small amount of the protein was produced. Therefore, both the promoter for the B. stearothermophilus alpha-amylase gene and the insecticidal protein gene were inserted in a repA (low-copy-number) plasmid to yield the recombinant plasmid pTBT-Pamy. B. subtilis MI113 carrying pTBT-Pamy produced more of the 130-kDa protein (about 10(4) molecules per cell) at 37 degrees C. In contrast, B. stearothermophilus SIC1 carrying pTBT-Pamy produced a small amount of 130-kDa protein (10(2) to 10(3) molecules per cell) at 55 degrees C.

Relationship among selected Leptospira interrogans serogroups as determined by nucleic acid hybridization

Leptospiral DNAs from a variety of Leptospira interrogans serogroups of veterinary significance, as well as a nonpathogenic leptospira, were compared by Southern blot hybridization of EcoRI-digested genomic DNA. The serogroups examined could be assigned to one of three groups on the basis of the degree of cross-hybridization between genomic DNAs. Only a few restriction fragments hybridized between the three groups, and most of these were shown to contain ribosomal DNA. The restriction fragment length polymorphism observed among the intergroup hybridizations allowed differentiation among serogroups and, in some cases, serovars. Under the hybridization conditions used, no hybridization was observed between leptospiral DNA and Leptonema, Escherichia coli, or porcine DNA.

Conserved sequence elements upstream and downstream from the transcription initiation site of the Caulobacter crescentus rrnA gene cluster

The nucleotide sequence and in vivo transcription start sites for rrnA, one of the two rRNA gene clusters of the eubacterium Caulobacter crescentus, have been determined. Two transcription start sites, a major and minor, for the rRNA gene cluster are located more than 700 nucleotides upstream from the 16 S rRNA gene. Transcription was detected from only the major start site in swarmer cells. But after the swarmer-to-stalked cell transition, transcription was detected from both rRNA start sites and continued throughout the developmental cell cycle when cells were grown in minimal medium. On the other hand, transcription from only the major start site was detected in cells growing in a complex medium. A small open reading frame was found upstream from the rRNA gene transcription start sites and was followed by an inverted repeat sequence. No sequence homology was found between the major rRNA gene transcription start site and the Escherichia coli sigma 70 promoters or the consensus sequence elements reported for C. crescentus fla promoters. However, there were two areas of homology when the major rRNA gene promoter was compared to the nucleotide sequence of the C. crescentus trpFBA promoter. There was a 12 nucleotide sequence centered around the -10 region of both promoters that was closely homologous. In addition, immediately downstream from the transcription start there was a sequence element that was identical in both promoters. These nucleotide sequence elements were not in the temporally expressed fla promoters of C. crescentus.

Mutant rho factors with increased transcription termination activities. II. Identification and functional dissection of amino acid changes

We have determined the nucleotide sequences of three mutant rho genes encoding hyperfunctional rho proteins (rho S) together with their parent allele, rho-ts702. These mutant rho factors contain the following amino acid changes as deduced from their sequences: (1) the thermo-labile mutant, rho-ts702, has Thr304 substituting for Ala; (2) rho S-77 and rho S-81, which are selectively altered in the primary polynucleotide binding site, share an identical mutation, Leu3----Phe; (3) rho S-82, which is altered in both the primary and secondary polynucleotide binding sites, carries three amino acid substitutions together, Leu3----Phe, Asp156----Asn and Thr323----Ile. Dissection and functional characterization of each mutation in rho S-82 have revealed that Ile323 alone is responsible for alterations in both the secondary RNA interaction and the terminator selectivity observed with the original mutant, rho S-82. Taken together, these results not only confirm our proposal in the accompanying paper that the primary and secondary RNA binding sites differently contribute in determining the overall efficiency and site-specificity of termination, respectively, but also support the possibility that these binding sites exist as structurally distinct domains in rho protein. In contrast, Asn156 was shown to cause decreased termination efficiency, though it had no influence on RNA interactions. Thus, this amino acid residue appears to be associated with still another rate-determining step of termination, for instance, interactions between rho and RNA polymerase. On the basis of Chou-Fasman secondary structure predictions as well as amino acid sequence comparison with F1-ATPase, we discuss how the proposed domains are structurally and functionally related to the putative ATPase reactive center of rho protein.

Effects of gene dosage on the expression of human growth hormone cDNA in Escherichia coli

Gene dosage effects on the foreign protein production in Escherichia coli have been analyzed with the expression vectors containing one, two and four tandemly arranged human growth hormone cDNAs under various culture conditions. In a limited synthetic culture medium, a proportional relationship was observed between the number of the integrated cDNA and the amount of human growth hormone produced. With a culture medium rich in the nutrients, however, no such relationship was observed. These results suggest that, under the limited culture conditions, high-level expression of a foreign gene can be achieved by tandemly joined multiple copies of cDNA.

Expression of an Anacystis nidulans photolyase gene in Escherichia coli; functional complementation and modified action spectrum of photoreactivation

The Anacystis nidulans photolyase gene inserted in an expression vector plasmid was introduced into Escherichia coli cells and the production of Anacystis photolyase protein was confirmed by reaction with antibodies raised against photolyase purified from A. nidulans cells. The Anacystis photolyase functioned in photoreactivation repair defective E. coli cells. The E. coli transformants exhibited an action spectrum with a maximum around 380 nm similar to that of E. coli photolyase in contrast with the action spectrum of A. nidulans cells which has a maximum at 437 nm. These results indicate that the Anacystis photolyase produced in E. coli cells has enzymatic activity in spite of the apparent lack of its intrinsic 8-hydroxy-5-deazaflavin cofactor.

Unique organization of Leptospira interrogans rRNA genes

We cloned Sau3AI fragments containing the rRNA genes for Leptospira interrogans serovar canicola strain Moulton in the BamHI site of lambda EMBL3 bacteriophage DNA. Physical maps of the fragments were constructed, and the locations of the rRNA genes were determined by Southern blot hybridization and S1 protection. Each fragment of the 23S or the 16S rRNA gene contained at least one copy of the 23S or the 16S sequence. Genomic hybridization showed that there were two genes for the 23S rRNA and the 16S rRNA but only one gene for the 5S rRNA on the chromosome of L. interrogans. The results revealed the important fact that each rRNA gene is located far from the other rRNA genes. Our findings, accordingly, also suggest that these rRNA genes are expressed independently in this organism.

Ribosomal RNA operon anti-termination. Function of leader and spacer region box B-box A sequences and their conservation in diverse micro-organisms

All Escherichia coli rrn operons show a common motif in which anti-terminator box B-box A sequences occur twice, first in the leader and again in the 16 S-23 S spacer. In this study we have analyzed several aspects of rrn anti-termination by leader and spacer anti-terminator sequences. Using DNA synthesis and a plasmid test system, we incorporated random changes into the leader anti-terminator region and examined these mutations for their ability to read through a strong terminator. We also examined anti-termination by synthetic box A and by rrn spacer region sequences. Information derived from these experiments was used to search the rrn sequences of other micro-organisms for possible anti-termination features. Our principal conclusions were that: (1) box A was sufficient for terminator readthrough; (2) we could show no positive requirement for box B in our test system; (3) many of the negative anti-terminator mutations caused a promoter up-effect in the absence of a terminator; (4) the search of rrn operons from other micro-organisms revealed that anti-terminator-like box B-box A sequences exist in leader and spacer regions of both eubacteria and archaebacteria. The frequent occurrence of this pattern suggested that the E. coli rrn anti-termination motif is widespread in nature and has been conserved in microbial evolution.

Evidence for unlinked rrn operons in the Planctomycete Pirellula marina

Southern hybridization of rRNAs to chromosomal BamHI-digested DNA of the eubacterium Pirellula marina revealed the presence of two sets of 16S and 23S rRNA genes. The two copies of the 23S rRNA genes, located on 11- and about 13-kilobase (kb) inserts, were isolated from a lambda bacteriophage Charon 35 library. The 11-kb fragment was cloned directly into pBR322, while a 5.4-kb BamHI-PstI rDNA subfragment of the approximately 13-kb insert was cloned into pUC18. Both recombinant plasmids, pPI1100 and pPI540, were characterized by restriction enzyme mapping and Southern hybridization with the large rRNA species. Restriction fragments from both inserts were subcloned into phage M13 mp18 and mp19. Correlation of genomic hybridization data with physical characterization of recombinant plasmids showed that, in contrast to the general organization of rrn operons in eubacteria, the 16S rRNA genes of P. marina are separated by at least 8.5 (pPI540) and 4.4 (pPI1100) kb, respectively, from the closely linked 23S-5S rRNA genes. Comparison of the flanking regions from both 23S-5S rRNA genes with published consensus sequences of structural elements indicates the presence of putative transcription signals, i.e., a single Pribnow box, discriminator, antitermination boxes A, B, and C, and a Rho-independent terminator.

The difficulty of cloning Streptococcus pneumoniae mal and ami loci in Escherichia coli: toxicity of malX and amiA gene products

Stability problems are frequently encountered when cloning pneumococcal DNA in Escherichia coli multicopy plasmid vectors such as derivatives of ColE1. In this paper, we report our investigations of these problems using the pneumococcal mal and ami regions. We offer evidence that, in both cases, promoters are not the primary cause of cloning problems. Indeed, successful cloning of mal and ami promoters has been achieved with standard vectors (devoid of transcriptional terminators flanking the insertion site). Moreover, we show that the entire mal fragment can be introduced into an E. coli strain harboring a chromosomal mutation that reduces plasmid copy number. The cause of the cloning problems has been traced to the malX and amiA structural genes. Overexpression of these genes, which probably encode lipoproteins, could have deleterious effects on E. coli hosts, possibly as a result of impairing the protein export machinery.

Recombinant anaerobic maize aldolase: overexpression, characterization, and metabolic implications

Complementary DNA sequence of anaerobically induced cytoplasmic maize aldolase was expressed under control of the tac promoter sequence in Escherichia coli using the pKK223-3 plasmid as a vehicle. Levels of recombinant protein expressed exceeded 20 mg of soluble aldolase per liter of culture. The purified recombinant enzyme displayed the expected molecular weight and tetrameric subunit assembly on the basis of mobilities on denaturing electrophoretic gels and gel filtration, respectively. Sequencing of the NH2 terminus and amino acid composition analysis of the recombinant protein including COOH-terminal peptides agreed with the cDNA sequence. Partial kinetic characterization based on product inhibition studies was consistent with the ordered uni-bi reaction mechanism expected of aldolases. Turnover with respect to substrates Fru-1,6-P2 and Fru-1-P by the recombinant enzyme is the highest reported to date for class I aldolases. Fru-1,6-P2 cleavage rate by recombinant cytoplasmic maize enzyme is three times greater than that of the chloroplast enzyme. Fru-1-P cleavage is 8-fold greater than that of the rabbit liver isozyme and 20-fold greater than that of the rabbit muscle isozyme to which maize aldolase exhibits the greatest homology. The implications of such a high Fru-1-P turnover on carbohydrate utilization under anaerobiosis is discussed.

Transcription mapping of the Escherichia coli chromosome by electron microscopy

The distinctive double Christmas tree morphology of rRNA operons as visualized by electron microscopy makes them easy to recognize in chromatin spreads from Escherichia coli. On the basis of the pattern of nascent transcripts on nearby transcription units and the relative distances of the operons from one another and the replication origin, we are now able to specifically identify five of the seven rRNA operons in E. coli. The use of rRNA operons as markers of both position and distance has resulted in the morphological mapping of a significant portion of the E. coli chromosome; over 600 kilobase pairs in the 84- to 90-min and 72-min regions can now be recognized. Since individual rRNA operons could be identified, direct comparisons could be made of their transcriptional activities. As judged by the densities of RNA polymerases along the operons, rrnA, rrnB, rrnC, rrnD, and rrnE were all transcribed at similar levels, with one RNA polymerase every 85 base pairs. The ability to recognize individual operons and specific regions of the chromosome allows direct comparisons of various genetic parameters.

A new procedure for the targeted inactivation of essential bacterial genes

A new method is described for the exchange of a plasmid encoded mutant gene with its chromosomal counterpart. The method is based on positive selection and is applicable for the exchange of essential genes. The main features of the method are: (1) cloning of an antibiotic resistance marker (without its promoter) downstream of the cloned target gene, thus forming an artificial operon; (2) inactivating the target gene (and consequently also the antibiotic resistance gene) by inserting a strong transcriptional termination signal into it; and (3) selection for double recombinants by means of the antibiotic resistance gene.

Ribosome-binding sites and RNA-processing sites in the transcript of the Escherichia coli unc operon

The polycistronic mRNA encoding the nine genes of the unc operon of Escherichia coli was studied. We demonstrated the ribosome-binding capabilities of six of the nine unc genes, uncB, uncE, uncF, uncH, uncA, and uncD, by using the technique of primer extension inhibition or "toeprinting." No toeprint was detected for the other genes, uncI, uncG, and uncC. The lack of a toeprint for uncG suggests that this gene is expressed by some form of translational coupling, such that either uncG is read by ribosomes which have translated the preceding gene, uncA, or translation of uncA is required for ribosome binding at the uncG site. RNA sequencing and primer extension in the regions of uncI and uncC, the first and last genes in the operon, respectively, gave less intense signals than those obtained for the other unc genes. This suggested that there are fewer copies of those regions of the transcript and that processing of the unc transcript occurred. Using primer extension and RNA sequencing, we identified sites in the unc transcript at which processing appears to take place, including a site which may remove much of the uncI portion of the transcript. Northern (RNA) blot analysis of unc RNA is consistent with the presence of an RNA-processing site in the uncI region of the transcript and another in the uncH region. These processing events may account for some of the differential levels of expression of the unc genes.

Organization and nucleotide sequence analysis of a ribosomal RNA gene cluster from Streptomyces ambofaciens

The Streptomyces ambofaciens genome contains four rRNA gene clusters. These copies are called rrnA, B, C and D. The complete nucleotide (nt) sequence of rrnD has been determined. These genes possess striking similarity with other eubacterial rRNA genes. Comparison with other rRNA sequences allowed the putative localization of the sequences encoding mature rRNAs. The structural genes are arranged in the order 16S-23S-5S and are tightly linked. The mature rRNAs are predicted to contain 1528, 3120 and 120 nt, for the 16S, 23S and 5S rRNAs, respectively. The 23S rRNA is, to our knowledge, the longest of all sequenced prokaryotic 23S rRNAs. When compared to other large rRNAs it shows insertions at positions where they are also present in archaebacterial and in eukaryotic large rRNAs. Secondary structure models of S. ambofaciens rRNAs are proposed, based upon those existing for other bacterial rRNAs. Positions of putative transcription start points and of a termination signal are suggested. The corresponding putative primary transcript, containing the 16S, 23S and 5S rRNAs plus flanking regions, was folded into a secondary structure, and sequences possibly involved in rRNA maturation are described. The G + C content of the rRNA gene cluster is low (57%) compared with the overall G + C content of Streptomyces DNA (73%).

Pea aphid symbiont relationships established by analysis of 16S rRNAs

The pea aphid (Acyrthosiphon pisum Harris) harbors two morphologically distinct procaryotic intracellular symbionts. The genes for the 16S rRNA from these symbionts have been cloned and sequenced. Comparisons with sequences of 16S rRNAs from selected procaryotes indicate that the two symbionts are evolutionarily distinct from each other and are members of the gamma-3 subdivision of the class Proteobacteria. One of the symbionts is a member of the family Enterobacteriaceae, while the other constitutes a lineage distinct from these organisms. Both symbionts appear to have only one copy of their rRNA operon.

The structural basis of the high in vivo strength of the rRNA P2 promoter of Escherichia coli

Ribosomal RNA promoters of Escherichia coli are probably the strongest promoters in vivo and they can be used on plasmid vectors to express protein-coding sequences at a high rate. In fact, the P2 promoter of the rrnB gene is stronger (in vivo) than the tac promoter, which has a perfect consensus sequence. Conversion of the rrnB P2 promoter sequence to consensus significantly increases in vivo promoter strength. The removal of four nucleotides downstream of the -10 region also increases the strength of this promoter. On the other hand, shifting of the A + T-rich region upstream of this promoter by an 11-bp insertion drastically decreases in vivo activity. It is concluded that the two functionally important hexanucleotide sequences, -35 and -10, are necessary but not sufficient factors for the optimalization of in vivo promoter strength.

Processing of chloroplast ribosomal RNA transcripts in Euglena gracilis bacillaris

The ribosomal RNA operons (rrn operons) of Euglena gracilis chloroplasts contain genes for (in order) 16S rRNA, tRNA(Ile), tRNA(Ala),23S rRNA and 5S rRNA. Major sites of cleavage of the primary rrn transcript were identified by Northern blot hybridization and S1-mapping. The presumptive termini of all of the mature products have now been identified. During initial processing in the chloroplast, the primary transcript is cleaved between the two tRNAs and between the 23S and 5S rRNAs so as to separate the sequences found in the different mature rRNAs. Subsequently the tRNAs are separated from the rRNAs, further trimming provides the remaining proper ends, and the 3'-ends of the tRNAs are added.

Blastocystis hominis: phylogenetic affinities determined by rRNA sequence comparison

In 1912 Blastocystis hominis was identified as a new species and classified as a yeast (Brumpt 1912). In the early 1920s several groups confirmed its classification as a yeast, specifically a member of the genus Schizosaccharomyces (discussed by Zierdt et al. 1967). Apart from an occasional case report, the classification of B. hominis and its role as a harmless intestinal yeast was not questioned for another 50 years. Then, Zierdt (1967) suggested that it should be classified in the phylum Protozoa, subphylum Sporozoa, and that it should be considered as a potential pathogen. The likely role of B. hominis as a human pathogen has recently become more firmly established (Garcia et al. 1984; Sheehan et al. 1986) and its classification has been changed. Although the classification of B. hominis as a protozoon was assumed widely, classification as a sporozoon was not accepted, and the most recent definitive classification of the Protozoa did not even list B. hominis (Lee et al. 1985). Then, based essentially on a review of the known characteristics of the organism, it was recently reclassified into the subphylum Sarcodina (Zierdt 1988). Clearly, the phylogeny of this emerging human pathogen needs definitive analysis (Mehlhorn 1988).

Functional characterization of a putative internal promoter sequence between the 16S and the 23S RNA genes within the Escherichia coli rrnB operon

Transcription of ribosomal RNAs in Escherichia coli is started from two strong tandem promoters, P1 and P2. It is known, however, that internal promoter-like structures occur and in a recent report (Mankin et al., 1987) a promoter sequence Pi within the 16S and 23S RNA spacer region showing good homology to the prokaryotic consensus promoter structure was identified. It was proposed that this putative promoter has a possible function in the transcription of ribosomal RNAs in E. coli. Fusion of various DNA fragments containing the putative promoter sequence and different parts of the 16S/23S spacer region as well as the 23S RNA to the galactokinase gene allowed us to assess the functional activity of the promoter in vivo. To determine any growth rate dependent function of the putative promoter, the measurements were performed under different growth conditions. The promoter activity did not exceed 7% of the lac promoter under in vivo assay conditions. In addition, transcription starting at the promoter Pi did not proceed through the entire 23S RNA gene. We conclude, therefore, that transcription from Pi does not contribute significantly to the synthesis of ribosomal RNAs. Thus its functional significance, if any, remains elusive.

Processing pathway of Escherichia coli 16S precursor rRNA

Immediate precursors of 16S rRNA are processed by endonucleolytic cleavage at both 5' and 3' mature termini, with the concomitant release of precursor fragments which are further metabolized by both exo- and endonucleases. In wild-type cells rapid cleavages by RNase III in precursor-specific sequences precede the subsequent formation of the mature ends; mature termini can, however, be formed directly from pre-16S rRNA with no intermediate species. The direct maturation is most evident in a strain deficient in RNase III, and the results in whole cells are consistent with results from maturation reactions in vitro. Thus, maturation does not require cleavages within the double-stranded stems that enclose mature rRNA sequences in the pre-16S rRNA.

Characterization of the two rRNA gene operons present in Thiobacillus ferrooxidans

The organization of rRNA genes from the autotrophic, acidophilic bacterium Thiobacillus ferrooxidans has been examined. Two rRNA operons were found in this microorganism by means of genomic hybridization studies. Recombinant plasmids, pTR-3 and pTR-1 that carry a portion of 16/23 S rDNA from one operon and the 5'-flanking region of the second operon, respectively, were identified and characterized.

A plasmid to visualize and assay termination and antitermination of transcription in Escherichia coli

To facilitate the analysis of termination and antitermination of transcription in prokaryotes, a complex operon has been assembled into the pBR322 replicon, drawing upon natural and synthetic DNA elements. This operon is initiated from a strongly inducible promoter without temperature restraints. It includes a severe transcription terminator and therefore requires antitermination of transcription to express a downstream lacZ reporter gene. Antitermination can be provided by an upstream N-utilization site from phage lambda, working in conjunction with N protein supplied in trans from a compatible plasmid. In this situation, the nusA gene of Salmonella, substituted into the Escherichia coli host, prevents lacZ function, confirming that a good facsimile of lambda's specific antitermination mechanism has been recreated. The nonessential, easily assayed product of this operon, beta-galactosidase, is also screenable by colony color on chromogenic substrate. The plasmid described will therefore serve as a tester for mutations affecting the various aspects of transcription regulation by termination.

The nucleotide sequence of the Escherichia coli rts gene

The nucleotide sequence of rts, an essential Escherichia coli gene, has been determined. Transformation of an rts mutant with the plasmid, pJAF1, containing the rts gene resulted in rescue of the defect. The transformation experiments indicate that the rts gene is distinct from the flanking birA, tRNA and tufB genes.

Analysis of the promoters and transcripts involved in IS10 anti-sense RNA control

Genetic analysis of eleven mutations affecting the IS10 promoters, pIN and pOUT, involved in anti-sense RNA control of transposase gene expression, and characterization of the transcripts, reveal that: (i) The transposase message (RNA-IN) and the anti-sense RNA (RNA-OUT) have been unambiguously identified in vivo. (ii) Five mutations affect pIN activity, and establish that pIN is the only IS10 promoter transcribing the tnp gene, and the only such IS10 promoter that responds to DNA-adenine methylation. (iii) Six mutations alter pOUT activity, and establish that pOUT is the only IS10 promoter specifying the anti-sense RNA-OUT. (iv) The latter, however, need not be so: heterologous promoters, if properly positioned, can also specify active anti-sense RNAs. (v) These heterologously promoted anti-sense RNAs are processed to species closely resembling native RNA-OUT.

The evolutionary relationships among known life forms

Sequences of small subunit (SSU) and large subunit (LSU) ribosomal RNA genes from archaebacteria, eubacteria, and the nucleus, chloroplasts, and mitochondria of eukaryotes have been compared in order to identify the most conservative positions. Aligned sets of these positions for both SSU and LSU rRNA have been used to generate tree diagrams relating the source organisms/organelles. Branching patterns were evaluated using the statistical bootstrapping technique. The resulting SSU and LSU trees are remarkably congruent and show a high degree of similarity with those based on alternative data sets and/or generated by different techniques. In addition to providing insights into the evolution of prokaryotic and eukaryotic (nuclear) lineages, the analysis reported here provides, for the first time, an extensive phylogeny of the mitochondrial lineage.

An efficiently mutagenizable recombinant plasmid for in vitro transcription of the Escherichia coli 16 S RNA gene

The portion of the rrnB operon coding for 16 S RNA was modified to permit efficient in vitro transcription by T7 RNA polymerase of full-length, correctly terminated, biologically active 16 S RNA (W. Krzyzosiak et al., 1987, Biochemistry 26, 2353-2364). The 5'-end of the gene was fused to the class III T7 promoter and the 3'-end was modified so that cleavage with MstII would generate correctly terminated RNA upon runoff transcription. The modified gene was placed in pUC19 by a four-way ligation reaction involving linearized pUC19, a 1490-bp fragment of 16 S rDNA, and two synthetic oligodeoxynucleotides. Because of the cohesive end design, phosphorylation of the synthetic oligomers was not necessary. Single and tandem cassette insertions were used to generate single base changes in the C-1400 region of 16 S RNA. Three examples are described. This method is generally applicable to the 16 S RNA molecule as suitable singlecleavage restriction sites allow all regions to be mutated by this approach.

Study on rRNA genes in Mycobacterium smegmatis

The number of rRNA genes in Mycobacterium smegmatis was examined by hybridization of BamHI and SalI digests of chromosomal DNA with 3'-end-labeled 5S, 16S, 23S rRNA and tRNA. Each RNA probe gave two hybridization bands. The PstI fragments of 6.6 kilobases were cloned to pBR322. The cloned DNA was characterized by restriction endonuclease mapping, DNA-RNA hybridization, and the R-loop technique.

Mutational analysis of the L1 binding site of 23S rRNA in Escherichia coli

The L11 ribosomal protein operon of Escherichia coli contains the genes for L11 and L1 and is feedback regulated by the translational repressor L1. Both the L1 binding site on 23S rRNA and the L1 repressor target site on L11 operon mRNA share similar proposed secondary structures and contain some primary sequence identity. Several site-directed mutations in the binding region of 23S rRNA were constructed and their effects on binding were examined. For in vitro analysis, a filter binding method was used. For in vivo analysis, a conditional expression system was used to overproduce a 23S rRNA fragment containing the L1 binding region, which leads to specific derepression of the synthesis of L11 and L1. Changes in the shared region of the 23S rRNA L1 binding site produced effects on L1 binding similar to those found previously in analysis of corresponding changes in the L11 operon mRNA target site. The results support the hypothesis that r-protein L1 interacts with both 23S rRNA and L11 operon mRNA by recognizing similar features on both RNAs.