Organization and nucleotide sequence analysis of an rRNA and tRNA gene cluster from Caulobacter crescentus

Spatial organization and dynamics of RNase E and ribosomes in Caulobacter crescentus

We report the dynamic spatial organization of Caulobacter crescentus RNase E (RNA degradosome) and ribosomal protein L1 (ribosome) using 3D single-particle tracking and superresolution microscopy. RNase E formed clusters along the central axis of the cell, while weak clusters of ribosomal protein L1 were deployed throughout the cytoplasm. These results contrast with RNase E and ribosome distribution in Escherichia coli, where RNase E colocalizes with the cytoplasmic membrane and ribosomes accumulate in polar nucleoid-free zones. For both RNase E and ribosomes in Caulobacter, we observed a decrease in confinement and clustering upon transcription inhibition and subsequent depletion of nascent RNA, suggesting that RNA substrate availability for processing, degradation, and translation facilitates confinement and clustering. Importantly, RNase E cluster positions correlated with the subcellular location of chromosomal loci of two highly transcribed rRNA genes, suggesting that RNase E's function in rRNA processing occurs at the site of rRNA synthesis. Thus, components of the RNA degradosome and ribosome assembly are spatiotemporally organized in Caulobacter, with chromosomal readout serving as the template for this organization.

Is the 16S-23S rRNA internal transcribed spacer region a good tool for use in molecular systematics and population genetics? A case study in cyanobacteria

We amplified, TA-cloned, and sequenced the 16S-23S internal transcribed spacer (ITS) regions from single isolates of several cyanobacterial species, Calothrix parietina, Scytonema hyalinum, Coelodesmium wrangelii, Tolypothrix distorta, and a putative new genus (isolates SRS6 and SRS70), to investigate the potential of this DNA sequence for phylogenetic and population genetic studies. All isolates carried ITS regions containing the sequences coding for two tRNA molecules (tRNA and tRNA). We retrieved additional sequences without tRNA features from both C. parietina and S. hyalinum. Furthermore, in S. hyalinum, we found two of these non-tRNA-encoding regions to be identical in length but different in sequence. This is the first report of ITS regions from a single cyanobacterial isolate not only different in configuration, but also, within one configuration, different in sequence. The potential of the ITS region as a tool for studying molecular systematics and population genetics is significant, but the presence of multiple nonidentical rRNA operons poses problems. Multiple nonidentical rRNA operons may impact both studies that depend on comparisons of phylogenetically homologous sequences and those that employ restriction enzyme digests of PCR products. We review current knowledge of the numbers and kinds of 16S-23S ITS regions present across bacterial groups and plastids, and we discuss broad patterns congruent with higher-level systematics of prokaryotes.

Comparative analysis of Pseudomonas syringae pv. actinidiae and pv. phaseolicola based on phaseolotoxin-resistant ornithine carbamoyltransferase gene (argK) and 16S-23S rRNA intergenic spacer sequences

Pseudomonas syringae pv. phaseolicola, which causes halo blight on various legumes, and pv. actinidiae, responsible for canker or leaf spot on actinidia plants, are known as phaseolotoxin producers, and the former possesses phaseolotoxin-resistant ornithine carbamoyltransferase (ROCT) which confers resistance to the toxin. We confirmed that the latter is also resistant to phaseolotoxin and possesses ROCT, and we compared the two pathovars by using sequence data of the ROCT gene and the intergenic spacer region located between the 16S and 23S rRNA genes (16S-23S spacer region) as an index. It was found that the identical ROCT gene (argK) is contained not only in bean isolates of P. syringae pv. phaseolicola in Mexico and the United States but also in bean isolates in Japan and Canada, and that it is also distributed in the kudzu (Pueraria lobata) isolates of P. syringae pv. phaseolicola. Moreover, the kiwifruit and tara vine isolates of P. syringae pv. actinidiae were also found to possess the identical argK. On the contrary, the 16S-23S spacer regions showed a significant level of sequence variation between P. syringae pv. actinidiae and pv. phaseolicola, suggesting that these two pathovars evolved differently from each other in the phylogenetic development. The fact that even synonymous substitution has not occurred in argK among these strains despite their extreme differences in phylogenetic evolution and geographical distribution suggests that it was only recently in evolutionary time that argK was transferred from its origin to P. syringae pv. actinidiae and/or pv. phaseolicola.

Typing of Staphylococcus aureus strains by PCR-amplification of variable-length 16S-23S rDNA spacer regions: characterization of spacer sequences

To develop a rapid and accurate method of typing large numbers of clinical isolates of Staphylococcus aureus, the spacer region C of the rRNA operon [1391-507 (16S-23S)] was enzymically amplified from 322 strains. When the products were separated by denaturing PAGE, 15 variable-length rrn alleles were demonstrated, ranging in size from 906 to 1223 bp. The variable-length HpaII-digested region C [(region E; 1446-196 (16S-23S)] amplification products were cloned into M13mp18RF to sequence separate variable-length alleles. A total of 17 region E inserts were sequenced, aligned and divided into nine alleles by length (938-1174) and sequence properties. The 16S-23S spacer rDNA varied in length (303-551 bp) and in properties; three alleles contained a tRNAIle gene alone, two alleles contained a tRNAIle and a tRNAAla gene, and four alleles lacked tRNA genes. The sequences of two alleles showed less than 1% variation when isolated from two or three S. aureus strains. The 48 penicillin- and methicillin-sensitive strains were divided into 26 ribotypes; in contrast, the 274 methicillin-resistant S. aureus (MRSA) strains were divided into nine ribotypes (A-I) with 97% typing as either ribotype A or B (rrnL was missing in B). The sequence conservation of the rrn operons argues for the use of the 16S-23S spacer region as a stable and direct indicator of the evolutionary divergence of S. aureus strains.

The sequence of the single 16S rRNA gene of the thermophilic eubacterium Rhodothermus marinus reveals a distant relationship to the group containing Flexibacter, Bacteroides, and Cytophaga species

Rhodothermus marinus, a gram-negative heterotrophic marine thermophile, has been the subject of several recent studies. Isolation, sequencing, and analyses of a 16S rRNA gene have shown that R. marinus diverges sharply from major bacterial phyla and is most closely allied to the Flexibacter-Cytophaga-Bacteroides group. Further analyses revealed that the R. marinus chromosome contains a single rRNA operon with a 16S-23S intergenic region coding for tRNA(Ile) and tRNA(Ala).

Analysis of operons encoding 23S rRNA of Clostridium botulinum type A

Southern hybridization analysis of Clostridium botulinum type A chromosomal DNA indicated the presence of six copies of the 23S rRNA gene. Fragments of DNA encoding 23S rRNA were amplified by polymerase chain reaction and cloned in Escherichia coli. Three clones examined by restriction enzyme and sequence analysis were found to be derived from different operons. Sequence determination of the entire insert of two clones revealed nine nucleotide changes in the genes coding for 23S rRNA (99.7% sequence identity) between operons encoded on the same chromosome, showing microheterogeneity in the rRNA operons of this organism.

The flax ribosomal RNA-encoding genes are arranged in tandem at a single locus interspersed by 'non-rDNA' sequences

The ribosomal RNA (rRNA)-encoding genes (rDNA) in flax, estimated to be present in about 2400 copies per diploid nucleus, have been reported as a single homogeneous repeat unit of 8.6 kb. In situ hybridization analysis indicated that these genes were located at a single site on one pair of chromosomes. However, an analysis of a flax variety, CI 1303, has revealed heterogeneity in the intergenic spacer of the rDNA repeat unit. A genetic analysis of rDNA inheritance in two flax lines, Stormont Cirrus and CI 1303, has again supported the observation that there is a single rDNA locus in this plant species. Screening of four different genomic libraries made in methylation-sensitive and -insensitive systems, and the analysis of 40 phage clones, demonstrate a much higher number than that expected of junctions between rDNA and non-rDNA. Direct evidence of rRNA-encoding genes being present in tandem comes from a few phage clones that contain more than two rDNA repeats. The evidence presented here indicates that rDNA, although present at a single locus in tandem arrays, may be interrupted frequently by other non-rDNA sequences, thus giving rise to questions about their organization into long tandem arrays.

DNA sequence of the 3' end of the Caulobacter crescentus 16S rRNA gene

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The 16S rRNA gene of Streptomyces lividans TK64 contains internal promoters

A 632-bp Sau3AI fragment of Streptomyces lividans TK64 genome was found to confer promoter activity in Streptomyces and Escherichia coli. This fragment showed almost identical sequence (97.8%) to the S. coelicolor 16S rRNA segment encompassing from nucleotide 706 to 1337 region. The transcription start points of this fragment were identified by the primer extension method. Analysis of the nucleotide sequence upstream the transcription start points revealed two putative E. coli-like promoters resided within this fragment. The occurrence of internal promoters active in Streptomyces and E. coli was also confirmed in the 16S rRNA gene of rrnE operon from TK64.

Characterization of the Caulobacter crescentus flbF promoter and identification of the inferred FlbF product as a homolog of the LcrD protein from a Yersinia enterocolitica virulence plasmid

We have investigated the organization and expression of the Caulobacter crescentus flbF gene because it occupies a high level in the flagellar gene regulatory hierarchy. The nucleotide sequence comprising the 3' end of the flaO operon and the adjacent flbF promoter and structural gene was determined, and the organization of transcription units within this sequence was investigated. We located the 3' ends of the flaO operon transcript by using a nuclease S1 protection assay, and the 5' end of the flbF transcript was precisely mapped by primer extension analysis. The nucleotide sequence upstream from the 5' end of the flbF transcript contains -10 and -35 elements similar to those found in promoters transcribed by sigma 28 RNA polymerase in other organisms. Mutations that changed nucleotides in the -10 or -35 elements or altered their relative spacing resulted in undetectable levels of flbF transcript, demonstrating that these sequences contain nucleotides essential for promoter function. We identified a 700-codon open reading frame, downstream from the flbF promoter region, that was predicted to be the flbF structural gene. The amino-terminal half of the FlbF amino acid sequence contains eight hydrophobic regions predicted to be membrane-spanning segments, suggesting that the FlbF protein may be an integral membrane protein. The FlbF amino acid sequence is very similar to that of a transcriptional regulatory protein called LcrD that is encoded in the highly conserved low-calcium-response region of virulence plasmid pYVO3 in Yersinia enterocolitica (A.-M. Viitanen, P. Toivanen, and M. Skurnik, J. Bacteriol. 172:3152-3162, 1990).

Novel tRNA gene organization in the 16S-23S intergenic spacer of the Streptococcus pneumoniae rRNA gene cluster

Isoleucine and alanine tRNAs are encoded tandemly within the 16S-23S intergenic spacer of some eubacterial rRNA gene clusters. Southern hybridization analysis and DNA sequence analysis demonstrated a novel gene organization for an rRNA gene cluster on the Streptococcus pneumoniae chromosome. A sequence specifying an alanine tRNA was found within the intergenic spacer, but no sequence specifying an isoleucine tRNA was found there. Southern hybridization analysis indicated that the location of the isoleucine tRNA gene was near the 5S rRNA gene in two of four rRNA gene clusters.

Physical map of the Brucella melitensis 16 M chromosome

We present the first restriction map of the Brucella melitensis 16 M chromosome obtained by Southern blot hybridization of SpeI, XhoI, and XbaI fragments separated by pulsed-field gel electrophoresis. All restriction fragments (a total of 113) were mapped into an open circle. The main difficulty in mapping involved the exceedingly high number of restriction fragments, as was expected considering the 59% G + C content of the Brucella genome. Several cloned genes were placed on this map, especially rRNA operons which are repeated three times. The size of the B. melitensis chromosome, estimated as 2,600 kb long in a previous study, appeared longer (3,130 kb) by restriction mapping. This restriction map is an initial approach to achieve a genetic map of the Brucella chromosome.

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.

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.

Organization of the Haemophilus influenzae Rd genome

We present the first complete map of the Haemophilus influenzae genome, consisting of a detailed restriction map with a number of genetic loci. All of the ApaI, SmaI, and RsrII restriction sites (total of 45 sites) were mapped by Southern blot hybridization analysis of fragments separated by pulsed-field gel electrophoresis. Cloned genes were placed on the restriction map by Southern hybridization, and antibiotic resistance loci were also located by transformation with purified restriction fragments. The attachment site of the HP1 prophage was mapped. In addition, the number, locations, and orientations of the six rRNA operons in the H. influenzae chromosome were determined. The positions of conserved restriction sites in these rrn operons confirm that the direction of transcription is 16S to 23S, as in most other bacteria. The widely used strain BC200 appears to contain an unexpected 45-kilobase duplication.

Temporal regulation and overlap organization of two Caulobacter flagellar genes

The biogenesis of the bacterial flagellum and chemotaxis apparatus in both Escherichia coli and Caulobacter crescentus requires the ordered expression of over 40 genes whose expression is controlled by a trans-acting regulatory hierarchy. In C. crescentus, additional control mechanisms ensure that the transcription of these genes is initiated at the correct time in the cell cycle. We demonstrate here that two flagellar genes, flaE and flaY, whose products function in trans to modulate the level of transcription of other flagellar genes, are themselves temporally controlled. DNA sequence analysis of the 3413 base-pairs encompassing the flaE and flaY coding sequences and the 5' regulatory region showed that flaE encodes a protein of 16,000 Mr and flaY a protein of 17,000 Mr. Evidence that flaE and flaY are transcribed as a polycistronic message includes (1) the polar effect of Tn5 insertions; (2) deletion analysis showing that the flaE promoter is essential for complementation of both flaE and flaY alleles; and (3) nuclease S1 assays showing protection of a transcript spanning both genes. The transcript start site in front of flaE was determined and the -10 region conforms to the E. coli sigma 28 promoter consensus sequence. Nuclease S1 analysis also revealed a protected fragment whose size was consistent with a transcript initiating in vivo at a consensus "nif" promoter sequence in front of the flaY gene. The entire promoter region and an upstream consensus sequence that might be a regulatory element for the flaY gene lies within the carboxyl-terminal coding sequence of the flaE gene.

Rate, origin, and bidirectionality of Caulobacter chromosome replication as determined by pulsed-field gel electrophoresis

Cell division in Caulobacter crescentus yields progeny cells that differ with respect to cell structure and developmental program. Chromosome replication initiates in the daughter stalked cell but is repressed in the daughter swarmer cell until later in the cell cycle. To study cell-type-specific DNA initiation, chromosome replication was directly analyzed by pulsed-field gel electrophoresis. Analysis of Dra I restriction fragments of DNA taken at various times from synchronized cell cultures labeled with 2'-deoxy[3H]guanosine has allowed us to determine the origin of DNA replication, the rate and direction of fork movement, and the order of gene replication. The first labeled Dra I fragment to appear contains the site of replication initiation. Based on the correlation of the physical and genetic maps derived by Ely and Gerardot [Ely, B. & Gerardot, C. J. (1988) Gene 68, 323-333], the origin was localized to a 305-kilobase fragment containing the rrnA gene. Furthermore, the sequential replication through unmapped Dra I fragments has enabled us to localize their positions on the genome. The order of appearance of labeled restriction fragments revealed that the chromosome replicates bidirectionally at a fork movement rate of 21 kilobases per minute.

Use of transmissible plasmids as cloning vectors in Caulobacter crescentus

Cloning vectors for studies of Caulobacter crescentus genes should be transferrable between Escherichia coli and C. crescentus since a transformation system has not been developed for C. crescentus. We have tested a large number of vectors containing IncP or IncQ replicons and found that many of the vectors containing IncQ replicons, and all but one of the vectors containing IncP replicons, are readily transferred by conjugation into C. crescentus. All of the plasmids tested were maintained in C. crescentus at 1 to 5 copies per cell, but plasmids containing IncP replicons were more stable than plasmids containing IncQ replicons. Further studies with a derivative of the IncQ plasmid R300B showed that when a promoterless kanamycin (Km)-resistance gene (npt2) was inserted into the intercistronic region of the sul-aphC (SuR-SmR) operon, Km resistance was expressed only when the npt2 gene was inserted such that it would be transcribed from the sul promoter. These data indicate that R300B does not contain sequences which would provide promoter function in C. crescentus in the orientation opposite to that of the sul operon and that any genes cloned in this orientation would require native promoters for expression. To provide greater versatility for cloning into R300B, additional vectors were constructed by the addition of multiple cloning sites in the intercistronic region of the sul-aphC operon. In addition, chromosomal DNA libraries were constructed in R300B and in the cosmid vector pLAFR1-7. Specific clones from these libraries containing genes of interest were identified by complementation of the appropriate C. crescentus mutants.

Use of pulsed-field-gradient gel electrophoresis to construct a physical map of the Caulobacter crescentus genome

The restriction enzyme DraI cleaves the Caulobacter crescentus genome into at least 35 fragments which have been resolved in agarose gels using pulsed-field-gradient gel electrophoresis (PFGE). When digests were performed using DNA from strains containing Tn5 insertion mutations, altered band migrations were observed. Using PFGE with the appropriate pulse times, size differences as small as 2% could be resolved in large fragments. Using this approach, we have constructed a partial physical map of the genome which correlates well with the C. crescentus genetic map and have shown the size of the genome to be approx. 3800 kb. Using hybridization with cloned genes, we have determined the map locations of five previously unmapped genes. In addition, we have shown that PFGE can be used to rapidly determine the map locations of new insertion mutations or the sizes of deletion mutations.

Transcriptional analysis of the 16S rRNA gene of the rrnD gene set of Streptomyces coelicolor A3(2)

The nucleotide sequence of 2.5 kb of the Streptomyces coelicolor A3(2) rRNA gene set rrnD, extending from upstream of the 16S rRNA gene to the putative 5' end of the 23S rRNA gene, has been determined (Baylis and Bibb, 1987; this paper). In addition to locating the 5' end of the 16S rRNA gene, nuclease S1 mapping identified seven RNA 5' end-points upstream of the 16S rRNA gene; four of these were coincident with transcriptional initiation points for S. coelicolor A3(2) RNA polymerase in vitro and were consequently regarded as in vivo transcription start points for promoters p1 to p4. One end-point identified by nuclease S1 mapping localized a putative processing site analogous to those found upstream of 16S rRNA genes in other eubacteria. Sequence motifs similar to those discovered in low G+C Gram-positive bacteria were found associated with two of the promoters and the processing site. A probable protein coding region was observed upstream of the promoter region.

Characterization of RNA transcripts from the alpha tubulin gene cluster of Leptomonas seymouri

A tandem cluster of alpha tubulin genes was identified in the trypanosomatid protozoan Leptomonas seymouri. One repeat unit and the first gene of the cluster, with its upstream flanking region, were cloned and analyzed for their transcriptional and coding capacities. The 12-15 copies per cell of the 4 kb repeat encode a stable 2 kb transcript, which contains a mini-exon at its 5' end and two closely spaced polyadenylation sites. Transcription of the alpha tubulin gene cluster in isolated nuclei was unidirectional. Intergenic and coding regions were transcribed at the same rate, and nascent intergenic and coding region transcripts were quantitatively linked. These results are consistent with the possibility that the primary transcripts are polycistronic, or that there is a single small intercistronic gap.

Structure of the Caulobacter crescentus trpFBA operon

The DNA sequences of the Caulobacter crescentus trpF, trpB, and trpA genes were determined, along with 500 base pairs (bp) of 5'-flanking sequence and 320 bp of 3'-flanking sequence. An open reading frame, designated usg, occurs upstream of trpF and encodes a polypeptide of 89 amino acids which seems to be expressed in a coupled transcription-translation system. Interestingly, the usg polypeptide is not homologous to any known tryptophan biosynthetic enzyme. S1 nuclease mapping of in vivo transcripts indicated that usg, trpF, trpB, and trpA are arranged into a single operon, with the transcription initiation site located 30 bp upstream from the start of usg. Sequences centered at -30 and -6 bp upstream from the transcription initiation site are somewhat homologous to the Escherichia coli promoter consensus sequence and are homologous to sequences found upstream of genes from several organisms which are evolutionarily related to C. crescentus. Furthermore, the trpFBA operon promoter sequence lacks homology to promoter sequences identified for certain developmentally regulated C. crescentus genes. The structures of the C. crescentus usg, trpF, trpB, and trpA genes were further analyzed in terms of codon usage, G+C content, and genetic signals and were related to genetic signals previously identified in C. crescentus and other bacteria. Taken together, these results are relevant to the analysis of gene expression in C. crescentus and the study of trp gene structure and regulation.

Organisation of the ribosomal RNA genes in Streptomyces coelicolor A3(2)

Using Southern hybridisation of radiolabelled purified ribosomal RNAs to genomic DNA the ribosomal RNA genes of Streptomyces coelicolor A3(2) were shown to be present in six gene sets. Each gene set contains at least one copy of the 5 S, 16 S and 23 S sequences and in at least two cases these are arranged in the order 16 S - 23 S - 5 S. Three gene sets, rrnB, rrnD and rrnF, were isolated by screening a lambda library of S. coelicolor A3(2) DNA. The restriction map of one of these, rrnD, was determined and the nucleotide sequences corresponding to the three rRNAs were localised by Southern hybridisation. The gene order in rrnD is 16 S - 23 S - 5 S.

Ribosomal RNA genes in plants: variability in copy number and in the intergenic spacer

Ribosomal RNA genes in plants are highly variable both in copy number and in intergenic spacer (IGS) length. This variability exists not only between distantly related species, but among members of the same genus and also among members of the same population of a single species. Analysis of inheritance indicates that copy number change is rapid, occurring even among somatic cells of individual plants, and that up to 90% or more of the gene copies are superfluous. Subrepetitive sequences within the IGS appear to be changing rapidly as well. They are not only variable in sequence from one species to the next, but can vary in number between neighboring gene repeats on the chromosome. In all species examined in detail they are located in the same region of the IGS and contain sequences that can be folded into stem-loop structures flanked by a pyrimidine-rich region. It has been suggested that these subrepeats function in transcriptional enhancement, termination or processing, or in recombination events generating the high multiplicity of ribosomal genes.

In vivo translation of a region within the rrnB 16S rRNA gene of Escherichia coli

In this study we show that a segment of the Escherichia coli rrnB 16S gene can be translated in vivo. Other laboratories have previously reported that there are internal transcription and translation signals and open reading frames within the E. coli rrnB rRNA operon. Their studies revealed a translation start signal followed by a 252-base-pair open reading frame (ORF16) within the 16S gene and detected a promoter (p16) in the same general region by using in vitro RNA polymerase binding and transcription initiation assays. By using plasmid gene fusions of ORF16 to lacZ we showed that an ORF16'-'beta-galactosidase fusion protein was made in vivo. Transcripts encoding the fusion protein were expressed either from the rrnB p1p2 control region or from a hybrid trp-lac promoter (tacP), but the amount of expression was considerably less than for a lacZ control plasmid. We used fusions to the cat gene to show that p16 is one-half as active as lacP. Deletions were used to show that p16 is located within ORF16 and thus cannot promote a transcript encoding the ORF16 peptide. A comparison of sequences from different organisms shows that ORF16 and p16 lie in a highly conserved region of the procaryotic 16S RNA structure. The first 20 amino acids of ORF16 are conserved in most eubacterial and plant organellar sequences, and promoter activity has been detected in this region of the Caulobacter crescentus sequence by other workers.

Transcription initiation in vitro and in vivo at a highly conserved promoter within a 16 S ribosomal RNA gene

Transcription initiation has been shown to occur in vitro at several sites within a cloned Caulobacter crescentus ribosomal RNA gene cluster that lacks the major promoter region 5' to the 16 S rRNA gene. The predominant transcription start site in vitro was located near the 3' end of the 16 S rRNA gene. Transcription initiation from this region was also detected in vivo, when the cloned rRNA gene cluster was present on a multi-copy plasmid. The transcription start sites in vitro and in vivo were shown to be identical by S1 nuclease mapping and were found to be located approximately 300 nucleotides upstream from the 3' end of the 16 S rRNA gene. The transcript synthesized in vitro was shown to be cleaved by C. crescentus RNase III and to release the transfer RNA genes from the downstream 16 S/23 S intergenic spacer region. Analysis of the nucleotide sequence near the internal 16 S rRNA transcription start site revealed the presence of a consensus promoter sequence followed by the beginning of an open reading frame approximately 90 nucleotides downstream. Examination of the 16 S rRNA genes from other bacterial species and chloroplasts and 18 S rRNA genes from Xenopus and yeast revealed that the nucleotide sequence of this internal 16 S rRNA promoter region was highly conserved. Although the length of these 16 S and 18 S rRNA genes is slightly variable, the distance of the conserved promoter sequence from the 3' end of these genes has been conserved.