Postmaturational cleavage of 23s ribosomal ribonucleic acid and its metabolic control in the blue-green alga Anacystis nidulans

Distinct and redundant functions of three homologs of RNase III in the cyanobacterium Synechococcus sp. strain PCC 7002

RNase III is a ribonuclease that recognizes and cleaves double-stranded RNA. Across bacteria, RNase III is involved in rRNA maturation, CRISPR RNA maturation, controlling gene expression, and turnover of messenger RNAs. Many organisms have only one RNase III while others have both a full-length RNase III and another version that lacks a double-stranded RNA binding domain (mini-III). The genome of the cyanobacterium Synechococcus sp. strain PCC 7002 (PCC 7002) encodes three homologs of RNase III, two full-length and one mini-III, that are not essential even when deleted in combination. To discern if each enzyme had distinct responsibilities, we collected and sequenced global RNA samples from the wild type strain, the single, double, and triple RNase III mutants. Approximately 20% of genes were differentially expressed in various mutants with some operons and regulons showing complex changes in expression levels between mutants. Two RNase III's had a role in 23S rRNA maturation and the third was involved in copy number regulation one of six native plasmids. In vitro, purified RNase III enzymes were capable of cleaving some of the known Escherichia coli RNase III target sequences, highlighting the remarkably conserved substrate specificity between organisms yet complex regulation of gene expression.

Mobile elements in a single-filament orange Guaymas Basin Beggiatoa ("Candidatus Maribeggiatoa") sp. draft genome: evidence for genetic exchange with cyanobacteria

The draft genome sequence of a single orange Beggiatoa ("Candidatus Maribeggiatoa") filament collected from a microbial mat at a hydrothermal site in Guaymas Basin (Gulf of California, Mexico) shows evidence of extensive genetic exchange with cyanobacteria, in particular for sensory and signal transduction genes. A putative homing endonuclease gene and group I intron within the 23S rRNA gene; several group II catalytic introns; GyrB and DnaE inteins, also encoding homing endonucleases; multiple copies of sequences similar to the fdxN excision elements XisH and XisI (required for heterocyst differentiation in some cyanobacteria); and multiple sequences related to an open reading frame (ORF) (00024_0693) of unknown function all have close non-Beggiatoaceae matches with cyanobacterial sequences. Sequences similar to the uncharacterized ORF and Xis elements are found in other Beggiatoaceae genomes, a variety of cyanobacteria, and a few phylogenetically dispersed pleiomorphic or filamentous bacteria. We speculate that elements shared among filamentous bacterial species may have been exchanged in microbial mats and that some of them may be involved in cell differentiation.

RNA helicases in cyanobacteria: biochemical and molecular approaches

RNA helicases are associated with every aspect of RNA metabolism and function. A diverse range of RNA helicases are encoded by essentially every organism. While RNA helicases alter gene expression, RNA helicase expression is itself regulated, frequently in response to abiotic stress. Photosynthetic cyanobacteria present a unique model system to investigate RNA helicase expression and function. This chapter describes methodology to study the expression and cellular localization of RNA helicases, providing insights into the metabolic pathway(s) in which these enzymes function in cyanobacteria. The approaches are applicable to other systems as well.

Bacterial ribosomal RNA in pieces

The exact knowledge on the ribosomal RNA (rRNA) structure is an important prerequisite for work with rRNA sequences in bioinformatic analyses and in experimental research. Most available rRNA sequences of bacteria are based on gene sequences and on similarity analyses using Escherichia coli rRNA as a standard. Therefore, it is often overlooked that many bacteria harbour mature rRNA 'in pieces'. In some cases, the processing steps during the fragmentation lead to the removal of rRNA segments that are usually found in the ribosome. In this review, the current knowledge on the mechanisms of rRNA fragmentation and on the occurrence of fragmented rRNA in bacteria is summarized, and the physiological implications of this phenomenon are discussed.

Intervening sequences in rrl genes and fragmentation of 23S rRNA in genera of the family Enterobacteriaceae

Intervening sequences (IVSs) in the rrl genes for 23S rRNA are transcribed but later removed by RNase III without religation during RNA processing, leading to fragmented rRNA. We examined about 240 strains of the family Enterobacteriaceae for presence of IVSs using PCR. No IVSs were detected in strains belonging to Escherichia, Shigella, Enterobacter, Erwinia, Ewingella, Hafnia, Kluyvera, Morganella, Pantoea, or Serratia. Previously unreported IVSs were detected in Klebsiella oxytoca, Citrobacter amalonaticus, and Providencia stuartii; previously reported IVSs are in species of Salmonella, Proteus, Providencia, and Yersinia. The sporadic distribution of IVSs indicates lateral genetic transfer of IVSs.

Sequence diversity of intervening sequences (IVSs) in the 23S ribosomal RNA in Salmonella spp

Intervening sequences (IVSs) occur sporadically in the rrl (ribosomal RNA large) genes for 23S ribosomal RNA (rRNA) at helix-25 (base pair 550) and helix 45 (base pair 1170) in several bacterial genera, including Salmonella, Yersinia, Proteus, and Providencia, representing the Enterobacteriaceae, but are missing from other genera such as Escherichia. These sequences are transcribed, but later excised without re-ligation during RNaseIII processing of the rRNA, resulting in fragmented 23S rRNA. The IVSs from 22 strains of the SARB (Salmonella Reference Collection B) set were amplified by PCR and sequenced.IVSs with 90% or more sequence identity were placed in the same family; Salmonella has three families of IVSs in helix-25 (A, B, and C) and two in helix-45 (M and O). The rRNA secondary structure for the IVSs predicted from the mfold program reveals a primary stem of about 14bp, which is the postulated RNaseIII cleavage site, and a secondary region of stems and loops. The primary stem is considerably well conserved, with a high rate of compensatory mutations (positional covariants), confirming the reality of the secondary structure and indicating that removal of the IVSs exerts a positive selective pressure to retain the secondary structure. The pattern of possession and presence of families of IVSs was diverse and could not be related to the proposed ancestry of the strains as revealed by the multi-locus enzyme electrophoresis pattern of the strains, suggesting that the IVSs are transferred between strains by lateral transfer. Helix-25 IVSs from families A, B, and C of Salmonella and D of Proteus, which share almost identical primary stems, are placed in superfamily I, while the primary stems of other IVSs from Proteus and Providencia are unrelated to superfamily I and are thus placed into superfamily II; this indicates lateral transfer of members of superfamily I between Proteus and Salmonella, but an independent origin of IVSs of superfamily II in Proteus and Providencia.

Aspects of the relation between Cyanophora paradoxa (Korschikoff) and its endosymbiotic cyanelles Cyanocyta korschikoffiana (Hall & Claus) - III. Characterization of ribosomal ribonucleic acids

Analysis of ribosomal RNA from Cyanophora paradoxa (Korschikoff) demonstrated the existence of four species. Two species, 25 S and 18 S r-RNA, are characteristic of the host, while two other species, 23 S and 16 S , are characteristic of the endosymbiotic cyanelles, Cyanocyta korschikoffiana (Hall & Claus). The 23 S r-RNA from C. korschikoffiana was found to be labile and yielded degradation patterns resembling those seen in some chloroplast r-RNA preparations.

Cloning of a gene involved in rRNA precursor processing and 23S rRNA cleavage in Rhodobacter capsulatus

In Rhodobacter capsulatus wild-type strains, the 23S rRNA is cleaved into [16S] and [14S] rRNA molecules. Our data show that a region predicted to form a hairpin-loop structure is removed from the 23S rRNA during this processing step. We have analyzed the processing of rRNA in the wild type and in the mutant strain Fm65, which does not cleave the 23S rRNA. In addition to the lack of 23S rRNA processing, strain Fm65 shows impeded processing of a larger 5.6-kb rRNA precursor and slow maturation of 23S and 16S rRNAs from pre-23S and pre-16S rRNA species. Similar effects have also been described previously for Escherichia coli RNase III mutants. Processing of the 5.6-kb precursor was independent of protein synthesis, while the cleavage of 23S rRNA to generate 16S and 14S rRNA required protein synthesis. We identified a DNA fragment of the wild-type R. capsulatus chromosome that conferred normal processing of 5.6-kb rRNA and 23S rRNA when it was expressed in strain Fm65.

Atypical structure of the 23S ribosomal RNA molecule in certain oral bacteria

Ribosomal RNA (rRNA) isolated from Wolinella recta and seven related bacteria was examined by agarose gel electrophoresis. The 23S rRNA molecule could not be detected in W. recta, Wolinella curva, Bacteroides gracilis, or Bacteroides ureolyticus. In place of the 23S molecule, there were three smaller molecules of approximately 1700, 650, and 600 bases designated 23S alpha, 23S beta, and 23S delta, respectively. An intact 23S rRNA molecule could be isolated from Wolinella succinogenes, Campylobacter concisus, and Campylobacter sputorum. The cleavage sites of the W. recta 23S rRNA molecule were located by direct RNA sequence analysis and were found to be in similar locations, nucleotides 546 and 1180, as cleavage sites described in other prokaryotes. The presence or absence of the 23S rRNA molecule may be a useful marker for these micro-organisms.

16S rRNA sequences of uncultivated hot spring cyanobacterial mat inhabitants retrieved as randomly primed cDNA

Cloning and analysis of cDNAs synthesized from rRNAs is one approach to assess the species composition of natural microbial communities. In some earlier attempts to synthesize cDNA from 16S rRNA (16S rcDNA) from the Octopus Spring cyanobacterial mat, a dominance of short 16S rcDNAs was observed, which appear to have originated only from certain organisms. Priming of cDNA synthesis from small ribosomal subunit RNA with random deoxyhexanucleotides can retrieve longer sequences, more suitable for phylogenetic analysis. Here we report the retrieval of 16S rRNA sequences from three formerly uncultured community members. One sequence type, which was retrieved three times from a total of five sequences analyzed, can be placed in the cyanobacterial phylum. A second sequence type is related to 16S rRNAs from green nonsulfur bacteria. The third sequence type may represent a novel phylogenetic type.

The excision of intervening sequences from Salmonella 23S ribosomal RNA

Novel, approximately 90 bp intervening sequences (IVs) were discovered within the 23S rRNA genes of S. typhimurium and S. arizonae. These non-rRNA sequences are transcribed and then excised during rRNA maturation. The rRNA fragments that result from the excision of the extra sequences are not religated. This results in fragmented 23S rRNAs. The excision of one IVS was shown to be catalyzed in vivo and in vitro by ribonuclease III. These IVSs are highly volatile evolutionarily, sometimes occurring in only some of the multiple rRNA operons of a particular cell. The sporadic nature of the occurrence of fragmented rRNAs among closely related organisms argues that such fragmentation is a derived state, not a primitive one. Possible sources of these IVSs, their parallels with internal transcribed spacers and introns in eukaryotes, and their possible roles in the evolutionary process are discussed.

A method for RNA isolation from marine macro-algae

Sulfated, carboxylic polysaccharides and polyphenols found in marine macro-algae interfere with RNA isolation from these plants and inhibit RNA activities in vitro. Methods based on differential precipitation of RNA or carbohydrates in high salts were used to eliminate the acidic carbohydrates. To protect RNA from inactivation by oxidized polyphenols, strong reducing reagents were used to prevent polyphenol oxidation. RNA was successfully isolated from Macro-cystis pyrifera (brown alga), Porphyra schizophylla (red alga), and Enteromorpha intestinalis (green alga). mRNA isolated from the total RNA was shown to be translationally active.

Unusual pattern of ribonucleic acid components in the ribosome of Crithidia fasciculata, a trypanosomatid protozoan

In a previous study from this laboratory, presumptive ribosomal ribonucleic acid (RNA) species were identified in the total cellular RNA directly extracted from intact cells of the trypanosomatid protozoan Crithidia fasciculata (M. W. Gray, Can. J. Biochem. 57:914-926, 1979). The results suggested that the C. fasciculata ribosome might be unusual in containing three novel, low-molecular-weight ribosomal RNA components, designated e, f, and g (apparent chain lengths 240, 195, and 135 nucleotides, respectively), in addition to analogs of eucaryotic 5S (species h) and 5.8S (species i) ribosomal RNAs. In the present study, all of the presumptive ribosomal RNAs were indeed found to be associated with purified C. fasciculata ribosomes, and their localization was investigated in subunits produced under different conditions of ribosome dissociation. When ribosomes were dissociated in a high-potassium (880 mM K+, 12.5 mM Mg2+) medium, species e to i were all found in the large ribosomal subunit, which also contained an additional, transfer RNA-sized component (species j). However, when subunits were prepared in a low-magnesium (60 mM K+, 0.1 mM Mg2+) medium, two of the novel species (e and g) did not remain with the large subunit, but were released, apparently as free RNAs. Control experiments have eliminated the possibility that the small RNAs are generated by quantitative and highly specific (albeit artifactual) ribonuclease cleavage of large ribosomal RNAs during isolation. In terms of RNA composition and dissociation properties, therefore, the ribosome of C. fasciculata is the most "atypical" eucaryotic ribosome yet described. These observations raise interesting questions about the function and evolutionary origin of C. fasciculata ribosomes and about the organization and expression of ribosomal RNA genes in this organism.

On the evolution of ribosomal RNA

Despite the availability of a rapidly growing ribosomal RNA database that now includes organisms in all three primary lines of descent (eubacteria, archaebacteria, and eukaryotes), theoretical treatment of the evolution of the ribosomal RNAs has lagged behind that of the protein genes. In this paper a theory is developed that applies current views of protein gene evolution to the ribosomal RNAs. The major topics addressed are the variability in size, gene arrangement, and processing of the rRNAs among the three primary lines of descent. Among the conclusions are that the rRNAs of eukaryotes retain some primitive features that were probably present in the rRNAs of the earliest cell (the progenote) and that the genes coding for the three major rRNA species were probably originally unlinked.

Complete nucleotide sequence of the 23S rRNA gene of the Cyanobacterium, Anacystis nidulans

The nucleotide sequence of the Anacystis nidulans 23S rRNA gene, including the 5'- and 3'-flanking regions has been determined. The gene is 2876 nucleotides long and shows higher primary sequence homology to the 23S rRNAs of plastids (84.5%) than to that of E. coli (79%). The predicted rRNA transcript also shares many secondary structural features with those of plastids, reinforcing the endosymbiont hypothesis for the origin of these organelles.

Polyadenylated mRNA from the photosynthetic procaryote Rhodospirillum rubrum

Total cellular RNA extracted from Rhodospirillum rubrum cultured in butyrate-containing medium under strict photosynthetic conditions to the stationary phase of growth has been fractionated on an oligodeoxythymidylic acid-cellulose column into polyadenylated [poly(A)+] RNA and poly(A)- RNA fractions. The poly(A)+ fraction was 9 to 10% of the total bulk RNA isolated. Analysis of the poly(A)+ RNA on a denaturing urea-polyacrylamide gel revealed four sharp bands of RNA distributed in heterodisperse fashion between 16S and 9S. Similar fractionation of the poly(A)- RNA resulted in the separation of 23, 16, and 5S rRNAs and 4S tRNA. Poly(A)+ fragments isolated after combined digestion with pancreatic A and T1 RNases and analysis by denaturing gel electrophoresis demonstrated two major components of 80 and 100 residues. Alkaline hydrolysis of the nuclease-resistant, purified residues showed AMP-rich nucleotides. Through the use of snake venom phosphodiesterase, poly(A) tracts were placed at the 3' end of poly(A)+ RNA. Stimulation of [3H]leucine incorporation into hot trichloroacetic acid-precipitable polypeptides in a cell-free system from wheat germ primed by the poly(A)+ RNA mixture was found to be 220-fold higher than that for poly(A)- RNAs (on a unit mass basis), a finding which demonstrated that poly(A)+ RNAs in R. rubrum are mRNAs. Gel electrophoretic analysis of the translation mixture revealed numerous 3H-labeled products including a major band (Mr, 52,000). The parent protein was precipitated by antibodies to ribulose bisphosphate carboxylase-oxygenase and comprised 6.5% of the total translation products.

Hidden breaks in ribosomal RNA of phylogenetically tetraploid fish and their possible role in the diploidization process

Hidden breaks occur in the ribosomal RNA of tetraploid Cyprinid fish such that the large ribosomal RNA (28 S) yields upon denaturation two RNA fragments of 8.7 X 10(5) and 5.0 X 10(5) daltons, whereas the small rRNA (18 S) yields fragments of 3.2 X 10(5) to 5.0 X 10(4) daltons. In tetraploid Cyprinids hidden breaks occur only in the rRNA of somatic tissue and not in oocytes and sperm cells. Hidden breaks can be detected only slightly in diploid Cyprinid species. Ribosomes purified from somatic tissue of tetraploid Cyprinids show a reduced efficiency in protein synthesis in vitro. The ribosomal proteins from diploid and tetraploid Cyprinid fish show considerable electrophoretic differences. This is discussed in light of a possible functional role of hidden breaks in rRNA in the process of diploidization of gene expression in tetraploid Cyprinid species.

Processing of the ribonucleic acid in the large ribosomal subunits of Urechis caupo

Ribosomal subunits were isolated from eggs or embryos of Urechis caupo, and the ribonucleic acid (RNA) was characterized by electrophoresis under denaturing conditions. The small ribosomal subunit contains a single 17S RNA sequence with a molecular weight of 6.20 X 10(5). The large ribosomal subunit contains four polynucleotide sequences. The 5S RNA has a molecular weight of 4.09 X 10(4). The 26S RNA complex isolated under nondenaturing conditions dissociates in the presence of formamide to yield a 5.8S RNA, molecular weight 5.46 X 10(4), and two approximately 17S and 17.5S RNA sequences with molecular weights of 6.04 X 10(5) and 6.61 X 10(5). The 17S and 17.5S RNAs of the large ribosomal subunits are formed in vivo from a 26S RNA precursor after assembly of the large ribosomal subunit. Large ribosomal subunits are transferred from the nucleus to the cytoplasm with the 26S RNA precursor intact. The hidden break to form the 17S and 17.5S RNAs is introduced in the cytoplasm. No intact 26S RNA could be detected in polysomes; this indicates that the conversion of the 26S RNA to the 17S and 17.5S RNAs may be required to produce large ribosomal subunits capable of participating in protein synthesis.

Unusual pattern of ribonucleic acid components in the ribosome of Crithidia fasciculata, a trypanosomatid protozoan

In a previous study from this laboratory, presumptive ribosomal ribonucleic acid (RNA) species were identified in the total cellular RNA directly extracted from intact cells of the trypanosomatid protozoan Crithidia fasciculata (M. W. Gray, Can. J. Biochem. 57:914-926, 1979). The results suggested that the C. fasciculata ribosome might be unusual in containing three novel, low-molecular-weight ribosomal RNA components, designated e, f, and g (apparent chain lengths 240, 195, and 135 nucleotides, respectively), in addition to analogs of eucaryotic 5S (species h) and 5.8S (species i) ribosomal RNAs. In the present study, all of the presumptive ribosomal RNAs were indeed found to be associated with purified C. fasciculata ribosomes, and their localization was investigated in subunits produced under different conditions of ribosome dissociation. When ribosomes were dissociated in a high-potassium (880 mM K+, 12.5 mM Mg2+) medium, species e to i were all found in the large ribosomal subunit, which also contained an additional, transfer RNA-sized component (species j). However, when subunits were prepared in a low-magnesium (60 mM K+, 0.1 mM Mg2+) medium, two of the novel species (e and g) did not remain with the large subunit, but were released, apparently as free RNAs. Control experiments have eliminated the possibility that the small RNAs are generated by quantitative and highly specific (albeit artifactual) ribonuclease cleavage of large ribosomal RNAs during isolation. In terms of RNA composition and dissociation properties, therefore, the ribosome of C. fasciculata is the most "atypical" eucaryotic ribosome yet described. These observations raise interesting questions about the function and evolutionary origin of C. fasciculata ribosomes and about the organization and expression of ribosomal RNA genes in this organism.

The number, physical organization and transcription of ribosomal RNA cistrons in an archaebacterium: Halobacterium halobium

Because it is now clear that archaebacteria may be as distinct from eubacteria as either group is from eukaryotic cells, and because a specifically archaebacterial ancestry has been proposed for the nuclear-cytoplasmic component of eukaryotic cells, we undertook to characterize, for the first time, the ribosomal RNA cistrons of an archaebacterium (Halobacterium halobium). We found these cistrons to be physically linked in the order 16S-23S-5S, and obtained evidence that they are also transcribed from a common promoter(s) in the order 5'-16S-23S-5S-3'. We showed that, although slightly larger immediate precursors of 16S and 23S are readily seen, no common precursor of both 16S and 23S can be easily detected in vivo. In all these respects the archaebacterium H. halobium is like a eubacterium and unlike the nuclear-cytoplasmic component of eukaryotic cells. We found, however, that it differs from eubacteria of comparable (large) genome size in having only one copy of the rRNA gene cluster per genome.

Ribosomal ribonucleic acid isolated from Salmonella typhimurium: absence of the intact 23S species

Ribonucleic acid (RNA) isolated by four distinct methods and from a variety of Salmonella typhimurium strains lacked intact 23S ribosomal RNA (rRNA). On sucrose gradients which minimize aggregation, the vast majority of S. typhimurium rRNA sedimented as a 16S peak with a 14S shoulder. RNA from this region of the gradient was resolved into three discrete bands by electrophoresis in formamide. Two very minor S. typhimurium RNA peaks were resolved at 21S and 10S on sucrose gradients, and each peak formed discrete bands in electrophoresis. It is concluded that if S. typhimurium does possess an intact 23S rRNA species, this species is extremely "labile." The absence of isolatable S. typhimurium 23S rRNA possibly reflected in vivo processing of the rRNA before isolation. Under certain conditions, S. typhimurium rRNA formed discrete aggregates which sedimented similarly to intact Escherichia coli 23S rRNA.

Preservation of algal and higher plant ribosomal RNA integrity during extraction and electrophoretic quantitation

Isolation of high molecular weight ribosomal RNA from the wall-less alga Olisthodiscus luteus and the angiospermous plant Sauromatum guttatum is described. It has been found that a buffer which contains magnesium must be used to successfully isolate Olisthodiscus rRNA whereas the isolation of intact Sauromatum rRNA requires a buffer system containing a high amount of the chelator EDTA. Sauromatum but not Olisthodiscus extracts were contaminated with ribonuclease unless the inhibitor diethylpyrocarbonate was used during the ribonucleic acid extraction procedure. Nuclease levels were monitored by coincubating [3H]-labeled Escherichia coli ribosomal RNA with the experimental RNA samples. The effects of detergents on the isolation and quantitation of RNA are presented, and methods to avoid loss of highly thermolabile plant ribosomal RNA species are discussed.

Genetics of Rhodospirillaceae

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Ribosomal ribonucleic acid synthesis by virulent Treponema pallidum

Ribosomal ribonucleic acid (rRNA) synthesis by virulent Treponema pallidum was monitored by incorporation of [(3)H]uridine into trichloroacetic acid-precipitable counts and examination of radiolabeled rRNA on polyacrylamide gels. Verification that rRNA synthesis originated with T. pallidum was based upon co-electrophoresis with Escherichia coli rRNA, proportionate reductions in the amount of rRNA synthesized when numbers of treponemes were decreased, and inclusion of appropriate animal cell controls. The rate of treponemal rRNA synthesis was greater at temperatures of 37 and 39 degrees C than at 33 degrees C; rRNA synthesis was inhibited at 4 and 42 degrees C and was effectively inhibited by actinomycin D. Kinetic experiments indicated that the majority of rRNA synthesis occurred early after extraction of treponemes from infected rabbit testicular tissue. Polyacrylamide gel profiles demonstrated the capacity of virulent T. pallidum to synthesize and process RNA to 23s, 16s, and 4 to 5s classes. Although motility of T. pallidum appeared unaffected during longer periods of incubation, pulselabeling experiments confirmed significant reductions in the rate of rRNA synthesis. When the effect of various environmental conditions upon rRNA synthesis was investigated, optimal synthesis was found to occur in an atmosphere of 20% oxygen whereas virtually no synthesis was observed under anaerobic or low-oxygen conditions.

Isolation and characterization of 32P-labeled mitochondrial and cytosol ribosomal RNA from germinating wheat embryos

With the aim of preparing highly labeled material, the incorporation of [32P]-orthophosphate into mitochondral and cytosol ribosomal RNA was examined in germinating wheat embryos. Nucleic acids were extracted from mitochondria and from post-mitochondrial supernatant (cytosol) prepared from homogenates of viable embryos (8g) imbibed for 24h in a medium containing [32P]orthophosphate (100mCi). High-molecular-weight ribosomal RNA was selectively precipitated in the presence of 3M NaCl and was further resolved on sucrose density gradients and polyacrylamide gels. Both the mitochondrial and cytosol NaCl-insoluble RNA fractions were found to contain two major radioactive components, corresponding to the large (26S) and small (18S)rRNA species. On non-denaturing gels, these species had apparent molecular weights of 1.3 and 0.67 million daltons (cytosol) and 1.3 and 0.75 million daltons (mitochondrial). The individual, purified [32P]rRNA components (isolated from sucrose gradients) had specific activities of 2--3-10(6) cpm/A260 unit, and were suitable for analysis of nucleotide composition and sequence. By hydrolyzing the individual [32P]rRNA specimens with purified snake venom phosphodiesterase and resolving the products by two-dimensional paper chromatography, it was possible to determine the specific activities (cpm/micronmol) of the four major 5'-nucleotide constituents. The results indicated that there had been no differential 32P-labeling of the nuclear and mitochondrial pools of ribonucleoside 5'-triphosphates (rNTP) during the 24 h imbibition period; however, as previously observed in this system (Lau, R.Y., Kennedy, T.D. and Lane, B.G. (1974) Can. J. Biochem. 52, 1110--1123), there had been unequal 32P-labeling of the individual rNTPs in both the mitochondria and nucleus. The relative specific activities of the 5'-nucleotide constituents of the mitochondrial and cytosol rRNA species were essentially the same, and in the order pA congruent to pU greater than pG greater than pC. By making suitable corrections for these differences in specific activity, the nucleotide composition of each of the [32P]rRNA specimens could be calculated...

Structure, synthesis, and post-transcriptional modification of ribosomal ribonucleic acid in Bdellovibrio bacteriovorus

The structure, synthesis, and post-transcriptional modifications of 23-S and 16-S ribosomal RNAs (rRNAs) have been studied in the facultatively parasitic bacterium, Bdellovibrio bacteriovorus. The mature 23-S and 16-S type of rRNAs in Bdellovibrio are larger than the analogous molecules in Escherichia coli by at least 1.0 - 10(5) and 0.5 - 10(5) daltons, respectively, and have a conformation different from E. coli rRNAs as judged by relative electrophoretic mobilities in polyacrylamide gels with and without denaturing conditions. Studies on the kinetics of synthesis and maturation of ribosomal RNA in Bdellovibrio show that precursor forms analogous to p23-S and p16-S in E. coli are synthesized. In addition, some earlier precursor rRNAs in Bdellovibrio are seen that appear analogous to the 25S and 17.5-S pre-rRNAs that have only been observed in the RNAase III deficient mutant of E. coli strain AB301-105 (Nikolaev, Birenbaum, M. and Schlessinger, D. (1975) Biocheim, Biophys. Acta 395, 478-489). These early precursor stages have not been observed in other procaryotic species, including E. coli that have normal levels of RNAase III. The results from the Bdellovibrio system provide that the 25-s and 17.5-S pre-rRNAs are normal stages of rRNA modification and are part of a multiple step maturation process, and therefore are not aberrations associated with the RNase III deficient mutation.

The postmaturational cleavage of 23 S ribosomal RNA in Anacystis nidulans is inhibited by infection with cyanophage AS-1

The 23S (1.1 X 10(6) mol.wt.) rRNA of Anacystis nidulans undergoes postmaturational cleavage to produce 0.9 X 10(6) and 0.2 X 10(6) molecular species. We have provided evidence in double labelling experiments, in which we could distinguish between the fate of molecules synthesized before and after infection, respectively, that infection with cyanophage AS-1 abruptly and completely inhibits the cleavage of 23S rRNA in Anacystis cells.

Nonribosomal nature of novel, stable ribonucleic acid species accumulated by blue-green bacteria

The facultatively chemoheterotrophic blue-green bacterium Aphanocapsa 6714 accumulates two novel, stable ribonucleic acid species when deprived of sources of carbon and energy. At least one of these species is nonribosomal.

Leucine biosynthesis in the blue-green bacterium Anacystis nidulans

Leucine-requiring auxotrophs of the unicellular blue-green bacterium Anacystis nidulans have been isolated. Extracts of these mutants were deficient in alpha-isopropylmalate synthetase (EC 4.1.3.12). In wild-type cells, this enzyme was subject to feedback inhibition by leucine. However, formation of the enzymes of leucine biosynthesis was little affected by exogenous leucine in either wild-type or mutant strains. Cultures of the latter subjected to extreme leucine deprivation showed no change in specific activity of beta-isopropylmalate isomerase (EC 4.2.1.33) and at most a 50% increase in the specific activity of beta-isopropylmalate dehydrogenase (EC 1.1.1.85). These results are compared with others bearing on the evolution of the control of amino acid biosynthesis in blue-green bacteria.

Mutational analysis of dark endogenous metabolism in the blue-green bacterium Anacystis nidulans

We describe a mutant (strain 704) of the obligate photoautotroph Anacystis nidulans which behaves like the wild type under continuous illumination but which in the dark rapidly loses viability, respires little, and incorporates label into ribonucleic acid and protein at rates considerably less than observed with the darkened wild type. Extracts of this mutant strain show no detectable 6-phosphogluconate dehydrogenase (EC 1.1.1.44) activity. Spontaneous revertants of mutant 704 were selected as survivors of prolonged incubation in darkness. Of 10 such strains examined, none had regained 6-phosphogluconate dehydrogenase activity, and all had lost detectable glucose-6-phosphate dehydrogenase (EC 1.1.1.49) activity. Although dark survival of these revertants paralleled that of the wild type, rates of dark endogenous respiration and incorporation of labeled precursors into ribonucleic acid were still very low, comparable to those observed with strain 704. These results are consistent with the following hypotheses concerning dark endogenous metabolism in unicellular blue-green bacteria. (i) Although the oxidative pentose phosphate cycle (hexose monophosphate shunt) may play a major role in endogenous metabolism in A. nidulans, as proposed by others, it is not the only pathway capable of providing energy for maintenance of viability in darkness. (ii) Much of the endogenous metabolic activity (respiration and macromolecular synthesis) observed in darkened cultures of wild-type A. nidulans is not required for survival alone, and must therefore serve other functions.

Novel ribonucleic acid species accumulated in the dark in the blue-green alga Anacystis nidulans

In the dark, the obligately photoautotrophic blue-green alga Anacystis nidulans accumulates large relative amounts of two novel stable ribonucleic acid species (RNAs). These species are also made in illuminated cells but are unstable in them. When darkened cells are reilluminated, these RNAs are rapidly degraded; degradation is inhibited by chloramphenicol. Upon denaturation with heat or urea, one novel species (0.33 x 10(6) daltons) dissociates into two fragments that comigrate with the second novel species (0.16 x 10(6) daltons) on polyacrylamide gels. Both RNAs are associated with particles sedimenting between 30S and 50S through sucrose gradients and are removed from these particles at low magnesium concentration. The function(s) of these RNAs remains unknown.

Precursor of 5S ribosomal ribonucleic acid in the blue-green alga Anacystis nidulans

The maturation of 5S ribosomal ribonucleic acid (rRNA) in the obligately photoautotrophic unicellular blue-green alga Anacystis nidulans has been studied by using polyacrylamide gel electrophoresis and T1 ribonuclease oligonucleotide analysis. A. nidulans mature 5S rRNA (m5) is of approximately the same molecular weight as the 5S rRNA of Escherichia coli, and is derived by cleavage of a precursor (p5) containing a few (three to six) additional nucleotides. Some of these additional nucleotides occur at the 5' end of the precursor molecule; others may occur at the 3' end. Kinetic experiments indicate that precursors of mature 5S rRNA larger than p5 either do not exist or are very transient in A. nidulans. These results are discussed in relation to those obtained with other prokaryotes.