Erythromycin resistant mutants of Bacillus subtilis

Summary Erythromycin resistant (ery ^r) mutants were isolated from Bacillus subtilis ATCC 6633. The composition of ribosomal proteins were analyzed for thirteen such ery ^r-mutants with chromatography on a carboxymethyl cellulose (CMC) column. The 50s subunit from all of the ery ^r-mutants was found to contain the altered 50d protein. The ribosomes prepared from the ery ^r-mutants did not show in vitro alteration of the ability to combine with erythromycin.     

Genetic studies of the ribosomal proteins in Escherichia coli. I. Mutants and strains having 30s ribosomal subunit with altered protein components

Summary Two 30s ribosomal protein components, 30-4_K and 30-7_K, from E. coli K12 strain were clearly distinguished on the CMC column chromatogram from the corresponding protein components, 30-4_B and 30-7_B, from B strain. The 30-7_K component was shown to correspond to the K-character.A mutant strain of K12, W3637, had an altered 30s ribosomal protein component, 30-9_W3637.The characters of 30-4_K, 30-7_K, 30-9_W3637 and str ^r were found to be cotransduced from W3637 to B strain by Plke phage in 16 out of 20 str ^r transductants. The 30-9_W3637 and 30-4_K components were separated from str ^r in 4 str ^r transductants. These results indicate that (1) neither 30-4 nor 30-9 is the protein whose mutational change leads to str ^r, and (2) the genes specifying the 30s ribosomal proteins, 30-4, 30-7, 30-9 and str are linked on the chromosome.Abbreviations used CMC carboxymethyl cellulose - str streptomycin     

Genetic studies of the ribosomal proteins in Escherichia coli. 7. Mapping of several ribosomal protein components by transduction experiments between different strains of Escherichia coli

Summary Two 50s (50-10 and 50-12) and two 30s (30-4 and 30-7) ribosomal proteins could be distinguished between Shigella dysenteriae Sh/s and Escherichia coli K-12 JC411 with CMC column chromatography. On the other hand, E. coli K-12 AT2472 was shown to have a 30s ribosomal protein, 30-6(AT), which is specific to this strain and distinguishable from 30-6 of other E. coli K-12 strains. Transduction experiments by phage Plkc between Sh. dysenteriae Sh/s and E. coli ATSPCO1, a spectinomycin resistant mutant derived from AT2472 in which the 30-4 protein is altered, indicated that the genes specifying the above five ribosomal protein components are located in the streptomycin region on the E. coli chromosome.The gene order for three 50s (50-8, 50-10 and 50-12) and three 30s [str (30-?), 30-4 and 30-6] ribosomal proteins on the chromosome was determined by transduction technique between Sh. dysenteriae Sh/s and E. coli ATSPC01, between E. coli ATSPC01 and E. coli ER05 (an erythromycin resistant strain in which the 50-8 protein is altered), and between Sh. dysenteriae Sh/s and E. coli ERSPC14 (str ^s spc ^r ery ^r), respectively. It was found that these protein genes are arranged on the chromosome in the order of str (30-?)-30-4-30-6-50-8-50-10-50-12.     

Genetic studies of the ribosomal proteins in Escherichia coli. 8. Mapping of ribosomal protein components by intergeneric mating experiments between Serratia marcescens and Escherichia coli

Summary Ribosomal protein compositions of Serratia marcescens and Escherichia coli K12 were analyzed by using carboxymethyl cellulose column chromatography. Nine 50S and nine 30S ribosomal proteins of E. coli K12 could be distinguished from those of S. marcescens on the chromatogram.Episomes of E. coli K12, which cover the streptomycin(str) region of the chromosome, were transferred to S. marcescens. Chromatographic analyses were made on the ribosomal proteins extracted from these hybrid strains. At least nine 30S and six 50S ribosomal proteins of E. coli-type could be detected in the ribosomes of the hybrid strains in addition to the ribosomal proteins of S. marcescens.     

Gene locus of a 30s ribosomal protein S20 of Bacillus subtilis

Summary The gene locus of the 30s ribosomal protein S20 of Bacillus subtilis was mapped in the str-region at the right side of S5 gene. The gene order was cysA-str(S12)-ery(50D)-[spc(S5); 50G]-S20-.     

Phenotypic instability in a tif-1 mutant of Escherichia coli

Summary A recent study showed that in E. coli T44 () carrying the tif-1 mutation, elevated temperature and adenine can interfere with the translation process. The present study shows that the expression of tif phenotypes (thermoinduction and filamentation) is suppressed by factors which affect ribosomal function. Ethanol suppresses thermoinduction and, in some spc ^r mutants, both thermoinduction and filamentation are suppressed. An unknown factor(s) in yeast extract suppresses both thermoinduction and filamentation. In thermoresistant revertant (ts⁺), the expression of the ts⁺ phenotype is suppressed by yeast extract, ethanol, guanosine+cytidine and by the addition of a spc ^r mutation. This indicates that this phenotype could be due to suppressor mutations, and the interaction between factors affecting ribosomal function and the ts⁺ phenotype suggests that the suppression of tif in the ts⁺ strains could operate on the ribosomal level. In vitro studies show that in extracts from either spc ^r or ts⁺ strains, or in the presence of ethanol, translational restriction is relieved, suggesting that the suppression of tif phenotypes could involve the translation process.     

Evolution of ribosomal proteins in Enterobacteriaceae.

The evolution of ribosomal proteins of about 70 bacterial strains belonging to the family Enterobacteriaceae has been studied by use of previously reported data (S. Osawa, T. Itoh, and E. Otaka, J. Bacteriol. 107:168-178, 1971) and those obtained in this paper. The proximity of the bacteria was quantified by co-chromatographing the differentially labeled ribosomal proteins from two strains on a column of carboxymethyl cellulose in various combinations. The were then classified into 12 groups (=species?) according to their ribosomal protein compositions and were placed in a phylogenic tree.     

Extrachromosomal inheritance inSchizosaccharomyces pombe

Summary Spontaneous chloramphenicol (cap ^r)- and erythromycin (ery ^r)-resistant mutants were isolated from strain ade7–50 h ^- and the antimycin-resistant mutant ana ^r-8 ade 7–50 h^- of Schizosaccharomyces pombe (Sch. p.). By mitotic segregation analysis all 154 cap ^r- and 120 ery ^r-mutants derived from ade 7–50 h ^- proved to be recessive chromosomal, whereas all 108 cap ^r- and 200 ery ^r-mutants originating from ana ^r-8 were extrachromosomally inherited. The rate of spontaneous cap ^r- and ery ^r-mutants was about hundredfold in ana ^r-8 compared to ade 7–50 h ^-. Growth of cap ^r-and ery ^r-mutants was not inhibited by chloramphenicol or erythromycin, respectively, in glucose-medium and only slightly in glycerol-medium at concentrations which completely inhibited ana ^r-8. By mitotic segregation-, tetrad-, and mitotic haploidization-analysis the extrachromosomal inheritance of mutants derived from ana ^r-8 was established. Segregational patterns of cap ^r- and ery ^r-determinats during mitosis, meiosis, and mitotic haplidization of diploids are discussed.     

Peptide analyses of a protein component, 50-8, of 50s ribosomal subunit from erythromycin resistant mutants of Escherichia coli and Escherichia freudii

Summary Chromatographic analyses on a Dowex 50x8 column of tryptic digests of the mutationally altered 50-8 protein component from several erythromycin resistant (ery ^r) mutants of Escherichia coli and Escherichia freundii have been performed. It was found that (1) the difference in the elution profile of the altered components detected with carboxymethyl cellulose column chromatography reflects the difference in their amino acid sequence, (2) the structural change(s) of the 50-8 protein from three E. coli ery ^r mutants examined seems to exist only in the same single peptide fragment and (3) the primary structure of the 50-8(R) protein of E. freundii (ery ^s: wild type) differs from that of E. coli Q13 (ery ^s) and the structural change in 50-8(R) component of E. freundii caused by the ery ^r mutation was found to take place in different peptide fragments from that in which the mutational change of the E. coli 50-8 component occurred.     

Organization of ribosomal protein genes in Escherichia coli: II. Mapping of ribosomal protein genes by in vitro synthesis of ribosomal proteins using DNA fragments of a transducing phage as templates

The structural genes for six ribosomal proteins (r-proteins) located in the str-spc region around 64 minutes on the Escherichia coli chromosome have been mapped physically with respect to each other and the neighboring genes aroE and trkA. The genes code for the 30 S r-proteins S4 (ram), S5 (spc), S8, S11, S13 and S14. Furthermore, regions coding for unidentified 50 S r-proteins have been indicated.The mapping was performed by biochemical methods employing DNA from the specialized transducing phage λspc1, which carries the aroE-trkA-spc region of the E. coli chromosome. The phage DNA was cleaved by restriction endonucleases, and the generated DNA fragments used as templates for synthesis of r-proteins in a DNA-dependent cell-free system. Since the relative order of the DNA fragments created by the restriction endonucleases is known, a genetic map could be constructed.     

The rates of evolution in some ribosomal components

Summary The rate of nucleotide substitution (k(nuc)) of 5s RNA was estimated to be (1.8 ± 0.5) × 10^–10 per site per year by comparing the nucleotide sequences of human andXenopus 5s RNA and using the geological time elapsed since the separation of mammals and amphibians. Similarly, k(nuc) of 5.8s rRNA was calculated to be 0.93 – 1.4 × 10^–10 per site per year from the sequences of rat hepatoma cells andSaccharomyces cerevisiae. For the comparison of these data with the amino acid substitution rate of known proteins, the k(nuc) values of 5s rRNA and 5.8s rRNA were converted to the rate of amino acid substitution (k(aa)). The k(aa) values in pauling units were 0.4 and 0.2 – 0.3, respectively.The average k(aa) of ribosomal proteins was also estimated to be 0.2 – 0.3 pauling from the N-terminal amino acid sequences of seventeen 30s ribosomal proteins ofBacillus stearothermophilus andEscherichia coli. Thus, the evolutionary rates of these ribosomal components studied here are similar to each other; they are considerably slower than that of the known cellular proteins. Most, if not all, of the replacements in ribosomal proteins occurred between amino acids of a chemically similar nature.     

Fine structure of the 21S ribosomal RNA region on yeast mitochondrial DNA

Summary The omega locus controls the polarity of recombination and transmission of genetic markers in the 21S ribosomal RNA region in yeast mtDNA. Polarity is observed in crosses between omega⁺ and omega^- strains. These two strains differ by the presence of an intervening sequence in the 21S ribosomal RNA gene of omega⁺ strains. Mutations of the omega^- allele, omega neutral (omegaⁿ), can eliminate the polarity effect. We have made DNA:RNA hybrids containing ribosomal RNA from an omegaⁿ strain and mtDNA from Saccharomyces carlsbergensis (identical to omega^- in the nucleotide sequence of the omega region). These hybrids contain no mismatch at the omega region detectable by digestion with S₁ nuclease. We conclude that omegaⁿ differs from omega^- only in a point mutation or analogous small alteration and that the omegaⁿ mutation can result either m a C^r phenotype (omegaⁿC^r) or in the phenotypic suppression of pre-existing C^r mutations (omegaⁿC^s). All results can be explained by a model which postulates interaction in the ribosome between the C^r and omegaⁿ regions of the ribosomal RNA and interference of the omegaⁿ mutation with splicing of the precursor ribosomal RNA in omega⁺ strains. The mechanism of omega-directed polarity is discussed.Abbreviations rRNA ribosomal RNA - bp base pair(s) - kb kilo base pair(s)     

Ultrasound mediated enzymatic hydrolysis of cellulose and carboxymethyl cellulose

A recombinant Trichoderma reesei cellulase was used for the ultrasound‐mediated hydrolysis of soluble carboxymethyl cellulose (CMC) and insoluble cellulose of various particle sizes. The hydrolysis was carried out at low intensity sonication (2.4–11.8 W cm^?2 sonication power at the tip of the sonotrode) using 10, 20, and 40% duty cycles. [A duty cycle of 10%, for example, was obtained by sonicating for 1 s followed by a rest period (no sonication) of 9 s.] The reaction pH and temperature were always 4.8 and 50°C, respectively. In all cases, sonication enhanced the rate of hydrolysis relative to nonsonicated controls. The hydrolysis of CMC was characterized by Michaelis‐Menten kinetics. The Michaelis‐Menten parameter of the maximum reaction rate V_max was enhanced by sonication relative to controls, but the value of the saturation constant K_m was reduced. The optimal sonication conditions were found to be a 10% duty cycle and a power intensity of 11.8 W cm^?2. Under these conditions, the maximum rate of hydrolysis of soluble CMC was nearly double relative to control. In the hydrolysis of cellulose, an increasing particle size reduced the rate of hydrolysis. At any fixed particle size, sonication at a 10% duty cycle and 11.8 W cm^?2 power intensity improved the rate of hydrolysis relative to control. Under the above mentioned optimal sonication conditions, the enzyme lost about 20% of its initial activity in 20 min. Sonication was useful in accelerating the enzyme catalyzed saccharification of cellulose. © 2013 American Institute of Chemical Engineers Biotechnol. Prog., 29:1448–1457, 2013     

Effect of antibiotics on ribosomal RNA and proteins from Streptococcus pyogenes

Summary Cells of Streptococcus pyogenes were prepared under rigid conditions. The microorganisms were then incubated for 3 hours in the presence or absence of chloramphenicol, actinomycin or puromycin. RNA, ribosomal fraction and ribosomal proteins were isolated from the cells. The materials were invesigated with the help of infra red spectroscopy using the potassium bromide pellet method. Quantitative differences in the 1750–1500 cm^-1 region were observed with materials treated with the antibiotics. Synthetic mixtures of ribosomal RNA with progressively larger amounts of ribosomal proteins show analogous changes, namely a progressive increase in the strength of the 1650 cm^-1 band relative to the 1685 cm^-1 band, and an increase in the 1535 cm^-1 band. The analytical results obtained with the ribosomal RNA isolated from S. pyogenes treated with antibiotics indicated increased amounts of proteins which could not be removed by the applied extraction method. The evidence presented suggests a change in the binding between ribosomal RNA and ribosomal proteins in the material isolated from the antibiotic treated microorganisms. The I. R. spectroscopy seems to be an useful tool in the investigation of some aspects of biological materials.     

Genetic studies of the ribosomal proteins in Escherichia coli. 3. Compositions of ribosomal proteins in various strains of Escherichia coli

Summary The comparative chromatographic investigations into the ribosomal proteins of various strains of E. coli have demonstrated that most of the strains including three strains of E. coli subsp. communior had ribosomes with the same protein compositions (C-type). The ribosomes from strain B are different from the C-type ribosomes in having the specific 30-4 (B) component in place of 30-4 (B-type), while those from strains K 12 may be distinguished from the type-C ribosomes by the presence of the specific 30-7 (K) component in place of 30-7 (K-type) or, in addition to 30-7 (K), the presence of 30-9 (W3637) in place of 30-9 (K-3637 type). Two strains, IAM 1132 and IAM 1182, have R-type ribosomes, in which at least six 50s proteins and four 30s protein components are distinct from the corresponding protein components in the C-type ribosomes.     

Chloramphenicol resistant mutants of Bacillus subtilis

Summary Telve chloramphenicol resistant (CM ^r)-mutants were isolated from B. subtilis ATCC 6633 and were classified into the following six groups. Group I. No 50s ribosomal protein change was detectable. Ribosomes did not show alteration of the binding ability to CM or to erythromycin in vitro. Group II. A 50s protein, 50a, was altered. Ribosomes did not show alteration of the binding ability to CM or to erythromycin in vitro. The genes specifying the 50a protein was in the cysA-str region on B. subtilis chromosome. Group III. A 50s protein, 50b, was altered. Biological properties of the ribosomes were the same as Group I or II so fas as examined. The genes for 50b protein was in the cysA-str region. Group IV. A 50s protein, 50c, was altered. Ribosomes showed a definite decrease in ability to bind to CM in vitro. The binding of erythromycin to the ribosomes was not impaired. The chromosomal locus of the CM ^r (and for 50c protein) was in the cysA-str region. Group V. A 50s protein, 50e, was changed. The ability of the ribosomes to bind in vitro both to CM and to erythromycin was greatly reduced. The genetic locus of the CM ^r (and for 50e protein) was in the cysA-str region. Group VI. A 50s protein, 50f, was altered. Ribosomes showed a decrease in ability to bind in vitro both to CM and to erythromycin. The genes for 50f protein was in the cysA-str region.The results suggest that the ribosomal resistance to CM may be caused by an independent change of at least several 50s ribosomal protein species. The genetic data shown here and those reported previously show that at least two 30s and seven 50s ribosomal protein genes are situated in the cysA-str region on B. subtilis chromosome.     

A Thermostable Xylanase from a Thermophilic Acidophilic Bacillus sp.

Bacillus sp. 11-IS, a strain of thermophilic acidophilic bacteria, produced an extracellular xylanase during growth on xylan. The enzyme purified from the culture supernatant solution was homogeneous on disc-gel electrophoresis. The molecular weight was calculated to be 56,000 by SDS-gel electrophoresis. The enzyme had a pH optimum for activity at 4.0, and its stability range was pH 2.0 ~ 6.0. The temperature optimum was 80°C (10-min assay); however, the enzyme retained full activity after incubation at 70°C for 15 min. The enzyme acted on carboxymethyl cellulose (CMC) and cellulose, as well as on xylan. The Michaelis constants for larchwood xylan and CMC were calculated to be 1.68 mg xylose eq/ml and 0.465 mg glucose eq/ml, respectively. The predominant hydrolysis products from larchwood xylan were xylobiose, xylotriose, and xylose; the release of arabinose from rice-straw arabinoxylan was not detected. CMC was cleaved to cellobiose and larger oligosaccharides. Thus, the enzyme is considered to be an endoenzyme which degrades the β-1,4-glycosyl linkages in xylan and cellulose.     

Sequencing and analysis of the Thermus thermophilus ribosomal protein gene cluster equivalent to the spectinomycin operon

To assess the organization of the Thermus thermophilus ribosomal protein genes, a fragment of DNA containing the complete S10 region and ten ribosomal protein genes of the spc region was cloned, using an oligonucleotide coding for the N-terminal amino acid (aa) sequence of T. thermophilus S8 protein as hybridization probe. The nucleotide sequence of a 4290 bp region between the rps17 and rpl15 genes was determined. Comparative analysis of this gene cluster showed that the gene arrangement (S17, L14, L24, L5, S14, S8, L6, L18, S5, L30 and L15) is identical to that of eubacteria. However, T. thermophilus ribosomal protein genes corresponding to the Escherichia coli S10 and spc operons are not resolved into two clusters: the stop codon of the rps17 gene (the last gene of the S10 operon in E. coli) and the start codon of the rpl14 gene (the first gene of the spc operon in E. coli) overlap. Most genes, except the rps14-rps8 intergenic spacer (69 bp), are separated by very short (only 3–7 bp) spacer regions or partially overlapped. The deduced aa sequences of T. thermophilus proteins share about 51–100% identities with the sequences of homologous proteins from thermophile Thermus aquaticus and Thermotoga maritima and 27–70% identities with the sequences of their mesophile counterparts.     

Separation and characterization of the complexes constituting the cellulolytic enzyme system of Clostridium thermocellum

Clostridium thermocellum, strain JW20 (ATCC 31449) when growing in cellulose produces a cellulolytic enzyme system, that at the early stage of the fermentation is largely bound to the substrate. As cellulose is consumed the bound enzyme is released as free enzyme to the culture fluid. The bound enzyme fraction extracted with distilled water from the cellulose contains two major components, a large complex (M_r100×10⁶) and a small complex M_r4.5×10⁶) which were separated by gel filtration and sucrose solved by affinity chromatography into a complex that binds to the column and into a non-bindable mixture of proteins. All four fractions have endo--glucanase activity but only the two bound complexes and the free bindable complex hydrolyze crystalline cellulose with cellobiose as the main product. These three complexes are qualitatively similar in that they each contain about 20 different polypeptides (M_r values from 45,000 to 200,000) of which about ten are major components. However, the relative amounts of some of the peptides in the complexes differ. At least four polypeptides of the complexes have endo--glucanase activity.Abbreviations CM cellulose, carboxymethyl cellulose - CMCase carboxymethyl cellulase cosidered endo--1,4-glucanase - SDS sodium dodecyl sulfate - YAS yellow affinity substance - YAS-cellulose yellow affinity substance-cellulose complex