A novel approach for monitoring genetically engineered microorganisms by using artificial, stable RNAs.

Further improvements in technology for efficient monitoring of genetically engineered microorganisms (GEMs) in the environment are needed. Technology for monitoring rRNA is well established but has not generally been applicable to GEMs because of the lack of unique rRNA target sequences. In the work described herein, it is demonstrated that a deletion mutant of a plasmid-borne Vibrio proteolyticus 5S rRNA gene continues to accumulate to high levels in Escherichia coli although it is no longer incorporated into 70S ribosomes. This deletion construct was subsequently modified by mutagenesis to create a unique recognition site for the restriction endonuclease BstEII, into which new sequences could be readily inserted. Finally, a novel 17-nucleotide identifier sequence from Pennisetum purpureum was embedded into the construct to create an RNA identification cassette. The artificial identifier RNA, expressed from this cassette in vivo, accumulated in E. coli to levels comparable to those of wild-type 5S rRNA without being seriously detrimental to cell survival in laboratory experiments and without entering the ribosomes. These results demonstrate that artificial, stable RNAs containing sequence segments remarkably different from those present in any known rRNA can be designed and that neither the deleted sequence segment nor ribosome incorporation is essential for accumulation of an RNA product.     

Interaction among silkworm ribosomal proteins P1, P2 and P0 required for functional protein binding to the GTPase-associated domain of 28S rRNA

Acidic ribosomal phosphoproteins P0, P1 and P2 were isolated in soluble form from silkworm ribosomes and tested for their interactions with each other and with RNA fragments corresponding to the GTPase-associated domain of residues 1030–1127 (Escherichia coli numbering) in silkworm 28S rRNA in vitro. Mixing of P1 and P2 formed the P1–P2 heterodimer, as demonstrated by gel mobility shift and chemical crosslinking. This heterodimer, but neither P1 or P2 alone, tightly bound to P0 and formed a pentameric complex, presumably as P0(P1–P2)₂, assumed from its molecular weight derived from sedimentation analysis. Complex formation strongly stimulated binding of P0 to the GTPase-associated RNA domain. The protein complex and eL12 (E.coli L11-type), which cross-bound to the E.coli equivalent RNA domain, were tested for their function by replacing with the E.coli counterparts L10.L7/L12 complex and L11 on the rRNA domain within the 50S subunits. Both P1 and P2, together with P0 and eL12, were required to activate ribosomes in polyphenylalanine synthesis dependent on eucaryotic elongation factors as well as eEF-2-dependent GTPase activity. The results suggest that formation of the P1–P2 heterodimer is required for subsequent formation of the P0(P1–P2)₂ complex and its functional rRNA binding in silkworm ribosomes.     

Host factor for coliphage Qbeta RNA replication is present in Pseudomonas putida.

Summary Host Factor (HF)¹, is a 12000 molecular weight polypeptide that is found in uninfected Escherichia coli and is required as a hexamer along with Q replicase for in vitro replication of Q phage RNA. It has recently been found to be associated with ribosomes and to bind tightly to poly(A).We report here the identification and purification of HF from Pseudomonas putida. HF can be detected in crude extracts by both functional activity in the Q RNA replication assay and by immunodiffusion with antibody made against E. coli HF. HF from E. coli and P. putida chromatograph similarly on DEAE-cellulose and phosphocellulose. They have similar but not identical molecular weights as judged by SDS-polyacrylamide gel electrophoresis. Like E. coli HF, P. putida HF was found to be associated with ribosomes and to bind tightly to poly (A). Furthermore, the pure protein from P. putida has full functional activity in the in vitro Q RNA replication assay.The findings that HF has been conserved during evolution, is associated with ribosomes, and binds poly(A), suggest that HF may be an important translational element in uninfected cells and that its role involves an interaction with RNA.Research supported by National Institutes of Health Grant GM 21024.     

Characterization of a novel small RNA encoded by Dictyostelium discoideum mitochondrial DNA

In this study, we analyzed a mitochondrial small (ms) RNA in Dictyostelium discoideum, which is 129 nucleotides long and has a GC content of only 22.5%. In the mitochondrial DNA, a single-copy gene (msr) for the ms RNA was located downstream of the gene for large-subunit rRNA. The location of msr was similar to that of the 5S rRNA gene in prokaryotes and chloroplasts, but clearly different from that in mitochondria of plants, liverwort and the chlorophycean alga Prototheca wikerhamii, in which small-subunit rRNA and 5S rRNA genes are closely linked. The primary sequence of ms RNA showed low homology with mitochondrial 5S rRNA from plants, liverwort and the chlorophycean alga, but the proposed secondary structure of ms RNA was similar to that of cytoplasmic 5S rRNA. In addition, ms RNA showed a highly conserved GAAC sequence in the same loop as in common 5S rRNA. However, ms RNA was detected mainly in the mitochondrial 25 000 × g supernatant fraction which was devoid of ribosomes. It is possible that ms RNA is an evolutionary derivative of mitochondrial 5S rRNA. Received: 17 May 1997 / Accepted: 26 August 1997     

The rne gene is the structural gene for the processing endoribonuclease RNase E of Escherichia coli.

Summary Using T7 RNA polymerase and specific constructs derived from 5S rRNA and RNA I genes, we generated substrates for the RNA processing enzyme RNase E. Using these substrates we have shown that a 3.2 kb DNA fragment that complements the rne-3071 mutation can express RNase E activity. We also found that T7 RNA polymerase terminates within the 5S rRNA gene.     

Influence of mycoplasma infection on the incorporation of different precursors into RNA components of tissue culture cells

Seven different tissue culture cells have been cultured with and without mycoplasma (M. hyorhinis) in the presence of various precursors of RNA. Total cellular RNA was isolated and analysed by electrophoresis on polyacrylamide gels. The results obtained with mycoplasma-infected cells can be summarized as follows:

1. 1. When cells are labelled with [8-³H]guanosine or [5-³H]uridine there is some incorporation into host cell 28S and 18S rRNA, but it is less than into mycoplasma 23S and 16S rRNA. [8-³H]guanosine or [5-³H]uridine are also incorporated into host cell and mycoplasma tRNA and mycoplasma 4.7S RNA, but the incorporation into host cell 5S rRNA and low molecular weight RNA components (LMW RNA) is reduced.

2. 2. [5-³H]uracil is not incorporated into host cell RNA but into mycoplasma tRNA, 4.7S RNA, a mycoplasma low molecular weight RNA component M₁ and 23S and 16S rRNA.

3. 3. [³H]methyl groups are incorporated into mycoplasma tRNA, 23S and 16S rRNA, but not into host cell 28S, 18S, 5S rRNA nor into mycoplasma 4.7S RNA.

4. 4. With [³²P]orthophosphate or [³H]adenosine as precursors, the labelling is primarily in the host RNA.

Mycoplasma infection influences the labelling of RNA primarily by an effect on the utilization of the exogenously added radioactive RNA precursors, since the generation time of mycoplasma infected cells is about the same as that of uninfected cells. Mycoplasma infection may completely prevent the identification of LMW RNA components.     

Molecular cloning of the ribosomal RNA genes of the photosynthetic bacterium Rhodopseudomonas capsulata

Summary Chromosomal segments of Rhodopseudomonas capsulata carrying the ribosomal operons and cloned with the cosmid vector pHC79 have been identified by cross hybridization with ³²P-ATP labeled rRNAs. At least seven rRNA operons are present in the R. capsulata chromosome. By R-loop analyses of DNA-RNA hybrids, two distinct loop structures of sizes 1.50 kb and 2.52 kb corresponding to the 16S and 23S RNA molecules, respectively, were detected. Intact 23S RNA molecules can be isolated from R. capsulata ribosomes by sucrose density centrifugation. However, fragmentation of the 23S RNA molecule into a 16S-like molecule was observed during gel electrophoresis. Restriction mapping and hybridization of a 9 kb PstI fragment that contained one copy of the rRNA operon showed the following sequence of the RNA genes in R. capsulata 16S, 23S, and 5S. A spacer region of 0.91 kb was found between the 16S and the 23S RNA genes.     

Engineering Pichia pastoris for stereoselective nitrile hydrolysis by co-producing three heterologous proteins

A Pichia pastoris strain with stereoselective nitrile hydratase activity has been constructed by engineering the co-expression of three genes derived from Pseudomonas putida. Using a technique that could be widely applicable, the genes encoding nitrile hydratase α and β structural subunits and P14K accessory protein were first assembled as individual expression cassettes and then incorporated onto one plasmid, which was integrated into the P. pastoris chromosome. The resulting strain can be used as a catalyst for bioconversions requiring stereospecific nitrile hydrolysis. Received: 3 November 1998 / Received revision: 25 February1999 / Accepted: 14 March 1999     

Heterologous expression of cholesterol oxidase in<Emphasis Type="Italic"> Bifidobacterium longum</Emphasis> under the control of 16S rRNA gene promoter of bifidobacteria

We have constructed a constitutive high-level-expression vector for the genus Bifidobacterium and used it to express cholesterol oxidase from Streptomyces coelicola. The promoter region of the 16S rRNA gene was amplified by inverse PCR and used for the construction of pBES16PR. The optimal ribosome-binding site (RBS) for Bifidobacterium was incorporated in pBES16PR. In order to test the efficacy of this expression vector, we constructed pBES16PR-CHOL with the structural gene for cholesterol oxidase under the control of the 16S rRNA promoter, and used it to transform Bifidobacterium longum. The gene was successfully expressed and high level of cholesterol oxidase activity was obtained in B. longum. This is the first report of an expression vector for the genus Bifidobacterium using a 16S rRNA gene promoter and successful expression of cholesterol oxidase. Myeong Soo Park and Bin Kwon contributed equally.     

Oligonucleotide directed mutagenesis of Escherichia coli 5S ribosomal RNA: construction of mutant and structural analysis.

The ribosomal 5S RNA gene from the rrnB operon of E. coli was mutagenised in vitro using a synthetic oligonucleotide hybridised to M13 ssDNA containing that gene. The oligonucleotide corresponded to the 5S RNA sequence positions 34 to 51 and changed the guanosine at position 41 to a cytidine. The DNA containing the desired mutation was identified by dot blot hybridisation and introduced back into the plasmid pKK 3535 which contains the total rrnB operon in pBR 322. Plasmid coded 5S rRNA was selectively labeled with 32p using a modified maxi-cell system, and the replacement of guanosine G41 by cytidine was confirmed by RNA sequencing. The growth of cells containing mutant 5S rRNA was not altered by the base change, and the 5S rRNA was processed and incorporated into 50S ribosomal subunits and 70S ribosomes. The structure of wildtype and mutant 5S rRNA was compared by chemical modification of accessible guanosines with kethoxal and limited enzymatic digestion using RNase T1 and nuclease S1. These results showed that the wildtype and mutant 5S rRNA do not differ significantly in their structure. Furthermore, the formation, interconversion and stability of the two 5S rRNA A- and B-conformers are unchanged.     

Protocols for yTREX/Tn5-based gene cluster expression in Pseudomonas putida

Bacterial gene clusters, which represent a genetic treasure trove for secondary metabolite pathways, often need to be activated in a heterologous host to access the valuable biosynthetic products. We provide here a detailed protocol for the application of the yTREX ‘gene cluster transplantation tool’: Via yeast recombinational cloning, a gene cluster of interest can be cloned in the yTREX vector, which enables the robust conjugational transfer of the gene cluster to bacteria like Pseudomonas putida, and their subsequent transposon Tn5-based insertion into the host chromosome. Depending on the gene cluster architecture and chromosomal insertion site, the respective pathway genes can be transcribed effectively from a chromosomal promoter, thereby enabling the biosynthesis of a natural product. We describe workflows for the design of a gene cluster expression cassette, cloning of the cassette in the yTREX vector by yeast recombineering, and subsequent transfer and expression in P. putida. As an example for yTREX-based transplantation of a natural product biosynthesis, we provide details on the cloning and activation of the phenazine-1-carboxylic acid biosynthetic genes from Pseudomonas aeruginosa in P. putidaKT2440 as well as the use of β-galactosidase-encoding lacZ as a reporter of production levels.     

Ribonucleic acid synthesis and loss of viability in pea seed

Summary RNA synthesis and protein synthesis in embryonic axis tissue of viable pea (Pisum arvense L. var. N.Z. maple) seed commences during the first hour of germination. Protein synthesis in axis tissue of non-viable pea seed is barely detectable during the first 24 h after the start of imbibition. Nonviable axis tissue incorporates significant levels of [³H]uridine into RNA during this period but the level of incorporation does not increase significantly over the first 24 h of imbibition. In axis tissue of non-viable seed during the first hour of imbibition most of the [³H]uridine was incorporated into low molecular weight material migrating in advance of the 4S and 5S RNA species in polyacrylamide gels but some radioactivity was incorporated into a discrete species of RNA having a molecular weight of 2.7×10⁶. After 24 h, non-viable axis tissue incorporates [³H]uridine into ribosomal RNA, the low molecular weight material migrating in advance of the 4S and 5S RNA peak in polyacrylamide gels and a heterogeneous RNA species of molecular weight ranging from 2.2×10⁶ to 2.7×10⁶. No 4S or 5S RNA synthesis is detectable after 24 h of imbibition in non-viable axis tissue. Axis tissue of viable pea seed synthesises rRNA, 4S and 5S RNA, the low molecular weight material migrating in advance of the 4S and 5S RNA peak in polyacrylamide gels and the rRNA precursor species at both periods of germination studied. Loss of viability in pea seed appears to be accompanied by the appearance of lesions in the processing of rRNA precursor species and a significant loss of RNA synthesising activity.Abbreviations rRNA ribosomal RNA - TCA trichloroacetic acid - SLS sodium lauryl sulphate - PPO 2,5 Diphenyloxazole - POPOP 1,4-Bis-2-(4-methyl-5-penyloxazolyl)-benzene     

A cold-sensitive cytoplasmic mutation of Saccharomyces cerevisiae affecting assembly of the mitochondrial 50S ribosomal subunit.

Summary A cytoplasmic mutant of Saccharomyces cerevisiae (E23-1) has been isolated that is resistant to erythromycin and cold sensitive for growth on nonfermentable carbon sources at 18°. Genetic analysis has shown that both of these properties probably result from a single mutation at the rib2 locus which maps close to or within the gene for the 21S rRNA of the mitochondrial 50S ribosomal subunit. Electrophoresis of total RNA extracted from purified mitochondria demonstrated that the 21S and 14S rRNA species from both mutant and wild-type cells were present in roughly equimolar quantities regardless of growth temperature. The mutant is therefore not defective in the synthesis of the 21S rRNA. Sucrose gradient analysis of the mitochondrial ribosomes in Mg²⁺-containing buffers revealed that approximate values for the ratio of 50S to 37S subunits were 1:1 for wild-type cells grown at either 18° or 32°, 0.5:1 for the mutant grown at 32° and 0.2:1 for the mutant grown at 18°. The subunit ratios were approximately 1:1 when Ca²⁺-containing buffers were used, however, In alls cases, 50S particles from the mutant grown at 18° lacked or contained markedly reduced amounts of two distinctive protein components that were present in the mutant at 32° and in the wild-type at both temperatures. In addition, no intact 21S RNA could be recovered from the mitochondrial ribosomes of the mutant grown at the restrictive temperature, even in the presence of Ca²⁺. These findings indicate that mitochondrial 50S ribosomal subunits produced by the mutant at 18° are structurally defective and raise the possibility that the defect results from an alteration in the gene for 21S rRNA.A preliminary report of this work was presented at the meeting on The Molecular Biology of Yeast, Cold Spring Harbor Laboratory, August 18–22, 1977     

Action of Ribonuclease T1 on 30S Ribosomes of Escherichia coli and Its Role in Sequence Studies on 16S Ribonucleic Acid

Two large ribonucleic acid (RNA) fragments have been obtained from T1-RNase-treated 30S ribosomes of Escherichia coli. One fragment, about 475 nucleotides long, contains all the unique oligonucleotides found by Fellner and associates in sections of 16S RNA designated P, E, E', and K, and one-half the large oligonucleotides of section A. The other large fragment is about 300 nucleotides long and contains the oligonucleotides found in sections C, C', C'. The isolation of these large fragments seems to confirm the arrangement of sections within 16S RNA. There are also recovered from nuclease-treated ribosomes three small fragments, one (120 nucleotides long) from the 5' end, one (26 nucleotides long) from the 3' OH end of the chain, and another section (66 nucleotides long) from the middle of the 16S RNA chain. Small molecular weight material is also generated by nuclease treatment, and about half this material is derived from a region close to the 3' OH end of the 16S RNA chain. This indicates that the most accessible part of the rRNA of E. coli 30S ribosomes is a region 100 to 150 nucleotides long near the 3' end of the chain. A general scheme is proposed to explain the generation of the various-sized RNA products from the rRNA of the 30S ribosome.     

The Ribonucleic Acids of Crithidia fasciculata*

SYNOPSIS. Crithidia fasciculata ribosomes were found to be 80S and to dissociate into 58 and 41S subunits; on 5 to 50% sucrose gradients, rRNA was separated into 25, 18, and 5S components. The molecular sizes of the heavier rRNA species, estimated by polyacrylamide gel electrophoresis were 1.24 and 0.84 M (×10⁶ daltons). The 25S RNA has a tendency to interact with the 18S RNA to give a complex that is difficult to separate by sucrose gradient centrifugation. The 25S RNA is also unstable and dissociates into 0.73 and 0.57 M components. The 18S RNA has molecular size (0.84 M) higher than the 0.7 M reported for most eukaryotes, but similar to that of Euglena and Amoeba. Ribosomal RNA hybridized 0.29% of the nuclear DNA. Mitochondrial RNA, extracted by a rapid procedure was resolved into 16 and 5S components in sucrose gradients.