The making of strand-specific M13 probes

Activation of interferon-regulated, dsRNA-dependent enzymes by human immunodeficiency virus-1 leader RNA

Human immunodeficiency virus-1 (HIV-1) leader RNA, which contains double-stranded regions due to inverted repeats, was shown to activate the dsRNA-dependent enzymes associated with the interferon system. HIV-1 leader RNA produced in vitro using SP6 RNA polymerase was characterized using probes for antisense and sense-strand RNA. The RNA preparation was free from significant levels of antisense RNA. HIV-1 leader RNA was shown to activate dsRNA-dependent protein kinase in a cell-free system from interferon-treated HeLa cells. Affinity resins, consisting of HIV-1 leader RNA covalently attached to cellulose, immobilized and activated dsRNA-dependent protein kinase and 2-5A-synthetase. HIV-1 leader RNA, therefore, may be a contributing factor in the mechanism by which interferon inhibits HIV replication.

Terminal sequences do not contain the rate-limiting decay determinants of E. coli cat mRNA

The mechanism of E. coli chloramphenicol acetyltransferase (cat) mRNA decay was investigated. Alteration of the 5' untranslated terminus does not appear to have an effect on the turnover rate of the mRNA. Similarly, changes at the 3' terminus of the message, including the addition of a stable stem and loop structure, do not affect the half-life of the message. The data suggest that 5' and 3' terminal untranslated sequences do not contain the rate-limiting determinants for cat message decay. Decay rates for various segments of the cat mRNA were measured and indicate that all regions of the message have similar stabilities. The current model of cat mRNA degradation involves a rate-limiting endonucleolytic decay event that occurs internal to the message followed by degradation of the cleavage products.

Molecular characterization of a Dictyostelium discoideum gene encoding a multifunctional enzyme of the pyrimidine pathway

We have isolated and characterized a Dictyostelium discoideum gene (PYR1-3) encoding a multifunctional protein that carries the three first enzymatic activities of the de novo pyrimidine biosynthetic pathway. The PYR1-3 gene is adjacent to another gene of the pyrimidine biosynthetic pathway (PYR4); the two genes are separated by a 1.5-kb non-coding sequence and transcribed divergently. The PYR1-3 gene is transcribed to form a 7.5-kb polyadenylated mRNA. As with the other genes of the pyrimidine biosynthetic pathway, the PYR1-3 mRNA level is high during growth and decreases sharply during development. We have determined the nucleotide sequence of 63% of the coding region of the PYR1-3 gene. We have identified the activities of the protein encoded by the D. discoideum PYR1-3 gene by comparison of amino acid sequences with the products of genes of known function. The PYR1-3 gene contains four distinct regions that probably correspond to four domains in the protein. From the NH2 extremity to the COOH extremity, these domains are: glutamine amidotransferase, carbamoylphosphate synthetase, dihydroorotase and aspartate transcarbamylase. This organization is identical to the one found in the rudimentary gene of Drosophila. The evolutionary implications of this finding are discussed.

Detection of a homologue to an E. coli glutamate synthase gene in a cyanobacterium

The gltBY locus of E. coli, which codes for the two subunits of pyridine nucleotide dependent glutamate synthase, was used as a probe to detect homologues in genomic DNA of Synechococcus PCC6301, a unicellular cyanobacterium. Non-overlapping probes from gltB detected a single homologue with extensive homology, however gltY probes do not detect a strong homologue. The possibility that the gltB homologue encodes a ferredoxin-dependent glutamate synthase of the type found in cyanobacteria, algae and plants is discussed.

Characterization of the two rRNA gene operons present in Thiobacillus ferrooxidans

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

Gene replacement and retrieval with recombinant M13mp bacteriophages

We have developed an allele exchange system for shuttling sequences of DNA to and from their original chromosomal loci. Cloned segments of the histidine operon of Salmonella typhimurium and the lactose operon of Escherichia coli served as target sequences and were used to develop the system. Replacement and retrieval of target sequences used the phage M13mp vectors and proceeded through an M13 lysogen intermediate. The intermediates and products of allele exchange were characterized by genetic and hybridization analyses. Several unique properties of M13 lysogens were exploited to devise positive selections to detect integration and excision. These positive selections were used to manipulate phenotypically silent alleles.

The REV1 gene of Saccharomyces cerevisiae: isolation, sequence, and functional analysis

The REV1 gene of Saccharomyces cerevisiae is required for normal induction of mutations by physical and chemical agents. We have determined the sequence of a 3,485-base-pair segment of DNA that complements the rev1-1 mutant. Gene disruption was used to confirm that this DNA contained the REV1 gene. The sequenced segment contains a single long open reading frame, which can encode a polypeptide of 985 amino acid residues. The REV1 transcript is 3.1 kilobase pairs in length. Frameshift mutations introduced into the open reading frame yielded a Rev-phenotype. A base substitution, encoding Gly-193 to Arg-193, was found in this open reading frame in rev1-1. Deletion mutants, lacking segments of the 5' region of REV1, had intermediate mutability relative to REV1 and rev1-1; a complete deletion exhibited lower mutability than rev1-1. REV1 is not an essential gene. An in-frame fusion of the 5' end of the REV1 open reading frame to the lacZ gene produced beta-galactosidase activity constitutively. The predicted REV1 protein is hydrophilic, with a predicted pI of 9.82. No homologies to RAD1, RAD2, RAD3, RAD7, or RAD10 proteins were noted. A 152-residue internal segment displayed 25% identity with UMUC protein.

Transferable vancomycin and teicoplanin resistance in Enterococcus faecium

Enterococcus faecium BM4165 and BM4178, isolated from immunocompromised patients, one treated with vancomycin, were inducibly resistant to high levels of the glycopeptide antibiotics vancomycin and teicoplanin but susceptible to the new lipopeptide daptomycin (LY146032). Strain BM4165 was also resistant to macrolidelincosamide-streptogramin B-type (MLS) antibiotics. The genes conferring resistance to glycopeptides and to MLS antibiotics in strain BM4165 were carried on plasmids pIP819 and pIP821, respectively; pIP819 also carried genes that encoded resistance to MLS antibiotics. The two plasmids, which were distinct although related, were self-transferable to other E. faecium strains. Plasmid pIP819 could also conjugate to E. faecalis, Streptococcus sanguis, S. pyogenes, S. lactis, and Listeria monocytogenes, in which it conferred inducible glycopeptide resistance, but not to S. aureus. Glycopeptide-inactivating activity was not detected, and the biochemical mechanism of resistance remains unknown. Based on this first report of transferable resistance to glycopeptides, we anticipate dissemination of resistance to these antibiotics in gram-positive cocci and bacilli in which it can be phenotypically expressed.

Nucleic acid analysis by sandwich hybridization

One of the most significant achievements of the biochemist during the past two decades is the use to which immunologically based assays have been put in clinical diagnosis (Hood et al.: Immunology, 1984). The problem faced and surmounted by immunologists in effecting the transition from research tool to routine clinical assay bears a remarkable similarity to that confronting the molecular biologist today; i.e., how can nucleic acid hybridization, a technique of obvious potential (Meinkoth and Wahl: Anal Biochem 138:267-284, 1984; Syvanen: Med Biol 64:313-324, 1986; Matthews and Kricka: Anal Biochem 169:1-25, 1988), be modified in order to fulfill all necessary parameters of a routine diagnostic assay? There are several such requirements, and the importance placed on each depends on the objectives of the assay: the technique must be sensitive, specific, and reproducible. Other advantages would be cost-effectiveness, ease of manipulation, and amenability to automation. Ideally, the signal detection should be based on a non-radioactive system, because of the instability of probes labelled with isotopes like 32p, and the potential hazards involved in their handling and disposal. The sandwich hybridization for the analysis of nucleic acid sequences was first used in 1977 (Dunn and Hassell: Cell 12:23-36, 1977), but its potential as a diagnostic assay was not realized until 1983, when it was applied to the detection of adenovirus DNA in nasopharyngeal aspirates from children with acute respiratory infection (Ranki et al: Gene 21:77-85, 1983). It has since been modified and used not only for the detection of microbial infection (Virtanen et al.: Lancet i:381-383, 1983; Ranki et al.: Cur Top Microbiol Immunol 104:307-318, 1983; Lehtomaki et al.: J Clin Microbiol 24:108-111, 1986; Virtanen et al.: J Clin Microbiol 20:1083-1088, 1984; Palva and Ranki: Clin Lab Med 5:475-490, 1985; Polsky-Cynkin et al.: Clin Chem 31:1438-1443, 1985; Parkkinen et al.: J Med Virol 20:279-288, 1986; Palva: FEMS Microbiol Lett 28:85-91, 1985; Palva et al: FEMS Microbiol Lett 23:83-89, 1984; Zolg et al.: Mol Biochem Parasitol 22:145-151, 1987; Palva: J Clin Microbiol 18:92-100, 1983), but also for the analysis of nucleotide sequence variations (Langdale and Malcolm: Gene 36:201-210, 1985). We will discuss the development of the sandwich technique and the advantages it conveys over the more conventional nucleic acid hybridization formats, together with new developments which will ensure that it earns a place alongside immunoassay in the diagnostic laboratory.

Sequence analysis of the wheat mitochondrial atp6 gene reveals a fused upstream reading frame and markedly divergent N termini among plant ATP6 proteins

The nucleotide sequence of the wheat mitochondrial gene for subunit 6 (atp6) of the F1F0 ATPase complex has been determined. Unlike bacterial, chloroplast or animal/fungal mitochondrial atp6 counterparts, which encode proteins of about 230-270 amino acids, the wheat mitochondrial atp6 homologue comprises the latter part of an open reading frame (ORF) of 386 codons. The ATP6 protein may therefore by synthesized with a long N-terminal presequence. This is supported by the finding that the ORF is preceded by a conserved sequence block closely related to ones preceding several other actively transcribed wheat mitochondrial protein-coding genes. The fused upstream ORF is similar in length, but unrelated in sequence, to those preceding the maize and tobacco mitochondrial atp6 genes. In wheat, the atp6 gene is located on a recombinationally active repeated DNA element, whose length of 1.4 kb corresponds approximately to that of the atp6 mRNA. A comparison of the wheat and maize ATP6 sequences reveals unexpectedly high divergence in the region corresponding to the mature N-terminal domain and may reflect mitochondrial DNA rearrangements during atp6 gene evolution in monocotyledonous plants.

Occurrence of the Campylobacter resistance gene tetO in Enterococcus and Streptococcus spp

The distribution of nucleotide sequences related to tetK, tetL, tetM, and tetO was studied by dot blot hybridization in 178 strains of Streptococcus and Enterococcus spp. that were resistant to tetracycline. The tetO gene, which is responsible for tetracycline resistance in Campylobacter spp., was detected in six Streptococcus strains and two Enterococcus strains, in which it was borne by similar plasmids. This observation confirms our previous proposal that tetO originated in gram-positive cocci. tetM, the most prevalent resistance gene, was present alone in 109 strains and associated with tetL in 33 strains in which the two genes contributed cooperatively to high-level tetracycline resistance. tetL was present alone in five Enterococcus strains, and tetK was detected in a single Streptococcus strain. The existence of 22 strains that did not hybridize to the probes suggest that tetracycline resistance in streptococci and enterococci involves additional gene classes as well.

Nucleic acid sandwich hybridization: enhanced reaction rate with magnetic microparticles as carriers

A method for the detection of nucleic acid hybrids using the sandwich hybridization technique with magnetic polystyrene microparticles as the solid support is described. The capture DNA is coupled to the polystyrene-hydroxy surface of the particles through p-toluenesulfonyl chloride activation. The use of microparticles results in a substantial increase in the reaction rate compared to filter hybridization, without decreasing the sensitivity of detection. Polyethylene glycol additionally enhances the reaction rate. The use of magnetic microparticles allows rapid and convenient collection of the formed hybrids.

Molecular cloning and nucleotide sequence of the nuclear PET122 gene required for expression of the mitochondrial COX3 gene in S. cerevisiae

The nuclear PET122 gene from S. cerevisiae is necessary for translation of a single mitochondrial mRNA that encodes subunit III of cytochrome c oxidase. We report here the cloning and nucleotide sequence of PET122, and properties of the predicted protein product, which consists of 242 residues. Analysis of PET122-lacZ translational fusions confirms that the PET122 coding region is translated in vivo and indicates that the PET122 protein product is targeted to mitochondria. A 117 residue domain located in the carboxy-terminal half of the PET122 protein, at least part of which is shown by characterization of mutants to be critical for PET122 function, exhibits 24% identity and 59% similarity to a portion of the catalytic domain of E. coli alanyl-tRNA synthetase. However, pet122 mutants are not defective in mitochondrial translation per se, as would be expected if PET122 encoded a tRNA synthetase. Instead, the PET122 protein may carry out one or more activities in common with tRNA synthetases, such as binding of ATP or RNA.

A novel reverse transcriptase activity associated with mitochondrial plasmids of Neurospora

The Mauriceville and Varkud mitochondrial plasmids of Neurospora are closely related DNA elements whose nucleotide sequences and genetic organization suggest relationships to retrotransposons and mitochondrial introns. Both plasmids potentially encode a reverse transcriptase-like protein of 710 amino acids. We show that mitochondria from the Mauriceville and Varkud strains contain a reverse transcriptase activity highly specific for endogeneous plasmid RNA in RNP preparations. The reverse transcriptase synthesizes full-length minus-strand DNA beginning at the 3' end of the plasmid transcript, which has tRNA-like characteristics similar to the 3' ends of plant viral RNAs. Our results suggest that the plasmids use a novel mechanism of reverse transcription, which may have evolved to utilize tRNA-like structures at the 3' ends of self-replicating RNAs. This mechanism may be ancestral to the standard retroviral mechanism.

Repetitive DNA sequences as probes for Mycobacterium tuberculosis

Three cloned segments of Mycobacterium tuberculosis DNA which are promising as clinical probes were identified. An MboI digest of DNA from a clinical isolate of M. tuberculosis was cloned into bacteriophage M13. To identify recombinants specific for the M. tuberculosis complex, plaque lifts were hybridized with M. bovis and M. kansasii DNA. Recombinants which selectively hybridized with M. bovis DNA were characterized by probing slot blots and restriction digests of DNA from various mycobacteria. Three recombinants that did not hybridize to a significant extent with DNA from nontuberculous mycobacteria were identified. These three probes are of special interest because they are each repeated multiple (10 to 16) times in the M. tuberculosis chromosome. These probes were also shown to be useful for fingerprinting strains for epidemiological studies.

Characterization of temperature-sensitive mutants of Pichinde virus

The synthesis of viral proteins and S RNAs in cells infected with 12 temperature-sensitive (ts) mutants of Pichinde virus was characterized. The mutants could be divided into five groups on the basis of the patterns of radiolabeled proteins immunoprecipitated from infected-cell lysates. Markedly reduced nucleoprotein levels and undetectable amounts of glycoprotein precursor and L protein were synthesized at the nonpermissive temperature in cells infected with five of the mutants. Reduced but detectable amounts of the viral proteins were synthesized at the nonpermissive temperature in cells infected with a single mutant. Two mutants were associated with the intracellular accumulation of glycoprotein precursor, which was apparently not transported across the cell membrane in cells incubated at the nonpermissive temperature. The synthesis of viral proteins in cells infected with two mutants was indistinguishable from those produced by wild-type virus. Two additional mutants were associated with markedly reduced amounts of immunoprecipitable proteins in infected cells incubated at both the permissive and nonpermissive temperatures. Analysis of viral RNA with radiolabeled single-stranded cDNA probes representing complementary and genomic-sense sequences corresponding to the 3' region of S RNA revealed two basic patterns of viral RNA synthesis. At the nonpermissive temperature, the synthesis of complementary- and genomic-sense sequences and mRNA of the S RNA segment was markedly reduced in cells infected with representative members of these mutant groups, suggesting the presence of mutations altering transcriptase activity. Viral-complementary- and genomic-sense sequence and RNA synthesis, as well as nucleoprotein mRNA in cells, was detected in reduced amounts for mutants associated with reduced levels of proteins at both temperatures. Interestingly, RNA species larger than the S RNA segment were detected in cells infected with some of the mutants, especially those with putative transcriptase lesions. These molecules suggest a possible oligomeric intermediate in the synthesis of S RNA of Pichinde virus.

Transcriptional analysis of the major surface array gene of Caulobacter crescentus

The major component of the paracrystalline surface array of Caulobacter crescentus CB15 and one of the most abundant cellular proteins is a protein designated 130K. We have determined the DNA sequence of the 5' portion of the 130K gene, including the N-terminal one-third of the protein coding region, and analyzed the transcription of the gene. The site of transcription initiation was determined by S1 mapping of Caulobacter RNA. Although the DNA sequence upstream from the transcription start site showed significant homology to the consensus promoter sequences of Escherichia coli, S1 analysis of RNA from E. coli carrying the 130K gene on a plasmid indicated that the 130K promoter was not transcribed by E. coli RNA polymerase in vivo. Quantitative S1 analysis of RNA isolated from synchronously growing Caulobacter cells suggested that this promoter was not under developmental regulation; the amount of 130K transcript varied no more than 1.5-fold during the cell cycle. The length of the 130K mRNA was determined to be 3.3 kilobases by Northern (RNA blot) analysis, indicating that the 130K mRNA is not part of a polycistron. The amino acid sequence predicted from the DNA sequence agreed well with the N-terminal amino acid sequence determined by sequencing of the 130K protein. The 130K protein appears to be synthesized without an N-terminal leader sequence, but the N-terminal 20 amino acids are relatively hydrophobic and may function like a signal sequence during transmembrane translocation.

A comparison of cytoplasmic revertants to fertility from different CMS-S maize sources

The mitochondrial genome organizations of a number of independent culture-derived fertile CMS-S revertants with the nuclear genotype W182BN were compared to spontaneous field revertants with the genotypes WF9, M825/Oh07 and 38-11. Regions of the genome around sequences homologous to the terminal repeats of the linear S1 and S2 episomes characteristic of CMS-S mitochondria were used as hybridization probes on Southern blots of BamHI and SalI digested mitochondrial DNA. The results obtained suggest that the nuclear, not the cytoplasmic, genotype of the parent plant affects the type of novel mitochondrial DNA organization found in the revertant. The DNA reorganization during reversion from CMS-S in tissue culture appears to be similar to that observed in spontaneous revertants obtained during the normal plant life-cycle. Unlike the situation for reversion from CMS-T, no common DNA sequence or reading frame appeared to be lost or disrupted in revertants.

Isolation of the gene encoding the S. cerevisiae heat shock transcription factor

The yeast heat shock transcription factor gene, HSF1, has been isolated from an S. cerevisiae genomic expression library (in lambda gt11). The sequenced gene encodes an 833 amino acid protein having a mass of 93,218 daltons. Expression of specific DNA-binding activity in E. coli and of transcriptional activity in yeast confirmed the identity of the cloned gene. Southern analysis and gene-disruption experiments indicate that the heat shock transcription factor is encoded by a single-copy, essential gene. The DNA-binding domain was localized to a 118 amino acid region in the amino-terminal third of the protein. Inspection of the DNA-binding domain reveals no resemblance to any currently known secondary structural motifs implicated in DNA recognition and binding.

Expression of herpes simplex virus type 1 (HSV-1) latency-associated transcripts and transcripts affected by the deletion in avirulent mutant HFEM: evidence for a new class of HSV-1 genes

During latent herpes simplex virus type 1 (HSV-1) infection in the trigeminal ganglia of mice, three virus-specific transcripts, 2.0, 1.5, and 1.45 kilobases (kb), are detectable by Northern (RNA) blot analysis, but only the 2.0-kb transcript can be detected in HSV-1-infected tissue culture cells (J.G. Spivack and N. W. Fraser, J. Virol. 61:3842-3847, 1987). Since these latency-associated genes map to a diploid region of the genome, transcription from the deletion mutant HFEM, which contains only one complete copy of these genes, was investigated to determine the effect of gene dosage. The 4.1-kb HFEM deletion is located between the alpha genes ICP0 and ICP27. ICP0 mRNA and the 2.0-kb latency-associated transcript were present at normal levels during HFEM infection, but ICP27 mRNA and 0.9- and 1.1-kb transcripts that map near the deletion were not readily detectable. The levels of expression of one or more of these genes might be an important determinant of HSV-1 virulence in animal hosts. ICP27 mRNA accumulated when protein synthesis was inhibited before HFEM infection, implying that the deletion may affect ICP27 regulatory rather than coding elements. Expression of the 2.0-kb latency-associated transcript was characterized in infected CV-1 cells with metabolic inhibitors and strand-specific probes. On the basis of metabolic inhibitor studies, the gene encoding the 2.0-kb latency-associated transcript is not an alpha gene. During HSV-1 replication in infected tissue culture cells, the beta and gamma genes require the prior expression of alpha gene products. However, the latency-associated RNAs are expressed in the absence of detectable levels of alpha transcripts in latently infected mice. Thus, this latency-associated gene family appear to be regulated quite differently than alpha, beta, or gamma genes. For these reasons, and because the latency-associated genes may perform latent rather than replicative functions, we propose that they should be considered members of a new HSV-1 gene class, the lambda genes.

Synthesis and turnover of late H2B histone mRNA in developing embryos of the sea urchin, Strongylocentrotus purpuratus

In sea urchins, "early" histone proteins are synthesized during cleavage and blastula formation, "late" histone proteins in subsequent stages of development. To understand the molecular mechanisms responsible for this ontogenic switch in histone subtype synthesis, we determined the absolute amounts, rates of synthesis, and rates of turnover of late H2b histone mRNAs during development. We showed previously that late H2b mRNA comprises several mRNA isotypes. In this study, we used both a class-specific DNA probe to measure the amounts of the late H2b mRNA isotypes collectively, and a gene-specific probe to measure amounts of a particular late H2b mRNA encoded by a gene known as L1. We found that the amount of late H2b mRNA increased dramatically from 85,000 molecules per embryo in the 16-hr blastula to a peak of 670,000 molecules per embryo in the 24-hr mesenchyme blastula, and fell to 380,000 molecules per embryo in the 72-hr pluteus larva. The L1 late H2b mRNA achieved its maximum abundance earlier than the late H2b mRNA class as a whole, reaching a peak of 34% of total late H2b in the 14-hr blastula and declining to 7% in the pluteus larva. Measurements of the rate of incorporation of [3H]uridine into late class H2b mRNA, performed by a novel in vivo isotope incorporation method, enabled us to calculate both synthesis rates and half-lives of late H2b mRNA during development. These calculations showed (1) that the increase in late H2b mRNA level between 16 and 24 hr postfertilization is regulated primarily if not entirely at the level of mRNA synthesis; and (2) that the half-life of late H2b mRNA is comparatively short, around 20 min, at all stages examined.

Latent herpes simplex virus type 1 transcription in human trigeminal ganglia

We studied latent herpes simplex virus type 1 gene expression in human trigeminal ganglia. Two transcripts were mapped to a 3.0-kilobase region within the long repeat region and appeared to be located in neuronal nuclei. These viral RNAs were not abundant during lytic replication and may represent an alternative pattern of herpes simplex virus type 1 gene expression involved in the pathogenesis of latent infection.

The molecular cloning of the chromogranin A-like precursor of beta-granin and pancreastatin from the endocrine pancreas

The cDNA encoding the precursor form of the chromogranin A-related proteins, beta-granin and pancreastatin, was obtained by immune screening of rat insulinoma and pancreatic islet cDNA libraries. The sequence was virtually identical to that of rat adrenal chromogranin A, suggesting that the different molecular forms of chromogranin A immunoreactivity found in adrenal medulla and endocrine pancreas are related to differences in post-translational proteolytic processing. The rat chromogranin A, unlike its bovine and human counterparts, contained a 20-residue glutamine sequence inserted within the N-terminal beta-granin sequence. Although the encoding CA(G/A) repeat recurs frequently in the rat genome, the rat chromogranin A molecule appears to be the product of a single gene and mRNA transcript.

Mild temperature shock affects transcription of yeast ribosomal protein genes as well as the stability of their mRNAs

Shifting the temperature of a yeast culture from 23 degrees to 36 degrees C results in a sudden and severe (greater than 85%) decline in the cellular levels of ribosomal protein (rp-)mRNAs. Recovery during continued growth at 36 degrees C occurs within 1 h. The use of hybrid genes carrying different portions of the region upstream of the gene coding for ribosomal protein L25 revealed that this characteristic, coordinate temperature shock phenomenon does not depend on the presence of specific upstream DNA sequences. Analysis of a heterologous gene carrying a synthetic UASrpg (upstream activation site of yeast ribosomal protein genes) provided conclusive evidence that the rp-characteristic, transient heat shock response is not mediated through the UASrpg elements. The addition of the transcription inhibitor 1,10-phenantroline prior to a 23 degrees to 36 degrees C heat shock inhibited the severe decline of the rp-mRNA levels. The latter observation indicates that transcription is required for the rp-gene- specific response to heat shock. A milder temperature shift, from 23 degrees to 30 degrees C, gave rise to a two-fold decrease in mRNA levels for all genes studied, both ribosomal and non-ribosomal. Together, these results indicate that a temperature shift causes a temporary general transcriptional arrest in yeast cells, resulting in an over-all decrease in mRNA levels. In addition, an enhanced nucleolytic break-down of pre-existing rp-mRNAs accounts for the dramatic drop in the steady state amounts of these mRNAs observed upon a 23 degrees----36 degrees C shift. This enhanced breakdown is caused directly or indirectly by a factor whose synthesis is induced by the heat shock treatment.

Yeast gene SRP1 (serine-rich protein). Intragenic repeat structure and identification of a family of SRP1-related DNA sequences

We have isolated and sequenced a yeast gene encoding a protein (Mr 24,875) very rich in serine (SRP) and alanine residues that accounted for 25% and 20% of the total amino acids, respectively. The SRP1 gene is highly expressed in culture conditions leading to glucose repression (Marguet & Lauquin, 1986), the amount of SRP1 mRNA representing about 1 to 2% of total poly(A)+ RNA. A repetitive structure of eight direct tandem repeats 36-base long, also reflected in the amino acid sequence, was found in the second half of the open reading frame. The consensus amino acid sequence of the repeat was Ser-Ser-Ser-Ala-Ala-Pro-Ser-Ser-Ser-Glu-Ala-Lys. Replacing the genomic copy of the cloned gene with a disrupted SRP1 gene indicated that the SRP1 gene was not essential for viability in yeast, but several SRP1-homologous sequences were found within the yeast genome, raising the possibility that the disrupted SRP1 gene is rescued by one of the other SRP-homologous sequences. Complete separation of yeast chromosomes by contour-clamped homogeneous field electrophoresis indicated that, apart from chromosome V, which carries the SRP1 gene, 12 chromosomes have SRP-related sequences with various degrees of homology. These sequences were located on chromosomes XV, VII and XI under stringent conditions of hybridization (tm -20 degrees C), and observed on chromosomes I, II, III, IV, VI, VIII, X, XI and XII, only under low-stringency conditions (tm -40 degrees C). Northern blot analysis of both the wild type and SRP1-disrupted strains indicated that along with SRP1 at least one more member of the SRP family was transcribed to a 0.7 kb (1 kb = 10(3) bases) polyadenylated RNA species clearly distinct from the SRP1-specific mRNA (1 kb long). Analyses of the SRP1 repeat domain suggested a model for the divergent evolution of the repeats in the SRP1 sequence.

Regional distribution of the expression of a human stimulatory GTP-binding protein alpha-subunit in the human brain studied by in situ hybridization

Using a cDNA probe complementary to an mRNA coding for the alpha-subunit of a human GTP-binding protein that stimulates adenylate cyclase we have studied its regional distribution in human brain by in situ hybridization histochemistry. The specificity of the hybridization signal was examined by using a labelled sense probe and RNase treatment. Gs alpha transcripts presented a widespread but heterogeneous distribution in human brain postmortem tissues. The cell bodies of the granular layer of the cerebellum were the most heavily labelled cells in all the cases examined. High levels of hybridization were also seen in the pyramidal cell layer of the hippocampus and over the cell bodies of the granule cells of the dentate gyrus. Several cortical regions also presented high levels of hybridization. Another area rich in the Gs alpha mRNA was the hypothalamus. The caudate and putamen nuclei presented intermediate levels while the globus pallidus, the thalamus, the midbrain and the brainstem presented only very low levels of hybridization. This distribution differs from the known distribution of adenylate cyclase activity and other GTP-binding proteins, and could indicate that this particular Gs alpha clone codes for a subset of the alpha-subunit of the Gs protein family.

Isolation of cDNAs of scrapie-modulated RNAs by subtractive hybridization of a cDNA library

We have developed a subtractive cloning procedure based on the hybridization of single-stranded cDNA libraries constructed in pi H3M, a vector containing the phage M13 origin of replication. We have used this strategy to isolate three transcripts whose abundance is increased in scrapie-infected brain. DNA sequence analysis showed that they represent glial fibrillary acidic protein, metallothionein II, and the B chain of alpha-crystallin; the latter two may represent a response to stress.

A 36-kilodalton Brucella abortus cell envelope protein is encoded by repeated sequences closely linked in the genomic DNA

Recombinant bacteriophage expressing Brucella abortus antigens have been isolated from a lambda gt11 expression library by using antibody raised against a sodium dodecyl sulfate-polyacrylamide gel electrophoresis-purified cell envelope protein of 36 kilodaltons. Fusion products expressed by these recombinants vary in apparent molecular mass by sodium dodecyl sulfate-polyacrylamide gel electrophoresis but only slightly exceed the size of beta-galactosidase. Western blot (immunoblot) analysis of crude lysates derived from lambda gt11 lysogens indicates that the fusion products react specifically with the original antisera used for recombinant selection and selectively bind antibody directed against the 36-kilodalton cell envelope protein. Analysis of the DNA inserts from 11 independently selected recombinants reveals similar-size EcoRI fragments which range in size from 150 to 300 base pairs (bp), all of which cross-hybridize via Southern blot analysis. Three independently selected EcoRI inserts ranging in size from 200 to 270 bp have been subcloned into M13mp18 and sequenced; all three contain a common region of about 200 bp. Southern blot analysis of B. abortus genomic DNAs digested with EcoRI, PstI, or DdeI indicates the presence of two fragments which hybridize to these DNA probes while single BamHI and HindIII fragments hybridize. The absence of these sites from the internal DNA sequence of the cloned probes suggests the presence of more than one copy of these sequences within the B. abortus genome. The same DNA probes have been used to select genomic clones of approximately 20 kbp from a lambda 2001 library. The lambda 2001 recombinants contain single BamHI fragments and two PstI fragments which hybridize to these oligonucleotide probe constructed on the basis of the amino-terminal sequence of the mature gene product hybridizes to the same BamHI and PstI fragments as the lambda gt11-derived DNA probe. Although the relative positions of the oligonucleotide sequences and the lambda gt11 insert within the genes is not known, the two sequences flank a region which corresponds to at least 40% of the size of the predicted gene. Additional experimentation must be performed to determine whether these sequences represent either two complete structural genes encoding major cell envelope proteins or repetitive sequences within a single structural gene.

A knotted free minicircle in kinetoplast DNA

Kinetoplast DNA, the mitochondrial DNA of trypanosomes, is a network containing thousands of minicircles that are topologically interlocked. The minicircle replication intermediates are free molecules that have been released from the network. We report here that one form of free minicircles is a trefoil knot. Identification of this knotted structure is based on its electrophoretic and sedimentation properties, its response to treatments with restriction enzymes or topoisomerase II, and its appearance by electron microscopy. Except for its topology, the knotted minicircle closely resembles a previously described replication intermediate with a unique gap in the newly synthesized L strand.

Excess antisense RNA from infectious recombinant SV40 fails to inhibit expression of a transfected, interferon-inducible gene

SV40-based infectious virus constructs were used to produce a high copy number of full-length antisense RNA in essentially every cell in a population. Chloramphenicol acetyltransferase (CAT) cDNA was placed in either the sense or antisense orientation relative to the SV40 early promoter in helper-free recombinant virus. RNA synthesized at high levels from the antisense virus was without effect on the expression of a stably-transfected CAT mini-gene controlled by an interferon-inducible promoter in monkey CV1 and large T antigen-expressing tsCOS cells. In double infection experiments the antisense RNA was similarly without effect on expression from CAT cDNA placed in the sense orientation in a second virus vector. No activation of the ppp(A2'p)nA(n greater than or equal to 2) system was observed after interferon treatment in either type of experiment. There was no evidence, therefore, for the formation of double-stranded (ds)RNA. It can be concluded that a large excess of a full-length antisense RNA is not necessarily sufficient to cause inhibition of gene expression even when interferon treatment is used to enhance any effect of dsRNA.

Primary structure and functional organization of Drosophila 1731 retrotransposon

We have determined the nucleotide sequence of the Drosophila retrotransposon 1731. 1731 is 4648 bp long and is flanked by 336 bp terminal repeats (LTRs) previously described as being reminiscent of provirus LTRs. The 1731 genome consists of two long open reading frames (ORFs 1 and 2) which slightly overlap each other. The ORF 1 and 2 present similarities with retroviral gag and pol genes respectively as shown by computer analysis. The pol gene exhibits several enzymatic activities in the following order: protease, endonuclease and reverse transcriptase. It is possible that 1731 also encompasses a ribonuclease H activity located between the endonuclease and reverse transcriptase domains. Moreover, comparison of the 1731 pol gene with the pol region of copia shows similarities extending over the protease, endonuclease and reverse transcriptase domains. We show that codon usage in the two retrotransposons is different. Finally, no ORF able to encode an env gene is detected in 1731.

Transcriptional organization of the phycocyanin subunit gene clusters of the cyanobacterium Anacystis nidulans UTEX 625

The phycocyanin subunit gene cluster is duplicated on the chromosome of the cyanobacterium Anacystis nidulans UTEX 625. The two gene clusters cpcB1A1 (left) and cpcB2A2 (right) are separated by about 2,500 base pairs, and in each cluster the beta-subunit gene is located upstream from the alpha-subunit gene. Filter hybridizations with phycocyanin-specific probes to total RNA detected at least two major transcripts that were 1,300 to 1,400 nucleotides long. Besides these major mRNA species, two minor transcripts of 3,400 and 3,700 nucleotides covering one of the gene clusters and the region between the clusters were found. No additional minor transcripts were found in the intergenic region between the two phycocyanin gene clusters. The lengths of the major mRNAs indicated that the beta- and alpha-subunit genes were cotranscribed. No apparent homologies were found when the DNA sequences located upstream from the proposed ribosome-binding site of the two phycocyanin beta-subunit genes were compared. Northern hybridizations with gene cluster-specific probes from the regions 5' of the beta-subunit genes, as well as S1 nuclease mapping and mRNA primer extension experiments, showed that both gene clusters were transcribed. The minor transcripts were found to initiate upstream from the left gene cluster. Two mRNA 5' ends were mapped upstream from the cpcB1A1 gene cluster, while only one 5' end was mapped in front of the cpcB2A2 gene cluster. All transcripts were present in RNA preparations from cultures grown under high levels of white light as well as under low levels of red light. The level of phycocyanin-specific mRNA, measured as part of the total RNA, was lower under low levels of red light compared with that under high levels of white light. Conserved sequence motifs were found when the promoter region of the cpcB1A1 gene cluster and promoter regions from other cyanobacterial photosynthesis genes were compared. The DNA sequences covering the proposed transcriptional attenuators and transcriptional stop signals contained several potential hairpin structures. One potential hairpin structure was located immediately downstream of the left phycocyanin gene cluster and was concluded to limit the level of transcription for the minor transcripts initiating upstream of the cpcB1A1 gene cluster.

Organization of RNA transcripts from a 7.8-kb region of the frog virus 3 genome

The detailed organization of the RNAs transcribed from a region of the FV 3 genome (Sa/I-F fragment and adjacent sequences) has been determined. The information was derived from the cell-free translation of hybrid-selected RNA to locate the genes encoding specific polypeptides, RNA filter hybridization to size the transcripts, and S1 nuclease mapping to locate the 5'- and 3'-ends of the RNAs on the genome. Three genes are contiguous and are transcribed from the same strand: two immediate early genes encoding transcripts of about 1.3 kb that directed the in vitro synthesis of 42K and 46K polypeptides, separated by the late gene encoding the major capsid protein (48K). At an advanced stage in infection, transcripts derived from the immediate early genes are also present. A set of RNAs with different 5'-ends ranging from 1.7 to 0.58 kb is produced from the p46 gene region whereas RNAs, 0.98 and 0.6 kb in size, complementary to the 5'-end of the p42 message, are synthesized. This gene cluster is located between two genes transcribed in the opposite direction from the rightward-reading strand: a late gene whose message is 0.5 kb in size and encodes a 15K polypeptide and a gene transcribed at immediate early and late times of infection which encodes a protein of 70 kDa. The 5'-end of the late RNA maps downstream of the 5'-end of the early one, their sizes being 1.85 and 2 kb, respectively, but both of them can be translated in vitro into a 70K polypeptide. These observations suggest that transcription is not regulated by the organization of the genes; they suggest rather that specific DNA sequences are responsible for the promotion of immediate early and late transcriptions.

The α1-tubulin gene of Arabidopsis thaliana: primary structure and preferential expression in flowers

The primary structure of the α1-tubulin gene of Arabidopsis thaliana was determined and the 5' and 3' ends of its transcript were identified by S1 nuclease mapping experiments. The information obtained was used to (i) predict the amino acid sequence of the α1-tubulin, (ii) deduce the positions of introns within the α1-tubulin gene, and (iii) construct 3' noncoding gene-specific hybridization probes with which to study the pattern of α1-tubulin transcript accumulation in different tissues and at different stages of development. The predicted amino acid sequence of the α1-tubulin has 92% identity with the predicted product of the previously characterized A. thaliana α3-tubulin gene. The coding sequence of the α1-tubulin gene is interrupted by four introns located at positions identical to those of the four introns in the α3 gene. RNA blot hybridization studies carried out with an α1-tubulin gene-specific probe showed that the α1 gene transcript accumulates primarily in flowers, with little transcript present in RNA isolated from roots or leaves. In order to investigate the pattern of α-tubulin gene expression in developing flowers, RNA was isolated from flowers at five different stages of development: flower buds, unopened flowers with pollen, open flowers, flowers with elongating carpels, and green seed pods. RNA blot hybridizations performed with 3' noncoding gene-specific probes showed that the α3 tubulin gene transcript is present in flowers at all stages of development, whereas the α1-tubulin gene transcript could only be detected in RNA from unopened flowers with pollen, open flowers, and flowers with elongating carpels.

The promoter of the beta-glucosidase gene from Kluyveromyces fragilis contains sequences that act as upstream repressing sequences in Saccharomyces cerevisiae

The relationship between the promoter length of the Kluyveromyces fragilis beta-glucosidase gene and the level of its expression in Saccharomyces cerevisiae was studied by gene fusion between deleted promoter fragments of various lengths and the promoterless beta-galactosidase gene of Escherichia coli. The removal of a region from position -425 to -232 led to a tenfold increase in the expression of the gene. The same results were obtained for the reconstructed beta-glucosidase gene with the same promoter length. It is likely that the deletion of this part of the promoter removes negative regulatory elements which are functional in Saccharomyces cerevisiae. This increase in activity is the main event which may explain the high increase in gene expression (60-fold) previously observed for an upstream deletion obtained during subcloning experiments of the beta-glucosidase gene. It is also shown that the expression of the gene greatly depends upon the nature of the recipient strain, the growth phase of the cell and that of the vector carrying it.

A γ-hordein gene

The 1614 bp nucleotide sequence of a barley gene encoding a γ-hordein endosperm storage polypeptide is presented. The deduced amino acid sequence is 305 amino acids long. It comprises a 19 amino acid signal peptide, an N-terminal half composed of proline-glutamine blocks organized in repeating units and a C-terminal half where the repeats are dispersed and less conserved. The deduced amino acid sequence shows strong homology to a γ-gliadin polypeptide from wheat and a γ-secalin polypeptide from rye and less homology to a B1 hordein polypeptide from barley. The 378 bp 5' non-coding region contains a TATA box at-85, an AGGA sequence at-105 and a-300 element typical of prolamin storage protein genes. The transcript start is 56 bp upstream of the ATG codon and 30 bp downstream of the TATA box. The 318 bp 3' non-coding region contains 2 putative polyadenylation signals, 76 and 132 bp downstream of the stop codon. γ-Hordein polypeptides are encoded by a small multigene family. The γ-hordein gene family is not part of the deleted chromosome 5 region, containing the Hor 2 locus, in the B hordein-deficient mutant hor 2ca. Two mRNA size classes of 1350 and 1450 nt are detectable in wild-type endosperms from 8 to 26 days after anthesis. The mutant hor 2ca contains as much γ-hordein mRNA as the wild type, whereas the B and C hordein-deficient mutant lys 3a contains barely detectable amounts.

M13 phage DNA as a universal marker for DNA fingerprinting of animals, plants and microorganisms

Hypervariable polymorphic patterns were detected with M13 phage DNA as a probe in genomic DNA of organisms belonging to different taxonomic groups including animals (vertebrates and invertebrates), plants and microorganisms. Individual-specific restriction pattern analysis (DNA fingerprinting) with this probe proved to be useful for individual identification, analysis of somatic stability and paternity testing in man. The nuclear type of inheritance indicates that the hypervariable DNA regions in question are located in the chromosomes, not in the mitochondrial DNA. The data obtained also demonstrate a potential range of M13 DNA applications as a probe for DNA fingerprinting of animals, plants and microorganisms, particularly for the determination of inbred lines, identification of bacterial strains and establishing stock, variety and strain distinctions.

Restriction fragment polymorphism in the sex-determining region of the Y chromosomal DNA of European wild mice

Using 32P-labeled probe consisting mainly of (GATA)n we have shown that a male specific Alu1 DNA blot pattern which defines the Y chromosome sex-determining locus in inbred mice is highly polymorphic in wild mice, indicating substantial sequence evolution in this region under field conditions. In all cases examined by in situ hybridization, the region concerned is paracentromeric. In contrast, the blot pattern of another probe (M 34) which detects repeated sequences specific to the mouse Y chromosome but outside the sex-determining locus, remains constant between different isolates.

The sheep metallothionein gene family. Structure, sequence and evolutionary relationship of five linked genes

Southern blot analysis of the sheep genome revealed a metallothionein gene family with at least nine members. Two overlapping cosmid clones spanning approximately 67 kb and containing five metallothionein genes have been isolated. DNA sequence analysis reveals that one of these is a metallothionein II variant, three are metallothionein I variants and one is a truncated metallothionein pseudogene containing only the first exon. The predicted amino acid sequence was compared with previously reported amino acid composition data of sheep metallothioneins [Whanger, P. D., Oh, S.-H. & Deagen, J. T. (1981) J. Nutr. 111, 1207-1215], and this suggests that we have isolated the genes encoding the major protein isoforms found in the sheep liver. The promoter regions of these genes contain many conserved elements, among them metal-regulatory elements and putative glucocorticoid-responsive elements. However, there are a number of differences between these genes in the arrangement of these elements. Sequence comparisons indicate that the multiple metallothionein I genes and the pseudogene appear to have resulted from sequential duplication events, and a larger cluster of metallothionein I genes may have been disrupted leading to the formation of the pseudogene.

Cytoplasmic assembly of snRNP particles from stored proteins and newly transcribed snRNA's in L929 mouse fibroblasts

Newly synthesized snRNAs appear transiently in the cytoplasm where they assemble into ribonucleoprotein particles, the snRNP particles, before returning permanently to the interphase nucleus. In this report, bona fide cytoplasmic fractions, prepared by cell enucleation, are used for a quantitative analysis of snRNP assembly in growing mouse fibroblasts. The half-lives and abundances of the snRNP precursors in the cytoplasm and the rates of snRNP assembly are calculated in L929 cells. With the exception of U6, the major snRNAs are stable RNA species; U1 is almost totally stable while U2 has a half-life of about two cell cycles. In contrast, the majority of newly synthesized U6 decays with a half-life of about 15 h. The relative abundances of the newly synthesized snRNA species U1, U2, U3, U4 and U6 in the cytoplasm are determined by Northern hybridization using cloned probes and are approximately 2% of their nuclear abundance. The half-lives of the two major snRNA precursors in the cytoplasm (U1 and U2) are approximately 20 min as determined by labeling to steady state. The relative abundance of the snRNP B protein in the cytoplasm is determined by Western blotting with the Sm class of autoantibodies and is approximately 25% of the nuclear abundance. Kinetic studies, using the Sm antiserum to immunoprecipitate the methionine-labeled snRNP proteins, suggest that the B protein has a half-life of 90 to 120 min in the cytoplasm. These data are discussed and suggest that there is a large pool of more stable snRNP proteins in the cytoplasm available for assembly with the less abundant but more rapidly turning-over snRNAs.

Differential expression of slow and fast skeletal muscle troponin C. Slow skeletal muscle troponin C is expressed in human fibroblasts

We have isolated and sequenced the cDNAs for human slow and fast skeletal muscle troponin C (TnC). Each cDNA is encoded by one of the two TnC genes in the human genome. The fast skeletal muscle TnC gene appears to be expressed exclusively in skeletal muscle. Only the slow TnC gene is expressed in human cardiac ventricle. The slow skeletal TnC gene is also expressed in skeletal muscle and, surprisingly, in several human fibroblast cell lines. Thus, at least one of the three proteins of the troponin complex appears to be expressed in non-muscle cells of higher vertebrates. The relative steady-state amounts of the slow and fast skeletal TnC mRNAs in various adult and embryonic striated muscles are similar to the expected amounts of the corresponding protein, suggesting that the expression of TnC genes is controlled predominantly by the production or accumulation of mRNA rather than by translational or post-translational mechanisms.

Comparison of the structure and cell cycle expression of mRNAs encoded by two histone H3-H4 loci in Saccharomyces cerevisiae

The haploid genome of Saccharomyces cerevisiae contains two nonallelic sets of histone H3 and H4 gene pairs, termed the copy I and copy II loci. The structures of the mRNA transcripts from each of these four genes were examined by nuclease protection and primer extension mapping. For each gene, several species of mRNAs were identified that differed in the lengths of their 5' and 3' untranslated regions. The cell cycle accumulation pattern of the H3 and H4 mRNAs was determined in cells from early-exponential-growth cultures fractionated by centrifugal elutriation. The RNA transcripts from all four genes were regulated with the cell division cycle, and transcripts from the nonallelic gene copies showed tight temporal coordination. Cell cycle regulation did not depend on selection of a particular histone mRNA transcript since the ratio of the multiple species from each gene remained the same across the division cycle. Quantitative measurements showed significant differences in the amounts of mRNA expressed from the two nonallelic gene sets. The mRNAs from the copy II H3 and H4 genes were five to seven times more abundant than the mRNAs from the copy I genes. There was no dosage compensation in the steady-state levels of mRNA when either set of genes was deleted. In particular, there was no increase in the amount of copy I H3 or H4 transcripts in cells in which the high-abundance copy II genes were deleted.

Mys retrotransposons in Peromyscus leucopus and transgenic Mus musculus

The mys family of retrotransposons exhibits an interesting phylogenetic distribution with 500-1000 copies per haploid genome in the white-footed mouse Peromyscus leucopus and no copies detectable in the house mouse Mus musculus, even though most other repeated sequences are shared by these two species. Comparison of the DNA sequences from the 3' ends of five mys elements show that insertion occurs just upstream of a well-conserved 11 bp target sequence. Transcription patterns of the elements in brain, liver, heart, kidneys and gonads in Peromyscus leucopus are analyzed. Transcripts are found in all tissues examined, but they are remarkably heterogeneous in size. When four cloned elements are introduced into transgenic Mus musculus, however, discrete patterns of expression are revealed. Furthermore, a study of the structure of the concatemers of mys elements in the transgenic mice demonstrates that recircularization of injected linear molecules is an important event in concatemer generation.