Superkiller mutations in Saccharomyces cerevisiae suppress exclusion of M2 double-stranded RNA by L-A-HN and confer cold sensitivity in the presence of M and L-A-HN.

In an mktl host, L-A-HN double-stranded RNA excludes M2 double-stranded RNA at 30 degrees C but not at 20 degrees C. Recessive mutations suppressing the exclusion of M2 by L-A-HN in an mktl host include six ski (superkiller) genes, three of which (ski6, ski7 and ski8) are new genes. The dominant mutations in one gene (MKS50) and recessive mutations in at least two genes (mks1 and mks2) suppress M2 exclusion by L-A-HN but do not show other characteristics of ski mutations and thus define a new class of killer-related chromosomal genes. Mutations in ski2, ski3, ski4, ski6, ski7, and ski8 result in increased M copy number at 30 degrees C and prevent the cells from growing at 8 degrees C. Elimination of M double-stranded RNA from a cold-sensitive ski- strain results in the loss of cold sensitivity. ski- [KIL-sd1] strains lack L-A-HN, carry L-A-E, and have a lower M1 copy number than do ski- [KIL-k1] strains and are only slightly cold sensitive. The LTS5 (=MAK6) product is required both for low temperature growth and for M1 maintenance or replication. We propose that the elevated levels of M in ski- strains divert the host LTS5 product away from the host and to the M replication process. We also suggest that the essential role of L-A in M replication is protection of M double-stranded RNA from the negative influence of SKI+ products.     

Hydration of short DNA, RNA and 2'-OMe oligonucleotides determined by osmotic stressing

Studies on hydration are important for better understanding of structure and function of nucleic acids. We compared the hydration of self-complementary DNA, RNA and 2′-O-methyl (2′-OMe) oligonucleotides GCGAAUUCGC, (UA)₆ and (CG)₃ using the osmotic stressing method. The number of water molecules released upon melting of oligonucleotide duplexes, Δn_W, was calculated from the dependence of melting temperature on water activity and the enthalpy, both measured with UV thermal melting experiments. The water activity was changed by addition of ethylene glycol, glycerol and acetamide as small organic co-solutes. The Δn_W was 3–4 for RNA duplexes and 2–3 for DNA and 2′-OMe duplexes. Thus, the RNA duplexes were hydrated more than the DNA and the 2′-OMe oligonucleotide duplexes by approximately one to two water molecules depending on the sequence. Consistent with previous studies, GC base pairs were hydrated more than AU pairs in RNA, whereas in DNA and 2′-OMe oligonucleotides the difference in hydration between these two base pairs was relatively small. Our data suggest that the better hydration of RNA contributes to the increased enthalpic stability of RNA duplexes compared with DNA duplexes.     

Study of DNA melting in the region of the inversion of relative stability of AT and GC pairs]

Systematic data on the dependence of the melting curve parameters of DNA from different organisms on the concentration of salt (C2H5)5NBr have been obtained. The melting curves were studied by spectrophotometric as well as by microcalorimetric methods. The DNA melting range width is shown to pass through the minimum value delta0T = 0.6 +/- 0.1 degrees at the point of inversion of relative stability of AT and GC pairs that corresponds to the concentration of (C2H5)4NBr equal to 2.9 +/- 0.1 M. This concentration, as well as the value of delta0T, are the same for different DNA's of common chemical structure. The T2 and T4 DNA containing hydroxymethylated and glucosylated cytosine residues show an anomalous behaviour. The enthalpy of melting falls very slowly as the salt concentration increases. The possible causes of the observed value of delta0T are discussed. A conclusion is drawn that the main factor which governs the DNA melting process in the region of inversion of the relative stability of AT and GC pairs is the heterogeneity of stacking interaction between different base pairs.     

Physico-chemical characteristics of the DNA of the nuclear polyhedrosis virus of the moth Porthetria dispar L

DNA preparations were obtained after dissolving the inclusion bodies, polyhedra virus particles, from the purified bundle virus of Porthetria dispar L. nuclear polyhedrosis. The DNA molecules in the preparations obtained are of different conformation and separate within the CsCl density gradient in the presence of ethidium bromide into supercoiled catenated and relaxed circular molecules (with the admixture of linear molecules). The circular DNA was studied by electron microscopy. The size of virus genome according to the data of reassociation kinetics of DNA is about 100 MD. Estimated on the basis of the values of buoyant density (p) and the melting temperature (Tmelt.) the content of guanine-cytosine pairs (GC pairs) in the viral DNA varies from 61 up to 65 mol%, and in the insect cell DNA--from 38 up to 40 mol%. The viral and cellular DNA are distinctly separated by centrifugation within the CsCl density gradient.     

Secondary structure of 5S RNA: NMR experiments on RNA molecules partially labeled with nitrogen-15

A method has been found for reassembling fragment 1 of Escherichia coli 5S RNA from mixtures containing strand III (bases 69-87) and the complex consisting of strand II (bases 89-120) and strand IV (bases 1-11). The reassembled molecule is identical with unreconstituted fragment 1. With this technique, fragment 1 molecules have been constructed 15N-labeled either in strand III or in the strand II-strand IV complex. Spectroscopic data obtained with these partially labeled molecules show that the terminal helix of 5S RNA includes the GU and GC base pairs at positions 9 and 10 which the standard model for 5S secondary structure predicts [see Delihas, N., Anderson, J., & Singhal, R. P. (1984) Prog. Nucleic Acid Res. Mol. Biol. 31, 161-190] but that these base pairs are unstable both in the fragment and in native 5S RNA. The data also assign three resonances to the helix V region of the molecule (bases 70-77 and 99-106). None of these resonances has a "normal" chemical shift even though two of them correspond to AU or GU base pairs in the standard model. The implications of these findings for our understanding of the structure of 5S RNA and its complex with ribosomal protein L25 are discussed.     

Thermodynamics and kinetics of the helix-coil transition of oligomers containing GC base pairs

Absorbance-temperature profiles have been determined for the following self-complementary oligonucleotides or equimolar paris of complementary oligonucleotides containing GC base pairs: A₂GCU₂, A₃GCU₃, A₄GCU₄, A₆CG + CGU₆, A₈CG + CGU₈, A₄G₂ + C₂U₄, A₅G₂ + C₂U₅, A₄G₃ + C₃U₄, and A₅G₃ + C₃U₅. In all cases cooperative melting transitions indicate double-helix formation. As was found previously, the stability of GC containing oligomer helices is much higher than that of AU helices of corresponding length. Moreover, helices with the same length and base composition but different sequences also have quite different stabilites. The melting curves were andlyzed using a zipper model and the thermodynamic parameters for the AU pairs determined previously. The effect of single-strand stacking was considered separately. According to this model, the formation of a GC pair from unstacked single strands is associated with an ethalpy change of ?15 kcal/mole. Due to the high degree of single-strand stacking at room temperature the enthalpy change for the formation of GC pairs from unstacked single strands is only ?5 to ?6 kcal/mole. (The corresponding parameters for AU pairs are ?10.7 kcal/mole and ?5 to ?6 kcal/mole.) The sequence dependence of helix stability seems to be primarily entropic since no differences in ΔH were seen among the sequence isomers. The kinetics of helix formation was investigated for the same molecules using the temperature jump technique. Recombination of strands is second order with rate constants in the range of 10⁵ to 10⁷M^?1 sec^?1 depending on the chain length and the nucleotide sequence. Within a series of oligomers of a given type, the rates of recombination decrease with increasing chain length. Oligomers with the sequence A_nGCU_n recombine six to eight times slower than the other oligomers of corresponding chain length. The experimental enthalpies of activation of 6 to 9 kcal/mole suggest a nucleation length of one or two GC base pairs. The helix dissociation process has rate constants between 0.5 and 500 sec^?1 and enthalpies of activation of 25 to 50 kcal/mole. An increase of chain length within a given nucleotide series leads to decreased rates of dissociation and increased enthalpies of activation. An investigation of the effect of ionic strength on A_nGCU_n helix formation showed that the rates of recombination increase considerably with increased ionic strength.     

Replicative DNA Polymerase δ but Not ε Proofreads Errors in Cis and in Trans

It is now well established that in yeast, and likely most eukaryotic organisms, initial DNA replication of the leading strand is by DNA polymerase ε and of the lagging strand by DNA polymerase δ. However, the role of Pol δ in replication of the leading strand is uncertain. In this work, we use a reporter system in Saccharomyces cerevisiae to measure mutation rates at specific base pairs in order to determine the effect of heterozygous or homozygous proofreading-defective mutants of either Pol ε or Pol δ in diploid strains. We find that wild-type Pol ε molecules cannot proofread errors created by proofreading-defective Pol ε molecules, whereas Pol δ can not only proofread errors created by proofreading-defective Pol δ molecules, but can also proofread errors created by Pol ε-defective molecules. These results suggest that any interruption in DNA synthesis on the leading strand is likely to result in completion by Pol δ and also explain the higher mutation rates observed in Pol δ-proofreading mutants compared to Pol ε-proofreading defective mutants. For strains reverting via AT→GC, TA→GC, CG→AT, and GC→AT mutations, we find in addition a strong effect of gene orientation on mutation rate in proofreading-defective strains and demonstrate that much of this orientation dependence is due to differential efficiencies of mispair elongation. We also find that a 3′-terminal 8 oxoG, unlike a 3′-terminal G, is efficiently extended opposite an A and is not subject to proofreading. Proofreading mutations have been shown to result in tumor formation in both mice and humans; the results presented here can help explain the properties exhibited by those proofreading mutants.     

Sequence analysis and in vitro maturation of five precursor 5S RNAs from Bacillus Q.

Bacillus Q, which is closely related to B. subtilis, contains at least six different precursors of 5S rRNA. The complete nucleotide sequences of four of these precursors, as well as the major part of the sequence of a fifth one, have been determined. They all contain the same 5'-terminal non-conserved segment which is to a large degree homologous with the corresponding segment of the B. subtilis p5S RNAs (Sogin, M.L., Pace, N.R., Rosenberg, M., Weissman, S.M. (1976) J. Biol. Chem. 251, 3480-3488). On the other hand the 3'-terminal non-conserved sequences of the various Bacillus Q precursors show considerable differences both in length and in nucleotide sequence, while there is also little or no homology with the 3'-terminal non-conserved sequence of the B. subtilis precursors. Bacillus Q p5S RNAs do not possess tetranucleotide repeats around the sites which are cleaved during maturation, as does B. subtilis p5S RNA. Like in B. subtilis, however, the cleavage sites are contained within a double-helical region of the precursor molecules. Crude RNAse M5 isolated from various Bacillus strains can maturate the Bacillus Q p5S RNAs with high efficiency. Despite considerable differences in primary structure between the precursors from the various strains, each RNAs M5 preparation can maturate all these precursors with about the same efficiency.     

Modulation of the stability of the Salmonella fourU-type RNA thermometer

RNA thermometers are translational control elements that regulate the expression of bacterial heat shock and virulence genes. They fold into complex secondary structures that block translation at low temperatures. A temperature increase releases the ribosome binding site and thus permits translation initiation. In fourU-type RNA thermometers, the AGGA sequence of the SD region is paired with four consecutive uridines. We investigated the melting points of the wild-type and mutant sequences. It was decreased by 5°C when a stabilizing GC basepair was exchanged by an AU pair or increased by 11°C when an internal AG mismatch was converted to a GC pair, respectively. Stabilized or destabilized RNA structures are directly correlated with decreased or increased in vivo gene expression, respectively. Mg(2+) also affected the melting point of the fourU thermometer. Variations of the Mg(2+) concentration in the physiological range between 1 and 2 mM translated into a 2.8°C shift of the melting point. Thus, Mg(2+) binding to the hairpin RNA is regulatory relevant. Applying three different NMR techniques, two Mg(2+) binding sites were found in the hairpin structure. One of these binding sites could be identified as outer sphere binding site that is located within the fourU motif. Binding of the two Mg(2+) ions exhibits a positive cooperativity with a Hill coefficient of 1.47. Free energy values ΔG for Mg(2+) binding determined by NMR are in agreement with data determined from CD measurements.     

Possible insertion sequences in a mosaic genome organization upstream of the exotoxin A gene in Pseudomonas aeruginosa.

Nucleotide sequence and Southern hybridization data revealed a mosaic genome organization in a region that extends several thousand base pairs upstream of the exotoxin A (toxA) gene in Pseudomonas aeruginosa. An interstrain comparison of DNA in this region showed a pattern of alternating segments of homologous and nonhomologous sequences. Two nonhomologous elements, approximately 1 kilobase pair upstream of the gene in strains PA103 and Ps388, were characterized in more detail. The sequence elements, denoted IS-PA-1 and IS-PA-2 for the different strains, are about 1,000 and 785 base pairs long, respectively, and have 5-base-pair direct repeats at their boundaries, consistent with their being DNA insertion sequences. The distribution of these elements in 34 different strains was determined. IS-PA-1 was found in a single copy upstream of toxA in half of the strains and was found in two copies in four of the strains. Some strains contained neither element, and one strain carried both. The genome of another strain, WR5, which lacks toxA, was shown to contain a 350-base-pair region that was highly homologous to DNA sequences located just upstream of toxA in other strains. The WR5 genome lacked several kilobase pairs of DNA that was found both upstream and downstream of this homologous region in the other strains.     

High base pair opening rates in tracts of GC base pairs

Sequence-dependent structural features of the DNA double helix have a strong influence on the base pair opening dynamics. Here we report a detailed study of the kinetics of base pair breathing in tracts of GC base pairs in DNA duplexes derived from 1H NMR measurements of the imino proton exchange rates upon titration with the exchange catalyst ammonia. In the limit of infinite exchange catalyst concentration, the exchange times of the guanine imino protons of the GC tracts extrapolate to much shorter base pair lifetimes than commonly observed for isolated GC base pairs. The base pair lifetimes in the GC tracts are below 5 ms for almost all of the base pairs. The unusually rapid base pair opening dynamics of GC tracts are in striking contrast to the behavior of AT tracts, where very long base pair lifetimes are observed. The implication of these findings for the structural principles governing spontaneous helix opening as well as the DNA-binding specificity of the cytosine-5-methyltransferases, where flipping of the cytosine base has been observed, are discussed.     

Pronounced instability of tandem IU base pairs in RNA

Optical melting was used to determine the stabilities of three series of RNA oligomers containing tandem XU base pairs, GGCXUGCC (5′XU3′), GGCUXGCC (5′UX3′) and GGCXXGGC/CCGUUCCG (5′XX3′), where X is either A, G or I (inosine). The helices containing tandem AU base pairs were the most stable in the first two series (5′XU3′ and 5′UX3′), with an average melting temperature ~11°C higher than the helices with tandem 5′GU3′ base pairs and 25°C higher than the helices with tandem 5′IU3′ base pairs. For the third series (5′XX3′), the helix containing tandem GG is the most stable, with an average melting temperature ~2°C higher than the helix with tandem AA base pairs and ~24°C higher than the helix with tandem II base pairs. The thermodynamic stability of the oligomers with tandem IU base pairs was also investigated as a function of magnesium ion concentration. As with normal A–U or G–U tandem duplexes, the data could best be interpreted as non-specific binding of magnesium ions to the inosine-containing RNA oligonucleotides.     

Genetic engineering of peptide hormones. I. Cloning and primary structure of cDNA of chicken growth hormone

The cDNA coding for the chicken growth hormone was cloned and sequenced. The 795 base pairs long cDNA insert contains a 5'-untranslated region (35 b.p.), a sequence coding for precursor of growth hormone (648 b.p.), a 3'-untranslated region (96 b.p.) and a poly(A)-tail (16 b.p.). Comparison of the cDNA sequence cloned by us with that published earlier revealed several differences including the additional unique HinfI site at the position corresponding to codons for Leu-87 and Thr-88.     

Features of two hepatitis B virus (HBV) DNA integrations suggest mechanisms of HBV integration.

Two integrated hepatitis B virus (HBV) DNA molecules were cloned from two primary hepatocellular carcinomas each containing only a single integration. One integration (C3) contained a single linear segment of HBV DNA, and the other integration (C4) contained a large inverted duplication of viral DNA at the site of a chromosome translocation (O. Hino, T.B. Shows, and C.E. Rogler, Proc. Natl. Acad. Sci. USA 83:8338-8342, 1986). Sequence analysis of the virus-cell junctions of C3 placed the left virus-cell junction at nucleotide 1824, which is at the 5' end of the directly repeated DR1 sequence and is 6 base pairs from the 3' end of the long (L) negative strand. The right virus-cell junction was at nucleotide 1762 in a region of viral DNA (within the cohesive overlap) which shared 5-base-pair homology with cellular DNA. Sequence analysis of the normal cellular DNA across the integration site showed that 11 base pairs of cellular DNA were deleted at the site of integration. On the basis of this analysis, we suggest a mechanism for integration of the viral DNA molecule which involves strand invasion of the 3' end of the L negative strand of an open circular or linear HBV DNA molecule (at the DR1 sequence) and base pairing of the opposite end of the molecule with cellular DNA, accompanied by the deletion of 11 base pairs of cellular DNA during the double recombination event. Sequencing across the inverted duplication of HBV DNA in clone C4 located one side of the inversion at nucleotide 1820, which is 2 base pairs from the 3' end of the L negative strand. Both this sequence and the left virus-cell junction of C3 are within the 9-nucleotide terminally redundant region of the HBV L negative strand DNA. We suggest that the terminal redundancy is a preferred topoisomerase I nicking region because of both its base sequence and forked structure. Such nicking would lead to integration and rearrangement of HBV molecules within the terminal redundancy, as we have observed in both our clones.