In vitro Transcription of Kinetoplast and Nuclear DNA in Kinetoplastida*†

SYNOPSIS. DNA-dependent RNA polymerases have been solubilized from homogenates of Crithidia fasciculata using gentle extraction procedures. RNA polymerase I and II are separated on DEAE cellulose at 0.07M (NH₄)₂SO₄ and 0.13M (NH₄)₂SO₄ respectively. RNA polymerase II is inhibited 80% by α-amanitin (25 μg/ml). Both RNA polymerases require DNA as a template, ribonucleoside triphosphates and Mn²⁺. The synthesis of RNA as a product is inhibited by DNase. RNase, pronase and actinomycin D. Purified kinetoplast and nuclear DNA can serve as templates for the RNA polymerases. Denatured DNA templates are preferred. The synthesis of RNA continues for at least an hour and is inhibited by trypanocidal drugs including suramin. antrycide, acriflavine, ethidium bromide and berenil. Complementary RNA synthesized in vitro from C. fasciculata kinetoplast DNA hybridizes with C. fasciculata kinetoplast DNA but not with C. fasciculata nuclear DNA or Blastocrithidia culicis kinetoplast DNA, Escherichia coli, T4 or calf thymus DNAs. The complementary RNA synthesized in vitro from C.fasciculata kinetoplast DNA sediments at 4–5S.     

Synthesis and characterization of amplified DNA in oocytes of the house cricket,Acheta domesticus (Orthoptera: Gryllidae)

At a time in the life cycle when a large proportion of the oocytes of Acheta incorporate ³H-thymidine into an extrachromosomal DNA body, synthesis of a satellite or minor band DNA, the density of which is greater than main band DNA, is readily detected. Synthesis of the satellite DNA is not detectable in tissues, the cells of which do not have a DNA body, or in ovaries in which synthesis of extrachromosomal DNA by the oocytes is completed. The DNA body contains the amplified genes which code for ribosomal RNA. However, less than 1 percent of the satellite DNA, all of which appears to be amplified in the oocyte, is complementary to ribosomal 18S and 28S RNA. In situ hybridization demonstrates that non-ribosomal elements, like the ribosomal elements of the satellite DNA, are localized in the DNA body.Abbreviations used rRNA ribosomal RNA, includes 18S and 28S RNA - rDNA gene sequences complementary to rRNA - cRNA complementary RNA synthesized in vitro     

Non-specific incorporation of nucleic acid precursors in Blastomyces dermatitidis and Histoplasma capsulatum

Incorporation of thymidine, thymidine monophosphate (TMP), thymidine triphosphate (TTP), uridine and orotic acid into DNA, RNA and protein in Blastomyces dermatitidis and Histoplasma capsulatum was studied utilizing a specific acid hydrolysis technique developed for these fungi. Thymidine was incorporated to the greatest extent (approximately 0.5 % of added label) followed by uridine, orotic acid, TMP and TTP. In Blastomyces, uridine and orotic acid labeled primarily RNA. TMP and TTP labeled RNA, DNA and protein at nearly the same level. In Histoplasma RNA was labeled poorly by any of these precursors. TMP and TTP labeled DNA predominately and protein to a slightly lower level. Deoxyadenosine or uridine media supplements of 250 g/ml did not enhance incorporation. All precursors tested were found to be nonspecific in that RNA, DNA and protein were labeled. All data indicate that neither RNA nor DNA synthesis can be specifically measured in whole cells or acid precipitates by any of these precursors. Specific radiometric monitoring with these isotopes therefore requires the separation of these macromolecules.     

The chromosomal localization of a heavy satellite DNA in the testis of Plethodon c. cinereus

When DNA from blood or liver of Plethodon c. cinereus is centrifuged to equilibrium in cesium chloride it separates out into 2 components. The smaller or satellite component is relatively rich in G + C and is therefore heavy, and it amounts to about 2% of the total DNA. The heavy satellite does not include the ribosomal cistrons, and it is unrelated to the nucleolar organizer. When squash preparations of cells from the testis of P. c. cinereus are incubated in synthetic E³RNA complementary to the satellite DNA, the RNA anneals specifically to the centromeric heterochromatin of spermatogonia, spermatocytes, and spermatids, and to the centromeric regions of all discernible chromosomes. RNA/DNA hybrids were located by autoradiography. H³RNA complementary to the major component of the DNA anneals to all nuclei and to all parts of the chromosomes. H³RNA complementary to nucleolar DNA from Xenopus laevis anneals specifically to the chromatin associated with nucleoli in nuclei at various stages of the meiotic divisions. The nature of the centromeric heterochromatin and its role in the meiotic divisions are discussed.     

Identification of the lampbrush chromosome loops which transcribe 5S ribosomal RNA in Notophthalmus (Triturus) viridescens

The loops which transcribe 5S ribosomal RNA in lampbrush chromosomes of the newt, Notophthalmus (Triturus) viridescens, were identified by hybridizing purified 5S DNA to nascent 5S RNA in situ. The genes which code for 5S RNA were found near the centromeres of chromosomes 1, 2, 6, and 7 by hybridizing iodinated 5S RNA to denatured lampbrush and mitotic chromosomes in situ. These genes and their intervening spacer DNA were isolated from Xenopus laevis using sequential silver-cesium sulfate equilibrium centrifugations. This purified 5S DNA was iodinated and hybridized to non-denatured lampbrush chromosomes in situ, where it bound to nascent 5S RNA on loops at the base of the centromeres of chromosomes 1, 2, 6, and 7. The number of 5S genes present in the haploid chromosome complement of N. viridescens was determined. — The 5S loops were chosen for study, since (1) the synthesis of 5S RNA has been demonstrated during the lampbrush stage, (2) both 5S RNA and 5S DNA could be isolated in pure form, and (3) the localization of the repetitive 5S genes could be verified by conventional in situ hybridization procedures. These methods may be applicable to the identification of other loops, leading to a better understanding of lampbrush chromosome function.     

Quantitative micro-assay for RNA/DNA hybrids in the study of nucleolar RNA from Chironomus tentans salivary gland cells

A microassay for RNA/DNA hybrids has been designed for the study of RNA from different nuclear components of Chironomus tentans salivary gland cells. The procedure comprises a scale reduction of the conventional filter method for hybridization, using ultraviolet microphotometry for quantitation of RNA and DNA. Hybridization is performed in 0.3 μl of 2 × SSC containing 1–2 × 10^-2 μg DNA, immobilized on a 0.2 mm² ‘micro-filter’, and 0.5–5 × 10⁻² μg RNA, with a specific activity of more than 10⁶ cpm/μg. Results obtained by the microtechnique are found to agree with results obtained by a large-scale, standard procedure. The applicability of the microtechnique is demonstrated in saturation and presaturation-competition experiments. RNA from micro-isolated nucleoli hybridizes a maximum of 0.22% of Chironomus tentans DNA, which corresponds to about 100 cistrons for the 38S ribosomal precursor in the haploid genome. The hybrids show a steep thermal dissociation profile with a T_m of 79 °C, close to the value expected for hybrids with a G + C content of 42%. Presaturation of filter-bound DNA by total unlabelled nucleolar RNA prevents 80% of the subsequent hybridization by labeled nucleolar Presaturation by RNA from one of the two nucleolar organizers prevents to a similar degree the subsequent hybridization by RNA from the other nucleolar organizer. This result indicates a sequence similarity of RNA transcribed in different nucleolar organizers. Further applications of the microtechnique are presented in the accompanying paper where the hybridization properties of chromosomal and nuclear sap RNA are investigated.     

Studies on the functions of the RNA polymerase components by means of mutations

Summary It had been shown earlier, that RNA polymerase 13 S particles contain the large components with a molecular weight of about 3–10⁵ and small subunits with a molecular weight of 4·10⁴-1·10⁵. These polymerase components easily dissociate and reassociate with restoration of the enzyme activity.Both temperature-sensitive (tsX) and rifamycin-resistant (rif-r-I) mutations proved to affect the large polymerase component without changing the small subunits. These mutations were mapped at different, though closely linked, loci of metB-thi region of E. coli K12 chromosome. These results as well as certain literature data allow to conclude that the large RNA polymerase component consists of at least two polypeptides, one being altered by ts mutation, and the other—by rif-r mutation.The large polymerase component when separated from the small subunits retain the ability to bind to T2 phage DNA while the separate small subunits lack this property. Rifamycin does not affect RNA polymerase-T2 DNA binding while ts mutation leads to inability of the enzyme to form stable complexes with DNA. Therefore, it is likely that the polypeptide affected by ts mutation is responsible for the attachment of RNA polymerase to specific sites of DNA template. On the other hand, the small subunits as well as polypeptide of the large component, which determines RNA polymerase sensitivity to rifamycin, seem not to participate in the enzyme binding to DNA template. It is suggested, that the catalytic site of RNA polymerase is located in the large component and formed by rifamycin-binding polypeptide. The small subunits are supposed to have regulatory function and activate the large components.     

Fine structure physical mapping of 4S RNA genes on mitochondrial DNA of Saccharomyces cerevisiae.

Summary We have localized the genes for mitochondrial 4S RNA on the physical map of themtDNA of severalSaccharomyces cerevisiae strains by hybridization of iodinated 4S RNA to the restriction fragments obtained with endonucleasesHindII+III,EcoRI andHapII. The data indicate that 5–8 of the 4S RNA genes are dispersed over a large area of the genome whereas the rest (about 18 genes) is located within an area of about 9000 bp in length (about 12% of the genome) between the markers for chloramphenicol and paromomycin resistance (RIB 1 and PAR 1 loci). Within this region a cluster is present of 5 genes on a DNA fragment of 460 bp.Abbreviations Used mtDNA mitochondrial DNA - mtRNA mitochondrial RNA - rRNA ribosomal RNA - tRNA transfer RNA - C, E, P and O cytoplasmically-inherited resistance markers for chloramphenicol, erythromycin, paromomycin and oligomycin, respectively - SSC 150 mM sodium chloride, 15 mM sodium citrate (pH 7.0) - SDS sodium dodecylsulphate - EDTA (sodium)ethylenediaminetetraacetate; TEMED - N,N,N N-tetramethylethylenediamine; (k)bp, (kilo)base pairs - EthBr ethidium bromide     

Synthesis of the Oligoribonucleotides Incorporating 8-Oxo-Guanosine and Evaluation of their Base Pairing Properties

6-O-7-N-Bis(diphenylcarbamoyl)-2-N-phenoxyacetyl-5′-O-dimethoxytrityl-2′-O-{[(triisopropyl- silyl)oxy]methyl}-8-oxoguanosine-3′-yl-β-cyanoethyl-N,N-diisopropylphosphoramidite (5) was synt- hesized as a new phosphoramidite precursor unit for the synthesis of RNA. Compound 5 was successfully incorporated into the middle of the RNA sequences, and the synthesized RNAs were identified by MALDI-TOF mass measurements. Their properties were evaluated for formation of the RNA duplex and RNA/DNA heteroduplex. ORNs 1 and 4 containing 8-oxo-G can form base pairs with rC or dC in an anti conformation, while it can also interact with rA or dA in a syn conformation in the RNA duplex or RNA/DNA heteroduplex. The described synthetic method is therefore a useful procedure for the synthesis of ORN containing 8-oxo-G and contributes to the study of 8-oxo-G in RNA.     

Discrimination of competent Bacillus subtilis with respect to ribonucleic acids

Summary A study has been made of the affinity of double-stranded heliced RNA for DNA receptors in competent Bacillus subtilis. In competition experiments, using homologous and heterologous DNA samples which had been sheared to molecular weights comparable to that of the RNA (about 2×10⁶), and which still exhibited appreciable competition in DNA uptake experiments, the replicative form of phage f2 RNA showed no evidence of affinity for receptor sites. A second double-stranded RNA preparation from a widely different source, a mycophage of Penicillium chrysogenum, behaved similarly to the f2 RNA. Transfer RNA and 23S ribosomal RNA, which reduce transformation frequencies in pneumococcus, did not compete for B. subtilis receptors. Lack of competition was not due to enzymatic degradation of the RNA, since the latter was recovered intact following exposure to competent cells. Under conditions where homologous native DNA undergoes normal uptake, there was virtually no uptake of native double-stranded RNA. The results are examined in the light of reports on transformation by RNA and DNA-RNA hybrids, and also in relation to the characterization of the specificity of cell-nucleic acid interactions.     

pet 18: A chromosomal gene required for cell growth and for the maintenance of mitochondrial DNA and the killer plasmid of yeast

Summary Mutations in the pet18 gene of Saccharomyces cerevisiae (formerly denoted pets) confer three phenotypes on mutant strains: (i) inability to respire (petite), (ii) inability to maintain the double-stranded RNA killer plasmid (sensitive), and (iii) temperature sensitivity for growth. We find that pet18 mutants lack mitochondrial DNA. However, despite their inability to maintain the killer RNA plasmid and mitochondrial DNA, pet18 mutants still can carry the other yeast plasmids, [URE3-1], [PSI], and 2-micron DNA. The temperature sensitivity of the pet18 mutants is not expressed as a selective defect in total DNA, RNA, or protein synthesis.     

Repression of lipopolysaccharide biosynthesis in Escherichia coli by an antisense RNA of Acetobacter methanolicus phage Acm1

Lysogenic Acetobacter methanolicus strains carrying the prophage Acm1 were found to be unable to synthesize both the capsutar polysaccharide (CPS) and the O-specific side-chain of lipopolysaccharide (LPS) and to represent rough variants of the host bacterium. A 262 bp DNA fragment of phage Acm1, obviously required for interference with LPS biosynthesis, was cloned and expressed in Escherichia coli Independently of the O-type, transformation of various E. coli strains with the recombinant DNA resulted in a suppression of biosynthesis of the O-specific chains. The DNA fragment of phage Acm1 contained three very short open reading frames of 21, 24, and 36 bp. However, attempts to express phage-encoded peptides were not successful. Instead, the Acm1-derived DNA fragment was shown to code for the synthesis of a trans-acting RNA molecule of 97 nucleotides, designated lbi (L PS b iosynthesis-i nterfering) RNA. This RNA contains sequence complementarity to E. coli target RNA sequences and appears to have the ability to form intracellularly RNA hybrid duplexes with mRNA. The data presented in this study support the hypothesis that the phenotypic effect of conversion to rough-type LPS is accompanied by the expression of an antisense RNA of phage Acm1.     

Evolutionary conservation of DNA sequences expressed in sea urchin eggs and early embryos

Summary DNA sequence divergence measurements indicate thatStrongylocentrotus franciscanus is more distinct fromS. purpuratus andS. drobachiensis than these two species are from each other, in agreement with paleontological and morphological evidence. The evolutionary divergence of several classes of expressed DNA sequences was compared with that of total single-copy DNA. BetweenS. franciscanus andS. purpuratus the divergence of cDNA made from gastrula cytoplasmic poly(A)⁺ RNA is about half that of total single-copy DNA. Similar results were obtained for cDNA made from unfertilized egg poly(A)⁺ RNA. In contrast, sequences expressed in gastrula nuclear RNA have diverged almost as much as total single-copy DNA.     

Activities of DNA polymerases and RNA polymerases detected in situ in growing and differentiating cells of root cortex

Summary Activities of DNA polymerases and RNA polymerases were studied by autoradiographic methods in growing and differentiating root cortex cells ofZea mays — a species in which endomitosis occurs — andTulipa kaufmanniana — in which this process does not occur. InTulipa kaufmanniana, the highest activity of DNA polymerase appears in the nuclei of meristematic zone during the S phase of the cell cycle. InZea mays, endomitotic replication of DNA occurs in all growth and differentiation zones and the activity of DNA polymerase in the nuclei is similar to that in the meristematic zone. In both species, nuclear RNA synthesis, measured with³H uridine incorporation, is highest in the meristematic zone and declines steadily with development. Activity of nuclear RNA polymerase is present in all developmental zones in both species and is similar to that in the meristematic zone.³H uridine incorporation into nucleoli decreases markedly in both species, whereas the activity of nucleolar RNA polymerase remains at a high level in all root segments inZea mays and decreases slightly inTulipa kaufmanniana.It is argued that the differences between the incorporation of³H uridine and that or³H UMP may be caused by a reduction of the pool of endogenous ribonucleoside triphosphates. Marked activities of DNA polymerase and RNA polymerase in cytoplasm are possibly related to the growth and division of plastids and mitochondria.     

Variations in biochemical parameters of Heterocapsa sp. and Olisthodiscus luteus grown in 12:12 light:dark cycles I. Cell cycle and nucleic acid composition

The division cycle of two phytoplankton species, Olisthodiscus luteus and Heterocapsa sp. was studied in relation to a 12:12 light:dark cycle. Batch cultures in exponential phase were sampled every three hours during 48 hours. Cell number, cellular volume and DNA and RNA concentrations were measured. Microscopic observations of the nuclei of Heterocapsa sp. were also performed. In both species, cell division took place in the dark. In Heterocapsa sp., DNA and RNA showed a similar diel variability pattern, with synthesis starting at the end of the light period, previously to mitosis and cytokinesis. In O. luteus. Major RNA synthesis occurred during darkness, and DNA was produced almost continuously. Both species presented different values and diel rhythmicity on the RNA/DNA ratios.     

The Effects of Canavanine on Protein and Nucleic Acid Synthesis in Canavanine Resistant and Sensitive Species of Higher Plants

The effectiveness of the inhibitor, canavanine, was evaluated by examining its action in Canavalia ensiformis and Glycine max. Isolated roots were grown in culture tubes containing White's medium plus canavanine or arginine. A differential effect of canavanine on the incorporation of precursors of DNA, RNA, and protein was found, which is assumed to be related to the ability of the plant to utilize canavanine in reactions typically involving arginine. Canavanine was not found to affect DNA, RNA, or protein synthesis in Canavalia ensiformis, a plant in which this amino acid is synthesized naturally. In the canavanine sensitive species, Glycine max, of the same subfamily Papilionoideae, canavanine was observed to inhibit strongly DNA, RNA, and protein synthesis. A primary inhibition of the RNA synthesizing system is suggested. The data indicate the canavanine inhibitions are more complex than a simple competition with arginine in protein synthesis.     

Consequences of artificial and natural chromosome doubling on DNA,RNA and protein contents inCochlearia (Brassicaceae)

The effects of chromosome doubling on macromolecular composition, i.e. DNA, RNA and protein, were examined in diploidCochlearia pyrenaica DC., its established natural autotetraploidC. officinalis L., and their newly colchicine-induced autotetraploid and autooctoploid derivatives. DNA, RNA and protein contents increase from lower to higher ploidy levels (2x > 4x > 8x). The established natural autotetraploids and newly induced autotetraploids also differ, as DNA, RNA and protein have been reduced during the course of establishment. Net synthesis of RNA and protein per unit DNA does not change significantly neither from lower to higher ploidy levels nor between the autotetraploids of newly induced and established natural origins.