RNA facilitates RecA-mediated DNA pairing and strand transfer between molecules bearing limited regions of homology

The RecA protein ofEscherichia coli catalyzes homologous pairing and strand exchange between a wide range of molecules showing nucleotide sequence complementarity, including a linear duplex and a single-stranded DNA molecule. We demonstrate that RecA can promote formation of joint molecules when the duplex contains an RNA/DNA hairpin and a single-stranded circle serves as the pairing partner. A chimeric RNA/DNA hairpin can be used to form stable joint molecules with as little as 15 bases of shared homology as long as the RNA stretch contains complementarity to the circle. The joint molecule bears some resemblance to a triple helical structure composed of RNA residues surrounded by two DNA strands which are in a parallel orientation. Evidence is presented that supports the notion that short stretches of RNA can be used in homologous pairing reactions at lengths below that required for DNA-DNA heteroduplex formation.     

Effect of actinomycin D on nucleic acid hybridization: the cause of erroneous DNA elongation during DNA synthesis of RNA tumor viruses in vitro

Actinomycin D, known for its suppression of cellular RNA synthesis and for the reduction of the rate of synthesis of double-stranded DNA by the RNA tumor virus RNA-dependent DNA polymerase, was found to interact with single-stranded DNA in such a way as to inhibit DNA . DNA and DNA . RNA hybridizations. This finding is discussed in the light of the observation that DNA elongation during DNA synthesis of RNA tumor viruses is blocked in vitro in the presence of actinomycin D. It thus supports the model that hybridization is a necessary step during RNA tumor virus DNA synthesis.     

Evolution of Tertiary Structure of Viral RNA Dependent Polymerases

Viral RNA dependent polymerases (vRdPs) are present in all RNA viruses; unfortunately, their sequence similarity is too low for phylogenetic studies. Nevertheless, vRdP protein structures are remarkably conserved. In this study, we used the structural similarity of vRdPs to reconstruct their evolutionary history. The major strength of this work is in unifying sequence and structural data into a single quantitative phylogenetic analysis, using powerful a Bayesian approach.The resulting phylogram of vRdPs demonstrates that RNA-dependent DNA polymerases (RdDPs) of viruses within Retroviridae family cluster in a clearly separated group of vRdPs, while RNA-dependent RNA polymerases (RdRPs) of dsRNA and +ssRNA viruses are mixed together. This evidence supports the hypothesis that RdRPs replicating +ssRNA viruses evolved multiple times from RdRPs replicating +dsRNA viruses, and vice versa. Moreover, our phylogram may be presented as a scheme for RNA virus evolution. The results are in concordance with the actual concept of RNA virus evolution. Finally, the methods used in our work provide a new direction for studying ancient virus evolution.     

Lutropin stimulation of RNA synthesis in corpus luteum chromatin.

Lutropin and human choriogonadotropin stimulated the endogenous chromatin-associated polymerase activity in purified chromatin prepared from nuclei of bovine corpus luteum. Chromatin was incubated in two different buffer systems: one that mainly supports the activity of polymerase I, another that supports the activity of polymerase II and is largely alpha-amanitin sensitive. The hormones lutropin and chorigonadotropin stimulated an increase in the rate of incorporation of [14C]ATP or [14C]UTP into RNA in both buffer systems. Follitropin, prolactin and beta-corticotropin had no stimulatory effect. Neither the alpha nor beta subunit of lutropin stimulated RNA synthesis. When premixed, the subunits rapidly formed the active molecule. A maximum response to RNA synthesis was achieved by a 10(-9) M concentration of human choriogonadotropin. Considerable activity was obtained at 10(-11) M human choriogonadotropin. There was no lutropin stimulation to RNA synthesis using calf thymus DNA and Escherichia coli RNA polymerase.     

6S RNA is a widespread regulator of eubacterial RNA polymerase that resembles an open promoter

6S RNA is an abundant noncoding RNA in Escherichia coli that binds to sigma70 RNA polymerase holoenzyme to globally regulate gene expression in response to the shift from exponential growth to stationary phase. We have computationally identified >100 new 6S RNA homologs in diverse eubacterial lineages. Two abundant Bacillus subtilis RNAs of unknown function (BsrA and BsrB) and cyanobacterial 6Sa RNAs are now recognized as 6S homologs. Structural probing of E. coli 6S RNA and a B. subtilis homolog supports a common secondary structure derived from comparative sequence analysis. The conserved features of 6S RNA suggest that it binds RNA polymerase by mimicking the structure of DNA template in an open promoter complex. Interestingly, the two B. subtilis 6S RNAs are discoordinately expressed during growth, and many proteobacterial 6S RNAs could be cotranscribed with downstream homologs of the E. coli ygfA gene encoding a putative methenyltetrahydrofolate synthetase. The prevalence and robust expression of 6S RNAs emphasize their critical role in bacterial adaptation.     

In vitro transcription of Drosophila ribosomal genes using Drosophila RNA polymerases

Drosophila RNA polymerases I &; II were used to transcribe a recombinant bacterial plasmid containing one copy of Drosophila ribosomal DNA. Both supercoiled and relaxed, closed circular plasmids were used. With Mg⁺² as the divalent cation, enzyme I is much more active on both forms of the plasmid; the relaxed form in particular supports almost no RNA synthesis by enzyme II. When Mn⁺² is present, differences in template efficiencies are minimal. The differences observed in the absence of Mn⁺² seem to depend only on different preferences for the physical state of the template and not on recognition of specific promotor sequences, since enzyme I shows no strand selection when transcribing these plasmids.     

迟钝爱德华氏菌RNA提取及痕量基因组DNA去除方法探究

迟钝爱德华氏菌EIB202是一类细胞壁结构特殊的革兰氏阴性菌,高质量RNA提取相对较难。为了从转录组水平研究这类致病菌的致病机理,需要摸索有效的RNA提取及RNA样品中痕量基因组DNA去除方法。对常规RNA提取步骤进行改进,增加PBS清洗、反复冻融及较高浓度溶菌酶处理等步骤;另外,利用小体系基因组DNA去除系统,Mg2+与Mn2+协同激活DNase I去除RNA样品中基因组DNA污染。利用优化方法提取的RNA在质量及浓度(1 740 ng/μL)方面均有了显著改善,并建立了一套完全去除RNA样品中痕量基因组DNA污染的程序。     

Characterization of RNA primers synthesized by the human breast cancer cell DNA synthesome

We previously reported on the purification and characterization of a functional multi‐protein DNA replication complex (the DNA synthesome) from human cells and tissues. The synthesome is fully competent to carry‐out all phases of the DNA replication process in vitro. In this study, DNA primase, a component of the synthesome, is examined to determine its activity and processivity in the in vitro synthesis and extension of RNA primers. Our results show that primase activity in the P4 fraction of the synthesome is 30‐fold higher than that of crude cell extracts. The synthesome synthesizes RNA primers that are 7–10 ribonucleotides long and DNA primers that are 20–40 deoxyribonucleotides long using a poly(dT) template of exogenous single‐stranded DNA. The synthesome‐catalyzed RNA primers can be elongated by E. coli DNA polymerase I to form the complementary DNA strands on the poly(dT) template. In addition, the synthesome also supports the synthesis of native RNA primers in vitro using an endogenous supercoiled double‐stranded DNA template. Gel analysis demonstrates that native RNA primers are oligoribonucleotides of 10–20 nt in length and the primers are covalently link to DNA to form RNA‐primed nascent DNA of 100–200 nt. Our study reveals that the synthesome model is capable of priming and continuing DNA replication. The ability of the synthesome to synthesize and extend RNA primers in vitro elucidates the organizational and functional properties of the synthesome as a potentially useful replication apparatus to study the function of primase and the interaction of primase with other replication proteins. J. Cell. Biochem. 106: 798–811, 2009. © 2009 Wiley‐Liss, Inc.     

SP6 RNA polymerase efficiently synthesizes RNA from short double-stranded DNA templates.

SP6 DNA-dependent RNA polymerase, like T7 RNA polymerase, can be used to synthesize RNA sequences from short DNA templates which contain the 18 base pair promoter region. Use of SP6 polymerase extends the range of possible 5' sequences of RNA products, since the preferred SP6 start site (of the RNA product) is 5'GAAGA, while T7 polymerase prefers 5'GGGAG. The SP6 start site can be advantageous in large-scale syntheses where high concentrations of RNA can lead to aggregation. Using the limited number of DNA templates described here, there appears to be a significant difference between the two enzymes: SP6 polymerase requires a complete duplex DNA substrate for efficient synthesis, unlike the T7 enzyme which works efficiently when only the 18 base promoter region is double-stranded. SP6 polymerase consistently produces higher yields of RNA than does T7 polymerase, and the reactions can be easily scaled up to produce milligram quantities of RNA.