Analytical and preparative electrophoresis of RNA in agarose-urea.

Agarose-6 m urea gels at neutral pH stained with ethidium bromide give high resolution of complex mixtures of RNA molecules. These RNA species can be readily distinguished from contaminating DNA, which does not have to be purified away from the RNA, and electrophoresis can be carried out using phenol-saturated deproteinated cellular extracts without loss of resolution. Individual RNA species can be extracted from the gels by freezing, thawing, and centrifugation; the RNA may then be purified by phenol extraction and ethanol precipitation. Such purified RNA is an excellent substrate for RNA-DNA hybridization and cell-free translation. In addition, the RNA can be easily transferred with high resolution from the agarose-6 m urea gels to diazobenzyloxymethyl paper for subsequent hybridization to labeled DNA.     

Use of Mono Q high-resolution ion-exchange chromatography to obtain highly pure and active Escherichia coli RNA polymerase

A method for the purification of highly pure and active Escherichia coli RNA polymerase holoenzyme is described. This method is simple, reproducible, and can be performed at room temperature. The procedure involves the high-performance liquid chromatography of a partially purified RNA polymerase sample on a Mono Q ion-exchange column. Under the conditions used, RNA polymerase holoenzyme is well separated from the core RNA polymerase and other impurities. The purified RNA polymerase contains virtually no impurities as judged by SDS-polyacrylamide gel electrophoresis. The purified RNA polymerase holoenzyme contains the sigma 70 subunit in stoichiometric amounts and is at least 90% active.     

Isolation of a soluble and template-dependent poliovirus RNA polymerase that copies virion RNA in vitro.

A soluble RNA-dependent RNA polymerase was isolated from poliovirus-infected HeLa cells and was shown to copy poliovirus RNA in vitro. The enzyme was purified from a 200,000-X-g supernatant of a cytoplasmic extract of infected cells. The activity of the enzyme was measured throughout the purification by using a polyadenylic acid template and oligouridylic acid primer. The enzyme was partially purified by ammonium sulfate precipitation, glycerol gradient centrifugation, and phosphocellulose chromatography. The polymerase precipitated in a 35% saturated solution of ammonium sulfate, sedimented at about 7S on a glycerol gradient, and eluted from phosphocellulose with 0.15 M KC1. The polymerase was purified about 40-fold and was shown to be totally dependent on exogenous RNA for activity and relatively free of contaminating nuclease. The partially purified polymerase was able to use purified polio virion RNA as well as a template. Under the reaction conditions used, the polymerase required an oligouridylic acid primer and all four ribonucleside triphosphates for activity. The optimum ratio of oligouridylic acid molecules to poliovirus RNA molecules for priming activity was about 16:1. A nearest-neighbor analysis of the in vitro RNA product shows it to be heteropolymeric. Annealing the in vitro product with poliovirus RNA product shows it to be heteropolymeric. Annealing the in vitro product with poliovirus RNA rendered it resistant to RNase digestion, thus suggesting that the product RNA was complementary to the virion RNA template.     

Primer-dependent synthesis of covalently linked dimeric RNA molecules by poliovirus replicase.

Poliovirus-specific RNA-dependent RNA polymerase (replicase, 3Dpol) was purified from HeLa cells infected with poliovirus. The purified enzyme preparation contained two proteins of apparent molecular weights 63,000 and 35,000. The 63,000-Mr polypeptide was virus-specific RNA-dependent RNA polymerase, and the 35,000-Mr polypeptide was of host origin. Both polypeptides copurified through five column chromatographic steps. The purified enzyme preparation catalyzed synthesis of covalently linked dimeric RNA products from a poliovirion RNA template. This reaction was absolutely dependent on added oligo(U) primer, and the dimeric product appeared to be made of both plus- and minus-strand RNA molecules. Experiments with 5' [32P]oligo(U) primer and all four unlabeled nucleotides suggest that the viral replicase elongates the primer, copying the poliovirion RNA template (plus strand), and the newly synthesized minus strand snaps back on itself to generate a template-primer structure which is elongated by the replicase to form covalently linked dimeric RNA molecules. Kinetic studies showed that a partially purified preparation of poliovirus replicase contains a nuclease which can cleave the covalently linked dimeric RNA molecules, generating template-length RNA products.     

3' truncated tRNAArg is essential for in vitro specific cleavage of partially synthesized mouse 18S rRNA.

In vitro synthesized 5' portions of mouse 18S rRNA are cleaved efficiently at a specific site in partially purified extracts of mouse FM3A cells and several mouse tissues. This activity is composed of both protein and RNA, and can be reconstituted with the protein component in micrococcal nuclease-treated extracts and the RNA component in phenol-treated ones. The RNA component of about 65 nucleotides with the complementing activity was purified from total RNA in the partially purified FM3A cell extracts by polyacrylamide gel electrophoreses. Chemical sequencing of this RNA elucidated that it is tRNAArg lacking nine nucleotides from its 3' terminus. Ribonuclease H treatment directed by deoxyoligonucleotides complementary to tRNAArg completely abolishes the cleavage activity, supporting the above conclusion.     

Purification of virus-specific RNA from chicken cells infected with avian sarcoma virus: identification of genome-length and subgenome-leghth viral RNAs.

Avian sarcoma virus (ASV)-specific RNA was purified from ASV-infected cells by using hybridization techniques which employ polydeoxycytidylic acid-elongated DNA complementary to ASV RNA as well as chromatography on polyinosinic acid-Sephadex columns. The purity and nucleotide sequence composition of purified, virus-specific RNA were established by rehybridization experiments and analysis of labeled RNase T1-resistant oligonucleotides by two-dimensional polyacrylamide gel electrophoresis. Polyadenylic acid-containing RNA purified from ASV-infected cells contained approximately 1 to 4% virus-specific RNA, compared with 0.06 to 0.15% observed in uninfected cells. Sucrose gradient analysis of virus-specific RNA isolated from ASV-infected cells revealed two major classes of polyadenylated viral RNA with sedimentation values of 36S and 26-28S. Cells infected with transformation-defective ASV (virus containing a deletion of the sarcoma gene) contained 34S and 20-22S viral RNA species. Double-label experiments employing infected cells labeled initially for 48 h with [3H]uridine and then for either 30, 60, or 240 min with [32P]phosphate showed that the intracellular accumulation of genome-length RNA (36S) was significantly faster than that of the 26-28S viral RNA species.     

Partial purification of rat alpha-lactalbumin mRNA.

Alpha-lactalbumin messenger RNA was partially purified from RNA extracted from 3-5 day lactating rat mammary glands on a poly(U)-sepharose column followed by sucrose gradient centrifugation. Apha-Lactalbumin mRNA activity was assayed in wheat germ cell-free translational system by immunoprecipitation of the in vitro synthesized protein using specific antiserum prepared against purified rat alpha-lactalbumin. In the purified mRNA preparation alpha-lactalbumin mRNA activity comprised approximately 85% of the total mRNA activity.     

Studies on the low molecular weight RNA associated with 28S ribosomal RNA from Crotalus durissus terrificus liver.

A low molecular weight RNA was released from the purified rattlesnake 28 S RNA by brief heat treatment as well as by treatment with 80% dimethylsulfoxide or formamide. The sedimentation coeficient of this low molecular weight RNA was found to be 5.5 S, corresponding to a nucleotide number of 140 and a molecular weight of 46 000. It was also observed that 5.5S RNA is present in equimolar ratio to 5 S rRNA. Heat treatment of the purified 60 S ribosomal subunit also released the 5.5 S RNA. The possibility that this low molecular weight RNA is located on the surface of the large ribosomal subunit is discussed.     

Encapsidation of Sendai virus genome RNAs by purified NP protein during in vitro replication.

The ability of the Sendai virus major nucleocapsid protein, NP, to support the in vitro synthesis and encapsidation of viral genome RNA during Sendai virus RNA replication was studied. NP protein was purified from viral nucleocapsids isolated from Sendai virus-infected BHK cells and shown to be a soluble monomer under the reaction conditions used for RNA synthesis. The purified NP protein alone was necessary and sufficient for in vitro genome RNA synthesis and encapsidation from preinitiated intracellular Sendai virus defective interfering particle (DI-H) nucleocapsid templates. The amount of DI-H RNA replication increased linearly with the addition of increasing amounts of NP protein. With purified detergent-disrupted DI-H virions as the template, however, there was no genome RNA synthesis in either the absence or presence of the NP protein. Furthermore, addition of the soluble protein fraction of uninfected cells alone or in the presence of purified NP protein also did not support DI-H genome RNA synthesis from purified DI-H. Another viral component in addition to the NP protein appears to be required for the initiation of encapsidation, since the soluble protein fraction of infected but not uninfected cells did support DI-H genome replication from purified DI-H.     

口蹄疫病毒3D基因的克隆表达及功能分析

利用RT-PCR技术扩增了口蹄疫病毒(FMDV)编码RNA依赖的RNA聚合酶的3D基因,并将其克隆到原核表达质粒载体pET-28a( )中。3D基因经测序确认后在大肠杆菌BL-21中表达,表达产物纯化的目的蛋白进行Western-blotting检测,获得分子量约55KDa的单一3D基因表达产物。利用RNA体外复制体系和荧光定量PCR技术,证明纯化的3D基因表达产物RNA依赖的RNA聚合酶具有较高的酶活性,可以在体外从头合成FMDVRNA,且主要以引物依赖的方式合成病毒基因组。     

Demethylation of DNA by purified chick embryo 5-methylcytosine-DNA glycosylase requires both protein and RNA.

We have previously purified and characterized a 5-methylcytosine (5-MeC)-DNA glycosylase from 12 day old chick embryos [Jost,J.P. et al. (1995) J. Biol. Chem. 270, 9734-9739]. The activity of the purified enzyme is abolished upon treatment with proteinase K and ribonuclease A. RNA copurifies with 5-MeC-DNA glycosylase activity throughout all chromatographic steps and preparative gel electrophoresis. RNA with a length of approximately 300-500 nucleotides was isolated from the gel purified enzyme. Upon extensive treatment with proteinase K, the gel eluted and labeled RNA did not show any significant change in molecular mass. The purified RNA incubated alone or in the presence of Mg2+and deoxyribonucleotide phosphates had no 5-MeC-DNA glycosylase or demethylating activities. However, activity of 5-MeC-DNA glycosylase could be restored when the purified RNA was incubated with the inactive protein, free of RNA.     

RNase A及其链亲和素融合蛋白在pET系统中的表达

在大肠杆菌中用pET28a表达载体表达重组RNaseA。变性条件下,利用His-Resin亲和纯化,得到60mg／L电泳纯的RNaseA。纯化的RNaseA复性后,利用含大量RNA分子的碱法抽提质粒为底物,测定重组RNaseA活性,与商品化的RNaseA活性相当。同时在RNaseA活性测定体系中加入4mol／L尿素会使RNA分子切割效率提高10倍左右。在此基础上,成功表达RNaseA与链亲和素(streptavidjn)的融合蛋白,经纯化复性后,该融合蛋白同时具有核酸酶、biotin结合活性,在分子生物学中具有重要的应用价值。