Characterization of poly(a)-protein complexes isolated from free and membrane-bound polyribosomes of Ehrlich ascites tumor cells

Proteins present in messenger ribonucleoprotein particles were labeled with [³⁵S]-methionine in Ehrlich ascites tumor cells in which synthesis of new ribosomes was inhibited. Poly(A)-protein complexes were isolated from free and membrane-bound polyribosomes by sucrose gradient centrifugation and affinity chromatography on oligo(dT)-cellulose. Both classes of Poly(A)-protein particles contain a poly(A) chain of about 70 adenyl residues and a protein with a molecular weight of 76000 attached to it.     

CHARACTERIZATION OF POLY(A) SEQUENCES IN BRAIN RNA

—Nuclear and polysomal brain RNA from the rabbit bind to Millipore filters and oligo(dT)-cellulose suggesting the presence of poly(A) sequences. The residual polynucleotide produced after RNase digestion of ³²P pulse-labelled brain RNA is 95% adenylic acid and 200-250 nucleotides in length. After longer isotope pulses the polysomal poly(A) sequence appears heterodisperse in size and shorter than the nuclear poly (A). Poly(A) sequences of brain RNA are located at the 3′-OH termini as determined by the periodate-[³H]NaBH₄ labelling technique. Cordycepin interferes with the processing of brain mRNA as it inhibits in vivo poly(A) synthesis by about 80% and decreases the appearance of rapidly labelled RNA in polysomes by about 45%. A small poly(A) molecule 10-30 nucleotides in length is present in rapidly labelled RNA. It appears to be less sensitive to cordycepin than the larger poly(A) and is not found in polysomal RNA.     

Poly(A)-protein interactions and transport of mRNA in isolated nuclei.

RNA-protein complexes (RNP), formed in a cell-free system using nuclei from GH cells, prelabelled, with [³H] leucine,were isolated from nucleoplasm and from postnuclear supernatant (PNS). Radioactive proteins, associated with newly synthesized HnRNP and mRNP-like material in the PNS were examined. On SDS gels, the [³H] protein pattern of poly(A)HnRNP was found to be more complex than that of PNS poly(A)-RNP. Only three radioactive proteins (78K, 100K and 120K) were associated with the poly(A) segments of cell-free formed HnRNP and PNS poly(A)-RNP. Cordycepintriphosphate and α-amanitin reduced the transport of cell-free formed poly(A) RNP associated [³H] proteins to the extent of 52% and 46% respectively. It may be concluded that the poly(A) segment of newly synthesized mRNA-like material is directly or indirectly (by providing binding sites for specific proteins) responsible for the transport of poly(A) containing mRNA.     

Erratum

RNA polynucleotide kinase has been shown to transfer [γ³²P] from ATP to 5-OH termini of endogenous nuclear RNA. The products of this reaction have been isolated in RNA larger than 125 after in vitro incubation of mouse L cell nuclei. About 20%–30% of these 5′-OH kinase products are polyadenylated. A sizeable fraction of the [γ³²P] label from ATP is also found in internal phosphodiester bonds after 30-minute nuclear incubation in vitro. The possibility of substantial [³²P] recycling via the α position of nucleoside triphosphate was ruled out because: (1) 2mM nucleoside triphosphates in the incubation medium, (2) limited nearestneighbor distribution 3′ and 5′ to the phosphodiester bond compared with that from [α³²P] UTP, (3) different nearest-neighbor distribution for RNA molecules > 12S and 12-3S, (4) relative insensitivity of the [γ³²P] incorporation to α-amanitin as compared with total RNA synthesis, (5) internal [³²P] appearance in RNA > 12S in less than five minutes of incubation, and (6) < 0.03% to 0.6% of the total [³²P] in the α position of nucleoside triphosphates after 30 minutes of incubation. The [γ³²P] incorporation was dependent on high ATP concentration and was insensitive to competition by inorganic phosphate. These results are consistent with the levels of 5′ RNA polynucleotide kinase activity in L cell nuclei and suggest the presence of an RNA ligase that can utilize the termini generated by the 5′-OH RNA kinase in a ligation reaction.     

Binding geometries of triple helix selective benzopyrido [4,3-b]indole ligands complexed with double- and triple-helical polynucleotides

The binding modes of three benzopyrido [4,3-b]indole derivatives (and one benzo[-f]pyrido [4-3b] quinoxaline derivative) with respect to double helical poly(dA) · poly(dT) and poly[d(A-T)]₂ and triple-helical poly(dA) · 2poly(dT) have been investigated using linear dichroism (LD) and CD: (I) 3-methoxy-11-amino-BePI where BePI = (7H-8-methyl-benzo[e]pyrido [4,3-b]indole), (II) 3-methoxy-11-[(3′-amino) propylamino]-BePI, (III) 3-methoxy-7-[(3′-diethylamino)propylamino] BgPI where BgPI = (benzo[g]pyrido[4,3-b]indole), and (IV) 3-methoxy-11-[(3′-amino)propylamino] B f P Q where B f P Q = {benzo[-f]pyrido[4-3b]quinoxaline}. The magnitudes of the reduced LD of the electronic transitions of the polynucleotide bases and of the bound ligands are generally very similar, suggesting an orientation of the plane of the ligands' fused-ring systems preferentially perpendicular to the helix axis. The LD results suggest that all of the ligands are intercalated for all three polynucleotides. The induced CD spectrum of the BePI chromophore in the (II-BePI)-poly[d(A-T)]₂ complex is almost a mirror image of that for the (I-BePI)-poly(dA) · poly(dT) and (I-BePI)-poly(dA) · 2poly(dT) complexes, suggesting an antisymmetric orientation of the BePI moiety upon intercalation in poly[d(A-T)]₂ compared to the other polynucleotides. The induced CD of I-BePI bound to poly(dA) · 2poly(dT) suggests a geometry that is intermediate between that of its other two complexes. The concluded intercalative binding as well as the conformational variations between the different BePI complexes are of interest in relation to the fact that BePI derivatives are triplex stabilizers. © 1997 John Wiley & Sons, Inc. Biopoly 42: 101–111, 1997     

Ontogeny of ppp(A2′p)nA-binding protein in mouse brain

Mouse brain tissue extracts at various stages of development show a drastic change in the specific activity of pp(A2′p)₂A-[³²P]pCp binding protein. Identification of the ppp(A2′p)₃A-[³²P]pCp binding protein was established by (i) binding to the specific ligand ppp(A2′p)₃A-[³²P]pCp, (ii) displacement of binding by nanomolar concentration of pppA(pA)₃, and (iii) affinity labeling techniques in which periodate oxidized ppp(A2′p)₃A-[³²P]pC was specifically cross-linked to a protein with a molecular weight of 86 000. These data suggest that the ppp(A2′p)₃A-[³²P]pCp protein is closely associated with the process of cellular proliferation and differentiation.     

Endonucleolytic cleavage of murine leukemia virus 35S RNA by microsome-associated nuclease.

Moloney murine leukemia virus 35S RNA (molecular weight 3 to 3.4 × 10⁶) is cleaved by nuclease activity present in microsomal fractions from MLV infected or uninfected mouse embryo cells to two RNA species of approximate molecular weights 1.8 × 10⁶ and 1.5 × 10⁶. Microsomal fractions from MLV infected and uninfected cells also contained nucleolytic activity that solubilized [³H]poly(A)·poly(U) but not [³H]poly(C) or [³H]poly(U); the cleavage of poly(A)·poly(U) was inhibited by ethidium bromide. The cleavage of MLV RNA was also inhibited by ethidium bromide, suggesting double stranded regions in 35S RNA as the site of cleavage.     

Evidence for a 5' leads to 3' direction of hydrolysis by a 5' mononucleotide-producing exoribonuclease from Saccharomyces cerevisiae.

[³H]rRNA labeled at the 5′ terminus with ³²P and [³H]rRNA labeled at the 3′ end with [¹⁴C] (pA)_n have been degraded at 0° with a highly purified exoribonuclease from $\text{Saccharomyces cerevisiae}$. The results show that with the [³²P, ³H] substrate, the ³²P label is rendered acid-soluble at a much faster rate than the ³H label. Both acid-soluble labels are found in 5′ mononucleotide. With the [¹⁴C, ³H]rRNA, the ³H label is hydrolyzed at a faster rate than the ¹⁴C label. The exoribonuclease hydrolyzes in the 5′ → 3′ direction.     

Enzymatic sulfation of a large molecular weight glycoprotein associated with pig brain membranes

Pig brain membranes catalyze the transfer of [³⁵S]sulfate from 3′-phosphoadenosine 5′-phospho[³⁵S]sulfate into two macromolecular endogenous acceptors. Several operational enzymatic properties of the sulfotransferase activity have been defined. An apparent K_m = 0.65 μm for 3′-phosphoadenosine 5′-phosphosulfate has been determined for the pig brain in vitro sulfotransferase system. Direct proof for the absolute requirement of the 3′-phosphate moiety of 3′-phosphoadenosine 5′-phosphosulfate is presented. The nucleotide end product, 3′,5′-ADP, is a potent competitive inhibitor of the pig brain sulfotransferase activity. One of the major products enzymatically labeled during incubation with 3′-phosphoadenosine 5′-phospho[³⁵S]sulfate is a membrane-bound glycoprotein of high molecular weight. The sulfated glycoprotein appears to be an integral membrane glycoprotein, requiring 1% Triton X-100 for extraction. An ³⁵S-labeled oligosaccharide, released by mild base treatment, contains O-sulfate ester groups and at least one N-acetylneuraminic acid residue. The sulfated glycoprotein has an apparent molecular weight of 198,000. Under the same in vitro conditions [³⁵S]sulfate is also incorporated into a membrane-associated ³⁵S-labeled proteoglycan having the properties of heparan sulfate. The ³⁵S-labeled proteoglycan is electrostatically bound to the pig brain membranes, and can be readily extracted with 1 m NaCl.     

The presence of polyriboadenylic acid sequences in calf lens messenger RNA

The presence of poly(rA) sequences in lens RNA has been demonstrated by the isolation of RNase A and T₁-resistant fragments of approximately 50 nucleotide residues. These poly(rA)-rich sequences, obtained from lenses incubated for six hours in organ culture with [³H]adenosine, are located at the 3′ termini of mRNA as determined by 3′ exoribonuclease digestion. Limited digestion of the [³H]adenosine-labeled mRNA with the enzyme led to the abolition of binding to poly(rU)-filters and a concomitant loss of template activity with avian myeloblastosis virus RNA-dependent DNA polymerase. Furthermore, after incubation of lenses in organ culture with 3′-deoxyadenosine, the isolated polysomal RNA was unable to function as a template in an avian myeloblastosis virus RNA-dependent DNA polymerase-catalyzed reaction system.     

Binding properties of Ru(II) polypyridyl complexes with poly(U)·poly(A)*poly(U) triplex: the ancillary ligand effect on third-strand stabilization

The binding properties of [RuL₂(mip)]²⁺ {where L is 1,10-phenanthroline (phen) or 4,7-dimethyl-1,10-phenanthrollne (4,7-dmp) and mip is 2′-(3″,4″-methylenedioxyphenyl)imidazo[4′,5′-f][1,10]phenanthroline} with regard to the triplex RNA poly(U)·poly(A)*poly(U) were investigated using various biophysical techniques and quantum chemistry calculations. In comparison with [Ru(4,7-dmp)₂(mip)]²⁺, remarkably higher binding affinity of [Ru(phen)₂(mip)]²⁺ for the triplex RNA poly(U)·poly(A)*poly(U) was achieved by changing the ancillary ligands. The stabilization of the Hoogsteen-base-paired third strand was improved by about 10.9 °C by [Ru(phen)₂(mip)]²⁺ against 6.6 °C by [Ru(4,7-dmp)₂(mip)]²⁺. To the best of our knowledge, [Ru(phen)₂(mip)]²⁺ is the first metal complex able to raise the third-strand stabilization of poly(U)·poly(A)*poly(U) from 37.5 to 48.4 °C. The results reveal that the ancillary ligands have an important effect on third-strand stabilization of the triplex RNA poly(U)·poly(A)*poly(U) when metal complexes contain the same intercalative ligands.     

A study of adenosine 3′–5′ cyclic monophosphate binding sites of human erythrocyte membranes using 8-azidoadenosine 3′–5′ cyclic monophosphate,a photoaffinity probe

An earlier report (1a) has shown the utility of 8-N₃cAMP (8-azidoadenosine-3′, 5′-cyclic monophosphate) as a photoaffinity probe for cAMP binding sites in human erythrocyte membranes. The increased resolution obtained using a linear-gradient SDS polyacrylamide gel system now shows that: (1) both cAMP and 8-N₃cAMP stimulate the phosphorylation by [γ-³²P]-ATP of the same red cell membrane proteins; (2) the protein of approximately 48,000 molecular weight whose phosphorylation by [γ-³²P]-ATP is stimulated by cAMP and 8-N₃cAMP migrates at a solwer rate than the protein in the same molecular weight range which is heavily photolabeled with [³²P]-8-N₃cAMP; (3) other cyclic nucleotide binding sites exist besides those initailly reported; (4) the variation in the ratio of incorporation of ³²P-8-N₃cAMP into the two highest affinity binding sites appears to be the result of a specific proteolysis of the larger protein.     

Processing of exogenous poly(A) added to virus-infected cells.

Exogenous [³H]-poly(A) was taken up by and was stable for some hours in monolayers of human embryo lung cells in culture. The poly(A) was extracted and sized by G200 Sephadex chromatography. Non-infected and virus-infected cells converted the majority of [³H]-poly(A) into a smaller poly(A) molecule which could still bind to oligo(dT)cellulose. In addition virus-infected cells only converted 11% into a poly(A) containing-molecule which was at least 4-fold greater in size than the original poly(A). This larger material could also bind to oligo(dT)cellulose and did not result from the breakdown and re-utilization of the [³H]-poly(A).     

The Use of Biotinylated Poly(ADP-Ribose) for Studies on Poly(ADP-Ribose)-Protein Interaction

Poly(ADP-ribose) is routinely detected by the use of radioactive polymers formed from labeled substrates. In this report a simple and time-saving method for the biotinylation and the detection of poly(ADP-ribose) on blots is described. The polymer modified by light-induced reaction with photobiotin was colorimetrically detected and quantified, using streptavidine-alkaline phosphatase conjugates. The separation of poly(ADP-ribose) chains on polyacrylamide gels was not affected by the biotinylation of the polymers. When biotinylated poly(ADP-ribose) was used to detect the poly(ADP-ribose) binding capability of proteins in ligand blots, the results were comparable to those obtained with poly([³²P]ADP-ribose). Experiments with histones and rat liver nuclear proteins demonstrate that in studies on poly(ADP-ribose)-protein interaction, this method is applicable to the detection of poly(ADP-ribose) binding proteins.     

A radiotracer enzyme assay for phosphofructokinase using ( , , -32P) adenosine triphosphate

A radiotracer enzyme assay for phosphofructokinase using adenosine 5′-triphosphate[α,β,γ-³²P] is described in this paper. Here the rates of appearance of both [1-³²P]d-fructose 1,6-diphosphate and [α,β-³²P] adenosine 5′-diphosphate were followed to establish enzyme activity. The unique advantages of multiple rate determinations in a single reaction sequence which accrue from the use of a readily available multiply labeled cosubstrate are discussed. By an extension of this approach other labeled(¹) nucleotides of the type, N(¹P)_n, and enzymes in the Enzyme Commision categories, EC 2.7(phosphotransferases) and EC 6.1–6.4(ligases) are equally amenable to radionuclide assay.     

Identification of a selenocysteine-specific aminoacyl transfer RNA from rat liver

The aminoacylation of rat liver tRNA with selenocysteine was studied in tissue slices and in a cell-free system with [⁷⁵Se]selenocysteine and [⁷⁵Se]selenite as substrates. [⁷⁵Se]Selenocysteyl tRNA was isolated via phenol extraction, 1 M NaCl extraction and chromatography on DEAE-cellulose. [⁷⁵Se]Selenocysteyl tRNA was purified on columns of DEAE-Sephacel, benzoylated DEAE-cellulose and Sepharose 4B. In a dual-label aminoacylation with [³⁵S]cysteme, the most highly purified ⁷⁵Se-fractions were > 100-fold purified relative to ³⁵S. These fractions contained < 0.7% of the [³⁵S]cysteine originally present in the total tRNA. When [³⁵Se]selenocysteyl tRNA was purified from a mixture of ¹⁴C-labeled amino acids, over 97% of the [¹⁴C]aminoacyl tRNA was removed. The [⁷⁵Se]selenocysteine was associated with the tRNA via an aminoacyl linkage. Criteria used for identification included alkaline hydrolysis and recovery of [⁷⁵Se]selenocysteine, reaction with hydroxylamine and recovery of [⁷⁵Se]selenocysteyl hydroxamic acid and release of ⁷⁵Se by ribonuclease. The specificity of [⁷⁵Se]selenocysteine aminoacylation was demonstrated by resistance to competition by a 125-fold molar excess of either unlabeled cysteine or a mixture of the other 19 amino acids in the cell-free selenocysteine aminoacylation system.     

Regulation of poly(A) polymerase activity and poly(A)+ RNA in germinated wheat embryos under conditions of pathogenesis

The induction of poly(A) polymerase was accompanied by a rise in the level of poly(A)⁺ RNA during early germination of excised wheat embryos (48 h). Fractionation of this RNA-processing enzyme by acrylamide gel electrophoresis and also by molecular sieving on Sephadex G-200 revealed a single molecular form of poly(A) polymerase with a molecular weight of 125 000. Wheat poly(A) polymerase specifically catalyzed the incorporation of [³H]AMP from [³H]ATP into the polyadenylate product only in the presence of primer RNA. Substitution of [³H]ATP by other labelled nucleoside triphosphates, such as [³H]GTP, [³H]UTP or [α-³²P]CTP in the assay mixture did not yield any labelled polynucleotide reaction product. The ³H-labelled reaction product was retained on poly(U)-cellulose affinity column and was not degraded by RNAase A and RNAase T₁ treatment. In addition, the nearest-neighbour frequency analysis of the ³²P-labelled reaction product predominantly yielded [³²P]AMP. Thus, characterization of the reaction product clearly indicated its polyadenylate nature. The average chain length of the [³H]poly(A) product was 26 nucleotides. Infection of germinating wheat embryos by a fungal pathogen (Drechslera sorokiana) brought about a severe inhibition (62–79%) of poly(A) polymerase activity. Concurrently, there was a parallel decrease (73%) in the level of poly(A)⁺ RNA. Inhibition of poly(A) polymerase activity in infected embryos could be due to enzyme inactivation, which in turn brought about a downward shift in the level of poly(A)⁺ RNA. The crude extract of the cultured pathogen contains a non-dialysable, heat-labile factor, which, along with a ligand, inactivates (65–74%) poly(A) polymerase in vitro. The fungal extracts also contained a dialysable, heat-stable stimulatory effector which activated wheat poly(A) polymerase (3.6–4.0-fold stimulation) in vitro. However, the stimulatory fungal effector was not expressed in vivo, but was detectable after the inhibitory fungal factor had been destroyed by heat-treatment in our in vitro experiments.     

Isoprenylated Proteins in Myelin

Abstract: Incubation of rat brainstem slices with [³H]- mevalonate ([³H]MVA) in the presence of lovastatin resulted in the incorporation of label into three groups of myelin-associated proteins with molecular masses of 47, 21–27, and 8 kDa, as revealed on sodium dodecyl sulfate- polyacrylamide rod gel electrophoresis. Although the gel patterns of [³H]MVA-derived prenylated proteins were similar, the relative level of ³H incorporated into each protein species differed between myelin and the brainstem homogenate. Immunoprecipitation studies identified the 47-kDa prenylated protein as a 2′-3′-cyclic nucleotide phospho- diesterase, whereas the 8-kDa protein proved to be the γ subunit of membrane-associated guanine nucleotide regulatory protein. The ³H-labeled 21–27-kDa group in myelin corresponds to the molecular mass of the extensive Ras- like family of monomeric GTP-binding proteins known to be prenylated in other tissues. Increase in lovastatin concentration resulted in reduced levels of [³H]MVA-labeled species in myelin and concomitantly increased levels in the cytosol. A cold MVA chase restored to normality the appearance of [³H]MVA-labeled proteins in myelin. Furthermore, a high lovastatin concentration in the brainstem slice incubation mixture altered the appearance of newly synthesized nonprenylated myelin proteins, including proteolipid protein and the 17-kDa subspecies of myelin basic protein. Because other myelin proteins were unaffected by the high lovastatin concentration, restricting the availability of MVA in myelin-forming cells may selectively alter processes required for myelinogenesis. Although the molecular basis for the” different MVA requirements in myelin- forming cells remains undefined, it may involve an alteration in the biological activity of certain proteins that require prenylation to be functionally active, and that are responsible for promoting insertion of specific proteins into the myelin membrane.     

DNA-Binding and Photocleavage Properties of Ru(II) Polypyridyl Complexes with DNA and Their Toxicity Studies on Eukaryotic Microorganisms

Four Ru(II) polypyridyl complexes, [Ru(bpy)₂(7-NO₂-dppz)]²⁺, [Ru(bpy)₂(7-CH₃-dppz)]²⁺, [Ru(phen)₂(7-NO₂-dppz)]²⁺, and [Ru(phen)₂(7-CH₃-dppz)]²⁺ (bpy = 2,2′-bipyridine, phen = 1,10-phenanthroline), (7-Nitro-dppz = 7-Nitro dipyrido[3,2-a:2′-3′-c]phenazine, 7-CH₃-dppz = 7-Methyl dipyrido[3,2-a:2′-3′-c]phenazine), have been synthesized and characterized by IR, UV, elemental analysis, ¹H NMR, ¹³C-NMR, and mass spectroscopy. The DNA-binding properties of the four complexes were investigated by spectroscopic and viscosity measurements. The results suggest that all four complexes bind to DNA via an intercalative mode. Under irradiation at 365 nm, all four complexes were found to promote the photocleavage of plasmid pBR 322 DNA. Toxicological effects of the selected complexes were performed on industrially important yeasts (eukaryotic microorganisms).