Analysis of the Saccharomyces cerevisiae exosome architecture and of the RNA binding activity of Rrp40p

The exosome is a complex of eleven subunits in yeast, involved in RNA processing and degradation. Despite the extensive in vivo functional studies of the exosome, little information is yet available on the structure of the complex and on the RNase and RNA binding activities of the individual subunits. The current model for the exosome structure predicts the formation of a heterohexameric RNase PH ring, bound on one side by RNA binding subunits, and on the opposite side by hydrolytic RNase subunits. Here, we report protein-protein interactions within the exosome, confirming the predictions of constituents of the RNase PH ring, and show some possible interaction interfaces between the other subunits. We also show evidence that Rrp40p can bind RNA in vitro, as predicted by sequence analysis.     

REGULATION OF PROTEIN SYNTHESIS IN DEVELOPING MOUSE BRAIN TISSUE: IN VITRO BINDING OF TEMPLATE RNA TO BRAIN RIBOSOMES

Abstract— Ribosomes, isolated from brain tissue of mice of various ages, were tested for their ability to participate in cell-free protein synthesis and to bind polyuridylic acid. Although protein synthesis was markedly reduced by ribosomal preparations obtained from increasingly older animals, no significant differences could be measured with respect to template RNA binding. Similar binding properties were also measured with ribosomal subunits purified from young and mature brain cell ribonucleoprotein particles. In addition, no differences could be detected in the relative firmness of template RNA binding that could explain the maturation-dependent loss in ribosomal activity.     

The role of Halobacterium cutirubrum deoxyribonucleic acid-dependent ribonucleic acid polymerase subunits in initiation and polymerization

1. The two subunits alpha and beta of Halobacterium cutirubrum DNA-dependent RNA polymerase are required in equimolar amounts for RNA synthesis to occur in vitro at the maximum rate. 2. In the absence of bivalent cations no interaction occurs between alpha and beta subunits or between the subunits and DNA. 3. Mn(2+) causes the subunits to form a 1:1 complex that still does not bind to the template. 4. Mg(2+) permits binding of the Mn(2+)-mediated complex to DNA. 5. The complete enzyme, alphabeta, is inhibited by rifampicin and only the beta subunit relieves the inhibition when added in excess. 6. Rifampicin-insensitive, template-dependent RNA synthesis occurs in the presence of protein alpha alone provided an oligonucleotide with a 5'-purine terminus is supplied as primer. 7. In the primed reaction with the alpha protein and an oligonucleotide, the template specificity is independent of the ionic strength, in contrast with the marked effect of salt concentration on the template specificity of the complete enzyme. 8. It is concluded that the beta protein controls the specificity of chain initiation and the template specificity of the complete enzyme and also carries the rifampicin-binding site, whereas the catalytic site is on the alpha subunit.     

The role of subunits in yeast DNA-dependent ribonucleic acid polymerase A.

The properties of RNA polymerase A, which lacked the subunits of 48 000, 37 000 and 16 000 mol. wt., were compared with those of RNA polymerase A by using native calf thymus DNA as the template. The results showed that: (1) the specific activity of RNA polymerase A was about one-third that of RNA polymerase A; (2) more than 80% of RNA polymerase A, but only about 25% of RNA polymerase A, made RNA; (3) initiation by RNA polymerase A, but not by RNA polymerase A, began after a lag of 2 min; (4) the temperature-dependence for productive binding to DNA was greater for RNA polymerase A; (5) the apparent Km for UTP was greater for RNA polymerase A. These results support the supposition that the subunits missing from RNA polymerase A are involved in DNA binding [Huet, Dezélée, Iborra, Buhler, Sentenac & Fromageot (1976) Biochimie 58, 71-80] and show also that the loss of these subunits affects the elongation reaction.     

Role of Subunits of 60 to 70S Avian Tumor Virus Ribonucleic Acid in Its Template Activity for the Viral Deoxyribonucleic Acid Polymerase

Heating the 60 to 70S ribonucleic acid (RNA) of Rous sarcoma virus (RSV) destroys both its subunit structure and its high template activity for RSV deoxyribonucleic acid (DNA) polymerase. In comparative analyses, it was found that the template activity of the RNA has a thermal transition of 70 C, whereas the 60 to 70S structure dissociates into 30 to 40S and several distinct small subunits with a T(m) of 55 C. Analysis by velocity sedimentation and isopycnic centrifugation of the primary DNA product obtained by incubation of 60 to 70S RSV RNA with RSV DNA polymerase indicated that most, but perhaps not all, DNA was linked to small (<10S) RSV RNA primer. Sixty percent of the high template activity of 60 to 70S RSV RNA lost after heat dissociation could be recovered by incubation of the total RNA under annealing conditions. The template activity of purified 30 to 40S subunits isolated from 60 to 70S RSV RNA was not enhanced significantly by annealing. However, in the presence of small (<10S) subunits also isolated from 60 to 70S RNA, the template activity of 30 to 40S RNA subunits was increased to the same level as that of reannealed total 60 to 70S RNA. It was concluded that neither the 30 to 40S subunits nor most of the 4S subunits of 60 to 70S RSV RNA contribute much as primers to the template activity of 60 to 70S RSV RNA. The predominant primer molecule appears to be a minor component of the <10S subunit fraction of 60 to 70S RSV RNA. Its electrophoretic mobility is similar to, and its dissociation temperature from 60 to 70S RSV RNA is higher than that of the bulk of 60 to 70S RSV RNA-associated 4S RNA. The role of primers in DNA synthesis by RSV DNA polymerase is discussed.     

Insight into the Human DNA Primase Interaction with Template-Primer

DNA replication in almost all organisms depends on the activity of DNA primase, a DNA-dependent RNA polymerase that synthesizes short RNA primers of defined size for DNA polymerases. Eukaryotic and archaeal primases are heterodimers consisting of small catalytic and large accessory subunits, both of which are necessary for the activity. The mode of interaction of primase subunits with substrates during the various steps of primer synthesis that results in the counting of primer length is not clear. Here we show that the C-terminal domain of the large subunit (p58_C) plays a major role in template-primer binding and also defines the elements of the DNA template and the RNA primer that interact with p58_C. The specific mode of interaction with a template-primer involving the terminal 5′-triphosphate of RNA and the 3′-overhang of DNA results in a stable complex between p58_C and the DNA/RNA duplex. Our results explain how p58_C participates in RNA synthesis and primer length counting and also indicate that the binding site for initiating NTP is located on p58_C. These findings provide notable insight into the mechanism of primase function and are applicable for DNA primases from other species.     

RBRDetector: Improved prediction of binding residues on RNA‐binding protein structures using complementary feature‐ and template‐based strategies

Computational prediction of RNA‐binding residues is helpful in uncovering the mechanisms underlying protein‐RNA interactions. Traditional algorithms individually applied feature‐ or template‐based prediction strategy to recognize these crucial residues, which could restrict their predictive power. To improve RNA‐binding residue prediction, herein we propose the first integrative algorithm termed RBRDetector (RNA‐Binding Residue Detector) by combining these two strategies. We developed a feature‐based approach that is an ensemble learning predictor comprising multiple structure‐based classifiers, in which well‐defined evolutionary and structural features in conjunction with sequential or structural microenvironment were used as the inputs of support vector machines. Meanwhile, we constructed a template‐based predictor to recognize the putative RNA‐binding regions by structurally aligning the query protein to the RNA‐binding proteins with known structures. The final RBRDetector algorithm is an ingenious fusion of our feature‐ and template‐based approaches based on a piecewise function. By validating our predictors with diverse types of structural data, including bound and unbound structures, native and simulated structures, and protein structures binding to different RNA functional groups, we consistently demonstrated that RBRDetector not only had clear advantages over its component methods, but also significantly outperformed the current state‐of‐the‐art algorithms. Nevertheless, the major limitation of our algorithm is that it performed relatively well on DNA‐binding proteins and thus incorrectly predicted the DNA‐binding regions as RNA‐binding interfaces. Finally, we implemented the RBRDetector algorithm as a user‐friendly web server, which is freely accessible at http://ibi.hzau.edu.cn/rbrdetector . Proteins 2014; 82:2455–2471. © 2014 Wiley Periodicals, Inc.     

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.     

Structural insight into the essential PB1–PB2 subunit contact of the influenza virus RNA polymerase

Influenza virus RNA‐dependent RNA polymerase is a multi‐functional heterotrimer, which uses a ‘cap‐snatching’ mechanism to produce viral mRNA. Host cell mRNA is cleaved to yield a cap‐bearing oligonucleotide, which can be extended using viral genomic RNA as a template. The cap‐binding and endonuclease activities are only activated once viral genomic RNA is bound. This requires signalling from the RNA‐binding PB1 subunit to the cap‐binding PB2 subunit, and the interface between these two subunits is essential for the polymerase activity. We have defined this interaction surface by protein crystallography and tested the effects of mutating contact residues on the function of the holo‐enzyme. This novel interface is surprisingly small, yet, it has a crucial function in regulating the 250 kDa polymerase complex and is completely conserved among avian and human influenza viruses.     

Letter: functional form of RNA synthesis termination factor rho

The ability of rho factor to effect in vitro termination of RNA synthesis requires the association of rho monomers into an oligomer consisting of at least four subunits. It was found that (1) rho factor activity has a sigmoidal dependence upon concentration, and (2) rho factor's sedimentation coefficient decreases with decreasing concentration, proceeding through 8.5 S (tetramer), 6.2 S (dimer) and finally 4.3 S (monomer) forms as the concentration approaches the apparent equilibrium binding constant. Rho factor may function at specific sites in the DNA template through the co-operative binding of subunits into an oligomer which surrounds the DNA helix.     

Characterization of a trp RNA-binding attenuation protein (TRAP) mutant with tryptophan independent RNA binding activity

TRAP (trp RNA-binding attenuation protein) is an 11 subunit RNA-binding protein that regulates expression of genes involved in tryptophan metabolism (trp) in Bacillus subtilis in response to changes in intracellular tryptophan concentration. When activated by binding up to 11 tryptophan residues, TRAP binds to the mRNAs of several trp genes and down-regulates their expression. Recently, a TRAP mutant was found that binds RNA in the absence of tryptophan. In this mutant protein, Thr30, which is part of the tryptophan-binding site, is replaced with Val (T30V). We have compared the RNA-binding properties of T30V and wild-type (WT) TRAP, as well as of a series of hetero-11-mers containing mixtures of WT and T30V TRAP subunits. The most significant difference between the interaction of T30V and WT TRAP with RNA is that the affinity of T30V TRAP is more dependent on ionic strength. Analysis of the hetero-11-mers allowed us to examine how subunits interact within an 11-mer with regard to binding to tryptophan or RNA. Our data suggest that individual subunits retain properties similar to those observed when they are in homo-11-mers and that individual G/UAG triplets within the RNA can bind to TRAP differently.     

Mechanism of inhibition of Escherichia coli RNA polymerase by captan.

Captan (N-trichloromethylthiocyclohex-4-ene-1,2-dicarboximide) was shown to inhibit RNA synthesis in vitro catalysed by Escherichia coli RNA polymerase. Incorporation of [gamma-32P]ATP and [gamma-32P]GTP was inhibited by captan to the same extent as overall RNA synthesis. The ratio of [3H]UTP incorporation to that of [gamma-32P]ATP or of [gamma-32P]GTP in control and captan-treated samples indicated that initiation was inhibited, but the length of RNA chains being synthesized was not altered by captan treatment. Limited-substrate assays in which re-initiation of RNA chains did not occur also showed that captan had no effect on the elongation reaction. Studies which measured the interaction of RNA polymerase with template DNA revealed that the binding of enzyme to DNA was inhibited by captan. Glycerol-gradient sedimentation of the captan-treated RNA polymerase indicated that the inhibition of the enzyme was irreversible and did not result in dissociation of its subunits. These data are consistent with a mechanism in which RNA polymerase activity was irreversibly altered by captan, resulting in an inability of the enzyme to bind to the template. This interaction was probably at the DNA-binding site on the polymerase and did not involve reaction of captan with the DNA template.     

Identification of several proteins involved in the messenger RNA binding site of the 30 S ribosome by inactivation with 2-methoxy-5-nitrotropone

Chemical modification of unwashed 30 S ribosomal subunits with 2-methoxy-5-nitrotropone causes a rapid loss of their capacity to bind bacteriophage Qβ RNA. Reconstitution experiments show that ribosomal protein is the functionally inactivated species. When purified unmodified ribosomal proteins were included in a mixture of 16 S ribosomal RNA and total protein derived from 2-methoxy-5-nitrotropone-treated subunits, four proteins (S1, S12, S13 and S21) were found to promote the reconstitution of particles capable of binding natural messenger RNA.