Crosslinking of proteins to ribosomal RNA in HeLa cell polysomes by sodium periodate.

HeLa cell polysomes were oxidized with sodium periodate and reduced with sodium borohydride to induce covalent crosslinks between ribosomal RNA and nearby proteins. We proved that RNA was tryly crosslinked to protein in oxidized, and not in control, samples using denaturing cesium trichloroacetate density gradients and phenol extraction. By both one- and two-dimensional gel analysis, we found that protein S3a can be crosslinked to 18S RNA, protein L3 to 28S RNA, and proteins L7′ and L23′ to 5.8S RNA. Because of the specificity of the periodate reaction, and since we were able to crosslink protein S1 to 16S RNA in $\text{Escherichia}$,$\text{coli}$ 30S ribosomal subunits, it is likely that we have crosslinked proteins to the 3′OH ends of HeLa polysomal RNAs.     

In vitro reconstitution of messenger ribonucleoprotein particles from globin messenger RNA and cytosol proteins

Deproteinized globin poly(A) + mRNAs reassociate readily in vitro with soluble RNA-binding proteins of the cytosol; reconstituted messenger ribonucleoprotein complexes are obtained which are very similar to native globin polyribosomal-mRNP as far as bouyant density in Cs2SO4 and the composition of proteins which can be crosslinked to the mRNA are concerned. Proteins thus identified bind specifically to mRNA and not to ribosomal RNA or any synthetic oligonucleotides, with one exception: a 78-kDa protein could be cross-linked to poly(A).     

Interaction of tetracycline with RNA: photoincorporation into ribosomal RNA of Escherichia coli.

Photolysis of [3H]tetracycline in the presence of Escherichia coli ribosomes results in an approximately 1:1 ratio of labelling ribosomal proteins and RNAs. In this work we characterize crosslinks to both 16S and 23S RNAs. Previously, the main target of photoincorporation of [3H]tetracycline into ribosomal proteins was shown to be S7, which is also part of the one strong binding site of tetracycline on the 30S subunit. The crosslinks on 23S RNA map exclusively to the central loop of domain V (G2505, G2576 and G2608) which is part of the peptidyl transferase region. However, experiments performed with chimeric ribosomal subunits demonstrate that peptidyltransferase activity is not affected by tetracycline crosslinked solely to the 50S subunits. Three different positions are labelled on the 16S RNA, G693, G1300 and G1338. The positions of these crosslinked nucleotides correlate well with footprints on the 16S RNA produced either by tRNA or the protein S7. This suggests that the nucleotides are labelled by tetracycline bound to the strong binding site on the 30S subunit. In addition, our results demonstrate that the well known inhibition of tRNA binding to the A-site is solely due to tetracycline crosslinked to 30S subunits and furthermore suggest that interactions of the antibiotic with 16S RNA might be involved in its mode of action.     

The subunit interface of the Escherichia coli ribosome: Identification of proteins at the interface between the 30 S and 50 S subunits by crosslinking with 2-iminothiolane

The 70 S ribosomes of Escherichia coli were treated with 2-iminothiolane with the resultant addition of 110 sulfhydryl groups per ribosome. The modified ribosomes were oxidized to promote disulfide bond formation, some of which formed intermolecular crosslinks. About 50% of the crosslinked 70 S ribosomes did not dissociate when exposed to low concentrations of magnesium in the absence of reducting agent. Dissociation took place in the presence of reducing agents, which indicated that the subunits had become covalently linked by disulfide linkages. Proteins extracted from purified crosslinked 70 S ribosomes were first fractionated by polyacrylamide/urea gel electrophoresis. The proteins from sequential slices of these gels were analyzed by two-dimensional polyacrylamide/sodium dodecyl sulfate diagonal gel electrophoresis. Monomeric proteins derived from crosslinked dimers appeared below the diagonal containing non-crosslinked proteins, since the second electrophoresis, but not the first, is run under reducing conditions to cleave the crosslinked species. Final identification of the proteins in each dimer was made by radioiodination of the crosslinked proteins, followed by two-dimensional polyacrylamide/urea gel electrophoresis in the presence of non-radioactive total 70 S proteins as markers. This paper describes the identification of 23 protein dimers that contained one protein from each of the two different ribosomal subunits. The proteins implicated must have some part of their structure in proximity to the other ribosomal subunit and are therefore defined as “interface proteins”. The group of interface proteins thus defined includes 50 S proteins that are part of the 5 S RNA: protein complex and 30 S proteins at the initiation site. Correlations between the crosslinked interface proteins and other functional data are discussed.     

Ultraviolet light-induced crosslinking of mRNA to proteins.

Irradiation of intact or EDTA-dissociated L-cell polyribosomes with 254 nm UV light at doses of 1-2 x 10(5) ergs/mm2 extensively crosslinks mRNA to proteins. The crosslinked mRNA-protein complexes can be isolated on the basis of buoyant density in urea-containing CS2SO4 gradients that dissociate non-covalent complexes. Crosslinking of mRNA can also be assayed by phenolchloroform extraction. mRNA recovered from the crosslinked complexes by digestion with proteinase K has the same electrophoretic mobility in polyacrylamide gels as unirradiated mRNA. Therefore, irradiation does not either crosslink RNA molecules to RNA molecules or break phosphodiester bonds. With these methods it has been found that more than 70% of high molecular weight polydisperse mRNA, but only 25-40% of histone mRNA, can be crosslinked to protein. On the basis of buoyant density the histone mRNA-protein complex had a protein content of 26%, whereas the mean protein content of most non-histone mRNA-protein complexes was 65%. It is concluded that most mRNA in polyribosomes is in close contact with proteins, and that histone mRNA can be crosslinked to many fewer proteins that most other mRNAs.     

Ribonucleic acid-protein crosslinking in Escherichia coli ribosomal 30S subunits by the use of two new heterobifunctional reagents: 4-azido-2,3,5,6-tetrafluoropyridine and 4-azido-3,5-dichloro-2,6-difluoropyridine

Two new heterobifunctional reagents (4-azido-2,3,5,6-tetrafluoropyridine and 4-azido-3,5-dichloro-2,6-difluoropyridinel were synthesized and used to crosslink RNA to protein in Escherichia coli ribosomal 30S subunits. The maximal yield of crosslinking of the protein moiety was evaluated as 3.5%. Only proteins S4, S7 and S9 were found to be crosslinked to the 16S RNA within the 30S subunits.     

Crosslinking of eukaryotic initiation factor eIF3 to the 40S ribosomal subunit from rabbit reticulocytes

Complexes of purified 40S ribosomal subunits and initiation factor 3 from rabbit reticulocytes were crosslinked using the reversible protein crosslinking reagent, 2-iminothiolane, under conditions shown previously to lead to the formation of dimers between 40S proteins but not higher multimers. The activity of both the 40S subunits and initiation factor 3 was maintained. Protein crosslinked to the factor was purified by sucrose density gradient centrifugation following nuclease digestion of the ribosomal subunit: alternatively, the total protein was extracted from 40S: factor complexes. The protein obtained by either method was analyzed by two-dimensional diagonal polyacrylamide/sodium dodecyl sulfate gel electrophoresis. Ribosomal proteins were found in multimeric complexes of high molecular weight due to their crosslinking to components of eIF3. Identification of the ribosomal proteins appearing below the diagonal was accomplished by elution, radioiodination, two-dimensional polyacrylamide/urea gel electrophoresis, and radioautography. Proteins S2, S3, S3a, S4, S5, S6, S8, S9, S11, S12, S14, S15, S16, S19, S24, S25, and S26 were identified. Because many of the proteins in this group form crosslinked dimers with each other, it was impossible to distinguish proteins directly crosslinked to eIF3 from those crosslinked indirectly through one bridging protein. The results nonetheless imply that the 40S ribosomal proteins identified are at or near the binding site for initiation factor 3.     

Molecular interactions of ribosomal components

Summary Five of the 30S ribosomal proteins from E. coli were tested for their ability to bind to 16S ribosomal RNA. Only one of these, S15, can form a complex with the RNA. Quantitative measurements as well as competition experiments show that the RNA binding site for the attachment of S15 is specific for this protein.These experiments complete our analysis of all 21 of the 30S ribosomal proteins. Five of these have now been shown to form a site-specific complex with 16S RNA. These are S4, S7, S8, S15 and S20. The relationship of these data to the assembly and structure of the ribosome are discussed.     

The ribosomes of Drosophila

Summary The assembly of proteins and RNA into mature ribosomal subunits has been studied in Drosophila cell cultures by pulse-chase experiments. Pulse labeled rRNA has a transit time of 3 h, while the transfer of ribosomal protein occurs completely within 30 min. Inhibition of protein synthesis by cycloheximide results in an almost immediate cessation of ribosome assembly, a result which indicates that no large pool of free ribosomal proteins exists in the cell. Substituting pre-ribosomal RNA with the analogue 5-fluorouridine (5-FU) results in a cessation of ribosome maturation. Under these conditions at least three large subunit proteins continue to accumulate on pre-existing cytoplasmic subunits, indicating an exchange. A portion of ribosomal subunit proteins synthesized in the presence of 5-FU can be recovered in cytoplasmic subunits once the effect of 5-FU has been reversed. This is most easily interpreted in terms of their stabilization on substituted pre-rRNA within the nucleolus, and subsequent utilization on unsubstituted RNA.Work supported by a grant from the NIH (GM 22866)     

Synthesis of a cleavable protein-crosslinking reagent for the investigation of ribosome structure.

This communication describes a simple method for synthesizing cleavable bifunctional imido esters of different chain lengths. These reagents, which form covalent crosslinks between lysine residues of proteins, contain a disulfide bond which is cleaved under mild conditions by reducing agents such as 2-mercaptoethanol. The reagents are synthesized via the dithiobisnitrile which is prepared in high yield by reacting the appropriate omega-activated nitrile with sodium polysulfide and is then converted quantitatively to the diimidate. Three such reagents were prepared: dimethyl 3.3'-dithiobispropionimidate, dimethyl 4,4'-dithiobisbutyrimidate, and dimethyl 6-6'-dithiobiscaproimidate. The first was synthesized from acrylonitrile, and the others from the appropriate omega-bromonitriles. Experiments with the bispropionimidate and a test protein, pancreatic ribonuclease, have shown the reagent to be effective in producing multimeric crosslinked complexes, from which monomeric proteins can recovered after treatment with 2-mercaptoethanol. The reagents are suitable for studies of ribosomal structure.     

核糖体蛋白质的新功能及其与相关疾病的关系

核糖体蛋白质与核糖体RNA共同组成了核糖体,是合成蛋白质的细胞器。除参与蛋白质合成,核糖体蛋白质还具有广泛的核糖体外功能,如独立于核糖体外发挥调控基因转录、mRNA翻译、细胞的增殖、分化和凋亡等等。基于诸多的核糖体外功能,核糖体蛋白质与人类疾病密切相关,例如在先天性贫血、生长发育不全和肿瘤的发生发展过程中均发挥重要作用。本文对近年来核糖体蛋白质的核糖体外新功能及其相关疾病的研究进展作一综述。     

Preliminary x-ray diffraction data for tetragonal crystals of trypsinized Escherichia coli elongation factor.

Previous studies (Craven et al., 1974) demonstrated that the capacity of ribosomal proteins to be chemically modified by iodine is extensively reduced when they are members of an intact ribosome. We have attempted to exploit this observation by analyzing in detail the alterations in the iodine accessibility of the individual 30 S ribosomal proteins. We have prepared a total of 38 different complexes between 16 S RNA and mixtures of individual purified 30 S ribosomal proteins. Eighteen of the 21 30 S proteins were used in the formation of these complexes. Comparison of the iodination patterns obtained for the various proteins derived from different complexes has revealed that sometimes a specific protein can selectively alter the chemical reactivity of another protein in the complex. We have found 30 different examples of protein pairs in which one protein effectively protects another protein from chemical iodination.     

Molecular interactions of ribosomal components

Summary The formation of a complex between individual 30S ribosomal proteins and 16S ribosomal RNA was studied by three techniques: zone centrifugation, molecular-sieve chromatography and electrophoresis in polyacrylamide gels. Five 30S proteins form a stable complex with the RNA under the conditions used to assemble ribosomes. Specific and nonspecific complex formation can be distinguished by an analysis of the concentration-dependence for complex formation. Similarly, competition experiments between heterologous proteins that bind to RNA can also be used to establish the uniquness of the RNA binding sites for ribosomal proteins. The data show that four of the five proteins bind to unique sites on the RNA. The fifth protein binds nonspecifically to the RNA. In addition, cooperative interactions between several proteins were observed; these enhance the interaction of proteins with the 16S RNA. A partial assembly sequence for the 30S ribosomal subunit is presented.     

Studies on the binding of the ribosomal protein complex L7/12-L10 and protein L11 to the 5''-one third of 23S RNA: a functional centre of the 50S subunit.

The RNA binding sites of the protein complex of L7/12 dimers and L10, and of protein L11, occur within the 5'-one third of 23S RNA. Binding of the L7/12-L10 protein complex to the 23S RNA is stimulated by protein L11 and vice-versa. This is the second example to be established of mutual stimulation of RNA binding by two ribosomal proteins or protein complexes, and suggests that this may be an important principle governing ribosomal protein-RNA assembly. When the L7/12-L10 complex is bound to the RNA, L10 becomes strongly resistant to trypsin. Since the L7/12 dimer does not bind specifically to the 23S RNA, this suggests that L10 constitutes a major RNA binding site of the protein complex. Only one of the L7/12 dimers is bound strongly in the (L7/12-L10)-23S RNA complex; the other can dissociate with no concurrent loss of L10.     

Photocrosslinking of proteins to maternal mRNA in Xenopus oocytes

Ultraviolet irradiation was used to covalently crosslink poly(A) RNA and associated proteins in Xenopus oocytes and reticulocytes. Each cell type contained similar as well as unique crosslinked proteins. The somatic cells contained a single 78-kDa 3' poly(A) tract binding protein while oocyte poly(A), however, was bound by this protein and at least three additional proteins. Based on the mass of poly(A) RNA, oocytes in their earliest stages of growth contained crosslinked proteins that were generally more prevalent than in fully grown oocytes. An investigation of possible messenger RNA-specific proteins was undertaken by a series of RNA injection experiments. Two radiolabeled SP6-derived mRNAs were injected into oocytes; the first, globin mRNA, assembled into polysomes, while the second, a maternal mRNA termed G10, entered a nontranslating ribonucleoprotein compartment. Following the induction of oocyte maturation, additional globin mRNA was recruited onto polysomes while G10 mRNA remained a nontranslating mRNP. The proteins that can be crosslinked to these injected mRNAs were detected by 32P nucleotide transfer. Each mRNA associated with shared as well as unique proteins, some of which were detected only in mature oocytes. The possible function of these proteins is discussed.