Studies on proteins of animal ribosomes. 8. Two-dimensional polyacrylamide gel electrophoresis of ribosomal proteins of rat liver

Characterisation of the ribosomal binding site for eukaryotic elongation factor 2 by chemical cross-linking

Ribosomal complexes containing elongation factor 2 (EF-2) were formed by incubation of 80 S ribosomes in the presence of EF-2 and the non-hydrolysable GTP analogue GuoPP[CH2]P. The factor was covalently coupled to the ribosomal proteins located at the factor binding site, by treatment with bifunctional reagents. After isolation of the covalent EF-2.ribosomal protein complexes, the proteins were labelled with 125I and the introduced covalent links cleaved. The ribosomal proteins were identified by electrophoresis in two independent two-dimensional gel systems, followed by autoradiography. After cross-linking with bis(hydroxysuccinimidyl) tartrate (4 A between the reactive groups), protein S3/S3a, S7 and S11 were found as the major ribosomal proteins covalently linked to EF-2. The longer reagent, dimethyl 3,8-diaza-4,7-dioxo-5,6-dihydroxydecanbisimidate (11 A between the reactive groups), covalently coupled proteins S7, S11, L5, L13, L21, L23, L26, L27a and L32 to EF-2. After cross-linking with dimethyl suberimidate (9 A between the reactive groups) proteins S3/3a, S7, S11, L5, L8, L13, L21, L23, L26, L27a, L31 and L32 were identified as belonging to the EF-2-binding site. The results indicate that the ribosomal domain interacting with EF-2 is located on both the small and the large ribosomal subunit close to the subunit interface.

Selective high-efficiency cross-linking of mammalian ribosomal proteins with cleavable thiol-directed heterobifunctional reagents: identification and binding directions of major protein complexes

Rat liver and mouse ascitic tumour ribosomal proteins are cross-linked selectively in good yield with the newly developed cleavable heterobifunctional reagents 2-(4-hydroxy-2-maleimidophenylazo)benzoic acid N-hydroxysuccinimide ester (reagent A) and 4-(4-hydroxy-3-maleimidophenylazo)[carboxyl-14C]benzoic acid N-hydroxysuccinimide ester (reagent B). The primary function of the reagents, an N-aroylated maleimide, binds quantitatively at low pH to accessible cysteine groups. After eliminating the free reagent, the pH is increased to make the secondary function, a juxtanuclear aroyl ester, reactive against neighboring amino groups, essentially lysine. The spacer, 4-phenylazophenol, is readily cleaved by reduction with dithionite. The ranges of cross-linking of the two reagents are approx. 8 and 12 A, respectively. Using the radiolabelled reagent B the secondarily attached protein (and its contact sequence) is made recognizable even in trace amounts. The order of binding of the interacting proteins is thereby established. The two reagents produce similar, but not identical, patterns of selective cross-linking. The following protein complexes are readily observed after conventional staining. With reagent A: S8-S11, L4-L14, L4-L18, L6-L29 and L21-L18a. With the radioactive, longer-range reagent B: L4 ---- L13a, L4 ---- L18, L4 ---- L18a, L4 ---- L26, L6 ---- L29, L14 ---- L13a, L21 ---- L18a and L27 ---- L30 (arrows indicating the direction of binding). Ternary and quaternary complexes are also obtained, especially of the large protein L4. With both reagents a protein designated L6' is cross-linked to L23. The predominant cross-linked complexes can be obtained on a preparative scale for isolation and characterization of contact sequences by optional fragmentation and fractionation methods.

Studies on the distribution of ribosomal proteins in mammalian ribosomal subunits

Murine L5178Y cell ribosomes were dissociated into subunits either with potassium chloride in the presence of puromycin or with the chelating agent EDTA. The proteins of ribosomal subunits obtained by these different methods were compared by means of bidimensional polyacrylamide gel electrophoresis. KCl-derived 60S and 40S subunits were shown to contain 38 and 31 proteins respectively, 3 of them having identical electrophoretic mobilities. Preparations of EDTA-dissociated ribosomal subparticles contained different proportions of these proteins, and 11 major spots were shared between the EDTA-derived large and small ribosomal subunits. Furthermore, 10 proteins absent from subunits treated by high concentrations of KCl were reproducibly found in EDTA-treated ribosomal subparticles.

Number and molecular weights of the basic proteins of rat liver ribosomes

1) Efficient separation of the proteins from rat liver ribosomes can by achieved by two-dimensional polyacrylamide gel electrophoresis. Complete separation of all components, however, is not possible with one system only. Comparison of the results obtained with different systems suggests further heterogeneity of S15, L22, L28, L33 and L35 and enables identification of S15a, S15b, L22a, L22b, L28a, L28b, L33, L33a, L35a and L36b. 2) Ribosomal proteins were substituted with iodoacetamide prior to electrophoresis or handled in all steps of the procedure in the presence of reducing agents. These procedures prevent the formation of oxidation products described erroneously as ribosomal proteins S5, S6, L15, L17 and L32 in earlier papers. 3) Estimation of the molecular weights was performed by two-dimensional separation of the small and large subunit proteins using sodium dodecyl sulphate in the second dimension. The positions of the 70 basic proteins in the 2-D patterns were identified. 4) The small and large subunit proteins have molecular weights in the range of 8000 to 35,000 and 11,000 to 55,500 Dalton, respectively. The number average molecular weights for the small and large subunit proteins are 22,500 and 26,500 Dalton, respectively. The sum of the molecular weights is 0.67 x 10(6) Dalton for the proteins of the small subunit and 1.05 x 10(6) Dalton for the proteins of the large subunit.

Characterisation of ribosomal proteins from HeLa and Krebs II mouse ascites tumor cells by different two-dimensional polyacrylamide gel electrophoresis techniques

Electrophoresis of ribosomal proteins according to Kaltschmidt and Wittmann, 1970a, b (pH 8.6/pH 4.5 urea system) yielded 29 proteins for the small subunits and 35 and 37 proteins for the large subunits of Krebs II ascites and HeLa ribosomes, respectively. Analysis of the proteins according to a modified technique by Mets and Bogorad (1974) (pH 4.5/pH 8.6 SDS system) revealed 28 and 29 proteins in the small subunits and 37 and 38 proteins in the large subunits of Krebs II ascites and HeLa ribosomes. The molecular weights of the individual proteins were determined by: 1. "three-dimensional" gel electrophoresis; 2. two-dimensional gel electrophoresis at pH 4.K/pH 8.6 in SDS. The molecular weights for 40S proteins ranged from 10,000 to 39,000 dalton (number average molecular weight: 21,000). The molecular weights for the 60S proteins ranged from 14,000 to 44,000 dalton (number average molecular weight: 23,000) using the "three-dimensional" technique. A molecular weight range from 10,000 to 38,000 dalton (number average molecular weight: 21,000) was obtained for the 40S subunits, whereas the molecular weights for the 60S ribosomal proteins (average molecular weight: 26,000) ranged from 12,000 to 69,000 dalton using the pH 4.5/pH 8.6 SDS system. The molecular weights Krebs II ascites and HeLa ribosomal proteins are compared with those obtained by other authors for different mammalian species.

Analysis by two-dimensional polyacrylamide gel electrophoresis of liver ribosomal subunnit proteins obtained from free and membrane-bound polysomes of unfasted animals

Ribosomal proteins were analyzed by means of two-dimensional gel electrophoresis. To insure that the analysis included only that fraction of the ribosome actively participating in protein synthesis, only polysomal-bound ribosomes were used. This differs from previously reported analyses of liver ribosomal proteins. The ribosomal proteins were prepared from ribosomes of polysomal origin from membrane-bound and free polysomes. Membrane-bound and free liver polysomes were isolated from unfasted mice. The polysomes were purified on hydroxyapatite under conditions known to result in polysomes and ribosomes that are active in both endogenous and synthetic mRNA translation. Moreover, this is the first time that liver ribosomal protein was obtained and analyzed from animals that have not been starved prior to sacrifice. The puromycin-released ribosomes were dissociated into subunits and ribosomal proteins were analyzed by means of two-dimensional polyacrylamide gel electrophoresis. When 100-200 mug samples of the ribosomal subunit proteins were analyzed by two-dimensional electrophoresis, approximately 32 major proteins were detected for the 60 S ribosomal subunit and 25 major proteins for the 40 S ribosomal subunit. A total of 13 "fractional" ribosomal proteins was also detected in the ribosomal subunit profiles. No differences in number or mobility of the ribosomal proteins were found between the membrane-bound and free ribosome populations. We describe a system in which all ribosomal proteins are completely solubilized and quantitatively move from the first to the second dimension gel. Thus the total sample is separated and fractionated. This procedure elimates artifacts due to incomplete solubilization of ribosomal proteins, which is common for the transfer from the first- to second-dimension gel. Therefore, a more detailed and accurate analysis is achieved.

Characterisation of eukaryotic ribosomal proteins

A simple method of two-dimensional polyacrylamide gel electrophoresis is described which affords: (1) high resolution of eukaryotic ribosomal proteins; (2) good recovery of protein in the transfer from first to second dimension; and (3) characterisation of the separated proteins in terms of molecular weights and other electrophoretic properties. Using this method, we have characterised 70 proteins in rabbit reticulocyte ribosomes, 30 from the small subunit and 40 from the large subunit. The molecular weight distribution is compared with those obtained by other authors after fractionation of the proteins in two dimensions.

Micro-scale two-dimensional polyacrylamide gell electrophoresis of ribosomal proteins

A specially designed apparatus and conditions are described for the rapid analysis of ribosomal proteins by two-dimensional gel electrophoresis on a micro scale. The resolution of proteins in electropherograms is comparable to that obtained with other systems, but because of miniaturization, only 0.5 to 1 mug of each protein is required, and the entire procedure, including electrophoresis in both dimensions, and staining and destaining can be completed in 6 to 7 hours.

Complementary binding of oligonucleotides with 16S RNA and ribosomal ribonucleoproteins

The accessibility of single-stranded sequences in 16S RNA in free state and in ribonucleoprotein particles (RNP) to complementary binding with isoplith fractions of oligonucleotides was studied. RNP had different protein composition and corresponded to intermediate stages of E. coli 30S subunit assembly in vitro. Gel-filtration was used to detect the most strong binding. It was found that S4 essentially inhibited the hexamer binding to RNA. 'Core' proteins bound to 16S RNA strongly increased the shielding of single-stranded regions while 'split' proteins insignificantly changed the hexamer binding. Nevertheless evidence is presented that 'split' proteins might also interact directly with 16S RNA in the 30S subunit.

The extraction of proteins from eukaryotic ribosomes and ribosomal subunits

Proteins were extracted from rat liver ribosomes and ribosomal subunits: with 67% acetic acid (in the presence of 3.3 mM, 33 mM, or 67 mM Mg) with 2 M LiCL in 4 M urea; with 0.25 N HCI; with 1% SDS; and after RNase digestion. The most efficient extraction and the best recovery were either with acetic acid in the presence of 33 mM or 67 mM Mg, or with LiCI-urea. Protein extracted with acetic acid, LiCi-urea, or with HCI had little or no contamination with RNA. The ribosomal proteins were analyzed by two-dimensional polyacrylamide gel electrophoresis: the proteins extracted with acetic acid were the most soluble in the sample gel solution; their electrophoretograms displayed the maximum number of spots and the smallest number of derivatives or altered proteins. Preparations of protein extracted with SDS or RNase were relatively insoluble in the sample gel solution, and proteins extracted with HCI showed a large number of derivatives. All things considered, the most satisfactory method for the extraction of protein from eukaryotic ribosomes is with 67% acetic acid in the presence of 33 mM MgCl2.