In vitro assembly of 30S and 70S bacterial ribosomes from 16S RNA containing single base substitutions, insertions, and deletions around the decoding site (C1400)

An in vitro system developed for the site-specific mutagenesis of 16S RNA of Escherichia coli ribosomes [Krzyzosiak et al. (1987) Biochemistry 26, 2353-2364] was used to make 10 single base changes around C1400, a residue known to be at the decoding site. C1400 was replaced by U, A, or G, five single base deletions at and to either side of C1400 were made, and C or U was inserted next to C1400. Another mutant possessed seven additional nucleotides at the 3' end of the 16S RNA such that a stem and loop involving the anti-Shine-Dalgarno sequence could form. Each of the mutant RNAs was reconstituted with a complete mixture of 30S proteins to yield 30S ribosomes. Modified in vitro reconstitution conditions were required to obtain assembly of all of the synthetic ribosomes. Quantitative HPLC analysis of the protein content of each mutant showed that all of the proteins were present. The ability of synthetic 30S to form 70S particles under functional assay conditions was about 75% that of natural 30S and was unchanged by any of the mutations except for the deletion of G1401, which decreased the association activity under the standard conditions to 35-40% of synthetic 30S. That part of the ribosomal P site which interacts with the anticodon loop of tRNA was investigated by near-UV (greater than 300 nm) induced cross-linking of AcVal-tRNA. Cross-linking depended on both 30S subunits and the correct codon. The cross-linking yield of all mutants with a pyrimidine at position 1400 was equal to control isolated 30S, and the first-order rate constants for cross-linking of those mutants tested were like reconstituted natural 30S. The site of cross-linking for mutants with a C or U insertion between C1400 and G1401 was shifted to the inserted residue. Cross-linking to the base 5' to G1401 rather than to the residue 3' to C1399 indicates that G1401 is an important structural determinant of the P site.     

Effect of removal of 160 nucleotides from the 3′ end of Escherichia coli 16S rRNA on the reconstitution and activity of 30S ribosomes

$\text{E. coli}$ 16S rRNA deprived of 160 nucleotides from its 3′ end was obtained by digestion with polynucleotide phosphorylase. Such rRNA was used for the reconstitution of 30S subunits and the resulting particles contained all proteins present in native 30S ribosomes. Their sedimentation coefficient was estimated as 26.5S. Poly AUG-dependent binding of fMet-tRNA to subunits reconstituted with shortened rRNA was the same as to 30S particles reconstituted with the native 16S rRNA. Subunits reconstituted with shortened rRNA were also active in poly U-dependent phenylalanine incorporation; however, their activity reached only 50% of that obtained with 30S subunits reconstituted with native 16S rRNA.     

Efficient reconstitution of functional Escherichia coli 30S ribosomal subunits from a complete set of recombinant small subunit ribosomal proteins.

Previous studies have shown that the 30S ribosomal subunit of Escherichia coli can be reconstituted in vitro from individually purified ribosomal proteins and 16S ribosomal RNA, which were isolated from natural 30S subunits. We have developed a 30S subunit reconstitution system that uses only recombinant ribosomal protein components. The genes encoding E. coli ribosomal proteins S2-S21 were cloned, and all twenty of the individual proteins were overexpressed and purified. Reconstitution, following standard procedures, using the complete set of recombinant proteins and purified 16S ribosomal RNA is highly inefficient. Efficient reconstitution of 30S subunits using these components requires sequential addition of proteins, following either the 30S subunit assembly map (Mizushima & Nomura, 1970, Nature 226:1214-1218; Held et al., 1974, J Biol Chem 249:3103-3111) or following the order of protein assembly predicted from in vitro assembly kinetics (Powers et al., 1993, J MoI Biol 232:362-374). In the first procedure, the proteins were divided into three groups, Group I (S4, S7, S8, S15, S17, and S20), Group II (S5, S6, S9, Sll, S12, S13, S16, S18, and S19), and Group III (S2, S3, S10, S14, and S21), which were sequentially added to 16S rRNA with a 20 min incubation at 42 degrees C following the addition of each group. In the second procedure, the proteins were divided into Group I (S4, S6, S11, S15, S16, S17, S18, and S20), Group II (S7, S8, S9, S13, and S19), Group II' (S5 and S12) and Group III (S2, S3, S10, S14, and S21). Similarly efficient reconstitution is observed whether the proteins are grouped according to the assembly map or according to the results of in vitro 30S subunit assembly kinetics. Although reconstitution of 30S subunits using the recombinant proteins is slightly less efficient than reconstitution using a mixture of total proteins isolated from 30S subunits, it is much more efficient than reconstitution using proteins that were individually isolated from ribosomes. Particles reconstituted from the recombinant proteins sediment at 30S in sucrose gradients, bind tRNA in a template-dependent manner, and associate with 50S subunits to form 70S ribosomes that are active in poly(U)-directed polyphenylalanine synthesis. Both the protein composition and the dimethyl sulfate modification pattern of 16S ribosomal RNA are similar for 30S subunits reconstituted with either recombinant proteins or proteins isolated as a mixture from ribosomal subunits as well as for natural 30S subunits.     

The effects of initiation factor 3 on the formation of 30S initiation complexes with synthetic and natural messengers

Initiation factor IF-3 is required for the binding of fMet-tRNA to 70S ribosomes directed by AUG, poly (U,G), f₂RNA and T₄ late RNA as well as for the binding of acPhe-tRNA directed by poly (U). In contrast, IF-3 is not required for the binding of the initiator aminoacyl-tRNAs to isolated 30S subunits directed by the synthetic messengers, but is required for maximal formation of initiation complexes with natural messengers. These data indicate that with synthetic messengers the sole function of IF-3 is to dissociate the 70S ribosomes into subunits, whereas with natural messengers IF-3 is required not only for dissociation of the ribosomes but also for the binding of the messenger to the 30S subunit.     

Mutants with base changes at the 3'-end of the 16S RNA from Escherichia coli. Construction, expression and functional analysis

The functionally important 3' domain of the ribosomal 16S RNA was altered by in vitro DNA manipulations of a plasmid-encoded 16S RNA gene. By in vitro DNA manipulations two double mutants were constructed in which C1399 was converted to A and G1401 was changed to either U or C and a single point mutant was made wherein G1416 was changed to U. Only one of the mutated rRNA genes could be cloned in a plasmid under the control of the natural rrnB promoters (U1416) whereas all three mutations were cloned in a plasmid under the control of the lambda PL promoter. In a strain coding for the temperature-sensitive lambda repressor cI857 the mutant RNAs could be expressed conditionally. We could show that all three mutant rRNAs were efficiently incorporated into 30S ribosomes. However, all three mutants inhibited the formation of stable 70S particles to various degrees. The amounts of mutated rRNAs were quantified by primer extension analysis which enabled us to assess the proportion of the mutated ribosomes which are actively engaged in in vivo protein biosynthesis. While ribosomes carrying the U1416 mutation in the 16S RNA were active in vivo a strong selection against ribosomes with the A1399/U1401 mutation in the 16S RNA from the polysome fraction is apparent. Ribosomes with 16S RNA bearing the A1399/C1401 mutation did not show a measurable protein biosynthesis activity in vivo. The growth rate of cells harbouring the different mutations reflected the in vivo translation capacities of the mutant ribosomes. The results underline the importance of the highly conserved nucleotides in the 3' domain of the 16S RNA for ribosomal function.     

On the accessibility and selection of the initiator site of mRNA in protein synthesis.

The specificity of the cell-free system of Escherichia coli for mRNA was examined, and the "accessibility" of some natural and synthetic RNAs to the ribosomes was determined by measurement of AcPhe-tRNA and fMet-tRNA binding, AcPhe-puromycin and fMet-puromycin formation, and polypeptide synthesis. The E. coli system effectively initiates the translation of various synthetic RNAs with AcPhe-tRNA or fMet-tRNA under conditions optimal for the translation of viral RNA. Poly(A,G,U) is accessible to the ribosomes according to all of the above criteria. Poly(A,C,G,U), 23 S rRNA, R17 RNA, and MS2 RNA, on the other hand, show limited accessibility when tested for initiator tRNA binding, or for AcPhe-puromycin and fMet-puromycin formation. MS2 and R17 RNA, but not poly(A,C,G,U) and 23 S rRNA, show accessibility when measured by polypeptide synthesis. The results suggest that, except at initiator sites of natural mRNA, an RNA containing about equal amounts of all four bases is inaccessible to E. coli ribosomes for polypeptide synthesis. Rate constants obtained for fMet-tRNA binding with MS2 RNA, poly(A,G,U), and poly(C,G,U) indicate that the ribosomes do not have any special affinity for the viral RNA. Thus, the selection of the initiator site in protein synthesis may be critically determined more by the accessibility of the initiator codon than by ribosomal recognition of the site.     

30S ribosomal subunits with fragmented 16S RNA: a new approach for structure and function study of ribosomes.

A new approach for function and structure study of ribosomes based on oligodeoxyribonucleotide-directed cleavage of rRNA with RNase H and subsequent reconstitution of ribosomal subunits from fragmented RNA has been developed. The E coli 16S rRNA was cleaved at 9 regions belonging to different RNA domains. The deletion of 2 large regions was also produced by cleaving 16S rRNA in the presence of 2 or 3 oligonucleotides complementary to different RNA sites. Fragmented and deleted RNA were shown to be efficiently assembled with total ribosomal protein into 30S-like particles. The capacity to form 70S ribosomes and translate both synthetic and natural mRNA of 30S subunits reconstituted from intact and fragmented 16S mRNA was compared. All 30S subunits assembled with fragmented 16S rRNA revealed very different activity: the fragmentation of RNA at the 781-800 and 1392-1408 regions led to the complete inactivation of ribosomes, whereas the RNA fragmentation at the regions 296-305, 913-925, 990-998, 1043-1049, 1207-1215, 1499-1506, 1530-1539 did not significantly influence the ribosome protein synthesis activity, although it was also reduced. These findings are mainly in accordance with the data on the functional activity of some 16S rRNA sites obtained by other methods. The relations between different 16S RNA functional sites are discussed.     

Ribosome-DnaK interactions in relation to protein folding

Bacterial ribosomes or their 50S subunit can refold many unfolded proteins. The folding activity resides in domain V of 23S RNA of the 50S subunit. Here we show that ribosomes can also refold a denatured chaperone, DnaK, in vitro, and the activity may apply in the folding of nascent DnaK polypeptides in vivo. The chaperone was unusual as the native protein associated with the 50S subunit stably with a 1:1 stoichiometry in vitro. The binding site of the native protein appears to be different from the domain V of 23S RNA, the region with which denatured proteins interact. The DnaK binding influenced the protein folding activity of domain V modestly. Conversely, denatured protein binding to domain V led to dissociation of the native chaperone from the 50S subunit. DnaK thus appears to depend on ribosomes for its own folding, and upon folding, can rebind to ribosome to modulate its general protein folding activity.     

Ribosomes with unique breaks in 16S RNA: isolation and biological activity

A set of Escherichia coli 16S rRNA having unique breaks were prepared using the method of oligodeoxyribonucleotide-directed fragmentation with RNAse H. 16S RNA remained compact or dissociated to separate fragments, depending on the cleavage site location in the RNA structure. 16S rRNAs which have been split at different sites or their isolated fragments were used for a reconstitution of the 30S ribosomal subunits. These reconstituted 30S subunits carrying unique breaks at positions 301, 772, 1047 have the same sedimentation coefficients and electron microscopy images as the native subunit. They were active in the poly(U)-directed cell-free system of synthesis of polyphenylalanine.     

A Comparison of the Native and Derived 30S and 50S Ribosomes of Escherichia coli

Four types of ribosomes occurring in E. coli have been separated by sucrose gradient centrifugation. These are the 30S and 50S particles occurring in E. coli extracts (native particles), and the 30S and 50S particles which are the subunits of 70S ribosomes (derived particles). Two criteria were used in comparing these particles: (1) The type of RNA contained in each, as determined by sedimentation velocity in the analytical ultracentrifuge. (2) The ability of mixtures of 30S and 50S ribosomes (derived 30S + derived 50S, native 30S + native 50S) to undergo the reaction: [Formula: see text] Native and derived 30S particles were found to contain 16S RNA. Derived 50S particles contained 23S RNA and a small amount of 15 to 20S RNA, whereas native 50S ribosomes contained only 16S RNA. Derived 30S and 50S particles combined to form 70S particles. However, under identical conditions, native 30S and 50S particles did not form 70S ribosomes.     

Reconstitution of active 30-S ribosomal subunits in vitro using heat-denatured 16-S rRNA.

30-S ribosomal subunits which have been reconstituted using heat-denatured 16-S rRNA can participate in the synthesis of lysosyme in vitro. Therefore all the information contributed by 16-S rRNA to the reconstitution process is carried in the primary sequence of this RNA. The specific protein-synthesizing activity of 30-S subunits reconstituted from 30-S subunit proteins and heat-denatured 16-S rRNA is about one third of that observed if unheated 16-S rRNA is used and is comparable to the activity of 30-S particles isolated after dissociation of 70-S ribosomes in the presence of 0.1 mM Mg2+.     

An efficient in vitro total reconstitution of the Escherichia coli 50S ribosomal subunit

A new, relatively simple technique for the total invitro reconstitution of E. coli 50S ribosomes has been developed. It is a two-step procedure like that previously reported by Nierhaus and Dohme [Proc. Natl. Acad. Sci. 71, 4713 (1974)], but it differs in a number of important aspects. Ribosomal RNA is prepared by direct phenol extraction of 70S particles to minimize nuclease fragmentation. A mixture of 50S proteins is prepared by acetic acid extraction and immediate removal of the acetic acid by thin film dialysis. The resulting protein mixture is soluble and stable. Separate RNA and protein fractions are mixed, incubated first at 44 degrees C in 7.5 mM Mg(2+), and then at 50 degrees C in 20 mM Mg(2+). The resulting 50S particles comigrate with native 50S particles in analytical gradients. They range from 50 to 100% active in five different functional assays. This is a fairly stringent test of the effectiveness of reconstitution since 50S particles derived from highly active vacant couples were used as a control.Images     

Elongation factor Tu ternary complex binds to small ribosomal subunits in a functionally active state

A complex between elongation factor Tu (EF-Tu), GTP, phenylalanyl-tRNA (Phe-tRNA), oligo(uridylic acid) [oligo(U)], and the 30S ribosomal subunit of Escherichia coli has been formed and isolated. Binding of the EF-Tu complex appears to be at the functionally active 30S site, by all biochemical criteria that were examined. The complex can be isolated with 0.25-0.5 copy of EF-Tu bound per ribosome. The binding is dependent upon the presence of both the aminoacyl-tRNA and the cognate messenger RNA. Addition of 50S subunits to the preformed 30S-EF-Tu-GTP-Phe-tRNA-oligo(U) complex ("30S-EF-Tu complex") causes a rapid hydrolysis of GTP. This hydrolysis is coordinated with the formation of 70S ribosomes and the release of EF-Tu. Both the release of EF-Tu and the hydrolysis of GTP are stoichiometric with the amount of added 50S subunits. 70S ribosomes, in contrast to 50S subunits, neither release EF-Tu nor rapidly hydrolyze GTP when added to the 30S-EF-Tu complexes. The inability of 70S ribosomes to react with the 30S-EF-Tu complex argues that the 30S-EF-Tu complex does not dissociate prior to reaction with the 50S subunit. The requirements of the 30S reaction for Phe-tRNA and oligo(U) and the consequences of the addition of 50S subunits resemble the reaction of EF-Tu with 70S ribosomes, although EF-Tu binding to isolated 30S subunits does not occur during the elongation microcycle. This suggests that the EF-Tu ternary complex binds to isolated 30S subunits at the same 30S site that is occupied during ternary complex interaction with the 70S ribosome.(ABSTRACT TRUNCATED AT 250 WORDS)     

Area of 16S ribonucleic acid at or near the interface between 30S and 50S ribosomes of Escherichia coli.

To determine the region of 16S ribonucleic acid (RNA) at the interface between 30 and 50S ribosomes of Escherichia coli, 30 and 70S ribosomes were treated with T1 ribonuclease (RNase). The accessibility of 16S RNA in the 5' half of the molecule is the same in 30 and 70S ribosomes. The interaction with 50S ribosomes decreases the sensitivity to T1 RNase of an area in the middle of 16S RNA. A large area near the 3' end of 16S RNA is completely protected in 70S ribosomes. The RNA near the 3' end of the molecule and an area of RNA in the middle of the molecule appear to be at the interface between 30 and 50S ribosomes. One site in 16S RNA, 13 to 15 nucleotides from the 3' end, normally inaccessible to T1 RNase in 30S ribosomes, becomes accessible to T1 RNase in 70S ribosomes. This indicates a conformational change at the 3' end of 16S RNA when 30S ribosomes are associated with 50S ribosomes.     

Effects of aminoethylation of cysteine residues on the structural and functional activities of the Escherichia coli 30 S ribosomal proteins

The purified 30 S ribosomal proteins from Escherichia coli strain Q13 were chemically modified by reaction with ethyleneimine, specifically converting cysteine residues to S-2-aminoethylcysteine residues. Proteins S1, S2, S4, S8, S11, S12, S13, S14, S17, S18 and S21 were found to contain aminoethylcysteine residues after modification, whereas proteins S3, S5, S6, S7, S9, S10, S15, S16, S19 and S20 did not. Aminoethylated proteins S4, S13, S17 and S18 were active in the reconstitution of 30 S ribosomes and did not have altered functional activities in poly(U)-dependent polyphenylalanine synthesis, R17-dependent protein synthesis, fMet-tRNA binding and Phe-tRNA binding. Aminoethylated proteins S2, S11, S12, S14 and S21 were not active in the reconstitution of complete 30 S ribosomes, either because the aminoethylated protein did not bind stably to the ribosome (S2, S11, S12 and S21) or because the aminoethylated protein did not stabilize the binding of other ribosomal proteins (S14). The functional activities of 30 S ribosomes reconstituted from a mixture of proteins containing one sensitive aminoethylated protein (S2, S11, S12, S14 or S21) were similar to ribosomes reconstituted from mixtures lacking that protein. These results imply that the sulfhydryl groups of the proteins S4, S13, S17 and S18 are not necessary for the structural or functional activities of these proteins, and that aminoethylation of the sulfhydryl groups of S2, S11, S12, S14 and S21 forms either a kinetic or thermodynamic barrier to the assembly of active 30 S ribosomes in vitro.     

The role of magnesium and potassium ions in the molecular mechanism of ribosome assembly: hydrodynamic, conformational, and thermal stability studies of 16 S RNA from Escherichia coli ribosomes

In an attempt to understand the role of magnesium ion in ribosome assembly in vitro, the hydrodynamic shape, conformation, and thermal stability of ribosomal 16 S RNA were studied systematically as a function of Mg2+ concentration by sedimentation velocity, intrinsic viscosity, circular dichroism, and difference ultraviolet absorption spectroscopy. These results were then compared with the corresponding parameters obtained for 16 S RNA under the optimal conditions of reconstitution, i.e., at 37 degrees C, 20 mM Mg2+, an ionic strength equal to 0.37, and pH 7.8 [S. H. Allen, and K.-P. Wong (1978) J. Biol. Chem. 253, 8759-8766]. When the 360 mM KCl required for reconstitution of 30 S ribosomes is added to the medium, only subtle conformational changes are observed, consistent with the destabilization of the conformation, thus making the RNA molecule more "open" and accessible to protein binding. However, when the concentration of Mg2+ is lowered from 20 to 1 mM, the hydrodynamic parameters indicate that the 16 S RNA is partially unfolded, while thermal denaturation studies suggest that the amount of base-stacking and base-pairing is not concomitantly altered. Further removal of the Mg2+ by dialysis against a pH 7.8 buffer containing no Mg2+ results in a drastic decrease of secondary structure and indicates that the Mg2+ is required for maintenance of the pairing, stacking, and stability of the nucleotide bases, in addition to the long range interactions which result in a compact structure. The results suggest that the 20 mM Mg2+ is required for the 16 S RNA molecules to assume the proper secondary and tertiary structure containing the protein-binding sites, while the high K+ concentration (360 mM KCl) is needed for "loosening up" the RNA, making the protein binding sites more accessible to the ribosomal proteins for molecular recognition and binding as well as for the conformational changes that occur during ribosome assembly.     

Partial reassembly of yeast 60 S ribosomal subunits in vitro following controlled dissociation under nondenaturing conditions

Previously it has been shown that 12 of the yeast ribosomal proteins were extractable from 60 S subunits under a specific nondenaturing condition [J. C. Lee, R. Anderson, Y. C. Yeh, and P. Horowitz (1985) Arch. Biochem. Biophys. 237, 292-299]. In the present paper, we showed that these proteins could be reassembled with the corresponding protein-deficient core particles to form biologically active ribosomal subunits. Effects of time, temperature, and varying concentrations of monovalent cations, divalent cations, cores, and ribosomal proteins on reconstitution were examined. Reconstitution was determined by binding of radiolabeled proteins to the nonradiolabeled cores as well as activity for polypeptide synthesis in a cell-free protein-synthesizing system. The optimal conditions for reconstitution were established. Whereas the core particles were about 10-20% as active as native 60 S subunits in an in vitro yeast cell-free protein-synthesizing system, the reconstituted particles were 80% as active. The activity of the reconstituted particles was proportional to the amount of extracted proteins added to the reconstitution mixture. About 55 +/- 7% of the core particles recombined with the extracted proteins to form reconstituted particles. These reconstituted particles cosedimented with native 60 S subunits in glycerol gradients and contained all of the 12 extractable proteins.