RNA-protein interactions in the ribosome. I. Characterization and ribonuclease digestion of 16 S RNA-ribosomal protein complexes

The structure of a ribosomal protein S8/spc operon mRNA complex

In bacteria, translation of all the ribosomal protein cistrons in the spc operon mRNA is repressed by the binding of the product of one of them, S8, to an internal sequence at the 5' end of the L5 cistron. The way in which the first two genes of the spc operon are regulated, retroregulation, is mechanistically distinct from translational repression by S8 of the genes from L5 onward. A 2.8 A resolution crystal structure has been obtained of Escherichia coli S8 bound to this site. Despite sequence differences, the structure of this complex is almost identical to that of the S8/helix 21 complex seen in the small ribosomal subunit, consistent with the hypothesis that autogenous regulation of ribosomal protein synthesis results from conformational similarities between mRNAs and rRNAs. S8 binding must repress the translation of its own mRNA by inhibiting the formation of a ribosomal initiation complex at the start of the L5 cistron.

Assembly of the 30S ribosomal subunit

Ribosomes are large macromolecular complexes responsible for cellular protein synthesis. The smallest known cytoplasmic ribosome is found in prokaryotic cells; these ribosomes are about 2.5 MDa and contain more than 4000 nucleotides of RNA and greater than 50 proteins. These components are distributed into two asymmetric subunits. Recent advances in structural studies of ribosomes and ribosomal subunits have revealed intimate details of the interactions within fully assembled particles. In contrast, many details of how these massive ribonucleoprotein complexes assemble remain elusive. The goal of this review is to discuss some crucial aspects of 30S ribosomal subunit assembly.

Mutagenesis of ribosomal protein S8 from Escherichia coli: expression, stability, and RNA-binding properties of S8 mutants

Protein S8, a 129 amino acid component of the Escherichia coli ribosome, plays an essential role in the assembly of the 30S ribosomal subunit and in the translational regulation of the spc operon by virtue of its capacity to bind specifically to rRNA and mRNA. To study structure-function relationships within the protein, we have constructed a vector for its high-level expression in vivo and developed efficient methods for its purification. Under our conditions, S8 accumulates to a level of 35% of the cellular protein and can be prepared at a purity of over 98% using either HPLC or a combination of ion-exchange and gel-filtration chromatography. The unique cysteine residue at position 126 was replaced by alanine or serine by oligonucleotide-directed mutagenesis, and the two mutant proteins, CA126 and CS126, were expressed and isolated. The effects of the mutations on the RNA-binding ability, secondary structure, and stability of S8 were assessed. CD spectra indicated that wild-type S8 and the two mutant proteins have very similar secondary structures at 25 degrees C. In addition, both mutants are metabolically stable in vivo as inferred from pulse-chase labeling and immunoprecipitation experiments. However, while CA126 exhibits the same affinity for RNA and the same susceptibility to urea and thermal denaturation as wild-type S8, CS126 is severely impaired in its ability to interact with RNA and displays a dramatic reduction in conformational stability. Our results suggest that Cys126 is unlikely to play a specific role in RNA recognition but that it is an integral part of the RNA-binding domain of protein S8.

Escherichia coli 30S mutants lacking protein S20 are defective in translation initiation

The 30S ribosomal subunits derived from Escherichia coli TA114, a a temperature-sensitive mutant lacking ribosomal protein S20, were shown to be defective in two ways: (a) they have a reduced capacity for association with the 50S ribosomal subunit which results in the impairment of most of the functions requiring a coordinated interaction between the two subunits; (b) they are defective in functions which do not require their interaction with the large subunit (i.e., the formation of ternary complexes with aminocyl-tRNAs and templates, including the formation of 30S initiation complexes with fMet-tRNA and mRNA). The 30S (-S20) subunits seem to interact normally with both template and aminoacyl-tRNA individually, but appear to be impaired in the rate-limiting isomerization step leading to the formation of a codon-anticodon interaction in the P site.

Subunit association defects in Escherichia coli ribosome mutants lacking proteins S20 and L11

The subunit association capacity of 30S and 50S ribosomal subunits from Escherichia coli mutants lacking protein S20 or L11 as well as of 50S subunits depleted of L7/L12 was tested by sucrose gradient centrifugation and by a nitrocellulose filtration method based on the protection from hydrolysis with peptidyl-tRNA hydrolase of ribosome-bound AcPhe-tRNA. It was found that the subunits lacking either S20 or L11 display an altered association capacity, while the 50S subunits lacking L7/L12 have normal association behavior. The association of S20-lacking 30S subunits is quantitatively reduced, especially at low Mg2+ concentrations (5-12 mM), and produces loosely interacting particles which dissociate during sucrose gradient centrifugation. The association of L11-lacking 50S subunits is quantitatively near-normal at all Mg2+ concentrations and produces loosely associating particles only at low Mg2+ concentrations (5-8 mM); the mechanism of their association with 30S subunits, however, or the structure of the resulting 30S-50S couples is altered in such a way as to cause the ejection of an AcPhe-tRNA molecule pre-bound to the 30S subunits in response to poly(U).

Interaction of proteins S16, S17 and S20 with 16 S ribosomal RNA

We have used rapid chemical probing methods to examine the effect of assembly of ribosomal proteins S16, S17 and S20 on the reactivity of individual residues of 16 S rRNA. Protein S17 strongly protects a compact region of the RNA between positions 245 and 281, a site previously assigned to binding of S20. Protein S20 also protects many of these same positions, albeit more weakly than S17. Strong S20-dependent protections are seen elsewhere in the 5' domain, most notably at positions 108, and in the 160-200 and 330 loop regions. Enenpectedly, S20 also causes protection of several bases in the 1430-1450 region, in the 3' minor domain. In the presence of the primary binding proteins S4, S8 and S20, we observe a variety of effects that result from assembly of the secondary binding protein S16. Most strongly protected are nucleotides around positions 50, 120, 300 to 330 and 360 in the 5' domain, and positions 606 to 630 in the central domain. In addition, numerous nucleotides in the 5' and central domains exhibit enhanced reactivity in response to S16. Interestingly, the strength of the S20-dependent effects in the 1430-1450 region is attenuated in the presence of S4 + S8 + S20, and restored in the presence of S4 + S8 + S20 + S16. Finally, the previously observed rearrangement of the 300 region stem-loop that occurs during assembly is shown to be an S16-dependent event. We discuss these findings with respect to assignment of RNA binding sites for these proteins, and in regard to the co-operativity of ribosome assembly.

Higher-order structure of domain III in Escherichia coli 16S ribosomal RNA, 30S subunit and 70S ribosome

We have investigated in detail the conformation of domain III of 16S rRNA (nucleotides 913-1408), using a variety of chemical and enzymatic structure probes. The sites of reaction were identified by primer extension with reverse transcriptase using appropriate oligodeoxyribonucleotide primers. This study has been done on 16S rRNA in its naked form, in the 30S subunit and in the 70S ribosome. Data obtained with naked RNA broadly confirm the secondary structure model proposed essentially by comparative sequence analysis, and allow identification of nucleotides involved in tertiary interactions. Our results are in reasonably good agreement with structure probing experiments of Moazed et al. [1]. However, several discrepancies have been observed. Within the 30S subunit, a high number of nucleotides become unreactive whereas other nucleotides show an enhanced reactivity. This probably reflects local conformational changes. Interestingly, they are located in strategic regions of the RNA, e.g. around C1400 (involved in tRNA binding) and C1192 (involved in spectinomycin recognition). Results are also discussed together with the topographical localization of the ribosomal proteins in this area. The study on the 70S particle allows identification of regions at the interface of subunits or exposed at the surface of the ribosome.

Rapid separation of Escherichia coli 30S ribosomal proteins by fast protein liquid chromatography (FPLC)

The proteins of the 30S ribosomal subunit from Escherichia coli have been separated by reverse-phase high-performance liquid chromatography on a short alkyl chain (C1/C8)-coated phase. The reverse-phase column was connected to a fast protein liquid chromatography (FPLC) system. The 21 proteins of the 30S ribosomal subunit were resolved into 16 peaks. Eleven proteins were isolated in purified form in a single chromatographic run as shown by polyacrylamide gel electrophoresis and amino acid analysis. Interestingly, the retention times of some proteins differed from the retention times observed on other reversed-phase support materials. The results show the speed and resolution of reverse-phase FPLC for both analytical and semi-preparative separations of 30S ribosomal proteins.

Evidence that E. coli ribosomal protein S13 has two separable functional domains involved in 16S RNA recognition and protein S19 binding

We have found that E. coli ribosomal protein S13 recognizes multiple sites on 16S RNA. However, when protein S19 is included with a mixture of proteins S4, S7, S8, S16/S17 and S20, the S13 binds to the complex with measurably greater strength and with a stoichiometry of 1.5 copies per particle. This suggests that the protein may have two functional domains. We have tested this idea by cleaving the protein into two polypeptides. It was found that one of the fragments, composed of amino acid residues 84-117, retained the capacity to bind 16S RNA at multiple sites. Protein S19 had no affect on the strength or stoichiometry of the binding of this fragment. These data suggest that S13 has a C-terminal domain primarily responsible for RNA recognition and possibly that the N-terminal region is important for association with protein S19.

Photochemical cross-linking of tRNA1Arg to the 30S ribosomal subunit using aryl azide reagents attached to the anticodon loop

The 2-thiocytidine residue at position 32 of tRNA1Arg from Escherichia coli was modified specifically with three photoaffinity reagents of different lengths, and the corresponding N-acetylarginyl-tRNA1Arg derivatives were cross-linked to the P site of E. coli 70S ribosomes by irradiation. Covalent attachment was dependent upon the presence of a polynucleotide template and exposure to light of the appropriate wavelength. From 4% to 6% of the noncovalently bound tRNA became cross-linked to the ribosome as a result of photolysis, and attachment to the P site was confirmed by the reactivity of arginine in the covalent complexes toward puromycin. Analysis of the irradiated ribosomes by sucrose-gradient sedimentation at low Mg2+ concentration revealed that the tRNA was associated exclusively with the 30S subunit in all cases. Two of the N-acetylarginyl-tRNA1Arg derivatives were attached primarily to ribosomal proteins whereas the third was cross-linked mainly to 16S RNA. Partial RNase digestion of the latter complex demonstrated that the tRNA had become attached to the 3' third of the rRNA molecule. In addition, the tRNA-rRNA bond was shown to be susceptible to cleavage by hydroxylamine and mercaptoethanol.

Covalent cross-linking of tRNAGly1 to the ribosomal P site via the dihydrouridine loop

The dihydrouracil residue at position 20 of Escherichia coli tRNAGly1 has been replaced by the photoaffinity reagent, N-(4-azido-2-nitrophenyl)glycyl hydrazide (AGH). The location of the substituent was confirmed by the susceptibility of the modified tRNA to cleavage with aniline. When N-acetylglycyl-tRNAGly1 derivatized with AGH was bound noncovalently to the P site of E. coli 70 S ribosomes, 5-6% on average was photochemically cross-linked to the ribosomal particles in a reaction requiring poly(G,U), irradiation and the presence of the AGH label in the tRNA. Approximately two-thirds of the covalently attached tRNA was associated with 16 S RNA in the 30 S subunit. This material was judged to be in the P site by the criterion of puromycin reactivity. As partial RNAase digestion of the tRNA-16 S RNA complex produced labeled fragments from both 5' and 3' segments of the rRNA, there appeared to be more than one site of cross-linking in the 30 S subunit. The small amount of N-acetylglycyl-tRNAGly1 associated with the 50 S subunit was also linked mainly to rRNA, but it was not puromycin-reactive.

Ribonucleic acid-protein cross-linking within the intact Escherichia coli ribosome, utilizing ethylene glycol bis[3-(2-ketobutyraldehyde) ether], a reversible, bifunctional reagent: identification of 30S proteins

To obtain detailed topographical information concerning the spatial arrangement of the multitude of ribosomal proteins with respect to specific sequences in the three RNA chains of intact ribosomes, a reagent capable of covalently and reversibly joining RNA to protein has been synthesized [Brewer, L.A., Goelz, S., & Noller, H. F. (1983) Biochemistry (preceding paper in this issue)]. This compound, ethylene glycol bis[3-(2-ketobutyraldehyde) ether] which we term "bikethoxal", possesses two reactive ends similar to kethoxal. Accordingly, it reacts selectively with guanine in single-stranded regions of nucleic acid and with arginine in protein. The cross-linking is reversible in that the arginine- and guanine-bikethoxal linkage can be disrupted by treatment with mild base, allowing identification of the linked RNA and protein components by standard techniques. Further, since the sites of kethoxal modification within the RNA sequences of intact subunits are known, the task of identifying the components of individual ribonucleoprotein complexes should be considerably simplified. About 15% of the ribosomal protein was covalently cross-linked to 16S RNA by bikethoxal under our standard reaction conditions, as monitored by comigration of 35S-labeled protein with RNA on Sepharose 4B in urea. Cross-linked 30S proteins were subsequently removed from 16S RNA by treatment with T1 ribonuclease and/or mild base cleavage of the reagent and were identified by two-dimensional polyacrylamide gel electrophoresis. The major 30S proteins found in cross-linked complexes are S4, S5, S6, S7, S8, S9 (S11), S16, and S18. The minor ones are S2, S3, S12, S13, S14, S15, and S17.

Expression of the gene for ribosomal protein S20: effects of gene dosage

We have exploited the properties of three different plasmids which carry the gene for Escherichia coli ribosomal protein S20 (rpsT) to test the effects of gene dosage on the expression of rpsT. Over a range of total copies of rpsT of 1 to 58 per haploid genome equivalent, the rate of incorporation of uridine during a 30-s pulse into RNA annealing to either of two specific probes for S20 mRNA increased essentially in proportion to copy number. In contrast, the rate of synthesis of S20 protein increased no more than 2.1-fold at the highest copy number. We conclude, in contrast to an earlier report (D. Geyl, and A. Böck, Mol. Gen. Genet. 154:327-334, 1977), that the synthesis of S20 is regulated at a posttranscriptional step. We propose that S20 itself is the regulatory agent and that binding of S20 to its own mRNA in regions homologous in structure with 16S rRNA can account for our results.

Physical characteristics of the reconstitution intermediates (RI30 and RI30*) from the 30S ribosomal subunit of Escherichia coli

The isolated reconstitution intermediates (RI30 and RI30*) from the 30S ribosomal subunit of Escherichia coli were found to contain ten proteins. The sedimentation coefficients, diffusion coefficients, density increments, extinction coefficients, and molecular weights were determined for the reconstitution particles and compared with those obtained from the 16S rRNA under identical buffer conditions. The results show that the binding of the proteins on the 16S rRNA at 4 degrees C does not markedly affect the folding of the RNA molecule. However, upon heating the RI30 particle at 40 degrees C to form the RI30* particle, significant folding of the RNA took place, giving a structure considerably more compact than that of the 16S rRNA or the RI30 particle.

Structural organization of the 16S ribosomal RNA from E. coli. Topography and secondary structure

Extensive studies in our laboratory using different ribonucleases resulted in valuable data on the topography of the E.coli 16S ribosomal RNA within the native 30S subunit, within partially unfolded 30S subunits, in the free state, and in association with individual ribosomal proteins. Such studies have precise details on the accessibility of certain residues and delineated highly accessible RNA regions. Furthermore, they provided evidence that the 16S rRNA is organized in its subunit into four distinct domains. A secondary structure model of the E.coli 16S rRNA has been derived from these topographical data. Additional information from comparative sequence analyses of the small ribosomal subunit RNAs from other species sequenced so far has been used.

Apparent association constants for E. coli ribosomal proteins S4, S7, S8, S15, S17 and S20 binding to 16S RNA

We have previously reported the development of a technique utilizing nitrocellulose filters, which rapidly separates ribosomal protein-ribosomal RNA complexes from unbound protein. We have used this technique to obtain binding data for the association of proteins S4, S7, S8, S15, S17, and S20 with 16S RNA. With the exception of protein S17, the association behavior for each of these proteins exhibits a single binding site with a unique binding constant. The apparent association constants have been calculated and have been found to have a range from 1.6 x 10(6) M-1 for protein S7 to 7.1 x 10(7) M-1 for protein S17. The Scatchard plot for the protein S17 binding data is biphasic, suggesting that within the RNA population two different binding sites exist, each with a different apparent association constant.

Factors modulating transcription and translation in vitro of ribosomal protein S20 and isoleucyl-tRNA synthetase from Escherichia coli

The DNA-dependent protein-synthesizing system developed by Zubay [Zubay, G. (1973) Annu. Rev. Genet. 7, 267--287] was optimized for the transcription and translation of genes from the 0.5-min region of the Escherichia coli chromosome carried by transducing lambda phages. The E. coli gene products synthesized were isoleucyl tRNA synthetase, ribosomal protein S20, dihydrodipicolinic acid reductase and (possibly) the two subunits carbamoyl-phosphate synthetase. Formation of ribosomal protein S20 is specifically stimulated by the addition of 16-S rRNA and not by 5-S or 23-S rRNA. 16-S rRNA increases the rate of S20 synthesis, the final yield of product depends on the duration of persistence of the RNA added. Addition of 16-S rRNA to the separate transcription and translation systems showed that it is the translation of the S20 mRNA which is enhanced. Furthermore, S20 synthesis is stimulated more than fourfold when concomitant synthesis of rRNA occurs from a plasmid carrying an rrn transcriptional unit. The results described are explained in terms of a model which suggests that ribosomal protein S20 feedback inhibits its synthesis at the translational level and that removal of S20 into ribosomal assembly (i.e. binding to 16-S rRNA) releases inhibition. The model postulates a direct link between synthesis of ribosomal RNA and ribosomal protein and between the rates of ribosomal assembly and ribosomal protein synthesis. The stimulatory effect of guanosine 3'-diphosphate 5'-diphosphate on isoleucyl-tRNA synthetase formation and its inhibition of the synthesis of ribosomal protein S20 in vitro occurs at the level of transcription. Its relevance in vivo, however, remains to be demonstrated. Formation of isoleucyl-tRNA synthetase in vitro is not influenced either by the addition of a surplus of purified enzyme nor by the limitation of protein synthesis by the addition of anti-(isoleucyl-tRNA synthetase) serum. There is no evidence, therefore, that isoleucyl-tRNA synthetase is autogenously regulated.

Ribonucleic acid-protein cross-linking in Escherichia coli ribosomes: (4-azidophenyl)glyoxal, a novel heterobifunctional reagent

We have used the heterobifunctional reagent (4-azidophenyl)glyoxal (APG) to cross-link RNA to protein in Escherichia coli 30S ribosomal subunits. Synthesis and characterization of the reagent are described. Like other dicarbonyl reagents (e.g., kethoxal), APG reacts specifically with guanosine among the four ribonucleosides. The azido group in APG can be photolyzed with UV light (lambda greater than 300 nm), yielding an unstable nitrene which is potentially reactive with many groups in proteins and nucleic acids. Conditions for APG modification of guanylic acid residues in 30S subunits are described; photolysis of bound APG results in cross-linking of approximately 5% of the total 30S proteins to 16S RNA. A specific subset of the 30S proteins is cross-linked to 16S RNA by APG.

The conformation of a large RNA fragment from the E.coli ribosomal 16S-RNA. An X-ray and neutron small-angle scattering study

A large 12S RNA fragment which constitutes the 5' two-thirds of 16S-RNA from the E. coli 30S subunit has been investigated by small-angle X-ray and neutron scattering. The results indicate that in reconstitution buffer the 12S-RNA fragment has a molecular weight of 270,000 +/- 20,000 and a radius of gyration of 7.1 nm. The scattering data are compatible with the RNA being folded into two major domains with the shapes of two adjacent, quite similar cylinders.

Methylation map of Xenopus laevis ribosomal RNA

One of the most enigmatic features of eukaryotic ribosomal RNA is the presence of many methylated nucleotides. The numbers of RNA methyl groups range from approximately 70 per ribosome in yeast to over 100 in vertebrates. Here it is shown that the methylated nucleotides in Xenopus laevis rRNA are broadly but non-uniformly distributed. In 18S rRNA 2'-O-methylations are partly concentrated in the 5' region and base methylations near the 3' end. In 28S rRNA methyl groups are infrequent in the 5' region, moderately frequent in the central region and abundant in an 1,100-nucleotide tract near the 3' end.

30-S ribosomal subunit proteins of an Escherichia coli mutant in which assembly of the small ribosomal subunit is temperature-sensitive

Escherichia coli 219ts2, a temperature-sensitive streptomycin-independent revertant of the streptomycin-dependent strain E. coli 209 is defective in 30-S ribosomal subunit assembly at 42 degrees C. Total 30-S ribosomal subunit proteins of this strain contain two additional components one of which (alpha) migrates below and the other (beta) to the right of protein S7 in two-dimensional polyacrylamide gel analyses carried out according to Kaltschmidt and Wittmann. These two components are also resolved from normal 30-S subunit proteins by chromatography on phosphocellulose. Tryptic fingerprinting of proteins alpha and beta identifies alpha as protein S7B, the form of S7 found in B strains of E. coli and beta as a mutant form of protein S4 produced by deletion of about 20 amino acids from the COOH terminus of the wild-type protein.

Regulation of synthesis of ribosomal protein S20 in vitro

Addition of 16S rRNA to a coupled transcription-translation in vitro system stimulated the synthesis of ribosomal protein S20 from transducing phage lambda DNA. The S20 made under this condition was found to be bound to 16S rRNA. These results may indicate a connection between ribosomal assembly and the rate of ribosomal protein synthesis.

Binding sites for ribosomal proteins S8 and S15 in the 16 S RNA of Escherichia coli

A fragment of the 16 S ribosomal RNA of Escherichia coli that contains the binding sites for proteins S8 and S15 of the 30 S ribosomal subunit has been isolated and characterized. The RNA fragment, which sediments as 5 S, was partially protected from pancreatic RNAase digestion when S15 alone, or S8 and S15 together, were bound to the 16 S RNA. Purified 5 S RNA was shown to reassociate specifically with protein S15 by analysis of binding stoichiometry. Although interaction between the fragment and protein S8 alone could not be detected, the 5 S RNA selectively bound both S8 and S15 when incubated with an unfractionated mixture of 30-S subunit proteins. Nucleotide sequence analysis demonstrated that the 5 S RNA arises from the middle of the 16 S RNA molecule and encompasses approximately 150 residues from Sections C, C'1 and C'2. Section C consists of a long hairpin loop with an extensively hydrogen-bonded stem and is contiguous with Section C'1. Sections C'1 and C'2, although not contiguous, are highly complementary and it is likely that together they comprise the base-paired stem of an adjacent loop.

The primary structure of ribosomal protein S7 from E. coli strains K and B

Ribosomal proteins S7 from 30S subunits of Escherichia coli strains K and B differ extensively in their aminoacid compositions. The experimental details which led to the determination of the complete primary structures of proteins S7K and S7B are presented. Protein S7K consists of a single polypeptide chain of 177 aminoacids giving a calculated molecular weight of 19, 732, whereas protein S7B has 153 residues which amount to a molecular weight of 17,131. Aminoacid sequences were determined by a combination of automated Edman degradation of the intact proteins in a modified Beckman sequenator and sequencing of peptides obtained by digestion with trypsin. Staphylococcus aureus protease, thermolysin and pepsin, either by solid-phase Edman degradation or by dansyl-Edman degradation. Additional information about the primary structure was derived from peptides resulting from chemical cleavages of the protein by 2-(2-nitrophenyl-sulphenyl)-3-methyl 3' bromoindolenine at its tryptophanyl bonds and by cyanogen bromide at its methionyl bonds leading to large fragments. The mutational event occurring between S7B and S7K was characterized. Protein S7K contains an additional sequence of 24 aminoacids at its C-terminal end. The aminoacid sequence of both proteins S7K and S7B was compared to the published sequences of the other ribosomal proteins of Escherichia coli and predictions for the secondary structure of these proteins were made.

Conformational changes in 16S ribosomal RNA induced by 30S ribosomal subunit proteins from Escherichia coli

Laser light scattering has been used to evaluate conformational differences between free 16S RNA and several specific protein-16S RNA complexes. Proteins that interact strongly with the 16S RNA early in subunit assembly stabilize the RNA chain against unfolding in 1 mM Mg2+ and actually promote the formation of a more compact teriary structure in 20 mM Mg2+. A vital function of these proteins may therfore consist in altering the configuration of the RNA so that further assembly reactions can take place.

Localisation of part of the binding sites of 30S ribosomal proteins S4 and S20 in a small uninterrupted fragment of 16S RNA

Analyses of the T1 ribonuclease-alkaline phosphatase fingerprint of a continuous fragment of the 16S rRNA, 170-230 nucleotides long, isolated from the products of autodigestion of 30S ribosome subunits show that it contains a sequence near the 5'-phosphate terminus of intact 16S rRNA and corresponds to segment H'-M of this molecule as defined by Ehresmann et al [29]. Incubation of this fragment with total 30S ribosomal proteins under reconstitution conditions leads to the formation of a complex containing proteins S4, S20, and one or both of proteins S16 and S17. The stoichiometry of these proteins in the complex is discussed.

Further evidence that the ribosomal 30S proteins S3, S5, S9, S11, S12, and S18 possess specific 16S RNA binding sites

E. Coli ribosomal 16S RNA prepared by an acetic acid-urea extraction technique individually binds, in addition to the seven established proteins, 6 new 30S ribosomal proteins (S3, S5, S9, S12, S18 and S11) (Hochkeppel et al., 1976). In this communication we demonstrate the site specificity of these proteins. Binding curves of the individual proteins with acetic acid-urea 16S RNA show that the binding of all six proteins to the RNA reaches a plateau at 0.3-0.97 copies per 16S RNA molecule. No significant binding of these proteins to classicial phenol extracted 16S RNA is observed, with the exception of S13 which binds 0.2 copies of protein per molecule of 16S RNA. Specificity of binding of these proteins is also demonstrated in "chase" experiments. The site specificity of individual [3H]-labeled 30S proteins bounds to 16S RNA is tested by the addition of non-radioactive 30S total protein to the reaction mixture.

Characterisation of RNA fragments obtained by mild nuclease digestion of 30-S ribosomal subunits from Escherichia coli

When Escherichia coli 30-S ribosomal subunits are hydrolysed under mild conditions, two ribonucleoprotein fragments of unequal size are produced. Knowledge of the RNA sequences contained in these hydrolysis products was required for the experiments described in the preceding paper, and the RNA sub-fragments have therefore been examined by oligonucleotide analysis. Two well-defined small fragments of free RNA, produced concomitantly with the ribonucleoprotein fragments, were also analysed. The larger ribonucleoprotein fragment, containing predominantly proteins S4, S5, S8, S15, S16 (17) and S20, contains a complex mixture of RNA sub-fragments varying from about 100 to 800 nucleotides in length. All these fragments arose from the 5'-terminal 900 nucleotides of 16-S RNA, corresponding to the well-known 12-S fragment. No long-range interactions could be detected within this RNA region in these experiments. The RNA from the smaller ribonucleoprotein fragment (containing proteins S7, S9 S10, S14 and S19) has been described in detail previously, and consists of about 450 nucleotides near the 3' end of the 16-S RNA, but lacking the 3'-terminal 150 nucleotides. The two small free RNA fragments (above) partly account for these missing 150 nucleotides; both fragments arose from section A of the 16-S RNA, but section J (the 3'-terminal 50 nucleotides) was not found. This result suggests that the 3' region of 16-S RNA is not involved in stable interactions with protein.

Evidence for a precursor-product relationship in the biosynthesis of ribosomal protein S20

The kinetics of labeling ribosomal protein S20 of Escherichia coli strains H882 and H882 groE44 have been examined using partial reconstitution as a means of binding this and some other 30S subunit proteins selectively to 16S RNA from crude extracts prepared by acetic acid extraction of pulse-labeled whole cells. The rate of labeling of S20 during short pulses at 44 degrees C is less than 20% of that observed at 28 degrees C. S20 can be recovered from the cells labeled at the higher temperature if they are chased at 28 degrees C, but not at 44 degrees C, in the presence of excess sulfate prior to their extraction. These observations suggest that S20 is derived from a precursor whose processing is blocked at 44 degrees C. Among the proteins extracted from cells labeled at 44 degrees C capable of binding to 16S RNA is a novel polypeptide, p2, which is not normally present on the 30S subunit. The kinetics of its appearance at 44 degrees C, and its chasing at 28 degrees C, suggest a precursor-product relationship with S20. p2 contains a tryptic peptide with the chromatographic properties of the peptide Ser-Met-Met-Arg at position 25-28 in S20. A second methionine-containing peptide at positions 49-59 of S20 is missing from p2. In addition, the apparent molecular weight of p2 (8600) is less than that of S20 (9500). p2 may represent the product of degradation of a precursor to S20, yet retains the ability to bind to 16S RNA. It is much less likely that p2 is a bona fide precursor which is converted into S20 by fusion to some other polypeptide.