Visualization of tRNA movements on the Escherichia coli 70S ribosome during the elongation cycle.

Three-dimensional cryomaps have been reconstructed for tRNA-ribosome complexes in pre- and posttranslocational states at 17-A resolution. The positions of tRNAs in the A and P sites in the pretranslocational complexes and in the P and E sites in the posttranslocational complexes have been determined. Of these, the P-site tRNA position is the same as seen earlier in the initiation-like fMet-tRNA(f)(Met)-ribosome complex, where it was visualized with high accuracy. Now, the positions of the A- and E-site tRNAs are determined with similar accuracy. The positions of the CCA end of the tRNAs at the A site are different before and after peptide bond formation. The relative positions of anticodons of P- and E-site tRNAs in the posttranslocational state are such that a codon-anticodon interaction at the E site appears feasible.

Hepatitis C virus IRES RNA-induced changes in the conformation of the 40s ribosomal subunit.

Initiation of protein synthesis in eukaryotes requires recruitment of the 40S ribosomal subunit to the messenger RNA (mRNA). In most cases, this depends on recognition of a modified nucleotide cap on the 5' end of the mRNA. However, an alternate pathway uses a structured RNA element in the 5' untranslated region of the messenger or viral RNA called an internal ribosomal entry site (IRES). Here, we present a cryo-electron microscopy map of the hepatitis C virus (HCV) IRES bound to the 40S ribosomal subunit at about 20 A resolution. IRES binding induces a pronounced conformational change in the 40S subunit and closes the mRNA binding cleft, suggesting a mechanism for IRES-mediated positioning of mRNA in the ribosomal decoding center.

A method for differentiating proteins from nucleic acids in intermediate-resolution density maps: cryo-electron microscopy defines the quaternary structure of the Escherichia coli 70S ribosome.

BACKGROUND: This study addresses the general problem of dividing a density map of a nucleic-acid-protein complex obtained by cryo-electron microscopy (cryo-EM) or X-ray crystallography into its two components. When the resolution of the density map approaches approximately 3 A it is generally possible to interpret its shape (i. e., the envelope obtained for a standard choice of threshold) in terms of molecular structure, and assign protein and nucleic acid elements on the basis of their known sequences. The interpretation of low-resolution maps in terms of proteins and nucleic acid elements of known structure is of increasing importance in the study of large macromolecular complexes, but such analyses are difficult. RESULTS: Here we show that it is possible to separate proteins from nucleic acids in a cryo-EM density map, even at 11.5 A resolution. This is achieved by analysing the (continuous-valued) densities using the difference in scattering density between protein and nucleic acids, the contiguity constraints that the image of any nucleic acid molecule must obey, and the knowledge of the molecular volumes of all proteins. CONCLUSIONS: The new method, when applied to an 11.5 A cryo-EM map of the Escherichia coli 70S ribosome, reproduces boundary assignments between rRNA and proteins made from higher-resolution X-ray maps of the ribosomal subunits with a high degree of accuracy. Plausible predictions for the positions of as yet unassigned proteins and RNA components are also possible. One of the conclusions derived from this separation is that 23S rRNA is solely responsible for the catalysis of peptide bond formation. Application of the separation method to any nucleoprotein complex appears feasible.

Direct three-dimensional localization and positive identification of RNA helices within the ribosome by means of genetic tagging and cryo-electron microscopy.

BACKGROUND: Ribosomes are complex macromolecular machines that perform the translation of the genetic message. Cryo-electron microscopic (cryo-EM) maps of the Escherichia coli 70S ribosome are approaching a resolution of 10 A and X-ray maps of the 30S and 50S subunits are now available at 5 A. These maps show a lot of details about the inner architecture of the ribosome and ribosomal RNA helices are clearly visible. However, in the absence of further biological information, even at the higher resolution of the X-ray maps many rRNA helices can be placed only tentatively. Here we show that genetic tagging in combination with cryo-EM can place and orient double-stranded RNA helices with high accuracy. RESULTS: A tRNA sequence inserted into the E. coli 23S ribosomal RNA gene, at one of the points of sequence expansion in eukaryotic ribosomes, is visible in the cryo-EM map as a peripheral 'foot' structure. By tracing its acceptor-stem end, the location of helix 63 in domain IV and helix 98 in domain VI of the 50S subunit could be precisely determined. CONCLUSIONS: Our study demonstrates for the first time that features of a three-dimensional cryo-EM map of an asymmetric macromolecular complex can be interpreted in terms of secondary and primary structure. Using the identified helices as a starting point, it is possible to model and interpret, in molecular terms, a larger portion of the ribosome. Our results might be also useful in interpreting and refining the current X-ray maps.

Similarities and differences in the inhibition patterns of thiostrepton and viomycin: evidence for two functionally different populations of P sites when occupied with AcPhe-tRNA.

According to the allosteric three-site model for the ribosomal elongation cycle, the reactions from the pre- to the post-translocational state and vice versa represent allosteric transitions which are catalyzed by elongation factor (EF)-G and EF-Tu, respectively. It has been shown recently that the non-related antibiotics thiostrepton and viomycin inhibit protein biosynthesis via a surprisingly similar mechanism. Both drugs primarily block the allosteric transitions in either direction (Hausner et al. (1988) J. Biol. Chem. 263, 13103-13111). Here we show that the secondary effects of these antibiotics differ strikingly. When the P site of poly(U) programmed ribosomes is quantitatively filled with AcPhe-tRNA, thiostrepton stimulates the rate of the formation of AcPhe-puromycin 2-fold, whereas viomycin inhibits the puromycin reaction (up to 75% inhibition). The thiostrepton-dependent stimulation is only observed when the drug is given before the P site is occupied; when thiostrepton is added after pre-filling the P site, the peptidyltransferase activity is not affected, in contrast to the translocation reaction, which is blocked irrespective of whether the drug is administered before or after tRNA is bound. The effects of both drugs became distinctly more pronounced when the P sites were saturated with AcPhe-tRNA as compared to half-saturated ribosomes. We conclude that roughly one half of the ribosomes, which first bind AcPhe-tRNA to the P site, carry this ligand in a different orientation to that of the second half of the ribosome population. These two populations probably reflect the P site in the pre- and post-translocational state, respectively.

Throwing a spanner in the works: antibiotics and the translation apparatus.

The protein synthetic machinery is essential to all living cells and is one of the major targets for antibiotics. Knowledge of the structure and function of the ribosome and its associated factors is key to understanding the mechanism of drug action. Conversely, drugs have been used as tools to probe the translation cycle, thus providing a means to further our understanding of the steps that lead to protein synthesis. Our current understanding as to how antibiotics disrupt this process is reviewed here, with particular emphasis on the prokaryotic elongation cycle and those drugs that interact with ribosomal RNAs.

Models of the elongation cycle: an evaluation.

The central process for the transfer of the genetic information from the nucleic acid world into the structure of proteins is the ribosomal elongation cycle, where the sequence of codons is translated into the sequence of amino acids. The nascent polypeptide chain is elongated by one amino acid during the reactions of one cycle. Essentially, three models for the elongation cycle have been proposed. The allosteric three-site model and the hybrid-site model describe different aspects of tRNA binding and do not necessarily contradict each other. However, the alpha-epsilon model is not compatible with both models. The three models are evaluated in the light of recent results on the tRNA localization within the ribosome: the tRNAs of the elongating ribosome could be localized by two different techniques, viz. an advanced method of small-angle neutron scattering and cryo-electron microscopy. The best fit with the biochemical and structural data is obtained with the alpha-epsilon model.

Interaction of tRNAs with the ribosome at the A and P sites.

In vitro transcribed tRNA(Phe) analogues from Escherichia coli containing up to four randomly distributed A, G, U or C phosphorothioated nucleotides were used to investigate contact patterns with the ribosome in the A and P sites. The tRNAs were biologically active. Molecular iodine (I2) can trigger a break in the sugar-phosphate backbone at phosphorothioated positions of the ribosomal bound tRNAs if contacts with ribosomal components do not prevent access of the iodine. Highly differentiated protection patterns were found which were strikingly different in the A and P sites, respectively. Strong protections accumulated in the T psi C loop and no protection was seen in the extra-arm region in both sites, whereas the phosphates in the anticodon loop are more strongly protected in the A site. Strong common protections in both the A and P sites were found neighbouring universally or semi-universally conserved bases in prominent regions of the tertiary structure of tRNAs: Y11, Y32, U33, psi55, C56, A58 and Y60. These bases are therefore candidates for 'identity elements' in ribosomal tRNA recognition. The data further indicate that tRNAs change their conformations upon binding to either ribosomal site.

Selecting rRNA binding sites for the ribosomal proteins L4 and L6 from randomly fragmented rRNA: application of a method called SERF.

Two-thirds of the 54 proteins of the Escherichia coli ribosome interact directly with the rRNAs, but the rRNA binding sites of only a very few proteins are known. We present a method (selection of random RNA fragments; SERF) that can identify the minimal binding region for proteins within ribonucleo-protein complexes such as the ribosome. The power of the method is exemplified with the ribosomal proteins L4 and L6. Binding sequences are identified for both proteins and characterized by phosphorothioate footprinting. Surprisingly, the binding region of L4, a 53-nt rRNA fragment of domain I of 23S rRNA, can simultaneously and independently bind L24, one of the two assembly initiator proteins of the large subunit.

Prediction of oxygen uptake and energy expenditure during exercise in obese women.

PURPOSE: For patients concerned with weight loss, monitoring the energy balance between daily dietary intake and exercise expenditure can be useful. Formulas commonly used to estimate the energy costs of exercise were previously derived from healthy men of normal body weight. The purpose of this study was to determine the relationship between measured and predicted exercise energy expenditure for obese women. METHODS: Oxygen uptake (VO2) was measured using respiratory gas analysis in 45 obese (92 +/- 16 kg; 40 +/- 7% fat) and 10 normal weight (control) (58 +/- 5 kg; 21 +/- 6% fat) women during progressive exercise on a motorized treadmill. VO2 was also calculated at matched workrates using a regression equation published by the American College of Sports Medicine. The relationship between predicted versus measured VO2 was determined using least squares regression analysis. RESULTS: The slope of the regression line for measured versus predicted VO2 for controls (y = 0.98x +/- 0.56; P < .001) was different than that of obese women (y = 0.75x +/- 3.06; P < .001). The slope of the regression line for controls was in close approximation to the line of identity, whereas the slope for obese was below it. Using VO2 to calculate kcal, measured energy expenditure, was significantly lower than predicted energy expenditure for obese subjects, but not for controls at several matched workrates: Stage III (213 +/- 40 versus 225 +/- 38 kcal per 30 minutes, P < .001); stage 4 (292 +/- 55 versus 340 +/- 58 kcal per 30 minutes, P < .001); and stage 5 (330 +/- 55 versus 412 +/- 70 kcal per 30 minutes, P < .001) obese measured versus obese predicted, respectively. CONCLUSIONS: The authors conclude that the standard prediction equation gives a better estimation of VO2 for women who have average body weight and body fat than for obese women. This may, in part, be due to the differences in weight and/or fat mass between these subjects and those used to derive this equation. These findings should be considered when estimates of VO2 and energy expenditure are used rather than direct measures for obese women.

Mutational analysis of two highly conserved UGG sequences of 23 S rRNA from Escherichia coli.

The 23 S-type rRNA contains two phylogenetically conserved UGG sequences, which have the potential to bind the universal CCA-3'-ends of tRNAs at the ribosomal peptidyltransferase center by base pairing. The first two positions, UG, of these sequences at the helix-loop 80 (U2249G2250) and helix-loop 90 (Psi2580G2581) and some related nucleotides were tested by site-directed mutagenesis for their involvement in ribosomal function, i.e. peptidyltransferase. The plasmid-derived mutated 23 S rRNA comprised about 50% of the total 23 S rRNA. None of the single mutations caused an assembly defect, and all 50 S subunits carrying an altered 23 S rRNA could freely exchange with the pools of 70S ribosomes and polysomes. The mutations at the helix-loop 80 region hardly affected bacterial growth. However, mutations at the helix 90 caused severe growth effects and severely impaired the in vitro protein synthesis, showing that this 23 S rRNA region is of high importance for ribosomal function.

Conserved nucleotides of 23 S rRNA located at the ribosomal peptidyltransferase center.

Two nucleotides of the 23 S rRNA gene were mutated; the nucleotides correspond to the first two positions of the universally conserved sequence PsiGG2582 at the peptidyltransferase ring of 23 S rRNA. The ribosomes containing the altered 23 S rRNA were analyzed. Previously, it was shown that ribosomal assembly was indistinguishable from that in wild-type cells, that the flow of the corresponding 50 S subunit into the polysome fraction was not restricted, but that the ribosomes were strongly impaired in poly(Phe) synthesis (C. M. T. Spahn, J. Remme, M. A. Schäfer, and K. H. Nierhaus (1996) J. Biol. Chem. 271, 32849-32856). Here we apply assay systems exclusively testing the puromycin reaction of ribosomes carrying plasmid-born rRNA, a dipeptide assay using the minimal P site donor pA(fMet) and a translocation system not depending on the puromycin reaction. The mutations in helix 90 exclusively abolish or severely impair the ribosome capability to catalyze AcPhe-puromycin formation. A possible explanation of these observations is that G2581 and Psi2580 (and possibly also G2582) are part of the binding site of C75 of peptidyl-tRNA in the P site. The results suggest that in this case, however, such an interaction would disobey canonical base pairing.

Protection patterns of tRNAs do not change during ribosomal translocation.

The translocation reaction of two tRNAs on the ribosome during elongation of the nascent peptide chain is one of the most puzzling reactions of protein biosynthesis. We show here that the ribosomal contact patterns of the two tRNAs at A and P sites, although strikingly different from each other, hardly change during the translocation reaction to the P and E sites, respectively. The results imply that the ribosomal micro-environment of the tRNAs remains the same before and after translocation and thus suggest that a movable ribosomal domain exists that tightly binds two tRNAs and carries them together with the mRNA during the translocation reaction from the A-P region to the P-E region. These findings lead to a new explanation for the translocation reaction.

Ribosomal tRNA binding sites: three-site models of translation.

The first models of translation described protein synthesis in terms of two operationally defined tRNA binding sites, the P-site for the donor substrate, the peptidyl-tRNA, and the A-site for the acceptor substrates, the aminoacyl-tRNAs. The discovery and analysis of the third tRNA binding site, the E-site specific for deacylated tRNAs, resulted in the allosteric three-site model, the two major features of which are (1) the reciprocal relationship of A-site and E-site occupation, and (2) simultaneous codon-anticodon interactions of both tRNAs present at the elongating ribosome. However, structural studies do not support the three operationally defined sites in a simple fashion as three topographically fixed entities, thus leading to new concepts of tRNA binding and movement: (1) the hybrid-site model describes the tRNAs' movement through the ribosome in terms of changing binding sites on the 30S and 50S subunits in an alternating fashion. The tRNAs thereby pass through hybrid binding states. (2) The alpha-epsilon model introduces the concept of a movable tRNA-binding domain comprising two binding sites, termed alpha and epsilon. The translocation movement is seen as a result of a conformational change of the ribosome rather than as a diffusion process between fixed binding sites. The alpha-epsilon model reconciles most of the experimental data currently available.

Mutational analysis of the donor substrate binding site of the ribosomal peptidyltransferase center.

Previous experiments have shown that the top of helix 90 of 23S rRNA is highly important for the ribosomal peptidyltransferase activity and might be part of the donor (P) site. Developing on these studies, mutations in the 23S rRNA at the highly conserved positions G2505, G2582, and G2583 were investigated. None of the mutations affected assembly, subunit association, or the capacity of tRNA binding to A and P sites. A "selective transpeptidation assay" revealed that the mutations specifically impaired peptide bond formation. Results with a modified "fragment" assay using the minimal donor substrate pA-fMet are consistent with a model where the nucleotides psiGG2582 form a binding pocket for C75 of the tRNA.

Effects of antisense DNA against the alpha-sarcin stem-loop structure of the ribosomal 23S rRNA.

Antisense DNAs complementary against various sequences of the alpha-sarcin domain (C2646-G2674) of 23S rRNA from Escherichia coli were hybridized to naked 23S rRNA as well as to 70S ribosomes. Saturation levels of up to 0.4 per 70S ribosome were found, the identical fraction was susceptible to the attack of the RNase alpha-sarcin. The hybridization was specific as demonstrated with RNase H digestion, sequencing the resulting fragments and blockage of the action of alpha-sarcin. The RNase alpha-sarcin seems to approach its cleavage site from the 3' half of the loop of the alpha-sarcin domain. Hybridization is efficiently achieved at 37 degrees C and can extend at least into the 3' strand of the stem of the alpha-sarcin domain. However, the inhibition of alpha-sarcin activity is observed at 30 degrees C but not at 37 degrees C. For a significant inhibition of poly(Phe) synthesis the temperature had to be lowered to 25 degrees C. The results imply that the alpha-sarcin domain changes its conformation during protein synthesis and that the conformational changes may include a melting of the stem of the alpha-sarcin domain.

Clinical profile and outcomes of obese patients in cardiac rehabilitation stratified according to National Heart, Lung, and Blood Institute criteria.

PURPOSE: Obesity is a major health problem and must be evaluated and treated in cardiac rehabilitation patients. The purpose of this study was to identify the scope of this problem in an urban-based cardiac rehabilitation program by evaluating the prevalence of obesity, and comparing the clinical and risk factor profiles and outcomes of patients stratified according to National Heart, Lung, and Blood Institute (NHLBI) weight classifications. METHODS: Four hundred forty-nine consecutive cardiac rehabilitation patients, aged 57 +/- 11 years, were stratified according to the NHLBI criteria as: normal (body mass index [BMI] 18-24.9 kg/m2), overweight (BMI 25-29.9 kg/m2), class I/II obese (BMI 30-39.9 kg/m2), and class III morbidly obese (BMI > or = 40 kg/m2). Baseline cardiac risk factors and dietary habits were identified, and both pre- and postexercise training measurements of exercise tolerance, weight, and lipid profile were obtained. RESULTS: Overweight and obesity (BMI > or = 25 kg/m2) were present in 88% of patients. Compared to normal weight patients, obese patients were younger and had a greater adverse risk profile (higher prevalence of diabetes and hypertension, larger waist circumference, lower exercise capacity, lower high-density lipoprotein cholesterol level) at entry. After 10 weeks, all groups had a significant increase in exercise capacity, and on average obese patients in each category lost weight (Class I/II--4 lbs and Class III--12 lbs). Dropout rates were similar among the groups. CONCLUSION: Overweight and obesity are highly prevalent in cardiac rehabilitation. Overweight and obese patients had a greater adverse cardiovascular risk profile, including a lower exercise capacity in the latter. Thus, targeted interventions toward weight management in contemporary cardiac rehabilitation programs are important. Although short-term outcomes appear promising, greater efforts to improve these outcomes and to support long-term management are needed.