Amino acid composition of ribosomes from Escherichia coli

Scaling of nuclear numbers and their spatial arrangement in skeletal muscle cell size regulation

Many cells display considerable functional plasticity and depend on the regulation of numerous organelles and macromolecules for their maintenance. In large cells, organelles also need to be carefully distributed to supply the cell with essential resources and regulate intracellular activities. Having multiple copies of the largest eukaryotic organelle, the nucleus, epitomizes the importance of scaling gene products to large cytoplasmic volumes in skeletal muscle fibers. Scaling of intracellular constituents within mammalian muscle fibers is, however, poorly understood, but according to the myonuclear domain hypothesis, a single nucleus supports a finite amount of cytoplasm and is thus postulated to act autonomously, causing the nuclear number to be commensurate with fiber volume. In addition, the orderly peripheral distribution of myonuclei is a hallmark of normal cell physiology, as nuclear mispositioning is associated with impaired muscle function. Because underlying structures of complex cell behaviors are commonly formalized by scaling laws and thus emphasize emerging principles of size regulation, the work presented herein offers more of a unified conceptual platform based on principles from physics, chemistry, geometry, and biology to explore cell size-dependent correlations of the largest mammalian cell by means of scaling.

Dynamics and growth rate implications of ribosomes and mRNAs interaction in E. coli

Understanding how cells grow and adapt under various nutrient conditions is pivotal in the study of biological stoichiometry. Recent studies provide empirical evidence that cells use multiple strategies to maintain an optimal protein production rate under different nutrient conditions. Mathematical models can provide a solid theoretical foundation that can explain experimental observations and generate testable hypotheses to further our understanding of the growth process. In this study, we generalize a modeling framework that centers on the translation process and study its asymptotic behaviors to validate algebraic manipulations involving the steady states. Using experimental results on the growth of E. coli under C-, N-, and P-limited environments, we simulate the expected quantitative measurements to show the feasibility of using the model to explain empirical evidence. Our results support the findings that cells employ multiple strategies to maintain a similar protein production rate across different nutrient limitations. Moreover, we find that the previous study underestimates the significance of certain biological rates, such as the binding rate of ribosomes to mRNA and the transition rate between different ribosomal stages. Furthermore, our simulation shows that the strategies used by cells under C- and P-limitations result in a faster overall growth dynamics than under N-limitation. In conclusion, the general modeling framework provides a valuable platform to study cell growth under different nutrient supply conditions, which also allows straightforward extensions to the coupling of transcription, translation, and energetics to deepen our understanding of the growth process.

Improving the Robustness of Engineered Bacteria to Nutrient Stress Using Programmed Proteolysis

The use of short peptide tags in synthetic genetic circuits allows for the tuning of gene expression dynamics and release of amino acid resources through targeted protein degradation. Here, we use elements of the Escherichia coli and Mesoplasma florum transfer-mRNA (tmRNA) ribosome rescue systems to compare endogenous and foreign proteolysis systems in E. coli. We characterize the performance and burden of each and show that, while both greatly shorten the half-life of a tagged protein, the endogenous system is approximately 10 times more efficient. On the basis of these results we then demonstrate using mathematical modeling and experiments how proteolysis can improve cellular robustness through targeted degradation of a reporter protein in auxotrophic strains, providing a limited secondary source of essential amino acids that help partially restore growth when nutrients become scarce. These findings provide avenues for controlling the functional lifetime of engineered cells once deployed and increasing their tolerance to fluctuations in nutrient availability.

Alternative type of Ames test allows for dynamic mutagenicity detection by online monitoring of respiration activity

The Ames test is the most commonly used mutagenicity test worldwide. It is based on a microbial system that uses histidine auxotrophic Salmonella typhimurium strains. Due to either spontaneous mutations or mutations induced by a mutagenic compound, the cells can regain their ability to grow without histidine supplementation. The degree of mutagenicity of a sample correlates with the number of cells that are able to grow in media that lack histidine. All test variants published up to now are endpoint determinations providing no information about cell growth and respiration activity during the cultivation time. This study aimed to develop an alternative type of Ames test by characterizing the respiration activity of Salmonella typhimurium over time for dynamic mutagenicity detection. It focuses on elucidating the mechanisms underlying this novel test system, and serves as a general proof of principle. Respiration activity (oxygen transfer and uptake rate) and biomass growth of Salmonella typhimurium TA 100 and TA 98 were mechanistically modeled to understand and predict the behavior of the bacteria during the Ames test. The results simulated by the model were experimentally validated by the online monitoring of respiration activity over cultivation time using a Respiration Activity MOnitoring System (RAMOS). The simulated prediction was observed to fit well to the experimental data. When a mutagenic compound was added, its mutagenicity could be detected online due to the elevated cell number and respiration of histidine prototrophic cells. Laborious manual evaluation of mutagenicity after cultivation is not necessary. Mutagenicity evaluation with the presented alternative Ames RAMOS test fitted well to results from an Ames fluctuation test. In the future, a miniaturized RAMOS device for microtiter plates should allow for a high-throughput Ames RAMOS test.

An improved method for the heterologous production of soluble human ribosomal proteins in Escherichia coli

Human ribosomal proteins play important structural and functional roles in the ribosome and in protein synthesis. An efficient method to recombinantly produce and purify these proteins would enable their full characterisation. However, the production of human ribosomal proteins can be challenging. The only published method about the recombinant production of human ribosomal proteins involved the recovery of proteins from inclusion bodies, a process that is tedious and may lead to significant loss of yield. Herein, we explored the use of different Escherichia coli competent cells and fusion protein tags for the recombinant production of human ribosomal proteins. We found that, by using thioredoxin as a fusion protein, soluble ribosomal protein could be obtained directly from cell lysates, thus leading to an improved method to recombinantly produce these proteins.

Protein production in Escherichia coli is guided by the trade-off between intracellular substrate availability and energy cost

Background

In vivo protein formation is a crucial part of cellular life. The process needs to adapt to growth conditions and is exploited for the production of technical and pharmaceutical proteins in microbes such as Escherichia coli. Accordingly, the elucidation of basic regulatory mechanisms controlling the in vivo translation machinery is of primary interest, not only to improve heterologous protein production but also to elucidate fundamental regulation regimens of cellular growth.

Results

The current modeling analysis elucidates the impact of diffusion for the stochastic supply of crucial substrates such as the elongation factor EFTu, and tRNA species, all regarded as key elements for ensuring optimum transcriptional elongation. Together with the consideration of cellular ribosome numbers, their impact on the proper functioning of the translation machinery was investigated under different in vivo and in vitro conditions and utilizing the formation of non-native GFP and native EFTu as target proteins. The results show that translational elongation was diffusion limited. However, this effect was much more pronounced for the translation of non-native proteins than for the formation of codon-optimized native proteins.

Conclusions

Cellular ATP requirements constrain the options of improving protein production. In the case of non-native protein sequences, an optimized tRNA supply may be the most economical solution, as cells necessarily have to invest in ATP-costly ribosome synthesis to boost translation and increase growth rates.

Large-scale analysis of post-translational modifications in E. coli under glucose-limiting conditions

Background

Post-translational modification (PTM) of proteins is central to many cellular processes across all domains of life, but despite decades of study and a wealth of genomic and proteomic data the biological function of many PTMs remains unknown. This is especially true for prokaryotic PTM systems, many of which have only recently been recognized and studied in depth. It is increasingly apparent that a deep sampling of abundance across a wide range of environmental stresses, growth conditions, and PTM types, rather than simply cataloging targets for a handful of modifications, is critical to understanding the complex pathways that govern PTM deposition and downstream effects.

Results

We utilized a deeply-sampled dataset of MS/MS proteomic analysis covering 9 timepoints spanning the Escherichia coli growth cycle and an unbiased PTM search strategy to construct a temporal map of abundance for all PTMs within a 400 Da window of mass shifts. Using this map, we are able to identify novel targets and temporal patterns for N-terminal N α acetylation, C-terminal glutamylation, and asparagine deamidation. Furthermore, we identify a possible relationship between N-terminal N α acetylation and regulation of protein degradation in stationary phase, pointing to a previously unrecognized biological function for this poorly-understood PTM.

Conclusions

Unbiased detection of PTM in MS/MS proteomics data facilitates the discovery of novel modification types and previously unobserved dynamic changes in modification across growth timepoints.

Electronic supplementary material

The online version of this article (doi:10.1186/s12864-017-3676-8) contains supplementary material, which is available to authorized users.

[FeFe]-hydrogenase abundance and diversity along a vertical redox gradient in Great Salt Lake, USA

The use of [FeFe]-hydrogenase enzymes for the biotechnological production of H₂ or other reduced products has been limited by their sensitivity to oxygen (O₂). Here, we apply a PCR-directed approach to determine the distribution, abundance, and diversity of hydA gene fragments along co-varying salinity and O₂ gradients in a vertical water column of Great Salt Lake (GSL), UT. The distribution of hydA was constrained to water column transects that had high salt and relatively low O₂ concentrations. Recovered HydA deduced amino acid sequences were enriched in hydrophilic amino acids relative to HydA from less saline environments. In addition, they harbored interesting variations in the amino acid environment of the complex H-cluster metalloenzyme active site and putative gas transfer channels that may be important for both H₂ transfer and O₂ susceptibility. A phylogenetic framework was created to infer the accessory cluster composition and quaternary structure of recovered HydA protein sequences based on phylogenetic relationships and the gene contexts of known complete HydA sequences. Numerous recovered HydA are predicted to harbor multiple N- and C-terminal accessory iron-sulfur cluster binding domains and are likely to exist as multisubunit complexes. This study indicates an important role for [FeFe]-hydrogenases in the functioning of the GSL ecosystem and provides new target genes and variants for use in identifying O₂ tolerant enzymes for biotechnological applications.

Properties of ribosomal proteins from two mammalian sources

1. Ribosomal protein fractions from rabbit reticulocytes and rat liver were prepared by extracting ribosomes with 0.2n-hydrochloric acid or guanidinium chloride and subsequent dialysis. 2. Treatment for 2.5hr. or less with 0.2n-hydrochloric acid dissolved 46-54% of the proteins, which were richer in arginine and lysine and in N-terminal alanine groups and poorer in aspartic acid and glutamic acid and in N-terminal glycine groups than the acid-insoluble proteins. 3. Protein fractions prepared from the guanidinium chloride extract of ribosomes from rat liver were usually more basic than those from rabbit reticulocytes. 4. The ratios lysine: arginine of fractions in the guanidinium chloride extracts were appreciably higher for proteins from rabbit reticulocytes than from rat liver. 5. The concentration of urea and the pH of the gel affected the rate of migration and number of bands in starch-gel electrophoresis.

Purification, primary structure, and homology relationships of a chloroplast ribosomal protein

A chloroplast ribosomal protein that showed immunological homology to Escherichia coli ribosomal protein L12 was purified from spinach (Spinacia oleracea) leaves and its primary structure was determined by manual micro Edman degradation. The protein is composed of 130 amino acid residues and has M(r) 13,576. It shows structural features characteristic of the L12 proteins of eubacterial 70S ribosomes (e.g., identical amino acid residues in about 50% of the sequence) but no apparent homology to the L12-type proteins of eukaryotic cytoplasmic 80S ribosomes. The homology to eubacterial proteins is highest in the COOH-terminal region (70%) and low in the NH(2)-terminal region (<20%).

The relationship of the "sphere chromatophile" to the fate of displaced histones following histone transition in rat spermiogenesis

Cytochemical, radioautographic, and microspectrophotometric studies bearing on the relationship of histone transition to the origin and development of the protein and RNA components of the "sphère chromatophile" in the developing spermatogenic cells of the albino rat are presented. These studies show that the sphère chromatophile has many features in common with somatic nuclei: it contains histonelike basic proteins rich in lysine, with lesser amounts of arginine. No evidence is found for the presence of a protamine in this granule. The sphère chromatophile is rich in RNA, but contains no DNA. The failure of a positive reaction with basic protein stains, unless the RNA is first removed, indicates either a chemical bonding or a very close association between the RNA and basic protein. The basic protein and RNA components of the sphère chromatophile appear to have different origins in the cell. A sequence of stages in the development of the lysine-rich basic protein component of this structure commences with the appearance of tiny grains in those spermatid nuclei which are beginning to replace lysine-rich histones with arginine-rich histones. Subsequently, similar-staining cytoplasmic grains appear, which coalesce to form the sphère chromatophile in the cytoplasm. Labeling studies show that the basic protein component is synthesized at about the time of the last premeiotic DNA (and histone) synthesis. The results of the microspectrophotometric measurements support the idea that the basic protein lost from the spermatid nucleus is the source of the basic protein in the sphère chromatophile.

[FeFe] hydrogenase genetic diversity provides insight into molecular adaptation in a saline microbial mat community

Degenerate primers for the [FeFe] hydrogenase (hydA) were developed and used in PCRs to examine hydA in microbial mats that inhabit saltern evaporative ponds in Guerrero Negro (GN), Mexico. A diversity of deduced HydA was discovered that revealed unique variants, which may reflect adaptation to the environmental conditions present in GN.

A three-dimensional model of domain III of the Escherichia coli small ribosomal subunit

A three-dimensional model of domain III (nucleotides 920 to 1395) of the 30S ribosomal subunit of E. coli is proposed. The data used as a guide in folding the secondary structure of the RNA into a tertiary structure are four long range RNA-RNA interactions proposed by us on the basis of experiments performed in this laboratory plus two sets of data from other laboratories: protein-RNA cross-linking sites for proteins S1, S3, S7, S10 and S12, and the interprotein distances determined by neutron scattering. The model is consistent with nearly all of the published experimental findings on the structure of domain III.

Characterization of the phosphoproteins of Escherichia coli cells by electrophoretic analysis

The phosphorylated proteins of Escherichia coli, radioactively labeled with [32P]orthophosphate, have been analyzed by the O'Farrell gel technique and autoradiography. The effects of various culture conditions on the pattern of protein phosphorylation have been studied, including growth on different carbon sources in either exponential or stationary phase, treatment of cells with ethanol, heat shock and amino acid starvation. A total number of 128 different phosphoproteins, labeled to a varying extent, have been detected and each of them has been characterized by both its molecular mass and isoelectric point. These proteins are located mainly in the cytosolic fraction of cells, none of them being present within either ribosomes or nucleoids, and only three being associated with membranes. Analysis of their phosphoamino acid content has shown that they are phosphorylated mostly at serine residues and, less frequently, at threonine and tyrosine residues.

Growth rate-dependent regulation of RNA polymerase synthesis in Escherichia coli

The rate of synthesis of the beta and beta' subunits of RNA polymerase relative to the rate of synthesis of total protein was found to remain constant with increasing steady state growth rate. This is in contrast to the relative synthesis rates of ribosomal proteins which are known to increase with growth rate. Yet the ratio of the rate of transcription of the ribosomal protein (rplJL) and RNA polymerase (rpoBC) domains of the rplKAJLrpoBC gene cluster was found to be invariant. Fusions to lacZ were used to relate the rate of transcription of the rplKAJL genes to the rate of synthesis of total protein. No change was seen at growth rates above 0.8 doublings per hour. This indicates that the growth rate-dependent expression of these ribosomal proteins is regulated at the post-transcriptional level. However because both the relative rate of transcription of rpoBC and rate of synthesis of beta and beta' were found to remain invariant over this growth range it suggests the expression of these RNA polymerase subunits is regulated at the transcriptional level.

DNA sequence of the Escherichia coli gene, gnd, for 6-phosphogluconate dehydrogenase

Expression of gnd of Escherichia coli, which encodes 6-phosphogluconate dehydrogenase, an enzyme of the hexose monophosphate shunt, is subject to growth rate-dependent regulation and is gene dosage-dependent: the level of the enzyme increases in direct proportion to the cellular growth rate at both low and high gene copy numbers. We have determined the nucleotide sequence of gnd and flanking control regions, the 5'-end of in vivo gnd mRNA, and the start codon of the structural gene. Analysis of the sequence indicated that: (i) the gnd promoter is typical of other E. coli promoters and the structural gene is followed by a rho-independent transcription termination signal; (ii) the 56-nucleotide leader of gnd mRNA does not contain a rho-independent transcription termination signal, so growth rate-dependent regulation of 6-phosphogluconate dehydrogenase level is not carried out by an attenuation mechanism analogous to the one that controls expression of the E. coli ampC gene; (iii) the codon composition of the structural gene resembles that of other highly expressed E. coli genes and thus is not responsible for the regulation either; (iv) the structural gene is preceded at an optimal distance by a strong Shine-Dalgarno (SD) sequence, AGGAG ; (v) the leader region of the mRNA contains regions of dyad symmetry that have the potential to sequester the SD sequence and the start codon. This latter feature of the gene suggests that growth rate-dependent regulation may involve regulation of translation initiation frequency.

Functional aspects of bacterial polysomes during limited protein synthesis

The effects of amino acid starvation on the metabolic behavior of polysomes and the size distribution of proteins have been studied in an otherwise isogenic pair of stringent (relA+) and relaxed (relA) strains of Escherichia coli. The stability of polysomes has been analyzed by using two different approaches. First, the process of their degradation has been followed after treating the cells with rifampicin, an inhibitor of the synthesis of all classes of RNA including messenger RNA. Secondly, the process of their assembly has been studied after their previous conversion to monosomes, as induced by glucose deprivation of cells. It is shown that, in either type of bacterial strain, polysomes are continually broken down and re-synthesized during amino acid starvation. However, such polysome turnover is then less rapid than in normally growing bacteria and, moreover, it seems amino acid specific since it occurs at a lower rate during arginine starvation than during histidine starvation, namely, in the relaxed strain. The molecular weight distribution of proteins has been determined after labeling of cells with radioactive methionine and separation of polypeptides by one-dimensional polyacrylamide gel electrophoresis. The average size of polypeptides synthesized in the stringent strain during starvation is quite similar to that measured during normal growth. By contrast, a significant shift towards smaller molecules is observed in the relaxed strain deprived of an essential amino acid. Here again, this reduction of the size of polypeptides seems amino acid specific since it is especially marked during arginine starvation. These results are discussed in terms of ribosomes translocation and premature peptide chain termination in connection with the accuracy of the translational process.

Properties and proteolysis of ferric enterobactin outer membrane receptor in Escherichia coli K12

A protein with a relative subunit molecular weight of 81000 (81K) has been isolated in virtually pure form from the outer membrane of low iron grown cells of Escherichia coli K12. The 81K protein, which is part of the receptor complex for translocation of the siderophore ferric enterobactin, displays activity in vitro for binding both ferric enterobactin and colicin B. The dissociation constant for the 81K-ferric enterobactin compound at 4 degrees C in 2% Triton-0.1 M Tris, pH 7, was determined to be 10 nM. The N-terminal amino acid was identified as phenylalanine, and the amino acid composition was shown to be similar to that published for the ferric aerobactin-cloacin receptor of Enterobacter cloacae. A plasmid-bearing strain of E. coli was employed to confirm that degradation of 81K to a slightly smaller, inactive form (81K) is performed by a second outer membrane component, protein a. The endoproteolytic action of protein a was verified by the finding of alanine as the N-terminal residue of 81K. A survey of enteric species suggests that the 81K-protein a interaction is confined to the K12 strain of E. coli.

Structural stability of halophilic proteins

An examination of halobacterial amino acids exchanges as they appear in the known Spirulina platensis [2Fe-2S] ferredoxin tertiary structure indicated that most of the additional acidic residues of the halophiles occurred on the external surface of the alga structure; however, further negative changes were not placed in the ferredoxin active site region. A statistical investigation of the amino acid compositions of seven halophile and nonhalophile protein counterparts indicated that the bulkiness of amino acids used by halophiles is considerably reduced and that the overall hydrophobicity of halophilic and non halophilic molecules was essentially the same. It is suggested that the principal mode of structural stabilization for halophilic proteins is effective competition with the cytoplasmic salt for water through utilization of many external carboxyl groups of glutamic and aspartic acids. A reduction is residue bulkiness would prevent inactivation in the presence of the high molarity, antichaotropic KCl. Halophilic functionality is preserved through avoidance of additional negative charge at the active site surface.

Crowding depression of UV-mutagenesis in E. coli

Strains of E. coli B/r were exposed to UV radiation and assayed for reversion mutation, using a standard selection medium. If more irradiated bacteria were assayed per petri dish, a proportional increase in the number of indicated reversion mutants was found only up to a limiting plating density. Beyond a density of about 10(8) viable bacteria per petri dish, the number of indicated revertants per viable bacteria assayed (the mutation frequency) decreased as the plating density was increased. The crowding depression of mutagenesis was more severe for de novo and converted suppressor mutations, the mutation frequency being reduced 100-fold at a plating density of about 6 x 10(9) viable bacteria per plate. The effect on backmutation was 10 times less. Crowding depression of mutagenesis occurred in excision-proficient and -deficient strains, with identical effects in the 2 strains on de novo and converted suppressor mutation, but different effects on backmutations. There were no accompanying effects on viability. Irreversible loss of potential mutants during crowded growth was indicated in wash-off experiments. The kinetics suggested a half-life of approximately 1 h. Kinetics for accumulation by the bacteria of the limiting metabolite (tyrosine) on the assay plate indicated a short period of time for protein synthesis, but direct examination of the proteins synthesized during early growth on a crowded plate demonstrated successful induction of recA protein. The results suggested a possible disruption in the rec/lex respondency system somewhere between induction of recA protein and the various end points, including mutational repair, in cells plated close to one another.

Synthesis and function of ribonucleic acid polymerase and ribosomes in Escherichia coli B/r after a nutritional shift-up

The syntheses of stable ribosomal ribonucleic acid (RNA) and transfer RNA in bacteria depend on the concentration and activity of RNA polymerase and on the fraction of active RNA polymerase synthesizing stable RNA. These parameters were measured in Escherichia coli B/r after a nutritional shift-up from succinate-minimal to glucose-amino acids medium and were found to change in complex patterns during a 1- to 2-h period after the shift-up before reaching a final steady-state level characteristic for the postshift growth medium. The combined effect of these changes was an immediate, one-step increase in the exponential rate of stable RNA synthesis and thus of ribosome synthesis. This suggests that the distribution of transcribing RNA polymerase over ribosomal and nonribosomal genes and the polymerase activity are continuously adjusted during postshift growth to some growth-limiting reaction whose rate increases exponentially. It is proposed that this reaction is the production of amino-acylated transfer RNA and that is exponentially increasing rate results in part from a gradually increasing concentration of aminoacyl transfer RNA synthetases after a shift-up. This idea was tested and is supported by a computer simulation of a nutritional shift-up.

Synthesis and activity of ribonucleic acid polymerase in Escherichia coli

The amounts of ribonucleic acid (RNA) polymerase (beta' subunits) and ribosomes (RNA), and the fraction of RNA polymerase actively engaged in transcription, were measured in Escherichia coli B/r as a function of growth rate. By an improved method of quantitating protein bands on electrophoresis gels, the systematic error and reproducibility of the RNA polymerase determination were estimated to be less than 15 and 6%, respectively. For a threefold increase in growth rate, the fractional synthesis of polymerase (relative to protein) increased 1.5-fold, whereas the fractional synthesis of ribosomal protein increased 2.2-fold. The decrease in the amount of RNA polymerase per ribosome with increasing growth rate is interpreted as an expression of the control of the transcriptional read-through from the genes for ribosomal protein, rplJ,L, to the adjacent genes for RNA polymerase subunits, rpoB,C. The number of active RNA polymerase molecules was determined from the synthesis rates of stable and messenger RNA and the known RNA chain growth rates. Comparison of active and total RNA polymerase indicates that the fraction of active enzyme increases from 20 to 30% in the range of growth rates between 0.6 and 2.0 doublings per hour. Possible causes for the inactive enzyme are discussed.

Comparison of amino acid compositions of mitochondrial and cytoplasmic ribosomal proteins of Saccharomyces cerevisiae

The amino-acid compositions of the mitochondrial ribosomal subunits of Saccharomyces cerevisiae have been determined and compared to those of cytoplasmic ribosomal subunits. For the large subunits, the mitochondrial and cytoplasmic ribosomes showed major differences in the proportions of arginine, alanine and methionine. For the small subunits, arginine, aspartic acid, alanine, valine and methionine showed marked differences. We have compared these amino-acid compositions with those already published of bacterial and eukaryotic ribosomes by a statistical method of data analysis. It appeared clearly that the yeast mitoribosomes are more distant from bacterial ribosomes than from eukaryotic cytoribosomes.

The relationship between guanosine tetraphosphate, polysomes and RNA synthesis in amino acid starved Escherichia coli

A relA+ strain of E. coli with four amino acid requirements was starved separately for each amino acid, after which the levels of polysomes, guanosine-5'-diphosphate-3'-diphosphate and the residual net synthesis of RNA were determined. The polysome level and guanosine-5'-diphosphate-3'-diphosphate production were coordinately affected by starvation for the different amino acids, whereas no correlation was found between these two parameters and residual RNA synthesis. The main conclusion stemming from these results is that guanosine-5'-diphosphate-3'-diphosphate cannot act as the sole effector molecule in stringent control of RNA synthesis.

On the distribution and packing of RNA and protein ribosomes

From the analysis of the measured radii of gyration of the RNA (Rg = 6.6 +/- 0.3 nm) and protein (Rg = 10.2 +/- 0.5 nm) components of the 50-S subparticle of Escherichia coli ribosomes it is concluded that proteins containing a large amount of hydrodynamically bound water are located on the periphery of the tightly packed RNA. We found that the common features of the measured X-ray scattering curves of the E. coli 70-S ribosome, its 30-S and 50-S subparticles and wheat 80-S ribosomes in the region of scattering angles corresponding to scattering vectors mu from 1 to 5 nm-1 reflect features of the RNA compact packing. A hypothesis is proposed that the compact packing of RNA helices in the range of Bragg distances of 4.5--2.0 nm is a general structural feature of all ribosomal particles.

Phenotypic modifications in amino acid profiles of cell residues of Candida utilis and Enterobacter aerogenes

Glucose-limited chemostat cultures of Candida utilis were cultivated at various pH levels (3.0-7.5), temperatures (15-37.5 degrees C), dilution rates (0.006-0.42 hr-1), and with one of two nitrogen sources (NH+4 or NO-3). Enterobacter aerogenes was also cultivated in the chemostat under nitrogen and phosphorus limitations. The amino acid profile of total cell protein is expressed as the content of each amino acid relative to the sum of all amino acids recovered ater acid hydrolysis. Cell residues obtained after hot trichloracetic acid extraction display small variations in amino acid profile. Some of these variations correlate with the growth rate at satisfactory levels of statistical significance. In C. utilis, the correlations cover increased levels of lysine, arginine, and leucine and decreased levels of serine and glutamic acid with increased "reduced dilution rate" (D/Dc). In E. aerogenes, increased levels of lysine and arginine and a decreased level of glutamic acid correlate with increased dilution rate. The directions of most of these correlations and the extents of those pertaining to lysine and arginine are consistent with the change predicted to occur simultaneously in the relative level of the ribosomal protein group.

Establishment of exponential growth after a nutritional shift-up in Escherichia coli B/r: accumulation of deoxyribonucleic acid, ribonucleic acid, and protein

The accumulation of deoxyribonucleic acid (DNA), ribonucleic acid (RNA), and protein was followed in cultures of Escherichia coli B/r during exponential growth in different media and for 2 h after a nutritional shift-up from succinate minimal medium (growth rate [mu1] = 0.67 doublings per h) to glucose plus amino acids medium (mu2 = 3.14 doublings per h). During postshift growth of the culture, the amounts of RNA (R), DNA (D), and protein (P) increased such that the ratios of the increments (delta R/delta P; delta D/delta P) were constants (k1, k2). This implies that the rates of accumulation of nuclei1:k2:1. These constants change from their preshift value to their final postshift value (i.e., k1 and k2) within a few minutes after the shift. k1 is a function of the activity of ribosomes, whereas k2 is related to the initiation of rounds of DNA replication. These parameters and the observed change in the doubling time of RNA (= mu2/mu1) were used to derive kinetic equations that describe the accumulation of DNA, RNA, protein, and cell mass during the 2- to 3-h transition period after a shift-up. The calculated kinetics agree closely with the observed kinetics.

Polypeptide-chain-elongation rate in Escherichia coli B/r as a function of growth rate

By evaluating the kinetics of radioactive labelling of nascent and finished polypeptides, the peptide-chain elongation rate for Escherichia coli B/r at three different growth rates (mu) was determined to be 17 amino acids/s for the fast-growing cells (mu equals 1.3 and 2.0 doublings/h) and 12 amino acids/s for slow-growing cells (mu equals 0.67 doublings/h). The results agree with the growth-rate-dependence of the rate of peptide-chain elongation found for the translation of newly induced beta-galactosidase messenger in this strain and under these conditions of growth [Dalbow & Young (1975) Biochem. J. 150, 13-20]. Together with the previously observed ribosome efficiency at these growth rates [Dennis & Bremer (1974) J. Mol. Biol. 84, 407-422] the results indicate that the fraction of ribosomes engaged in protein synthesis is about 0.8 at all three growth rates.

The properties of ribosomal proteins from a moderate halophile

The ribosomes from the extreme halophile Halobacterium cutirubrum are unusual in that their ribosomal proteins are acidic rather than basic as is the case with almost all bacterial ribosomes (Bayley, S.T. (1966) J. Mol. Biol. 15, 420-427). To determine whether the ribosomes of a moderate halophile show similar properties the ribosomal proteins from an unidentified moderate halophile, which grows over a wide range of NaCl concentrations (0.04-4.3 M), were compared to those of Escherichia coli and H. cutirubrum. The proteins are slightly more acidic than those of E. coli but much less acidic than those from the extreme halophile as judged by their mobility on polyacrylamide gels and their amino acid composition. The electrophoretic profile on polyacrylamide gels of the ribosomal proteins from the moderate halophile is similar whether the cells are grown in 0.5 M or 4.25 M NaCl.

Fluorescent labelling of Escherichia coli ribosomal sulfhydryl groups

The reactivity of the sulfhydryl groups of Escherichia coli ribosome has been investigated using a fluorescent label. Under denaturing conditions, all the --SH groups can be titrated. In the native form of the ribosome, six and less than one labels can be respectively conjugated to the 30-S and 50-S subparticles without loss of activity for poly(U)-dependent polyphenylalanine synthesis. The most reactive thiol groups belong to proteins S1, S12, S18, S21. The binding of mRNA plus tRNA to the 70-S ribosomes affects the spectroscopic properties of the labels showing that conformational changes are induced by these interactions. Furthermore, the treatment of these complexes by the labelling agent demonstrates that the --SH group belonging to protein S1 is partially protected whereas other thiol groups located on the 50-S subparticle become reactive.

Solution of ribosomal proteins under mild conditions

Ribosomal proteins from two eucaryotic species, prepared by either the guanidine . HCl or LiCl . urea method and subsequently dissolved in 8 M urea were found to be largely retained in solution after removal of the urea by dialysis against a solution of low ionic strength (0.05 M Tris . HCl, pH 7.6, 0.025 M KCl, 0.005 M magnesium acetate) and centrifugation at 100,000 times g. The protein composition of this preparation was virtually identical to that of the original urea-containing solution as determined by two-dimensional polyacrylamide gel electrophoresis. Thus, there exists a very simple method for obtaining the bulk of the ribosomal proteins in solution under conditions where ribosomes themselves are stable.

Studies of mutations in T4 control genes 33 and 55

Available mutations in transcriptional control genes 33 and 55 of coliphage T4 have been examined. By complementation analysis and map position, 15 mutants (13 in T4D, 2 in T4B) have been shown to lie in gene 33 and 6 (5 in T4D, 1 in T4B) in gene 55. According to patterns of suppression and recombination, these mutants define three distinct amber sites in gene 33 and also three distinct amber sites in gene 55. All of these mutations are true amber mutations, in apparent contrast to some traditional T4 "amber" mutants which grow in su+ E. coli CR63 but not in su minus E. coli B because of a strain difference other than the su+ determinant. Evidence is presented that, contrary to previous suggestions (BOLLE et al. 1968; pulitzer and geiduschek 1970), the gene 33 product is absolutely essential for T4 development.