Differences in codon bias cannot explain differences in translational power among microbes

Background  

Translational power is the cellular rate of protein synthesis normalized to the biomass invested in translational machinery. Published data suggest a previously unrecognized pattern: translational power is higher among rapidly growing microbes, and lower among slowly growing microbes. One factor known to affect translational power is biased use of synonymous codons. The correlation within an organism between expression level and degree of codon bias among genes of Escherichia coli and other bacteria capable of rapid growth is commonly attributed to selection for high translational power. Conversely, the absence of such a correlation in some slowly growing microbes has been interpreted as the absence of selection for translational power. Because codon bias caused by translational selection varies between rapidly growing and slowly growing microbes, we investigated whether observed differences in translational power among microbes could be explained entirely by differences in the degree of codon bias. Although the data are not available to estimate the effect of codon bias in other species, we developed an empirically-based mathematical model to compare the translation rate of E. coli to the translation rate of a hypothetical strain which differs from E. coli only by lacking codon bias.     

Evolutionary principles and the regulation of engineered bacteria

The introduction of engineered bacteria to the environment is being overregulated, on the basis of several assumptions: (i) the danger from deliberate introduction on a large scale is much greater than that from accidental release; (ii) the more distant the source of the DNA the greater the risk; (iii) novel organisms are likely to cause unexpected ecological damage, like that seen with native organisms transplanted to a novel location; (iv) even if the probability of harm is very small, great care must be taken because the harm might be large; (v) products of recombinant DNA must be treated differently from products of classical genetic manipulation; and (vi) our unlimited power to manipulate DNA implies an unlimited power to refashion organisms. Evolutionary principles contradict all these assumptions. Moreover, our increased power of genetic manipulation must be recognized as an expansion of the biotechnology of domestication; and unlike the physical technologies, the long history of domestication has not adventitiously created harmful by-products. I propose that in dealing with such novel and unpredictable developments it would be better to respond with speed and resilience to problems as they arise, rather than to hamper advances by clumsy regulations based on unsubstantiated guesses.     

Characterization of ten extreme disturbance events in the context of social and ecological systems

An extreme disturbance event is one in which any of its component disturbance forces and their interactions with affected systems have dimensions and responses that exceed the known range of variation expected of those parameters. If the exposed system does not respond or exhibits a low level response to an event, the event was not extreme to the exposed system, regardless of the dimensions of its disturbance forces. Extreme disturbance events are complex and require disaggregation to improve understanding of their effects. The areas affected by extreme events and the duration of the events are related but involve many orders of magnitude in terms of area affected and duration. One way to compare events is through a common and objective unit of measure such as energy. A comparison of ten extreme events in terms of their power and total energy delivered per unit area revealed a broad range of values among them. The power of events ranged 8 orders of magnitude and the total load per unit area ranged 14 orders of magnitude. Each event had different points of interaction with exposed ecosystems. When exposed to the same extreme event, the response of social systems is different from the response of the ecological systems. Also, social systems recovered quicker to a category 3 hurricane than did ecological systems. Both social and ecological systems have the capacity to evolve, adapt, innovate, and develop novelty in response to the selective pressure of extreme events.     

Comparative RNomics and modomics in Mollicutes: prediction of gene function and evolutionary implications

Stable RNAs are central to protein synthesis. Ribosomal RNAs make the core of the ribosome and provide the scaffold for accurate translation of mRNAs by a set of tRNA molecules each carrying an activated amino acid. To fulfill these important cellular functions, both rRNA and tRNA molecules require more than the four canonical bases and have recruited enzymes that introduce numerous modifications on nucleosides. Mollicutes are parasitic unicellular bacteria that originated from gram-positive bacteria by considerably reducing their genome, reaching a minimal size of 480 kb in Mycoplasma genitalium. By analyzing the complete set of tRNA isoacceptors (tRNomics) and predicting the tRNA/rRNA modification enzymes (Modomics) among all sequenced Mollicutes (15 in all), our goal is to predict the minimal set of RNA modifications needed to sustain accurate translation of the cell's genetic information. Building on the known phylogenetic relationship of the 15 Mollicutes analyzed, we demonstrate that the solutions to reducing the RNA component of the translation apparatus vary from one Mollicute to the other and often rely on co-evolution of specific tRNA isoacceptors and RNA modification enzymes. This analysis also reveals that only a few modification enzymes acting on nucleotides of the anticodon loop in tRNA (the wobble position 34 as well as in position 37, 3'-adjacent to anticodon) and of the peptidyltransferase center of 23S rRNA appear to be absolutely essential and resistant to gene loss during the evolutionary process of genome reduction.     

Transfer RNAs Mediate the Rapid Adaptation of Escherichia coli to Oxidative Stress

Translational systems can respond promptly to sudden environmental changes to provide rapid adaptations to environmental stress. Unlike the well-studied translational responses to oxidative stress in eukaryotic systems, little is known regarding how prokaryotes respond rapidly to oxidative stress in terms of translation. In this study, we measured protein synthesis from the entire Escherichia coli proteome and found that protein synthesis was severely slowed down under oxidative stress. With unchanged translation initiation, this slowdown was caused by decreased translation elongation speed. We further confirmed by tRNA sequencing and qRT-PCR that this deceleration was caused by a global, enzymatic downregulation of almost all tRNA species shortly after exposure to oxidative agents. Elevation in tRNA levels accelerated translation and protected E. coli against oxidative stress caused by hydrogen peroxide and the antibiotic ciprofloxacin. Our results showed that the global regulation of tRNAs mediates the rapid adjustment of the E. coli translation system for prompt adaptation to oxidative stress.     

Gene expression regulation at the translational level: contribution of marine organisms

Gene expression regulation is crucial for organism survival. Each step has to be regulated, from the gene to the protein. mRNA can be stored in the cell without any direct translation. This process is used by the cell to control protein synthesis rapidly at the right place, at the right time. Protein synthesis costs a lot of energy for the cell, so that a precise control of this process is required. Translation initiation represents an important step to regulate gene expression. Many factors that can bind mRNA and recruit different partners are involved in the inhibition or stimulation of protein synthesis. Oceans contain an important diversity of organisms that are used as important models to analyse gene expression at the translational level. These are useful to study translational control in different physiological processes for instance cell cycle (meiosis during meiotic maturation of starfish oocytes, mitosis following fertilization of sea urchin eggs) or to understand nervous system mechanisms (aplysia). All these studies will help finding novel actors involved in translational control and will thus be useful to discover new targets for therapeutic treatments against human diseases.     

Plant metabolomics for plant chemical responses to belowground community change by climate change

General circulation models on global climate change predict increase in surface air temperature and changes in precipitation. Increases in air temperature (thus soil temperature) and altered precipitation are known to affect the species composition and function of soil microbial communities. Plant roots interact with diverse soil organisms such as bacteria, protozoa, fungi, nematodes, annelids and insects. Soil organisms show diverse interactions with plants (eg. competition, mutualism and parasitism) that may alter plant metabolism. Besides plant roots, various soil microbes such as bacteria and fungi can produce volatile organic compounds (VOCs), which can serve as infochemicals among soil organisms and plant roots. While the effects of climate change are likely to alter both soil communities and plant metabolism, it is equally probable that these changes will have cascading consequnces for grazers and subsequent food web components aboveground. Advances in plant metabolomics have made it possibile to track changes in plant metabolomes as they respond to biotic and abiotic environmental changes. Recent developments in analytical instrumentation and bioinformatics software have established metabolomics as an important research tool for studying ecological interactions between plants and other organisms. In this review, we will first summarize recent progress in plant metabolomics methodology and subsequently review recent studies of interactions between plants and soil organisms in relation to climate change issues.     

PROTEIN SYNTHESIS AND DEGRADATION DURING AGING AND SENESCENCE

1. The published results on protein synthesis during aging are contradictory. Possible sources of error and variability include: an insufficient number of different animal ages used; use of whole organs that are cytologically highly heterogeneous; different animal strains; neglecting to measure the specific activity of the precursor pool for protein synthesis; and inadequate methodology for measurement of in vivo rates of protein synthesis. 2. In general, protein synthesis rates in mammals have been reported to decline 4–70% with age. In insects and other organisms, greater losses (60–90%) have been observed. 3. Limited evidence indicates that in some systems a decline in the rate of protein synthesis may be due to alterations (as yet of unknown nature) in the initiation components of the protein synthetic apparatus. Futhermore, some studies suggest that in some organisms aging affects the expression of specific parts of the genome. 4. The significance of results on protein metabolism obtained from some studies with nematodes is at present unknown, owing to problems associated with age-synchronization methods. Also, the in vitro fibroblast system for the study of human cellular aging has not been met with universal acceptance; it is generally believed that this system has not yet been established as a valid analogy to mammalian aging in vivo. 5. Failure to detect defective enzymes in many old organisms indicates at least that not all proteins are altered during aging. The complete thermal stability of purified enzymes from old organisms suggests that the observed thermolability of the same enzymes in crude cell extracts is not an intrinsic property of those enzymes. Post-translational modifications (partial denaturation) may constitute the primary mechanism for the production of altered cell polypeptides during aging. 6. The available evidence does not support the concept of an age-dependent decline in translational accuracy. The future purification to absolute homogeneity of an altered enzyme and its ‘young’ (unaltered) counterpart, and their sequencing, should resolve the question of translational errors. 7. Some degree of age-related ribosome loss appears to occur in fixed postmitotic cells. In general, the published polyribosomal profiles may represent artefacts due to insufficiently suppressed ribonuclease activity during extraction. 8. The published studies on protein degradation during aging are also contradictory. Some investigators have neglected the possibility of reutilization of labelled amino acid. It is possible that some of the observed age-related alterations in protein degradation rates are due to altered endocrine status of the animals used, rather than to defects in the protein degradative pathways. The studies utilizing cell culture systems are also contradictory, probably due to different experimental designs. 9. Limited evidence suggests that protein degradation may slow down with age in mammals and nematodes. An inefficient protein degradation system in old organisms could provide an explanation for the accumulation of altered macromolecules in some organisms. Virtually nothing is known about regulatory mechanisms of protein degradation during senescence. 10. There is a need to examine which proteins are synthesized and degraded at selectively different rates as a function of age and what their physiological role is. This approach would be more informative than the study of total protein turnover with age. 11. The physiological significance, and the causes of the observed declines in protein synthesis and degradation rates during aging and senescence, remain to be established.     

Expression vectors for quatitating in vivo translational ambiguity: Their potential use to analyse frameshifting at the HIV gag-pol junction

Translational errors are necessary so as to allow gene expression in various organisms. In retroviruses, synthesis of pol gene products necessitates either readthrough of a stop codon or frameshifting. Here we present an experimental system that permits quantification of translational errors in vivo. It consists of a family of expression vectors carrying different mutated versions of the luc gene as reporter. Mutations include both an in-frame stop codon and 1-base-pair deletions that require readthough or frameshift, respectively, to give rise to an active product. This system is sensitive enough to detect background errors in mammalian cells. In addition, one of the vectors contains two unique cloning sites that make it possible to insert any sequence of interest. This latter vector was used to analyse the effect of a DNA fragment, proposed to be the target of high level slippage at the gag-pol junction of HIV. The effect of paromomycin and kasugamycin, two antibiotics known to influence translational ambiguity, was also tested in cultured cells. The results indicate that paromomycin diversely affects readthrough and frameshifting, while kasugamycin had no effect.This family of vectors can be used to analyse the influence of structural and external factors on translational ambiguity in both mammalian cells and bacteria.     

Oxidation of elongation factor G inhibits the synthesis of the D1 protein of photosystem II

Oxidative stress inhibits the repair of photodamaged photosystem II (PSII). This inhibition is due initially to the suppression, by reactive oxygen species (ROS), of the synthesis de novo of proteins that are required for the repair of PSII, such as the D1 protein, at the level of translational elongation. To investigate in vitro the mechanisms whereby ROS inhibit translational elongation, we developed a translation system in vitro from the cyanobacterium Synechocystis sp. PCC 6803. The synthesis of the D1 protein in vitro was inhibited by exogenous H2O2. However, the addition of reduced forms of elongation factor G (EF-G), which is known to be particularly sensitive to oxidation, was able to reverse the inhibition of translation. By contrast, the oxidized forms of EF-G failed to restore translational activity. Furthermore, the overexpression of EF-G of Synechocystis in another cyanobacterium Synechococcus sp. PCC 7942 increased the tolerance of cells to H2O2 in terms of protein synthesis. These observations suggest that EF-G might be the primary target, within the translational machinery, of inhibition by ROS.     

Variation in chronic radiation exposure does not drive life history divergence among Daphnia populations across the Chernobyl Exclusion Zone

Ionizing radiation is a mutagen with known negative impacts on individual fitness. However, much less is known about how these individual fitness effects translate into population‐level variation in natural environments that have experienced varying levels of radiation exposure. In this study, we sampled genotypes of the freshwater crustacean, Daphnia pulex, from the eight inhabited lakes across the Chernobyl Exclusion Zone (CEZ). Each lake has experienced very different levels of chronic radiation exposure since a nuclear power reactor exploded there over thirty years ago. The sampled Daphnia genotypes represent genetic snapshots of current populations and allowed us to examine fitness‐related traits under controlled laboratory conditions at UK background dose rates. We found that whilst there was variation in survival and schedules of reproduction among populations, there was no compelling evidence that this was driven by variation in exposure to radiation. Previous studies have shown that controlled exposure to radiation at dose rates included in the range measured in the current study reduce survival, or fecundity, or both. One limitation of this study is the lack of available sites at high dose rates, and future work could test life history variation in various organisms at other high radiation areas. Our results are nevertheless consistent with the idea that other ecological factors, for example competition, predation or parasitism, are likely to play a much bigger role in driving variation among populations than exposure to the high radiation dose rates found in the CEZ. These findings clearly demonstrate that it is important to examine the potential negative effects of radiation across wild populations that are subject to many and varied selection pressures as a result of complex ecological interactions.     

Synthesis of individual ribosomal proteins in Escherichia coli B/r

The differential synthesis rates of individual ribosomal proteins (r-proteins) were measured in Escherichia coli B/r during the transition period following a nutritional shift-up from succinate minimal to glucose/ammo acids medium. These rates were observed to respond sequentially to the shift-up; the differential synthesis rate of protein L28 begins to increase within 0.1 of a minute following the shift-up, while the protein L29 synthesis rate begins to increase only after a lag of 2.5 minutes. The onset of induction of the remaining r-proteins occurs within this 2.5-minute interval. Furthermore, there was a twofold variation in the acceleration of the differential synthesis rates of individual r-proteins. Within the initial two to ten-minute period following the shift-up the differential synthesis rates of most r-proteins reached values ranging from 2.2 to 3.0-fold higher than the pre-shift rates, before declining to the post-shift steady-state values. It is suggested that the increases in the differential synthesis rates of r-proteins result in part from increases in the translational efficiency of messenger RNA in the post-shift growth medium and in part from increases in the amount of r-protein mRNA that is present.     

Trypanothione-dependent synthesis of deoxyribonucleotides by Trypanosoma brucei ribonucleotide reductase

Trypanosoma brucei, the causative agent of African sleeping sickness, synthesizes deoxyribonucleotides via a classical eukaryotic class I ribonucleotide reductase. The unique thiol metabolism of trypanosomatids in which the nearly ubiquitous glutathione reductase is replaced by a trypanothione reductase prompted us to study the nature of thiols providing reducing equivalents for the parasite synthesis of DNA precursors. Here we show that the dithiol trypanothione (bis(glutathionyl)spermidine), in contrast to glutathione, is a direct reductant of T. brucei ribonucleotide reductase with a K(m) value of 2 mm. This is the first example of a natural low molecular mass thiol directly delivering reducing equivalents for ribonucleotide reduction. At submillimolar concentrations, the reaction is strongly accelerated by tryparedoxin, a 16-kDa parasite protein with a WCPPC active site motif. The K(m) value of T. brucei ribonucleotide reductase for T. brucei tryparedoxin is about 4 micrometer. The disulfide form of trypanothione is a powerful inhibitor of the tryparedoxin-mediated reaction that may represent a physiological regulation of deoxyribonucleotide synthesis by the redox state of the cell. The trypanothione/tryparedoxin system is a new system providing electrons for a class I ribonucleotide reductase, in addition to the well known thioredoxin and glutaredoxin systems described in other organisms.