QM/MM výpočty a klasické molekulárně-dynamické simulace biomolekul / QM/MM výpočty a klasické molekulárně-dynamické simulace biomolekul

Melcr, Josef

January 2013

Systematic calculations were performed to uncover the free energy surfaces for hydrolytic reactions of methyl-diphosphate (in vacuum and implicit solvents) and GTP in EF-Tu active site. Density functional theory and ONIOM extrapolative QM/MM scheme were adopted for the assay. In accordance with experiments, the catalytic effect of the sodium cation was mild. It changes the conformation of GTP attracting its negatively charged oxygen atoms. hydrolýze GTP. The Na+ also equilibrates the charges of all phosphate groups of the GTP mostly by transferring electrons from gamma to beta-phosphate group, which is characteristic for the intermediate states during the hydrolytic reaction.

EF-Tu and RNase E : Essential and Functionally Connected Proteins

Hammarlöf, Disa L.

January 2011

The rate and accuracy of protein production is the main determinant of bacterial growth. Elongation Factor Tu (EF-Tu) provides the ribosome with aminoacylated tRNAs, and is central for its activity. In Salmonella enterica serovar Typhimurium, EF-Tu is encoded by the genes tufA and tufB. A bacterial cell depending on tufA499-encoded EF-Tu mutant Gln125Arg grows extremely slowly. We found evidence that this is caused by excessive degradation of mRNA, which is suggested to be the result of transcription-translation decoupling because the leading ribosome is ‘starved’ for amino acids and stalls on the nascent mRNA, which is thus exposed to Riboendonuclease RNase E. The slow-growth phenotype can be reversed by mutations in RNase E that reduce the activity of this enzyme. We found that the EF-Tu mutant has increased levels of ppGpp during exponential growth in rich medium. ppGpp is usually produced during starvation, and we propose that Salmonella, depending on mutant EF-Tu, incorrectly senses the resulting situation with ribosomes ‘starving’ for amino acids as a real starvation condition. Thus, RelA produces ppGpp which redirects gene expression from synthesis of ribosomes and favours synthesis of building blocks such as amino acids. When ppGpp levels are reduced, either by over-expression of SpoT or by inactivation of relA, growth of the mutant is improved. We suggest this is because the cell stays in a fast-growth mode. RNase E mutants with a conditionally lethal temperature-sensitive (ts) phenotype were used to address the long-debated question of the essential role of RNase E. Suppressor mutations of the ts phenotype were selected and identified, both in RNase E as well as in extragenic loci. The internal mutations restore the wild-type RNase E function to various degrees, but no single defect was identified that alone could account for the ts phenotype. In contrast, identifying three different classes of extragenic suppressors lead us to suggest that the essential role of RNaseIE is to degrade mRNA. One possibility to explain the importance of this function is that in the absence of mRNA degradation by RNase E, the ribosomes become trapped on defective mRNAs, with detrimental consequences for continued cell growth.

bacterial growth

translation

EF-Tu

RNase E

mRNA

RNA degradation

Functional Constraints on Replacing an Essential Gene with Its Ancient and Modern Homologs

Kacar, Betül, Garmendia, Eva, Tuncbag, Nurcan, Andersson, Dan I., Hughes, Diarmaid

29 August 2017

Genes encoding proteins that carry out essential informational tasks in the cell, in particular where multiple interaction partners are involved, are less likely to be transferable to a foreign organism. Here, we investigated the constraints on transfer of a gene encoding a highly conserved informational protein, translation elongation factor Tu (EF-Tu), by systematically replacing the endogenous tufA gene in the Escherichia coli genome with its extant and ancestral homologs. The extant homologs represented tuf variants from both near and distant homologous organisms. The ancestral homologs represented phylogenetically resurrected tuf sequences dating from 0.7 to 3.6 billion years ago (bya). Our results demonstrate that all of the foreign tuf genes are transferable to the E. coli genome, provided that an additional copy of the EF-Tu gene, tufB, remains present in the E. coli genome. However, when the tufB gene was removed, only the variants obtained from the gammaproteobacterial family (extant and ancestral) supported growth which demonstrates the limited functional interchangeability of E. coli tuf with its homologs. Relative bacterial fitness correlated with the evolutionary distance of the extant tuf homologs inserted into the E. coli genome. This reduced fitness was associated with reduced levels of EF-Tu and reduced rates of protein synthesis. Increasing the expression of tuf partially ameliorated these fitness costs. In summary, our analysis suggests that the functional conservation of protein activity, the amount of protein expressed, and its network connectivity act to constrain the successful transfer of this essential gene into foreign bacteria. IMPORTANCE Horizontal gene transfer (HGT) is a fundamental driving force in bacterial evolution. However, whether essential genes can be acquired by HGT and whether they can be acquired from distant organisms are very poorly understood. By systematically replacing tuf with ancestral homologs and homologs from distantly related organisms, we investigated the constraints on HGT of a highly conserved gene with multiple interaction partners. The ancestral homologs represented phylogenetically resurrected tuf sequences dating from 0.7 to 3.6 bya. Only variants obtained from the gammaproteobacterial family (extant and ancestral) supported growth, demonstrating the limited functional interchangeability of E. coli tuf with its homologs. Our analysis suggests that the functional conservation of protein activity, the amount of protein expressed, and its network connectivity act to constrain the successful transfer of this essential gene into foreign bacteria.

EF-Tu

horizontal gene transfer

ancient genes

proteobacteria

tuf

Study on Bacterial Protein Synthesis System toward the Incorporation of D-Amino Acid & Synthesis of 2'-deoxy-3'-mercapto-tRNA

Huang, Po-Yi

22 April 2017

Life is anti-entropic and highly organized phenomenon with two characteristics reinforcing each other: homochirality and the stereospecific catalysis of chemical reactions. The exclusive presence of L-amino acids and R-sugars in living world well depict this. Hypothetically, the amino acids and sugars of reverse chirality could form a parallel kingdom which is highly orthogonal to the present world. The components from this mirror kingdom, such as protein or nucleic acid, will be much more resistant to the defensive mechanism of present living system, which could be of great value. Therefore, by gradually rewiring the present bio-machineries, we look to build a bridge leading us to the space of mirror-imaged biomolecules. We begin by investigating protein synthesis with mirror amino acid since most amino acids contain one chiral center to be inversed comparing to sugars. In this work, we analyzed three stages critical for the incorporation of D-amino acid into ribosomal protein synthesis: amino acylation, EF-Tu binding of amino acyl-tRNA and delivery bias, and ribosome catalyzed peptidyl transfer. We have demonstrated that the affinity between EF-Tu and amino acyl-tRNA plays critical role on D-amino acid incorporation, and built a platform aimed to select for ribosome tolerating D-amino acid better. / Chemistry and Chemical Biology

Biochemistry

D-amino acid

EF-Tu

Ribosome engineering

The Role of SmpB in Licensing tmRNA Entry into Stalled Ribosomes

Miller, Mickey R.

03 July 2013

Ribosomes translate the genetic information contained in mRNAs into protein by linking together amino acids with the help of aminoacyl-tRNAs. In bacteria, protein synthesis stalls when the ribosome reaches the 3'-end of truncated mRNA transcripts lacking a stop codon. Trans-translation is a conserved bacterial quality control process that rescues stalled ribosomes. Transfer-messenger RNA (tmRNA) and its protein partner SmpB mimic a tRNA by entering the A site of the ribosome and accepting the growing peptide chain. The ribosome releases the truncated mRNA and resumes translation on the tmRNA template. The open reading frame found on tmRNA encodes a peptide tag that marks the defective nascent peptide for proteolysis. A stop codon at the end of the open reading frame allows the ribosome to be recycled and engage in future rounds of translation.The entry of tmRNA into stalled ribosomes presents a challenge to our understanding of ribosome function because during the canonical decoding process, the ribosome specifically recognizes the codon-anticodon duplex formed between tRNA and mRNA in the A site. Recognition of proper base-pairing leads to conformational changes that accelerate GTP hydrolysis by EF-Tu and rapid accommodation of the tRNA into the ribosome for peptidyl transfer. The puzzle is that tmRNA enters stalled ribosomes and reacts with the nascent peptide in the absence of a codon-anticodon interaction. Instead, SmpB binding in the decoding center begins the rescue process, but it has been unclear how SmpB licenses tmRNA entry into stalled ribosomes. We analyzed a series of SmpB and ribosomal RNA mutants using pre-steady-state kinetic assays for EF-Tu activation and peptidyl transfer. Although the conserved 16S nucleotides A1492 and A1493 play an essential role in canonical decoding, they play little or no role in EF-Tu activation or peptidyl transfer to tmRNA. In contrast, a third nucleotide, G530, stacks with the side chain of SmpB residue His136, inducing conformational changes that lead to GTP hydrolysis by EF-Tu. A portion of the C-terminal tail forms a helix within the mRNA channel, monitoring the length of mRNA bound in the ribosome to avoid aborting productive protein synthesis. Helix formation in the mRNA channel is essential for accommodation and peptidyl transfer, but not for GTP hydrolysis. We show that conserved residues in the tail are essential for EF-Tu activation, accommodation, or translocation to the P site. Our findings lead to a clearer model of how the tmRNA-SmpB complex enters stalled ribosomes.

tmRNA

SmpB

decoding

EF-Tu

ribosome

Biochemistry

Chemistry

Evolutionary synthetic biology: structure/function relationships within the protein translation system

Cacan, Ercan

06 September 2011

Production of mutant biological molecules for understanding biological principles or as therapeutic agents has gained considerable interest recently. Synthetic genes are today being widely used for production of such molecules due to the substantial decrease in the costs associated with gene synthesis technology. Along one such line, we have engineered tRNA genes in order to dissect the effects of G:U base-pairs on the accuracy of the protein translation machinery. Our results provide greater detail into the thermodynamic interactions between tRNA molecules and an Elongation Factor protein (termed EF-Tu in bacteria and eEF1A in eukaryotes) and how these interactions influence the delivery of aminoacylated tRNAs to the ribosome. We anticipate that our studies not only shed light on the basic mechanisms of molecular machines but may also help us to develop therapeutic or novel proteins that contain unnatural amino acids. Further, the manipulation of the translation machinery holds promise for the development of new methods to understand the origins of life. Along another line, we have used the power of synthetic biology to experimentally validate an evolutionary model. We exploited the functional diversity contained within the EF-Tu/eEF1A gene family to experimentally validate the model of evolution termed ‘heterotachy’. Heterotachy refers to a switch in a site’s mutational rate class. For instance, a site in a protein sequence may be invariant across all bacterial homologs while that same site may be highly variable across eukaryotic homologs. Such patterns imply that the selective constraints acting on this site differs between bacteria and eukaryotes. Despite intense efforts and large interest in understanding these patterns, no studies have experimentally validated these concepts until now. In the present study, we analyzed EF-Tu/eEF1A gene family members between bacteria and eukaryotes to identify heterotachous patterns (also called Type-I functional divergence). We applied statistical tests to identify sites possibly responsible for biomolecular functional divergence between EF-Tu and eEF1A. We then synthesized protein variants in the laboratory to validate our computational predictions. The results demonstrate for the first time that the identification of heterotachous sites can be specifically implicated in functional divergence among homologous proteins. In total, this work supports an evolutionary synthetic biology paradigm that in one direction uses synthetic molecules to better understand the mechanisms and constraints governing biomolecular behavior while in another direction uses principles of molecular sequence evolution to generate novel biomolecules that have utility for industry and/or biomedicine.

Functional divergence

TRNA

Heterotachy

EF-Tu

Unnatural amino acids

Evolutionary synthetic biology

Transfer RNA

Aminoacyl-tRNA

Amino acids

Synthetic biology

Genetics and Growth Regulation in Salmonella enterica

Bergman, Jessica M.

January 2014

Most free-living bacteria will encounter different environments and it is therefore critical to be able to rapidly adjust to new growth conditions in order to be competitively successful. Responding to changes requires efficient gene regulation in terms of transcription, RNA stability, translation and post-translational modifications. Studies of an extremely slow-growing mutant of Salmonella enterica, with a Glu125Arg mutant version of EF-Tu, revealed it to be trapped in a stringent response. The perceived starvation was demonstrated to be the result of increased mRNA cleavage of aminoacyl-tRNA synthetase genes leading to lower prolyl-tRNA levels. The mutant EF-Tu caused an uncoupling of transcription and translation, leading to increased turnover of mRNA, which trapped the mutant in a futile stringent response. To examine the essentiality of RNase E, we selected and mapped three classes of extragenic suppressors of a ts RNase E phenotype. The ts RNase E mutants were defective in the degradation of mRNA and in the processing of tRNA and rRNA. Only the degradation of mRNA was suppressed by the compensatory mutations. We therefore suggest that degradation of at least a subset of cellular mRNAs is an essential function of RNase E. Bioinformatically, we discovered that the mRNA of tufB, one of the two genes encoding EF-Tu, could form a stable structure masking the ribosomal binding site. This, together with previous studies that suggested that the level of EF-Tu protein could affect the expression of tufB, led us to propose three models for how this could occur. The stability of the tufB RNA structure could be affected by the elongation rate of tufB-translating ribosomes, possibly influenced by the presence of rare codons early in the in tufB mRNA. Using proteomic and genetic assays we concluded that two previously isolated RNAP mutants, each with a growth advantage when present as subpopulations on aging wild-type colonies, were dependent on the utilization of acetate for this phenotype. Increased growth of a subpopulation of wild-type cells on a colony unable to re-assimilate acetate demonstrated that in aging colonies, acetate is available in levels sufficient to sustain the growth of at least a small subpopulation of bacteria.

tufA

tufB

EF-Tu

ppGpp

Stringent response

RNase E

RNA turnover

Post-transcriptional regulation

rpoB

rpoS

Growth in stationary phase

A Unified Multitude : Experimental Studies of Bacterial Chromosome Organization

Garmendia, Eva

January 2017

Bacteria are many, old and varied; different bacterial species have been evolving for millions of years and show many disparate life-styles and types of metabolism. Nevertheless, some of the characteristics regarding how bacteria organize their chromosomes are relatively conserved, suggesting that they might be both ancient and important, and that selective pressures inhibit their modification. This thesis aims to study some of these characteristics experimentally, assessing how changes affect bacterial growth, and how, after changing conserved features, bacteria might evolve. First, we experimentally tested what are the constraints on the horizontal transfer of a gene highly important for bacterial growth. Second, we investigated the significance of the location and orientation of a highly expressed and essential operon; and we experimentally evolved strains with suboptimal locations and orientations to assess how bacteria could adapt to these changes. Thirdly, we sought to understand the accessibility of different regions of the bacterial chromosome to engage in homologous recombination. And lastly, we constructed bacterial strains with chromosomal inversions to assess what effect the inversions had on growth rate, and how bacteria carrying costly inversions could evolve to reduce these costs. The results provide evidence for different selective forces acting to conserve these chromosome organizational traits. Accordingly, we found that evolutionary distance, functional conservation, suboptimal expression and impaired network connectivity of a gene can affect the successful transfer of genes between bacterial species. We determined that relative location of an essential and highly expressed operon is critical for supporting fast growth rate, and that its location seems to be more important than its orientation. We also found that both the location, and relative orientation of separated duplicate sequences can affect recombination rates between these sequences in different regions of the chromosome. Finally, the data suggest that the importance of having the two arms of a circular bacterial chromosome approximately equal in size is a strong selective force acting against certain type of chromosomal inversions.

bacterial evolution

chromosome organization and structure

chromosomal inversions

EF-Tu

horizontal gene transfer

Microbiology

Mikrobiologi

Genetics

Genetik

Evolutionary Biology

Evolutionsbiologi

Biased Evolution : Causes and Consequences

Brandis, Gerrit

January 2016

In evolution alternative genetic trajectories can potentially lead to similar phenotypic outcomes. However, certain trajectories are preferred over others. These preferences bias the genomes of living organisms and the underlying processes can be observed in ongoing evolution. We have studied a variety of biases that can be found in bacterial chromosomes and determined the selective causes and functional consequences for the cell. We have quantified codon usage bias in highly expressed genes and shown that it is selected to optimise translational speed. We further demonstrated that the resulting differences in decoding speed can be used to regulate gene expression, and that the use of ‘non-optimal’ codons can be detrimental to reading frame maintenance. Biased gene location on the chromosome favours recombination between genes within gene families and leads to co-evolution. We have shown that such recombinational events can protect these gene families from inactivation by mobile genetic elements, and that chromosome organization can be selectively maintained because inversions can lead to the formation of unstable hybrid operons. We have used the development of antibiotic resistance to study how different bacterial lifestyles influence evolutionary trajectories. For this we used two distinct pairs of antibiotics and disease-causing bacteria, namely (i) Mycobacterium tuberculosis that is treated with rifampicin and (ii) Escherichia coli that is treated with ciprofloxacin. We have shown that in the slow-growing Mycobacterium tuberculosis, resistance mutations are selected for high-level resistance. Fitness is initially less important, and over time fitness costs can be ameliorated by compensatory mutations. The need for rapid growth causes the selection of ciprofloxacin resistance in Escherichia coli not only to be selected on the basis of high-level resistance but also on high fitness. Compensatory evolution is therefore not required and is not observed. Taken together, our results show that the evolution of a phenotype is the product of multiple steps and that many factors influence which trajectory is the most likely to occur and be most beneficial. Over time, selection will favour this particular trajectory and lead to biased evolution, affecting genome sequence and organization.

Evolution

Codon usage bias

Post-transcriptional regulation

Recombination

Inversion

EF-Tu

Frameshift suppression

Antibiotic resistance

Rifampicin

Ciprofloxacin

Compensatory evolution

Drug efflux

RNA polymerase

DNA gyrase

Elucidating the interaction of Borrelia burgdorferi OspC with phagocytes in the establishment of lyme borreliosis

Carrasco, Sebastian Eduardo

20 March 2015

Indiana University-Purdue University Indianapolis (IUPUI) / Lyme disease, the most prevalent vector-borne illness in the United States, is a multisystem inflammatory disorder caused by infection with the spirochete Borrelia burgdorferi (Bb). This spirochete is maintained in nature through an enzootic cycle involving ticks and small mammals. The Bb genome encodes a large number of surface lipoproteins, many of which are expressed during mammalian infection. One of these lipoproteins is the major outer surface protein C (OspC) whose production is induced during transmission as spirochetes transition from ticks to mammals. OspC is required for Bb to establish infection in mice and has been proposed to facilitate evasion of innate immunity. However, the exact biological function of OspC remains elusive. Our studies show the ospC-deficient spirochete could not establish infection in NOD-scid IL2rγnull mice that lack B cells, T cells, NK cells, and lytic complement, whereas the wild-type spirochete was fully infectious in these mice. The ospC mutant also could not establish infection in SCID and C3H mice that were transiently neutropenic during the first 48 h post-challenge. However, depletion of F4/80+ phagocytes at the skin-site of inoculation in SCID mice allowed the ospC mutant to establish infection in vivo. In phagocyte-depleted SCID mice, the ospC mutant was capable to colonize the joints and triggered neutrophilia during dissemination in a similar pattern as wild-type bacteria. We then constructed GFP-expressing Bb strains to evaluate the interaction of the ospC mutant with phagocytes. Using flow cytometry and fluorometric assay for phagocytosis, we found that phagocytosis of GFP-expressing ospC mutant spirochetes by murine peritoneal macrophages and human THP-1 cells was significantly higher than parental wild-type Bb strains, suggesting that OspC has an anti-phagocytic property. This enhancement in phagocytosis was not mediated by MARCO and CD36 scavenger receptors and was not associated with changes in mRNA levels of TNFα, IL-1β, and IL-10. Phagocytosis assays with HL60 neutrophil-like cells showed that uptake of Bb strains was independent to OspC. Together, our findings reveal that F4/80+ phagocytes are important for clearance of the ospC mutant, and suggest that OspC promotes spirochetes' evasion of macrophages in the skin of mice during early Lyme borreliosis.

Borrelia burgdorferi

EF-Tu

Infection

Lyme disease

OspC

Phagocytes

Lyme disease

Borrelia burgdorferi -- Research

Protein C

Lyme disease -- Molecular aspects

Relapsing fever

Spirochetes -- Molecular aspects

Bacteria