The 5-chlorouracil:7-deazaadenine base pair as an alternative to the dT:dA base pair.

5-Chloro-2'-deoxyuridine as a possible component of a chemically modified genome has been discussed in terms of its influence on duplex stability and DNA polymerase incorporation properties. The search for its counterpart among different deoxyadenosine analogs (7-deaza-, 8-aza- and 8-aza-7-deaza-2'-deoxyadenosines) showed that the stable duplex formation as well as the synthesis of long constructs, more than 2 kb, were successful with the 5-chloro-2'-deoxyuridine and 7-deaza-2'-deoxyadenosine combination and with Taq DNA polymerase.

Sulfonate derived phosphoramidates as active intermediates in the enzymatic primer-extension of DNA.

Novel unnatural 5'-phosphoramidate nucleosides, capable of being processed as substrates by DNA polymerases for multiple nucleotide incorporations, have been designed. The mimics feature metabolites such as taurine and a broad range of aliphatic sulfonates coupled through a P-N bond to the 5'-phosphate position of deoxynucleotides, to allow binding interactions in the enzyme active site. The utility of all of the analogues as pyrophosphate mimics was demonstrated for the chain elongation of DNA, using both thermophilic and mesophilic microbial polymerases.

A metabolic prototype for eliminating tryptophan from the genetic code.

We set out to reduce the chemical constitution of a living organism to 19 amino acids. A strain was constructed for reassigning the tryptophan codon UGG to histidine and eliminating tryptophan from Escherichia coli. Histidine codons in the gene for an essential enzyme were replaced with tryptophan codons and the restoration of catalytic activity by missense suppressor His-tRNA bearing a CCA anticodon was selected. We used automated cultivation to assess the stability of this genetic construct during evolution. Histidine to tryptophan mutation at codon 30 in the transketolase gene from yeast and its cognate suppressor tRNA were stably propagated in a tktAB deletant of E. coli over 2500 generations. The ratio of histidine misincorporation at tryptophan sites in the proteome increased from 0.0007 to 0.03 over 300 days of continuous culture. This result demonstrated that the genetic code can be forced to evolve by permanent metabolic selection.

Redesigning the leaving group in nucleic acid polymerization.

Artificial nucleic acids have the potential to propagate genetic information in vivo purposefully insulated from the canonical replication and transcription processes of cells. Natural nucleic acids are synthesized using nucleoside triphosphates as building blocks and polymerases as catalysts, pyrophosphate functioning as the universal leaving group for DNA and RNA biosynthesis. In order to avoid entanglement between the propagation of artificial nucleic acids in vivo and the cellular information processes, we promote the biosynthesis of natural and xenobiotic nucleic acids (XNA) dependent on the involvement of leaving groups distinct from pyrophosphate. The feasibility of such radically novel biochemical systems relies on the systematic exploration of the chemical diversity of nucleic acid leaving groups that can undergo the catalytic mechanism of phosphotransfer in nucleic acid polymerization. Initial forays in this research area demonstrate the wide acceptance of polymerases and augur well for in vivo implementation and integration with canonical metabolism.

Polymerase-catalyzed synthesis of DNA from phosphoramidate conjugates of deoxynucleotides and amino acids.

Some selected amino acids, in particular L-aspartic acid (L-Asp) and L-histidine (L-His), can function as leaving group during polymerase-catalyzed incorporation of deoxyadenosine monophosphate (dAMP) in DNA. Although L-Asp-dAMP and L-His-dAMP bind, most probably, in a different way in the active site of the enzyme, aspartic acid and histidine can be considered as mimics of the pyrophosphate moiety of deoxyadenosine triphosphate. L-Aspartic acid is more efficient than D-aspartic acid as leaving group. Such P-N conjugates of amino acids and deoxynucleotides provide a novel experimental ground for diversifying nucleic acid metabolism in the field of synthetic biology.

Artificially ambiguous genetic code confers growth yield advantage.

A primitive genetic code is thought to have encoded statistical, ambiguous proteins in which more than one amino acid was inserted at a given codon. The relative vitality of organisms bearing ambiguous proteins and the kinds of pressures that forced development of the highly specific modern genetic code are unknown. Previous work demonstrated that, in the absence of selective pressure, enforced ambiguity in cells leads to death or to sequence reversion to eliminate the ambiguous phenotype. Here, we report the creation of a nonreverting strain of bacteria that produced statistical proteins. Ablating the editing activity of isoleucyl-tRNA synthetase resulted in an ambiguous code in which, through supplementation of a limited supply of isoleucine with an alternative amino acid that was noncoding, the mutant generating statistical proteins was favored over the wild-type isogenic strain. Such organisms harboring statistical proteins could have had an enhanced adaptive capacity and could have played an important role in the early development of living systems.

Long term adaptation of a microbial population to a permanent metabolic constraint: overcoming thymineless death by experimental evolution of Escherichia coli.

BACKGROUND: To maintain populations of microbial cells under controlled conditions of growth and environment for an indefinite duration is a prerequisite for experimentally evolving natural isolates of wild-type species or recombinant strains. This goal is beyond the scope of current continuous culture apparatus because these devices positively select mutants that evade dilution, primarily through attachment to vessel surfaces, resulting in persistent sub-populations of uncontrollable size and growth rate. RESULTS: To overcome this drawback, a device with two growth chambers periodically undergoing transient phases of sterilization was designed. The robustness of this device was assessed by propagating an E. coli strain under permanent thymine starvation for over 880 days, i.e. metabolic conditions notoriously known to lead to cell death and clogging of cultivation vessels. Ten thousand generations were required to obtain a descendant lineage that could resist thymine starvation and had recovered wild-type growth rate. CONCLUSIONS: This approach provides a technological framework for the diversification and improvement of microbial strains by long-term adaptation to inescapable metabolic constraints. An E. coli strain that is totally resistant to thymineless death was selected.

Molecular evolution of protein atomic composition.

Living organisms encounter various growth conditions in their habitats, raising the question of whether ecological fluctuations could alter biological macromolecules. The advent of complete genome sequences and the characterization of whole metabolic pathways allowed us to search for such ecological imprints. Significant correlations between atomic composition and metabolic function were found in sulfur- and carbon-assimilatory enzymes, which appear depleted in sulfur and carbon, respectively, in both the bacterium Escherichia coli and the eukaryote Saccharomyces cerevisiae. In addition to genetic instructions, genomic data thus also provide paleontological records of environmental nutrient availability and of metabolic costs.

Enlarging the amino acid set of Escherichia coli by infiltration of the valine coding pathway.

Aminoacyl transfer RNA (tRNA) synthetases establish the rules of the genetic code by catalyzing the aminoacylation of tRNAs. For some synthetases, accuracy depends critically on an editing function at a site distinct from the aminoacylation site. Mutants of Escherichia coli that incorrectly charge tRNA(Val) with cysteine were selected after random mutagenesis of the whole chromosome. All mutations obtained were located in the editing site of valyl-tRNA synthetase. More than 20% of the valine in cellular proteins from such an editing mutant organism could be replaced with the noncanonical aminobutyrate, sterically similar to cysteine. Thus, the editing function may have played a central role in restricting the genetic code to 20 amino acids. Disabling this editing function offers a powerful approach for diversifying the chemical composition of proteins and for emulating evolutionary stages of ambiguous translation.

Enzymatic incorporation in DNA of 1,5-anhydrohexitol nucleotides.

The ability of several DNA polymerases to catalyze the template-directed synthesis of duplex oligonucleotides containing a base pair between a nucleotide with anhydrohexitol ring and its natural complement has been investigated. All DNA polymerases were able to accept the chemically synthesized anhydrohexitol triphosphate as substrate and to catalyze the incorporation of one anhydrohexitol nucleotide. However, only family B DNA polymerases succeeded in elongating the primer after the incorporation of an anhydrohexitol nucleotide. In this family, Vent (exo(-)) DNA polymerase is the most successful one and was therefore selected for further investigation. Results revealed that at high enzyme concentrations six hATPs could be incorporated; however, a selective incorporation proved only feasible under experimental conditions where no more than two analogues could be inserted. Also the synthesis of a mixed HNA-DNA sequence was examined. Kinetic parameters for incorporation of one anhydrohexitol adenine nucleoside were similar to those of its natural analogue.

Genetic and biochemical characterization of Salmonella enterica serovar typhi deoxyribokinase.

We identified in the genome of Salmonella enterica serovar Typhi the gene encoding deoxyribokinase, deoK. Two other genes, vicinal to deoK, were determined to encode the putative deoxyribose transporter (deoP) and a repressor protein (deoQ). This locus, located between the uhpA and ilvN genes, is absent in Escherichia coli. The deoK gene inserted on a plasmid provides a selectable marker in E. coli for growth on deoxyribose-containing medium. Deoxyribokinase is a 306-amino-acid protein which exhibits about 35% identity with ribokinase from serovar Typhi, S. enterica serovar Typhimurium, or E. coli. The catalytic properties of the recombinant deoxyribokinase overproduced in E. coli correspond to those previously described for the enzyme isolated from serovar Typhimurium. From a sequence comparison between serovar Typhi deoxyribokinase and E. coli ribokinase, whose crystal structure was recently solved, we deduced that a key residue differentiating ribose and deoxyribose is Met10, which in ribokinase is replaced by Asn14. Replacement by site-directed mutagenesis of Met10 with Asn decreased the V(max) of deoxyribokinase by a factor of 2.5 and increased the K(m) for deoxyribose by a factor of 70, compared to the parent enzyme.

Reassigning cysteine in the genetic code of Escherichia coli.

We investigated directed deviations from the universal genetic code. Mutant tRNAs that incorporate cysteine at positions corresponding to the isoleucine AUU, AUC, and AUA and methionine AUG codons were introduced in Escherichia coli K12. Missense mutations at the cysteine catalytic site of thymidylate synthase were systematically crossed with synthetic suppressor tRNACys genes coexpressed from compatible plasmids. Strains harboring complementary codon/anticodon associations could be stably propagated as thymidine prototrophs. A plasmid-encoded tRNACys reading the codon AUA persisted for more than 500 generations in a strain requiring its suppressor activity for thymidylate biosynthesis, but was eliminated from a strain not requiring it. Cysteine miscoding at the codon AUA was also enforced in the active site of amidase, an enzyme found in Helicobacter pylori and not present in wild-type E. coli. Propagating the amidase missense mutation in E. coli with an aliphatic amide as nitrogen source required the overproduction of Cys-tRNA synthetase together with the complementary suppressor tRNACys. The toxicity of cysteine miscoding was low in all our strains. The small size and amphiphilic character of this amino acid may render it acceptable as a replacement at most protein positions and thus apt to overcome the steric and polar constraints that limit evolution of the genetic code.

Human deoxycytidine kinase as a conditional mutator in Escherichia coli.

The chemical diversification of DNA precursors was undertaken in Escherichia coil by expressing the human gene for deoxycytidine kinase, and supplying such recombinant strains with nucleoside analogues bearing an altered base or sugar. Arabinocytidine and dideoxycytidine thus became highly toxic to E. coli in the sub-millimolar range. Deoxynucleosides bearing isoadenine (2-aminopurine) and isoguanine (2-hydroxy-6-aminopurine) showed a high mutagenic potency towards the recombinant strains, to an extent comparable to that of the most efficient mutator alleles (dnaQ). These findings open the way to the propagation of chemically remodelled nucleic acids and to the controlled hypermutagenesis of plasmids in vivo.

Human deoxycytidine kinase as a conditional mutator in Escherichia coli.

The chemical diversification of DNA precursors was undertaken in Escherichia coli by expressing the human gene for deoxycytidine kinase, and supplying such recombinant strains with nucleoside analogues bearing an altered base or sugar. Arabinocytidine and dideoxycytidine thus became highly toxic to E. coli in the sub-millimolar range. Deoxynucleosides bearing isoadenine (2-aminopurine) and isoguanine (2-hydroxy-6-aminopurine) showed a high mutagenic potency towards the recombinant strains, to an extent comparable to that of the most efficient mutator alleles (dnaQ). These findings open the way to the propagation of chemically remodelled nucleic acids and to the controlled hypermutagenesis of plasmids in vivo.

A survey of polypeptide deformylase function throughout the eubacterial lineage.

N-terminal formylation of ribosome-synthesized polypeptides is assumed to be among the most conserved features that distinguish the eubacterial line of descent from other living phyla. In order to assess the ancientness of this trait, def genes encoding polypeptide deformylase were characterized from four eubacterial species, Lactococcus lactis, Bacillus subtilis, Calothrix PCC7601 and Thermotoga maritima, taking advantage of the conditional viability of the def mutants of Escherichia coli. Altogether, eight sequences of polypeptide deformylase have been obtained from all the eubacterial sources which were investigated, either through systematic genome sequence analysis or through genetic screening, yielding a highly homologous family. A gene putatively encoding Met-tRNAi formyltransferase, fmt, was found downstream of the deformylase gene except in L. lactis, Mycoplasma genitalium, Calothrix PCC7601 and T. maritima. These results argue strongly for the ancestral character of N-terminal formylation in eubacteria. Most of the wide deviations of amino acid usage observed in def- and fmt-encoded proteins among species is best accounted for by the nucleotide composition of genomes. Furthermore, the species of origin of each protein appears to be more recognizable than its function, considering only its amino acid composition.

Exploring the functional robustness of an enzyme by in vitro evolution.

The evolution of natural proteins is thought to have occurred by successive fixation of individual mutations. In vitro protein evolution seeks to accelerate this process. RNA hypermutagenesis, cDNA synthesis in the presence of biased dNTP concentrations, delivers elevated mutant and mutation frequencies. Here lineages of active enzymes descended from the homotetrameric 78 residue dihydrofolate reductase (DHFR) encoded by the Escherichia coli R67 plasmid were generated by iterative RNA hypermutagenesis, resulting in >20% amino acid replacement. The 22 residue N-terminus could be deleted yielding a minimum functional entity refractory to further changes, designating it as a determinant of R67 robustness. Complete substitution of the segment still allowed fixation of mutations. By the facile introduction of multiple mutations, RNA hypermutagenesis allows the generation of active proteins derived from extant genes through a mode unexplored by natural selection.

Construction of a self-complementary nucleoside from deoxyguanosine.

The 8-hydroxyguanine:adenine mispairing scheme that spontaneously occurs in vivo through oxidative metabolism of DNA was edited to obtain a pair closely fitting the Watson-Crick geometry in which 2 purine bases of identical structure but oppositely rotated in the syn and anti configurations are hydrogen-bonded. The structure thus designed, 2-amino-8-hydroxypurine, was synthesized as a DNA precursor from deoxyguanosine in 8 steps by oxidation at carbon 8 of guanine followed by reduction at carbon 6. Polydeoxynucleotides embodying this self-complementary base are expected to undergo direct copying processes through polymerase catalysis.

Multienzymatic non ribosomal peptide biosynthesis: identification of the functional domains catalysing peptide elongation and epimerisation.

Peptide synthetases are multienzymatic complexes that synthesize bioactive peptides molecules by the thiotemplate mechanism. Comparison of the known sequences of peptide synthetases led us to the identification of a 350 amino acids domain catalysing elongation and containing the motif HHxxxDG. This motif is present as many times as acyltransfer or epimerisation reactions occur during biosynthesis of the peptide. The distance between this motif and the phosphopantetheinyl attachment site is nearly invariant. An identical motif is found in other enzymes effecting acyl transfer such as chloramphenicol acetyltransferase from Tn9 and dihydrolipoamide acyltransferase. Altogether, the HHxxxDG motif may constitute the signature of a superfamily sharing a common catalytic mechanism based on the acid-base properties of the second histidine for effecting acyl transfer or peptide epimerisation.

Convergent evolution of amino acid usage in archaebacterial and eubacterial lineages adapted to high salt.

Chemical composition and physical properties of the total protein of Haloferax mediterranei, a halophilic archaebacterium requiring high salt concentration for growth, of Halomonas elongata, a halotolerant eubacterium able to grow at any concentration of salt, and of Escherichia coli B, a eubacterium related to H. elongata, unable to grow at high salt concentration, were compared using robust standard biochemical methods. The distribution of amino acid abundancies in the bulk protein from H. elongata was found to be intermediate between that from H. mediterranei and that from E. coli. The two high-salt-adapted organisms displayed an enrichment in aspartic acid and glutamic acid together with an impoverishment in lysine as compared to E. coli. This signature in amino acid usage is reflected in the charge distribution of proteins, as revealed by anion exchange chromatography of crude cell extracts. Since H. elongata diverged from H. mediterranei more than three billion years ago, the resemblance of their amino acid usages can be interpreted as a convergent imprint of their common habitats onto the chemical constitution of their proteins.

Genetic characterization of polypeptide deformylase, a distinctive enzyme of eubacterial translation.

Deformylase performs an essential step in the maturation of proteins in eubacteria, by removing the formyl group from the N-terminal methionine residue of ribosome-synthesized polypeptides. In spite of this important role in translation, the enzyme had so far eluded characterization because of its instability. We report the isolation of the deformylase gene of Escherichia coli, def, by overexpression of a genomic library from a high-copy-number plasmid and selection for utilization of the substrate analogue formyl-leucyl-methionine as a source of methionine. The def gene encodes a 169 amino acid polypeptide that bears no obvious resemblance to other known proteins. It forms an operon with the fmt gene, that encodes the initiator methionyl-tRNA(i) transformylase, which was recently characterized (Guillon et al., J. Bacteriol., 174, 4294-4301, 1992). This operon was mapped at min 72 of the E. coli chromosome. The def gene could be inactivated if the fmt gene was also inactivated, or if biosynthesis of N10-formyl-tetrahydrofolate, the formyl donor in methionyl-tRNA(i) transformylation, was blocked by trimethoprim. These findings designate deformylase as a target for antibacterial chemotherapy.