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Query: EC:1.5.1.3 (
dihydrofolate reductase
)
5,819
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Nucleotide sequences around the boundaries of all open reading frames in the Escherichia coli whole genome were analyzed. Characteristic base biases were observed after the initiation codon and before the termination codon. We examined the effect of the base sequence after the initiation codon on the translation efficiency, by introducing mutations after the initiation codon of the E. coli
dihydrofolate reductase
(
DHFR
) gene, considering codon and base biases, and using in vitro and in vivo translation systems. In both assay systems, the two most frequent second codons,
AAA
and AAU, enhanced the translation efficiency compared with the wild type, whereas the effects of lower frequency codons were not significant. Experiments using 16S rRNA variants with mutations in the putative complementary sequence to the region downstream of the initiation codon showed that the translation efficiency of none of the
DHFR
mutants was affected. These results demonstrate that the statistically most frequent sequences for the second codon enhance translation efficiency, and this effect seems to be independent of base pairing between mRNA and 16S rRNA.
...
PMID:Codon and base biases after the initiation codon of the open reading frames in the Escherichia coli genome and their influence on the translation efficiency. 1138 98
The sudden increase in information derived from the completed Mycobacterium tuberculosis (Mtb) genome sequences has revealed the need for approaches capable of converting raw genome sequence data into functional information. To date, an experimental system for studying protein-protein association in mycobacteria is not available. We have developed a simple system, termed mycobacterial protein fragment complementation (M-PFC), that is based upon the functional reconstitution of two small murine
dihydrofolate reductase
domains independently fused to two interacting proteins. Using M-PFC, we have successfully demonstrated dimerization of yeast GCN4, interaction between Mtb KdpD and KdpE, and association between Esat-6 and Cfp-10. We established the association between the sensor kinase, DevS, and response regulator, DevR, thereby demonstrating the potential of M-PFC to study protein associations in the mycobacterial membrane. To validate our system, we screened an Mtb library for proteins that associate with the secreted antigen Cfp-10 and consistently identified Esat-6 in our screens. Additional proteins that specifically associate with Cfp-10 include Rv0686 and Rv2151c (FtsQ), a component and substrate, respectively, of the evolutionary conserved signal recognition pathway; and Rv3596c (ClpC1), an
AAA
-ATPase chaperone involved in protein translocation and quality control. Our results provide empirical evidence that directly links the Mtb specialized secretion pathway with the evolutionary conserved signal recognition and SecA/SecYEG pathways, suggesting they share secretory components. We anticipate that M-PFC will be a major contributor to the systematic assembly of mycobacterial protein interaction maps that will lead to the development of better strategies for the control of tuberculosis.
...
PMID:Dissecting virulence pathways of Mycobacterium tuberculosis through protein-protein association. 1684 84
The vast majority of mitochondrial proteins are synthesized in the cytosol and transported into the organelle in a largely, if not completely, unfolded state. The proper function of mitochondria thus depends on folding of several hundreds of proteins in the various subcompartments of the organelle. Whereas folding of proteins in the mitochondrial matrix is supported by members of several chaperone families, very little is known about folding of proteins in the intermembrane space (IMS). We targeted
dihydrofolate reductase
(
DHFR
) as a model substrate to the IMS of yeast mitochondria and analyzed its folding.
DHFR
can fold in this compartment, and its aggregation upon heat shock can be prevented in an ATP-dependent manner. Yme1, an
AAA
(ATPases associated with diverse cellular activities) protease of the IMS, prevented aggregation of
DHFR
. Analysis of protein aggregates in mitochondria lacking Yme1 revealed the presence of a number of proteins involved in the establishment of mitochondrial ultrastructure, lipid metabolism, protein import, and respiratory growth. These findings explain the pleiotropic effects of deletion of YME1 and suggest an important role for Yme1 as a folding assistant, in addition to its proteolytic function, in the protein homeostasis of mitochondria.
...
PMID:Role of the AAA protease Yme1 in folding of proteins in the intermembrane space of mitochondria. 2299 11
Multiple-site-specific incorporation of a noncanonical amino acid into a recombinant protein would be a very useful technique to generate multiple chemical handles for bioconjugation and multivalent binding sites for the enhanced interaction. Previously combination of a mutant yeast phenylalanyl-tRNA synthetase variant and the yeast phenylalanyl-tRNA containing the
AAA
anticodon was used to incorporate a noncanonical amino acid into multiple UUU phenylalanine (Phe) codons in a site-specific manner. However, due to the less selective codon recognition of the
AAA
anticodon, there was significant misincorporation of a noncanonical amino acid into unwanted UUC Phe codons. To enhance codon selectivity, we explored degenerate leucine (Leu) codons instead of Phe degenerate codons. Combined use of the mutant yeast phenylalanyl-tRNA containing the CAA anticodon and the yPheRS_naph variant allowed incorporation of a phenylalanine analog, 2-naphthylalanine, into murine
dihydrofolate reductase
in response to multiple UUG Leu codons, but not to other Leu codon sites. Despite the moderate UUG codon occupancy by 2-naphthylalaine, these results successfully demonstrated that the concept of forced ambiguity of the genetic code can be achieved for the Leu codons, available for multiple-site-specific incorporation.
...
PMID:Forced Ambiguity of the Leucine Codons for Multiple-Site-Specific Incorporation of a Noncanonical Amino Acid. 2702 6
Evolutionary trajectories and mutational landscapes of drug-resistant bacteria are influenced by cell-intrinsic and extrinsic factors. In this study, I demonstrated that loss of the Lon protease altered susceptibility of
Escherichia coli
to trimethoprim and that these effects were strongly contingent on the drug concentration and genetic background. Lon, an
AAA
+
ATPase, is a bacterial master regulator protease involved in cytokinesis, suppression of transposition events, and clearance of misfolded proteins. I show that Lon deficiency enhances intrinsic drug tolerance at sub-MIC levels of trimethoprim. As a result, loss of Lon, though disadvantageous under drug-free conditions, has a selective advantage at low concentrations of trimethoprim. At high drug concentrations, however, Lon deficiency is detrimental for
E. coli
I show that the former is explained by suppression of drug efflux by Lon, while the latter can be attributed to SulA-dependent hyperfilamentation. On the other hand, deletion of
lon
in a trimethoprim-resistant mutant
E. coli
strain (harboring the Trp30Gly
dihydrofolate reductase
[
DHFR
] allele) directly potentiates resistance by enhancing the
in vivo
stability of mutant
DHFR
. Using extensive mutational analysis at 3 hot spots of resistance, I show that many resistance-conferring mutations render
DHFR
prone to proteolysis. This trade-off between gaining resistance and losing
in vivo
stability limits the number of mutations in
DHFR
that can confer trimethoprim resistance. Loss of Lon expands the mutational capacity for acquisition of trimethoprim resistance. This paper identifies the multipronged action of Lon in trimethoprim resistance in
E. coli
and provides mechanistic insight into how genetic backgrounds and drug concentrations may alter the potential for antimicrobial resistance evolution.
IMPORTANCE
Understanding the evolutionary dynamics of antimicrobial resistance is vital to curb its emergence and spread. Being fundamentally similar to natural selection, the fitness of resistant mutants is a key parameter to consider in the evolutionary dynamics of antimicrobial resistance (AMR). Various intrinsic and extrinsic factors modulate the fitness of resistant bacteria. This study demonstrated that Lon, a bacterial master regulator protease, influences drug tolerance and resistance. Lon is a key regulator of several fundamental processes in bacteria, including cytokinesis. I demonstrated that Lon deficiency produces highly contingent phenotypes in
E. coli
challenged with trimethoprim and can expand the mutational repertoire available to
E. coli
to evolve resistance. This multipronged influence of Lon on drug resistance provides an illustrative instance of how master regulators shape the response of bacteria to antibiotics.
...
PMID:Highly Contingent Phenotypes of Lon Protease Deficiency in Escherichia coli upon Antibiotic Challenge. 3174 Apr 90
