The extremely thermophilic bacterium Thermus thermophilus HB8, which belongs to the phylum DeinococcusThermus, has an open reading frame encoding a protein belonging to the cyclic AMP (cAMP) receptor protein (CRP) family present in many bacteria. The protein named T. thermophilus CRP is highly homologous to the CRP family proteins from the phyla Firmicutes, Actinobacteria, and Cyanobacteria, and it forms a homodimer and interacts with cAMP. CRP mRNA and intracellular cAMP were detected in this strain, which did not drastically fluctuate during cultivation in a rich medium. The expression of several genes was altered upon disruption of the T. thermophilus CRP gene. We found six CRP-cAMP-dependent promoters in in vitro transcription assays involving DNA fragments containing the upstream regions of the genes exhibiting de- Cyclic AMP (cAMP) receptor proteins (CRPs) are global transcriptional regulators broadly distributed in bacteria (30,72). The cellular roles of such CRP family proteins are diverse and include carbohydrate metabolism (3, 30), development of competence for transformation (8), modulation of virulence gene expression and pathogenesis (10,11,55,57,65), resuscitation (50), and germination and morphological development (13,49).Escherichia coli CRP controls the activity of over 100 genes and has been the most extensively studied so far (30, 72). This CRP was first named the catabolite gene-activating protein, since it induces the transcription of a number of genes in response to carbon source limitation (16,73). In the absence of a carbon source such as glucose, the intracellular cAMP level increases, resulting in the formation of a CRP-cAMP complex, which binds to specific DNA sequences at target promoters. The CRP-cAMP regulatory complex is also involved in the regulation of genes that are not directly related to catabolism (3). In addition, the complex acts as a negative regulator of transcription at cya gene promoter cyaP2, gal operon promoter galP2, crp gene promoter crpP, and deo operon promoter deoP2 (3). E. coli CRP is a dimer of two identical subunits, each 209 residues in length, and contains a helix-turn-helix DNA-binding motif in its C-terminal domain (40). Each subunit can bind one molecule of allosteric effector cAMP. This CRP undergoes a conformational change upon cAMP binding (21,66,67), and the CRP-cAMP complex interacts with a 22-bp DNA site exhibiting twofold symmetry, with the consensus sequence 5Ј-AAATGTGATCTAGATCACATTT-3Ј (15). Biochemical and genetic analyses have revealed that this CRP interacts with the C-terminal domain of the RNA polymerase (RNAP) ␣ subunit (␣CTD) (5,6,24,35,43,44,58). This interaction is thought to facilitate RNAP binding to the promoter, which leads to the formation of an open complex and induction of transcription initiation. Crystallographic studies on E. coli CRP have been performed to determine the structure of CRP-cAMP and the mechanisms underlying the interactions among CRP-cAMP, DNA, and RNAP ␣CTD (30, 34).CRP homologs have been found not only in othe...
The immutability of the genetic code has been challenged with the successful reassignment of the UAG stop codon to non-natural amino acids in Escherichia coli. In the present study, we demonstrated the in vivo reassignment of the AGG sense codon from arginine to l-homoarginine. As the first step, we engineered a novel variant of the archaeal pyrrolysyl-tRNA synthetase (PylRS) able to recognize l-homoarginine and l-N6-(1-iminoethyl)lysine (l-NIL). When this PylRS variant or HarRS was expressed in E. coli, together with the AGG-reading tRNAPylCCU molecule, these arginine analogs were efficiently incorporated into proteins in response to AGG. Next, some or all of the AGG codons in the essential genes were eliminated by their synonymous replacements with other arginine codons, whereas the majority of the AGG codons remained in the genome. The bacterial host's ability to translate AGG into arginine was then restricted in a temperature-dependent manner. The temperature sensitivity caused by this restriction was rescued by the translation of AGG to l-homoarginine or l-NIL. The assignment of AGG to l-homoarginine in the cells was confirmed by mass spectrometric analyses. The results showed the feasibility of breaking the degeneracy of sense codons to enhance the amino-acid diversity in the genetic code.
Background Validation and standardization of methodologies for microbial community measurements by high-throughput sequencing are needed to support human microbiome research and its industrialization. This study set out to establish standards-based solutions to improve the accuracy and reproducibility of metagenomics-based microbiome profiling of human fecal samples. Results In the first phase, we performed a head-to-head comparison of a wide range of protocols for DNA extraction and sequencing library construction using defined mock communities, to identify performant protocols and pinpoint sources of inaccuracy in quantification. In the second phase, we validated performant protocols with respect to their variability of measurement results within a single laboratory (that is, intermediate precision) as well as interlaboratory transferability and reproducibility through an industry-based collaborative study. We further ascertained the performance of our recommended protocols in the context of a community-wide interlaboratory study (that is, the MOSAIC Standards Challenge). Finally, we defined performance metrics to provide best practice guidance for improving measurement consistency across methods and laboratories. Conclusions The validated protocols and methodological guidance for DNA extraction and library construction provided in this study expand current best practices for metagenomic analyses of human fecal microbiota. Uptake of our protocols and guidelines will improve the accuracy and comparability of metagenomics-based studies of the human microbiome, thereby facilitating development and commercialization of human microbiome-based products.
Background: Photosynthetic eukaryotes have evolved through the acquisition of plastids by secondary endosymbiosis, a process that requires several steps. Immediately before plastid acquisition, the genome of the symbiont is known to be dramatically reduced, but few studies have focused on the genomic changes in the symbiont at the early stages of secondary endosymbiosis. Methods: To investigate the genetic basis of the transition from facultative to obligate endosymbiosis, we compared the genomes of Chlorella variabilis, a representative symbiotic alga, with that of Paramecium bursaria, to compare closely related free-living species and transcriptomes between organisms in symbiotic and non-symbiotic conditions. Results: We found that the non-reduced genome of C. variabilis and its genes play a crucial role in endosymbiosis, being involved in cell wall biogenesis and degradation, and metabolic exchanges with the host. Our results suggest that the genetic mechanism underlying the enhancement of photosynthesis under symbiosis is the increasing light absorption efficiency and carbon fixation capacity of the endosymbiont, resulting in an increase in the supply of maltose to P. bursaria.
Background: Photosynthetic eukaryotes have evolved through the acquisition of plastids by secondary endosymbiosis, a process that requires several steps. Immediately before plastid acquisition, the genome of the symbiont is known to be dramatically reduced, but few studies have focused on the genomic changes in the symbiont at the early stages of secondary endosymbiosis. Methods: To investigate the genetic basis of the transition from facultative to obligate endosymbiosis, we compared the genomes of Chlorella variabilis, a representative symbiotic alga, with that of Paramecium bursaria, to compare closely related free-living species and transcriptomes between organisms in symbiotic and non-symbiotic conditions. Results: We found that the non-reduced genome of C. variabilis and its genes play a crucial role in endosymbiosis, being involved in cell wall biogenesis and degradation, and metabolic exchanges with the host. Our results suggest that the genetic mechanism underlying the enhancement of photosynthesis under symbiosis is the increasing light absorption efficiency and carbon fixation capacity of the endosymbiont, resulting in an increase in the supply of maltose to P. bursaria.
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