Project description:Mitochondrial (mt) gene sequences have been widely used to infer phylogeny in animals. The relative order of mt genes in the mitogenome can also be a useful marker for evolution, but the propensity of mt gene rearrangements vary tremendously among taxa. Ticks and mites in Acari exemplify this trend as some families retain the ancestral arthropod gene order, while others show highly divergent gene orders. Mites in Phytoseiidae, many of which are effective biological control agents, show some of the most divergent gene orders. However, the diversity of mitogenome order within this family is little known. We thus sequenced three mt genomes of phytoseiid mites from two of the most speciose genera: Amblyseius swirskii (Athias-Henriot), Amblyseius tsugawai (Ehara) and Neoseiulus womersleyi (Schicha). We find differences in mt GC skew and nucleotide composition, especially between N. womersleyi and the two Amblyseius species. Each species within Phytoseiidae (including three previously available sequences) present a unique gene order. Phytoseiid mitogenomes show some of the highest numbers of breakpoints when compared to the ancestral arthropod order (up to 33), as well as high numbers of breakpoints within the family (14-30). This suggests a history of massive, ongoing mitogenome rearrangements in the family. Phylogenetic analyses of mt sequences confirm that the degree of gene rearrangements follows phylogenetic relatedness. We discuss possible causes for the high degree of mt gene rearrangement within phytoseiid mites as well as selection in the mt and nuclear genome tied to the independent evolution of many diverse feeding strategies in the family. Finally, we suggest N. womersleyi should be used instead of the synonym Amblyseius pseudolongispinosus.

Project description:Many fungi restructured their proteomes through incorporation of serine (Ser) at thousands of protein sites coded by the leucine (Leu) CUG codon. How these fungi survived this potentially lethal genetic code alteration and its relevance for their biology are not understood. Interestingly, the human pathogen Candida albicans maintains variable Ser and Leu incorporation levels at CUG sites, suggesting that this atypical codon assignment flexibility provided an effective mechanism to alter the genetic code. To test this hypothesis, we have engineered C. albicans strains to misincorporate increasing levels of Leu at protein CUG sites. Tolerance to the misincorporations was very high, and one strain accommodated the complete reversion of CUG identity from Ser back to Leu. Increasing levels of Leu misincorporation decreased growth rate, but production of phenotypic diversity on a phenotypic array probing various metabolic networks, drug resistance, and host immune cell responses was impressive. Genome resequencing revealed an increasing number of genotype changes at polymorphic sites compared with the control strain, and 80% of Leu misincorporation resulted in complete loss of heterozygosity in a large region of chromosome V. The data unveil unanticipated links between gene translational fidelity, proteome instability and variability, genome diversification, and adaptive phenotypic diversity. They also explain the high heterozygosity of the C. albicans genome and open the door to produce microorganisms with genetic code alterations for basic and applied research.

Project description:BackgroundGenetic code alterations have been reported in mitochondrial, prokaryotic, and eukaryotic cytoplasmic translation systems, but their evolution and how organisms cope and survive such dramatic genetic events are not understood.ResultsHere we used an unusual decoding of leucine CUG codons as serine in the main human fungal pathogen Candida albicans to elucidate the global impact of genetic code alterations on the proteome. We show that C. albicans decodes CUG codons ambiguously and tolerates partial reversion of their identity from serine back to leucine on a genome-wide scale.ConclusionSuch codon ambiguity expands the proteome of this human pathogen exponentially and is used to generate important phenotypic diversity. This study highlights novel features of C. albicans biology and unanticipated roles for codon ambiguity in the evolution of the genetic code.

Project description:Cancer is driven by somatically acquired point mutations and chromosomal rearrangements, conventionally thought to accumulate gradually over time. Using next-generation sequencing, we characterize a phenomenon, which we term chromothripsis, whereby tens to hundreds of genomic rearrangements occur in a one-off cellular crisis. Rearrangements involving one or a few chromosomes crisscross back and forth across involved regions, generating frequent oscillations between two copy number states. These genomic hallmarks are highly improbable if rearrangements accumulate over time and instead imply that nearly all occur during a single cellular catastrophe. The stamp of chromothripsis can be seen in at least 2%-3% of all cancers, across many subtypes, and is present in ?25% of bone cancers. We find that one, or indeed more than one, cancer-causing lesion can emerge out of the genomic crisis. This phenomenon has important implications for the origins of genomic remodeling and temporal emergence of cancer.

Project description:When using a compacted version of the "I Ching" genetic code, the number of symbols is reduced to only 8 symbolic binary constants, integrated by only three symbols, being each: either the continuous or the broken horizontal line, plus the respective one word abbreviations of their resulting amino acids, namely, between four to eight accompanying the triad of lines, giving a total set of 46 possible combinations. This study is an alternate way of file compression for the genetic code, focused in the nucleotides, while another one I explored elsewhere, was focused in the groupings of amino acids, both individually and by their codon equivalents. As an Appendix 1 & 2 analogy, I add an example of "mutations" in literature, based on two early versions of "The Fair" (in its first edition of 1963, and in its first red edition of 1971), comparing its vignettes, and written in Spanish by my professor Juan José Arreola, now at his 101 year of birth.

Project description:The genetic code-the language used by cells to translate their genomes into proteins that perform many cellular functions-is highly conserved throughout natural life. Rewriting the genetic code could lead to new biological functions such as expanding protein chemistries with noncanonical amino acids (ncAAs) and genetically isolating synthetic organisms from natural organisms and viruses. It has long been possible to transiently produce proteins bearing ncAAs, but stabilizing an expanded genetic code for sustained function in vivo requires an integrated approach: creating recoded genomes and introducing new translation machinery that function together without compromising viability or clashing with endogenous pathways. In this review, we discuss design considerations and technologies for expanding the genetic code. The knowledge obtained by rewriting the genetic code will deepen our understanding of how genomes are designed and how the canonical genetic code evolved.

Project description: Not available

Project description:Poly(A) binding protein nuclear 1 (PABPN1) is a multifunctional regulator of mRNA processing. PABPN1 inhibits alternative polyadenylation (APA), and in conditions with reduced PABPN1 levels APA utilization causes genome-wide mRNA dysregulation. PABPN1 levels decline from midlife onwards in Oculopharyngeal Muscular Dystrophy (OPMD) and in aged muscles. Reduced PABPN1 levels cause muscle atrophy by altering mRNA levels of the ubiquitin proteasome system. The effect of PABPN1-mediated APA utilization on the proteome has not been investigated yet. We report the PABPN1-mediated proteome in Tibialis anterior (TA) mouse muscles, signifying functional impact for the mitochondria, cytoskeleton and translation cellular machineries. Central nucleation and split myofibers marked PABPN1-derived muscle histology. We show that up-regulation of the cytoskeletal proteins: Murc, Pfn1 and Csrp3, is highly associated with PABPN1-mediated muscle pathology and with reduced PABPN1 levels. Elevation of PABPN1 levels by sirtinol treatment reversed muscle pathology and restored levels of those cytoskeletal proteins. We suggest that restoration of PABPN1 levels in aged muscles could be a novel therapeutic strategy to mitigate muscle waste.

Project description:A dynamical theory for the evolution of the genetic code is presented, which accounts for its universality and optimality. The central concept is that a variety of collective, but non-Darwinian, mechanisms likely to be present in early communal life generically lead to refinement and selection of innovation-sharing protocols, such as the genetic code. Our proposal is illustrated by using a simplified computer model and placed within the context of a sequence of transitions that early life may have made, before the emergence of vertical descent.

Project description:Expanding the genetic code to enable the incorporation of unnatural amino acids into proteins in biological systems provides a powerful tool for studying protein structure and function. While this technology has been mostly developed and applied in bacterial and mammalian cells, it recently expanded into animals, including worms, fruit flies, zebrafish, and mice. In this review, we highlight recent advances toward the methodology development of genetic code expansion in animal model organisms. We further illustrate the applications, including proteomic labeling in fruit flies and mice and optical control of protein function in mice and zebrafish. We summarize the challenges of unnatural amino acid mutagenesis in animals and the promising directions toward broad application of this emerging technology.