Christopher Johnston scite author profile

Christopher Johnston

5Publications

69Citation Statements Received

432Citation Statements Given

How they've been cited

How they cite others

276

407

Affiliations

University of North Texas, University of Aberdeen, Institute of Medical Sciences

Publications

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Operons Are a Conserved Feature of Nematode Genomes

Pettitt

Philippe

Sarkar

et al. 2014

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The organization of genes into operons, clusters of genes that are co-transcribed to produce polycistronic pre-mRNAs, is a trait found in a wide range of eukaryotic groups, including multiple animal phyla. Operons are present in the class Chromadorea, one of the two main nematode classes, but their distribution in the other class, the Enoplea, is not known. We have surveyed the genomes of Trichinella spiralis, Trichuris muris, and Romanomermis culicivorax and identified the first putative operons in members of the Enoplea. Consistent with the mechanism of polycistronic RNA resolution in other nematodes, the mRNAs produced by genes downstream of the first gene in the T. spiralis and T. muris operons are trans-spliced to spliced leader RNAs, and we are able to detect polycistronic RNAs derived from these operons. Importantly, a putative intercistronic region from one of these potential enoplean operons confers polycistronic processing activity when expressed as part of a chimeric operon in Caenorhabditis elegans. We find that T. spiralis genes located in operons have an increased likelihood of having operonic C. elegans homologs. However, operon structure in terms of synteny and gene content is not tightly conserved between the two taxa, consistent with models of operon evolution. We have nevertheless identified putative operons conserved between Enoplea and Chromadorea. Our data suggest that operons and “spliced leader” (SL) trans-splicing predate the radiation of the nematode phylum, an inference which is supported by the phylogenetic profile of proteins known to be involved in nematode SL trans-splicing.

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Resolution of polycistronic RNA by SL2trans-splicing is a widely conserved nematode trait

Wenzel

Johnston

Müller

et al. 2020

RNA

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Spliced leader trans-splicing is essential for the processing and translation of polycistronic RNAs generated by eukaryotic operons. In C. elegans, a specialized spliced leader, SL2, provides the 5 ′ ′ ′ ′ ′ end for uncapped pre-mRNAs derived from polycistronic RNAs. Studies of other nematodes suggested that SL2-type trans-splicing is a relatively recent innovation, confined to Rhabditina, the clade containing C. elegans and its close relatives. Here we conduct a survey of transcriptomewide spliced leader trans-splicing in Trichinella spiralis, a distant relative of C. elegans with a particularly diverse repertoire of 15 spliced leaders. By systematically comparing the genomic context of trans-splicing events for each spliced leader, we identified a subset of T. spiralis spliced leaders that are specifically used to process polycistronic RNAs-the first examples of SL2-type spliced leaders outside of Rhabditina. These T. spiralis spliced leader RNAs possess a perfectly conserved stem-loop motif previously shown to be essential for SL2-type trans-splicing in C. elegans. We show that genes transspliced to these SL2-type spliced leaders are organized in operonic fashion, with short intercistronic distances. A subset of T. spiralis operons show conservation of synteny with C. elegans operons. Our work substantially revises our understanding of nematode spliced leader trans-splicing, showing that SL2 trans-splicing is a major mechanism for nematode polycistronic RNA processing, which may have evolved prior to the radiation of the Nematoda. This work has important implications for the improvement of genome annotation pipelines in nematodes and other eukaryotes with operonic gene organization.

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Effective Mechanisms for Improving Seed Oil Production in Pennycress (Thlaspi arvense L.) Highlighted by Integration of Comparative Metabolomics and Transcriptomics

et al. 2022

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Pennycress is a potentially lucrative biofuel crop due to its high content of long-chain unsaturated fatty acids, and because it uses non-conventional pathways to achieve efficient oil production. However, metabolic engineering is required to improve pennycress oilseed content and make it an economically viable source of aviation fuel. Research is warranted to determine if further upregulation of these non-conventional pathways could improve oil production within the species even more, which would indicate these processes serve as promising metabolic engineering targets and could provide the improvement necessary for economic feasibility of this crop. To test this hypothesis, we performed a comparative biomass, metabolomic, and transcriptomic analyses between a high oil accession (HO) and low oil accession (LO) of pennycress to assess potential factors required to optimize oil content. An evident reduction in glycolysis intermediates, improved oxidative pentose phosphate pathway activity, malate accumulation in the tricarboxylic acid cycle, and an anaplerotic pathway upregulation were noted in the HO genotype. Additionally, higher levels of threonine aldolase transcripts imply a pyruvate bypass mechanism for acetyl-CoA production. Nucleotide sugar and ascorbate accumulation also were evident in HO, suggesting differential fate of associated carbon between the two genotypes. An altered transcriptome related to lipid droplet (LD) biosynthesis and stability suggests a contribution to a more tightly-packed LD arrangement in HO cotyledons. In addition to the importance of central carbon metabolism augmentation, alternative routes of carbon entry into fatty acid synthesis and modification, as well as transcriptionally modified changes in LD regulation, are key aspects of metabolism and storage associated with economically favorable phenotypes of the species.

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Comparative omics as a strategy for identifying biomarkers associated with oil production in pennycress

Johnston

2020

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Deep evolutionary origin of nematode SL2 trans-splicing revealed by genome-wide analysis of the Trichinella spiralis transcriptome

Wenzel

Johnston

Müller

et al. 2019

Preprint

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Spliced leader trans-splicing is intimately associated with the presence of eukaryotic operons, allowing the processing of polycistronic RNAs into individual mRNAs. Most of our understanding of spliced leader trans-splicing as it relates to operon gene expression comes from studies in C. elegans. In this organism, two distinct spliced leader trans-splicing events are recognised: SL1, which is used to replace the 5' ends of pre-mRNAs that have a nascent monomethyl guanosine cap; and SL2, which provides the 5' end to uncapped pre-mRNAs derived from polycistronic RNAs. Limited data on operons and spliced leader trans-splicing in other nematodes suggested that SL2-type trans-splicing is a relatively recent innovation, associated with increased efficiency of polycistronic processing, and confined to only one of the five major nematode clades, Clade V. We have conducted the first transcriptome-wide analysis of spliced leader trans-splicing in a nematode species, Trichinella spiralis, which belongs to a clade distantly related to Clade V. Our work identifies a set of T. spiralis SL2type spliced leaders that are specifically used to process polycistronic RNAs, the first examples of specialised spliced leaders that have been found outside of Clade V. These T. spiralis spliced leader RNAs possess a perfectly conserved stem-loop motif previously shown to be essential for polycistronic RNA processing in C. elegans. We show that this motif is found in specific sets of spliced leader RNAs broadly distributed across the nematode phylum. This work substantially revises our understanding of the evolution of nematode spliced leader trans-splicing, showing that the machinery for SL2 trans-splicing evolved much earlier during nematode evolution than was previously appreciated, and has been conserved throughout the radiation of the nematode phylum.

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