Daniel M. Vernon scite author profile

Molecular mechanisms of osmotic stress tolerance were studied in Mesembryanthemum crystallinum (ice plant), a facultative halophyte capable of adjusting to and surviving in highly saline conditions. We screened a subtracted cDNA library enriched for salt stress‐induced mRNAs to identify transcripts involved in this plant's adaptation to salinity. One mRNA, Imt1, was found to be up‐regulated in leaves and, transiently, in roots. Nuclear run‐on assays indicated that this mRNA is transcriptionally regulated. Imt1 encoded a predicted polypeptide of M(r) 40,250 which exhibited sequence similarity to several hydroxymethyl transferases. Expression of the protein in Escherichia coli and subsequent activity assays identified the protein as a novel myoinositol O‐methyl transferase which catalyzes the first step in the biosynthesis of the cyclic sugar alcohol pinitol. Pinitol accumulates in salt‐stressed M.crystallinum and is abundant in a number of salt‐ and drought‐tolerant plants. The presence of high levels of sugar alcohols correlates with osmotolerance in a diverse range of organisms, including bacteria, fungi and algae, as well as higher plants. The stress‐initiated transcriptional induction of IMT1 expression in a facultative halophyte provides strong support for the importance of sugar alcohols in establishing tolerance to osmotic stress in higher plants.

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T-DNA-Associated Duplication/Translocations in Arabidopsis. Implications for Mutant Analysis and Functional Genomics

Tax

Vernon

2001

136

110

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(D.M.V.) T-DNA insertion mutants have become a valuable resource for studies of gene function in Arabidopsis. In the course of both forward and reverse genetic projects, we have identified novel interchromosomal rearrangements in two Arabidopsis T-DNA insertion lines. Both rearrangements were unilateral translocations associated with the left borders of T-DNA inserts that exhibited normal Mendelian segregation. In one study, we characterized the embryo-defective88 mutation. Although emb88 had been mapped to chromosome I, molecular analysis of DNA adjacent to the T-DNA left border revealed sequence from chromosome V. Simple sequence length polymorphism mapping of the T-DNA insertion demonstrated that a Ͼ40-kbp region of chromosome V had inserted with the T-DNA into the emb88 locus on chromosome I. A similar scenario was observed with a prospective T-DNA knockout allele of the LIGHT-REGULATED RECEPTOR PROTEIN KINASE (LRRPK) gene. Whereas wild-type LRRPK is on lower chromosome IV, mapping of the T-DNA localized the disrupted LRRPK allele to chromosome V. In both these cases, the sequence of a single T-DNA-flanking region did not provide an accurate picture of DNA disruption because flanking sequences had duplicated and inserted, with the T-DNA, into other chromosomal locations. Our results indicate that T-DNA insertion lines-even those that exhibit straightforward genetic behavior-may contain an unexpectedly high frequency of rearrangements. Such duplication/translocations can interfere with reverse genetic analyses and provide misleading information about the molecular basis of mutant phenotypes. Simple mapping and polymerase chain reaction methods for detecting such rearrangements should be included as a standard step in T-DNA mutant analysis.

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Arabidopsis emb175 and other ppr knockout mutants reveal essential roles for pentatricopeptide repeat (PPR) proteins in plant embryogenesis

Cushing

Forsthoefel

Gestaut

et al. 2005

Planta

133

110

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Pentatricopeptide repeat proteins (PPRPs) constitute one of the largest superfamilies in plants, with more than 440 identified in the Arabidopsis thaliana (L.) Heynh genome. While some PPRPs are known to take part in organelle gene expression, little is known about the broader biological contexts of PPRP gene function. Here, using developmental-and reverse-genetic approaches, we demonstrate that a number of PPRPs are essential early in plant development. We have characterized the Arabidopsis embryo-defective175 mutant and identified the EMB175 gene. Emb175 consistently displays aberrant cell organization and undergoes morphological arrest before the globular-heart transition. The emb175 mutation disrupts an intronless open reading frame encoding a predicted chloroplast-localized PPR protein-the first to be rigorously associated with an early embryo-lethal phenotype. To determine if other PPRP genes act in embryogenesis, we searched Arabidopsis insertion mutant collections for pprp knockout alleles, and identified 29 mutants representing 11 loci potentially associated with embryo-defective phenotypes. We assessed gene structures, T-DNA insertion position, and allelism for these loci and were able to firmly establish essential functions for six PPRP genes in addition to EMB175. Interestingly, Nomarski DIC microscopy revealed diverse embryonic defects in these lines, ranging from early lethality to dramatic late-stage morphological defects such as enlarged shoot apices and stunted cotyledons. Together, emb175 and these pprp knockout mutants establish essential roles for PPRPs in embryogenesis, thus broadening the known organismal context for PPRP gene function. The diversity of embpprp knockout phenotypes indicates that mutation of different PPRPs can, directly or indirectly, have distinct impacts on embryo morphogenesis.

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Embryogenic Transformation of the Suspensor in twin, a Polyembryonic Mutant of Arabidopsis

Vernon

Meinke

1994

Developmental Biology

140

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Substrates of the Arabidopsis thaliana Protein Isoaspartyl Methyltransferase 1 Identified Using Phage Display and Biopanning

Chen

Nayak

Majee

et al. 2010

Journal of Biological Chemistry

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The role of protein isoaspartyl methyltransferase (PIMT) in repairing a wide assortment of damaged proteins in a host of organisms has been inferred from the affinity of the enzyme for isoaspartyl residues in a plethora of amino acid contexts. The identification of PIMT target proteins in plant seeds, where the enzyme is highly active and proteome long-lived, has been hindered by large amounts of isoaspartate-containing storage proteins. Mature seed phage display libraries circumvented this problem. Inclusion of the PIMT co-substrate, S-adenosylmethionine (AdoMet), during panning permitted PIMT to retain aged phage in greater numbers than controls lacking co-substrate or when PIMT protein binding was poisoned with S-adenosyl homocysteine. After four rounds, phage titer plateaued in AdoMet-containing pans, whereas titer declined in both controls. This strategy identified 17 in-frame PIMT target proteins, including a cupin-family protein similar to those identified previously using on-blot methylation. All recovered phage had at least one susceptible Asp or Asn residue. Five targets were recovered independently. Two in-frame targets were produced in Escherichia coli as recombinant proteins and shown by onblot methylation to acquire isoAsp, becoming a PIMT target. Both gained isoAsp rapidly in solution upon thermal insult. Mutant analysis of plants deficient in any of three in-frame PIMT targets resulted in demonstrable phenotypes. An overrepresentation of clones encoding proteins involved in protein production suggests that the translational apparatus comprises a subgroup for which PIMT-mediated repair is vital for orthodox seed longevity. Impaired PIMT activity would hinder protein function in these targets, possibly resulting in poor seed performance.

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Daniel M. Vernon

A novel methyl transferase induced by osmotic stress in the facultative halophyte Mesembryanthemum crystallinum.

T-DNA-Associated Duplication/Translocations in Arabidopsis. Implications for Mutant Analysis and Functional Genomics

Arabidopsis emb175 and other ppr knockout mutants reveal essential roles for pentatricopeptide repeat (PPR) proteins in plant embryogenesis

Embryogenic Transformation of the Suspensor in twin, a Polyembryonic Mutant of Arabidopsis

Substrates of the Arabidopsis thaliana Protein Isoaspartyl Methyltransferase 1 Identified Using Phage Display and Biopanning

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