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Query: EC:3.2.1.31 (
beta-glucuronidase
)
7,680
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Glycine decarboxylase
is a mitochondrial enzyme complex, which is the site of photorespiratory CO2 and NH3 release. Although the proteins that constitute the complex are located within the mitochondria, because of their intimate association with photosynthesis their expression is controlled by light. Comparisons of the kinetics of mRNA accumulation between the small subunit of ribulose-1,5-bisphosphate carboxylase/oxygenase and the H-protein of
glycine decarboxylase
during the greening of etiolated Arabidopsis thaliana suggest that their expression is controlled in parallel. A genomic clone for the H-protein (gdcH) was isolated from Arabidopsis and sequenced. The upstream region from -856 to +62 was fused to the
beta-glucuronidase
(GUS) reporter gene, and this construct was transformed into tobacco. This 5' upstream regulatory region appears to control GUS expression in a manner very similar to that of the endogenous H-protein gene. Constructs with deletions in the 5' upstream region were transformed into tobacco. These deletions revealed that light-dependent and tissue-specific expression was largely controlled by a 259-bp region between -376 and -117 bp. This region contains several putative GT boxes with the GGTTAA consensus core sequence. Once these strong light-dependent elements were removed, a second level of control was revealed. In constructs in which the gdcH 5' regulatory region was shortened to -117 bp or less, there was more GUS activity in the roots than in the leaves, and in dark-grown plants than in light-grown plants. This suggests that more proximal control elements may be responsible for the constitutive low levels of gene expression noted in all nonphotosynthetic tissues.
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PMID:Light-dependent and tissue-specific expression of the H-protein of the glycine decarboxylase complex. 748 Mar 20
In Flaveria pringlei, a C3 plant, P protein of the glycine-cleavage system is encoded by a small gene family consisting of at least five transcriptionally active genes. We have cloned and sequenced two of these genes, gdcsPA and gdcsPB, and provide the first detailed report on the complete structure of eukaryotic gdcsP genes. Based on the lengths of exons and intervening sequences, the
P-protein
genes can be subdivided into two parts. In both cases the N-terminal region consists of one very long exon followed by a long intron. In contrast, the C-terminal parts show a complex mosaic structure of relatively small exons and introns. A highly conserved leucine-zipper motif was identified, which is supposed to participate in the assembly of the
glycine decarboxylase
multienzyme complex. The transcript derived from the gdcsPA sequence corresponds perfectly to a leaf cDNA isolated earlier. Reverse-transcriptase PCR experiments show that both genes are preferentially active in leaves. Stems contain distinctly less P protein mRNA and the relative level in roots is very low but still clearly detectable. In all three organs, but most significantly in roots, the gdcsPA transcript level is distinctly higher than that of gdcsPB. Analysis of promoter-
beta-glucuronidase
fusions in transgenic tobacco suggests that far-upstream elements enhance the transcriptional activity of both genes in leaves relative to stems. The analysis of distal gdcsPA promoter deletions reveals the presence of regulatory elements acting with a distinct organ preference and indicates their approximate location.
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PMID:Structure and expression analysis of the gdcsPA and gdcsPB genes encoding two P-isoproteins of the glycine-cleavage system from Flaveria pringlei. 852 30
The four component proteins of the
glycine decarboxylase
multienzyme complex (the P-, H-, T-, and L-proteins) comprise over one-third of the soluble proteins in mitochondria isolated from the leaves of C3 plants. Together with serine hydroxymethyltransferase,
glycine decarboxylase
converts glycine to serine and is the site of photorespiratory CO2 and NH3 release. The component proteins of the complex are encoded on nuclear genes with N-terminal presequences that target them to the mitochondria. The isolated complex readily dissociates into its component proteins and reassociates into the intact complex in vitro. Because of the intimate association between photosynthesis and photorespiration, the proteins of the complex are present at higher levels in leaves in the light. The expression of these genes is controlled at the transcriptional level and the kinetics of expression are closely related to those of the small subunit of Rubisco. Deletion analysis of fusions between the promoter of the H-protein of the complex and the reporter gene
beta-glucuronidase
in transgenic tobacco has identified a region responsible for the tissue specificity and light dependence of gene expression. Gel shift experiments show that a nuclear protein in leaves binds to this region.
Glycine decarboxylase
has proven to be an excellent system for studying problems in plant biochemistry ranging from protein-protein interactions to control of gene expression.
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PMID:Glycine decarboxylase: protein chemistry and molecular biology of the major protein in leaf mitochondria. 859 76
Mitochondrial serine hydroxymethyltransferase (SHMT), combined with
glycine decarboxylase
, catalyzes an essential sequence of the photorespiratory C2 cycle, namely, the conversion of two molecules of glycine into one molecule each of CO2, NH4+, and serine. The Arabidopsis (Arabidopsis thaliana) mutant shm (now designated shm1-1) is defective in mitochondrial SHMT activity and displays a lethal photorespiratory phenotype when grown at ambient CO2, but is virtually unaffected at elevated CO2. The Arabidopsis genome harbors seven putative SHM genes, two of which (SHM1 and SHM2) feature predicted mitochondrial targeting signals. We have mapped shm1-1 to the position of the SHM1 gene (At4g37930). The mutation is due to a G --> A transition at the 5' splice site of intron 6 of SHM1, causing aberrant splicing and a premature termination of translation. A T-DNA insertion allele of SHM1, shm1-2, and the F1 progeny of a genetic cross between shm1-1 and shm1-2 displayed the same conditional lethal phenotype as shm1-1. Expression of wild-type SHM1 under the control of either the cauliflower mosaic virus 35S or the SHM1 promoter in shm1-1 abrogated the photorespiratory phenotype of the shm mutant, whereas overexpression of SHM2 or expression of SHM1 under the control of the SHM2 promoter did not rescue the mutant phenotype. Promoter-
beta-glucuronidase
analyses revealed that SHM1 is predominantly expressed in leaves, whereas SHM2 is mainly transcribed in the shoot apical meristem and roots. Our findings establish SHM1 as the defective gene in the Arabidopsis shm1-1 mutant.
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PMID:The photorespiratory Arabidopsis shm1 mutant is deficient in SHM1. 1633 99
