22 research outputs found
Rice LGD1 containing RNA binding activity affects growth and development through alternative promoters
Tiller initiation and panicle development are important agronomical traits for grain production in Oryza sativa L. (rice), but their regulatory mechanisms are not yet fully understood. In this study, T-DNA mutant and RNAi transgenic approaches were used to functionally characterize a unique rice gene, LAGGING GROWTH AND DEVELOPMENT 1 (LGD1). The lgd1 mutant showed slow growth, reduced tiller number and plant height, altered panicle architecture and reduced grain yield. The fewer unelongated internodes and cells in lgd1 led to respective reductions in tiller number and to semi-dwarfism. Several independent LGD1-RNAi lines exhibited defective phenotypes similar to those observed in lgd1. Interestingly, LGD1 encodes multiple transcripts with different transcription start sites (TSSs), which were validated by RNA ligase-mediated rapid amplification of 5′ and 3′ cDNA ends (RLM-RACE). Additionally, GUS assays and a luciferase promoter assay confirmed the promoter activities of LGD1.1 and LGD1.5. LGD1 encoding a von Willebrand factor type A (vWA) domain containing protein is a single gene in rice that is seemingly specific to grasses. GFP-tagged LGD1 isoforms were predominantly detected in the nucleus, and weakly in the cytoplasm. In vitro northwestern analysis showed the RNA-binding activity of the recombinant C-terminal LGD1 protein. Our results demonstrated that LGD1 pleiotropically regulated rice vegetative growth and development through both the distinct spatiotemporal expression patterns of its multiple transcripts and RNA binding activity. Hence, the study of LGD1 will strengthen our understanding of the molecular basis of the multiple transcripts, and their corresponding polypeptides with RNA binding activity, that regulate pleiotropic effects in rice
Rice LGD1 containing RNA binding activity affects growth and development through alternative promoters
Tiller initiation and panicle development are important agronomical traits for grain production in Oryza
sativa L. (rice), but their regulatory mechanisms are not yet fully understood. In this study, T-DNA mutant and
RNAi transgenic approaches were used to functionally characterize a unique rice gene, LAGGING GROWTH
AND DEVELOPMENT 1 (LGD1). The lgd1 mutant showed slow growth, reduced tiller number and plant height,
altered panicle architecture and reduced grain yield. The fewer unelongated internodes and cells in lgd1 led to
respective reductions in tiller number and to semi-dwarfism. Several independent LGD1-RNAi lines exhibited
defective phenotypes similar to those observed in lgd1. Interestingly, LGD1 encodes multiple transcripts with
different transcription start sites (TSSs), which were validated by RNA ligase-mediated rapid amplification of 5�
and 3� cDNA ends (RLM-RACE). Additionally, GUS assays and a luciferase promoter assay confirmed the
promoter activities of LGD1.1 and LGD1.5. LGD1 encoding a von Willebrand factor type A (vWA) domain
containing protein is a single gene in rice that is seemingly specific to grasses. GFP-tagged LGD1 isoforms were
predominantly detected in the nucleus, and weakly in the cytoplasm. In vitro northwestern analysis showed
the RNA-binding activity of the recombinant C-terminal LGD1 protein. Our results demonstrated that LGD1
pleiotropically regulated rice vegetative growth and development through both the distinct spatiotemporal
expression patterns of its multiple transcripts and RNA binding activity. Hence, the study of LGD1 will
strengthen our understanding of the molecular basis of the multiple transcripts, and their corresponding
polypeptides with RNA binding activity, that regulate pleiotropic effects in rice
A previously unknown maltose transporter essential for starch degradation in leaves
A previously unknown maltose transporter is essential for the conversion of starch to sucrose in Arabidopsis leaves at night. The transporter was identified by isolating two allelic mutants with high starch levels and very high maltose, an intermediate of starch breakdown. The mutations affect a gene of previously unknown function, MEX1. We show that MEX1 is a maltose transporter that is unrelated to other sugar transporters. The severe mex1 phenotype demonstrates that MEX1 is the predominant route of carbohydrate export from chloroplasts at night. Homologous genes in plants including rice and potato indicate that maltose export is of widespread significance
Starch Synthesis in Arabidopsis Is Achieved by Spatial Cotranscription of Core Starch Metabolism Genes1[W][OA]
Starch synthesis and degradation require the participation of many enzymes, occur in both photosynthetic and nonphotosynthetic tissues, and are subject to environmental and developmental regulation. We examine the distribution of starch in vegetative tissues of Arabidopsis (Arabidopsis thaliana) and the expression of genes encoding core enzymes for starch synthesis. Starch is accumulated in plastids of epidermal, mesophyll, vascular, and root cap cells but not in root proper cells. We also identify cells that can synthesize starch heterotrophically in albino mutants. Starch synthesis in leaves is regulated by developmental stage and light. Expression of gene promoter-β-glucuronidase fusion constructs in transgenic seedlings shows that starch synthesis genes are transcriptionally active in cells with starch synthesis and are inactive in root proper cells except the plastidial phosphoglucose isomerase. In addition, ADG2 (for ADPG PYROPHOSPHORYLASE2) is not required for starch synthesis in root cap cells. Expression profile analysis reveals that starch metabolism genes can be clustered into two sets based on their tissue-specific expression patterns. Starch distribution and expression pattern of core starch synthesis genes are common in Arabidopsis and rice (Oryza sativa), suggesting that the regulatory mechanism for starch metabolism genes may be conserved evolutionarily. We conclude that starch synthesis in Arabidopsis is achieved by spatial coexpression of core starch metabolism genes regulated by their promoter activities and is fine-tuned by cell-specific endogenous and environmental controls