Project description:Senescence is genetically-controlled and activated in mature tissues during ageing. However, immature plant tissues also display senescence-like symptoms when continuously exposed to adverse energy-depleting conditions. We used detached dark-held immature inflorescences of Arabidopsis thaliana to understand the metabolic reprogramming occurring in immature tissues transitioning from rapid growth to precocious senescence. Macroscopic growth of the detached inflorescences rapidly ceased upon placement in water in the dark at 21M-BM-0C. Inflorescences were completely de-greened by 120 h of dark incubation and by 24 h had already lost 24% of their chlorophyll and 34% of their protein content. Comparative transcriptome profiling at 24 h revealed that inflorescences response at 24 h had a large carbon-deprivation component. Genes that positively regulate developmental senescence (ANAC092) and shade avoidance syndrome (PIF4 and PIF5) were up-regulated within 24 h. Mutations in these genes delayed de-greening of the inflorescences. Their up-regulation was suppressed in dark-held inflorescences by glucose treatment, which promoted macroscopic growth and development and inhibited de-greening of the inflorescences. Detached inflorescences held in the dark for 4 days were still able to re-initiat development to produce siliques upon being brought out to light indicating the transcriptional reprogramming at 24 h was adaptive and reversible. Our results suggest that the response of detached immature tissues to dark storage involves interactions between carbohydrate status sensing and light deprivation signaling and that the dark adaptive response of the tissues appears to utilize some of the same key regulators as developmental senescence. Detached arabidopsis inflorescences were harvested and either immediately snap-frozen in liquid nitrogen and stored at -80M-BM-0C, or placed at 21M-BM-0C on blotting paper moistened with water inside a 2-L black plastic container for RNA extraction and hybridization on Affymetrix microarrays. Ten inflorescences from 10 independent plants were pooled for each time point (0 h or 24 h).

Project description:Senescence is a developmental process and chlorophyll is an indicator of leaf senescene. In plants cytokinin plays a role in delaying leaf senescence. Chlorophyll degradation is tightly regulated during senescence and cytokinin might interplay in the chrorophyll degradation pathway to regulate leaf greening. we used microarray to study the differential gene expression during leaf senescence and inpresence of a synthetic cytokinin (6-benzyl adenine).

Project description:RNA polymerase IV-dependent siRNAs, usually 24 nt in length, function in the RNAdirected DNA methylation that is responsible for de novo methylation in plants. We analyzed 24 nt siRNAs in inflorescences and found that among the 20,200 24 nt siRNA clusters, the top 0.81% highly expressed clusters accounted for more than 68% of the 24 nt siRNA reads in inflorescences. We named the highly expressed siRNAs as billionaire siRNAs (bill-siRNAs) and the less-expressed siRNAs as pauper siRNAs (pau-siRNAs). The bill-siRNAs in inflorescences are mainly derived from the ovary. Female gametes produced more bill-siRNAs than male gametes. In embryos and seedlings developed from fertilized egg cells, the bill-siRNAs from gametes disappeared. The endosperm, which develops from the fertilized central cell, also contained no bill-siRNAs from gametes but did contain newly and highly expressed siRNAs produced in different regions. In contrast, bill-siRNAs from the ovaries were maintained in the seed coat. The biosynthesis of bill-siRNAs in various tissues and cells is dependent on OsRDR2 (RNA-dependent RNA polymerase 2) and Pol IV (DNA-dependent RNA polymerase IV). Similar to the pau-siRNAs, the first base of bill-siRNAs is enriched at adenine, and bill-siRNAs can direct DNA methylation in various tissues.

Project description:RNA polymerase IV-dependent siRNAs, usually 24 nt in length, function in the RNAdirected DNA methylation that is responsible for de novo methylation in plants. We analyzed 24 nt siRNAs in inflorescences and found that among the 20,200 24 nt siRNA clusters, the top 0.81% highly expressed clusters accounted for more than 68% of the 24 nt siRNA reads in inflorescences. We named the highly expressed siRNAs as billionaire siRNAs (bill-siRNAs) and the less-expressed siRNAs as pauper siRNAs (pau-siRNAs). The bill-siRNAs in inflorescences are mainly derived from the ovary. Female gametes produced more bill-siRNAs than male gametes. In embryos and seedlings developed from fertilized egg cells, the bill-siRNAs from gametes disappeared. The endosperm, which develops from the fertilized central cell, also contained no bill-siRNAs from gametes but did contain newly and highly expressed siRNAs produced in different regions. In contrast, bill-siRNAs from the ovaries were maintained in the seed coat. The biosynthesis of bill-siRNAs in various tissues and cells is dependent on OsRDR2 (RNA-dependent RNA polymerase 2) and Pol IV (DNA-dependent RNA polymerase IV). Similar to the pau-siRNAs, the first base of bill-siRNAs is enriched at adenine, and bill-siRNAs can direct DNA methylation in various tissues.

Project description:RNA polymerase IV-dependent siRNAs, usually 24 nt in length, function in the RNAdirected DNA methylation that is responsible for de novo methylation in plants. We analyzed 24 nt siRNAs in inflorescences and found that among the 20,200 24 nt siRNA clusters, the top 0.81% highly expressed clusters accounted for more than 68% of the 24 nt siRNA reads in inflorescences. We named the highly expressed siRNAs as billionaire siRNAs (bill-siRNAs) and the less-expressed siRNAs as pauper siRNAs (pau-siRNAs). The bill-siRNAs in inflorescences are mainly derived from the ovary. Female gametes produced more bill-siRNAs than male gametes. In embryos and seedlings developed from fertilized egg cells, the bill-siRNAs from gametes disappeared. The endosperm, which develops from the fertilized central cell, also contained no bill-siRNAs from gametes but did contain newly and highly expressed siRNAs produced in different regions. In contrast, bill-siRNAs from the ovaries were maintained in the seed coat. The biosynthesis of bill-siRNAs in various tissues and cells is dependent on OsRDR2 (RNA-dependent RNA polymerase 2) and Pol IV (DNA-dependent RNA polymerase IV). Similar to the pau-siRNAs, the first base of bill-siRNAs is enriched at adenine, and bill-siRNAs can direct DNA methylation in various tissues.

Project description:RNA polymerase IV-dependent siRNAs, usually 24 nt in length, function in the RNAdirected DNA methylation that is responsible for de novo methylation in plants. We analyzed 24 nt siRNAs in inflorescences and found that among the 20,200 24 nt siRNA clusters, the top 0.81% highly expressed clusters accounted for more than 68% of the 24 nt siRNA reads in inflorescences. We named the highly expressed siRNAs as billionaire siRNAs (bill-siRNAs) and the less-expressed siRNAs as pauper siRNAs (pau-siRNAs). The bill-siRNAs in inflorescences are mainly derived from the ovary. Female gametes produced more bill-siRNAs than male gametes. In embryos and seedlings developed from fertilized egg cells, the bill-siRNAs from gametes disappeared. The endosperm, which develops from the fertilized central cell, also contained no bill-siRNAs from gametes but did contain newly and highly expressed siRNAs produced in different regions. In contrast, bill-siRNAs from the ovaries were maintained in the seed coat. The biosynthesis of bill-siRNAs in various tissues and cells is dependent on OsRDR2 (RNA-dependent RNA polymerase 2) and Pol IV (DNA-dependent RNA polymerase IV). Similar to the pau-siRNAs, the first base of bill-siRNAs is enriched at adenine, and bill-siRNAs can direct DNA methylation in various tissues.

Project description:Many flowering plants attract pollinators by offering a reward of floral nectar. Remarkably, the molecular events involved in the development of nectaries, the organs that produce nectar, as well as the synthesis and secretion of nectar itself, are poorly understood. Indeed, to date, no genes have been shown to directly affect the de novo production or quality of floral nectar. To address this gap in knowledge, the ATH1 Affymetrix GeneChip array was used to systematically investigate the Arabidopsis nectary transcriptome to identify genes and pathways potentially involved in nectar production. In this study, we identified a large number of genes differentially expressed between secretory lateral nectaries and non-secretory median nectary tissues, as well as between mature lateral nectaries (post-anthessis) and immature lateral nectary tissue (pre-anthesis). Three different types of RNA samples were prepared from Arabidopsis thaliana ecotype Columbia-0 nectaries: mature lateral nectaries (MLN; Stage 14-15 flowers), immature lateral nectaries (ILN, Stage 11-12 flowers), and mature median nectaries (MMN, Stage 14-15 flowers) [developmental stages defined by (Smyth et al., 1990)]. MLN are secretory tissues, whereas, ILN and MMN are pre-secretory and nonsecretory tissues, respectively. All nectary tissues were separately dissected by hand from the flowers of primary inflorescences of ca. 30-35 day-old plants. All plants were grown in soil with a 16h light/8h dark light regimen. Due to the small size of nectaries, dissections took place over several days from 4-8 hours after dawn (h.a.d.).

Project description:Correlative controls (influences of one organ over another organ) of seeds over maternal growth are one of the most obvious phenotypic expressions of the trade-off between growth and reproduction. However, the underlying molecular mechanisms are largely unknown. Here, we characterize the physiological and molecular effects of correlative inhibition by seeds on Arabidopsis thaliana inflorescences, i.e. global proliferative arrest (GPA) during which all maternal growth ceases upon the production of a given number of seeds. We use laser-assisted microdissection and RNA-seq or Affymetrix GeneChip hybridizations to compare sterile growing, fertile growing and fertile arrested meristems or whole inflorescences. In shoot tissues, we detected the induction of stress- and senescence-related gene expression upon fruit production and GPA, and a drop in chlorophyll levels - suggestive of altered source-sink relationships between vegetative shoot and reproductive tissues. Levels of shoot reactive oxygen species, however, strongly decreased upon GPA - a phenomenon that is associated with bud dormancy in some perennials. Indeed, gene expression changes in arrested apical inflorescences after fruit removal resembled changes observed in axillary buds following release from apical dominance. This suggests that GPA represents a form of bud dormancy, and that dominance is gradually transferred from growing inflorescences to maturing seeds - allowing offspring control over maternal resources, simultaneously restricting offspring number.

Project description:Correlative controls (influences of one organ over another organ) of seeds over maternal growth are one of the most obvious phenotypic expressions of the trade-off between growth and reproduction. However, the underlying molecular mechanisms are largely unknown. Here, we characterize the physiological and molecular effects of correlative inhibition by seeds on Arabidopsis thaliana inflorescences, i.e. global proliferative arrest (GPA) during which all maternal growth ceases upon the production of a given number of seeds. We use laser-assisted microdissection and RNA-seq or Affymetrix GeneChip hybridizations to compare sterile growing, fertile growing and fertile arrested meristems or whole inflorescences. In shoot tissues, we detected the induction of stress- and senescence-related gene expression upon fruit production and GPA, and a drop in chlorophyll levels - suggestive of altered source-sink relationships between vegetative shoot and reproductive tissues. Levels of shoot reactive oxygen species, however, strongly decreased upon GPA - a phenomenon that is associated with bud dormancy in some perennials. Indeed, gene expression changes in arrested apical inflorescences after fruit removal resembled changes observed in axillary buds following release from apical dominance. This suggests that GPA represents a form of bud dormancy, and that dominance is gradually transferred from growing inflorescences to maturing seeds - allowing offspring control over maternal resources, simultaneously restricting offspring number.

Project description:Senescence is a developmental process and chlorophyll is an indicator of leaf senescene. In plants cytokinin plays a role in delaying leaf senescence. Chlorophyll degradation is tightly regulated during senescence and cytokinin might interplay in the chrorophyll degradation pathway to regulate leaf greening. we used microarray to study the differential gene expression during leaf senescence and inpresence of a synthetic cytokinin (6-benzyl adenine). third leaf of 30-day-old rice plant were selected and incubated for 72 hours in solution containing 6-BA in darkness. Control condition leaves were incubated in solution without 6-BA. Three sets of control versus 6-BA treated leaves were used for RNA extraction and hybridation on Affymatrix rice gene chip.