Project description:Polyploidization as the consequence of 2n gamete formation is a prominent mechanism in plant evolution. Studying its effects on the genome and its expression has both basic and applied interest. We crossed two diploid (2n=2x=16) M. sativa plants, a subsp. falcata seed parent and a coerulea x falcata pollen parent that produce a mixture of n and 2n eggs and pollen, respectively. Such cross produced full-sib diploid and tetraploid (2n=4x=32) progenies, the latter being the result of bilateral sexual polyploidization (BSP). These unique materials allowed us to investigate the effects of BSP, and separating the effect of intraspecific hybridization from those of polyploidization by comparing 2x with 4x full sib progeny plants. SSR marker segregation demonstrated tetrasomic inheritance for all chromosomes but one, demonstrating that these neotetraploids are true autotetraploids. BSP brought about increased biomass, earlier flowering, higher seed set and weight, larger leaves with larger cells. Microarray analyses with M. truncatula gene chips showed that several hundred genes, related to diverse metabolic functions, changed their expression level as a consequence of polyploidization. In addition, cytosine methylation increased in 2x but not in 4x hybrids. Our results indicate that sexual polyploidization induce significant transcriptional novelty, possibly mediated in part by DNA methylation, and phenotypic novelty that can be at the base of improved adaptation and reproductive success of tetraploid M. sativa with respect to its diploid progenitor. These polyploidy-induced changes may have promoted the adoption of tetraploid alfalfa in agriculture. Gene expression analysis of leaves at the vegetative stage of two Medicago sativa genotypes (PG-F9 and 12P) compared with three F1 diploid lines and three F1 tetraploid lines originating from crossing PG-F9 x 12P. Three biological replicates were taken for each sample, resulting in a total of twenty-four samples.

Project description:Polyploidization is one of the effective ways to improve plant height and yield of rice (Oryza sativa L.). However, the molecular mechanism of regulation is not yet fully understood. Here, we investigated the agronomic traits of diploid (Balilla-2x) and tetraploid (Balilla-4x) of japonica rice variety Balilla. Compared with Balilla-2x, Balilla-4x exhibited significantly increased plant height, spike length and yield per plant. RNA-seq analysis of the leaves of Balilla-2x and Balilla-4x was performed and the results showed that the expression levels of yield related genes (e.g., STH1, OsYUC9, and OsDEP1) were significantly upregulated in Balilla-4x rice plants, these genes are related to plant height and panicle development. These results indicated that polyploidization changed the expression of genes related to agronomic traits such as plant height and spike length, thereby increasing rice yield. This study provides a further basis for understanding the yield of rice after polyploidization, and can serve as a new theoretical reference for breeding high-yielding rice varieties achieved.

Project description:By reciprocally crossing 2x and 4x C24 ecotype plants, we have generated 4 types of offspring with various ploidy (2x; 3x; 4x) or parent-of-origin genome dosage (3x from 4xper2x; 3x from 2xper4x). For each offspring generated, total RNA was extracted using Trizol from 8 seedlings 9 days after germination (developmental stage1.02, 2 leaves). Sample names: DIP diploid TET tetraploid TFE triploid female excess TME triplod male excess Experimenter name: Olivier Garnier Experimenter phone: 00-353-21-490-4028 Experimenter address: Plant molecular genetics lab, Dpt of Biochemistry, UCC Experimenter address: Lee Maltings Prospect row Experimenter zip/postal_code: Cork Experimenter country: Ireland Keywords: strain_or_line_design

Project description:By reciprocally crossing 2x and 4x C24 ecotype plants, we have generated 4 types of offspring with various ploidy (2x; 3x; 4x) or parent-of-origin genome dosage (3x from 4xper2x; 3x from 2xper4x). For each offspring generated, total RNA was extracted using Trizol from 8 seedlings 9 days after germination (developmental stage1.02, 2 leaves). Sample names:; DIP diploid; TET tetraploid; TFE triploid female excess; TME triplod male excess; Experimenter name: Olivier Garnier; Experimenter phone: 00-353-21-490-4028; Experimenter address: Plant molecular genetics lab, Dpt of Biochemistry, UCC; Experimenter address: Lee Maltings Prospect row; Experimenter zip/postal_code: Cork; Experimenter country: Ireland Experiment Overall Design: 11 samples were used in this experiment

Project description:Speciation via interspecific or intergeneric hybridization and polyploidization triggers genomic responses Examination of small RNA of diploid Parent, Tetraploid parent, F1 hybrid and hexaploid amhiploid. Four pools of plants for each sample

Project description:The systematic deep sequencing analysis provided a comprehensive understanding of the transcriptome complexity of 2n and 3n Fujian oyster. This information broadens our understanding of the mechanisms of C.angulata polyploidization and contributes to molecular and genetic research by enriching the oyster database. This is the first report on genome-wide transcriptional analysis of adductor muscle of diploid and triploid Fujian oyster and has demonstrated triploid oysters are morphologically almost identical to their diploid counterparts, but have faster growth, due to the reorientation of energetic allocation from gametogenesis to somatic investment. This study provides a foundation for further analysis of the gene expression patterns and signaling pathways which regulate the molecular mechanisms of diploid and triploid oyster.

Project description:The systematic deep sequencing analysis provided a comprehensive understanding of the transcriptome complexity of 2n and 3n Fujian oyster. This information broadens our understanding of the mechanisms of C.angulata polyploidization and contributes to molecular and genetic research by enriching the oyster database. This is the first report on genome-wide transcriptional analysis of adductor muscle of diploid and triploid Fujian oyster and has demonstrated triploid oysters are morphologically almost identical to their diploid counterparts, but have faster growth, due to the reorientation of energetic allocation from gametogenesis to somatic investment. This study provides a foundation for further analysis of the gene expression patterns and signaling pathways which regulate the molecular mechanisms of diploid and triploid oyster. Examination of 3 different samples, including diploid (DF and DM) and triplod(T) oyster.

Project description:WGBS was used to assess gene expression variation between 2X and 4X grape

Project description:RNA-seq was used to assess gene expression variation between 2X and 4X grape

Project description:Heterosis occurs where F1 offspring display superior characteristics to the parents. Heterosis is usually considered to result from crosses of genetically distinct (e.g. homozygous inbred) parents producing heterozygous F1 offspring. Most mechanistic models for heterosis require genetically heterozygous F1 hybrid offspring harbouring allelic diversity. Epigenetic or dosage models for heterosis could allow for heterosis effects in F1 offspring that display no allelic diversity with their parents. Reciprocal inter-ploidy crosses between diploid (2x) and tetraploid (4x) lines in the same genetic background generates genetically identical F1 triploids (3x). Such reciprocal F1 triploids differ according to whether the additional chromosome set is either maternally (maternal excess) or paternally inherited (paternal excess). Biomass accumulation and abiotic stress tolerance between the parental (2x and 4x) and reciprocal F1 triploid (3x) offspring of Arabidopsis thaliana accession C24 reveals a strong parental genome-dosage induced heterosis in the paternal-excess triploid F1 plants. In these F1 triploids, the circadian clock related genes CCA1 and TOC1, and the growth factors PIF4 and PIF5, display different expression levels compared to the non-heterotic maternal excess F1 triploid siblings. Whole transcriptome profiling reveals a paternal genome dosage effect on gene expression levels with strong enrichment for dysregulated abiotic stress-related genes in the paternal excess F1 triploids. This study demonstrates that heterosis can be triggered without allelic diversity in F1 triploid plants. Heterosis without heterozygosity in plants can be induced via an epigenetic “chromosome imprinting” like parental genome dosage effect requiring paternal transmission of an additional chromosome set