Project description:F1 hybrids can outperform their parents in yield and vegetative biomass, features of hybrid vigor which form the basis of the hybrid seed industry. The yield advantage of the F1 is lost in the F2 and subsequent generations. In Arabidopsis, from F2 plants which have a F1 –like phenotype, we have by recurrent selection produced pure breeding F5/F6 lines “Hybrid Mimics”, in which the characteristics of the F1 Hybrid are stabilized. These Hybrid Mimic lines, like the F1 Hybrid, have larger leaves than the parent plant, the leaves having increased photosynthetic cell numbers, and in some lines increased size of cells, suggesting an increased supply of photosynthate. A comparison of the differentially expressed genes in the F1 Hybrid with those of eight Hybrid Mimic lines has identified metabolic pathways altered in both; these pathways include down regulation of defense response pathways and altered abiotic response pathways. F6 Hybrid Mimic lines are mostly homozygous at each locus in the genome yet retain the large F1-like phenotype. Many alleles in the F6 plants, when they are homozygous, have expression levels different to the level in the parent. We consider this altered expression to be a consequence of trans-regulation of genes from one parent by genes from the other parent. Transregulation could also arise from epigenetic modifications in the F1. The pure breeding Hybrid Mimics have been valuable in probing the mechanisms of hybrid vigor and may also prove to be useful hybrid vigor equivalents in agriculture.

Project description:F1 hybrids in Arabidopsis and crops species are uniform and high yielding. The F2 generation loses much of the yield advantage and the plants have heterogeneous phenotypes. We generated pure breeding Hybrid Mimic lines by recurrent selection and also selected a pure breeding Small phenotype line. The Hybrid Mimics are almost completely homozygous with chromosome segments from each parent. Four particular chromosomal segments from C24 and eight from Ler were present in all of the Hybrid Mimic lines whereas in the F6 Small phenotype line the 12 segments were each derived from the alternative parent. Loci critical for promoting hybrid vigor may be contained in each of these 12 conserved segments. We have identified genes with similar altered expression in Hybrid Mimics and F1 plants but not in the Small phenotype line. These genes may be critical for the generation of hybrid vigour. Analysis of transcriptomes indicated that increased expression of the transcription factor PHYTOCHROME-INTERACTING FACTOR (PIF4) may contribute to hybrid vigor by targeting the auxin biosynthesis gene YUCCA8 and the auxin signalling gene IAA29. A number of auxin responsive genes promoting leaf growth were upregulated in the F1 hybrids and Hybrid Mimics suggesting increased auxin biosynthesis and signaling contribute to the hybrid phenotype. The Hybrid Mimic seeds had earlier germination as did the seeds of the F1 hybrids indicating co-segregation of the genes for rosette size and the germination trait. Early germination may be an indicator of vigorous hybrids.

Project description:F1 hybrids can outperform their parents in yield and vegetative biomass, features of hybrid vigor which form the basis of the hybrid seed industry. The yield advantage of the F1 is lost in the F2 and subsequent generations. In Arabidopsis, from F2 plants which have a F1€“like phenotype, we have by recurrent selection produced pure breeding F5/F6 lines€œHybrid Mimics€, in which the characteristics of the F1 Hybrid are stabilized. These Hybrid Mimic lines, like the F1 Hybrid, have larger leaves than the parent plant, the leaves having increased photosynthetic cell numbers, and in some lines increased size of cells, suggesting an increased supply of photosynthate. A comparison of the differentially expressed genes in the F1 Hybrid with those of eight Hybrid Mimic lines has identified metabolic pathways altered in both; these pathways include down regulation of defense response pathways and altered abiotic response pathways. F6 Hybrid Mimic lines are mostly homozygous at each locus in the genome yet retain the large F1-like phenotype. Many alleles in the F6 plants, when they are homozygous, have expression levels different to the level in the parent. We consider this altered expression to be a consequence of trans-regulation of genes from one parent by genes from the other parent. Transregulation could also arise from epigenetic modifications in the F1. The pure breeding Hybrid Mimics have been valuable in probing the mechanisms of hybrid vigor and may also prove to be useful hybrid vigor equivalents in agriculture. Plant Materials: Seeds were sterilized and sown onto plates containing MSN medium (MS salts supplemented with 1% (w/v) sucrose, pH7 with KOH, 0.6% wt/vol Noble agar). After 2 days at 4°C, the plates were transferred to a growth room with conditions of 22°C/18°C (day/night) and 16h light/8h dark cycle under Philips Cool Daylight TLD 58W/840 fluorescent tubes providing a photosynthetic photon flux density of 130 - 150 umol photons m-2·s-1 as measured using a quantum meter (Model MQ-200 calibrated for electric light source, Apogee). At 18 days after sowing (DAS), the plants were transferred to soil and grown to the reproductive stage in a growth room with controlled light conditions (OSRAM L 36W/865 LumLux Daylight, 130 - 150 umol photons m-2·s-1). To minimize the edge effects, the positioning of both plates and trays on the shelves was rotated every two days. All the plants were grown under the condition described above unless specified. Plant sample preparation and RNA extraction: For the transcriptomes of 15 DAS plants, the aerial tissues of 15 day seedlings were sampled. For the transcriptomes of plants at 28 DAS, the four largest leaves of 28 day plants from the parental lines (C24, Ler), the reciprocal Hybrids and eight F4 Hybrid Mimic lines were harvested. Each sample comprised a pool of five plants. Two biological replicates of each sample were sequenced. Total RNA was isolated using QIAGEN RNeasy MiniKitTM following the product instructions. To eliminate variation in experimental conditions in different positions in the growth room, nine F4 plant lines were divided into two batches to ensure plants were grown on the same shelves in each experiment. Parental lines C24 and Ler and the F1 Hybrid from which the F4 lines derived from were grown under the same conditions in each experiment as controls. The first batch including samples C24 (RepA and RepB), Ler (RepA and RepB), C24 x Ler F1, F4-L1-1, F4-L1-2, F4-L2-1, F4-L2-2 and F4-S-1 were grown under the condition describe above, we also sampled the five smallest C24 seedlings and five smallest Ler seedlings among the population (n = 50); the mRNA sequencing was performed by the Australian Genome Research Facility (AGRF). The second batch including C24 (RepC and RepD), Ler (RepC and RepD), Ler x C24 F1 Hybrid, F4-L3-1, F4-L3-2, F4-L4-1 and F4-L4-2 were grown in the same light intensity as above but under different light tubes (SYLVANIA PREMIUM extra FL36W/865 Super Daylight deluxe light tube). For the transcriptome of the two F6 Hybrid Mimic lines at 15 DAS, C24, Ler, Ler x C24 F1 Hybrids and three siblings from each F6 line (L3-1-1-2 and L4-2-1-2) were grown on MS medium (MS salts supplemented with 1% (w/v) sucrose, pH 5.7 with KOH, add 0.6% wt/vol agar) with controlled light conditions (SYLVANIA PREMIUM extra FL36W/865 Super Daylight deluxe, 130 - 150 umol photons m-2·s-1). The mRNA sequencing service was provided by AGRF on the Illumina platform, 100bp paired ends.

Project description:F1 hybrids can outperform their parents in yield and vegetative biomass, features of hybrid vigor which form the basis of the hybrid seed industry. The yield advantage of the F1 is lost in the F2 and subsequent generations. In Arabidopsis, from F2 plants which have a F1 –like phenotype, we have by recurrent selection produced pure breeding F5/F6 lines “Hybrid Mimics”, in which the characteristics of the F1 Hybrid are stabilized. These Hybrid Mimic lines, like the F1 Hybrid, have larger leaves than the parent plant, the leaves having increased photosynthetic cell numbers, and in some lines increased size of cells, suggesting an increased supply of photosynthate. A comparison of the differentially expressed genes in the F1 Hybrid with those of eight Hybrid Mimic lines has identified metabolic pathways altered in both; these pathways include down regulation of defense response pathways and altered abiotic response pathways. F6 Hybrid Mimic lines are mostly homozygous at each locus in the genome yet retain the large F1-like phenotype. Many alleles in the F6 plants, when they are homozygous, have expression levels different to the level in the parent. We consider this altered expression to be a consequence of trans-regulation of genes from one parent by genes from the other parent. Transregulation could also arise from epigenetic modifications in the F1. The pure breeding Hybrid Mimics have been valuable in probing the mechanisms of hybrid vigor and may also prove to be useful hybrid vigor equivalents in agriculture. Plant Materials: Seeds were sterilized and sown onto plates containing MSN medium (MS salts supplemented with 1% (w/v) sucrose, pH7 with KOH, 0.6% wt/vol Noble agar). After 2 days at 4°C, the plates were transferred to a growth room with conditions of 22 °C/18 °C (day/night) and 16h light/8h dark cycle under Philips Cool Daylight TLD 58W/840 fluorescent tubes providing a photosynthetic photon flux density of 130 - 150μmol photons m-2·s-1 as measured using a quantum meter (Model MQ-200 calibrated for electric light source, Apogee). At 18 days after sowing (DAS), the plants were transferred to soil and grown to the reproductive stage in a growth room with controlled light conditions (OSRAM L 36W/865 LumLux Daylight, 130 - 150μmol photons m-2·s-1). To minimize the edge effects, the positioning of both plates and trays on the shelves was rotated every two days. All the plants were grown under the condition described above unless specified. Plant sample preparation and RNA extraction: For the transcriptomes of 15 DAS plants, the aerial tissues of 15 day seedlings were sampled. For the transcriptomes of plants at 28 DAS, the four largest leaves of 28 day plants from the parental lines (C24, Ler), the reciprocal Hybrids and eight F4 Hybrid Mimic lines were harvested. Each sample comprised a pool of five plants. Two biological replicates of each sample were sequenced. Total RNA was isolated using QIAGEN RNeasy MiniKitTM following the product instructions. To eliminate variation in experimental conditions in different positions in the growth room, nine F4 plant lines were divided into two batches to ensure plants were grown on the same shelves in each experiment. Parental lines C24 and Ler and the F1 Hybrid from which the F4 lines derived from were grown under the same conditions in each experiment as controls. The first batch including samples C24 (RepA and RepB), Ler (RepA and RepB), C24 x Ler F1, F4-L1-1, F4-L1-2, F4-L2-1, F4-L2-2 and F4-S-1 were grown under the condition describe above, we also sampled the five smallest C24 seedlings and five smallest Ler seedlings among the population (n = 50); the mRNA sequencing was performed by the Australian Genome Research Facility (AGRF). The second batch including C24 (RepC and RepD), Ler (RepC and RepD), Ler x C24 F1 Hybrid, F4-L3-1, F4-L3-2, F4-L4-1 and F4-L4-2 were grown in the same light intensity as above but under different light tubes (SYLVANIA PREMIUM extra FL36W/865 Super Daylight deluxe light tube). For the transcriptome of the two F6 Hybrid Mimic lines at 15 DAS, C24, Ler, Ler x C24 F1 Hybrids and three siblings from each F6 line (L3-1-1-2 and L4-2-1-2) were grown on MS medium (MS salts supplemented with 1% (w/v) sucrose, pH 5.7 with KOH, add 0.6% wt/vol agar) with controlled light conditions (SYLVANIA PREMIUM extra FL36W/865 Super Daylight deluxe, 130 - 150μmol photons m-2·s-1). The mRNA sequencing service was provided by AGRF on the Illumina platform, 100bp paired ends.

Project description:Hybrid breeding is of economic importance in agriculture for increasing yield, yet the basis of the heterosis is not well understood. In Arabidopsis, crosses between different accessions produce hybrids with varied levels of heterosis relative to parental phenotypes in biomass. In all hybrids the advantages of the F1 hybrid is lost in the F2 for both phenotypic uniformity and yield gain. Success in generating F5/F6 Hybrid Mimic from the cross between C24 and Landsberg erecta (Ler) demonstrated that the large plant phenotype of the F1 hybrids can be stabilized. Hybrid Mimics selection was applied to Wassilewskija (Ws)/Ler and Col/Ler hybrids. The two hybrids showing different levels of heterosis. At 30 DAS, the Col/Ler hybrid generated Hybrid Mimics with rosette diameter and fresh weight equivalent to the F1 hybrid; Ws/Ler Hybrid Mimics outperformed the F1 hybrids in both the rosette size and biomass. Transcriptome analysis revealed up-regulation of cell wall biosynthesis and expansion genes could be a common pathway in increased size in Arabidopsis hybrids and Hybrid Mimics. Intercross of two independent Hybrid Mimic lines can further increase the biomass gain. Our results encourage the use of Hybrid Mimics for breeding and for investigating the molecular basis of heterosis.

Project description:To obtain new insights for heterosis mechanisms in Arabidopsis, transcript profiling of arabidopsis F1 hybrid and their parentral lines was obtained from Affymetrix GeneChips ATH array. The microarray analysis exhibited that there were 44 up-regulated and 12 down-regulated genes with more than a 1.5-fold changes in the profiles of F1 hybrid against those of each parent. Gene ontology analyses highlighted up-regulated genes as organic nitrogen-related in the F1 hybrid.

Project description:Non-additive gene regulation has been recently suggested as an important factor promoting phenotypic variation and plasticity. In order to obtain a description of gene expression status at an early stage of ear development in a maize (Zea mays L.) F1 hybrid as relative to its parental inbreds, we compared gene expression profiles in immature ears of elite inbred lines B73 and H99 to one of their F1 hybrids (B73xH99) using cDNA microarray technology. Results show several genes expressed at a significantly different level between both inbred lines and their hybrid. In addition, gene expression non-additivity in the hybrid was detected on a broad scale, consisting of both dominance and over-dominance components, indicating that complex non-additive interactions at the molecular level exist in the developing ear of the studied maize hybrid. Non-additively regulated genes belong to a wide range of molecular functions, indicating that several regulatory and metabolic patterns are possibly affected during ear development in the investigated hybrid. We discuss the possibility that observed gene expression non-additivity in immature ear might be an early molecular manifestation of hybrid vigor, the most exploited factor for maize agronomic improvement.

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:Non-additive gene regulation has been recently suggested as an important factor promoting phenotypic variation and plasticity. In order to obtain a description of gene expression status at an early stage of ear development in a maize (Zea mays L.) F1 hybrid as relative to its parental inbreds, we compared gene expression profiles in immature ears of elite inbred lines B73 and H99 to one of their F1 hybrids (B73xH99) using cDNA microarray technology. Results show several genes expressed at a significantly different level between both inbred lines and their hybrid. In addition, gene expression non-additivity in the hybrid was detected on a broad scale, consisting of both dominance and over-dominance components, indicating that complex non-additive interactions at the molecular level exist in the developing ear of the studied maize hybrid. Non-additively regulated genes belong to a wide range of molecular functions, indicating that several regulatory and metabolic patterns are possibly affected during ear development in the investigated hybrid. We discuss the possibility that observed gene expression non-additivity in immature ear might be an early molecular manifestation of hybrid vigor, the most exploited factor for maize agronomic improvement. We directly contrasted both B73 and H99 inbred lines vs. their F1 heterotic hybrid transcriptomes in immature ear. Our experimental design consisted of 10 cDNA microarray hybridizations, 5 for each combination of hybrid vs. inbred genotypes, involving 20 separate labeling reactions. Labeling dyes were swapped in two of the five replicates for each combination. In each hybridization, control channel was assigned to the F1 hybrid, and differences in transcriptional levels between B73 and H99 were inferred using the hybrid as a common reference sample in an indirect experimental design. To take in account variability in transcript population among individuals, total RNA coming from different isolations, each collected on multiple individuals, were mixed before poly(A+) RNA purification. All hybridizations on microarray slides were then performed using cDNA independently labeled from the poly(A+) RNA purification product for each genotype. Base-two logarithms of expression ratios were subjected to one-class response significance analysis in SAM v. 2.20 software [Tusher et al. 2001]. For each EST the estimates of additive parameter "a" and dominance parameter "d" (middle-parent heterosis) were obtained as a = (L2 – L1)/2 d = (L1 + L2)/2 (where L1 and L2 are mean base-two logarithms of expression ratios of F1 vs. B73 and F1 vs. H99, respectively). Positive values of "a" indicate expression values bigger in B73 than in H99. The dominance/additivity ratio (d/|a|) was also calculated [Falconer 1989]. Evaluation of statistical significance of parameters was done by calculating standard errors of the estimates "a" and "d" as standard errors of linear functions of the means. Significance testing was done correspondingly, using an F-test for linear contrasts. P-values for the families of tests corresponding to each parameter were subjected to global error analyses using a method based on fitting mixture distribution [Allison et al. 2002], allowing to estimate the false discovery rates (FDR) and false negative rates (FNR). Confidence intervals for d/|a| ratios were obtained by Fieller’s method [Piepho and Emrich 2005], allowing to classify the genes into different dominance type classes.

Project description:Mechanism, inheritance patterns and biological significance remain unclear. Here, we generated genome-wide integrated maps of H3K27me3 modification and transcriptome for Col, C24 and their F1 hybrid, and their clf mutants. We found that H3K27me3 modification profiles were divergent between Col and C24, and were inherited mainly additively in hybrid. By comparing H3K27me3 modification ratio between parents to allelic H3K27me3 modification ratio in hybrid, we identified cis- and trans-regulatory divergence for H3K27me3 modification variation between Col and C24, and found that cis-regulatory divergence was the predominant contributor to H3K27me3 variation. The majority of genes with both cis- and trans-regulatory divergence displayed "cis-trans" interaction, whereas "cis+trans" interaction resulted in higher magnitude of H3K27me3 variation. H3K27me3 modification variation was negatively correlated with gene expression variation between Col and C24, both of which might rise from the same cis-regulatory divergence. Moreover, cis-regulatory divergence could lead to the concurrent allelic H3K27me3 modification bias and allelic gene expression bias for auxin metabolic genes and stimulus responsive genes in Col×C24 hybrid. Natural variation of H3K27me3 modification and gene expression were changed upon CLF mutation, and heterosis, especially best-parent hetereosis, was largely compromised in clf hybrid. Together, our study provided a comprehensive analysis of regulatory divergence for natural variation of histone modification and its association with differential gene expression between Arabidopsis accessions and growth vigor in hybrid.