Heterosis associated gene expression in maize embryos 6 days after fertilization exhibits additive, dominant and overdominant pattern

Abstract: Heterosis is important for conventional plant breeding and is intensively used to increase the productivity of crop plants. Genetic processes shortly after fertilization might be of particular importance with respect to heterosis, because coordination of the diverse genomes establishes a basis for future performance of the sporophyte. Here we demonstrate a strong crossbreeding advantage of hybrid maize embryos as early as 6 days after fertilization in a modern maize hybrid and provide the first embryo specific… Show more

“…For 66% of the genes that displayed nonadditive expression in microarray experiments, this difference from additivity was confirmed in qRT-PCR experiments. This confirmation rate was similar to the values obtained for maize seedlings (Swanson-Wagner et al 2006) where among 45 genes tested in qRT-PCR 31 were confirmed to be nonadditively expressed (69%), for maize embryos where 8 of 12 (67%) nonadditively expressed genes were confirmed via qRT-PCR (Meyer et al 2007), and for shoot apical meristems where 2 of 3 genes (67%) were confirmed via qRT-PCR (Uzarowska et al 2007).…”

“…A number of studies have compared gene expression profiles of inbred lines vs. hybrids in different maize organs and developmental stages, including embryos (Stupar and Springer 2006;Meyer et al 2007), endosperm (Guo et al 2003;Song and Messing 2003), whole seedlings (Stupar and Springer 2006;Swanson-Wagner et al 2006), immature ears (Guo et al 2006;Stupar and Springer 2006), adult leaves (Auger et al 2005), and shoot apical meristem (Uzarowska et al 2007). In addition to these studies in maize, the transcriptomes of the first Arabidopsis leaf (Vuylsteke et al 2005) and rice panicles (Huang et al 2006) have been analyzed.…”

“…Heterosis was first described by Charles Darwin (Darwin 1876) and independently rediscovered by Shull (1908) and East (1908). Heterosis is most evident for adult traits like plant biomass or yield but is also apparent during embryo (Meyer et al 2007) and early seedling development .…”

“…However, in some instances the apparent loss of gene colinearity might be due to the movement of genes or gene fragments by helitron transposons to other genomic regions and thus the contribution of noncolinear regions of the genome to heterosis is unclear (Lai et al 2005). Moreover, a number of studies have compared gene expression patterns of selected genes in inbred lines and hybrids (Song and Messing 2003;Auger et al 2005;Meyer et al 2007) or examined global gene expression analyses (Guo et al 2003(Guo et al , 2006Stupar and Springer 2006;Swanson-Wagner et al 2006;Uzarowska et al 2007) to test the hypothesis that nonadditive gene expression in hybrids is associated with heterosis (Song and Messing 2003). These studies differed significantly in their experimental design, analyzed plant tissues and developmental stages, genotypes, and statistical procedures, making it difficult to compare them.…”

“…Nonadditive gene expression patterns in hybrids are significantly different from the midparent value, while additive expression patterns are not. While in some studies additive gene expression was prevalent (Stupar and Springer 2006;SwansonWagner et al 2006;Meyer et al 2007), in other studies nonadditive gene expression (Uzarowska et al 2007) or a similar number of genes that provided additive and nonadditive expression (Guo et al 2006) prevailed. Although this discrepancy in global gene expression patterns might be related to the different experimental approaches this could also be an indication of different global expression patterns in different tissues and developmental stages that might nevertheless be related to heterosis (Hochholdinger and Hoecker 2007).…”

Comparison of Maize (Zea mays L.) F1-Hybrid and Parental Inbred Line Primary Root Transcriptomes Suggests Organ-Specific Patterns of Nonadditive Gene Expression and Conserved Expression Trends

“…For 66% of the genes that displayed nonadditive expression in microarray experiments, this difference from additivity was confirmed in qRT-PCR experiments. This confirmation rate was similar to the values obtained for maize seedlings (Swanson-Wagner et al 2006) where among 45 genes tested in qRT-PCR 31 were confirmed to be nonadditively expressed (69%), for maize embryos where 8 of 12 (67%) nonadditively expressed genes were confirmed via qRT-PCR (Meyer et al 2007), and for shoot apical meristems where 2 of 3 genes (67%) were confirmed via qRT-PCR (Uzarowska et al 2007).…”

“…A number of studies have compared gene expression profiles of inbred lines vs. hybrids in different maize organs and developmental stages, including embryos (Stupar and Springer 2006;Meyer et al 2007), endosperm (Guo et al 2003;Song and Messing 2003), whole seedlings (Stupar and Springer 2006;Swanson-Wagner et al 2006), immature ears (Guo et al 2006;Stupar and Springer 2006), adult leaves (Auger et al 2005), and shoot apical meristem (Uzarowska et al 2007). In addition to these studies in maize, the transcriptomes of the first Arabidopsis leaf (Vuylsteke et al 2005) and rice panicles (Huang et al 2006) have been analyzed.…”

“…Heterosis was first described by Charles Darwin (Darwin 1876) and independently rediscovered by Shull (1908) and East (1908). Heterosis is most evident for adult traits like plant biomass or yield but is also apparent during embryo (Meyer et al 2007) and early seedling development .…”

“…However, in some instances the apparent loss of gene colinearity might be due to the movement of genes or gene fragments by helitron transposons to other genomic regions and thus the contribution of noncolinear regions of the genome to heterosis is unclear (Lai et al 2005). Moreover, a number of studies have compared gene expression patterns of selected genes in inbred lines and hybrids (Song and Messing 2003;Auger et al 2005;Meyer et al 2007) or examined global gene expression analyses (Guo et al 2003(Guo et al , 2006Stupar and Springer 2006;Swanson-Wagner et al 2006;Uzarowska et al 2007) to test the hypothesis that nonadditive gene expression in hybrids is associated with heterosis (Song and Messing 2003). These studies differed significantly in their experimental design, analyzed plant tissues and developmental stages, genotypes, and statistical procedures, making it difficult to compare them.…”

“…Nonadditive gene expression patterns in hybrids are significantly different from the midparent value, while additive expression patterns are not. While in some studies additive gene expression was prevalent (Stupar and Springer 2006;SwansonWagner et al 2006;Meyer et al 2007), in other studies nonadditive gene expression (Uzarowska et al 2007) or a similar number of genes that provided additive and nonadditive expression (Guo et al 2006) prevailed. Although this discrepancy in global gene expression patterns might be related to the different experimental approaches this could also be an indication of different global expression patterns in different tissues and developmental stages that might nevertheless be related to heterosis (Hochholdinger and Hoecker 2007).…”

Comparison of Maize (Zea mays L.) F1-Hybrid and Parental Inbred Line Primary Root Transcriptomes Suggests Organ-Specific Patterns of Nonadditive Gene Expression and Conserved Expression Trends

Genetic Rules of Heterosis in Plants

Gene Expression and Heterosis in Maize Hybrids