[30] found that a major QTL for yield and yield-related traits located on chromosome 5 had the gene action of over-dominance. Fine-mapping of this QTL indicated that it consisted of two dominant loci linked in repulsion [28]. A similar pattern of gene action was found in our study. The two QTL for TGW were linked in repulsion on the long arm of rice chromosome 1, of which qTGW1.1 had an additive effect of 0.26 g and a partial dominance effect of 0.16 g, whereas qTGW1.2 had an additive effect of 0.62 g and a partial dominance effect of 0.43 g. When the two QTL were segregating

simultaneously in the BC2F6-II population, a residual additive effect of 0.27 g and an learn more over-dominance effect of 0.72 g were detected ( Table 3). Since the population used in this study was derived from a cross find more between the maintainer and restorer lines of a three-line hybrid rice, this result suggests that dominant QTL linked in repulsion might play important roles in the genetic control of heterosis in rice. This work was funded in part by the National High-Tech Research and Development Program (2012AA101102), the Chinese High-yielding Transgenic Program (2011ZX08001-004), and the Research Funding of the China National Rice Research Institute (2012RG002-3). “
“Population structure

is of great importance for maximizing yield in crops. Plant density acts as a key factor in regulating plant competition within the population and optimal plant densities are very important for efficient agronomic practice. Plant spacing varies with the growth of plants and the growing environments [1]. To date, diverse planting patterns, such as narrow spacing [2] and [3], wide–narrow rows [4], [5] and [6], and multiple-plant hill plots [7], have been developed in maize (Zea mays L.) in pursuit of high grain

yields under different growing conditions. Studies addressing the effects of plant spacing on yield have largely focused on improvement of above-ground canopy structure, resulting in photosynthetic rate increases via effective interception of solar radiation [3] and [6] P-type ATPase or better photosynthetic performance of ear leaves [7]. These strategies often result in reduction in plant competition for light resources at high planting densities. However, individual plants always compete for nutrition, water and root space [8], and few reports are available regarding root nutrient absorption under different plant spacings. The fibrous root system of maize radiates outward and more than 90% of the dry root weight in soil is distributed in the top 20 cm, and 60% in the soil region within 10 cm from each plant [9]. Mineral nutrient absorption by roots results in the formation of a nutritional gradient zone around each individual. When the nutritional gradient zones of neighboring plants overlap, nutrient concentration in the overlapped area remarkably decreases because of interactions between adjacent roots, resulting in reduced root absorption efficiency [10].