Maize is an important global grain

Maize is an important global grain crop grown in Saudi Ara- bia basically as a component of feed. In a preliminary study,
El-Sharif (1986) showed the potential of maize production in the Kingdom and its role in food security. As a result, the annual hectare planted with this crop increased from more than 5000 hectare in the seventies to more than 15,000 hectare in the new millennium (CIMMYT, 2015). This increase was directly associated and supported with reclamation of mar- ginal lands, use of improved maize varieties, water irrigation and fertilizers. Despite this effort, demand for animal protein in the Kingdom continues to grow and requests for intensification of maize production. However water, an essential com- modity in farming, can hinder the self sufficiency goal simply because it may quick deplete if mismanaged. Additionally, water de?cit can occur at any stage of maize growth, but stress on maize at reproductive (mid-growth) stage was reported to cause the highest ever known grain loss (Atteya, 2003 and Ghooshchi et al., 2008). This observation leads Chapman et al. (1997) to state that selection for tolerance to mid- season drought stress would improve broad adaptation, and specific adaptation to drought environments. Decision on the genotypes that should be employed for improvement of crop yield under water deficit condition is critical to the success of the entire program. The good performance of varieties in a large number of yield trials simply indicates their relative superiority but does not necessarily reflect their ability to transmit the interesting character when crossed with a number of similar varieties. One of the suitable means to detect performance of offsprings is diallel mating system, a method whereby the parents and progeny performance can be statistically separated into components relating to GCA and SCA. Several methods for analysis have been adopted in which parents may be pure lines or open pollinated varieties. The analysis limited to the homozygous parents and F1 generation allows estimation of genetic parameters unbiased by link- age and assessment of dominance in the polygenic systems under study effects (Mather and Jinks, 1982). Combining ability analysis is employed to identify the better combiners which can be hybridized to exploit heterosis and to select better crosses for direct use or further breeding work. The ‘expected’ value of any particular cross, according to Allard (1960), is the sum of the GCA’s of its two parental lines, while the deviation from this expected value is called SCA. GCA values therefore describe the general usefulness of the parental form in terms of the concerned trait, whereas SCA indicates importance of the joint action of the genes of paren- tal forms (Baker, 1978). The occurrence of a considerable vari- ability in SCA effects for a given trait in the starting material for breeding is unfavorable because it increases the probability of obtaining hybrid progenies with an average value of that trait. The amount of improvement expected to come from GCA and SCA will be proportional to their variances (Griffing, 1956). The mean square ratio for GCA and SCA is employed to determine the prevailing gene actions (additive or non-additive) of a quantitative trait. The closer the ratio is to unity, the greater the performance of the progeny selected based on GCA values (Baker, 1978). There is no agreement among authors on the mode of gene action controlling maize yield or its related characters. It was reported by Nigussie and Zelleke (2001), Vacaro et al. (2002), El-Shouny et al. (2003) and Ojo et al. (2007) that additive genetic action was more important for maize traits suggesting for rapid improvement in selection. However Chaudhary et al. (2000) and Abdel-Moneam et al. (2009) showed that dominance gene effect was important in the inher- itance of maize characters. In addition, Nass et al. (2000) and Pswarayi and Vivek (2008), obtained significant (P < 0.05) GCA x E and SCA x E for almost all traits studied, an indi- cation of variation of general combining ability of lines under different environments. This study was designed to estimate the combining abilities of the inbreds and hybrids under three water regimes and determine effects of environments on expression of both GCA and SCA.