Sarma Govinda Rai, Zunjare Rajkumar U, Muthusamy Vignesh, Kasana Ravindra K, Gopinath Ikkurti, Singh Bhavna, Pawar Godawari S, Sharma Neha, Duo Hriipulou, Chhabra Rashmi, Devlash Rakesh K, Guleria Satish K, Chinnusamy Viswanathan, Hossain Firoz
ICAR-Indian Agricultural Research Institute, New Delhi, India.
Vasantrao Naik Marathwada Krishi Vidyapeeth, Parbhani, Maharashtra, India.
J Appl Genet. 2025 Jun 9. doi: 10.1007/s13353-025-00975-3.
High plant density assumes significance for higher yield per unit area. However, reports on breeding for ideal plant architecture (IPA) in maize are limited due to lack of comprehensive characterization of germplasm. Here, we assessed genetic variation and identified inbreds for 14 plant architectural traits among 48 subtropical maize inbreds through multi-location analysis. Wide genetic variation for (i) stalk-related traits, viz., plant height (100.5-209.8 cm), ear height (26.4-106.3 cm), internode number (3.8-10.9), and internode length (8.1-15 cm); (ii) leaf-related traits, viz., leaf length (39.7-77.1 cm), leaf width (5.2-10.5 cm), leaf area (158.6-568.4 cm), leaf angle (18.4-84.6°), leaf orientation value (2.2-71.3), number of leaves above-ear (3.2-7.2), and husk number (5.7-14.4); and (iii) tassel-related traits, viz., tassel height (21.8-34.9 cm), number of tassel branches (3.9-16.6), and tassel branching angle (10.2-78.4°) were observed. All traits showed significant variation due to environment and genotype × environment interactions. Correlation analysis implied that narrow leaf angle would produce compact tassel as well (r = 0.53, p < 0.001). Internode number and leaf width (r = - 0.33, p = 0.031), number of leaves and leaf length (r = 0.42, p = 0.004), plant height and leaf length (r = 0.39, p = 0.005), and leaf length and tassel height (r = 0.44, p = 0.003) were also associated. HKI-1105, CML-568, BAUIM-4, and BAUIM-2 were the most stable and promising inbreds with IPA using three popular selection indices (AMMI-TGSI, WAASBY-I, and MTSI). These promising inbreds could serve as suitable donors for germplasm diversification, besides generating hybrid combinations for high plant density. This is the first comprehensive analysis to characterize sub-tropically adapted maize inbreds for plant architectural traits.
高种植密度对于提高单位面积产量具有重要意义。然而,由于缺乏对种质的全面表征,关于玉米理想株型(IPA)育种的报道有限。在此,我们通过多地点分析评估了48个亚热带玉米自交系中14个植株架构性状的遗传变异并鉴定出了自交系。观察到以下方面存在广泛的遗传变异:(i)与茎秆相关的性状,即株高(100.5 - 209.8厘米)、穗位高(26.4 - 106.3厘米)、节数(3.8 - 10.9)和节间长度(8.1 - 15厘米);(ii)与叶片相关的性状,即叶长(39.7 - 77.1厘米)、叶宽(5.2 - 10.5厘米)、叶面积(158.6 - 568.4平方厘米)、叶夹角(18.4 - 84.6°)、叶向值(2.2 - 71.3)、穗上叶数(3.2 - 7.2)和苞叶数(5.7 - 14.4);以及(iii)与雄穗相关的性状,即雄穗高度(21.8 - 34.9厘米)、雄穗分枝数(3.9 - 16.6)和雄穗分枝角度(10.2 - 78.4°)。所有性状均因环境以及基因型×环境互作表现出显著变异。相关性分析表明,窄叶夹角也会产生紧凑的雄穗(r = 0.53,p < 0.001)。节数与叶宽(r = -0.33,p = 0.031)、叶片数与叶长(r = 0.42,p = 0.004)、株高与叶长(r = 0.39,p = 0.005)以及叶长与雄穗高度(r = 0.44,p = 0.003)也存在关联。利用三种常用选择指数(AMMI - TGSI、WAASBY - I和MTSI),HKI - 1105、CML - 568、BAUIM - 4和BAUIM - 2是具有IPA的最稳定且最有前景的自交系。这些有前景的自交系除了能产生用于高种植密度的杂交组合外,还可作为种质多样化的合适供体。这是首次对适应亚热带的玉米自交系植株架构性状进行全面分析。
