Variation of Macro- and Microelements, and Trace Metals in Spring Wheat Genetic Resources in Siberia

Western Siberia is one of the major spring wheat regions of Russia, cultivating over 7 Mha. The objective of the study was to evaluate the variation of macro- and microelements, and of trace metals in four distinct groups of genetic resources: primary synthetics from CIMMYT (37 entries), primary synthetics from Japan (8), US hard red spring wheat cultivars (14), and material from the Kazakhstan–Siberian Network on Spring Wheat Improvement (KASIB) (74). The experiment was conducted at Omsk State Agrarian University, using a random complete block design with four replicates in 2017 and 2018. Concentrations of 15 elements were included in the analysis: macroelements, Ca, K, Mg, P, and S; microelements, Fe, Cu, Mn, and Zn; toxic trace elements, Cd, Co, Ni; and trace elements, Mo, Rb, and Sr. Protein content was found to be positively correlated with the concentrations of 11 of the elements in one or both years. Multiple regression was used to adjust the concentration of each element, based on significant correlations with agronomic traits and macroelements. All 15 elements were evaluated for their suitability for genetic enhancement, considering phenotypic variation, their share of the genetic component in this variation, as well as the dependence of the element concentration on other traits. Three trace elements (Sr, Mo, and Co) were identified as traits that were relatively easy to enhance through breeding. These were followed by Ca, Cd, Rb, and K. The important biofortification elements Mn and Zn were among the traits that were difficult to enhance genetically. The CIMMYT and Japanese synthetics had significantly higher concentrations of K and Sr, compared to the local check. The Japanese synthetics also had the highest concentrations of Ca, S, Cd, and Mo. The US cultivars had concentrations of Ca as high as the Japanese synthetics, and the highest concentrations of Mg and Fe. KASIB’s germplasm had near-average values for most elements. Superior germplasm, with high macro- and microelement concentrations and low trace-element concentrations, was found in all groups of material included.

AAC Castle red spring wheat

AAC Castle, an awned hard red spring wheat (Triticum aestivum L.), cultivar, combines high grain yield and good agronomic characteristics with excellent resistance to leaf, stem, stripe rust, common bunt and loose smut. It also expressed tolerance to the orange wheat blossom midge. Based on 39 station years of data in the registration trials from 2014 to 2016, the grain yield of AAC Castle was about 17% higher than 5700PR but similar to the other checks. AAC Castle was significantly shorter than AAC Foray and CDC Terrain, but had similar lodging resistance and maturity. AAC Castle had higher test weight, protein concentration, falling number and flour yield than AAC Foray and CDC Terrain. AAC Castle is eligible for grade of the Canada Prairie Spring Red wheat market class.

AAC Perform red spring wheat

AAC Perform, an awned hard red spring wheat (Triticum aestivum L.) cultivar, combines high grain yield and good agronomic characteristics with excellent resistance to leaf, stem, and stripe rust. Based on 43 station years of registration trial data from 2017 to 2019, the grain yield of AAC Perform was about 6% higher than AAC Foray and about 12% over AAC Penhold. AAC Perform was significantly shorter than AAC Foray and had straw strength similar to AAC Penhold. It was about two days later maturing than AAC Foray. AAC Perform had similar test weight, smaller kernel size and lower protein concentration as compared with AAC Foray. AAC Perform had milling and baking quality suitable for grades of the Canada Prairie Spring Red wheat market class.

AAC Redberry Hard Red Spring Wheat

AAC Redberry hard red spring wheat (Triticum aestivum L.) has a grain yield significantly higher than the check cultivars Katepwa, and Lillian and is similar to Carberry. AAC Redberry matures in a similar number of days as Katewpa and Lillian, and is significantly earlier maturing than Carberry. AAC Redberry has an awned spike, and a low lodging score indicative of strong straw that is significantly lower than Katepwa and Lillian but significantly higher than Carberry. Plant stature is taller than Carberry, but shorter than Lillian and Katepwa. AAC Redberry expressed resistance to prevalent races of leaf rust, stem rust, yellow rust, loose smut, moderate resistance to common bunt and intermediate resistance to Fusarium head blight. AAC Redberry has quality attributes within the range of the check cultivars and is eligible for grades of Canada Western Red Spring wheat.