Abstract
Cassava (Manihot esculenta Crantz) is a major source of dietary carbohydrates for >700 million people globally. However, its long breeding cycle has slowed the rate of genetic gain for target traits. This study aimed to asses genetic variation, the level of inbreeding, and trait correlations in genomic selection breeding cycles. We used phenotypic and genotypic data from the National Crops Resources Research Institute (NaCRRI) foundation population (Cycle 0, C(0)) and the progeny (Cycle 1, C(1)) derived from crosses of 100 selected C0 clones as progenitors, both to evaluate and optimize genomic selection. The highest broad-sense heritability (H (2) = 0.95) and narrow-sense heritability (h (2) = 0.81) were recorded for cassava mosaic disease severity and the lowest for root weight per plot (H (2) = 0.06 and h (2) = 0.00). We observed the highest genetic correlation (r (g)= 0.80) between cassava brown streak disease root incidence measured at seedling and clonal stages of evaluation, suggesting the usefulness of seedling data in predicting clonal performance for cassava brown streak root necrosis. Similarly, high genetic correlations were observed between cassava brown streak disease severity (r (g)= 0.83) scored at 3 and 6 mo after planting (MAP) and cassava mosaic disease, scored at 3 and 6 MAP (r (g)= 0.95), indicating that data obtained on these two diseases at 6 MAP would suffice. Population differentiation between C(0) and C(1) was not well defined, implying that the 100 selected progenitors of C(1) captured the diversity in the C(0). Overall, genetic gain for most traits were observed from C(0) to C(1).