Abstract:
Maize is an important staple in Sub-Saharan Africa (SSA) but most varieties are low in
Provitamin-A (PVA) carotenoids, and the performance adversely affected by drought
stress. Development and adoption of PVA carotenoids-enriched drought-tolerant
Maize Synthetics (MS) could help improve maize yields and reduce vitamin A
deficiency in SSA. Marker Assisted Recurrent Selection (MARS) could be used to
improve the nutritional quality and resilience of maize. However, the effects of MARS
on carotenoid contents of MS and performance of the PVA carotenoids-enriched MS
in hybrid combinations and under drought stress have not been adequately
documented. The level of improvement of carotenoid content of MS using MARS,
combining ability and effects of drought stress on yield of PVA carotenoids-enriched
MS were evaluated.
Three selection cycles (C0, C1 and C2) of two MS (PVASYNHGA and PVASYNHGB)
each improved through MARS were crossed to generate nine Varietal-cross Hybrids
(VH). The genotypes [selection cycles, VH and a check (PVASYN13)] were evaluated
at Ikenne, Mokwa, Saminaka and Zaria using a 4×4 lattice design with four replicates.
The genotypes were also evaluated under Managed Drought Stress (MDS) at Ikenne
following standard procedures. Days to Silking (DS), Plant Height (PH, cm) and Ear
Aspect (EA) were measured and Grain Yield (GY, t/ha) was estimated. The α-
carotene, β-cryptoxanthin and β-carotene contents (μg/g) of grains were determined
using HPLC, and PVA content (μg/g) estimated. Data were analysed using descriptive
statistics and ANOVA at α0.05. Genetic gain/cycle, Mid-parent Heterosis (MPH),
Specific Combining Ability (SCA), General Combining Ability (GCA) and Drought
Tolerance Index (DTI, where DTI of 0–0.49=low, 0.50–0.69=moderate and 0.70–
1.0=high) were estimated.
Genotype and location effects were significant for GY, DS, PH, EA and PVA
carotenoids, while genotype×location effect was significant for DS, EA, β-carotene
and PVA. The GY, DS, PH, EA, α-carotene, β-cryptoxanthin, β-carotene and PVA
ranged from 3.7±0.3 (Ikenne) to 6.4±0.4 (Mokwa), 54.4±0.8 (Mokwa) to 63.0±0.8
(Zaria), 206.4±5.9 (Ikenne) to 222.5±8.0 (Saminaka), 2.4±0.2 (Saminaka) to 2.7±0.2
(Ikenne), 0.8±0.1 (Ikenne) to 1.0±0.1 (Mokwa), 2.4±0.3 (Ikenne) to 3.3±0.4 (Mokwa),
5.1±0.3 (Ikenne) to 6.5±0.8 (Mokwa) and 6.8±0.3 (Ikenne) to 8.7±0.8 (Mokwa),
respectively. The MARS increased β-carotene and PVA by 25.0% and 15.0%,
respectively in PVASYNHGA, and α-carotene by 5.0% in PVASYNHGB. Four VH
(PVASYNHGBC0/PVASYNHGAC0, PVASYNHGBC2/PVASYNHGAC0,
PVASYNHGBC0/PVASYNHGAC1 and PVASYNHGBC1/PVASYNHGAC2) had
significant MPH and SCA for GY. Only PVASYNHGBC0/PVASYNHGAC0 (4.0%),
PVASYNHGBC0/PVASYNHGAC2 (2.6%) and PVASYNHGBC0/PVASYNHGAC1
(2.3%) exhibited MPH for PVA. Three genotypes [PVASYNHGAC0 (0.7),
PVASYNHGAC1 (0.3) and PVASYNHGBC2 (0.1)] had significant GCA for GY,
while PVASYNHGAC2 (1.09) and PVASYNHGBC0 (1.27) had significant GCA for
PVA. Under MDS, significant genotypic differences were observed for GY and DTI.
Drought stress reduced GY by 31.4% (PVASYNHGBC1/PVASYNHGAC2) to 69.8%
(PVASYNHGBC1/PVASYNHGAC0). The four VH with MPH for GY out-yielded the
check by 12.7% to 16.4% and exhibited moderate to high DTI.
Marker-assisted recurrent selection improved carotenoid contents of PVASYNHGA
than PVASYNHGB. Genotypes PVASYNHGAC2 and PVASYNHGBC0 are suitable
for provitamin-A inbred line development. Drought stress reduced grain yield of theviii
maize synthetics but four varietal-cross hybrids (PVASYNHGBC0/PVASYNHGAC0,
PVASYNHGBC2/PVASYNHGAC0, PVASYNHGBC0/PVASYNHGAC1 and
PVASYNHGBC1/PVASYNHGAC2) were drought tolerant.