Assessing variability in yield performance and nutritional quality of citron watermelon (citrullus lanatus var. citroides (L.H. Bailey) mansf. ex greb.) genotypes under drought conditions.
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Abstract
Research is needed to investigate the potential of Neglected Underutilized Crop Species
(NUCS) such as citron watermelon, to increase crop diversity and mitigate the effects of
prolonged drought because of climate change. Little is known about citron watermelon’s food
quality attributes (seed popping yield, nutritional value, and lignin content). In addition, there
is a need to understand the agro-morphological, physiological and biochemical characteristics
associated with drought tolerance in citron watermelon. Therefore, the objectives of this study
were: (1) to assess citron watermelon genotypes for food quality attributes (popping yield,
chewability and nutritive value) of seeds based on visual appearance, (2) to screen citron
watermelon accessions for drought tolerance using morphological and physiological traits, (3)
to study the root system architecture of citron watermelon accessions and identify droughtadaptive
root traits for cultivar improvement under water-stressed environments and (4) to
reveal how citron watermelon responds to combined stress (water deficit and high temperature)
with respect to growth, water status, reserve mobilization and metabolite partitioning at
seedling stage.
The first study determined whether citron watermelon seed’s nutrient composition and physical
properties are related to the visual appearance of seed coat. Brown and red-coloured seeds have
a higher popping yield than dark-coloured seeds with poor popping ability and are prone to
burning during roasting. Seed coat thickness was closely related to hemicellulose contents and
cellulose across all seed coat colours. High hemicellulose, cellulose and lignin contents were
found in dark and red seeds associated with thick seed coats and increased chewing strength
than white seeds. From a nutritional perspective, dark and red seeds were good sources of Cu,
Zn, nitrogen and sulfur than brown seeds. Dark and brown seeds were good Mg sources,
whereas dark and red seeds were vital sources of potassium.
The second study determined variation in drought tolerance among South African citron
watermelon landrace accessions for selection and use as genetic stock for drought-tolerance
breeding in this crop and closely related cucurbit crops such as sweet watermelon. The forty
citron watermelon accessions evaluated showed varying levels of drought tolerance based on
morphological and physiological traits. These allowed five distinct groupings, namely: A
(highly drought-tolerant), B (drought-tolerant), C (moderately drought tolerant), D (droughtsensitive)
and E (highly drought-sensitive) based on various drought tolerance indices. The
following accessions (WWM02, WWM-05, WWM-09, WWM-15, WWM-37(2), WWM-39,
WWM-41 (A), WWM-46, WWM-47, WWM-57, WWM-64, WWM-66, WWM-68 and
WWM-79) were categorized as highly-drought tolerant and accessions WWM-03, WWM-08,
WWM-14, WWM-21, WWM-33, WWM-35(1), WWM-35(2), WWM-67 and WWM-76 as
drought tolerant. These are useful genetic stocks for improving drought tolerance in this crop
and related cucurbit crops, including sweet watermelon.
The third study examined citron watermelon accessions’ root system architecture and identified
drought-adaptive root traits for cultivar improvement under water-stressed environments. The
study showed that plasticity and biomass allocation shift according to genotype, presumably to
optimise the use of limited resources. The study found significant phenotypic variation in root
architecture among citron watermelon accessions that may relate to differences in water uptake.
The following traits of root system architecture (RSA) (total root length, root system width,
convex hull area and total root volume) were associated with drought tolerance. Further, RSA
traits such as root dry mass and root shoot mass ratio were highly correlated with root branch
count, root system depth, total root length and leaf number. These traits are useful selection
criteria for breeding and developing water-efficient citron watermelon accessions for
cultivation in drought-prone environments.
The fourth study identified multiple abiotic stress-induced modifications in different
phytosterols (campesterol, sitosterol and stigmasterol) in the seedling axis (embryonic leaf and
root) of genetically distinct citron watermelon accessions. Detailed evaluation of phytosterols
was done and the effects of the changes observed in stressed plants were discussed.
Description
Doctoral Degree. University of KwaZulu-Natal, Pietermaritzburg.