Lentil (Lens culinaris Medik.) is a nutritionally dense crop with significant quantities of protein, low-digestible carbohydrates, minerals, and vitamins. The amino acid composition of lentil protein can impact human health by maintaining amino acid balance for physiological functions and preventing protein-energy malnutrition and non-communicable diseases (NCDs). Thus, enhancing lentil protein quality through genetic biofortification, i.e., conventional plant breeding and molecular technologies, is vital for the nutritional improvement of lentil crops across the globe. This review highlights variation in protein concentration and quality across Lens species, genetic mechanisms controlling amino acid synthesis in plants, functions of amino acids, and the effect of antinutrients on the absorption of amino acids into the human body. Successful breeding strategies in lentils and other pulses are reviewed to demonstrate robust breeding approaches for protein biofortification. Future lentil breeding approaches will include rapid germplasm selection, phenotypic evaluation, genome-wide association studies, genetic engineering, and genome editing to select sequences that improve protein concentration and quality.
Productivity of chickpea (Cicer arietinum) under current climatic conditions is severely limited by water deficit and high temperatures, either alone or in combination. Breeding for improved tolerance, and increasing understanding of the physiological and biochemical mechanisms underlying tolerance, are imperative for achieving yield stabilisation. We evaluated 36 chickpea genotypes including 21 interspecific derivatives (from the cross C. arietinum ICCV96030 × C. pinnatifidum IC525200), their parents, 10 elite genotypes, and three checks (drought tolerant, heat tolerant, drought and heat susceptible) under three environments: timely sowing with irrigation, timely sowing with drought stress, and late sowing leading to heat stress. Four parameters were considered: seed yield, proline content, membrane permeability index, and relative leaf water content. Although the average seed yield plummeted under both stresses, the impact of high temperature was more pronounced. Mean leaf water content declined, whereas membrane permeability index and proline content increased, under both stresses. Leaf water content showed a significant positive correlation with seed yield under all environments, and thus can be employed as an early-stage screening strategy in breeding programs for developing stress tolerant genotypes. Based on estimated stress susceptibility indices for seed yield, derivative line GLW605 was identified as a promising donor for both drought and heat tolerance. Additionally, three derivative lines (GLW607, GLW649, GLW677) were found tolerant to drought, and one derivative line (GLW669) showed tolerance to heat alone. Yield levels of the identified lines were statistically on par with respective tolerant checks. Results suggest that tolerance to drought and heat was successfully introgressed from the wild species, C. pinnatifidum, into the cultivated background. The promising derivative lines can be employed for developing multi-stress tolerant cultivars.
A MANET is an autonomous collection of mobile users that communicate over relatively bandwidth restricted wireless links. Since the nodes in topology are mobile, the network might change rapidly and unpredictably with time. Due to mobility of nodes in a network, the path stability is disturbed and hence the link breakage occurs. In this paper, an estimated time based stable routing methodology is proposed with the help of flowchart, which further will improve breakage of link and hence the lifetime of the network will increase considerably.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.