Improvement of abiotic stress adaptive traits in mulberry (Morus spp.): an update on biotechnological interventions
- PMID: 28669073
- PMCID: PMC5494030
- DOI: 10.1007/s13205-017-0829-z
Improvement of abiotic stress adaptive traits in mulberry (Morus spp.): an update on biotechnological interventions
Abstract
Mulberry (Morus spp.), being an economically important tree, is cultivated in China, India, Thailand, Brazil, Uzbekistan and other Countries across the globe, for its leaves to feed monophagous mulberry silkworm (Bombyx mori). The sustainability of silk industry is directly correlated with the production and continuous supply of high-quality mulberry leaves. In India, it is cultivated on large scale in tropical, sub-tropical and temperate regions under irrigated conditions for silkworm rearing. Drought, low temperature, high salinity and alkalinity, being experienced in widespread areas, are the major abiotic stresses, causing reduction in its potential foliage yield and quality. Further, climate change effects may worsen the productivity of mulberry in near future, not only in India but also across the globe. Although traditional breeding methods contributed immensely towards the development of abiotic stress-tolerant mulberry varieties, still there is lot of scope for implementation of modern genomic and molecular biology tools for accelerating mulberry genetic improvement programmes. This review discusses omics approaches, molecular breeding, plant tissue culture and genetic engineering techniques exploited for mulberry genetic improvement for abiotic stress tolerance. However, high-throughput biotechnological tools such as RNA interference, virus-induced gene silencing, epigenomics and genome editing tools need to be utilized in mulberry to accelerate the progress of functional genomics. The application of genomic tools such as genetic engineering, marker-assisted selection and genomic selection in breeding programmes can hasten the development of climate resilient and productive mulberry varieties leading to the vertical and horizontal expansion for quality silk production.
Keywords: Climate resilience; Functional genomics; Genomic tool; Marker-assisted selection; Transgenic mulberry.
Conflict of interest statement
All the authors declare that they have no conflict of interest.
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References
-
- Aggarwal RK, Udaykumar D, Hender PS, Sarkar A, Singh L. Isolation and characterization of six novel microsatellite markers for mulberry (Morus indica) Mol Ecol Notes. 2004;4:477–479. doi: 10.1111/j.1471-8286.2004.00718.x. - DOI
-
- Ahmad P, Sharma S, Srivastava PS. In vitro selection of NaHCO3 tolerant cultivars of Morus alba (Local and Sujanpuri) in response to morphological and biochemical parameters. Hort Sci (Prague) 2007;34(3):114–122.
-
- Akram M, Aftab F. Efficient micropropagation and rooting of king white mulberry (Morus macroura Miq.) var. laevigata from nodal explants of mature tree. Pak J Bot. 2012;44:285–289.
-
- Anil Kumar HV, Muralidhar TS, Munirajappa R. RAPD analysis of EMS mutagenised mulberry genotype RFS135. Schol J Biotech. 2012;1:1–7.
-
- Anis M, Faisal M, Singh SK. Micropropagation of mulberry (Morus alba L.) through in vitro culture of shoot tip and nodal explants. Plant Tiss Cult. 2003;13:47–51.
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