Mustard is an edible oilseed crop and its consumption ranks second after soybean oil in India. Mustard is cultivated in India during the Rabi season widely in regions of Rajasthan, Uttar Pradesh, Haryana, and Madhya Pradesh. Rapeseed-mustard is a member of the flowering plant family Brassicaceae or Cruciferae, in which a total of 338 genus and 3709 species are known so far.The Brassica family comprises 37 species, and 6 of these species are mainly domesticated. Three of these are Brassica rapa, Brassica nigra, and Brassica oleracea,which are diploids used as spices and vegetables.
September 1st 2022, 5:44:19 pm | 5 min read
Mustard is an edible oilseed crop and its consumption ranks second after soybean oil in India. Mustard is cultivated in India during the Rabi season widely in regions of Rajasthan, Uttar Pradesh, Haryana, and Madhya Pradesh. Rapeseed-mustard is a member of the flowering plant family Brassicaceae or Cruciferae, in which a total of 338 genus and 3709 species are known so far.The Brassica family comprises 37 species, and 6 of these species are mainly domesticated. Three of these are Brassica rapa, Brassica nigra, and Brassica oleracea,which are diploids used as spices and vegetables. The diploid and tetraploid (amphidiploid) species share genomes amongst themselves. Brassica juncea (AABB=36) and Brassica napus (AACC=38) are mainly used for cooking oil. These species are known by different names in different regions, as shown in figure 1, explaining the interspecific relationship among Brassica cultivated species. It can be understood that amphidiploid species developed from natural crossing between the progenitor diploid species.
Figure 1. TheTriangle of U, given by Nagaharu U in 1935, shows the relationship among diploid and amphidiploid species of Brassica.
The cultivated species are known to get affected adversely by many biotic and abiotic stresses and lack the resistance needed to curb against such factors, due to which productivity is poorly affected. Such problems impose a challenge to gain higher productivity even in unfavourable conditions. The crop wild species can be looked upon for solutions to such issues. Naturally occurring wild species are known for their resistance to many diseases andstressessuch as diseases, pests, drought, high temperature, salinity, etc. Using them for crop improvement can increase the productivity of mustard varieties. Isolation and transfer of such desirable genetic traits also lead to the gene pool's expansion.Thesebeneficial traits can be transferred from wild to cultivated species for elite germplasm development by using differentgene transfer methods. Cross-pollination occurring in nature also helps in exchanging of genetic materialamong species. Genetic variations of wild species can be used in many ways,such as genetic recombination, broadening ofthe genetic base in cultivated crops, transferring selected genes from wild to cultivated species, development of new plant types, development of hybrid species, cytoplasmic male sterile plants,as well as to understand the evolutionary pattern of diploid and polyploid species.
Gene transfer from wild mustard species to cultivated varieties is complex and time-consuming. This is achieved by various early breeding methods such as wide hybridization, somatic hybridization, embryo rescue and advanced techniques, viz. genome sequencing, transgenics, and genome editing. However, several difficulties are facedduring hybridization programs like difficulty in obtaining hybrid plants aftercrossing wild and cultivated species, production of a very small number of seeds/embryos, use of tedioustissue culture techniques, infertility in hybrid plants (sterility), chromosomal doubling using colchicine, chimeric plants, partial fertility in subsequent generations, cytoplasmic male sterile in plants, etc. Examples of successful gene transfer from wild species to increase crop quality and yield can be seen in many crops. Wild species have been used to transfer stem rust resistance in wheat; resistance against potato blight, leaf roll, and charcoal rot diseases in potato; fungus andnematode resistance in tomato; cyst nematode resistance and cold tolerance in gram. Many wild species have also been identified that can tolerate various biotic and abiotic stresses, the details of which are given in Table 1.
S.No. | Trait | Brassica Crop Wild Relatives | References |
---|---|---|---|
1 | Alternaria blight resistance | Brassica desnottesii, Diplotaxiserucoides, Camelina sativa, Diplotaxisberthautii, D. catholica, Sinapis alba | (Prakash & Bhat, 2007), (Narasimhulu et al., n.d.) |
2 | Aphid resistance | Brassica fruticulosa, Brassica incana, Brassica vilosa, Eruca sativa | (Singh et al., 1994) |
3 | White rustresistance | Diplotaxiserucoides, Camelina sativa, Lepidium sativum, Eruca vesicaria | (Prakash & Bhat, 2007) |
4 | Cabbage whiteflyresistance | Brassica incana, Brassica vilosa; Brassica spinosa, Brassica cretica | (Pelgrom et al., 2015) |
5 | Cabbage root flyresistance | Brassica incana, Brassica vilosa; Brassica macrocarpa | (Ellis et al., 1999) |
6 | Stem rotresistance | Brassica cretica, Brassica fruticulosa, Erucastrum gallicum | (Prakash & Bhat, 2007) |
7 | Resistance to Pod shattering | Brassica macrocarpa, Brassica hilerionis, Enarthocarpuslyratus | (Prakash & Bhat, 2007) |
8 | High erucic acid content | Brassica incana, Brassica vilosa, Brassica cretica, Crambeabyssinica | (Goering et al., 1965) |
9 | High oleic &linoleic acid content | Orychophragmus violaceous, Moricandia spp., Lepidium sativum | (Prakash & Bhat, 2007), (Goering et al., 1965) |
10 | Cytoplasmic male sterility | Moricandia arvensis, Diplotaxiserucoides, Diplotaxisberthautii, Brassica oxyrrhina | (Bhat et al., 2006, 2008; Prakash et al., 1998; Prakash & Chopra, 1990) |
Table 1:- Wild mustard species with their specific traits that can be used in crop improvement |
Figure 2: Photograph of some wild species of mustard that can be used in crop improvement.
All over the world many scientistshave successfully transferred some traits from wild mustard species to cultivated varieties. In addition, efforts are going on to transfer more desirable characteristics not available in the primary gene pool. The introgression lines are being developed for B. juncea, B. carinata and B. napus so that important traits can be transferred to the widely used cultivars. New improved varieties can be developed for crop improvement in mustard breeding through these strategies.
Pooja Garg, Shikha Tripathi, Anamika Kashyap, Jyoti Sharma, Sujata Kumari, Ranjeet Kushwaha, N.C. Gupta, Ashish Kumar, R.C. Bhattacharya, Mahesh Rao* ICAR- National Institute for Plant Biotechnology, Pusa Campus, New Delhi-110012