P. B. Kirti

Transgenic Indian mustard (Brassica juncea) with resistance to the mustard aphid ( Lipaphis erysimi Kalt.)

Abstract. Wheat germ agglutinin (WGA), the chitin-binding lectin from wheat germ, has been shown to be antimetabolic, antifeedant and insecticidal to the mustard aphid (Lipaphis erysimi. Kalt). A cDNA encoding WGA was transferred to Indian mustard (Brassica juncea cv. RLM-198) through Agrobacterium-mediated transformation. Southern analysis of the transgenics showed the integration of the transgene, while Northern and Western analyses demonstrated that the transgene was expressed in the transgenics. Bioassays using leaf discs showed that feeding on transgenics induced high mortality and significantly reduced fecundity of aphids.

A Moricandia arvensis– based cytoplasmic male sterility and fertility restoration system in Brassica juncea

Abstract A cytoplasmic male-sterility system has been developed in mustard (Brassica juncea) following repeated backcrossings of the somatic hybrid Moricandia arvensis (2n=28, MM)+B. juncea (2n=36, AABB), carrying mitochondria and chloroplasts from M. arvensis, to Brassica juncea. Cytoplasmic male-sterile (CMS) plants are similar to normal B. juncea; however, the leaves exhibit severe chlorosis resulting in delayed flowering. Flowers are normal with slender, non-dehiscent anthers and excellent nectaries. CMS plants show regular meiosis with pollen degeneration occurring during microsporogenesis. Female fertility was normal. Genetic information for fertility restoration was introgressed following the development of a M. arvensis monosomic addition line on CMS B. juncea. The additional chromosome paired allosyndetically with one of the B. juncea bivalents and allowed introgression. The putative restorer plant also exhibited severe chlorosis similar to CMS plants but possessed 89% and 73% pollen and seed fertility, respectively, which subsequently increased to 96% and 87% in the selfed progeny. The progeny of the cross of CMS line with the restorer line MJR-15, segregated into 1 fertile : 1 sterile. The CMS (Moricandia) B. juncea, the restorer (MJR-15), and fertility restored F1 plants possess similar cytoplasmic organellar genomes as revealed by ‘Southern’ analysis.

Production of sodium-chloride-tolerant Brassica juncea plants by in vitro selection at the somatic embryo level

SummarySomatic embryos, developed from hypocotyl segments of light-grown seedlings of Brassica juncea cv RLM198, were subjected to selection at varying concentrations of sodium chloride (NaCl). Plants were developed from proliferated somatic embryos selected on NaCl-containing medium. The selections were characterized for salt tolerance, esterase isozyme pattern, and proline accumulation. It has been found that: (i) selected tolerant lines showed better root growth, shoot growth, and fresh weight accumulation on salt-containing medium when compared to the control; (ii) salt tolerance was transmitted to the next generation in seed progeny of tolerant plants grown in the absence of exposure to salt; (iii) both the starting material and the tolerant selections accumulated proline, even when grown in salt-free medium. On salt-containing medium, however, the differences in accumulated proline between the control and tolerant lines became more pronounced, and (iv) the patterns of esterase isozymes of two tolerant selections were similar but distinctly different from that of the parental control.

Transfer of Ogu cytoplasmic male sterility to Brassica juncea and improvement of the male sterile line through somatic cell fusion

Male sterility conferred by ogu cytoplasm of Raphanus sativus has been transferred to Brassica juncea cv ‘RLM 198’ from male-sterile B. napus through repeated backcrossing and selection. The male-sterile B. juncea is, however, highly chlorotic and late. It has low female (seed) fertility and small contorted pods. To rectify these defects, protoplasts of the male sterile were fused with normal ‘RLM 198’ (green, self fertile). Four dark green, completely male-sterile plants were obtained and identified as putative cybrids. All the plants were backcrossed three times with ‘RLM 198’. Mitochondrial and chloroplast DNA analysis of backcross progeny confirmed hybridity of the cytoplasm. The restriction pattern of the chloroplast DNA of progeny plants of three cybrids (Og 1, Og 2, Og 3) was similar to that of the green self-fertile ‘RLM 198’ and indicated that the correction of chlorosis resulted from chloroplast substitution. The chloroplast DNA of the lone progeny plant of the fourth cybrid (Og 10) could not be analyzed because the plant was stunted and had only a few leaves. When total cellular DNA was probed with mitochondrial probes coxI and atpA it was found that the cybrids had recombinant mitochondria. The chlorosis-corrected plants were early flowering and had vastly improved seed fertility.

Diplotaxis catholica + Brassica juncea somatic hybrids: molecular and cytogenetic characterization

SummaryIntergeneric somatic hybrids Diplotaxis catholica (2n=18) + Brassica juncea (2n=36) were produced by fusing mesophyll protoplasts of the former and hypocotyl protoplasts of the latter using polyethylene glycol. Out of 52 somatic embryos, 24 produced plants of intermediate morphology. Cytological analysis of 16 plants indicated that 15 were symmetric hybrids carrying 54 chromosomes, the sum of the parental chromosome numbers. One hybrid was asymmetric with 45 chromosomes. Nuclear hybridity of five putative hybrids was confirmed by the Southern hybridization pattern of full length 18s-25s wheat nuclear rDNA probe which revealed the presence of Hind III fragments characteristic of both the parental species. The hybridization pattern of mitochondria specific gene probe cox I indicated that three of the hybrids carried B. juncea mitochondria and one carried mitochondria of D. catholica. Presence of novel 3.5 kb Hind III and 4.8 kb Bgl II fragments suggested the occurrence of mtDNA recombination in one of the hybrids. The hybrids were pollen sterile. However, seeds were obtained from most of the hybrids by back crossing with B. juncea.

Cytoplasmic male sterility in alloplasmic Brassica juncea carrying Diplotaxis catholica cytoplasm: molecular characterization and genetics of fertility restoration

Abstract The present study was aimed at characterizing cytoplasmic male sterility (CMS) and identifying the fertility restorer gene for CMS (Diplotaxis catholica) Brassica juncea derived through sexual hybridization. The fertility restorer gene was identified by crossing the CMS line with progeny plants derived from somatic hybrids of B. juncea and D. cathoilca. The CMS line is comparable to the nuclear donor B. juncea in all respects except for flower and silique characteristics. In CMS plants, the flowers have smaller nectaries, and anthers are converted into petals or tubular structures. Gynoecium exhibits a crooked style and trilocular ovary. Seed fertility was reduced in the CMS line. Genetic segregation data indicated that a single, dominant, nuclear gene governs fertility restoration. Restored plants showed a high female fertility and lacked gynoecium abnormalities. In fertility-restored plants, petal development was found to be variable; some flowers had the normal number of four petals, while others had zero to three petals. Interestingly, the trilocular character of the ovary was found to co-segregate with CMS and became bilocular upon male-fertility restoration. Thus, this trait appears to be affected by the interaction of nuclear and mitochondrial (mt) genomes. Restriction fragment length polymorphism analysis indicated that mt-genome of D. catholica is highly divergent from that of B. juncea. However, in Northern analysis, out of eight mt genes studied, an altered transcript pattern was recorded for only atpA. In fertility-restored plants, the atpA transcript became shorter, thereby showing its association with CMS.

Chloroplast substitution overcomes leaf chlorosis in a Moricandia arvensis-based cytoplasmic male sterile Brassica juncea

Abstract A male sterile Brassica juncea line based on Moricandia arvensis cytoplasm was developed previously by backcrossing the somatic hybrid M. arvensis+B. juncea, and the gene for restoring fertility was introgressed. The CMS line is very severely chlorotic because of the presence of alien chloroplasts and flowering is delayed by 30–40 days, making it unsuitable for the exploitation of heterosis. We have resorted to another cycle of protoplast fusion between green fertile B. juncea and chlorotic male sterile B. juncea, and developed green male-sterile plants. Molecular analysis revealed that in green male-sterile plants chloroplasts of M. arvensis origin were substituted by those from B. juncea, giving rise to intergeneric cytoplasmic hybrids with mitochondria of M. arvensis origin. With the development of dark-green male-sterile plants, the CMS fertility restoration system is suitable for the production of hybrid mustard.

Random chloroplast segregation and mitochondrial genome recombination in somatic hybrid plants of Diplotaxis catholica+Brassica juncea

Abstract Detailed molecular analysis of the somatic hybrid plants of Diplotaxis catholica+B. juncea indicated random chloroplast segregation. One of the five hybrid plants analyzed derived its chloroplasts from D. catholica and two hybrids had chloroplasts of B. juncea origin. Two hybrid plants maintained mixed population of chloroplasts. The mitochondrial (mt) genomes of the fusion partners had undergone recombinations. Occurrence of fragments specific to both the parents in HindIII digestion followed by atp 9 probing, as in hybrid DJ5, provided evidence for intergenomic mitochondrial recombination between D. catholica and B. juncea. Similar mt genome organization in two hybrids (DJ3 and DJ6) suggested that intergenomic recombination may be preferred at specific sites. Hybrid DJ1 had about 70% similarity to D. catholica in mt genome organization. mt genomes of hybrids DJ2, 3, 5, and 6 differed from B. juncea by 14.3–28%. The significance of these novel mt genome organizations in developing novel male sterility systems is discussed.

Generation and characterisation of monosomic chromosome addition lines of Brassica campestris - B. oxyrrhina

Abstract Monosomic chromosome addition lines of Brassica oxyrrhina in the background of alloplasmic B. campestris carrying B. oxyrrhina cytoplasm were generated and characterised through morphology, cytology and molecular (RAPD) analysis. Four successive backcrosses of the synthetic alloploid B. oxycamp with B. campestris yielded 24 monosomic addition plants that were grouped into seven different synteny groups based on morphological similarity and RAPD patterns. Each synteny group exhibited morphological features diagnostic for the presence of individual B. oxyrrhina chromosomes including some novel phenotypes. Meiotic studies of the addition lines revealed the homoeology of four B. oxyrrhina chromosomes (synteny groups 1, 3, 5 and 6 ) with B. campestris chromosomes as indicated by trivalent associations, with the highest homoeology (44.23%) in synteny group 1 and the lowest (6.1%) in synteny group 3. Seed fertility of the addition lines ranged from 94.85% (synteny group 1) to 56.98% (synteny group 5). All of the addition lines were male-sterile except synteny group 6 which had 12–16% stainable pollen. Ovule transmission of the B. oxyrrhina chromosomes added to the progenies of addition lines ranged from 23.52% (synteny group 6) to 14% (synteny group 7). RAPD analysis confirmed the validity of synteny grouping based on morphological observations. Approximately 45% of the primers studied were informative, giving B. oxyrrhina-specific RAPD bands unique for each synteny group, except group 6.

Molecular Cloning and Characterization of FATTY ACID ELONGATION1 (BjFAE1) Gene of Brassica juncea

The Brassica juncea homologue of Arabidopsis thaliana FAE1 gene, which is responsible for elongation of fatty acid chain length from C18 to C20 and C22 was amplified via PCR (Polymerase Chain Reaction) using heterologous primers. The PCR product was cloned into pGEM-T vector, subcloned and sequenced. The BjFAE1 has 1536-nucleotides and shares 93.6% homology with the A. thaliana counterpart. Southern analysis, using the PCR product as probe, indicated that FAE1 gene is of the same size in all the cultivated Brassica species, i.e. B. juncea, B. nigra, B. campestris, B. oleracea, B. napus and B. carinata. It expresses strongly only in the developing seed and podwall.