Chickpea (Cicer arietinum L.) is an indeterminate plant and produce excessive vegetative growth that acts as a competitive sink for developing pods resulting in reduced fruit set whenever soil moisture and temperature conditions are favorable. Determinate genotype was so far not available in the world chickpea germplasm. Determinate chickpea is needed to change its plant architecture in order to achieve a breakthrough in its productivity and stabilize yields in cool and long-season sub-tropical environments of semi-arid tropics. A true breeding determinate chickpea genotype was developed for the first time in the breeding programme. The objectives were to study: (i) the new found determinate genotype BGD 9971 for important plant characteristics and (ii) the genetics of determinate growth habit in it. Determinate genotype was bushy, compact and dwarf in its morphology; the stem growth terminated by a flower and produced 1-4 seeds per pod. The segregation patterns in the F 2 and F 3 of the two crosses (BGD 72 9 BGD 9971 and BGD 128 9 BGD 9971) involving indeterminate and determinate parents have shown that the determinate growth habit in BGD 9971 was governed by two recessive genes. The genes for determinacy in BGD 9971 were designated as dt1 and dt2. The homozygous recessive for both alleles (dt1dt1dt2dt2) produced a determinate phenotype. The utilization of genes identified for determinacy in the newly developed BGD 9971 has the major impact on chickpea breeding for better adaptation to cool climate, high fertility and irrigated environments.
Time of flowering is an important component of adaptation and productivity of chickpea (Cicer arietinum L.) in semi-arid environments characterized by terminal drought and heat stress. Genetics of flowering time was studied in late · early, early · late and early · early crosses under field conditions to obtain additional information on the number of genes involved and their allelic relationships. Results have shown that duplicate dominant genes with cumulative but unequal effect govern flowering time in chickpea. A genotype with two dominant alleles in homozygous or heterozygous conditions at both loci (Efl1,Efl2) control late flowering (41 days and above). A genotype with a dominant allele in homozygous or heterozygous condition at one of the loci and homozygous recessive allele at the other (Efl1,efl2) control earliness (26-40 days) and a genotype with homozygous recessive alleles at both loci (efl1,efl2) is responsible for super-earliness (<25 days). Influence of maternal genetic factors on the inheritance of flowering time was non-significant in chickpea.
Cowpea landraces belonging to Vigna unguiculata (L.) Walp. subsp. unguiculata cv.-gr. unguiculata and cv.-gr. sesquipedalis collected from part of the Deccan Plateau and West Coast of India were evaluated to (i) identify the diverse source(s) of variation for improved characters like pods/peduncle and seed index (ii) study the response of landraces for adaptation to drought and heat stress and (iii) understand the breeding value of a landrace in the genetic improvement of a popular cowpea cultivar. Landraces were evaluated for various morphological characters, pods/peduncle, seed index and other economically important agronomic traits, rust resistance and drought and heat tolerance in different years and environments. Landraces were found as an important source of genetic variability for pods/plant, pods/ peduncle, better pod filling ability (seed index), grain yield/plant as well as drought and heat tolerance and rust resistance. Hybridization between C 152 (cv.) and DWDCC 016 (landrace) resulted in release of new variation not present in the two parents. Thus the landrace, DWDCC 016, can be utilized to improve cultivated varieties by transferring to them the economically valuable traits like pods/peduncle and seed index thereby enhancing realisation of sink potential and ultimately grain yield in a sustainable way.
Simultaneous acquisition of detrital zircon Pb-Pb ages and trace element abundances from grains collected across the Indian craton, spanning ~3 b.y., reveals prominent shifts in Eu/ Eu* and light and middle to heavy rare earth element ratios. These shifts correspond to a ca. 3.0-2.2 Ga interval of crustal thickening during Indian craton formation, followed by a period wherein arc magmatism occurred along thinner craton margins from ca. 1.9 to 1.0 Ga, with arc magmatism concentrated along attenuated continental margins after ca. 1.0 Ga. Similar temporal shifts in trace element concentrations are recognized in global whole-rock compilations. We propose that the post-1.0 Ga increase in juvenile magmatism reflects a switch to lateral arc terrane accretion as the primary style of continental growth over the past billion years.
Key message A combinatorial genomic strategy delineated functionally relevant natural allele of a CLAVATA gene and its marker (haplotype)-assisted introgression led to development of the early-flowering chickpea cultivars with high flower number and enhanced yield/productivity. Abstract Unraveling the genetic components involved in CLAVATA (CLV) signaling is crucial for modulating important shoot apical meristem (SAM) characteristics and ultimately regulating diverse SAM-regulated agromorphological traits in crop plants. A genome-wide scan identified 142 CLV1-, 28 CLV2-and 6 CLV3-like genes, and their comprehensive genomic constitution and phylogenetic relationships were deciphered in chickpea. The QTL/fine mapping and map-based cloning integrated with high-resolution association analysis identified SNP loci from CaCLV3_01 gene within a major CaqDTF1.1/ CaqFN1.1 QTL associated with DTF (days to 50% flowering) and FN (flower number) traits in chickpea, which was further ascertained by quantitative expression profiling. Molecular haplotyping of CaCLV3_01 gene, expressed specifically in SAM, constituted two major haplotypes that differentiated the early-DTF and high-FN chickpea accessions from late-DTF and low-FN. Enhanced accumulation of transcripts of superior CaCLV3_01 gene haplotype and known flowering promoting genes was observed in the corresponding haplotype-introgressed early-DTF and high-FN near-isogenic lines (NILs) with narrow SAM width. The superior haplotype-introgressed NILs exhibited early-flowering, high-FN and enhanced seed yield/ productivity without compromising agronomic performance. These delineated molecular signatures can regulate DTF and FN traits through SAM proliferation and differentiation and thereby will be useful for translational genomic study to develop early-flowering cultivars with enhanced yield/productivity. Communicated by Heiko C. Becker.
The identification of functionally relevant molecular tags is vital for genomics-assisted crop improvement and enhancement of seed yield, quality, and productivity in chickpea (Cicer arietinum). The simultaneous improvement of yield/productivity as well as quality traits often requires pyramiding of multiple genes, which remains a major hurdle given various associated epistatic and pleotropic effects. Unfortunately, no single gene that can improve yield/productivity along with quality and other desirable agromorphological traits is known, hampering the genetic enhancement of chickpea. Using a combinatorial genomics-assisted breeding and functional genomics strategy, this study identified natural alleles and haplotypes of an ABCC3-type transporter gene that regulates seed weight, an important domestication trait, by transcriptional regulation and modulation of the transport of glutathione conjugates in seeds of desi and kabuli chickpea. The superior allele/haplotype of this gene introgressed in desi and kabuli near-isogenic lines enhances the seed weight, yield, productivity, and multiple desirable plant architecture and seedquality traits without compromising agronomic performance. These salient findings can expedite crop improvement endeavors and the development of nutritionally enriched high-yielding cultivars in chickpea.
Chickpea is predominantly an indeterminate (IDT) plant due to which high fertility and irrigation have adverse effect on seed yield. The semi-determinate (SDT) types are relatively early, lodging resistant and found to be similar in their yield potential to that of IDT genotypes. However, the inheritance of SDT stem type is not well understood in chickpea. The present investigation was aimed at studying the genetics of SDT stem type and identifying molecular marker linked to Dt1 locus through Bulked Segregant Analysis (BSA). The genetics of semi-determinacy was studied in BGD 72 (IDT) x BG 3078-1(SDT) cross in which the genetic constitution of BGD 72 was already known as Dt1Dt1Dt2Dt2 based on the previous study. The F1 was IDT indicating the dominance of indeterminacy over semideterminacy. The segregation in F2 and F3 revealed that SDT stem growth in the new-found genotype BG3078-1 was governed by a single dominant gene Dt2 and its genotype designated as dt1dt1Dt2Dt2. The study of polymorphic survey between BGD-72(IDT) and BG 3078- 1(SDT) using 581 SSR markers found 50 markers polymorphic. The BSA using 50 polymorphic markers has identified TA42 and TR29 as polymorphic between IDT and SDT parents as well as IDT and SDT bulks and hence considered putatively linked to Dt1 locus governing IDT stem growth in chickpea. The two linked markers were validated in 15 IDT and 15 SDT F2 plants individually. These two markers were also validated in 3 IDT, 8SDT and 3 DT genotypes. This is the first report on the identification of a molecular marker associated with stem growth habit in chickpea.
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