Marker assisted early generation identification of root knot disease resistant orange tomato segregants with multiple desirable alleles.

Enhanced bioavailability of cis-isomers of lycopene, accumulated in orange-fruited tangerine mutant has broadened the scope of nutritional enrichment in tomato. At the same time, advancements in the field of marker assisted selection (MAS) have made the stacking of multiple desirable alleles through molecular breeding to develop superior tomato genotypes possible. Here we report seedling stage MAS from 146 F2 plants, to identify 3 superior performing, root knot disease resistant orange-fruited segregants. In the selected segregants, fruit weight ranged from 39.2 to 54.6 g, pericarp thickness ranged from 4.56 to 6.05 mm and total soluble solid content ranged from 3.65 to 4.87° Brix. Presence of parental diversity allowed identification of the other desirable alleles of the genes governing late blight and mosaic disease resistance, growth habit (determinate and indeterminate) as well as fruit elongation and firmness. Resistance to root knot disease of the selected 3 segregants was also validated through a unique method employing in vitro rooted stem cuttings subjected to artificial inoculation, where the resistant parent and the selected segregants developed no galls in comparison to ~ 24 galls developed in the susceptible parent. The selected segregants form the base for development of multiple disease resistant, nutritionally enriched orange-fruited determinate/indeterminate tomato lines with superior fruit quality. The study also highlights the utility of early generation MAS for detailed characterization of segregants, through which multiple desirable alleles can be precisely targeted and fixed to develop superior tomato genotypes. Supplementary Information: The online version contains supplementary material available at 10.1007/s12298-023-01361-1.

Understanding the genomic selection for crop improvement: current progress and future prospects.

Although increased use of modern breeding techniques and technology has resulted in long-term genetic gain, the pace of genetic gain must be sped up to satisfy global agricultural demand. However, marker-assisted selection has proven its potential for improving qualitative traits with large effects regulated by one to few genes. Its contribution to the improvement of the quantitative traits regulated by a number of small-effect genes is modest. In this context, genomic selection (GS) has been regarded as the most promising method for genetically enhancing complicated features that are regulated by several genes, each of which has minor effects. By examining a population's phenotypes and high-density marker scores, genomic selection can forecast the breeding potential of individual lines. The fact that GS uses all marker data in the prediction model prevents skewed marker effect estimations and maximizes the amount of variation caused by small-effect QTL. It has the ability to speed up the breeding cycle and as a consequence of which superior genotypes are selected rapidly. Developing the best GS models while taking into account non-additive effects, genotype-by-environment interaction, and cost-effectiveness will enable the widespread implementation of GS in plants. These steps will also increase heritability estimation and prediction accuracy. This review focuses on the shift from conventional selection methods to GS, underlying statistical tools and methodologies, the state of GS research in agricultural plants, and prospects for its effective use in the creation of climate-resilient crops.

A candidate gene OsAPC6 of anaphase-promoting complex of rice identified through T-DNA insertion.

A dwarf mutant (Oryza sativa anaphase-promoting complex 6 (OsAPC6)) of rice cultivar Basmati 370 with 50% reduced plant height as compared to the wild type was isolated by Agrobacterium tumefaciens-mediated transformation using Hm(R) Ds cassette. This mutant was found to be insensitive to exogenous gibberellic acid (GA(3)) application. Homozygous mutant plants showed incomplete penetrance and variable expressivity for plant height and pleiotropic effects including gibberellic acid insensitivity, reduced seed size, panicle length, and female fertility. Single copy insertion of T-DNA and its association with OsAPC6 was confirmed by Southern hybridization, germination on hygromycin, and 3:1 segregation of HPT gene in F(2) from OsAPC6 x Basmati 370 cross. The T-DNA flanking region sequenced through thermal asymmetric interlaced polymerase chain reaction showed a single hit on chromosome 3 of japonica rice cultivar Nipponbare in the second exonic region of a gene which encodes for sixth subunit of anaphase-promoting complex/cyclosome. The candidate gene of 8.6-kb length encodes a 728-amino acid protein containing a conserved tetratricopeptide repeat (TPR) domain and has only a paralog, isopenicillin N-synthase family protein on the same chromosome without the TPR domain. There was no expression of the gene in the mutant while in Basmati 370, it was equal in both roots and shoots. The knockout mutant OsAPC6 interferes with the gibberellic acid signaling pathway leading to reduced height and cell size probably through ubiquitin-mediated proteolysis. Further functional validation of the gene through RNAi is in progress.

The polyembryo gene (OsPE) in rice.

T-DNA insertional mutagenesis is one of the most important approaches for gene discovery and cloning. A fertile polyembryo mutant generated by T-DNA/Ds insertion in Oryza sativa, cv. Basmati 370 showed twin or triple seedlings at a frequency of 15-20%. T-DNA insertion was confirmed by 950 bp hpt gene amplification in the promoter region of the candidate gene. The annotated protein corresponding to the OsPE candidate gene has been reported as a hypothetical protein in O. sativa. OsPE gene lacked functional homologs in other species. No OsPE paralog was found in rice. No conserved domains were found in the protein coded by OsPE. RT-PCR showed the expression of OsPE gene in Basmati 370 shoots. Full-length OsPE gene was cloned in Basmati 370. The combined use of Southern blot, genome walking, TAIL-PCR, RT-PCR techniques, and bioinformatics led to the identification of a candidate gene controlling the multiple embryos in rice. There is gain of function, i.e., multiple embryos in the seeds in the knockout mutant OsPE whereas its wild-type allele strictly controls single embryo per seed. The seeds with multiple embryos are distributed at random in the rice mutant panicle. The origin of multiple embryos, whether apomictic, zygotic or both is under investigation.