Maya Karan

Start codon targeted (SCoT) polymorphism reveals genetic diversity in wild and domesticated populations of ramie (Boehmeria nivea L. Gaudich.), a premium textile fiber producing species

Twenty-four start codon targeted (SCoT) markers were used to assess genetic diversity and population structure of indigenous, introduced and domesticated ramie (Boehmeria nivea L. Gaudich.). A total of 155 genotypes from five populations were investigated for SCoT polymorphism, which produced 136 amplicons with 87.5% polymorphism. Polymorphism information content and resolving power of the SCoT markers were 0.69 and 3.22, respectively. The Indian ramie populations exhibited high SCoT polymorphism (> 50%), high genetic differentiation (GST = 0.27) and moderate gene flow (Nm = 1.34). Analysis of molecular variance identified significant differences for genetic polymorphism among the populations explaining 13.1% of the total variation. The domesticated population exhibited higher genetic polymorphism and heterozygosity compared to natural populations. Cluster analysis supported population genetic analysis and suggested close association between introduced and domesticated genotypes. The present study shows effectiveness of employing SCoT markers in a cross pollinated heterozygous species like Boehmeria, and would be useful for further studies in population genetics, conservation genetics and cultivar improvement.

Genome synteny and evolution of AABB allotetraploids in Hibiscus section Furcaria revealed by interspecific hybridization, ISSR and SSR markers

Two tetraploid species of Hibiscus section Furcaria, H. acetosella and H. radiatus, have an AABB genomic constitution. The diploid species, H. cannabinus (AA) and H. surattensis (BB), were hybridized to develop interspecific alloploid (AB) hybrids. The synthetic interspecific hybrid exhibited intermediate morphological characters, with expression of domestication-related traits, but exhibited higher genomic association with the B genome donor. Evolution of allopolyploids in section Furcaria was found to be associated with mutations in repetitive sequences, leading to higher variation in the tetraploid genome. Allopolyploidization was observed to be associated with both loss of repetitive sequences and appearance of new alleles. Genetic diversity analysis using ISSR and cross-species SSR markers revealed a closer association of diploid genomes and high variability of tetraploid genomes. The evolution of AABB tetraploids in this section possibly took place by hybridization of the A and B genome in geographically isolated regions.

Comparative analysis of diversification and population structure of kenaf (Hibiscus cannabinus L.) and roselle (H. sabdariffa L.) using SSR and RGA (resistance gene analogue) markers

Multiple DNA marker systems and complementary analytical approaches are often useful in population genetic analysis and speciation of plants. We investigated population structure of kenaf (Hibiscus cannabinus) and roselle (H. sabdariffa) for gaining insight in evolution and geographic separation of these crop species using SSR and RGA (resistance gene analogues) markers through Bayesian clustering and principal coordinate analysis (PCoA) methods. Genotyping by 12 SSR and 16 RGA markers amplified a total of 172 loci in the study population. The RGA markers generated higher number of alleles per marker (8.2) as compared to SSR (3.4), but exhibited lower heterozygosity in the population. Genetic variance and heterozygosity in roselle population for both marker systems were lower than in kenaf. RGA markers revealed higher variation among populations. Bayesian structure as well as PCoA analysis using RGA marker revealed distinct cluster for roselle, while SSR-based classification revealed high admixture. Results indicate geographic isolation and natural selection for adaptive RGA alleles in kenaf. The Indian kenaf landraces were distinct from the exotic kenaf accessions, suggesting separate lineage formation by geographic separation. Possible origin and domestication of roselle in South India is proposed.

Transcriptome profiling uncovers β-galactosidases of diverse domain classes influencing hypocotyl development in jute (Corchorus capsularis L.)

Enzyme β-galactosidase (EC 3.2.1.23) is known to influence vascular differentiation during early vegetative growth of plants, but its role in hypocotyl development is not yet fully understood. We generated the hypocotyl transcriptome data of a hypocotyl-defect jute (Corchorus capsularis L.) mutant (52,393 unigenes) and its wild-type (WT) cv. JRC-212 (44,720 unigenes) by paired-end RNA-seq and identified 11 isoforms of β-galactosidase, using a combination of sequence annotation, domain identification and structural-homology modeling. Phylogenetic analysis classified the jute β-galactosidases into six subfamilies of glycoside hydrolase-35 family, which are closely related to homologs from Malvaceous species. We also report here the expression of a β-galactosidase of glycoside hydrolase-2 family that was earlier considered to be absent in higher plants. Comparative analysis of domain structure allowed us to propose a domain-centric evolution of the five classes of plant β-galactosidases. Further, we observed 1.8-12.2-fold higher expression of nine β-galactosidase isoforms in the mutant hypocotyl, which was characterized by slower growth, undulated shape and deformed cell wall. In vitro and in vivo β-galactosidase activities were also higher in the mutant hypocotyl. Phenotypic analysis supported a significant (P ≤ 0.01) positive correlation between enzyme activity and undulated hypocotyl. Taken together, our study identifies the complete set of β-galactosidases expressed in the jute hypocotyl, and provides compelling evidence that they may be involved in cell wall degradation during hypocotyl development.