Flow cytometry and start codon targeted (SCoT) genetic fidelity assessment of regenerated plantlets in Tylophora indica (Burm.f.) Merrill

Tylophora indica (Burm.f.) Merrill. is a pharmacologically important plant, popular for alkaloidal and non-alkaloidal richness. Large scale propagation of T. indica is difficult in the wild as the seeds are small and the frequency of germination is very poor. In the present study, the genome size estimation of in vitro regenerated (indirect, direct and somatic embryo mediated) T. indica was made by flow cytometric method. Clonal fidelity of the regenerants was assessed using a start codon targeted (SCoT) molecular marker. Initially, the explants were inoculated on Murashige and Skoog basal medium supplemented with various concentrations of plant growth regulators like 2,4-dichlorophenoxy acetic acid (2,4-D), Kinetin, 6-benzyl amino purine (BAP) and 1-naphthalene acetic acid either singly or in combinations. The highest callus induction frequency (87.75%) was obtained in 6.7 µM 2,4-D added MS medium which metamorphosed into progressive stages (globular, heart, torpedo, and cotyledonary) of embryos. Mature and healthy somatic embryos efficiently germinated into plantlets on 8.8 µM BAP?+?1.4 µM GA₃ enriched MS medium. Histological and scanning electron microscopic study confirmed the above developing stages. The regenerated shoots were rooted best in 2.45 µM Indole-3-butyric acid supplemented solid MS medium. The plants were hardened and acclimatized with 90% survivability. The flow cytometric 2C DNA content of indirect, direct and somatic embryo derived plants was 1.896 pg, 1.940 pg and 1.926 pg respectively, very similar to the mother plant (1.928 pg). SCoT marker generated a high percentage of monomorphic bands (94%) revealing similarity with the mother plant, thus ensuring genetic fidelity. To the best of our knowledge, this is perhaps the first ever report of 2C DNA content estimation and SCoT marker based genetic homogeneity study in T. indica.

     

Comprehensive in vitro regeneration study with SCoT marker assisted clonal stability assessment and flow cytometric genome size analysis of Carthamus tinctorius L.: an important medicinal plant

An efficacious and reproducible in vitro regeneration technique for safflower was established using varying concentrations and composition of plant growth regulators (PGRs) supplemented Murashige and Skoog (MS) medium. Successful in vitro seed germination in half strength MS (H-MS) with 1.4 µM GA₃ resulted in procurement of sterile explants (cotyledons, apical meristems) for in vitro study. Callogenesis (2.2 µM BAP?+?2.7 µM NAA), indirect organogenesis of shoot buds (0.54 µM NAA?+?9.08 µM TDZ), somatic embryogenesis (2.2 µM BAP?+?5.4 µM NAA) and somatic embryo germinated plantlets (H-MS?+?1.4 µM GA₃?+?2.2 µM BAP?+?5.4 µM NAA) were successfully obtained. Histological study and scanning electron micrographs of embryogenic callus revealed pre-globular, heart-shaped and torpedo stages of dicot embryogeny. H-MS?+?8 µM NAA showed maximum rhizogenic response with a mean root and shoot length of 17.5 mm and 48.50 mm respectively in 2.2 µM BAP?+?0.54 µM NAA bearing an average of 9 capitula per plantlet with 70% post transplantation survival rate. True to type nature of the regenerates was confirmed using Start Codon Targeted (SCoT) marker, exhibiting 100% and 97.3% monomorphic bands for direct and somatic embryo regenerated plants respectively. Flow cytometry method (FCM) was employed for 2C DNA content analysis. The histogram peaks of 2C nuclear DNA content of in vitro regenerated safflower (direct and embryo derived) were similar to the peak of field grown donor plant. 2C nuclear DNA content of field grown, direct and somatic embryo regenerated C. tinctorius was 2.65?±?0.04 pg, 2.62?±?0.06 pg and 2.68?±?0.04 pg respectively, further verifying genetic homogeneity. All things considered, the above protocol is insusceptible to genetic alteration and can be used for large scale production and sustainable utilization of desired genotype.

     

The effect of in vivo heat treatments on blowfly flight muscle mitochondrial function: Effects on partial reactions of the respiratory chain

1. 1. The development of thermotolerance has been shown to protect blowfly flight muscle mitochondrial function from damage resulting from an LD₅₀ in vivo heat dose.

2. 2. The principal sites of the damage have been studied using specific inhibitors of the respiratory chain, rotenone and antimycin A, together with substrates that stimulate respiration through the different complexes.

3. 3. Complex I was identified as the primary site for heat damage. State III respiration was inhibited following the LD₅₀ in vivo heat dose, and uncoupling with FCCP did not restore respiration to control levels, indicating that the respiratory enzymes were inactivated. The development of thermotolerance protected this site from heat damage.

4. 4. In contrast, G3-P stimulated respiration was the same in control, LD₅₀ in vivo treated controls and LD₅₀, in vivo treated thermotolerant mitochondria, and significantly higher than state III respiration of LD₅₀ in vivo treated controls. This suggested that respiration through G3-P dehydrogenase, Co enzyme Q and Complex III is not damaged. However, as G3-P stimulated respiration of coupled mitochondria from LD₅₀ in-vivo treated flies was markedly reduced (El-Wadawi and Bowler, 1995. J. exp. Biol. 198: 2413–2421), phosphorylation at complex III may be inhibited also.

5. 5. Ferrocyanide stimulated respiration through cytochrome c-Complex IV was also inhibited in LD₅₀ in vivo treated flies, as compared with unheated control mitochondria. However, thermotolerance protected this site also from heat damage.