Rapid In Vitro Propagation of East Indian Rosewood (Dalbergia latifolia Roxb.) through High Frequency Shoot Proliferation from Cotyledonary Nodes

An efficient protocol is described for large scale in vitro propagation of east Indian rosewood (Dalbergia latifolia Roxb.) using cotyledonary nodes derived from axenic seedlings. Of the four different cytokinins tested, BA was most effective in inducing multiple shoot buds in the explants. High frequency shoot proliferation (93%) coupled with maximum number of shoot formation (10-12 shoots/explant) was recorded on Murashige and Skoog’s medium supplemented with 2.0 mg/l BA. The frequency of shoot proliferation declined at higher levels of cytokinins. Shoot culture was multiplied by subculturing the original cotyledonary node on a fresh shoot multiplication medium each time aHer excising the newly formed shoots. Shoots obtained from each passage were multiplied further as nodal explants and each node produced 3-4 shoots. In two months from a single cotyledonary node, about 90 shoots were obtained. Rooting was induced in 72% of the regenerated shoots on half-strength MS containing IAA, IBA and IPA each at 1.0 mg/l. Rooted plantlets were hardened off and eventually established in soil.     

Alginate encapsulation of axillary buds of Ocimum americanum L. (hoary basil), O. Basilicum L. (sweet basil), O. Gratissimum L. (shrubby basil), and O. Sanctum. L. (sacred basil)

Summary Propagation and conservation of four pharmaceutically important herbs, Ocimum americanum L. syn. O. canum Sims. (hoary basil); O basilicum L. (swett basil); O. gratissimum L. (shrubby basil); and O. sanctum L. (sacred basil) was attempted using synthetic seed technology. Synthetic seeds were produced by encapsulating axillary vegetative buds harvested from garden-grown plants of these four Ocimum species in calcium alginate gel. The gel contained Murashige and Skoog (MS) nutrients and 1.1-4.4 μM benzyladenine (BA). Shoots emerged from the encapsulated buds on all six planting media tested. However, the highest frequency shoot emergence and maximum number of shoots per bud were recorded on media containing BA. Of the six planting media tested, both shoot and root emergence from the encapsulated buds in a single step was recorded on growth regulator-free MS medium as well as on vermi-compost moistened with halfstrength MS medium. Rooted shoots were retrieved from the encapsulated buds of O. americanum, O. basilicum, and O. sanctum on these two media, whereas shoots of O. gratissimum failed to root. The encapsulated buds could be stored for 60 d at 4°C. Plants retrieved from the encapsulated buds were hardened off and established in soil.     

Plant peptide deformylase: a novel selectable marker and herbicide target based on essential cotranslational chloroplast protein processing

Transgenic tobacco plants expressing three different forms of Arabidopsis plant peptide deformylase ( At DEF1.1, At DEF1.2 and At DEF2; EC 3.5.1.88) were evaluated for resistance to actinonin, a naturally occurring peptide deformylase inhibitor. Over-expression of either AtDEF1.2 or AtDEF2 resulted in resistance to actinonin, but over-expression of AtDEF1.1 did not. Immunological analyses demonstrated that At DEF1.2 and At DEF2 enzymes were present in both stromal and thylakoid fractions in chloroplasts, but At DEF1.1 was localized to mitochondria. The highest enzyme activity was associated with stromal At DEF2, which was approximately 180-fold greater than the level of endogenous activity in the host plant. Resistance to actinonin cosegregated with kanamycin resistance in Atdef1.2-D and Atdef2-D transgenic plants. Here, we demonstrate that the combination of plant peptide deformylase and peptide deformylase inhibitors may represent a native gene selectable marker system for chloroplast and nuclear transformation vectors, and also suggest plant peptide deformylase as a potential broad-spectrum herbicide target.     

A novel salt-tolerant L-myo-inositol-1-phosphate synthase from Porteresia coarctata (Roxb.) Tateoka, a halophytic wild rice: molecular cloning, bacterial overexpression, characterization, and functional introgression into tobacco-conferring salt tolerance phenotype

l-myo-Inositol-1-phosphate synthase (EC 5.5.1.4, MIPS), an evolutionarily conserved enzyme protein, catalyzes the synthesis of inositol, which is implicated in a number of metabolic reactions in the biological kingdom. Here we report on the isolation of the gene (PINO1) for a novel salt-tolerant MIPS from the wild halophytic rice, Porteresia coarctata (Roxb.) Tateoka. Identity of the PINO1 gene was confirmed by functional complementation in a yeast inositol auxotrophic strain. Comparison of the nucleotide and deduced amino acid sequences of PINO1 with that of the homologous gene from Oryza sativa L. (RINO1) revealed distinct differences in a stretch of 37 amino acids, between amino acids 174 and 210. Purified bacterially expressed PINO1 protein demonstrated a salt-tolerant character in vitro compared with the salt-sensitive RINO1 protein as with those purified from the native source or an expressed salt-sensitive mutant PINO1 protein wherein amino acids 174-210 have been deleted. Analysis of the salt effect on oligomerization and tryptophan fluorescence of the RINO1 and PINO1 proteins revealed that the structure of PINO1 protein is stable toward salt environment. Furthermore, introgression of PINO1 rendered transgenic tobacco plants capable of growth in 200-300 mm NaCl with retention of approximately 40-80% of the photosynthetic competence with concomitant increased inositol production compared with unstressed control. MIPS protein isolated from PINO1 transgenics showed salt-tolerant property in vitro confirming functional expression in planta of the PINO1 gene. To our knowledge, this is the first report of a salt-tolerant MIPS from any source.