Urmil J. Mehta

Effect of thidiazuron in germinating tamarind seedlings

SummaryTamarind, a multipurpose tropical tree species, is economically important for sustainable development of wasteland due to its hardy nature and adaptability to various agroclimatic ocnditions. Reports on in vitro morphogenesis in this species are limited, due to its recalcitrant and callogenic nature. To overcome these limitations, an attempt was made to induce meristematic activity in seedling explants. Seedlings were germinated in medium with or without thidiazuron (4.54, 9.08, 13.12, 18.16 μM). This growth regulator restricted the differentiation of the apical meristem to form shoots. It triggered proliferation of the meristematic tissue at the cotyledonary node and a large number of meristematic buds appeared in a ridial pattern around the node. The meristematic activity extended to the junction of the epicotyl and hypocotyl, giving rise to buds in the form of protuberances in all sides of the junction. These buds differentiated to form shoot primordia and subsequently to shoots in medium devoid of growth regulators. Plants developed by micrografting of these shoots on seedling-derived rootstocks survived in soil.

Synthesis of gold nanoparticles by various leaf fractions of Semecarpus anacardium L. tree

Gold nanoparticles (NPs) were synthesized using Semecarpus anacardium leaf extracts in water and the green biomass. Extract prepared at ambient condition by crushing the leaves in deionized water is identified as ‘green extract’, and that by boiling the leaf pieces as ‘boiled extract’. The mass remaining after separating the ‘green extract’ is identified as ‘green biomass’. These components triggered rapid reduction of Au(III) to Au (0) in HAuCl4 solution indicating the natural ability of the leaves of S. anacardium to synthesize NPs in ambient conditions. Green extract produced more NPs compared to the boiled extract suggesting denaturization of some of the useful factors due to boiling. NPs were quantified using UV and ICP-AES analysis. These were characterized using Transmission electron microscopy, Fourier transform infrared spectroscopy and X-ray diffraction. TEM images of the particles formed with green extract, boiled extract and green biomass showed that the particles were of different shapes and sizes.

THIDIAZURON-INDUCED MORPHOGENESIS IN TAMARIND SEEDLINGS

SummaryGermination of tamarind seeds in medium containing thidiazuron (TDZ) resulted in induction of nodular protrusions in and around the cotyledonary node meristem. The structures developed radially in well-defined circles and subsequently spread towards the cotyledonary bridge and also in the proximal part of the hypocotyl. The structures developed into shoots on transfer to medium devoid of growth regulators. Histological studies revealed that the protrusions initiated from the nodal meristem and extended to the non-meristematic region between the two meristems and also in the proximal part of the hypocotyl in seedlings germinated in 9.08 μM TDZ. Newly formed cell layers and less-differentiated meristematic protrusions were also seen. With the increase in the distance from the meristem, the buds were less differentiated; in the proximal part of the hypocotyl only the multiple layers of meristematic cells were noted. With extension of the period of incubation, the TDZ-induced meristematic activity extended laterally in circles towards the neighboring region. The radial spread of the meristematic activity from the center of the nodal meristem was also evident at 18.16 μM TDZ. From the pattern of the morphogenic development and the histological studies it may be hypothesized that in tamarind, TDZ influences the existing meristems specifically. Subsequently de novo organogenesis is triggered in the neighboring cells.

Synthesis of Ag-glyconanoparticles using C-glycosides, their lectin binding studies and antibacterial activity

Two 12-C-glycosyl dodecanoic acids, namely, 1-(α-D-mannopyranosyl)-12-dodecanoic acid and 1-(α-D-glucopyranosyl)-12-dodecanoic acid were synthesized. Their ability to act as reducing and capping agents for the synthesis of water re-dispersible silver nanoparticles is displayed. These Ag C-glycosyl nanoparticles were later utilized to investigate the carbohydrate–lectin interactions. Furthermore, the specificity of mannoside binding to the surface of the Gram negative bacterium Escherichia coli has been utilized to demonstrate the enhanced antibacterial activity of Ag-C-mannosyl nanoparticles towards this bacterium as compared to Ag-C-glycosyl nanoparticles.

Micropropagation of Semecarpus anacardium L. from mature tree-derived nodal explants

A protocol was established for micropropagation of Semecarpus anacardium L. from mature tree-derived twigs. Sixty percent of aseptic cultures were obtained by surface sterilization with Bavistin, liquid detergent, and cefotaxime. Elongated twigs collected before flowering were optimum for in vitro culture initiation. Meristematic activity was triggered at all concentrations of thidiazuron (TDZ) incorporated into Woody Plant Medium. TDZ suppressed elongation of axillary buds, resulting into swollen meristems and upon its elimination multiple shoot primordia formation and differentiation were noted. Differentiation and shoot elongation were slower in explants pre-cultured with higher concentrations of TDZ. Swollen axillary meristems pre-cultured on TDZ (9.08 and 13.62 μM) failed to differentiate, whereas TDZ at 2.27 μM was optimal for shoot differentiation and elongation. Multiple bud induction was favored by 4.45 μM of TDZ. Differentiation of multiple shoot primordia by repeated subculturing on growth regulator-free medium and rooting was 100% in filter-paper supported half-strength liquid medium containing 7.38 μM IBA. Rooting was 90% in shoots placed directly in half-strength liquid medium with 2.46 μM IBA. Rooted plantlets hardened in soil:sand mixture (1:1) were transferred to green house. Genetic uniformity of in vitro raised clones with mother plant was confirmed by Inter-Simple Sequence Repeat markers.

Phytosynthesis of intracellular and extracellular gold nanoparticles by living peanut plant (Arachis hypogaea L.)

Inorganic nanomaterials of different chemical compositions are conventionally synthesized under harsh environments such as extremes of temperature, pressure, and pH. Moreover, these methods are eco‐unfriendly and cumbersome, yield bigger particles, and agglomerate because of not being capped by capping agents. In contrast, biological synthesis of inorganic nanomaterials occurs under ambient conditions, namely room temperature, atmospheric pressure, and physiological pH. These methods are reliable, eco‐friendly, and cheap. In this paper, we report for the first time the extracellular and intracellular synthesis of gold nanoparticles (GNPs) using living peanut seedlings. The formed GNPs were highly stable in solution and inside the plant tissue. Transmission electron microscopy revealed that extracellular GNPs distributions were in the form of monodispersed nanoparticles. The nanoparticles ranged from 4 to 6 nm in size. The intercellular nanoparticles were of oval shape and size ranged from 5 to 50 nm. Both extracellular and intracellular nanoparticles were further characterized by standard techniques. The formed GNPs inside the plant tissue were estimated by inductively coupled plasma spectrometry. This opens up an exciting possibility of a plant‐based nanoparticle synthesis strategy, wherein the nanoparticles may be entrapped in the biomass in the form of a film or produced in the solution, both of which have interesting applications.