An Overview of Nickel (Ni2+) Essentiality, Toxicity and Tolerance Strategies in Plants

Heavy metals (HMs) toxicity has an unavoidable threat to environment and public health due to their increasing contamination and accumulation in atmosphere which ultimately passes to the living beings by the route of food chain. Heavy metals are increasing rapidly in soil and water by weathering of rocks and anthropogenic activities and are now emerging as a major health hazard to humans and plants. Among them Nickel (Ni2+) is a controversial element because of debate on its essentiality or non-essentiality in plants. Ni2+ is an important constituent (micronutrient) of many metallo-enzymes including urease, Ni-Fe hydrogenase, Ni-superoxide dismutase etc. while at higher level it affects all cellular and metabolic processes and causes retardation of germination, competition with other essential metal ions, osmotic imbalance, alteration of many enzymatic activities, disruption of cell structure and wilting, reduced photosynthetic activity, oxidative stress etc. Plants also possess some natural and stress-induced strategies to cope up with Ni2+ excess/toxicity. These strategies include growth regulators, antioxidative enzymes, amino acids as osmoprotectant, and chelation of Ni2+ with metalloproteins and metallothionins. This review focuses on researches done on the morpho-biochemical alterations induced by elevated Ni2+ concentration in plants and as well as the strategies adapted by plants to survive and neutralize the effects of these alterations

Simulated Acid Rain-induced Alterations in Flowering, Leaf Abscission and Pollen Germination in Sunflower (Helianthus annuus L.)

This study examined the effects of simulated acid rain (SAR) of different pH [distilled water-7.0 (control), 5.7, 4.5 and 3.0] on leaf abscission, flowering and pollen germination in sunflower (Helianthus annuus L.) cv. ‘Morden’ as test system under field conditions in sandy loam soil with sufficient organic matter, pale yellow in color and pH 7.3 and 65 % water holding capacity. Acid rain solution (30 ml/plant) was sprayed on plants at weekly intervals starting from two leaved stage till initiation of flowering in the early morning under natural environment. Evaluation of SAR effects on budding, flowering, leaf abscission and pollen development revealed that initiation and duration of budding and flowering altered significantly in test plant with decreasing pH of acid rain solution. Acid rain application showed early leaf abscission and reduction in pollen germination percentage and pollen tube length. Effects of SAR increased more dramatically with the increase of SAR acidity. The study indicates the sunflower plant turns to be an acid rain sensitive system and demands for breeding with acid rain tolerant varieties in view of expanding acid rain geographical areas and growing industrialization.Keywords: Simulated acid rain, Helianthus annuus, flowering, leaf abscission, pollen germination, sunflower