Influence of Different Rates of Plant-Based Compost on Clay Soil Metal Behavior and Human Health Risk Assessment in Moringa oleifera Leaf Biomass.

An investigation of the impact of adding plant-based organic compost to clay soil from a Moringa oleifera farm focusing on the metal content, bioavailability, and accumulation of nutrients in M. oleifera leaves was conducted. Clay soil was mixed with 15%, 30%, 45% and 60% plant-based organic compost (by volume) in 20 cm wide, 2 L pots. Moringa oleifera plants were planted in four replicates of each treatment and control group. Results revealed that the addition of compost significantly (P < 0.05) altered the concentration of metals in the soil. Correspondingly, accumulation of nutrients in M. oleifera leaves increased with the addition of compost to the soil, except for cobalt and chromium. Trace elements had minimal bioavailability in the amended soils, and their presence in the leaves was lower than the permissible trace metal levels in food. The 30% combination had the highest concentration of calcium (45 042.5 mg/kg), magnesium (17430.0 mg/kg) and phosphorous (8802. 5 mg/kg) in M. oleifera leaves. The study concluded the addition of compost improved bioavailability of nutrients in the soil and their concentration in M. oleifera leaves. The target hazard quotients for heavy metals was less than one, indicating that M. oleifera leaf biomass harvested from soil amended with plant-based compost is safe for human consumption. These results serve as guidelines for recommended organic certification requiremets where plant-based compost is often used in the fast-growing herbal industry.

Programmed cell death and necrosis during cryopreparative drying of in vitro Eucalyptus grandis axillary buds.

In preparation for cryopreservation, Eucalyptus grandis in vitro axillary buds were dried over silica gel. Pretreatment of the buds with 5 mg per L ABA resulted in partial resistance to water loss (0.76 to 0.45 g per g fresh mass basis) as compared with untreated buds (0.76 to 0.33 g per g) and was associated with the retention of viability (70 vs. 55%). The loss of viability of the dried buds was protracted over several days. Ultrastructural examination and vital staining demonstrated cellular and tissue responses to drying. The meristem appeared to withstand drying and 72 h of rehydration whilst the leaf primordia were destroyed immediately after drying. High reactive oxygen species (ROS) activity was associated with bud excision and drying. Caspase-3-like protease activity was detected after rehydration, thereby providing evidence that the dried buds, that had ultimately died, had undergone programmed cell death. ROS production is considered to be the trigger for programmed cell death.