Response of senescing wheat leaves to ultraviolet a light: Changes in energy transfer efficiency and PS II photochemistry

Response of senescing leaves of wheat seedlings to ultraviolet A (UVA) radiation (365 nm) has been examined. The results indicate that senescence-induced disorganization of thylakoid membrane, decline in carotenoid-to-chlorophyll energy transfer, and enhancement of lipid peroxidation are furthered by radiation. The senescence-induced decline in photochemical activity of photosystem II further declines on irradiation. UVA does not specifically alter any site other than those damaged by senescence.     

Site specific inhibition by α-benzyl-α-bromomalodinitrile (BBMD) of electron transport in spinach chloroplasts

The addition of α-benzyl-α-bromomalodinitrile to different controlled states (non-phosphorylating [2]. phosphorylating [3], ATP-inhibited [4] and uncoupled) of photosynthetic electron transport to ferricyanide or benzoquinone demonstrate a significant inhibition in isolated spinach chloroplasts. α-Benzyl-α-bromomalodinitrile pretreatement of isolated chloroplasts or addition of α-benzyl-α-bromomalodinitrile at the onset of illumination completely abolished the O₂ evolving reaction. The level of the steady state fluorescence in intact chloroplasts showed a α-benzyl-α-bromomalodinitrile concentration-dependent increase. The gradual decrease in the reoxidation capacity of the reduced quencher, Q with increasing α-benzyl-α-bromomalodinitrile concentrations provides evidence for an additional inhibitory site for α-benzyl-α-bromomalodinitrile between the two photosystems.     

Combined arene ruthenium porphyrins as chemotherapeutics and photosensitizers for cancer therapy

Mononuclear 5-(4-pyridyl)-10,15,20-triphenylporphyrin and 5-(3-pyridyl)-10,15,20-triphenylporphyrin as well as tetranuclear 5,10,15,20-tetra(4-pyridyl)porphyrin (tetra-4-pp) and 5,10,15,20-tetra(3-pyridyl)porphyrin) (tetra-3-pp) arene ruthenium(II) derivatives (arene is C₆H₅Me or p-Pr ⁱ C₆H₄Me) were prepared and evaluated as potential dual photosensitizers and chemotherapeutics in human Me300 melanoma cells. In the absence of light, all tetranuclear complexes were cytotoxic (IC₅₀ ≤ 20 μM), while the mononuclear derivatives were not (IC₅₀ ≥ 100 μM). Kinetic studies of tritiated thymidine and tritiated leucine incorporations in cells exposed to a low concentration (5 μM) of tetranuclear p-cymene derivatives demonstrated a rapid inhibition of DNA synthesis, while protein synthesis was inhibited only later, suggesting arene ruthenium–DNA interactions as the initial cytotoxic process. All complexes exhibited phototoxicities toward melanoma cells when exposed to laser light of 652 nm. At low concentration (5 μM), LD₅₀ of the mononuclear derivatives was between 5 and 10 J/cm², while for the tetranuclear derivatives LD₅₀ was approximately 2.5 J/cm² for the [Ru₄(η⁶-arene)₄(tetra-4-pp)Cl₈] complexes and less than 0.5 J/cm² for the [Ru₄(η⁶-arene)₄(tetra-3-pp)Cl₈] complexes. Examination of cells under a fluorescence microscope revealed the [Ru₄(η⁶-arene)₄(tetra-4-pp)Cl₈] complexes as cytoplasmic aggregates, whereas the [Ru₄(η⁶-arene)₄(tetra-3-pp)Cl₈] complexes were homogenously dispersed in the cytoplasm. Thus, these complexes present a dual synergistic effect with good properties of both the arene ruthenium chemotherapeutics and the porphyrin photosensitizer.     

Changes in Proteins and RNA during Storage of Curcuma Longa L. Rhizome

Changes in RNA and protein contents, and protein profiles were studied in the rhizomes of turmeric (Curcuma longa L.) from the day of harvest to the commencement of sprouting. Protein and RNA contents increased gradually in the initial stages and rapidly in the final stages of storage period. SDS-PAGE analysis of storage proteins revealed synthesis of 56, 52 and 47 kDa proteins during the later stages of storage with concomitant disintegration of 23 and 18 kDa proteins.     

Photosystems activities and polypeptide composition of Cyamopsis tetragonoloba and Vigna mungo thylakoids as affected by exclusion of solar UV radiation

The impacts of solar UV (280–400 nm) radiation on photosynthetic activities and polypeptide composition of thylakoids of cluster bean (Cyamopsis tetragonoloba L, UV-B sensitive) and black gram (Vigna mungo L., UV-B resistant) plants were compared. The activity of photosystem 1 and especially photosystem 2 increased in cluster bean while decreased in black gram, when either UV-B or UV-B + UV-A radiation was removed as compared to control plants. Exclusion of UV-B radiation caused changes in the protein composition of the thylakoids particularly in the 33, 23 and 17 kDa proteins of photosystem 2.     

Batch and continuous removal of arsenic using hyacinth roots

Arsenic is considered a primary pollutant in drinking water because of its high toxicity. The unique property of water hyacinth roots (Eichhornia crassipes) to remove heavy metals is of great signiicance for the development of a cost-effective phytoremediation technology. An experimental test program was conducted at the United States Environmental Protection (USEPA) Test and Evaluation (T&E) Facility in Cincinnati, Ohio, to investigate the potential of water hyacinth roots to remove arsenic from spiked drinking water samples. Water hyacinth roots were washed, dried, and powdered to provide dried hyacinth roots (DHR) for batch and continuous column experiments, Various quantities of DHR were added to water spiked with 300 micrograms per liter (microg/L) arsenic. A concentration of 20 g/L DHR was found adequate for greater than 90% arsenic removal in the batch tests. Based on the batch test results, continuous column experiments were performed using a 2-L column. In a continuous system, 15 L of water containing 300 microg/L arsenic were treated to below 20 microg/L using 50 g DHR, and 44 L of water containing 600 microg/L arsenic were treated to below 20 microg/L using 100 g DHR, giving a specific accumulation rate of approximately 260 microg As/g DHR.     

Development of selective and reversible pyrazoline based MAO-A inhibitors: Synthesis,biological evaluation and docking studies

3,5-Diaryl pyrazolines analogs were synthesized and evaluated for their monoamine oxidase (MAO) inhibitory activity. The compounds were found reversible and selective towards MAO-A with selectivity index in the magnitude of 10³–10⁵. The docking studies were carried out to gain further structural insights of the binding mode and possible interactions with the active site of MAO-A. Interestingly, the theoretical (K_i) values obtained by molecular docking studies were in congruence with their experimental (K_i) values.     

Cooperativity between inhibition of cytosolic K+ efflux and AMPK activation during suppression of hypoxia-induced cellular apoptosis

Cellular potassium homeostasis has recently emerged as a critical regulator of apoptosis in response to variety of stimuli. However, functional hierarchy of this phenomenon in the apoptotic cascade and therefore, its significance as a pathway for intervention is not fully established. Chronic hypoxia, a known threat to cell survival, also modulates cellular potassium homeostasis. In this study, we tested if hypoxia-induced apoptosis in lymphocytes can be prevented by modulating cellular K+ homeostasis. We observed that chronic hypoxia accelerated the rate of apoptosis in resting murine splenocytes concomitant with cytosolic K+ efflux. We tested several modalities including elevated extracellular potassium besides various K+ channel inhibitors to curtail hypoxia-induced K+ efflux and interestingly, established that the supplementation of KCl in extracellular medium was most effective in preventing hypoxia-induced apoptosis in these cells. Subsequent mechanistic dissection of pathways underlying this phenomenon revealed that besides effectively inhibiting hypoxia-induced efflux of K+ ion and its downstream cell-physiological consequences; elevated extracellular KCl modulated steady state levels of cellular ATP and culminated in stabilization of AMPKα with pro-survival consequences. Also, interestingly, global gene expression profiling revealed that KCl supplementation down regulated a distinct p53-regulated cellular sub-network of genes involved in regulation of DNA replication. Additionally, we present experimental evidence for the functional role of AMPK and p53 activation during suppression of hypoxia-induced apoptosis. In conclusion, our study highlights a novel bimodal effect wherein cooperativity between restoration of K+ homeostasis and a sustainable ‘metabolic quiescence’ induced by AMPK activation appeared indispensible for curtailing hypoxia-induced apoptosis.     

Site specific inhibition by alpha-benzyl-alpha-bromomalodinitrile (BBMD) of electron transport in spinach chloroplasts.

The addition of alpha-benzyl-alpha-bromomalodinitrile to different controlled states (non-phosphorylating [2]. phosphorylating [3], ATP-inhibited [4] and uncoupled) of photosynthetic electron transport to ferricyanide or benzoquinone demonstrate a significant inhibition in isolated spinach chloroplasts. alpha-Benzyl-alpha-bromomalodinitrile pretreatement of isolated chloroplasts or addition of alpha-benzyl-alpha-bromomalodinitrile at the onset of illumination completely abolished the O2 evolving reaction. The level of the steady state fluorescence in intact chloroplasts showed a alpha-benzyl-alpha-bromomalodinitrile concentration-dependent increase. The gradual decrease in the reoxidation capacity of the reduced quencher, Q with increasing alpha-benzyl-alpha-bromomalodinitrile concentrations provides evidence for an additional inhibitory site for alpha-benzyl-alpha-bromomalodinitrile between the two photosystems.