DNA Intercalation and Photoinduced Cleavage by 4-Nitro(N-Hexylamine)1,8-Naphthalimide

Abstract

A novel intercalator, 4-nitro(N-hexylamine)1,8-naphthalimide, was synthesised and its DNA binding and photoinduced DNA cleavage properties were studied. The DNA unwinding results show that it binds through intercalation. Absorption and fluorescence spectroscopy reveal the preference for A/T base pairs as compared to G/C base pairs for the binding. The intercalator produces photoinduced single strand scissions in double helical DNA.     

Proteomic Analysis of Protease Resistant Proteins in the Diabetic Rat Kidney

Glycation induced protein aggregation has been implicated in the development of diabetic complications and neurodegenerative diseases. These aggregates are known to be resistant to proteolytic digestion. Here we report the identification of protease resistant proteins from the streptozotocin induced diabetic rat kidney, which included enzymes in glucose metabolism and stress response proteins. These protease resistant proteins were characterized to be advanced glycation end products modified and ubiquitinated by immunological and mass spectrometry analysis. Further, diabetic rat kidney exhibited significantly impaired proteasomal activity. The functional analysis of identified physiologically important enzymes showed that their activity was reduced in diabetic condition. Loss of functional activity of these proteins was compensated by enhanced gene expression. Aggregation prone regions were predicted by in silico analysis and compared with advanced glycation end products modification sites. These findings suggested that the accumulation of protein aggregates is an inevitable consequence of impaired proteasomal activity and protease resistance due to advanced glycation end products modification.One of the foremost causes of diabetic complications is formation of sugar-derived substances called advanced glycation end products (AGEs),¹ which affect target cell through altered protein structure- function, matrix-matrix/matrix-cell interaction, and by activation of receptor for AGE (RAGE) signaling pathway (1). Although the accumulation of AGEs is a slow process in healthy individuals, their formation is markedly accelerated in diabetes because of hyperglycemia (2). AGE-modified proteins are thermostable and resistant to denaturation. The stability of proteins is believed to be because of additional negative charge (highly oxidized state) brought by AGE modification of proteins, which may contribute to protease resistance (3). Glycation induced protease resistance has been studied in collagen (4–6) and amyloid (7). In addition to glycation, impairment in the proteasomal function may facilitate accumulation of protease resistant protein aggregates in diabetes. Proteasome mediated protein degradation is a central quality control mechanism in the cell. Activity of proteasome is affected during aging (8) and physiological disorders like diabetes (9) resulting in accumulation of ubiquitinated protein aggregates. In muscle extract of diabetic rats, accumulation of toxic glycated proteins was observed because of decreased proteasomal activity (6–9). This proteolytic system is of particular importance in protecting cells against adverse conditions, such as heat shock, glycation, or oxidative stress. However, when the generation of damaged proteins exceeds the capacity of the cell to degrade them, they are progressively accumulated leading to cytotoxicity (10). Severely aggregated, cross-linked, and oxidized proteins are poor substrates for degradation and inhibit the proteasomal activity (11).The kidney is one of the main organs affected in diabetes caused by accumulation of AGEs. Proteins of extracellular matrix, kidney, as well as proteins from circulation, get AGE modified and trapped in the kidney (12). Both intracellular and extracellular AGEs have been observed in the diabetic kidney. Extracellular AGEs interact with the RAGE leading to apoptosis and inflammation (13), whereas intracellular AGEs are formed because of various dicarbonyls. Eventually, both types of the AGEs contribute to kidney damage (14). Furthermore, methyl glyoxal, a highly reactive dicarbonyl covalently modifies the 20S proteasome, decreasing its activity in the diabetic kidney (15). Together AGE modification and decreased proteasomal function may be responsible for the accumulation of protease resistant proteins (PRPs) in the diabetic kidney. In our previous study, we have reported the presence of AGE modified proteins in the kidney of the streptozotocin (STZ) induced diabetic rat (12). The current work is inspired by a DARTS (drug affinity responsive target stability) approach, wherein the drug targets are relatively less susceptible to protease action on drug binding (16). A similar approach was adopted here to identify protease resistant proteins from the diabetic kidney. These proteins were characterized to be AGE modified and ubiquitinated by Western blot analysis and mass spectrometry. Functional characterization and expression analysis of some of the identified proteins was performed to gain insight into the consequences of these modifications in diabetes. Further, aggregation prone regions in these proteins were predicted by the in silico approach. These findings shed light on the role of identified PRPs in diabetic complications.     

Studies on high altitude saxicolous-Cyanophyta XI - On the morphology of Petalonema borzii sp. nov.

Abstract

The morphology of a new species of Petalonema Berk collected under a saxicolous habitat at 2900 m above sea level in the Singalila Range, Eastern Himalayas, during the Botanical Expedition of May 1974, was critically studied and named as Petalonema borzii sp. nov. The same alga was collected again on 28 Nov. 1982 from the Singalila Range at an altitude of 2500 m above sea level.     

A Novel Technique for Isolation of Pure Sperm Heads from Disintegrated Mammalian Spermatozoa

Abstract

The phenomenon of differential charge distribution on sperm surface membrane has been utilised here in a low e.m.f. (electro motive force) capillary electrophoresis system to effect separation of sperm heads from disintegrated mixed spermatozoal subfractions. Washed caudal sperm of goat (Black Bengal variety) and ejaculated washed human sperm were fractionated by sonication into head, mid-piece and tail portions. Routine techniques of density gradient centrifugation on Percoll and/or sucrose were performed with sonicated spermatozoa for separation into their respective subfractions. The products obtained were not free of contamination in either case. Mixed sperm fractions when subjected to the afore mentioned modified capillary electrophoresis technique only the head pieces exhibited high affinity for migration towards the cathode terminal. With this method around 50% of the total sperm heads were separated and collected in absolutely pure form at the cathode side within 2 hrs. at 150 volts (V) and 1.5 milliampere (mA) current at 37.5°C. A 4 cm. long capillary tube with a bore size 1.2 mm. was used for this purpose.     

Lignocellulose derived functional oligosaccharides: production,properties, and health benefits

Abstract

Lignocellulosic biomass (LB) is the renewable feedstock for the production of fuel/energy, feed/food, chemicals, and materials. LB could also be the versatile source of the functional oligosaccharides, which are non-digestible food ingredients having numerous applications in food, cosmetics, pharmaceutical industries, and others. The burgeoning functional food demand is expected to be more than US$440 billion in 2022. Because of higher stability at low pH and high temperature, oligosaccharides stimulate the growth of prebiotic bifidobacteria and lactic acid bacteria. Xylooligosaccharides (XOS) are major constituents of oligosaccharides consisting of 2–7 xylose monomeric units linked via β-(1,4)-linkages. XOS can be obtained from various agro-residues by thermochemical pretreatment, enzymatic or chemoenzymatic methods. While thermochemical methods are fast, reproducible, enzymatic methods are substrate specific, costly, and produce minimum side products. Enzymatic methods are preferred for the production of food grade and pharmaceutically important oligosaccharides. XOS are potent prebiotics having antioxidant properties and enhance the bio-adsorption of calcium and improving bowel functions, etc. LB can cater to the increasing demand of oligosaccharides because of their foreseeable amount and the advancements in technology to recover oligosaccharides. This paper summarizes the methods for oligosaccharides production from LB, classification, and benefits of oligosaccharides on human health.     

Five-factor-at-a-time (FFAT) approach for optimal production of an extracellular RNase from Bacillus safensis RB-5

Abstract

A Gram-positive, rod-shaped, endospore-forming, and RNA-degrading bacterium RB-5 was isolated from a soil sample. Based on 16-rDNA gene sequence, the bacterium RB-5 was identified as Bacillus safensis (Accession number KX443714.1). The bacterium appeared to be related to Bacillus safensis KL-052, an other-member of genus Bacillus. One-factor-at-a-time (OFAT) and Response Surface Methodology (RSM) statistical approaches were used to optimize the fermentation broth to obtain an improved extracellular RNase production from B. safensis RB-5. These approaches improved RNase activity of B. safensis KL-052 from 4.26 to 7.85?U/mL. The OFAT approach was used to study the effects of supplementation of carbon, nitrogen and physical conditions, which included temperature, pH and agitation rate on extracellular RNase production by B. safensis KL-052. Five variables screened by Central Composite Design (CCD) were employed to evaluate their interactive effects on RNase production by the organism. CCD selected 2⁵ factorial values obtained by the statistical approach were peptone 1.13% (w/v), sodium nitrate 1.13% (w/v), MgSO₄ 0.06% (w/v), pH 8.5, and temperature 35?°C for RNase production by B. safensis. The highest predicted value of RNase was 7.05?U/ml while actual obtained value was 7.85?U/ml that was ～84% and 1.84-fold higher than OFAT approach.     

Synthesis and Enzymatic Transformations of 5-Halo-6-Methoxy-5,6-Dihydro Derivatives of 5-[1-Methoxy-2-halo(or 2,2-dihalo)ethyl]-2′-deoxyuridines as Potential Herpes Simplex Virus Inhibitors

The 5-halo-6-methoxy-5,6-dihydro derivatives of 5-[1-methoxy-2-halo(or 2,2-dihalo)ethyl]-2′-deoxyuridines (3-12) were synthesized and investigated as potential anti-herpes agents. These 5,6-dihydro derivatives were designed to act as potential prodrugs to 5-[1-methoxy-2-halo(or 2,2-dihalo)ethyl]-2′-deoxyuridines (2a-e), with enhanced metabolic stability, and ready conversion to the parent molecules. These 5,6-disubstituted-5,6-dihydro analogs are stable to E. coli thymidine phosphorylase, and undergo regeneration of the 5,6-olefinic bond to provide parent moieties (2a-e), upon incubation with glutathione at 37°C. The compounds (3-12) themselves were found to be non-inhibitory against herpes simplex virus type-1 (HSV-1), likely due in part to their inability to undergo conversion to parent compounds in cell culture medium.     

A novel lincRNA identified in buffalo oocytes with protein binding characteristics could hold the key for oocyte competence

Molecular Biology Reports - Studying the maternal oocyte-specific genes, in farm animals is a significant step towards delineating the underlying mechanisms that regulate oocyte quality, early...     

Degradation of chlorpyriphos and polyethylene by endosymbiotic bacteria from citrus mealybug

Chlorpyriphos is one of the major organophosphorus pesticides used widely to control a range of insect pests across several crops. This insecticide is hazardous to the environment and toxic to mammals, thus, it is essential to remove the same from the environment. Similarly, use of polythene is also increasing day by day. Therefore, it is highly important to identify ways to degrade chlorpyriphos and other pesticides from the environment. We studied the degradation of chlorpyriphos and polyethylene by Citrus mealybug (Planococcus citri) bacterial endosymbionts such as Bacillus licheniformis, Pseudomonas cereus, Pseudomonas putida and Bacillus subtilis. This investigation revealed that bacterial endosymbionts use the polythene as a source of carbon and solubilize them by their enzymatic machinery. The degradation of polyethylene by endosymbionts showed a significant reduction in weight of polyethylene sheet after 15, 30 and 45 days of treatment. The SEM images showed localized degradation of the polyethylene around the bacterial cells in the biofilm. Further, the tensile strength (percentage elongation) was significantly reduced after 45 days of incubation. The weight of paraffin wax showed significant reduction in B. cereus. A significant reduction in total amount of chlorpyriphos in soil was observed at an interval of 7, 14 and 21 days after treatment by the bacterial isolates. Among the bacteria, B. cereus and P. putida were found to be most effective. The results from this study show that endosymbionts can be significantly implicated in degrading chlorpyriphos and polyethylene from the environment.