Mutational analysis of TYR gene and its structural consequences in OCA1A

Oculocutaneous albinism type 1A (OCA1A) is the most severe form of albinism characterized by a complete lack of melanin production throughout life and is caused by mutations in the TYR gene. TYR gene codes tyrosinase protein to its relation with melanin formation by knowing the function of these SNPs. Based on the computational approaches, we have analyzed the genetic variations that could change the functional behaviour by altering the structural arrangement in TYR protein which is responsible for OCA1A. Consequences of mutation on TYR structure were observed by analyzing the flexibility behaviour of native and mutant tyrosinase protein. Mutations T373K, N371Y, M370T and P313R were suggested as high deleterious effect on TYR protein and it is responsible for OCA1A which were also endorsed with previous in vivo experimental studies. Based on the quantitative assessment and flexibility analysis of OCA1A variants, T373K showed the most deleterious effect. Our analysis determines that certain mutations can affect the dynamic properties of protein and can lead to disease conditions. This study provides a significant insight into the underlying molecular mechanism involved in albinism associated with OCA1A.     

Action of nicotine and analogs on acetylcholine receptors having mutations of transmitter-binding site residue αG153

A primary target for nicotine is the acetylcholine receptor channel (AChR). Some of the ability of nicotine to activate differentially AChR subtypes has been traced to a transmitter-binding site amino acid that is glycine in lower affinity and lysine in higher affinity AChRs. We studied the effects of mutations of this residue (αG153) in neuromuscular AChRs activated by nicotine and eight other agonists including nornicotine and anabasine. All of the mutations increased the unliganded gating equilibrium constant. The affinity of the resting receptor (K_d) and the net binding energy from the agonist for gating (ΔG_B) were estimated by cross-concentration fitting of single-channel currents. In all but one of the agonist/mutant combinations there was a moderate decrease in K_d and essentially no change in ΔG_B. The exceptional case was nicotine plus lysine, which showed a large, >8,000-fold decrease in K_d but no change in ΔG_B. The extraordinary specificity of this combination leads us to speculate that AChRs with a lysine at position αG153 may be exposed to a nicotine-like compound in vivo.     

Lactobacillus rhamnosus GG antagonizes Giardia intestinalis induced oxidative stress and intestinal disaccharidases: an experimental study

The present study describes the in vivo modulatory potential of Lactobacillus rhamnosus GG (LGG), an effective probiotic, in Giardia intestinalis-infected BALB/c mice. Experimentally, it was observed that oral administration of lactobacilli prior or simultaneous with Giardia trophozoites to mice, efficiently (p < 0.05) reduced both the severity and duration of giardiasis. More specifically, probiotics fed, Giardia-infected mice, showed a significant increase in the levels of antioxidants [reduced glutathione (GSH) and superoxide dismutase (SOD)] and intestinal disaccharidases [sucrase and lactase] and decreased levels of oxidants in the small intestine, in comparison with Giardia-infected mice. Histopathological findings also revealed almost normal cellular morphology of the small intestine in probiotic-fed Giardia-infected mice compared with fused enterocytes, villous atrophy and increased infiltration of lymphocytes in Giardia-infected mice. The results of the present study has shed new light on the anti-oxidative properties of LGG in Giardia mediated tissue injury, thereby suggesting that the effects of probiotic LGG are biologically plausible and could be used as an alternative microbial interference therapy.     

Genomic annotation and validation of bacterial consortium NDMC-1 for enhanced degradation of sugarcane bagasse

This study aims at designing a consortium using rumen bacterial isolates for enhancing the hydrolysis of sugarcane bagasse (SB) for efficient biofuel formation. The microbial population was screened through biochemical and molecular tools along with enzymatic activity to obtain potential isolates for diverse cellulolytic and hemicellulolytic carbohydrate active enzyme (CAZyme). Five strains (Paenibacillus, Bacillus, Enterobacter, and Microbacterium) were selected for designing the consortium NDMC-1. The hydrolytic efficiency of NDMC-1 was determined based on cellulase production with simultaneous rise in monosaccharides, oligosaccharides, and soluble chemical oxygen demand (sCOD) concentration. Cellulolytic machinery of these isolates was further explored using genome sequencing. The isolates selected for consortia NDMC-1 interacted synergistically leading to enhanced cellulase production. Maximal endoglucanase (1.67 μmol ml−1 min−1), exoglucanase (0.69 μmol ml−1 min−1), and β-glucosidase (2.03 μmol ml−1 min−1) activity were achieved with SB as a sole carbon source after 48 h of incubation. Enhancement in SB hydrolysis employing NDMC-1 was evident by the increase in sCOD from 609 to 2589 mg/l and release of 1295 mg/l reducing sugar, comprising 59.8%, 8.23%, and 6.16% of glucose, cellobiose, and cellotriose, respectively, which resulted in 5.5-fold rise in biogas production. On genome annotation, total 472 contigs from glycoside hydrolase family: 84 from Microbacterium arborescens ND21, 72 from Enterobacter cloacae ND22, 61 from Bacillus subtilis ND23, 116 from Paenibacillus polymyxa ND24, and 140 from Paenibacillus polymyxa ND25 were identified. On further analysis, total 33 cellulases, 59 hemicellulases, and 48 esterases were annotated in the reported genomes. This work proposes the application of consortia-based bioprocessing systems over the conventionally favorable single organism approach for efficient hydrolysis of cellulosic substrates to fermentable sugars.     

Prophylactic Potential of Synbiotic (Lactobacillus casei and Inulin) in Malnourished Murine Giardiasis: an Immunological and Ultrastructural Study

Probiotics and Antimicrobial Proteins - Giardiasis is a re-emerging infectious disease with outbreaks reported globally specially in children and malnourished individuals leading to malabsorption,...     

Fluid shear stress stimulates breast cancer cells to display invasive and chemoresistant phenotypes while upregulating PLAU in a 3D bioreactor

Breast cancer cells experience a range of shear stresses in the tumor microenvironment (TME). However most current in vitro three-dimensional (3D) models fail to systematically probe the effects of this biophysical stimuli on cancer cell metastasis, proliferation, and chemoresistance. To investigate the roles of shear stress within the mammary and lung pleural effusion TME, a bioreactor capable of applying shear stress to cells within a 3D extracellular matrix was designed and characterized. Breast cancer cells were encapsulated within an interpenetrating network hydrogel and subjected to shear stress of 5.4 dynes cm⁻² for 72 hr. Finite element modeling assessed shear stress profiles within the bioreactor. Cells exposed to shear stress had significantly higher cellular area and significantly lower circularity, indicating a motile phenotype. Stimulated cells were more proliferative than static controls and showed higher rates of chemoresistance to the anti-neoplastic drug paclitaxel. Fluid shear stress-induced significant upregulation of the PLAU gene and elevated urokinase activity was confirmed through zymography and activity assay. Overall, these results indicate that pulsatile shear stress promotes breast cancer cell proliferation, invasive potential, chemoresistance, and PLAU signaling.