Residues at the interface between zinc binding and winged helix domains of human RECQ1 play a significant role in DNA strand annealing activity.

RECQ1 is the shortest among the five human RecQ helicases comprising of two RecA like domains, a zinc-binding domain and a RecQ C-terminal domain containing the winged-helix (WH). Mutations or deletions on the tip of a ß-hairpin located in the WH domain are known to abolish the unwinding activity. Interestingly, the same mutations on the ß-hairpin of annealing incompetent RECQ1 mutant (RECQ1T1) have been reported to restore its annealing activity. In an attempt to unravel the strand annealing mechanism, we have crystallized a fragment of RECQ1 encompassing D2-Zn-WH domains harbouring mutations on the ß-hairpin. From our crystal structure data and interface analysis, we have demonstrated that an α-helix located in zinc-binding domain potentially interacts with residues of WH domain, which plays a significant role in strand annealing activity. We have shown that deletion of the α-helix or mutation of specific residues on it restores strand annealing activity of annealing deficient constructs of RECQ1. Our results also demonstrate that mutations on the α-helix induce conformational changes and affects DNA stimulated ATP hydrolysis and unwinding activity of RECQ1. Our study, for the first time, provides insight into the conformational requirements of the WH domain for efficient strand annealing by human RECQ1.

Fluorescently labelled thioacetazone for detecting the interaction with Mycobacterium dehydratases HadAB and HadBC.

Thioacetazone (TAC) used to be a highly affordable, bacteriostatic anti-TB drug but its use has now been restricted, owing to severe side-effects and the frequent appearance of the TAC resistant M. tuberculosis strains. In order to develop new TAC analogues with fewer side-effects, its target enzymes need to be firmly established. It is now hypothesized that TAC, after being activated by a monooxygenase EthA, binds to the dehydratase complex HadAB that finally leads to a covalent modification of HadA, the main partner involved in dehydration. Another dehydratase enzyme, namely HadC in the HadBC complex, is also thought to be a possible target for TAC, for which definitive evidence is lacking. Herein, using a recently exploited azido naphthalimide template attached to thioacetazone and adopting a photo-affinity based labelling technique, coupled with electrophoresis and in-gel visualization, we have successfully demonstrated the involvement of these enzymes including HadBC along with a possible participation of an alternate mycobacterial monooxygenase MymA. In silico studies also revealed strong interactions between the TAC-probe and the concerned enzymes.

Silver Nanodot Decorated Dendritic Copper Foam As a Hydrophobic and Mechano-Chemo Bactericidal Surface.

The present work investigates the time-dependent antibacterial activity of the silver nanodot decorated dendritic copper foam nanostructures against Escherichia coli (Gram-negative) and Bacillus subtilis (Gram-positive) bacteria. An advanced antibacterial and antifouling surface is fabricated utilizing the collective antibacterial properties of silver nanodots, chitosan, and dendritic copper foam nanostructures. The porous network of the Ag nanodot decorated Cu foam is made up of nanodendrites, which reduce the wettability of the surface. Hence, the surface exhibits hydrophobic nature and inhibits the growth of bacterial flora along with the elimination of dead bacterial cells. The fabricated surface exhibits a water contact angle (WCA) of 158.7 ± 0.17°. Specifically, we tested the fabricated material against both the Gram-positive and Gram-negative bacterial models. The antibacterial activity of the fabricated surface is evident from the growth inhibition percentage of bacterial strains of Escherichia coli (72.30 ± 0.60%) and Bacillus subtilis (48.30 ± 1.71%). The micrographs obtained from scanning electron microscopy (SEM), transmission electron microscopy (TEM), and atomic force microscopy (AFM) of the treated cells show the damaged cellular structures of the bacteria, which is strong evidence of successful antibacterial action. The antibacterial effect can be attributed to the synergistic mechano-chemo mode of action involving mechanical disruption of the bacterial cell wall by the nanoprotrusions present on the Cu dendrites along with the chemical interaction of the Ag nanodots with vital intracellular components.

Design and development of a machine for continuous popping and puffing of grains.

Popping/puffing have been traditionally practiced for enhancing storage life, improving organoleptic properties and ease of incorporation in ready-to-eat-foods. Currently, batch type sand and electric popping/puffing machines involving conduction mode of heat transfer are employed. The major drawbacks of these methods are high-energy consumption, scorching of grains, non-uniform product quality, contamination (by sand/ash) and problems in scale-up. Since fluidization is known to increase heat and mass transfer, a continuous fluidized popping/puffing machine (capacity 10-20 kg/h) involving convective mode of heat transfer is designed/developed. Hot-flue gas generating from burning of LPG was used as the eco-friendly fuel. Process parameters such as expansion ratio, fluidization velocity, terminal velocity, carry over velocity, bulk density and voidage were estimated for un-popped and popped/puffed rice, maize, jowar (sorghum) and paddy. Fluidization and carry over velocities for these grains were in the range of 4.18-5.78 m/s and 2.15-6.18 m/s, respectively. Based on the terminal velocity of the grains and volumetric air flow rate of the blower, fluidization chamber diameter was arrived. Chamber diameter of 0.15 m was found to be sufficient to generate required air velocity of 6.89 m/s which met the fluidization and carry over velocities of popped/puffed grains. The designed fluidization chamber was analyzed for heat and mass transfer during popping/puffing. Convective heat and mass transfer coefficients were estimated to be in the range of 103-187 W/m2 °C and 0.124-0.162 m/s, respectively. Theoretical values for total heat and mass transfer were similar to the experimental values.

Characterization of two sugar transporters responsible for efficient xylose uptake in an oleaginous yeast Candida tropicalis SY005.

Microbial conversion of lignocellulosic feedstock to the target bioproduct requires efficient assimilation of its constituent sugars, a large part of which comprises of glucose and xylose. This study aims to identify and characterize sugar transporters capable of xylose uptake in an oleaginous strain of the industrially relevant yeast Candida tropicalis. In silico database mining resulted in two sugar transporter proteins- CtStp1 and CtStp2, containing conserved amino acid residues and motifs that have been previously reported to be involved in xylose transport in other organisms. Several softwares predicted the likelihood of 10-12 transmembrane (TM) helices to be present in both the Stps, while molecular modelling showed 12 TM helices that were organized into a typical structure found in the major facilitator superfamily of transporters. Docking with different sugars also predicted favorable interactions. Heterologous expression in a Saccharomyces cerevisiae strain harboring functional xylose metabolic genes validated the broad substrate specificity of the two Stps. Each transporter supported prominent growth of recombinant S. cerevisiae strains on six sugars including xylose at various concentrations. Expression of CtSTP1 and CtSTP2 along with the xylose metabolic genes in yeast transformants grown in presence of xylose was confirmed by transcript detection. Growth curve and sugar consumption profiles revealed uptake of both glucose and xylose simultaneously by the recombinant yeast strains, though CtStp1 showed relatively less effect of glucose repression in mixed sugars and was a better transporter of xylose than CtStp2. Such glucose-xylose utilizing efficient transporters can be effective tools for developing co-fermenting yeasts through genetic engineering in future, with noteworthy applications in renewable biomass utilization.

Electrodeposited Cu2O Nanopetal Architecture as a Superhydrophobic and Antibacterial Surface.

Bacterial infections being sporadic and uncontrollable demands an urgent paradigm shift in the development of novel antibacterial agents. This work involves the fabrication of Cu2O nanopetals over copper foil that show superlative antibacterial and superhydrophobic properties. A superhydrophobic surface has been fabricated using the electrochemical deposition (ECD) method. Here, it is aimed to establish the superior antibacterial activity as an outcome of the inherent superhydrophobic property of the as-fabricated nanostructures. The present study finds that the elevated value of the water contact angle (154 ± 0.6°) does not allow proper bacterial adhesion, and it is immune from the possibility of biofouling. Specifically, two kinds of bacterial strains have been tested and the time response of the antibacterial activity has been studied over a period of 12 h, taking DH5α Escherichia coli as a Gram-negative model and Bacillus subtilis 168 as a Gram-positive model. Higher antibacterial effects were observed for the Gram-negative model (E. coli) owing to its simplistic cell wall structure which facilitates the easy diffusion of Cu+ ions into the bacterial membrane. The simplicity of the developed method of fabrication along with the superlative superhydrophobic nature and excellent antibacterial property of the material, owing to its synergistic biophysical and biochemical modes of biocidal action, establishes its viability in many applications.

Inhibition of M. tuberculosis ß-ketoacyl CoA reductase FabG4 (Rv0242c) by triazole linked polyphenol-aminobenzene hybrids: comparison with the corresponding gallate counterparts.

Herein we report six novel triazole linked polyphenol-aminobenzene hybrids (3-8) as inhibitors of Mycobacterium tuberculosis FabG4 (Rv0242c), a less explored ß-ketoacyl CoA reductase that has immense potential to be the future anti-tuberculosis drug target due to its possible involvement in drug resistance and latent infection. Novel triazole linked polyphenol-aminobenzene hybrids have been synthesized, characterized and evaluated for their inhibitory activity against FabG4. All of them inhibit FabG4 at low micromolar concentrations. In silico docking study has been carried out to explain the experimental findings. A comparative study of these new inhibitors with previously reported gallate counterparts leads to structure-activity relations (SAR) of substituent linked to N-1 of triazole ring.

Design, synthesis and characterization of novel inhibitors against mycobacterial ß-ketoacyl CoA reductase FabG4.

We report the design and synthesis of triazole-polyphenol hybrid compounds 1 and 2 as inhibitors of the FabG4 (Rv0242c) enzyme of Mycobacterium tuberculosis for the first time. A major advance in this field occurred only a couple of years ago with the X-ray crystal structure of FabG4, which has helped us to design these inhibitors by the computational fragment-based drug design (FBDD) approach. Compound 1 has shown competitive inhibition with an inhibition constant (Ki) value of 3.97 ± 0.02 µM. On the other hand, compound 2 has been found to be a mixed type inhibitor with a Ki value of 0.88 ± 0.01 µM. Thermodynamic analysis using isothermal titration calorimetry (ITC) reveals that both inhibitors bind at the NADH co-factor binding domain. Their MIC values, as determined by resazurin assay against M. smegmatis, indicated their good anti-mycobacterial properties. A preliminary structure-activity relationship (SAR) study supports the design of these inhibitors. These compounds may be possible candidates as lead compounds for alternate anti-tubercular drugs. All of the reductase enzymes of the Mycobacterium family have a similar ketoacyl reductase (KAR) domain. Hence, this work may be extrapolated to find structure-based inhibitors of other reductase enzymes.

Thermal degradation of groundnut oil during continuous and intermittent frying.

The quality of refined groundnut oil, as affected by frying Poori, was assessed with respect to two types of frying operations viz., continuous frying and intermittent frying. Continuous frying was carried out consistently for 8 h, whereas intermittent frying was performed for 2 h everyday for 4 days for a total of 8 frying hours. The purpose of the study was to compare the level of deterioration that occurred during the two operations. Among the parameters studied, peroxide value (11.3 ± 0.26 meqO2/kg), anisidine value (172.4 ± 2.71), diene value (1.57 ± 0.095), oxidized fatty acid (2.6 ± 0.17%) and viscosity (103.8 ± 2.5 mPa s(-1)), were found to be higher after 8 h due to intermittent frying. The corresponding values 4.9 ± 0.15, 133.3 ± 0.49, 0.811 ± 0.04, 0.38 ± 0.023 and 81.8 ± 2.02 were observed in continuous frying. Parameters such as iodine value, unsaturated fatty acids, saponification value and smoke point decreased significantly (P < 0.5) due to intermittent frying. Results showed that intermittent frying caused more quality degradation to GNO than continuous frying.

A structurally novel hemopexin fold protein of rice plays role in chlorophyll degradation.

Proteins containing hemopexin fold domain are suggested to have diverse functions in various living organisms. In order to investigate the structure and function of this type of protein in rice plant (Oryza sativa), the gene encoding a hemopexin fold protein (OsHFP) was cloned, analyzed in silico and characterized. Molecular modeling revealed that the OsHFP is closely related to other hemopexin fold proteins, but is unique with a cylindrical central tunnel as well as extended N- and C-terminal domains. The recombinant OsHFP was found to bind hemin, the oxidized form of heme in vitro. The expression of the single copy OsHFP gene was detected in rice flower buds. Heterologous expression of OsHFP in green leaf tissues resulted in chlorophyll degradation; however, stable expression of OsHFP was observed in transgenic hairy roots, a non-green tissue. The possible role of OsHFP in regulating programmed cell death in anther green tissues of rice is proposed.

Characterization of an alcohol acetyltransferase GcAAT responsible for the production of antifungal volatile esters in endophytic Geotrichum candidum PF005.

Alcohol acetyltransferases (AATs) are a group of enzymes that catalyze the formation of esters from different alcohols and acetyl-CoA. However, these enzymes are not well characterized with regard to synthesis of antifungal compounds. The present study aims to investigate the AAT enzyme from Geotrichum candidum PF005, an endophytic yeast-like fungus that emits fruity scented antifungal volatiles, primarily comprising of acetate esters. After PCR-based cloning of the GcAAT gene, the encoded enzyme was characterized structurally through in silico methods and functionally via heterologous expression in Saccharomyces cerevisiae. In native host, the single copy GcAAT gene exhibited induced expression upon supplementation with metabolic precursors, like L-leucine (Leu) or α-ketoisocaproate (α-KIC). Docking studies using the modelled structure of GcAAT revealed differential but favourable binding interactions for three alcohol substrates (i.e., isoamyl alcohol, isobutyl alcohol and 2-phenylethanol) and the co-substrate acetyl-CoA. Binding sites for both substrate and co-substrate are found to be located inside a tunnel identified in the structure, wherein the H208 of the acetyltransferase conserved motif HXXXD was found at a hydrogen bond distance from the substrate. Functional complementation of GcAAT in S. cerevisiae AAT knockout strain caused 32% decrease in dry biomass weight of the test phytopathogenic fungus, Rhizoctonia solani as compared to the control (AAT knockout strain with empty plasmid) after 72 h of incubation due to the emitted volatiles. When the transformed yeast cells were fed with Leu and α-KIC, the relative abundance of the isoamyl acetate ester increased by 21% and 48%, respectively as compared to the control (without precursor). Further analysis documented that volatiles from α-KIC fed GcAAT transformant exhibited 58% higher antifungal activity against the test fungus R. solani than the control, engendered by increased oxidative stress that led to distorted mycelial morphology and increased hyphal branching. Together, the augmented antifungal effect displayed by the GcAAT expressing S. cerevisiae AAT knockout strain is clearly attributable to the acetate esters, especially isoamyl acetate, which are inherently produced in endophytic G. candidum PF005 as antifungal volatiles.

The C-terminal end of mycobacterial HadBC regulates AcpM interaction during the FAS-II pathway: a structural perspective.

Comprehending the molecular strategies employed by Mycobacterium tuberculosis (Mtb) in FAS-II regulation is of paramount significance for curbing tuberculosis progression. Mtb employs two sets of dehydratases, namely HadAB and HadBC (ß-hydroxyacyl acyl carrier protein dehydratase), for the regulation of the fatty acid synthase (FAS-II) pathway. We utilized a sequence similarity network to discern the basis for the presence of two copies of the dehydratase gene in Mtb. This analysis groups HadC and HadA in different clusters, which could be attributed to the variability in their physiological role with respect to the acyl chain uptake. Our study reveals structural details pertaining to the crystal structure of the last remaining enzyme of the FAS-II pathway. It also provides insights into the highly flexible hot-dog helix and substrate regulatory loop. Additionally, mutational studies assisted in establishing the role of the C-terminal end in HadC of HadBC in the regulation of acyl carrier protein from Mtb-mediated interactions. Complemented with surface plasmon resonance and molecular dynamics simulation studies, the present study provides the first evidence of the molecular mechanisms involved in the differential binding affinity of the acyl carrier protein from Mtb towards both mtbHadAB and mtbHadBC.

High-resolution crystal structure of LpqH, an immunomodulatory surface lipoprotein of Mycobacterium tuberculosis reveals a distinct fold and a conserved cleft on its surface.

Tuberculosis, caused by Mycobacterium tuberculosis, is predominantly a disease of the lungs acquired by inhaling mycobacteria from infected individuals via airborne droplets. In order to facilitate their entry into the alveolar macrophages, mycobacteria have a collection of pathogen-associated molecular patterns (PAMPs) on their surface that are known to detect certain pattern recognition receptors present on the surface of host cells. A major group of these PAMPs includes mycobacterial lipoproteins, of which, the 19 kDa surface antigen LpqH, has been reported to play a critical role in both host-pathogen interactions as well as pleiotropic immune regulation. Despite its crucial involvement in tuberculosis, the detailed structure-function relationship of this protein remains to be explored. Here, we report the high-resolution crystal structure of the non-acylated LpqH (LpqH48-159) at a resolution of 1.26 Å, which adopts a unique fold. Flow cytometry-based experiments show that the protein can bind and induce apoptosis in PMA-activated human monocytic cell line THP-1, indicative of the preservation of functionality of the protein. Furthermore, analysis of conservation of LpqH sequences from Mycobacterium species reveals a patch of conserved residues on the surface which may play a role in its binding partner recognition and hence in host-pathogen interaction.

Design, synthesis and inhibition activity of a novel cyclic enediyne amino acid conjugates against MPtpA.

In course of studies towards the discovery of selective inhibitors of MPtpA, a novel cyclic endiyne malonamic acid has been designed and synthesized. The synthesis involves a crucial intramolecular Knoevenagel reaction. The compound displayed a reversible non-competitive inhibition against MPtpA with inhibition constant K(i) of 22.5 µM. The enediyne acts as a recognition framework in inducing the inhibition and not as a reactive functional moiety. This was confirmed by comparing the inhibiting activity with that of the corresponding saturated cyclic non-enediyne analogue.

Mycobacterial crypto-AcpM as a tool to investigate the consequence of drug binding on its key FAS II partner enzyme HadAB.

Background Mycobacterial FASII pathway is governed by the Protein-Protein Interaction mediated dynamics existent between Acyl Carrier Protein and its partner enzymes. The dehydratase HadAB, involved in the third step of FASII synthesis has remained a key target of drugs like Thiacetazone (TAC) and its consequence on AcpM binding is yet to be deciphered. Owing to the transient nature of these interactions, analysing their implications as a drug target has been exhausting. Methods In this context, we have developed an in vitro method to study the effect of thiocarbamide-containing compounds, TAC and SPA0355 (a thiourea analogue) against mycobacterial HadAB. Additionally, by utilizing crypto-ACP (NBD-tagged Acyl Carrier Protein) as a tool of our choice, we attempted at exploring the effect of TAC and SPA0355 on mycobacterial HadAB. Results SPA0355 behaves at par with TAC and undergoes activation in the presence of monooxygenase EthA thus, bringing about a covalent modification in HadA subunit of HadAB. The crypto-ACP method provides insights into the altered substrate housing capability in HadAB associated with the impediment of its AcpM mediated functionality; an outcome attributed to the repercussions associated with the binding of the aforementioned thiourea compounds. Conclusion This investigation has assisted in unveiling a two-step mechanism undertaken by AcpM for interacting with its corresponding partner protein during acyl chain transfer. General significance This study highlights the alterations brought about by drug binding in the interplay between ACP and HadAB. Additionally, this work for the first time establishes the role of SPA0355 as a promising drug candidate against dehydratase HadAB.

C(2)-Symmetric azobenzene-amino acid conjugates and their inhibition of Subtilisin Kexin Isozyme-1.

C(2)-Symmetric azobenzene-amino acid/peptide hybrids containing stable E-azo moiety have been synthesized. Upon irradiation with long wavelength UV, these compounds isomerized to the Z-form, whose thermal reisomerization to the E isomer slowed down considerably. These compounds exhibited in vitro moderate to strong inhibition of mammalian cellular protease Subtilisin Kexin Isozyme-1, also called Site 1 Protease, which plays vital roles in cholesterol synthesis, lipid metabolism, bone formation, and viral infections.

Design, synthesis and inhibition activity of novel cyclic peptides against protein tyrosine phosphatase A from Mycobacterium tuberculosis.

Mycobacterium tuberculosis, the causative agent for tuberculosis has employed several signalling molecules to sense the host cellular environment and act accordingly. For example, protein tyrosine phosphatase A (MPtpA) of M. tuberculosis, a signalling protein belonging to the tyrosine phosphatase superfamily, is involved in phagocytosis and is active in virulent mycobacterial form. Starting from a ß-lactam framework a new class of structure based cyclic peptide (CP) inhibitors was designed. The synthesis involves a crucial intramolecular transamidation via a ring opening reaction. All the compounds show moderate to good inhibitory activities against MPtpA in micromolar concentrations. The results of inhibition kinetics suggest mixed mode of inhibition. The binding constant determined from circular dichroism (CD) and fluorescence quenching studies shows strong binding of the hydrophilic side chain of CPs with the enzyme active site residues. All these are well supported by docking studies.

Identification and functional characterization of a lipid droplet protein CtLDP1 from an oleaginous yeast Candida tropicalis SY005.

Proteins residing in lipid droplets (LDs) of organisms exhibit diverse physiological roles. Since the LD proteins of yeasts are largely unexplored, we have identified a putative LD protein gene, CtLDP1 in the oleaginous yeast Candida tropicalis SY005 and characterized its function. The increased lipid accumulation in SY005 could be correlated with enhanced (~2.67-fold) expression of the CtLDP1 after low-nitrogen stress. The N-terminal transmembrane domain similar to perilipin proteins and the amphipathic α-helices predicted in silico, presumably aid in targeting the CtLDP1 to LD membranes. Heterologous expression of CtLDP1-mCherry fusion in Saccharomyces cerevisiae revealed localization in LDs, yet the expression of CtLDP1 did not show significant effect on LD formation in transformed cells. Molecular docking showed favourable interactions of the protein with sterol class of molecules, but not with triacylglycerol (TAG); and this was further experimentally verified by co-localization of the mCherry-tagged protein in TAG-deficient (but steryl ester containing) LDs. While oleic acid supplementation caused coalescence of LDs into supersized ones (average diameter = 1.19 ± 0.12 µm; n = 160), this effect was suppressed due to CtLDP1 expression, and the cells mostly exhibited numerous smaller LDs (average diameter = 0.46 ± 0.05 µm; n = 160). Moreover, CtLDP1 expression in pet10Δ knockout strain of S. cerevisiae restored multiple LD formation, indicating functional complementation of the protein. Overall, this study documents functional characterization of an LD-stabilizing protein from an oleaginous strain of Candida genus for the first time, and provides insights on the characteristics of LD proteins in oleaginous yeasts for future metabolic engineering.

RUVBL1/RUVBL2 ATPase Activity Drives PAQosome Maturation, DNA Replication and Radioresistance in Lung Cancer.

RUVBL1 and RUVBL2 (collectively RUVBL1/2) are essential AAA+ ATPases that function as co-chaperones and have been implicated in cancer. Here we investigated the molecular and phenotypic role of RUVBL1/2 ATPase activity in non-small cell lung cancer (NSCLC). We find that RUVBL1/2 are overexpressed in NSCLC patient tumors, with high expression associated with poor survival. Utilizing a specific inhibitor of RUVBL1/2 ATPase activity, we show that RUVBL1/2 ATPase activity is necessary for the maturation or dissociation of the PAQosome, a large RUVBL1/2-dependent multiprotein complex. We also show that RUVBL1/2 have roles in DNA replication, as inhibition of its ATPase activity can cause S-phase arrest, which culminates in cancer cell death via replication catastrophe. While in vivo pharmacological inhibition of RUVBL1/2 results in modest antitumor activity, it synergizes with radiation in NSCLC, but not normal cells, an attractive property for future preclinical development.

Stimulation of indoleacetic acid production in a Rhizobium isolate of Vigna mungo by root nodule phenolic acids.

The influence of endogenous root nodules phenolic acids on indoleacetic acid (IAA) production by its symbiont (Rhizobium) was examined. The root nodules contain higher amount of IAA and phenolic acids than non-nodulated roots. Presence of IAA metabolizing enzymes, IAA oxidase, peroxidase, and polyphenol oxidase indicate the metabolism of IAA in the nodules and roots. Three most abundant endogenous root nodule phenolic acids (protocatechuic acid, 4-hydroxybenzaldehyde and p-coumaric acid) have been identified and their effects on IAA production by the symbiont have been studied in L-tryptophan supplemented yeast extract basal medium. Protocatechuic acid (1.5 microg ml(-1)) showed maximum stimulation (2.15-fold over control) of IAA production in rhizobial culture. These results indicate that the phenolic acids present in the nodule might serve as a stimulator for IAA production by the symbiont (Rhizobium).