In vitro activation of the IkappaB kinase complex by human T-cell leukemia virus type-1 Tax

Human T-cell leukemia virus type-I expresses Tax, a 40-kDa oncoprotein that activates IkappaB kinase (IKK), resulting in constitutive activation of NFkappaB. Herein, we have developed an in vitro signaling assay to analyze IKK complex activation by recombinant Tax. Using this assay in combination with reporter assays, we demonstrate that Tax-mediated activation of IKK is independent of phosphatases. We show that sustained activation of the Tax-mediated activation of the NFkappaB pathway is dependent on an intact Hsp90-IKK complex. By acetylating and thereby preventing activation of the IKK complex by the Yersinia effector YopJ, we demonstrate that Tax-mediated activation of the IKK complex requires a phosphorylation step. Our characterization of an in vitro signaling assay system for the mechanism of Tax-mediated activation of the IKK complex with a variety of mutants and inhibitors results in a working model for the biochemical mechanism of Tax-induced activation.     

Reversible HuR‐microRNA binding controls extracellular export of miR‐122 and augments stress response

microRNAs (miRNAs), the tiny but stable regulatory RNAs in metazoan cells, can undergo selective turnover in presence of specific internal and external cues to control cellular response against the changing environment. We have observed reduction in cellular miR‐122 content, due to their accelerated extracellular export in human hepatic cells starved for small metabolites including amino acids. In this context, a new role of human ELAV protein HuR has been identified. HuR, a negative regulator of miRNA function, accelerates extracellular vesicle (EV)‐mediated export of miRNAs in human cells. In stressed cells, HuR replaces miRNPs from target messages and is both necessary and sufficient for the extracellular export of corresponding miRNAs. HuR could reversibly bind miRNAs to replace them from Ago2 and subsequently itself gets freed from bound miRNAs upon ubiquitination. The ubiquitinated form of HuR is predominantly associated with multivesicular bodies (MVB) where HuR‐unbound miRNAs also reside. These MVB‐associated pool of miRNAs get exported out via EVs thereby delimiting cellular miR‐122 level during starvation. Therefore, by modulating extracellular export of miR‐122, HuR could control stress response in starved human hepatic cells.     

Growth Substances Separated from the Fruits of Cassia fistula

The growth substances of the seeds of Cassia fistula were studied and the changes in the relative levels in the endosperm and embryo (plus cotyledons) with development of the seed were noted. Indoleacetic acid was found to be the major auxin component of the seed almost throughout its growth and development, while acidic inhibitors possibly belonging to β-complex were also noted in bioassay tests. The main source of the IAA in the seed is the endosperm, although measurable amounts are also present in the embryo. While this IAA activity in the endosperm is detectable till maturity of the fruit, it decreases relatively in the embryo to fall to insignificance at maturity of the seed. However, there is indication of the binding of such IAA in the embryo or the cotyledon, which can be released by alkaline hydrolysis but not before the seeds are matured. No such bound auxin could be detected in the endosperm. The inhibitors, on the other hand, are more prominent in the embryo than in the endosperm, particularly with ageing of the fruit. The possible significance of these changes in the growth factors has been discussed in relation to the age of the seed and the development of the embryo inside it.     

Monitoring cholesterol organization in membranes at low concentrations utilizing the wavelength-selective fluorescence approach

We previously showed using a fluorescent analogue of cholesterol (NBD-cholesterol, or 25-[N-[(7-nitrobenz-2-oxa-1,3-diazol-4-yl)-methyl]amino]-27-norcholesterol), that cholesterol may exhibit local organization at low concentrations in membranes by the formation of transbilayer tail-to-tail dimers of cholesterol (Rukmini, R., Rawat, S.S., Biswas, S.C., Chattopadhyay, A., 2001. Biophys. J. 81, 2122-2134). In this report, we have monitored the microenvironmental features of cholesterol monomers and dimers utilizing wavelength-selective fluorescence spectroscopy. Our results utilizing red edge excitation shift (REES) and wavelength-dependent change in fluorescence anisotropy show that the microenvironment around the NBD moieties in the dimer form is more rigid possibly due to steric constraints imposed by the dimer conformation. These results provide new information and are relevant in understanding the organization of cholesterol in membranes at low concentrations.     

Analysis of the subsite specificity of rat insulysin using fluorogenic peptide substrates

Recombinant rat insulysin was shown to cleave the internally quenched fluorogenic peptide 2-aminobenzyl-GGFLRKVGQ-ethylenediamine-2,4-dinitrophenol at the R-K bond, exhibiting a K(m) of 13 microm and a V(max) of 2.6 micromol min(-1) mg(-1). Derivatives of this peptide in which the P(2) leucine or the P(2)' valine were replaced with other residues were used to probe the subsite specificity of the enzyme. Varying the P(2) residue produced a 4-fold range in K(m) and a 7-fold range in k(cat). The nature of the P(2) residue had a significant effect on the site of cleavage. Leucine, isoleucine, valine, and aspartate produced cleavage at the R-K bond. Asparagine produced 36% cleavage at the N-R bond and 64% cleavage at the R-K bond, whereas with alanine or serine the A-R and S-R bonds were the major cleavage sites. With tyrosine, phenylalanine, methionine, or histidine representing the varied residue X, cleavages at F-X, X-R, and R-K were seen, whereas with tryptophan equal cleavage occurred at the F-W and W-R bonds. Variable P(2)' residues produce less of a change in both K(m) and k(cat) and have little influence on the cleavage site. Exceptions are phenylalanine, tyrosine, leucine, and isoleucine, which in addition to producing cleavage at the R-K bond, produce significant cleavage at the L-R bond. Alanine and tyrosine were unique in producing cleavage at the F-L bond. Taken together, these data suggest that insulysin specificity is directed toward the amino side of hydrophobic and basic residues and that the enzyme has an extended substrate binding site.     

Lipase production by Serratia marcescens strain SN5gR isolated from the scat of lion-tailed macaque (Macaca silenus) in Silent Valley National Park, a biodiversity hotspot in India

An extracellular lipase-producing bacterium was isolated from a fecal sample of lion-tailed macaque (Macaca silenus), an endangered Old World monkey that is endemic to the Western Ghats of South India. Morphological, biochemical and molecular analyses identified the bacterium as Serratia marcescens. Production of lipase was investigated in shake-flask culture. Optimum tributyrin concentration of 1.5 % was found to be the most suitable triglyceride to increase lipase production (13.3 U ml^?1). The next best lipid source observed was olive oil (11.94 U ml^?1), followed by castor oil, coconut oil and palm oil. Analyzing the effect of different carbon sources on lipase production revealed that 2 % glucose yielded higher lipase production than the other tested carbon sources. Investigations on suitable nitrogen source for lipase production revealed that 2 % meat extract yielded higher lipase production. The most suitable trace element for maximum lipase production was zinc sulfate, followed by magnesium sulfate and copper sulfate. Partial characterization of the crude lipase revealed that pH 7.0 and a temperature of 40 °C gave optimal lipase activity. Enzymatic activity of the crude sample was retained over a wide temperature range (20–75 °C), and 70 % of enzyme activity was retained at 60 °C. Testing the effect of various organic solvents on lipase activity revealed that hexadecane increased lipase activity by 85 % over the control.     

Differential effect of retinoic acid on ADP and collagen induced platelet aggregation

Retinoic acid (RA) was found to inhibit ADP induced but not collagen induced aggregation of human platelets and the differential action is related to intraplatelet Ca2+ reflux. RA was active at concentrations as low as 10(-7) M and required 20 min prior incubation with platelet suspension in order to inhibit aggregation by ADP. All the steps in ADP induced but not collagen induced platelet activation, viz. hydrolysis of phosphatidyl inositol, phosphorylation of 20, 47 and 250 kDa proteins as well as increased association of actin with Triton X-100 insoluble cytoskeletal matrix were inhibited by RA. RA when used as an agent for differentiation induction of cell progenitor is likely to affect the platelet aggregation and thereby the haemostatic process.     

Computational identification of post-translational modification sites and functional families reveal possible moonlighting role of rotaviral proteins

Rotavirus (RV) diarrhoea causes huge number deaths in children less than 5 years of age. In spite of available vaccines, it has been difficult to combat RV due to large number of antigenically distinct genotypes, high mutation rates, generation of reassortant viruses due to segmented genome. RV is an eukaryotic virus which utilizes host cell machinery for its propagation. Since RV only encodes 12 proteins, post-translational modification (PTM) is important mechanism for modification, which consequently alters their function. A single protein exhibiting different functions in different locations or in different subcellular sites, are known to be 'moonlighting'. So there is a possibility that viral proteins moonlight in separate location and in different time to exhibit diverse cellular effects. Based on the primary sequence, the putative behaviour of proteins in cellular environment can be predicted, which helps to classify them into different functional families with high reliability score. In this study, sites for phosphorylation, glycosylation and SUMOylation of the six RV structural proteins (VP1, VP2, VP3, VP4, VP6 & VP7) & five non-structural proteins (NSP1, NSP2,NSP3,NSP4 & NSP5) and the functional families were predicted. As NSP6 is a very small protein and not required for virus growth & replication, it was not included in the study. Classification of RV proteins revealed multiple putative functions of each structural protein and varied number of PTM sites, indicating that RV proteins may also moonlight depending on requirements during viral life cycle. Targeting the crucial PTM sites on RV structural proteins may have implications in developing future anti-rotaviral strategies.     

Sialylation of Outer Membrane Porin Protein D: A Mechanistic Basis of Antibiotic Uptake in Pseudomonas aeruginosa

Pseudomonas aeruginosa (PA) is an environmentally ubiquitous, extracellular, opportunistic pathogen, associated with severe infections of immune-compromised host. We demonstrated earlier the presence of both α2,3- and α2,6-linked sialic acids (Sias) on PA (PA^+Sias) and normal human serum is their source of Sias. PA^+Sias showed decreased complement deposition and exhibited enhanced association with immune-cells through sialic acid binding immunoglobulin like lectins (Siglecs). Such Sias-siglec-9 interaction between PA^+Sias and neutrophils helped to subvert host immunity. Additionally, PA^+Sias showed more resistant to β-lactam antibiotics as reflected in their minimum inhibitory concentration required to inhibit the growth of 50% than PA^−Sias. Accordingly, we have affinity purified sialoglycoproteins of PA^+Sias. They were electrophoresed and identified by matrix-assisted laser desorption-ionization time-of-flight/time-of-flight mass spectrometry analysis. Sequence study indicated the presence of a few α2,6-linked, α2,3-linked, and both α2,3- and α2,6-linked sialylated proteins in PA. The outer membrane porin protein D (OprD), a specialized channel-forming protein, responsible for uptake of β-lactam antibiotics, is one such identified sialoglycoprotein. Accordingly, sialylated (OprD^+Sias) and non-sialylated (OprD^−Sias) porin proteins were separately purified by using anion exchange chromatography. Sialylation of purified OprD^+Sias was confirmed by several analytical and biochemical procedures. Profiling of glycan structures revealed three sialylated N-glycans and two sialylated O-glycans in OprD^+Sias. In contrast, OprD^−Sias exhibit only one sialylated N-glycans. OprD^−Sias interacts with β-lactam antibiotics more than OprD^+Sias as demonstrated by surface plasmon resonance study. Lyposome-swelling assay further exhibited that antibiotics have more capability to penetrate through OprD^−Sias purified from four clinical isolates of PA. Taken together, it may be envisaged that sialic acids on OprD protein play important role toward the uptake of commonly used antibiotics in PA^+Sias. This might be one of the new mechanisms of PA for β-lactam antibiotic uptake.Sialic acids (Sias)¹ are nine carbon atom containing acidic residues characteristically found in the terminal position of glycoproteins and glycolipids (1–4). Structural diversity of sialic acids is because of the modification of one or more hydroxyl groups in various positions of the core structure by different groups like acetyl-, methyl-, sulfate-, lactyl-, or phosphate (1, 5–7). More than fifty derivatives of Sias has been reported both in vertebrate and invertebrate systems. It functions as ligand for various cellular communications and also act as masking element for glycoconjugates (8–12).Sialic acid binding immunoglobulins (Ig)-like lectins (siglecs) selectively expressed on the hematopoetic cells and interact with an array of linkage-specific Sias on a glycan structure express on the same cells or other cells (13). Siglecs can also recognize terminal sialylated glycoconjugates on several pathogens (14–16). After recognizing, they carry out various functions like internalization, attenuation of inflammation, restraining cellular activation along with inhibition of natural killer cell activation (17).Pseudomonas aeruginosa (PA) is a Gram-negative, rod-shaped bacterium. This human pathogen has remarkable capacity to cause diseases in immune compromised hosts. This colonizing microbial pathogen is responsible for infection in chronic cystic fibrosis, nosocomial infections; severe burn, transplantation, cancer, and AIDS and other immuno-supressed patients (18).We have reported earlier the presence of linkage-specific Sias on PA. Normal human serum (NHS) is possibly one of the sources of these Sias (19). PA utilizes these Sias to interact through siglecs present on the surface of different immune cells. PA^+Sias showed enhanced association with neutrophils through α2,3-linked Sias-siglec-9 interaction which facilitated their survival by subverting innate immune function of host (20).The treatment of PA-infected patient depends upon the extent of the disease and the concerned organs. Conventional β-lactam, cephalosporins, and aminoglycosides group of antibiotics are most common for such treatment (21). β-lactam antibiotics inhibit cell wall synthesis by disrupting the synthesis of the peptidoglycan layer of bacterial cell walls (22). When PA showed resistant to β-lactam antibiotics, new generation of β-lactam with increased doses or other broad spectrum antibiotics like tetracyclines or fluoroquinolones are prescribed (23). PA isolates from intensive care unit (ICU) patients in general showed higher rates of β-lactam resistance among other hospitalized patients (24). The increasing frequency of resistance to ceftazidime, piperacillin, imipenem, fluoroquinolone, and aminoglycoside were 36.6%, 22.3%, 22.8%, 23.8%, and 17.8% respectively in PA (25).The outer membrane of Gram-negative bacteria is, in general, semipermeable through which hydrophilic molecules including antibiotics of below exclusion limit size (0.6 kDa) can pass through the channel-forming proteins generally called porins e.g. OprD, OprF, OprG etc. (26, 27). PA shows lower outer membrane permeability with respect to many other Gram-negative bacteria like Acinetobacter baumannii, Stenotrophomonas maltophilia, Burkholderia cepacia, hence the diffusion rate of β-lactam antibiotics is decreased (27).Additionally, PA uses MexA-MexB-OprM, MexC-MexD-OprJ, MexE-MexF-OprN, and MexX-MexY-OprM as efflux pumps along with important regulatory factors MexR/NalB, NfxB, NfxC/MexT, and MexZ respectively on their membrane to pump out undesirable chemicals, detergent and antibiotics (28–32). Other Gram-negative bacteria also uses similar types of efflux pumps for such purposes. Moreover, PA produces antibiotic-resistance genes by some mutation (33). Furthermore, β-lactamase and aminoglycoside-modifying enzymes produced by PA are capable of breaking down the antibiotics (34). Alternatively, these enzymes can directly modify the drug. Hence these antibiotics become functionally ineffective (27).The presence of lipopolysaccharides (LPS) containing O-specific polysaccharides with tri-saccharide repeats of 2-acetamido-2,6-dideoxy-d-glucose, 2-acetamido-2,6-dideoxy-d-galactose, and 5-acetamido-3,5,7,9-tetyradeoxy-7-[(R)-3-hydroxybutyramidol]-3-l-glycerol-l-manno-nonulosonic acid are known for PA serogroup O11 (35). The genes for key enzymes required for complex protein glycosylation are found in the genome of PA14 (36). Moreover, glycosylation in PA1244 has been reported in the form of an O-linked glycan in pilin (37). A cluster of seven genes known as the pel genes, encode proteins with similarity to components involved in polysaccharide biogenesis. Among these genes, PelF is a putative glycosyltransferase (GT) of the type IV glycosyltransferase (GT4) family (36). PA secreted sialidase in culture medium (38). Genome search reveals that PA14 has the sialidase gene, which may be responsible for cleaving sialic acids (39). PA1 also has sialic acid transporter gene, which possibly transport sialic acids inside the cells (Gene ID: 17688338, Source: http://www.ncbi.nlm.nih.gov/gene/17688338). Additionally, CMP-sialic acid transferase, which is responsible for converting sialic acids to CMP-sialic acid, was purified from PAO12 (40). This enzyme shows close similarity with the enzyme found in E. coli.However, PA being such a notorious organism, it might have many other different mechanisms to fight against antibiotics for their survival. Therefore, it is worthwhile to explore newer mechanism to understand how antibiotics penetrate inside this bacterium. Here we addressed the following questions. Does sialylation of glycoproteins demonstrated on PA play any role in the entry of antibiotics that might facilitate their survival within host?Accordingly, we have affinity purified a few sialoglycoproteins from PA. Sequence analysis identified twenty six α2,3- and α2,6-linked sialoglycoproteins. One such identified sialoglycoprotein is OprD porin protein. The presence of Sias on OprD was conclusively confirmed. We have demonstrated that Sias on OprD protein isolated four different clinical isolates hampered its interaction with β-lactam antibiotics. This might be one of the new mechanisms for β-lactam antibiotic resistance of PA and thereby facilitates their survival in host.