Calreticulin transacylase: Genesis,mechanism of action and biological applications

Our earlier investigations have identified a unique enzyme in the endoplasmic reticulum (ER) termed Acetoxy Drug: Protein Transacetylase (TAase) catalyzing the transfer of acetyl group from polyphenolic acetates (PA) to certain receptor proteins (RP). An elegant assay procedure for TAase was developed based on the inhibition of glutathione S-transferase (GST) due to acetylation by a model acetoxycoumarin, 7, 8-Diacetoxy-4-methylcoumarin (DAMC). TAase purified from various mammalian tissue microsomes to homogeneity exhibited a molecular weight (M.wt) of 55 kDa. Further, by N-terminal sequencing TAase was identified as Calreticulin (CR), a multifunctional Ca²⁺-binding protein in ER lumen. The identity of TAase with CR was evidenced by proteomics studies such as immunoreactivity with anti-CR antibody and mass spectrometry. This function of CR was termed Calreticulin transacetylase (CRTAase). CRTAase was also found to mediate the transfer of acetyl group from DAMC to RP such as NADPH Cytochrome c Reductase (CYPR) and Nitric Oxide Synthase (NOS). The autoacetylation of purified human placental CRTAase concomitant with the acetylation of RP by DAMC was observed. CRTAase activity was found to be inhibited by Ca²⁺. Our investigations on the individual domains (N, P and C) of CR from a nematode Haemonchus contortus revealed that the P-domain alone was found to possess CRTAase activity. Based on the observation that the autoacetylated CR was a stable intermediate in the CRTAase catalyzed protein acetylation by PA, a putative mechanism was proposed. Further, CRTAase was also found capable of transferring propionyl group from a propoxy derivative of polyphenol, 7,8-Dipropoxy-4-methylcoumarin (DPMC) to RP and concomitant autopropionylation of CR was encountered. Hence, CRTAase was assigned the general term Calreticulin Transacylase. Also, CRTAase was found to act upon the biological acyl group donors, acetyl CoA and propionyl CoA. CRTAase mediated modulation of specific functional proteins by way of acylation was exploited to elicit the biological applications of PA.     

4-Methylcoumarins as antioxidants: Scavenging of peroxyl radicals and inhibition of human low-density lipoprotein oxidation

The antioxidant activity of eight synthetic 4-methylcoumarins was systematically studied. The antioxidant capacity was measured using: (i) a competition kinetic test, to measure the relative capacity to quench peroxyl radical; (ii) the in vitro oxidative modification of human low-density lipoprotein, initiated by AAPH or catalyzed by copper. In both models, the ortho-OH substitutes were found to be better antioxidant than the meta one. The most efficient antioxidant was the 7,8-dihydroxy-4-methylcoumarin and the corresponding diacetoxy-substituted was unexpectedly a good antioxidant. Finally, the presence of an ethoxycarbonylethyl substituent at the C-3 position increased the antioxidant capacity of both 7,8-dihydroxy-4-methylcoumarin and 7,8-diacetoxy-4-methylcoumarin.     

Maneb and paraquat-induced modulation of toxicant responsive genes in the rat liver: comparison with polymorphonuclear leukocytes

Experimental studies have shown that toxicant responsive genes, cytochrome P450s (CYPs) and glutathione S-transferases (GSTs) play a critical role in pesticide-induced toxicity. CYPs play pro-oxidant role and GSTs offer protection in maneb (MB) and paraquat (PQ)-induced brain and lung toxicities. The present study aimed to investigate the effect of repeated exposures of MB and/or PQ on lipid peroxidation (LPO), glutathione content (GSH) and toxicant responsive genes, i.e., CYP1A1, 1A2, 2E1, GSTA4-4, GSTA1-1 and GSTA3-3 in the liver and to correlate the same with polymorphonuclear leukocytes (PMNs). A significant augmentation in LPO and reduction in GSH content was observed in a time of exposure dependent manner in the liver and PMNs of MB and/or PQ treated animals. The expression and catalytic activity of CYP2E1 and GSTA4-4 were significantly increased following MB and/or PQ exposure both in the liver and PMNs. Although the expression of GSTA3-3 was increased, the expression of GSTA1-1 was unaltered after MB and/or PQ treatment in both the liver and PMNs. MB augmented the expression and catalytic activity of CYP1A1 in the liver, however, CYP1A2 was unaffected. PQ, on the other hand, significantly increased hepatic CYP1A2 expression and catalytic activity. MB and/or PQ did not produce any significant changes in CYP1A1 and CYP1A2 in PMNs. The results of the study thus demonstrate that MB and PQ differentially regulate hepatic CYP1A1 and CYP1A2 while LPO, GSH, CYP2E1, GSTA4-4 and GSTA3-3 are modulated in the similar fashions both in the liver and PMNs.     

Structural transition from dimeric to tetrameric i‐motif,caused by the presence of TAA at the 3′‐end of human telomeric C‐rich sequence

Widely dispersed in genomic DNA, the tandem C‐rich repetitive stretches may fold below physiological pH, into i‐motif structures, stabilized by C·C⁺ pairing. Herein, structural status of a 9‐mer stretch d(CCCTAACCC), [the truncated double repeat of human telomeric sequence], and its extended version, comprising of additional ? TAA segment at the 3′‐end, representing the complete double repeat d(CCCTAACCCTAA), has been investigated. The pH dependent monophasic UV‐melting, Gel and CD data suggested that while the truncated version adopts a bimolecular i‐motif structure, its complete double repeat (12‐mer) sequence exists in two (bimolecular and tetramolecular) forms. A model is proposed for the tetramolecular i‐motif with conventional C · C⁺ base pairs, additionally stabilized by asymmetric A · A base pairs at the ?3′ TAA flanking ends and Watson–Crick A · T hydrogen bonding between intervening bases on antiparallel strands. Expanding the known topologies of DNA i‐motifs, such atypical geometries of i‐motifs may have implications in their recognition by proteins. © 2009 Wiley Periodicals, Inc. Biopolymers 93: 150–160, 2010. This article was originally published online as an accepted preprint. The “Published Online” date corresponds to the preprint version. You can request a copy of the preprint by emailing the Biopolymers editorial office at biopolymers@wiley.com     

Conformational Changes in the Capsid of a Calicivirus upon Interaction with Its Functional Receptor

Nonenveloped viral capsids are metastable structures that undergo conformational changes during virus entry that lead to interactions of the capsid or capsid fragments with the cell membrane. For members of the Caliciviridae, neither the nature of these structural changes in the capsid nor the factor(s) responsible for inducing these changes is known. Feline junctional adhesion molecule A (fJAM-A) mediates the attachment and infectious viral entry of feline calicivirus (FCV). Here, we show that the infectivity of some FCV isolates is neutralized following incubation with the soluble receptor at 37°C. We used this property to select mutants resistant to preincubation with the soluble receptor. We isolated and sequenced 24 soluble receptor-resistant (srr) mutants and characterized the growth properties and receptor-binding activities of eight mutants. The location of the mutations within the capsid structure of FCV was mapped using a new 3.6-Å structure of native FCV. The srr mutations mapped to the surface of the P2 domain were buried at the protruding domain dimer interface or were present in inaccessible regions of the capsid protein. Coupled with data showing that both the parental FCV and the srr mutants underwent increases in hydrophobicity upon incubation with the soluble receptor at 37°C, these findings indicate that FCV likely undergoes conformational change upon interaction with its receptor. Changes in FCV capsid conformation following its interaction with fJAM-A may be important for subsequent interactions of the capsid with cellular membranes, membrane penetration, and genome delivery.The interactions between viruses and receptors on the surface of host cells strongly influence viral pathogenesis and regulate morbidity and mortality in the host. Virus-receptor interactions determine the types of cells that can be infected, the pathway of entry into the cell, and the efficiency of productive infection. Interactions between nonenveloped virus capsids and their receptor(s) trigger one or more steps required for infectious entry. These steps can include interaction with other receptors, exposure to low pH or endosomal proteases, or other factors. Ultimately, one or more of these interactions induce changes in capsid conformation that result in the exposure of hydrophobic regions or release of a lipid-seeking factor that can interact with and disrupt the limiting cellular membrane to allow the capsid and/or the genome to be delivered to the interior of the cell (reviewed in reference 60).The Caliciviridae are small nonenveloped viruses containing a positive-sense RNA genome (∼7 to 8 kb). Several important disease-causing members of the Caliciviridae, including human noroviruses and rabbit hemorrhagic disease virus, cannot be propagated in tissue culture systems (19, 56). This has slowed progress on studies of the mechanisms of cellular entry of these viruses. In contrast, feline caliciviruses (FCVs) propagate readily in tissue culture, and two cell surface receptor molecules, feline junctional adhesion molecule A (fJAM-A) and α2,6 sialic acid, are known (29, 55).The FCV receptor, fJAM-A, is a type I transmembrane glycoprotein (molecular size of 36 to 41 kDa) member of the immunoglobulin superfamily (IgSF); it consists of an amino-terminal signal peptide, an extracellular domain (composed of two Ig-like domains—a membrane-distal D1 and a membrane-proximal D2), a transmembrane domain, and a short cytoplasmic domain that contains a type II PDZ domain-binding motif (11, 30). We have previously shown that the D1 domain of the fJAM-A ectodomain is necessary and sufficient for FCV binding and that preincubation of FCV with soluble fJAM-A (sfJAM-A) results in virus neutralization (35). Additional roles that fJAM-A might play in FCV entry, however, have not been investigated.Caliciviruses are composed of 180 copies of a single capsid protein. Atomic resolution structures of recombinant virus-like particles of Norwalk virus (genus Norovirus) and native San Miguel sea lion virus (SMSV) virions (genus Vesivirus) indicate that the virion consists of 90 dimers of the capsid protein arranged in T=3 icosahedral symmetry (5, 41). Each capsid monomer contains three structural domains—an N-terminal arm (NTA), the shell (S), and a protruding domain (P) that is further subdivided into P1 and P2 subdomains. The distal subdomain, P2, is structurally conserved between Norwalk virus and SMSV, but there is little sequence conservation. In the primary sequence of the FCV capsid, there are two hypervariable regions that contain neutralizing epitopes (18, 34, 58). The corresponding hypervariable regions (HVRs) of the SMSV capsid structure map to surface-exposed loops. Surface residues at the dimeric interface between two capsid monomers are conserved within individual calicivirus genera, and it has been suggested that this interface is involved in receptor binding (5). A cryo-electron microscopy (cryo-EM) reconstruction of the FCV vaccine strain F9 complexed with the ectodomain of fJAM-A (modeled on the crystal structures of SMSV and human JAM-A, respectively) shows that fJAM-A engages the top of the P2 domain and that binding causes a rotation in the P dimer (1). However, the relatively low resolution and the lack of atomic resolution structures of FCV and fJAM-A prevented precise identification of residues on the viral capsid that contact fJAM-A.A classical approach for identifying virus residues that directly bind or modulate the binding of a receptor is to select for mutant viruses resistant to neutralization with soluble receptors (6, 23, 46). Soluble receptor-resistant (srr) mutants of poliovirus revealed that both surface-exposed and internal residues regulate receptor attachment and conformational changes in the capsid (6, 42). Here, we report 24 srr mutants and the location of their capsid mutations on a 3.6-Å structure of FCV. In addition, we describe the growth kinetics and receptor-binding properties of a subpanel of eight srr mutants and examine changes in capsid hydrophobicity concurrent with the interaction of FCV capsids with sfJAM-A.     

A conceptual framework to analyse the land-use/land-cover changes and its impact on phytodiversity: a case study of North Andaman Islands,India

Phytodiversity is affected both by natural and anthropogenic factors and in Island ecosystems these impacts can devastate or reduce diversity, if the native vegetation is lost. In addition to rich species richness and diversity, Island systems are the sites of high endemism and any threat to these ecosystems will consequently lead to loss and extinction of species. To understand the dynamics including feedbacks of these changes in phytodiversity of North Andaman Islands, a conceptual framework is proposed which focuses on understanding the land-use and land-cover changes and its impact with phytodiversity. In considering land-use and land-cover changes this work highlights the direct and indirect drivers of changes—socio-economic, biophysical and climatic factors. Migration of population, their socio economic needs and government policies were identified as major driving forces threatening the phytodiversity of these Islands. Apart from human beings, natural disasters like tsunami and introduced herbivorous animals like elephants also contributed to forest destruction in these Islands. The integrated analysis based on such framework will provide insights for holistic resource management including ecological conservation.