Effect of acute aluminum phosphide exposure on rats: a biochemical and histological correlation.

Aluminum phosphide (AlP), a widely used fumigant and rodenticide leads to high mortality if ingested. Its toxicity is due to phosphine liberated when it comes in contact with moisture. The exact mechanism of action of phosphine is not known. In this study male Wistar rats were used. The animals received a single dose (20mg AlP/kg body weight i.g.) orally. Basic serum biochemical parameters, activity of mitochondrial complexes, antioxidant enzymes and parameters of oxidative stress, individual mitochondrial cytochrome levels were measured along with tissue histopathology and immunostaining for cytochrome c and compared with controls. The serum levels of creatinine kinase-MB, lactate dehydrogenase, magnesium and cortisol were higher (p<0.01); the activities of mitochondrial complexes I, II, IV were observed to be significantly decreased in liver tissue in treated rats (p<0.01). The activity of catalase was lower (p<0.05) with a significant increase in lipid peroxidation (p<0.05) whereas superoxide dismutase and glutathione peroxidase were unaffected in them. There was a significant decrease in all the cytochromes in brain and liver tissues (p<0.05) with the exception of cytochrome b in brain, the levels of which remained same. Histopathology revealed congestion in most organs with centrizonal hemorrhagic necrosis in liver. Ultra structural changes indicating mitochondrial injury was observed in heart, liver and kidney tissues. There was also a marked reduction in the cytochrome-c immunostaining compared to the controls. Toxicity due to AlP appears to result as a consequence of both-energy insufficiency and oxidative stress, with a possible and preferential interaction with the tissue cytochromes.

miR-24-2 controls H2AFX expression regardless of gene copy number alteration and induces apoptosis by targeting antiapoptotic gene BCL-2: a potential for therapeutic intervention.

INTRODUCTION: New levels of gene regulation with microRNA (miR) and gene copy number alterations (CNAs) have been identified as playing a role in various cancers. We have previously reported that sporadic breast cancer tissues exhibit significant alteration in H2AX gene copy number. However, how CNA affects gene expression and what is the role of miR, miR-24-2, known to regulate H2AX expression, in the background of the change in copy number, are not known. Further, many miRs, including miR-24-2, are implicated as playing a role in cell proliferation and apoptosis, but their specific target genes and the pathways contributing to them remain unexplored. METHODS: Changes in gene copy number and mRNA/miR expression were estimated using real-time polymerase chain reaction assays in two mammalian cell lines, MCF-7 and HeLa, and in a set of sporadic breast cancer tissues. In silico analysis was performed to find the putative target for miR-24-2. MCF-7 cells were transfected with precursor miR-24-2 oligonucleotides, and the gene expression levels of BRCA1, BRCA2, ATM, MDM2, TP53, CHEK2, CYT-C, BCL-2, H2AFX and P21 were examined using TaqMan gene expression assays. Apoptosis was measured by flow cytometric detection using annexin V dye. A luciferase assay was performed to confirm BCL-2 as a valid cellular target of miR-24-2. RESULTS: It was observed that H2AX gene expression was negatively correlated with miR-24-2 expression and not in accordance with the gene copy number status, both in cell lines and in sporadic breast tumor tissues. Further, the cells overexpressing miR-24-2 were observed to be hypersensitive to DNA damaging drugs, undergoing apoptotic cell death, suggesting the potentiating effect of mir-24-2-mediated apoptotic induction in human cancer cell lines treated with anticancer drugs. BCL-2 was identified as a novel cellular target of miR-24-2. CONCLUSIONS: mir-24-2 is capable of inducing apoptosis by modulating different apoptotic pathways and targeting BCL-2, an antiapoptotic gene. The study suggests that miR-24-2 is more effective in controlling H2AX gene expression, regardless of the change in gene copy number. Further, the study indicates that combination therapy with miR-24-2 along with an anticancer drug such as cisplatin could provide a new avenue in cancer therapy for patients with tumors otherwise resistant to drugs.

Defining the antigen receptor-dependent regulatory network that induces arrest of cycling immature B-lymphocytes.

BACKGROUND: Engagement of the antigen receptor on immature B-lymphocytes leads to cell cycle arrest, and subsequent apoptosis. This is an essential process for eliminating self reactive B cells during its different stages of development. However, the mechanism by which it is achieved is not completely understood. RESULTS: Here we employed a systems biology approach that combined extensive experimentation with in silico methodologies to chart the network of receptor-activated pathways that mediated the arrest of immature B cells in the G1 phase of the cell cycle. Interestingly, we found that only a sparse network of signaling intermediates was recruited upon engagement of the antigen receptor. This then led to the activation of a restricted subset of transcription factors, with the consequent induction of genes primarily involved in the cell death pathway. Subsequent experiments revealed that the weak initiation of intracellular signaling pathways derived from desensitization of the receptor-proximal protein tyrosine kinase Lyn, to receptor-dependent activation. Intriguingly, the desensitization was a result of the constitutive activation of this kinase in unstimulated cells, which was likely maintained through a regulatory feedback loop involving the p38 MAP kinase. The high basal activity then attenuated the ability of the antigen receptor to recruit Lyn, and thereby also the downstream signaling intermediates. Finally, integration of these results into a mathematical model provided further substantiation to the novel finding that the ground state of the intracellular signaling machinery constitutes an important determinant of the outcome of receptor-induced cellular responses. CONCLUSIONS: Our results identify the global events leading to the G1 arrest and subsequent apoptosis in immature B cells upon receptor activation.

3D cell growth and proliferation on a RGD functionalized nanofibrillar hydrogel based on a conformationally restricted residue containing dipeptide.

Three-dimensional (3D) hydrogels incorporating a compendium of bioactive molecules can allow efficient proliferation and differentiation of cells and can thus act as successful tissue engineering scaffolds. Self-assembled peptide-based hydrogels can be worthy candidates for such applications as peptides are biocompatible, biodegradable and can be easily functionalized with desired moieties. Here, we report 3D growth and proliferation of mammalian cells (HeLa and L929) on a dipeptide hydrogel chemically functionalized with a pentapeptide containing Arg-Gly-Asp (RGD) motif. The method of functionalization is simple, direct and can be adapted to other functional moieties as well. The functionalized gel was noncytotoxic, exhibited enhanced cell growth promoting properties, and promoted 3D growth and proliferation of cells for almost 2 weeks, with simultaneous preservation of their metabolic activities. The presence of effective cell growth supporting properties in a simple and easy to functionalize dipeptide hydrogel is unique and makes it a promising candidate for tissue engineering and cell biological applications.

Altered glucose homeostasis in response to aluminium phosphide induced cellular oxygen deficit in rat.

The present study was designed to analyze the effect of acute aluminium phosphide (ALP) (10 mg/kg body wt.) exposure on the glucose homeostasis in rat liver and brain. ALP has been implicated in the inhibition of cytochrome oxidase causing reduced oxygen uptake and decreased ATP synthesis eventually resulting in cellular energy crisis. A significant decrease in plasma glucose levels in the ALP treated rats has been observed. Therefore, decreased ATP levels coupled with hypoglycemia may further intensify the cellular energy deficits. In order to meet the sudden increase in the local energy demand, the brain tissue utilizes its stored energy in the form of glycogen breakdown as observed by a decrease in the glycogen levels in both liver and brain which was accompanied by a marked increase in the activity of glycogen phosphorylase in both the tissues. The glycolytic rate was found to be enhanced in brain tissue as evident by increased activities of hexokinase and phosphofructokinase enzymes, but decreased in liver of ALP treated rats. Lactate levels were increased in plasma and brain, but decreased in liver of ALP treated rats. Pyruvate levels increased in the plasma and liver, but no change was observed in the brain tissue. ALP did not cause any change in the gluconeogenic enzymes like glucose-6-phosphatase and fructose-1,6-bisphophatase in brain, but a significant increase was observed in the liver. Results of the study showed that ALP induced cellular energy deficit leads to compromised energy status of liver and brain coupled with substantial alterations in glucose homeostasis. However, the activity of glucose-6-phosphate dehydrogenase decreased significantly in both the tissues.

Identification of host-dependent survival factors for intracellular Mycobacterium tuberculosis through an siRNA screen.

The stable infection of host macrophages by Mycobacterium tuberculosis (Mtb) involves, and depends on, the attenuation of the diverse microbicidal responses mounted by the host cell. This is primarily achieved through targeted perturbations of the host cellular signaling machinery. Therefore, in view of the dependency of the pathogen on host molecules for its intracellular survival, we wanted to test whether targeting such factors could provide an alternate route for the therapeutic management of tuberculosis. To first identify components of the host signaling machinery that regulate intracellular survival of Mtb, we performed an siRNA screen against all known kinases and phosphatases in murine macrophages infected with the virulent strain, H37Rv. Several validated targets could be identified by this method where silencing led either to a significant decrease, or enhancement in the intracellular mycobacterial load. To further resolve the functional relevance of these targets, we also screened against these identified targets in cells infected with different strains of multiple drug-resistant mycobacteria which differed in terms of their intracellular growth properties. The results obtained subsequently allowed us to filter the core set of host regulatory molecules that functioned independently of the phenotypic variations exhibited by the pathogen. Then, using a combination of both in vitro and in vivo experimentation, we could demonstrate that at least some of these host factors provide attractive targets for anti-TB drug development. These results provide a "proof-of-concept" demonstration that targeting host factors subverted by intracellular Mtb provides an attractive and feasible strategy for the development of anti-tuberculosis drugs. Importantly, our findings also emphasize the advantage of such an approach by establishing its equal applicability to infections with Mtb strains exhibiting a range of phenotypic diversifications, including multiple drug-resistance. Thus the host factors identified here may potentially be exploited for the development of anti-tuberculosis drugs.

Integration of a phosphatase cascade with the mitogen-activated protein kinase pathway provides for a novel signal processing function.

We mathematically modeled the receptor-dependent mitogen-activated protein kinase (MAPK) signaling by incorporating the regulation through cellular phosphatases. Activation induced the alignment of a phosphatase cascade in parallel with the MAPK pathway. A novel regulatory motif was, thus, generated, providing for the combinatorial control of each MAPK intermediate. This ensured a non-linear mode of signal transmission with the output being shaped by the balance between the strength of input signal and the activity gradient along the phosphatase axis. Shifts in this balance yielded modulations in topology of the motif, thereby expanding the repertoire of output responses. Thus, we identify an added dimension to signal processing wherein the output response to an external stimulus is additionally filtered through indicators that define the phenotypic status of the cell.

Impaired mitochondrial energy metabolism and kinetic properties of cytochrome oxidase following acute aluminium phosphide exposure in rat liver.

The present study was designed with an aim to analyze the effect of acute aluminium phosphide (ALP) exposure (10mg/kg b.wt, intragastrically) on the kinetic characteristics of cytochrome oxidase and energy metabolism in male Wistar rat liver mitochondria. Liver mitochondrial preparations from ALP-treated rats exhibited significant decrease (66%) in the activity of cytochrome oxidase suggesting that there was a decrease in the catalytic efficiency of the active oxidase molecules on ALP treatment. The decreased activity of cytochrome oxidase with altered NADH and succinic dehydrogenase activities might have contributed towards a significant decline in state 3 and state 4 respiration as observed. These alterations in the electron transport chain complexes in turn adversely affected the ATP synthesis rate as well as ATP levels in the mitochondria isolated from treated rats. The alterations in the respiratory chain, was followed by enhanced lipid peroxidation in rat liver mitochondria which might have further contributed to change in the fluidity of membrane as depicted by decreased fatty acid content of liver mitochondria. However, no significant change was observed in cholesterol and phospholipids content in our study. The present study thus highlights the significance of altered mitochondrial respiratory chain functions and membrane integrity after acute ALP exposure.

Cellular phosphatases facilitate combinatorial processing of receptor-activated signals.

BACKGROUND: Although reciprocal regulation of protein phosphorylation represents a key aspect of signal transduction, a larger perspective on how these various interactions integrate to contribute towards signal processing is presently unclear. For example, a key unanswered question is that of how phosphatase-mediated regulation of phosphorylation at the individual nodes of the signaling network translates into modulation of the net signal output and, thereby, the cellular phenotypic response. RESULTS: To address the above question we, in the present study, examined the dynamics of signaling from the B cell antigen receptor (BCR) under conditions where individual cellular phosphatases were selectively depleted by siRNA. Results from such experiments revealed a highly enmeshed structure for the signaling network where each signaling node was linked to multiple phosphatases on the one hand, and each phosphatase to several nodes on the other. This resulted in a configuration where individual signaling intermediates could be influenced by a spectrum of regulatory phosphatases, but with the composition of the spectrum differing from one intermediate to another. Consequently, each node differentially experienced perturbations in phosphatase activity, yielding a unique fingerprint of nodal signals characteristic to that perturbation. This heterogeneity in nodal experiences, to a given perturbation, led to combinatorial manipulation of the corresponding signaling axes for the downstream transcription factors. CONCLUSION: Our cumulative results reveal that it is the tight integration of phosphatases into the signaling network that provides the plasticity by which perturbation-specific information can be transmitted in the form of a multivariate output to the downstream transcription factor network. This output in turn specifies a context-defined response, when translated into the resulting gene expression profile.

Impaired energy metabolism after co-exposure to lead and ethanol.

The neurotoxic effects of lead are controlled by a number of nutritional, physiological and environmental factors. One such factor, ethanol, might affect the neurotoxicity of lead by regulating its absorption and distribution. However, there is little information regarding the possible biochemical mechanism by which ethanol might be affecting the state of neuronal functions in lead-exposed individuals. Therefore, the present investigation involved the effect of alcohol (3 g/kg body weight, intragastrically, for 8 weeks) on lead-induced (50 mg/kg body weight, intragastrically, for 8 weeks) mitochondrial dysfunction in adult rat brain. Ethanol was found to enhance the toxic effects of lead in terms of decreased cellular energy reserves (ATP levels). Co-exposure to lead and ethanol caused marked decline in the rate of mitochondrial respiration as compared to lead alone. Further the activities of various components of the electron transport chain, viz. NADH dehydrogenase, succinate dehydrogenase and cytochrome oxidase depicted a significant decrease in the lead and ethanol co-exposed rats as compared to the lead-treated group. The results of the present study reflect that ethanol makes adult rat brain more vulnerable to the neurotoxic effects of lead in terms of altered mitochondrial energy metabolism.

Effect of aluminium phosphide exposure on kinetic properties of cytochrome oxidase and mitochondrial energy metabolism in rat brain.

This study involves the effect of aluminium phosphide exposure on the kinetic characteristics of cytochrome oxidase and the mitochondrial respiratory chain function in rat brain. Mitochondrial preparations from both control and aluminium phosphide-treated rats demonstrated significant decrease in the maximal activity of cytochrome oxidase (approximately 50%) when expressed per unit membrane protein and on a turnover number basis (nmol/min/nmol haem a). The results indicated that there was a decrease in the catalytic efficiency of the active oxidase molecules on aluminium phosphide treatment. Arrhenius plot characteristics differ for cytochrome oxidase activity in mitochondria isolated from treated and control rats, in the break point of the biphasic plot which was shifted to a higher temperature. The decreased activity of cytochrome oxidase along with altered NADH and succinic dehydrogenase activities might have contributed towards a significant decline in state 3 and state 4 respiration. These alterations in the electron transport chain complexes in turn affected the ATP synthesis rate adversely in the mitochondria, isolated from treated rats. The data reflect the interaction of aluminium phosphide with redox chain components leading to the impairment of the electron transfer along the respiratory chain.