In vitro demonstration of apoptosis mediated photodynamic activity and NIR nucleus imaging through a novel porphyrin.

We synthesized a novel water-soluble porphyrin THPP and its metalated derivative Zn-THPP having excellent triplet excited state quantum yields and singlet oxygen generation efficiency. When compared to U.S. Food and Drug Administration approved and clinically used sensitizer Photofrin, THPP showed ca. 2-3-fold higher in vitro photodynamic activity in different cell lines under identical conditions. The mechanism of the biological activity of these porphyrin systems has been evaluated through a variety of techniques: 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide (MTT) assay, comet assay, poly(ADP-ribose)polymerase (PARP) cleavage, CM-H(2)DCFDA assay, DNA fragmentation, flow cytometric analysis, fluorescence, and confocal microscopy, which confirm the apoptotic cell death through predominantly reactive oxygen species (ROS). Moreover, THPP showed rapid cellular uptake and are localized in the nucleus of the cells as compared to Hoechst dye and Photofrin, thereby demonstrating its use as an efficient sensitizer in photodynamic therapy and live cell NIR nucleus imaging applications.

αB-crystallin, a small heat shock protein, modulates NF-κB activity in a phosphorylation-dependent manner and protects muscle myoblasts from TNF-α induced cytotoxicity.

αB-crystallin, a member of the small heat shock protein family, has been implicated in various biological functions including response to heat shock, differentiation and apoptosis, the mechanisms of which have not been well understood. Myoblasts, the precursor cells in muscle regeneration, when subjected to growth factor deprivation differentiate to form myotubes or undergo apoptosis. During differentiation, myoblasts express elevated levels of αB-crystallin as well as TNF-α but the connecting link between these proteins in cell signaling is not clearly understood. We have therefore investigated the role of αB-crystallin in TNF-α induced regulation of NF-κB. We demonstrate that in response to TNF-α treatment, αB-crystallin associates with IKKß and activate its kinase activity, facilitating the degradation of phosphorylated I-kBα, a prime step in NF-κB activation. Reducing the level of αB-crystallin using the RNAi approach reduces the translocation of p65, further confirming the role of αB-crystallin in NF-κB activation. Our study shows that the ability of αB-crystallin to activate NF-κB depends on its phosphorylation status. The present study shows that αB-crystallin-dependent NF-κB activation protects myoblasts from TNF-α induced cytoxicity by enhancing the expression of the anti-apoptotic protein, Bcl 2. Thus, our study identifies yet another mechanism by which αB-crystallin exerts its anti-apoptotic activity.

Ubiquitin-proteasome-mediated degradation and synthesis of MyoD is modulated by alphaB-crystallin, a small heat shock protein, during muscle differentiation.

alphaB-crystallin, a small heat shock protein, plays an important role in muscle homeostasis. It gets up-regulated during muscle differentiation and mice lacking alphaB-crystallin die prematurely with extensive muscle wastage. We have examined the role of alphaB-crystallin in muscle development using C2C12 myoblasts as a model system. Over-expression of alphaB-crystallin delays the muscle differentiation program significantly. C2C12 myoblasts over-expressing alphaB-crystallin (CRYAB-C2C12) display defect in cell-cycle exit upon induction of differentiation. During differentiation, CRYAB-C2C12 cells exhibit sustained level of cyclin D1 and delay in p21 and myogenin expression as compared to C2C12 cells. We find less accumulation of MyoD in CRYAB-C2C12 cells than in C2C12 cells. In vivo protein stability studies reveal faster ubiquitin-proteasome-mediated MyoD degradation in CRYAB-C2C12 cells (t(1/2)=1.42 h) than in C2C12 cells (t(1/2)=2.37 h). Immuno-precipitation experiments showed that MyoD gets ubiquitinated at earlier time points in CRYAB-C2C12 cells than in C2C12 cells. Our data reveal alterations in the synthesis and degradation of MyoD in CRYAB-C2C12 cells. The level of alphaB-crystallin as well as its Ser-59 phosphorylated form increases with increasing time of differentiation. Our studies show, inter alia, that alphaB-crystallin modulates myogenesis by altering MyoD level and provide an interesting insight in its role in myogenesis.

Comparison of a novel semi-nested polymerase chain reaction (PCR) with a uniplex PCR for the detection of Acanthamoeba genome in corneal scrapings.

A semi-nested polymerase chain reaction (snPCR) was developed to improve the sensitivity of detection of Acanthamoeba sp. genome from corneal scrapings of Acanthamoeba keratitis patients. The snPCR was developed using a laboratory designed inner forward primer targeting the 450-bp product of the 18s rRNA-gene-based PCR. The snPCR was optimized using 11 Acanthamoeba sp. culture isolates and further applied onto 35 corneal scrapings from keratitis patients. The sensitivity and specificity of the snPCR was compared against conventional methods (smear and/or culture-gold standard) and the uniplex PCR described by Schroeder et al. Eleven out of the 35 corneal scrapings were positive by the gold standard and snPCR, whereas only 3 of these 11 were positive by the uniplex PCR. The clinical sensitivity and specificity of the snPCR was 100% when compared with the gold standard. DNA sequencing was performed on first round amplicons of four culture isolates and one specimen, and all of them were identified as genus Acanthamoeba when compared with the GenBank database sequences. Application of snPCR on the 11 culture isolates yielded amplicons ranging 120-160 bp in size, indicating sequence variation among the different culture isolates. The clinical sensitivity of snPCR was higher than the conventional methods and the uniplex PCR reported earlier.

Changes in cholesterol levels in the plasma membrane modulate cell signaling and regulate cell adhesion and migration on fibronectin.

The number and distribution of lipid molecules, including cholesterol in particular, in the plasma membrane, may play a key role in regulating several physiological processes in cells. We investigated the role of membrane cholesterol in regulating cell shape, adhesion and motility. The acute depletion of cholesterol from the plasma membrane of cells that were well spread and motile on fibronectin caused the rounding of these cells and decreased their adhesion to and motility on fibronectin. These modifications were less pronounced in cells plated on laminin, vitronectin or plastic, indicating that cholesterol-mediated changes in adhesion and motility are more specific for adhesion mediated by fibronectin-specific integrins, such as alpha5beta1. These changes were accompanied by remodeling of the actin cytoskeleton, the spatial reorganization of paxillin in the membrane, and changes to the dynamics of alpha5 integrin and paxillin-rich focal adhesions. Levels of tyrosine phosphorylation at position 576/577 of FAK and Erk1/Erk2 MAP-kinase activity levels were both lower in cholesterol-depleted than in control cells. These levels normalized only on fibronectin when cholesterol was reincorporated into the cell membrane. Thus, membrane cholesterol content has a specific effect on certain signaling pathways specifically involved in regulating cell motility on fibronectin and organization of the actin cytoskeleton.

Association of alphaB-crystallin, a small heat shock protein, with actin: role in modulating actin filament dynamics in vivo.

Disruption of cytoskeletal assembly is one of the early effects of any stress that can ultimately lead to cell death. Stabilization of cytoskeletal assembly, therefore, is a critical event that regulates cell survival under stress. alphaB-crystallin, a small heat shock protein, has been shown to associate with cytoskeletal proteins under normal and stress conditions. Earlier reports suggest that alphaB-crystallin could prevent stress-induced aggregation of actin in vitro. However, the molecular mechanisms by which alphaB-crystallin stabilizes actin filaments in vivo are not known. Using the H9C2 rat cardiomyoblast cell line as a model system, we show that upon heat stress, alphaB-crystallin preferentially partitions from the soluble cytosolic fraction to the insoluble cytoskeletal protein-rich fraction. Confocal microscopic analysis shows that alphaB-crystallin associates with actin filaments during heat stress and the extent of association increases with time. Further, immunoprecipitation experiments show that alphaB-crystallin interacts directly with actin. Treatment of heat-stressed H9C2 cells with the actin depolymerzing agent, cytochalasin B, failed to disorganize actin. We show that this association of alphaB-crystallin with actin is dependent on its phosphorylation status, as treatment of cells with MAPK inhibitors SB202190 or PD98059 results in abrogation of this association. Our results indicate that alphaB-crystallin regulates actin filament dynamics in vivo and protects cells from stress-induced death. Further, our studies suggest that the association of alphaB-crystallin with actin helps maintenance of pinocytosis, a physiological function essential for survival of cells.

Arginine hydrochloride enhances the dynamics of subunit assembly and the chaperone-like activity of alpha-crystallin.

PURPOSE: Alpha-crystallin, a major eye lens protein, bears homology with small heat shock proteins (sHsps) and exhibits molecular chaperone-like activity. Structural perturbation by temperature or low concentrations of denaturants leads to enhancement of its chaperone-like activity. We have earlier demonstrated similar enhancement of chaperone-like activity using biologically compatible solutes such as arginine hydrochloride and aminoguanidine. The purpose of the present study is to get an insight into the mechanism of the arginine induced enhancement of chaperone-like activity of alpha-crystallin. METHODS: The effect of arginine hydrochloride on the chaperone-like activity of alpha-crystallin at 25 degrees C was studied using DTT induced aggregation of insulin as a model system. Changes in the accessibility of the thiol group near the end of the alpha-crystallin domain in the absence and the presence of arginine hydrochloride were studied using dithiobisnitrobenzoic acid. Fluorescence resonance energy transfer studies were performed to investigate changes in the dynamics of the subunit assembly. Urea induced denaturation studies of alpha-crystallin were carried out to investigate structural destabilization of alpha-crystallin, if any, in the presence of arginine hydrochloride. RESULTS: Arginine hydrochloride increases the chaperone-like activity of alpha-crystallin several fold towards DTT induced aggregation of insulin at room temperature. Our study shows that both the extent and the rate of accessibility of the thiol group are increased in the presence of arginine. Fluorescence resonance energy transfer experiments show that arginine hydrochloride significantly increases the subunit exchange between the oligomers of alpha-crystallin. Arginine induced structural perturbation and loosening of subunit assembly of alpha-crystallin leads to overall destabilization of the protein as reflected by the urea denaturation study. CONCLUSIONS: Arginine perturbs the tertiary and quaternary structure of alpha-crystallin and enhances the dynamics of the subunit assembly leading to enhanced chaperone-like activity. Thus, in addition to size, surface hydrophobicity, and charge distribution, the dynamics of the subunit assembly appears to be one of the critical factors that can modulate the chaperone activity.