Formulation, evaluation and comparison of gels containing different COX-2 inhibitors.

PG synthesis plays major role in inflammation. The enzymes responsible for PG synthesis are cox-1 and cox-2. Cox-1 regulates physiological functions in gut and kidney while cox-2 induces inflammation. Selective cox-2 inhibitors have little effect on cox-1 and thus showed better GI tolerability. The efficacy of new drugs is not greater than that of NSAID's by oral route of administration. In the present study new selective cox-2 inhibitors also showed less efficacy than NSAID'S by topical route of administration. However if current studies confirm the reduced GI toxicity this can be the only advantage of these drugs because these drugs showed less efficacy than NSAID'S by oral and topical routes of administration.

HIP12 is a non-proapoptotic member of a gene family including HIP1, an interacting protein with huntingtin.

Huntingtin-interacting protein I (HIP1) is a membrane-associated protein that interacts with huntingtin, the protein altered in Huntington disease. HIP1 shows homology to Sla2p, a protein essential for the assembly and function of the cytoskeleton and endocytosis in Saccharomyces cerevisiae. We have determined that the HIP1 gene comprises 32 exons spanning approximately 215 kb of genomic DNA and gives rise to two alternate splice forms termed HIP1-1 and HIP1-2. Additionally, we have identified a novel protein termed HIP12 with significant sequence and biochemical similarities to HIP1 and high sequence similarity to Sla2p. HIP12 differs from HIP1 in its pattern of expression both at the mRNA and protein level. However, HIP1 and HIP12 are both found within the brain and show a similar subcellular distribution pattern. In contrast to HIP1, which is toxic in cell culture, HIP12 does not confer toxicity in the same assay systems. Interestingly, HIP12 does not interact with huntingtin but can interact with HIP1. suggesting a potential interaction in vivo that may influence the function of each respective protein.

An actin-binding protein of the Sla2/Huntingtin interacting protein 1 family is a novel component of clathrin-coated pits and vesicles.

The actin cytoskeleton has been implicated in endocytosis, yet few molecules that link these systems have been identified. Here, we have cloned and characterized mHip1R, a protein that is closely related to huntingtin interacting protein 1 (Hip1). These two proteins are mammalian homologues of Sla2p, an actin binding protein important for actin organization and endocytosis in yeast. Sequence alignments and secondary structure predictions verified that mHip1R belongs to the Sla2 protein family. Thus, mHip1R contains an NH(2)-terminal domain homologous to that implicated in Sla2p's endocytic function, three predicted coiled-coils, a leucine zipper, and a talin-like actin-binding domain at the COOH terminus. The talin-like domain of mHip1R binds to F-actin in vitro and colocalizes with F-actin in vivo, indicating that this activity has been conserved from yeast to mammals. mHip1R shows a punctate immunolocalization and is enriched at the cell cortex and in the perinuclear region. We concluded that the cortical localization represents endocytic compartments, because mHip1R colocalizes with clathrin, AP-2, and endocytosed transferrin, and because mHip1R fractionates biochemically with clathrin-coated vesicles. Time-lapse video microscopy of mHip1R-green fluorescence protein (GFP) revealed a blinking behavior similar to that reported for GFP-clathrin, and an actin-dependent inward movement of punctate structures from the cell periphery. These data show that mHip1R is a component of clathrin-coated pits and vesicles and suggest that it might link the endocytic machinery to the actin cytoskeleton.

A cellular stress model for the differential expression of glial lysosomal cathepsins in the aging nervous system.

Activation of the endosomal-lysosomal system and altered expression of various lysosomal hydrolases have been implicated in several senescence-dependent neurodegenerative disorders and occurs, to a lesser extent, in the course of normal brain aging. The progressive accumulation of autofluorescent, peroxidase-positive astrocytic granules represents a highly consistent biomarker of aging in the vertebrate CNS. The sulfhydryl agent cysteamine greatly accelerates the accumulation of these glial inclusions in situ and in primary brain cell cultures. We previously determined that these glial inclusions are derived from abnormal mitochondria which undergo fusion with lysosomal elements in a complex autophagic process. In the present study, we demonstrate that cysteamine suppresses cathepsin B mRNA levels and immunoreactive protein in cultured astroglia, whereas cathepsin D mRNA and protein levels are significantly augmented by CSH exposure in these cells. Moreover, cathepsin D (but not cathepsin B) exhibits robust colocalization to the red autofluorescent inclusions. Concordant with our in vitro observations, cathepsin B immunoreactivity is prominent in the hypothalamic ventromedial nucleus which accumulates few autofluorescent glial inclusions during aging and is relatively inapparent in the heavily granulated hypothalamic arcuate nucleus. Conversely, cathepsin D is prominent in the aging arcuate nucleus where it colocalizes to the autofluorescent inclusions and exhibits scant immunoreactivity in the adjacent ventromedial nuclear complex. In senescent astroglia, oxidative stress may down-regulate the cathepsin B gene as part of a concerted cellular stress (heat shock) response. Glial cathepsin D, on the other hand, resists stress-related inhibition and may play an important role in disposing of oxidatively modified mitochondria in the aging and degenerating nervous system.

Redox perturbations in cysteamine-stressed astroglia: implications for inclusion formation and gliosis in the aging brain.

The aminothiol compound, cysteamine (CSH), induces astrocyte hypertrophy (gliosis) and the appearance of autofluorescent, peroxidase-positive cytoplasmic granules in these cells akin to changes that occur spontaneously in astroglia of the aging periventricular brain. Paradoxically, CSH damages astroglial mitochondria (granule precursors) while protecting these cells from subsequent H2O2 and mechanoenzymatic stress. In this study, in vitro CSH administration significantly increased manganese superoxide dismutase (MnSOD) activity in cultured astroglia. Immunoblot and Northern analyses indicated that MnSOD protein and mRNA levels were increased in cultured astrocytes after 3-6 days of CSH treatment. Systemic administration of CSH also significantly augmented MnSOD activity in the intact diencephalon. CSH caused a pronounced (6-fold), but transient, increase in the level of reduced glutathione (GSH) in cultured astrocytes. In contrast, catalase and glutathione reductase (GR) activities were suppressed, whereas copper-zinc superoxide dismutase (CuZnSOD) activity remained unchanged both in cultured astroglia and in the intact diencephalon following CSH treatment. Glutathione peroxidase (GP) activity was increased after 3 and 48 h of CSH treatment and then declined below control levels in cultured astrocytes. CSH inhibited the formation of thiobarbituric acid-reactive products (TBAR) in whole astrocyte monolayers, although it promoted TBAR formation in suspensions of isolated astroglial mitochondria. CSH-related oxidative stress may accelerate aging-related changes in astroglial mitochondria while conferring cytoprotection to these cells by stimulating the upregulation of various heat shock proteins and MnSOD. These cytoprotective responses may facilitate astrocyte survival and the development of reactive gliosis in the face of concomitant neuronal degeneration. CSH-treated astrocytes may serve as a model for the (dys)regulation of neuroglial MnSOD and other antioxidant enzymes in the aging and degenerating nervous system.

Differential effects of cysteamine on heat shock protein induction and cytoplasmic granulation in astrocytes and glioma cells.

The sulfhydryl agent, cysteamine (CSH), promotes the accumulation of autofluorescent, peroxidase-positive cytoplasmic granules in cultured astroglia akin to those which naturally accumulate in astrocytes of the aging periventricular brain. Both in vitro and in situ, CSH rapidly induces various heat shock proteins (HSP) in astrocytes long before granulation occurs. In the present study, we determined that CSH treatment resulted in an increase in HSP 27, HSP 90 and heme oxygenase (HO-1) at both the protein and mRNA level. We also showed that C6 glioma cells, unlike primary astrocytes, constitutively express HSP 27, HSP 90 and HO-1 at low levels. Moreover, CSH is incapable of eliciting further HSP expression or inducing granulation in the glioma cells. Our results support the hypothesis that the biogenesis of redox-active astrocytic inclusions in CSH-treated glial cultures and in the aging periventricular brain is dependent on an antecedent cellular stress response.