BAG-1 family of cochaperones in the modulation of nuclear receptor action

BAG-1 is a family of cochaperones consisting of at least four polypeptides BAG-1L, BAG-1M/RAP46, BAG-1 and p29. These proteins are translated from the same mRNA at alternative translation initiation sites. They possess conserved carboxy-terminal sequences which enable them to bind and inhibit the action of the molecular chaperone Hsp70/Hsc70. BAG-1 was the first member in the family of the BAG-1 proteins to be isolated. It was identified as an anti-apoptotic protein because of its ability to bind and augment the activity of the anti-death protein, Bcl-2. Since then other BAG-1 proteins have been identified and shown to interact with several cellular factors including nuclear receptors. Recent findings show that the effect of the BAG-1 proteins on nuclear receptors ranges from inhibition to enhancement of the transactivation functions of the receptors. Available data on the negative regulation of glucocorticoid receptor (GR) action by the BAG-1 proteins identify two modes of action: inhibition of the hormone binding activity of the GR and a more direct nuclear action at the level of regulation of the transactivation function of the receptor. In the latter case, the BAG-1 proteins repress DNA binding by the GR in a process that requires prior binding of Hsp70/Hsc70 to the receptor. Positive regulatory action of the BAG-1 proteins on nuclear receptors has also been reported which may involve yet other mechanisms. This review puts together recent findings on the action the BAG-1 proteins and presents them as a novel group of regulators of action of nuclear receptor.     

Potential role of estrogen receptor α (ERα) phosphorylated at Serine in human breast cancer in vivo

Post-translational modifications of proteins are known to be important in protein activity and ERα is known to be phosphorylated at multiple sites within the protein. The exact function of site-specific phosphorylation in ERα is unknown, although several hypotheses have been developed using site-directed mutagenesis and cell culture models. Targeting the ERα at the level of such post-translational modification pathways would be a new and exciting approach to endocrine therapy in breast cancer, but adequate knowledge is lacking with regard to the relevance of site-specific phosphorylation in ERα in human breast cancer in vivo. Recently, antibodies to P-Serine¹¹⁸-ERα and P-Serine¹⁶⁷-ERα, two major sites of phosphorylation in ERα, have become available and some in vivo data are now available to complement studies in cells in culture. However, the in vivo data are somewhat contradictory and limited by the small cohorts used and the lack of standard well-characterized reagents and protocols.     

Phosphorylations of αA- and αB-crystallin

In addition to being refractive proteins in the vertebrate lens, the two α-crystallin polypeptides (αA and αB) are also molecular chaperones that can protect proteins from thermal aggregation. The αB-crystallin polypeptide, a functional member of the small heat shock family, is expressed in many tissues in a developmentally regulated fashion, is stress-inducible, and is overexpressed in many degenerative diseases and some tumors indicating that it plays multiple roles. One possible clue to α-crystallin functions is the fact that both polypeptides are phosphorylated on serine residues by cAMP-dependent and cAMP-independent mechanisms. The cAMP-independent pathway is an autophosphorylation that has been demonstrated in vitro, depends on magnesium and requires cleavage of ATP. Disaggregation of αA-, but not αB-crystallin into tetramers results in an appreciable increase in autophosphorylation activity, reminiscent of other heat shock proteins, and suggests the possibility that changes in the aggregation state of αA-crystallin are involved in yet undiscovered signal transduction pathways. The α-crystallin polypeptides differ with respect to their abilities to undergo cAMP-dependent phosphorylation, with preference given to the αB-crystallin chain. These differences and complexities in α-crystallin phosphorylations, coupled with the differences in expression patterns of the two α-crystallin polypeptides, are consistent with the idea that each polypeptide has distinctive structural and metabolic roles.     

Characterization of CaGSP1, the Candida albicans RAN/GSP1 homologue

Gsp1p is a small nuclear-located GTP binding protein from the yeast Saccharomyces cerevisiae. It is highly conserved among eucaryotic cells and is involved in numerous cellular processes, including nucleocytoplasmic trafficking of macromolecules. To learn more about the GSP1 structure/function, we have characterized its Candida albicans homologue. CaGsp1p is 214 amino acids long and displays 91% identity to the ScGsp1p. There is functional complementation in S. cerevisiae, and its mRNA is constitutively expressed in the diploid C. albicans grown under various physiological conditions. Disruption of both alleles was not possible, suggesting that it could be an essential gene, but heterozygous mutants exhibited genomic instability.     

α3β1 integrin promotes cell survival via multiple interactions between 14-3-3 isoforms and proapoptotic proteins

Laminin-5 and α3β1 integrin promote keratinocyte survival; however, the downstream signaling pathways for laminin-5/α3β1 integrin-mediated cell survival had not been fully established. We report the unexpected finding of multiple interactions between 14-3-3 isoforms and proapoptotic proteins in the survival signaling pathway. Ln5-P4 motif within human laminin-5 α3 chain promotes cell survival and anti-apoptosis by inactivating Bad and YAP. This effect is achieved through the formation of 14-3-3ζ/p-Bad and 14-3-3σ/p-YAP complexes, which is initiated by α3β1 integrin and FAK/PI3K/Akt signaling. These complexes result in cytoplasmic sequestration of Bad and YAP and their subsequent inactivation. An increase in Akt1 activity in cells induces 14-3-3ζ and σ, p-Bad, and p-YAP, promoting cell survival, whereas decreasing Akt activity suppresses the same proteins and inhibits cell survival. Suppression of 14-3-3ζ with RNA-interference inhibits cell viability and promotes apoptosis. These results reveal a new mechanism of cell survival whereby the formation of 14-3-3ζ/p-Bad and 14-3-3σ/p-YAP complexes is initiated by laminin-5 stimulation via the α3β1 integrin and FAK/PI3K/Akt signaling pathways, thereby resulting in cell survival and anti-apoptosis.     

On/Off-regulation of phospholipase C-γ1-mediated signal transduction

Alterations in the production and regulation of lipid second messengers can give rise to key molecular lesions that trigger tumorigenesis and cancer progression. Especially, the hydrolysis of membrane phospholipid, phosphatidylinositol 4,5-bisphosphate (PIP2), is mediated by a specific phospholipase C (PLC), which plays important roles in the regulation of various cell functions. PLC generates two intracellular messengers, diacylglycerol and inositol 1,4,5-trisphosphate, which mediate the activation of protein kinase C (PKC) and intracellular Ca²⁺ release, respectively. Among the PLC isozymes, PLC-γ1 contains two src homology (SH) 2 domains and one SH3 domain between the X and Y catalytic domains. The SH2 domains of PLC-γ1 have been implicated in the association between PLC-γ1 and activated receptor tyrosine kinases, and the SH3 domain of PLC-γ1 has been reported to be responsible for the mitogenic effect of PLC-γ1, suggesting that PLC-γ1 exerts other actions that are independent of its lipase activity and appears to be involved in the SH domains. However, the physiological role of SH domains in the regulation of PLC-γ1 is still unclear. We have recently characterized the regulation mechanism of PLC-γ1 through protein-protein interactions. We have elucidated that PLC-γ1 can serve as a guanine nucleotide exchange factor (GEF) for dynamin-1 through direct interaction via its SH3 domain. These results indicate that GEF function of PLC-γ1 for dynamin-1 may link with PLC-γ1's mitogenic actions. The SH3 domain of PLC-γ1 can mediate Sos and PIKE activation by acting as GEF, suggesting that PLC-γ1 plays an essential role on cellular proliferation through protein–protein interaction independent of its enzymatic activity. On the other hand, we have found that Cbl directly interacts with the SH3 domain of PLC-γ1 and inhibits its tyrosine phosphorylation and enzymatic activity, suggesting that PLC-γ1 can be off-regulated by protein–protein interaction. In addition, we demonstrate that Grb2 interacts with tyrosine phosphorylated PLC-γ1 and acts as an inhibitor on PLC-γ1-mediated signaling. These results suggest that Grb2, one of the key regulators of Ras/Raf/MAPK signaling pathway, may participate in the regulation of PLC-γ1. Lastly, PLC-γ1 forms a ternary complex with Jak2 and PTP-1B and negatively regulates GH-induced Jak2 phosphorylation. Taken together, our data strengthen the hypothesis that the interaction between PLC-γ1 and effector proteins plays a key role in on- or off-regulating PLC-γ1-mediated cellular proliferation independent its enzymatic activity. These results can provide novel insights to understand how PLC-γ1 is regulated and involved in cellular growth and proliferation.     

Conversion of α-methyltropate to optically active α-phenylpropionate by tropate-degrading Rhodococcus sp. KU1314

Microorganisms which can assimilate tropate were screened from soil. Among them, we found a microorganism which has an ability to convert α-methyltropate to optically active α-phenylpropionate, and it was identified as Rhodococcus sp. KU1314. Substrate specificity of the microorganism has been studied. When the aryl group was phenyl, 4-methoxyphenyl and 2-naphthyl, the substrate gave optically active α-propionate in good yields. To estimate the reaction mechanism, some compounds considered to be the intermediates were subjected to the reaction. Both enantiomers of α-methyltropate were converted to (R)-α-phenylpropionate with almost the same enantiomeric excess (68 and 72% from R-and S-enantiomers, respectively) and yield (605 and 48% from R-and S-enantiomers, respectively).     

Immunolocalization of the mGluR1b splice variant of the metabotropic glutamate receptor 1 at parallel fiber-Purkinje cell synapses in the rat cerebellar cortex

Several metabotropic glutamate receptor (mGluR) subtypes have been identified in the cerebellar cortex that are targeted to different compartments in cerebellar cells. In this study, preembedding immunocytochemical methods for electron microscopy were used to investigate the subcellular distribution of the mGluR1b splice variant in the rat cerebellar cortex. Dendritic spines of Purkinje cells receiving parallel fiber synaptic terminals were immunoreactive for mGluR1b. With a preembedding immunogold method, approximately 25% of the mGluR1b immunolabeling was observed perisynaptically within 60 nm from the edge of the postsynaptic densities. Values of extrasynaptic gold particles beyond the first 60 nm were maintained at between 10 and 18% along the whole intracellular surface of the dendritic spine membranes of Purkinje cells. For comparison, the distribution of mGluR1a was studied. A predominant (approximately 37%) perisynaptic localization of mGluR1a was seen in dendritic spines of Purkinje cells, dropping the extrasynaptic labeling to 15% in the 60-120-nm bin from the edge of the postsynaptic specialization. Our results reveal that mGluR1b and mGluR1a are localized to the same subcellular compartments in Purkinje cells but that the densities of the perisynaptic and extrasynaptic pools were different for both isoforms. The compartmentalization of mGluR1b and mGluR1a might serve distinct requirements in cerebellar neurotransmission.     

Transformation of 3-hydroxy-steroids by Fusarium moniliforme 7α-hydroxylase

Transformation of physiologically important 3-hydroxy-steroids by the DHEA-induced 7α-hydroxylase of F. moniliforme was investigated. Whereas DHEA was almost totally 7α-hydroxylated, PREG, EPIA and ESTR were only partially converted into their 7α-hydroxylated derivatives because hydroxylation at other undetermined positions as well as reduction of ketone at C17 or C20 into hydroxyl also occurred. Cholesterol was not transformed by the enzyme. Kinetic parameters of the 7α-hydroxylation for these substrates were determined and confirmed that DHEA was the best substrate of the 7α-hydroxylase. Inhibition studies of DHEA 7α-hydroxylation by the other 3-hydroxy-steroids were also carried out and proved that DHEA, PREG, EPIA and ESTR shared the same active site of the enzyme. Induction effects of these steroids were compared, and DHEA appeared to be the best inducer of the 7α-hydroxylase of F. moniliforme.     

Cardiovascular actions of prostaglandins F2α; 15-me-F2α; F1α; F2β and F1β in the cat

Prostaglandin F_2α (5μg/kg, i.v.) causes an increase in pulmonary arterial pressure, decrease in systemic arterial pressure, and reflex bradycardia in the anesthetized cat. The same dose of the 15-methyl analogue of PGF_2α produces the same triad of effects but of greater magnitude and duration. Although prostaglandins F_1α, F_2β and F_1β also cause the same cardiovascular effects as F_2α, there is a decrease in potency for all parameters measured, with PGF_2α>PGF_1α>PGF_2β>PGF_1β. When compared to the actions of PGF_2α in producing an increase in pulmonary arterial pressure, PGs F_1α, F_2β and F_1β were less potent by approximately 10, 100, and 1000 fold respectively.     

Mutual antagonism between dickkopf1 and dickkopf2 regulates Wnt/β-catenin signalling

Wnts are secreted glycoproteins implicated in diverse processes during embryonic patterning in metazoans. They signal through seven-transmembrane receptors of the Frizzled (Fz) family [1] to stabilise β-catenin [2]. Wnts are antagonised by several extracellular inhibitors including the product of the dickkopf1 (dkk1) gene, which was identified in Xenopus embryos and is a member of a multigene family. The dkk1 gene acts upstream of the Wnt pathway component dishevelled but its mechanism of action is unknown [3]. Although the function of Dkk1 as a Wnt inhibitor in vertebrates is well established [3], [4], [5] and [6], the effect of other Dkks on the Wnt/β-catenin pathway is unclear. Here, we report that a related family member, Dkk2, activates rather than inhibits the Wnt/β-catenin signalling pathway in Xenopus embryos. Dkk2 strongly synergised with Wnt receptors of the Fz family to induce Wnt signalling responses. The study identifies Dkk2 as a secreted molecule that is able to activate Wnt/β-catenin signalling. The results suggest that a coordinated interplay between inhibiting dkk1 and activating dkk2 can modulate Fz signalling.     

IGF-II Enhances Trichostatin A-Induced TGFβ1 and p21 Expression in Hep3B Cells

Cell growth and division are controlled through the actions of cyclin-dependent kinases (CDKs) and cyclin dependent kinase inhibitors (CKIs). Treatment of cell lines with Trichostatin A leads to induction of one of these CKIs, p21, and growth arrest. Induction of p21 can also occur through the actions of TGFβ1. Latent TGFβ1 can be activated by the M6P/IGF2R. In the present study we have examined the effect of TSA on members of the IGF axis, the CKIs p21 and p27, and also TGFβ1 in Hep3B cells. The only member of the IGF axis to be affected by treatments was IGF2. Expression of another gene from the same chromosomal location, H19, was also affected. TGFβ1 expression was greatly enhanced by TSA. In addition, both CKIs, p21 and p27, were upregulated by TSA. Effects of adding IGF-II or TGFβ1 to TSA-treated cells on p21 induction were examined. The results show that the induction of p21 by TSA can be modulated by additions of IGF-II whereas addition of TGFβ1 affects its own expression but not p21. In conclusion, the results indicate that the induction of p21 and cell growth arrest caused by Trichostatin A may involve multiple signaling pathways.