Proteomic analysis of rat prefrontal cortex after chronic valproate treatment.

Valproic acid (VPA) is commonly used to treat bipolar disorder (BD), but its therapeutic role has not been clearly elucidated. To gain insights into VPA's mechanism of action, proteomic analysis was used to identify differentially expressed proteins in the rat prefrontal cortex (PFC), a region particularly affected in BD, after 6 weeks of VPA treatment. Proteins from PFCs of control and VPA-treated rats were separated by 2D-DIGE and identified by mass spectrometry. Among the 2,826 protein spots resolved, the abundance of 19 proteins was found to be significantly altered in the VPA-treated group (with the levels of three proteins increasing and 16 decreasing). Seven proteins whose levels were significantly altered after chronic VPA exposure were quantified by Western blot analysis. The 19 identified proteins represent potential new targets for VPA action and should aid in our understanding of the role of VPA in BD.

Characterisation of ACP5 missense mutations encoding tartrate-resistant acid phosphatase associated with spondyloenchondrodysplasia.

Biallelic mutations in ACP5, encoding tartrate-resistant acid phosphatase (TRACP), have recently been identified to cause the inherited immuno-osseous disorder, spondyloenchondrodysplasia (SPENCD). This study was undertaken to characterize the eight reported missense mutations in ACP5 associated with SPENCD on TRACP expression. ACP5 mutant genes were synthesized, transfected into human embryonic kidney (HEK-293) cells and stably expressing cell lines were established. TRACP expression was assessed by cytochemical and immuno-cytochemical staining with a panel of monoclonal antibodies. Analysis of wild (WT) type and eight mutant stable cell lines indicated that all mutants lacked stainable enzyme activity. All ACP5 mutant constructs were translated into intact proteins by HEK-293 cells. The mutant TRACP proteins displayed variable immune reactivity patterns, and all drastically reduced enzymatic activity, revealing that there is no gross inhibition of TRACP biosynthesis by the mutations. But they likely interfere with folding thereby impairing enzyme function. TRACP exists as two isoforms. TRACP 5a is a less active monomeric enzyme (35kD), with the intact loop peptide and TRACP 5b is proteolytically cleaved highly active enzyme encompassing two subunits (23 kD and 16 kD) held together by disulfide bonds. None of the mutant proteins were proteolytically processed into isoform 5b intracellularly, and only three mutants were secreted in significant amounts into the culture medium as intact isoform 5a-like proteins. Analysis of antibody reactivity patterns revealed that T89I and M264K mutant proteins retained some native conformation, whereas all others were in "denatured" or "unfolded" forms. Western blot analysis with intracellular and secreted TRACP proteins also revealed similar observations indicating that mutant T89I is amply secreted as inactive protein. All mutant proteins were attacked by Endo-H sensitive glycans and none could be activated by proteolytic cleavage in vitro. In conclusion, determining the structure-function relationship of the SPENCD mutations in TRACP will expand our understanding of basic mechanisms underlying immune responsiveness and its involvement in dysregulated bone metabolism.

Properties and expression of human tartrate-resistant acid phosphatase isoform 5a by monocyte-derived cells.

Human serum tartrate-resistant acid phosphatase exists as two enzyme isoforms (TRACP 5a and 5b), derived by differential, post-translational processing of a common gene product. Serum TRACP 5b is from bone-resorbing osteoclasts (OC) and becomes elevated in diseases of increased bone resorption. TRACP 5a is secreted by macrophages (MPhi) and dendritic cells (DC) and is increased in many patients with rheumatoid arthritis. Our purpose was to fully characterize the properties of human TRACP isoforms and to produce an antibody specific to TRACP 5a for use as a biomarker in chronic inflammatory diseases. Partially purified, natural serum TRACP isoforms and recombinant TRACP 5a (rTRACP 5a) were compared with respect to specific activity and subunit structure and presence of sialic acid. Mice were immunized with rTRACP 5a, and resulting hybridomas were screened for monoclonal antibody to serum TRACP 5a. One antibody, 220, was tested for its epitope specificity and use in various immunological techniques. rTRACP 5a had properties identical to serum TRACP 5a. Antibody 220 was specific for the trypsin-sensitive epitope in the loop peptide, present only in TRACP 5a. Antibody 220 was effective for specific immunoprecipitation, immunoassay, and immunoblot of TRACP 5a. Intact TRACP was present in MPhi, DC, and OC. TRACP 5a was the predominant isoform secreted by MPhi and DC, whereas TRACP 5b was the predominant isoform secreted by OC. TRACP isoforms 5a and 5b may have different functions inside and outside of monocyte-derived cells. Antibody 220 is an important resource for studies of the biosynthetic relationship among TRACP isoforms and of the significance of serum TRACP 5a as a marker in diseases of bone metabolism and inflammation.

Regional changes in rat brain inositol monophosphatase 1 (IMPase 1) activity with chronic lithium treatment.

Myo-inositol monophosphatase 1 (IMPase 1) is one of the targets for the mood-stabilizing action of lithium. Inhibition of IMPase is the basis for the "inositol depletion hypothesis" for the molecular action of lithium. To better understand the precise action of chronic (up to 4 weeks) lithium treatment on IMPase 1 activity, we measured IMPase 1 activity using both a colorimetric and a radiometric assay in rats (53-58 days old) fed a diet containing 0.2% lithium carbonate. Our results show that IMPase 1 activity increases substantially in the various brain regions analyzed, even doubling in some regions in the following order, after chronic treatment: hippocampus>cerebellum>striatum>cerebral cortex>brain stem. Both the qualitative and quantitative increases of IMPase 1 activity by chronic lithium treatment were substantiated by Western blot analysis of hippocampal and cerebral cortex regions. We conclude that the increased IMPase 1 activity is an adaptational response to chronic lithium treatment, and may involve direct or indirect stimulation of IMPA1 (which encodes IMPase 1) and/or turnover of the enzyme. The increased enzyme activity may alter critical neurochemical processes involving either free myo-inositol, the precursor of inositol based signaling system or other metabolic pathways, since IMPase 1 also utilizes selective sugar phosphates, such as galactose-1-phosphate, as substrates. One or more of these signal and metabolic pathways may be associated with lithium's psychotherapeutic mood-stabilizing action.

Stable expression of human tartrate-resistant acid phosphatase isoforms by CHO cells.

OBJECTIVE: In human serum, type-5 tartrate-resistant acid phosphatase (TRACP) exists as two closely related isoforms: 5a and 5b. Serum isoform 5b is an osteoclast product that reflects bone resorption rate and is frequently increased in diseases of increased bone turnover. Isoform 5a protein is often increased in rheumatoid arthritis (RA) sera and may be a product of inflammatory macrophages. Our objective was to compare the biochemical characteristics of TRACP 5a and 5b. METHODS: We transfected the human ACP 5 gene into CHO cells and cloned a stable cell line (CHO/TRACP 8F5) that expresses high levels of TRACP activity both intracellularly and as a secreted product. Both enzyme preparations were purified on an anti-TRACP antibody column. Their biochemical properties were compared to the natural serum isoforms using colorimetric assays for activity and total protein. Their structural properties were compared to natural serum isoforms using denaturing and nondenaturing polyacrylamide gel electrophoresis. RESULTS: Both enzyme preparations were heterogeneous. The combined secreted recombinant TRACPs (rTRACP(ex)) had all the characteristics of natural serum TRACP 5a. There were seven uncleaved glycoproteins with a pH optimum of 5.2, relatively low specific activity (278 U/mg) and differentially sialylated. The combined intracellular TRACPs (rTRACP(in)) had all the characteristics of natural serum TRACP 5b. They consisted of two proteins, one of which was a processed heterodimer, with a pH optimum of 5.8, a relatively high specific activity (887 U/mg) and lacked sialic acid. CONCLUSION: This cell line provides an avenue for the simultaneous study of the regulation, function and intracellular trafficking of separate TRACP isoforms and the identification of their physiologic substrates in a single uniform cell source.

Lithium modulation of the human inositol monophosphatase 2 (IMPA2) promoter.

The inositol-signaling pathway is a therapeutic target for lithium in the treatment of bipolar disorder. Inositol monophosphatases (IMPases) play a key role in inositol signaling. Lithium's ability to inhibit IMPase 1 is well known, but its effect on IMPase 2 or on the transcriptional regulation of these genes has not been studied. Here, we report the identification and characterization of the minimal promoter of IMPA2 (encoding IMPase 2) in HeLa (epithelial) and SK-N-AS (neuronal) cells. IMPA2 promoter activity appears to be contributed by different elements in the 5' flanking region, suggesting that the gene is differentially regulated in neuronal and non-neuronal cells. Furthermore, IMPA2 promoter activity in both cell lines is downregulated, in a dose-dependent manner, by lithium after treatment for only 24h. This effect is also observed in vivo. Our results suggest a possible role for IMPA2 in bipolar disorder.

E2F1 regulation of the human myo-inositol 1-phosphate synthase (ISYNA1) gene promoter.

Human myo-inositol 1-phosphate synthase (IP synthase; E.C. 5.5.1.4), encoded by ISYNA1, catalyzes the de novo synthesis of inositol 1-phosphate from glucose 6-phosphate. It is a potential target for mood-stabilizing drugs such as lithium and valproate. But, very little is known about the regulation of human IP synthase. Here, we have characterized the minimal promoter of ISYNA1 and show that it is upregulated by E2F1. Upregulation occurs in a dose-dependent fashion and can be suppressed by ectopic expression of Rb. EMSA and antibody supershift analysis identified a functional E2F binding motif at -117. Complex formation at this site was competed by an excess of unlabeled Sp1 oligo consistent with the -117 E2F site overlapping an Sp1 motif. Because the -117 E2F motif is not a high-affinity binding site, we propose that the upregulation of ISYNA1 occurs through the cooperative interaction of several low-affinity E2F binding motifs present in the minimal promoter.