The regulation and function of protein phosphatases in the brain

Data emerging from a number of different systems indicate that protein phosphatases are highly regulated and potentially responsive to changes in the levels of intracellular second messengers produced by extracellular stimulation. They may therefore be involved in the regulation of many cell functions. The protein phosphatases in the nervous system have not been well studied. However, a number of neuronal-specific regulators (such as DARPP-32 and G-substrate) exist, and brain protein phosphatases appear to have particularly low specific activity, suggesting that neuronal protein phosphatases possess considerable and unique potential for regulation. Several early events following depolarization or receptor activation appear to involve specific dephosphorylations, indicating that regulation of protein phosphatase activity is important for the control of many neuronal functions. This article reviews the current literature concerning the identification, regulation, and function of serine/threonine protein phosphatases in the brain, with particular emphasis on the regulation of the major protein phosphatases, PP1 and PP2A, and their potential roles in modulating neurotransmitter release and postsynaptic responses.     

Observations on the fate of cystathionine in rat brain.

Direct intracerebral administration of ³⁵S-cystathionine has been shown to be capable of labelling the normal pools of cystathionine in rat brain tissue and thus capable of yielding useful information about the metabolic fate of the amino acid. Cystathionine was shown to be metabolised slowly to yield inorganic SO₄^2?, taurine and cystine. Sub-cellular fractionation studies concerned with the distribution of ³⁵S-cystathionine coupled with similar investigations involving enzymes of the transsulphuration pathway indicate that cystathionine fulfill some of the requirements of a neurotransmitter substance.     

Two distinct membrane-bound phosphatidylinositol-4-phosphate phosphatases in bovine brain.

Solubilized phosphatidylinositol-4-phosphate 4-phosphatase from bovine brain resolved into two peaks of activity by ion exchange chromatography. Both exhibited substantial detergent binding characteristic of integral membrane proteins, and both appear specific for phosphatidylinositol-4-phosphate, but their pH optima differ: the earlier eluting fraction (peak 1) is optimally active between pH 5.5 and 6, whereas the later eluting fraction (peak 2) is most active around pH 8.5. Detergent inhibition studies suggest that peak 2, but not peak 1, interacts with phosphatidylinositol-4-phosphate in the context of a single mixed micelle. Further characterization of these activities should help shed light on the biological function of polyphosphoinositide phosphatases.     

Observations under the electron microscope on the localization of phosphatases in epithelial cells of Cowper's glands in rats

The positive results of the reactions for alkaline and acid phosphatases were obtained in epithelial cells of Cowper's glands in rats. Observations under the electron microscope allowed us to state that alkaline phosphatase was localized in the cell's areola, in membranes of smooth intraplasmic reticulum and in the basement membrane of the epithelium. The acid phosphatase was seen in primary lysosomes as well as in the secondary ones, which are seldom seen on unincubated specimens.     

cAMP regulation of protein phosphatases PP1 and PP2A in brain

Normal functioning of the brain is dependent upon a complex web of communication between numerous cell types. Within neuronal networks, the faithful transmission of information between neurons relies on an equally complex organization of inter- and intra-cellular signaling systems that act to modulate protein activity. In particular, post-translational modifications (PTMs) are responsible for regulating protein activity in response to neurochemical signaling. The key second messenger, cyclic adenosine 3′,5′-monophosphate (cAMP), regulates one of the most ubiquitous and influential PTMs, phosphorylation. While cAMP is canonically viewed as regulating the addition of phosphate groups through its activation of cAMP-dependent protein kinases, it plays an equally critical role in regulating removal of phosphate through indirect control of protein phosphatase activity. This dichotomy of regulation by cAMP places it as one of the key regulators of protein activity in response to neuronal signal transduction throughout the brain. In this review we focus on the role of cAMP in regulation of the serine/threonine phosphatases protein phosphatase 1 (PP1) and protein phosphatase 2A (PP2A) and the relevance of control of PP1 and PP2A to regulation of brain function and behavior.     

Purification and characterization of two inactive/latent protein phosphatases from pig brain

Two inactive/latent protein phosphatases termed LP-1 (Mr 260,000) and LP-2 (Mr 350,000) were identified and purified from pig brain. Examination of molecular structures indicated that LP-1 has three subunits with molecular weights of 69,000, 55,000, and 34,000, respectively, whereas LP-2 contains only one subunit, with molecular weight of 49,000. When using phosphorylase a as a substrate, LP-1 was completely inactive and could be dramatically activated by freezing and thawing in 0.2 M 2-mercaptoethanol, whereas LP-2 contained some basal activity but could also be stimulated 40-fold by the same treatment. Kinetic analysis further indicated that both LP-1 and LP-2 enzymes dephosphorylate histone 2A, myelin basic protein, and phosphorylase a at a rather comparable rate, but the dephosphorylation of histone 2A and myelin basic protein seems to be spontaneously active. This, together with the results that trypsinolysis could specifically knock off phosphorylase phosphatase activity but caused no effect on the associated myelin basic protein/histone phosphatase activities, supports the notion that a two-site mechanism may possibly be involved in the regulation of substrate specificity of LP-1 and LP-2 enzymes in the central nervous system.     

Probable occurrence of brain basic protein factor I, an activator of phosphoprotein phosphatases

Basic protein factor I (BPFI was purified to homogeneity from bovine brain by boiling and trichloroacetic acid-precipitation of tissue homogenate, followed by DEAE-cellulose, Sephadex G-150, Affi-Gel-phenothiazine, and Bio-Gel P-6DG chromatographic procedures. The preparation appeared as a single protein band in the SDS-polyacrylamide gel electrophoresis with a minimal Mr of 13,200. The factor was a basic protein as indicated by an estimated isoelectric point of pH 8.3 and a high content of amino acids including arginine, histidine, lysine and others. In the absence of Mn2+, the factor stimulated the phosphoprotein phosphatases (PPase) from rabbit brains. Unlike histones or protamine, the factor was a poor substrate for megamodulin-dependent protein kinase. In addition, the factor did not interact significantly with E. coli megamodulin.     

Phosphoprotein phosphatases for myelin basic protein in myelin and cytosol fractions of brain.

Phosphoprotein phosphatase (phosphoprotein phosphohydrolase EC 3.1.3.16) activity for myelin basic protein was found to be present in the myelin fraction of rat brain. The enzyme activity was in a latent form and solubilized by 0.2% Triton X-100 treatment with about 50% increase of activity. The cytosol fraction from bovine brain also had phosphoprotein phosphatase activity for myelin basic protein, which was resolved into at least two peaks of activity on DEAE-cellulose column chromatography. Myelin basic protein was the best substrate for both the solubilized myelin fraction and the cytosol enzymes among the substrate proteins tested. The Km values of the solubilized myelin fraction were 4.2 muM for myelin basic protein, 7.4 muM for arginine-rich histone, 8.0 muM for histone mixture and 14.3 muM for protamine, respectively.