Mohammad D. Bazzi

Activation and regulation of protein Kinase C enzymes

Protein Kinase C (PKC) has been a principal regulatory enzyme whose function has been intensely investigated in the past decade. The primary features of this family of enzymes includes phosphorylation of serine and threonine residues located on basic proteins and peptides in a manner that is stimulated by calcium, phospholipid, and either diacylglycerol or phorbol esters. An additional intriguing feature of the enzyme is its ability to form two membrane-associated states, one of which is calcium dependent and reversible and the second is an irreversible complex which has the characteristics of an intrinsic membrane protein. Formation of the irreversible membrane-bound form is greatly facilitated by calcium and the tumor-promoting phorbol esters but does not appear to include covalent changes in the PKC structure. The intrinsic membrane-bound form is a very different enzyme in that its activity is no longer dependent on the other cofactors. It is proposed that formation of the irreversible membrane-bound form may be a mechanism for generating long-term cell regulation events where transient cell signals and second messengers induce long-term changes in the distribution of an enzyme in the cell. This property may be common to a number of regulatory proteins that are known to be distributed between the cytosol and membrane-fractions in the cell. Unfortunately, many problems have confronted study of PKC mechanism using thein vitro assay. This assay involves aggregation of the substrate, phospholipid, and enzyme to form a discontinuous mixture. Such as complex system prevents straightforward interpretation of enzyme kinetic data. Although many compounds affect thein vitro activity of PKC, most appear to accomplish this by relatively uninteresting mechanisms such as interference with the aggregation process. While some highly potent inhibitors undoubtedly interact directly with PKC, they also inhibit other enzymes and there are no entirely specific inhibitors of PKC known. Speculation on the possible roles of PKC in cell regulation are abundant and exciting. However, delineation of the regulatory roles of PKC may require another decade of intense effort.

Constitutive activity of membrane-inserted protein kinase C.

Incubation of purified protein kinase C (PKC) with phospholipid vesicles produced two populations of membrane-bound PKC: one population was dissociated by calcium chelation and the other was not. The second population appeared to be inserted into the membrane. The activity of membrane-inserted PKC was Ca2+-independent and was only modestly sensitive to phorbol esters. Insertion was caused by high calcium concentrations or by phorbol esters plus low calcium. These conditions correlated with those needed to activate PKC; insertion into the membrane may be a primary mechanism of PKC activation. PKC may be a long-term cell regulator which becomes inserted into the membrane upon appearance of the second messengers, calcium and diacylglycerol, and remains in an active membrane-bound state when the second messengers have been removed.

Mechanism of protein kinase C inhibition by sphingosine.

The in vitro mechanism by which sphingosine inhibits protein kinase C (PKC) was investigated by comparing enzyme activity and the physical associations of reaction components. Light scattering intensity measurements showed that sphingosine prevented the association of the substrate, histone, with micelles of Triton plus phosphatidylserine (PS). Addition of phosphatidylinositol (PI) or phosphatidylglycerol (PG) restored histone interaction. In direct correlation, both PI and PG were able to reverse inhibition of PKC activity by sphingosine. In Triton mixed micelles, neither PI nor PG alone would support PKC activity or substrate-lipid binding. Inhibition of PKC by positively charged sphingosine appeared to be related to simple charge neutralization of the lipid, thereby preventing interaction with PKC and/or its protein substrate.

Protein kinase C and annexins: Unusual calcium response elements in the cell

Protein kinase C and the annexins appear to share some unusual and potentially important membrane- and calcium-binding properties. While these proteins are calcium response elements, they are not calcium-binding proteins in the formal sense; at intracellular calcium concentrations, they only bind significant amounts of calcium when membranes or other suitable surfaces are present. The number of calcium ions bound per protein is large (> 8) and this stoichiometry, at the protein-membrane interface, may provide the large number of contact points needed for the very high-affinity interaction that is observed. The further ability of annexins and PKC to form structures with properties of integral membrane proteins may be important to provide a type of long-term cell signalling that produces a constitutively active kinase or ion channel activity. Selectivity for phospholipids in bilayer form is modest with respect to the acidic phospholipids but there is a surprising preference for phosphatidylethanolamine as the neutral phospholipid matrix. Along with other unusual properties, these proteins offer the potential for unique types of cell regulation events.

Substrate-specific stimulation of protein kinase C by polyvalent anions

The activity of protein kinase C (PKC) toward arginine-rich substrates was greatly stimulated by sulfate and phosphate, but not by monovalent anions. This stimulation did not require phospholipid, calcium, or diacylglycerol, and appeared to mimic the stimulation by phospholipid. Anionic proteins such as bovine serum albumin also promoted PKC activity toward certain substrates that were characterized by either high arginine or high lysine content. The mechanism of both of these stimulations appeared to be related to formation of a substrate-PKC complex which is essential to phosphorylation by PKC. Polyvalent anions bind the cationic substrate and, together with PKC, form an aggregate which allows phosphorylation. Potential physiological relevance of this stimulation is discussed.

Phosphorylation of troponin I by protein kinase C: Mechanism of inhibition by calmodulin and troponin C

The mechanism by which calmodulin and troponin C influence phosphorylation of troponin I (TnI) by protein kinase C was investigated. The phosphorylation of TnI by protein kinase C requires the presence of acidic phospholipid, calcium and diacylglycerol. Light scattering intensity and fluorescence intensity experiments showed that TnI associated with the phospholipid membranes and caused extensive aggregation. In the presence of Ca2+, TnI-phospholipid interactions were prevented by approximately stoichiometric amounts of either troponin C or calmodulin. Troponin C was shown to completely inhibit phosphorylation of TnI by either protein kinase C or by phosphorylase b kinase. In contrast, calmodulin completely inhibited phosphorylation of TnI by protein kinase C, but had only little effect on TnI phosphorylation by phosphorylase b kinase. Inhibition by calmodulin did not appear to be due to interaction with PKC, since calmodulin mildly increased protein kinase C phosphorylation of histone III-S. The ratio of phosphoserine to phosphothreonine in protein kinase C-phosphorylated TnI remained approximately constant for reactions inhibited by up to 90% by calmodulin. TnI interactions with phospholipid and phosphorylation of TnI by PKC were also prevented by high salt concentrations. However, salt concentrations adequate to inhibit phosphorylation were sufficient to dissociate only TnI, but not protein kinase C from the membrane. These results suggest that the binding of TnI to phospholipid is required for phosphorylation by protein kinase C and that prevention of this binding by any means completely inhibited phosphorylation of TnI by protein kinase C.