Unphosphorylated alpha-PKC exhibits phorbol ester binding but lacks protein kinase activity in vitro

Defining in vitro topical antimicrobial and antibiofilm activity of epoxy-tigliane structures against oral pathogens

Background

Peri-implantitis has become an inexorable clinical challenge in implantology. Topical immunomodulatory epoxy-tiglianes (EBCs), derived from the Queensland blushwood tree, which induce remodeling and resolve dermal infection via induction of the inflammasome and biofilm disruption, may offer a novel therapeutic approach.

Design

In vitro antimicrobial activity of EBC structures (EBC-46, EBC-1013 and EBC-147) against Streptococcus mutans, Aggregatibacter actinomycetemcomitans and Porphyromonas gingivalis in minimum inhibitory concentration, growth curve and permeabilization assays were determined. Antibiofilm activity was assessed using minimum biofilm eradication concentration (MBEC) experiments. Biofilm formation and disruption assays were analyzed using confocal laser scanning microscopy, scanning electron microscopy and direct plate counting.

Results

The observed antimicrobial efficacy of the tested compounds (EBC-1013 > EBC-46 > EBC-147) was directly related to significant membrane permeabilization and growth inhibition (p < 0.05) against planktonic S. mutans and P. gingivalis. Antibiofilm activity was evident in MBEC assays, with S. mutans biofilm formation assays revealing significantly lower biomass volume and increased DEAD:LIVE cell ratio observed for EBC-1013 (p < 0.05). Furthermore, biofilm disruption assays on titanium discs induced significant biofilm disruption in S. mutans and P. gingivalis (p < 0.05).

Conclusions

EBC-1013 is a safe, semi-synthetic, compound, demonstrating clear antimicrobial biofilm disruption potential in peri-implantitis.

Molecular cloning and expression of protein kinase C from Bombyx mori

Two partial cDNA clones (Protein kinase C alpha and Protein kinase C iota), each of which encoded a different member of PKC-protein family, were isolated using RT-PCR from mRNA of Bombyx mori. The full-length cDNAs were isolated using SMART-RACE. The cDNAs were expressed in HepG2 cells and the recombinant proteins were partially purified using an affinity chromatography. Protein kinase C alpha (BPKC alpha) showed a calcium-dependent kinase activity of histones. Whereas protein kinase C iota (BPKC iota) showed a calcium-independent activity. Bisindolyl maleimide I, a PKC inhibitor, inhibited these kinase activities. Furthermore, in vitro BPKC alpha interacted and phosphorylated two proteins expressed in the brain of Bombyx mori: Rab protein, which plays important roles in the vesicle transport in the brain, and bMBD2/3, which is a methyl DNA-binding protein and regulates transcription. These results suggest that these PKCs phosphorylate various substrate proteins and function in the brain of Bombyx mori.

Protein kinase C delta

The protein kinase C (PKC) family consists of 11 isoenzymes that, due to structural and enzymatic differences, can be subdivided into three groups: The Ca(2+)-dependent, diacylglycerol (DAG)-activated cPKCs (conventional PKCs: alpha, beta 1, beta 2, gamma); the Ca(2+)-independent, DAG-activated nPKCs (novel PKCs: delta, epsilon, eta, theta, mu), and the Ca(2+)-dependent, DAG non-responsive aPKCs (atypical PKCs: zeta, lambda/iota). PKC mu is a novel PKC, but with some special structural and enzymatic properties.

The broad specificity of dominant inhibitory protein kinase C mutants infers a common step in phosphorylation

Dominant negative properties are conferred on protein kinase (PK) Calpha by mutation of the phosphorylation site in the activation loop of the kinase domain. To address the universality and/or specificity of such mutations, analogous alterations were introduced in other members of the PKC family and tested for their effects on the function of co-transfected activated PKC. For all three subclasses of the PKC family, mutations of the predicted activation loop phosphorylation sites resulted in dominant negative properties. These properties were not restricted to the cognate PKC isotypes, but were effective across the different subclasses. For example, two PKCzeta mutants (atypical isotype) inhibited both PKCalpha (classical isotype) and PKCepsilon (novel isotype). For all these mutants, inhibition correlated with an ability to prevent the accumulation of phosphorylated PKCalpha, consistent with the expected mode of action. In the case of the PKCalpha mutant, it was shown that inhibition required the full-length mutant protein. The results provide evidence for the involvement of a common step in the phosphorylation of all PKC isotypes.

Phorbol-ester-activated protein kinase C-alpha lacking phosphorylation at Ser657 is down-regulated by a mechanism involving dephosphorylation

Protein kinase C (PKC) is a key enzyme in the intracellular signaling network. Upon activation by 12-O-tetradecanoylphorbol 13-acetate, the alpha-isoform of PKC translocates to the detergent-soluble and the detergent-insoluble fractions. Besides cofactors, the activity and stability of this protein is critically regulated by multisite phosphorylations. At least three distinct sites, Thr497, Thr638 and Ser657, are involved. We have previously shown that the replacement of Ser657 by alanine leads to a premature down-regulation in the detergent soluble compartment of LLC-PK1 cells [Gysin, S. & Imber, R. (1996) Eur. J. Biochem. 240, 747-750]. More detailed analysis revealed that, in contrast to the wild-type molecule, the down-regulation of the mutant protein is in vivo preceded by a rapid dephosphorylation after phorbol-ester-induced translocation to both the detergent-soluble and insoluble compartments. The [Ala657]PKC-alpha mutant protein molecule showed in vitro a strongly increased sensitivity towards protein phosphatase 2A whereas its overall proteolytic sensitivity remained unchanged when compared to wild type. The in vitro studies led to the suggestion that further dephosphorylation of the mutant protein is a prerequisite in order to become proteolytically down-regulated. Therefore phosphorylation of Ser657 controls the duration of activation of this PKC isozyme upon agonist-induced translocation by preventing premature proteolytic down-regulation via protecting the protein from dephosphorylation.

Phosphorylation of protein kinase Cdelta (PKCdelta) at threonine 505 is not a prerequisite for enzymatic activity. Expression of rat PKCdelta and an alanine 505 mutant in bacteria in a functional form

A structural feature shared by many protein kinases is the requirement for phosphorylation of threonine or tyrosine in the so-called activation loop for full enzyme activity. Previous studies by several groups have indicated that the isotypes alpha, betaI, and betaII of protein kinase C (PKC) are synthesized as inactive precursors and require phosphorylation by a putative "PKC kinase" for permissive activation. Expression of PKCalpha in bacteria resulted in a nonfunctional enzyme, apparently due to lack of this kinase. The phosphorylation sites for the PKC kinase in the activation loop of PKCalpha and PKCbetaII could be identified as Thr497 and Thr500, respectively. We report here that PKCdelta, contrary to PKCalpha, can be expressed in bacteria in a functional form. The activity of the recombinant enzyme regarding substrate phosphorylation, autophosphorylation, and dependence on activation by 12-O-tetradecanoylphorbol-13-acetate as well as the Km values for two substrates are comparable to those of recombinant PKCdelta expressed in baculovirus-infected insect cells. By site-directed mutagenesis we were able to show that Thr505, corresponding to Thr497 and Thr500 of PKCalpha and PKCbetaII, respectively, is not essential for obtaining a catalytically competent conformation of PKCdelta. The mutant Ala505 can be activated and does not differ from the wild type regarding activity and several other features. Ser504 can not take over the role of Thr505 and is not prerequisite for the kinase to become activated, as proven by the unaffected enzyme activity of respective mutants (Ala504 and Ala504/Ala505). These results indicate that phosphorylation of Thr505 is not required for the formation of functional PKCdelta and that at least this PKC isoenzyme differs from the isotypes alpha, betaI, and betaII regarding the permissive activation by a PKC kinase.

Replacement of Ser657 of protein kinase C-alpha by alanine leads to premature down regulation after phorbol-ester-induced translocation to the membrane

Protein kinase C (PKC) is activated at the cell membrane by interacting with both the acidic lipid phosphatidylserine and the second messenger diacylglycerol. A direct activation of the kinase is also possible by substituting diacylglycerol with phorbol esters such as the tumor promoting agent 12-O-tetradecanoylphorbol-13-acetate (TPA). Transphosphorylation of the activation loop followed by autophosphorylation at sites located on various domains of the protein have been suggested to be required as permissive activation of the alpha and beta isoforms of PKC [Cazaubon, S., Bornancin, F. & Parker, P. (1994) Biochem. J. 301, 443-448; Keranen, L. M., Dutil, E. M. & Newton, A. C. (1995) Curr. Biol. 5, 1393-1403]. Ser657, located near the C-terminus of PKC-alpha, represents a site which is very conserved among the members of the PKC protein family. Circumstantial evidence suggested that this residue represents a possible site of phosphorylation. The conversion of Ser657 to alanine caused a 70% loss of the catalytic activity as well as a drastically increased down regulation upon translocation of this isozyme to the membrane when induced by phorbol ester. The faster electrophoretic mobility of the mutant protein compared to that of the wild-type enzyme suggested that Ser657 represents a phosphorylation site.

Threonine-497 is a critical site for permissive activation of protein kinase C alpha

Phosphorylation of the region containing Thr-494, Thr-495 and Thr-497, present in the catalytic domain of protein kinase C alpha (PKC alpha), is a preliminary event necessary for subsequent PKC activation [Cazaubon and Parker (1993) J. Biol. Chem. 268, 17559-17563]. To define the essential residues in this region, various combinations of alanine substitutions for threonine residues 494, 495 and 497 have been tested. These mutations yielded expressed polypeptides of 76 and 80 kDa in ratios that vary from 100% 80 kDa (wild-type kinase, active) to 100% 76 kDa (AAA mutant, inactive) with the hierarchy being wild-type PKC alpha (TTT), ATT, AAT, TTA, ATA, TAA, AAA (the nomenclature indicates the location of alanine residues substituted for Thr-494, Thr-495 and Thr-497 respectively). Only the mutants retaining Thr-497 displayed kinase activity in vitro. The results overall indicate that Thr-497 plays the dominant role in the regulation of PKC alpha activity but that in the wild-type protein, Thr-495 may also be important. Consistent with the need for phosphorylation in this region, an intrinsically active PKC alpha could be produced in bacteria by exchanging Thr-495 for a glutamic acid residue.