Phosphorylation of the retinoblastoma-related protein p130 in growth-arrested cells.

The retinoblastoma family of proteins including pRB, p107 and p130 undergoes cell cycle dependent phosphorylation during the mid-G1 to S phase transition. This phosphorylation is dependent upon the activity of cyclin D/cdk4. In contrast to pRB and p107, p130 is phosphorylated during G0 and the early G1 phase of the cell cycle. We observed that p130 is specifically phosphorylated on serine and threonine residues in T98G cells arrested in G0 by serum deprivation or density arrest. Identification of the phospho-serine and phospho-threonine residues revealed that most were clustered within a short co-linear region unique to p130, defined as the Loop. Deletion of the Loop region resulted in a change in the phosphorylation status of p130 under growth arrest conditions. Notably, deletion of the Loop did not affect the ability of p130 to bind to E2F-4 or SV40 Large T antigen, to induce growth arrest in Saos-2 cells, and to become hyperphosphorylated during the proliferative phase of the cell cycle. p130 undergoes specific G0 phosphorylation in a manner that distinguishes it from pRB and p107.

Anti-head and anti-tail antibodies against distinct epitopes in the catalytic subunit of protein kinase A. Use in the study of the kinase splitting membranal proteinase KSMP.

Protein kinases share a considerable sequence homology in their catalytic core (residues 40-300 in PKA). Each core is flanked by "head" and "tail" segments at its amino- and carboxy-termini, which are different in the various kinases. These end segments may play an important role in creating the preferential affinity of each kinase for its physiological substrates or regulatory ligands. Here we describe three anti-peptide antibodies (alpha P-1, alpha P-2, and alpha P-3) that specifically recognize the head and tail segments of the catalytic subunit (C) of PKA. (i) alpha P-1 (against 6A-K23) react with C when denatured but not when in its native structure; (ii) alpha P-2 (against 319K-I335), bind to the site in C cleaved by the kinase splitting membranal proteinase (KSMP) and inhibit this cleavage of C; (iii) alpha P-3 (against 338S-F350) react with C but not with the KSMP cleavage product C', useful for detecting a KSMP-like activity in different tissues and subcellular loci. The combined use of the antibodies described here provides a strict definition of C, and thus a high degree of fidelity in its biorecognition.

The carboxyl-terminal tail of kinase splitting membranal proteinase/meprin beta is involved in its intracellular trafficking.

The kinase splitting membranal proteinase (KSMP), was recently shown to be identical with the beta-subunit of meprin. Meprin is a metalloendoproteinase located in brush border membranes and composed of the two types of subunits, alpha and beta. Despite their high sequence homology and similar domain organization, meprin subunits are differently processed during maturation; meprin alpha is retained in the endoplasmic reticulum (ER), and undergoes a proteolytic removal of the transmembrane and cytoplasmic domains, prior to its export from this organelle. In contrast, meprin beta retains these domains even after reaching its final destination in the plasma membrane. Using truncated mutants of rat meprin beta expressed in Cos-7 and human embryonic kidney (HEK) 293 cells, we show here that the cytoplasmic tail is indispensable for its exit from the ER. A meprin beta mutant lacking the last 25 amino acids is shown to be transport-incompetent, although it does not contain any of the known ER retention signals. Systematic analysis of the rate of the ER to Golgi transport using a series of mutants with Ala or Pro substitutions in the tail, suggests that while no specific amino acid residue by itself is imperative for normal intracellular trafficking of meprin beta, the insertion of a bend at a distinct position in the tail (specifically by a Y685P mutation) suffices to retain this protein in the ER. We propose that the very length of the cytoplasmic tail, as well as its secondary structure are essential for the ER to Golgi transport of meprin beta, possibly by allowing an interaction with a cargo receptor.

The cleavage of protein kinase A by the kinase-splitting membranal proteinase is reproduced by meprin beta.

The Kinase-Splitting Membranal Proteinase (KSMP) is a metallo-endoproteinase that clips off the carboxyl terminus tail of the catalytic (C) subunit of protein kinase A to yield a truncated, catalytically inactive protein (C'). Here we report (a) a new procedure for the purification of KSMP, yielding a major protein band in SDS-polyacrylamide gel electrophoresis that correlates with the characteristic KSMP activity; (b) the sequence of tryptic peptides obtained from this band, suggesting an identity between this protein and meprin beta; (c) the immuno-detection by specific anti-peptide antibodies of both the alpha and the beta subunits of meprin in KSMP preparations; (d) the stable expression of meprin beta in a mammalian cell line (293) to establish a clone that constitutively expresses the full-length precursor of meprin beta; and (e) the optimalization of the proteolytic activation of this precursor to obtain an enzyme exhibiting the specific KSMP cleavage, suggesting that KSMP is either derived from, or identical with, the meprin beta gene product. It is hoped that these results will shed light on the possible physiological role of KSMP and the way it may affect protein kinase A-mediated processes.

Functional malleability of the carboxyl-terminal tail in protein kinase A.

The catalytic (C) subunit of protein kinase A (PKA) is regarded as a framework for the protein kinase family. Its sequence is composed of a conserved core (residues 40 300) between two segments at the amino and carboxyl termini of the protein. Since the various protein kinases differ in their specificity, it seems reasonable to assume that these nonhomologous segments may be involved in endowing each kinase with its individual specificity. Here we present data to show that the cluster of acidic amino acids (328DDYEEEE334) at the carboxyl-terminal "tail" of the C subunit, specifically Tyr330, contributes to its substrate recognition. This is based on three complementary lines of evidence: (i) on a conformation-sensitive cleavage of the C subunit by a kinase-splitting membranal proteinase that specifically recognizes this cluster, to demonstrate the occurrence in solution of "open" (cleavable) and "closed" (noncleavable) conformations of the C subunit; (ii) on analysis of the three-dimensional structures of the open and closed conformations of the C subunit, showing an approximately 7-A movement of the phenolic hydroxyl of Tyr330 to reach (in the closed conformation) an approximately 3-A distance from the nitrogen atoms of the Arg residue at position p-3 of the PKA consensus sequence; and (iii) on single-site mutations of the C subunit (e.g. Y330A) that show a significant contribution of Tyr330 to the Km of PKA for its substrates/inhibitors and to its catalytic efficacy (Vmax/Km).

Unveiling the substrate specificity of meprin beta on the basis of the site in protein kinase A cleaved by the kinase splitting membranal proteinase.

The kinase splitting membranal proteinase (KSMP) is a metalloendopeptidase that inactivates the catalytic (C) subunit of protein kinase A (PKA) by clipping off its carboxyl terminal tail. Here we show that this cleavage occurs at Glu332-Glu333, within the cluster of acidic amino acids (Asp328-Glu334) of the kinase. The Km values of KSMP and of meprin beta (which reproduces KSMP activity) for the C-subunit are below 1 microM. The Km for peptides containing a stretch of four Glu residues are in the micromolar range, illustrating the significant contribution of this cluster to the substrate recognition of meprin beta. This conclusion is supported by a systematic study using a series of the C-subunit mutants with deletions and mutations in the cluster of acidics. Hydrophobic amino acids vicinal to the cleavage site increase the Kcat of the proteinase. These studies unveil a new specificity for meprin beta, suggesting new substrates that are 1-2 orders of magnitude better in their Km and Kcat than those commonly used for meprin assay. A search for substrates having such a cluster of acidics and hydrophobics, which are accessible to meprin under physiological conditions, point at gastrin as a potential target. Indeed, meprin beta is shown to cleave gastrin at its cluster of five glutamic acid residues and also at the M-D bond within its WMDF-NH2 sequence, which is indispensable for all the known biological activities of gastrins. The latter meprin cleavage will lead to the inactivation of gastrin and thus to the control of its activity.