Biochemical analysis of mouse FKBP60, a novel member of the FKPB family.

We have identified mouse and human FKBP60, a new member of the FKBP gene family. FKBP60 shares strongest homology with FKBP65 and SMAP. FKBP60 contains a hydrophobic signal peptide at the N-terminus, 4 peptidyl-prolyl cis/trans isomerase (PPIase) domains and an endoplasmic reticulum retention motif (HDEL) at the C-terminus. Immunodetection of HA-tagged FKBP60 in NIH-3T3 cells suggests that FKBP60 is segregated to the endoplasmic reticulum. Northern blot analysis shows that FKBP60 is predominantly expressed in heart, skeletal muscle, lung, liver and kidney. With N-succinyl-Ala-Ala-Pro-Phe-p-nitroanilide as a substrate, recombinant GST-FKBP60 is shown to accelerate effectively the isomerization of the peptidyl-prolyl bond. This isomerization activity is inhibited by FK506. mFKBP60 binds Ca2+ in vitro, presumably by its C-terminal EF-hand Ca2+ binding motif, and is phosphorylated in vivo. hFKBP60 has been mapped to 7p12 and/or 7p14 by fluorescence in situ hybridization (FISH).     

Activation of MK5/PRAK by the atypical MAP kinase ERK3 defines a novel signal transduction pathway

Extracellular signal-regulated kinase 3 (ERK3) is an atypical mitogen-activated protein kinase (MAPK), which is regulated by protein stability. However, its function is unknown and no physiological substrates for ERK3 have yet been identified. Here we demonstrate a specific interaction between ERK3 and MAPK-activated protein kinase-5 (MK5). Binding results in nuclear exclusion of both ERK3 and MK5 and is accompanied by ERK3-dependent phosphorylation and activation of MK5 in vitro and in vivo. Endogenous MK5 activity is significantly reduced by siRNA-mediated knockdown of ERK3 and also in fibroblasts derived from ERK3-/- mice. Furthermore, increased levels of ERK3 protein detected during nerve growth factor-induced differentiation of PC12 cells are accompanied by an increase in MK5 activity. Conversely, MK5 depletion causes a dramatic reduction in endogenous ERK3 levels. Our data identify the first physiological protein substrate for ERK3 and suggest a functional link between these kinases in which MK5 is a downstream target of ERK3, while MK5 acts as a chaperone for ERK3. Our findings provide valuable tools to further dissect the regulation and biological roles of both ERK3 and MK5.     

Docking of PRAK/MK5 to the Atypical MAPKs ERK3 and ERK4 Defines a Novel MAPK Interaction Motif

ERK3 and ERK4 are atypical MAPKs in which the canonical TXY motif within the activation loop of the classical MAPKs is replaced by SEG. Both ERK3 and ERK4 bind, translocate, and activate the MAPK-activated protein kinase (MK) 5. The classical MAPKs ERK1/2 and p38 interact with downstream MKs (RSK1–3 and MK2–3, respectively) through conserved clusters of acidic amino acids, which constitute the common docking (CD) domain. In contrast to the classical MAPKs, the interaction between ERK3/4 and MK5 is strictly dependent on phosphorylation of the SEG motif of these kinases. Here we report that the conserved CD domain is dispensable for the interaction of ERK3 and ERK4 with MK5. Using peptide overlay assays, we have defined a novel MK5 interaction motif (FRIEDE) within both ERK4 and ERK3 that is essential for binding to the C-terminal region of MK5. This motif is located within the L16 extension lying C-terminal to the CD domain in ERK3 and ERK4 and a single isoleucine to lysine substitution in FRIEDE totally abrogates binding, activation, and translocation of MK5 by both ERK3 and ERK4. These findings are the first to demonstrate binding of a physiological substrate via this region of the L16 loop in a MAPK. Furthermore, the link between activation loop phosphorylation and accessibility of the FRIEDE interaction motif suggests a switch mechanism for these atypical MAPKs in which the phosphorylation status of the activation loop regulates the ability of both ERK3 and ERK4 to bind to a downstream effector.Mitogen-activated protein kinase (MAPK)² phosphorylation cascades play important roles in the regulation of diverse cellular functions such as cell proliferation, differentiation, migration, and apoptosis (1, 2). A characteristic and conserved feature of this family of signaling pathways is their organization into modules comprising a sequential three-tiered kinase cascade. This contains a MAPK kinase kinase, a MEK, and the MAPK itself. Four such MAPK signaling modules have been described in mammals: ERK1 and ERK2, the c-Jun N-terminal kinases 1–3, the p38 kinases (p38α/β/γ/δ), and ERK5 (3–7). The MAPK kinase kinases phosphorylate and activate the MEKs, which in turn activate the MAPKs by dual phosphorylation on both the threonine and the tyrosine residue of a highly conserved TXY motif in the kinase activation loop. MAPKs are Ser/Thr kinases, which phosphorylate a wide range of substrates with the minimal consensus sequence (S/T)P (2).ERK4 and its close relative ERK3 are regarded as atypical members of the MAPK family. In contrast to the classical MAPKs, ERK3 and ERK4 harbor an SEG motif in the activation loop and thus lack a second phosphoacceptor site. In addition, protein kinases all possess a conserved APE motif located just C-terminal to the phosphoacceptor sites within subdomain VIII, in which the conserved glutamate is important for maintaining the stability of the kinase domain. In both ERK3 and ERK4, this motif is substituted by SPR, and ERK3 and ERK4 are the only two protein kinases in the human genome with an arginine residue in this position (8). Although they display significant sequence homology (44% identity) with ERK1 and ERK2 within their kinase domains, both ERK3 and ERK4 have unique C-terminal extensions, which account for the large differences in size observed between ERK1/2 (∼360 amino acids) and ERK3/ERK4 (721/587 amino acids). Whereas classical MAPKs have been highly conserved throughout evolution, with examples found in both unicellular and multicellular organisms, ERK3 and ERK4 are only present in vertebrates. Finally, in contrast to many of the classical MAPKs, the regulation, substrate specificity, and physiological functions of ERK3 and ERK4 are poorly understood. Although ERK3 and ERK4 are very similar to each other, there are significant differences between them. For instance, whereas ERK4, like most classical MAPKs, is a stable protein, ERK3 is highly unstable and subject to rapid proteosomal degradation. Thus, ERK3 activity may be regulated at the level of cellular abundance, and taken together these features indicate that ERK3 and ERK4 may perform specialized functions and enjoy different modes of regulation when compared with classical MAPKs (9–11).Despite the striking differences between ERK3 and ERK4 and the classical MAPKs, they do share one property with the ERK1/2, p38, and ERK5, namely the ability to interact with a group of downstream Ser/Thr protein kinases, termed MAPK-activated protein kinases (MAPKAPKs or MKs) (12, 13). In the case of ERK3 and ERK4, both proteins interact with, translocate, and activate the MK5 protein kinase. Several studies have drawn attention to the role of specific docking interactions that contribute to both substrate selectivity and regulation in MAPK pathways (14–17). These interactions involve docking domains, which specifically recognize small peptide docking motifs (D motifs) located on functional MAPK partner proteins including downstream substrates, scaffold proteins, as well as positive and negative regulators. The docking domains, although located within the kinase domains, are distinct from the active site. Similarly the D motifs, which these docking domains recognize, are also distinct from the phosphoacceptor sites within protein substrates (18). There are several classes of D motifs. The motifs found in MAPKAP kinases including MK5 have the consensus sequence LX_1–2(K/R)_2–5 where X is any amino acid (12). The corresponding docking domains within the MAPKs have also been characterized (16, 19, 20). The common docking (CD) domain is a cluster of negatively charged amino acids located in the L16 extension directly C-terminal to the kinase domain in the MAPK primary structure. A second domain termed ED (Glu-Asp) also contributes to binding specificity. This latter site is located near the CD domain in the MAPK tertiary structure. Whereas the CD domain is considered commonly important for all docking interactions, the ED site is thought to be important for the determination of specificity (16). Other residues and regions distinct from the ED and CD domains have also been shown to be important for docking.(21–25).This work has so far been largely confined to analysis of the classical MAPKs, and much less is known about the nature of substrate or regulatory docking interactions for the atypical MAPKs. We and others (9, 11, 26) have recently reported that the region encompassing residues 326–340 within both ERK3 and ERK4 is required for their ability to interact with and activate MK5. Furthermore, a truncated mutant of MK5, which lacks the 50 C-terminal residues (MK5 1–423), was unable to bind to ERK4 despite the fact that it retains its D domain. Finally, in contrast to conventional MAPKs, the interaction between ERK3 and ERK4 and MK5 requires activation loop phosphorylation of ERK3 and ERK4 (27, 28). Taken together these observations suggest that the mechanism by which the atypical MAPKs recognize and bind to at least one important class of effector kinases may be distinct to that found in the classical MAPKs such as ERK1/2 and p38.Here we demonstrate that two separate C-terminal regions, encompassing residues 383–393 and 460–465, respectively, are necessary for MK5 to interact with both ERK3 and ERK4. These regions are distinct from the D motif previously identified within MK5, suggesting that binding to ERK3 and ERK4 may be mediated by a different mechanism to that seen in the classical MAPKs. In support of this, the conserved CD domains within ERK3 and ERK4 are shown to be completely dispensable for MK5 interaction. Using peptide overlay assays, we have defined a minimal MK5 interaction motif FRIEDE in ERK4. Furthermore, we demonstrate that a single point mutation (ERK3 I334K or ERK4 I330K) within this FRIEDE motif is sufficient to disrupt the binding of both ERK3 and ERK4 to MK5 and consequently their ability to both translocate and activate MK5. The FRIEDE motif is located within the L16 extension C-terminal to the CD domain in both ERK3 and ERK4. Interestingly, molecular modeling of the corresponding region in ERK2 suggests that it undergoes a significant conformational change as a result of activation loop phosphorylation, making this part of the L16 extension more accessible (29). We propose that the FRIEDE motif represents a novel MAPK interaction motif, the function of which is linked to activation loop phosphorylation and MAPK activation.     

Regulation of MAPK-activated protein kinase 5 activity and subcellular localization by the atypical MAPK ERK4/MAPK4

MAPK-activated protein kinase 5 (MK5) was recently identified as a physiological substrate of the atypical MAPK ERK3. Complex formation between ERK3 and MK5 results in phosphorylation and activation of MK5, concomitant stabilization of ERK3, and the nuclear exclusion of both proteins. However, ablation of ERK3 in HeLa cells using small interfering RNA or in fibroblasts derived from ERK3 null mice reduces the activity of endogenous MK5 by only 50%, suggesting additional mechanisms of MK5 regulation. Here we identify the ERK3-related kinase ERK4 as a bona fide interaction partner of MK5. Binding of ERK4 to MK5 is accompanied by phosphorylation and activation of MK5. Furthermore, complex formation also results in the relocalization of MK5 from nucleus to cytoplasm. However unlike ERK3, ERK4 is a stable protein, and its half-life is not modified by the presence or absence of MK5. Finally, although knock-down of ERK4 protein in HeLa cells reduces endogenous MK5 activity by approximately 50%, a combination of small interfering RNAs targeting both ERK4 and ERK3 causes a further reduction in the MK5 activity by more than 80%. We conclude that MK5 activation is dependent on both ERK3 and ERK4 in these cells and that these atypical MAPKs are both physiological regulators of MK5 activity.     

Effects of double ligation of Stensen's duct on the rabbit parotid gland

Salivary gland duct ligation is an alternative to gland excision for treating sialorrhea or reducing salivary gland size prior to tumor excision. Duct ligation also is used as an approach to study salivary gland aging, regeneration, radiotherapy, sialolithiasis and sialadenitis. Reports conflict about the contribution of each salivary cell population to gland size reduction after ductal ligation. Certain cell populations, especially acini, reportedly undergo atrophy, apoptosis and proliferation during reduction of gland size. Acini also have been reported to de-differentiate into ducts. These contradictory results have been attributed to different animal or salivary gland models, or to methods of ligation. We report here a bilateral double ligature technique for rabbit parotid glands with histologic observations at 1, 7, 14, 30, 60 days after ligation. A large battery of special stains and immunohistochemical procedures was employed to define the cell populations. Four stages with overlapping features were observed that led to progressive shutdown of gland activities: 1) marked atrophy of the acinar cells occurred by 14 days, 2) response to and removal of the secretory material trapped in the acinar and ductal lumens mainly between 30 and 60 days, 3) reduction in the number of parenchymal (mostly acinar) cells by apoptosis that occurred mainly between 14–30 days, and 4) maintenance of steady-state at 60 days with a low rate of fluid, protein, and glycoprotein secretion, which greatly decreased the number of leukocytes engaged in the removal of the luminal contents. The main post- ligation characteristics were dilation of ductal and acinar lumens, massive transient infiltration of mostly heterophils (rabbit polymorphonuclear leukocytes), acinar atrophy, and apoptosis of both acinar and ductal cells. Proliferation was uncommon except in the larger ducts. By 30 days, the distribution of myoepithelial cells had spread from exclusively investing the intercalated ducts pre-ligation to surrounding a majority of the residual duct-like structures, many of which clearly were atrophic acini. Thus, both atrophy and apoptosis made major contributions to the post-ligation reduction in gland size. Structures also occurred with both ductal and acinar markers that suggested acini differentiating into ducts. Overall, the reaction to duct ligation proceeded at a considerably slower pace in the rabbit parotid glands than has been reported for the salivary glands of the rat.     

AN INDIRECT ENZYME-LINKED IMMUNOSORBENT ASSAY FOR THE DETECTION OF LEPTOSPIRA INTERROGANS SEROVAR POMONA ANTIBODIES IN BOVINE SERA

An indirect ELISA was developed and initially evaluated for the detection of bovine antibodies to Leptospira interrogans serovar pomona. The antigen used in this ELISA was extracted from a serovar pomona culture supernatant by a combination of centrifugation, digestion with proteinase K and ultra-centrifugation. The antigen showed little cross-reaction with immune rabbit sera to L. interrogans serovars copenhageni, grippotyphosa, hardjo and sejroe and, Leptospira biflexa serovar patoc. Some cross-reaction was observed with immune rabbit serum to L. interrogans serovar canicola. The relative sensitivity of the ELISA was 94.76% confidence interval =± 3.32%) when estimated with bovine sera (n=172) with serovar pomona microscopic agglutination test (MAT) titers of 100. The relative specificity of the ELISA was 99.28% (95% confidence interval = 1.40%) when estimated with bovine sera (n=139) with MAT titers of <100 to L. interrogans serovars canicola, copenhageni, grippotyphosa, hardjo, pomona and sejroe. Thirty six of 258 field sera (13.95%) with serovar pomona MAT titers of <100, gave positive reactions in the ELISA.