PKs的生物学功能

PKs是最近发现的多功能分泌蛋白,由PK1和PK2组成.在不同的系统中,它们通过两个高度同源G-蛋白偶联受体发挥各种生物学功能.它们与神经和血管的形成以及免疫应答的调节有关,并且对生殖系统的正常生理和促性腺激素释放激素系统的发育都有很大的影响.     

Non-Peptide Agonists and Antagonists of the Prokineticin Receptors

The prokineticin family comprises a group of secreted peptides that can be classified as chemokines based on their structural features and chemotactic and immunomodulatory functions. Prokineticins (PKs) bind with high affinity to two G protein-coupled receptors (GPCRs). Prokineticin receptor 1 (PKR1) and prokineticin receptor 2 (PKR2) are involved in a variety of physiological functions such as angiogenesis and neurogenesis, hematopoiesis, the control of hypothalamic hormone secretion, the regulation of circadian rhythm and the modulation of complex behaviors such as feeding and drinking. Dysregulation of the system leads to an inflammatory process that is the substrate for many pathological conditions such as cancer, pain, neuroinflammation and neurodegenerative diseases such as Alzheimer’s and Parkinson’s disease. The use of PKR’s antagonists reduces PK2/PKRs upregulation triggered by various inflammatory processes, suggesting that a pharmacological blockade of PKRs may be a successful strategy to treat inflammatory/neuroinflammatory diseases, at least in rodents. Under certain circumstances, the PK system exhibits protective/neuroprotective effects, so PKR agonists have also been developed to modulate the prokineticin system.     

Analysis of role of aromatic residues in extracellular loop 2 of Prokineticin receptor 2 in ligand binding probed with genetically encoded photo-crosslinkers

Prokineticin 2 (PK2) and Prokineticin 2 beta (PK2β), products of alternative splicing of pk2 gene, are chemokine-like proteins. While PK2 mediates its biological activities by signaling with the same efficiency through two homologous G protein coupled receptors, prokineticin receptor 1 (PKR1) and prokineticin receptor 2 (PKR2), PK2β is able to bind specifically PKR1.Extracellular loop 2 (ECL2) of chemokine receptors is a part of a transmembrane (TM) ligand binding site. In the ECL2 of PKR2 is present, as well as in all chemokine receptors, an aromatic residue cluster, involving tryptophan 212 localized four residues after an ECL2 conserved cysteine, and Phenylalanine 198 located in the top of TM 4.In this work, the photoactivatable unnatural amino acid p-benzoyl-L-phenylalanine is incorporated by amber codon suppression technology into PKR2 in position 212. Experiments of photoactivatable cross-linking demonstrated the role of tryptophan in position 212 for binding the ligand contacting Tryptophan in position 24. We also analyzed the role of Phenylalanine 198 in the specificity of PKRs binding. The comparison of TM-bundle binding sites between PKR1 and PKR2 revealed that they are completely conserved except for one residue: valine 207 in human PKR1, which is phenylalanine 198 in human PKR2. The F198V mutation in PKR2 permits to obtain a receptor able to bind more efficiently PK2β, a ligand highly specific for PKR1.     

两栖类动物皮肤分泌物及其生物学适应意义--大蹼铃蟾皮肤分泌物蛋白质多肽组的启示

以大蹼铃蟾(Bombina maxima)为代表性物种,揭示了两栖类皮肤分泌物蛋白质多肽组丰富的分子和功能多样性。目前在大蹼铃蟾已发现的分子包括3类不同的抗菌肽、缓激肽、缓激肽增强肽和缓激肽拮抗肽、缓激肽基因相关肽、富含脯氨酸铃蟾肽及其基因相关肽、神经调节素U、Bv8肽、三叶型蛋白和蛋白酶抑制剂等。抗菌肽分子多样性及其形成机制、缓激肽及其基因相关肽功能和表达模式的多样性都较好地揭示了在多样的生态条件下,两栖类皮肤活性肽环境适应的分子基础及生物合成的调控机制。富含血红素辅基的白蛋白广泛分布在大蹼铃蟾皮肤外皮层细胞膜上和真皮海绵层内,表明它在皮肤的生理功能,如在呼吸、物质交换和渗透压调节中有重要作用。两栖类皮肤分泌物蛋白质多肽组,由于其分子结构的多样性、新颖性和哺乳类同系物的存在,在生物医学研究和天然药物开发中具有独特和不可替代的价值;同时,两栖类皮肤功能基因组具有多样性丰富、快速重组突变的特征,是探讨生物适应的基因基础、基因形成机制和进化特性等生物学基本问题的优秀模型。     

Mechanisms that underlie the internalization and extracellular signal regulated kinase 1/2 activation by PKR2 receptor

Prokineticins (PKs) are a pair of signal factors involved in many physiological processes by binding to two closely related G-protein-coupled receptors (GPCRs), PKR1 and PKR2. We recently demonstrated that PKR2 undergoes rapid ligand-induced endocytosis, and PKR2 recycles back to the plasma membrane after the removal of ligand. However, little is known about the molecular mechanisms underlying the PKR2 endocytosis. Here, we studied the involvement of GPCR kinase 2 (GRK2), β-arrestins, clathrin and protein kinase C (PKC) in the PKR2 endocytosis. Our results indicated that PK2-induced PKR2 endocytosis is GRK2- and clathrin-dependent, but β-arrestin-independent. PKC activation also induced PKR2 endocytosis; however, PKC activation is not necessary for the PK2-induced PKR2 endocytosis. PK2 stimulation induced a transient activation of extracellular signal regulated kinase 1/2 (ERK1/2) on PKR2 expressing cells. The internalization and PKC activation are not required for the PK2-induced ERK1/2 activation. Our results indicated that PK2-induced ERK1/2 activation may involve the released βγ subunits of G-protein, phospholipase C β and MEK activation.     

Two novel Bv8-like peptides from skin secretions of the toad Bombina maxima

Two novel bioactive peptides were purified from skin secretions of the toad Bombina maxima. The partial N-terminal sequences of these two peptides were determined by automated Edman degradation. This allowed the cloning of full-length cDNAs encoding these two peptides from a cDNA library prepared from the toad skin. The deduced complete amino acid sequences indicate that both peptides are composed of 77 amino acids. A FASTA search in the databanks revealed that they exhibit 86-91% sequence identity with Bv8, a peptide originally isolated from skin secretions of Bombina variegata. They were thus named as Bv8-like peptide 1 (Bv8-LP1) and Bv8-like peptide 2 (Bv8-LP2), respectively. Sequence differences between Bv8-LP1 and 2 were due to six amino acid substitutions at positions 6, 11, 23, 24, 62 and 63. Bv8-LP1 and 2 differed from Bv8 with eleven and seven amino acid substitutions, respectively. Like Bv8, Bv8-LP1 and 2 possessed contractile activity on isolated guinea pig ileum. Additionally, they stimulated contraction of rabbit aortic rings in a dose-dependent manner at nanomolar concentrations.     

Expression of prokineticin 2 and its receptor in the macaque monkey brain

Prokineticin 2 (PK2) has been indicated as an output signaling molecule for the suprachiasmatic nucleus (SCN) circadian clock. Most of these studies were performed with nocturnal animals, particularly mice and rats. In the current study, the PK2 and its receptor, PKR2, was cloned from a species of diurnal macaque monkey. The macaque monkey PK2 and PKR2 were found to be highly homologous to that of other mammalian species. The mRNA expression of PK2 and PKR2 in the macaque brain was examined by in situ hybridization. The expression patterns of PK2 and PKR2 in the macaque brain were found to be quite similar to that of the mouse brain. Particularly, PK2 mRNA was shown to oscillate in the SCN of the macaque brain in the same phase and with similar amplitude with that of nocturnal mouse brain. PKR2 expression was also detected in known primary SCN targets, including the midline thalamic and hypothalamic nuclei. In addition, we detected the expression of PKR2 mRNA in the dorsal raphe nucleus (DR) of both macaque and mouse brains. As a likely SCN to dorsal raphe projection has previously been indicated, the expression of PKR2 in the raphe nuclei of both macaque and mouse brain signifies a possible role of DR as a previously unrecognized primary SCN projection target.     

ERK2-Pyruvate Kinase Axis Permits Phorbol 12-Myristate 13-Acetate-induced Megakaryocyte Differentiation in K562 Cells

Metabolic changes that contribute to differentiation are not well understood. Overwhelming evidence shows the critical role of glycolytic enzyme pyruvate kinase (PK) in directing metabolism of proliferating cells. However, its role in metabolism of differentiating cells is unclear. Here we studied the role of PK in phorbol 12-myristate 13-acetate (PMA)-induced megakaryocytic differentiation in human leukemia K562 cells. We observed that PMA treatment decreased cancer-type anabolic metabolism but increased ATP production, along with up-regulated expression of two PK isoforms (PKM2 and PKR) in an ERK2-dependent manner. Interestingly, silencing of PK (PKM2 and PKR) inhibited PMA-induced megakaryocytic differentiation, as revealed by decreased expression of megakaryocytic differentiation marker CD61 and cell cycle behavior. Further, PMA-induced ATP production reduced greatly upon PK silencing, suggesting that PK is required for ATP synthesis. In addition to metabolic effects, PMA treatment also translocated PKM2, but not PKR, into nucleus. ERK1/2 knockdowns independently and together suggested the role of ERK2 in the up-regulation of both the isoforms of PK, proposing a role of ERK2-PK isoform axis in differentiation. Collectively, our findings unravel ERK2 guided PK-dependent metabolic changes during PMA induction, which are important in megakaryocytic differentiation.     

Interaction of Hsp40 with influenza virus M2 protein: implications for PKR signaling pathway

Influenza virus contains three integral membrane proteins: haemagglutinin, neuraminidase, and matrix protein (M1 and M2). Among them, M2 protein functions as an ion channel, important for virus uncoating in endosomes of virus-infected cells and essential for virus replication. In an effort to explore potential new functions of M2 in the virus life cycle, we used yeast two-hybrid system to search for M2-associated cellular proteins. One of the positive clones was identified as human Hsp40/Hdj1, a DnaJ/Hsp40 family protein. Here, we report that both BM2 (M2 of influenza B virus) and A/M2 (M2 of influenza A virus) interacted with Hsp40 in vitro and in vivo. The region of M2-Hsp40 interaction has been mapped to the CTD1 domain of Hsp40. Hsp40 has been reported to be a regulator of PKR signaling pathway by interacting with p58^IPK that is a cellular inhibitor of PKR. PKR is a crucial component of the host defense response against virus infection. We therefore attempted to understand the relationship among M2, Hsp40 and p58^IPK by further experimentation. The results demonstrated that both A/M2 and BM2 are able to bind to p58^IPKin vitro and in vivo and enhance PKR autophosphorylation probably via forming a stable complex with Hsp40 and P58^IPK, and consequently induce cell death. These results suggest that influenza virus M2 protein is involved in p58^IPK-mediated PKR regulation during influenza virus infection, therefore affecting infected-cell life cycle and virus replication.     

Molecular cloning and characterization of prokineticin receptors

Recent studies have identified two novel biofunctional proteins, termed prokineticin 1/EG-VEGF and prokineticin 2, which were mammalian homologues of mamba MIT1 and frog Bv8. Prokineticins have been demonstrated to exert their physiological functions through G-protein coupled receptors (GPCRs). In this study, we report the molecular identification of two endogenous prokineticin receptors, designated PK-R1 and PK-R2, through a search of the human genomic DNA database. PK-R1, locating in chromosome 2, and PK-R2, locating in chromosome 20p13, shared 87% homology, which was an extremely high value among known GPCRs. In functional assays, mammalian cells expressing PK-Rs responded to prokineticins in a concentration-dependent manner. Tissue distribution analysis revealed that expression of PK-R1 was observed in the testis, medulla oblongata, skeletal muscle and skin, while that of PK-R2 showed preferential expression in the central nervous system. The tissue distribution of PK-Rs reported in this paper suggests that the prokineticins play multifunctional roles in vivo.     

Disease-causing mutation in PKR2 receptor reveals a critical role of positive charges in the second intracellular loop for G-protein coupling and receptor trafficking

Prokineticins are a pair of signal factors involved in many physiological processes by binding to two closely related G-protein-coupled receptors, PKR1 and PKR2. Recently, mutations in prokineticin 2 (PK2) and PKR2 are found to be associated with Kallmann syndrome and/or idiopathic hypogonadotropic hypogonadism, disorders characterized by delayed puberty and infertility. However, little is known how PKRs interact and activate G-proteins to elicit signal transduction. In the present study, we took advantage of one disease-associated mutation (R164Q) located in the second intracellular (IL2) loop of PKR2, to investigate the role of IL2 loop in the cell signaling, G-protein binding and receptor trafficking. R164Q mutant PKR2 showed normal cell surface expression and ligand binding capacity. However, the PKR2 signaling was abolished by R164Q mutation. We demonstrated that R164Q mutation disrupted the interaction of IL2 loop to the Gα(q), Gα(i), and Gα(16)-proteins. A positive-charged amino acid at this position is required for proper function, and the signaling efficacy and potency depend on the net amount of positive charges. We also demonstrated that the interactive partner of Arg-164 may localize in the C-terminal five residues of Gα(q)-protein. A series of mutation analysis indicated that the basic amino acids at the C terminus of IL2 loop may function cooperatively in GPCRs. Furthermore, R164Q mutation also results in minimal ligand-induced endocytosis of PKR2. As many GPCRs share structural homology in the C terminus of IL2 loop, our findings may have general application in understanding structure and function of GPCRs.     

Bacterial production and purification of SGPI-1 and SGPI-2, two peptidic serine protease inhibitors from the desert locust, Schistocerca gregaria

The last decade, a new serine protease inhibitor family has been described in arthropods. Eight members were purified from the locusts Locusta migratoria (LMPI-1-2 and HI) and Schistocerca gregaria (SGPI-1-5) and 11 additional locust peptides were identified by cDNA cloning. Furthermore, the light chain of the 155-kDa heterodimeric protease inhibitor pacifastin, from the freshwater crayfish Pacifastacus leniusculus, was found to be composed of nine consecutive inhibitory domains (PLDs). These domains share a pattern of 6 conserved cysteine residues (Cys-Xaa(9-12)-Cys-Asn-Xaa-Cys-Xaa-Cys-Xaa(2-3)-Gly-Xaa(3-4)-Cys-Thr-Xaa3-Cys) with the locust inhibitors. So far, for most of the PLD-related peptides the biological functions remain obscure. To obtain sufficient amounts of material to perform physiological experiments, we have optimised the production of SGPI-1-2 via a bacterial (Escherichia coli) expression system. The cDNA sequences encoding these peptides were inserted in the pMAL-2pX vector, downstream of the gene encoding the maltose-binding protein (including a signal peptide). As a consequence, both peptides were expressed as fusion proteins (2-3 mg/l) and targeted to the periplasmic space. Following a one-step affinity purification, both fusion proteins were successfully cleaved by Factor Xa and after a methanol extraction, it took only one additional RP-HPLC run to purify both peptides to homogeneity. Finally, the formation of the disulphide bridges and the biological activity of the recombinant peptides were verified by mass spectrometry and a spectrophotometric protease inhibitor assay, respectively.     

Involvement of classical bipartite/karyopherin nuclear import pathway components in acrosomal trafficking and assembly during bovine and murid spermiogenesis

This study arose from our finding that SubH2Bv, a histone H2B variant residing in the subacrosomal compartment of mammalian spermatozoa, contains a bipartite nuclear localization signal (bNLS) but in spite of this did not enter the spermatid nucleus. Instead, it associated with proacrosomic and acrosomic vesicles, which were targeted to the nuclear surface to form the acrosome. On this basis we proposed that SubH2Bv targets proacrosomic/acrosomic vesicles from the Golgi apparatus to the nuclear envelope by utilizing the classical bipartite/karyopherin alpha (KPNA) nuclear import pathway. To test the protein's nuclear targeting ability, SubH2Bv, with and without targeted mutations of the basic residues of bNLS, as well as bNLS alone, were transfected into mammalian cells as GFP-fusion proteins. Only the intact bNLS conferred nuclear entry. Subsequently, we showed that a KPNA, most likely KPNA6, occupies the same sperm head compartment and follows the same pattern of acrosomal association during spermiogenesis as SubH2Bv. Sperm head fractionation combined with Western blotting located this KPNA to the subacrosomal layer of the perinuclear theca, while immunocytochemistry of testicular sections showed that it associates with the surface of proacrosomic/acrosomic vesicles during acrosomal biogenesis. The identical sperm-localization and testicular-expression patterns between KPNA and SubH2Bv suggested a potential binding interaction between these proteins. This was supported by recombinant SubH2Bv affinity pull-down assays on germ cell extracts. The results of this study provide a compelling argument that these two nuclear homing proteins work in concert to direct the acrosomic vesicle to the nucleus. Their final residence in the subacrosomal layer of the perinuclear theca of spermatozoa indicates a role for SubH2Bv and KPNA in acrosomal-nuclear docking.     

Cysteine Cathepsins in the secretory vesicle produce active peptides: Cathepsin L generates peptide neurotransmitters and cathepsin B produces beta-amyloid of Alzheimer's disease

Recent new findings indicate significant biological roles of cysteine cathepsin proteases in secretory vesicles for production of biologically active peptides. Notably, cathepsin L in secretory vesicles functions as a key protease for proteolytic processing of proneuropeptides (and prohormones) into active neuropeptides that are released to mediate cell-cell communication in the nervous system for neurotransmission. Moreover, cathepsin B in secretory vesicles has been recently identified as a β-secretase for production of neurotoxic β- amyloid (Aβ) peptides that accumulate in Alzheimer's disease (AD), participating as a notable factor in the severe memory loss in AD. These secretory vesicle functions of cathepsins L and B for production of biologically active peptides contrast with the well-known role of cathepsin proteases in lysosomes for the degradation of proteins to result in their inactivation. The unique secretory vesicle proteome indicates proteins of distinct functional categories that provide the intravesicular environment for support of cysteine cathepsin functions. Features of the secretory vesicle protein systems insure optimized intravesicular conditions that support the proteolytic activity of cathepsins. These new findings of recently discovered biological roles of cathepsins L and B indicate their significance in human health and disease. This article is part of a Special Issue entitled: Proteolysis 50 years after the discovery of lysosome.     

Involvement of double-stranded RNA-dependent protein kinase and phosphorylation of eukaryotic initiation factor-2alpha in neuronal degeneration

Inhibition of protein translation plays an important role in apoptosis. While double-stranded RNA-dependent protein kinase (PKR) is named as it is activated by double-stranded RNA produced by virus, its activation induces an inhibition of protein translation and apoptosis via the phosphorylation of the eukaryotic initiation factor 2alpha (eIF2alpha). PKR is also a stress kinase and its levels increase during ageing. Here we show that PKR activation and eIF2alpha phosphorylation play a significant role in apoptosis of neuroblastoma cells and primary neuronal cultures induced by the beta-amyloid (Abeta) peptides, the calcium ionophore A23187 and flavonoids. The phosphorylation of eIF2alpha and the number of apoptotic cells were enhanced in over-expressed wild-type PKR neuroblastoma cells exposed to Abeta peptide, while dominant-negative PKR reduced eIF2alpha phosphorylation and apoptosis induced by Abeta peptide. Primary cultured neurons from PKR knockout mice were also less sensitive to Abeta peptide toxicity. Activation of PKR and eIF2alpha pathway by Abeta peptide are triggered by an increase in intracellular calcium because the intracellular calcium chelator BAPTA-AM significantly reduced PKR phosphorylation. Taken together, these results reveal that PKR and eIF2alpha phosphorylation could be involved in the molecular signalling events leading to neuronal apoptosis and death and could be a new target in neuroprotection.