Precursor Convertases Research Articles

The Ca2+ binding capacity of epidermal furin is disrupted by H2O2‐mediated oxidation in vitiligo

It was previously established that epidermal keratinocytes and melanosomes express the Ca2+‐dependent precursor convertase furin. All prohormone convertases including furin are regulated by Ca2+. Meanwhile, it is noteworthy that proopiomelanocortin (POMC) cleavage is processed by furin, in addition to the classical PC1 and PC2 convertases, leading to the production of ACTH, β‐LPH and β‐endorphin. Since numerous epidermal peptides and enzymes are affected by H2O2‐mediatedoxidation, including the POMC derived peptides α‐MSH and β‐endorphin, as shown in the epidermis of patients with vitiligo, it was of interest whether furin could also be a possible target for this oxidation mechanism. Confirming the presence of furin in epidermal keratinocytes and melanocytes using immunoflurescence, RT‐PCR, and Western blotting, we further demonstrate significantly decreased in situ immunoreactivity of furin in the epidermis of patients with progressive vitiligo suggesting H2O2‐mediated oxidation. This was substantiated by [45Ca2+] binding studies with human recombinant furin identifying the loss of one Ca2+‐binding site from the enzyme after oxidation with H2O2. Computer simulation supported alteration of one of the two Ca2+‐binding sites on furin. Overall, our results demonstrate that the Ca2+ dependent proteolytic activity of this convertase is a target for H2O2‐mediated oxidation which in turn could contribute to the reduced epidermal expression of the POMC derived peptides α‐MSH and β‐endorphin as documented earlier in patients with vitiligo.

The Ca2+-Binding Capacity of Epidermal Furin Is Disrupted by H2O2-Mediated Oxidation in Vitiligo

The Ca(2+)-dependent precursor convertase furin is abundantly expressed in epidermal keratinocytes and melanocytes. In this context, it is noteworthy that proopiomelanocortin (POMC) cleavage is also processed by furin, leading to ACTH, beta-lipotropin, and beta-endorphin. All prohormone convertases including furin are regulated by Ca(2+). Because numerous epidermal peptides and enzymes are affected by H(2)O(2)-mediated oxidation, including the POMC-derived peptides alpha-MSH and beta-endorphin as shown in the epidermis of patients with vitiligo, we here asked the question of whether furin could also be a possible target for this oxidation mechanism by using immunofluorescence, RT-PCR, Western blotting, Ca(2+)-binding studies, and computer modeling. Our results demonstrate significantly decreased in situ immunoreactivity of furin in the epidermis of patients with progressive vitiligo (n = 10), suggesting H(2)O(2)-mediated oxidation. This was confirmed by (45)Ca(2+)-binding studies with human recombinant furin identifying the loss of one Ca(2+)-binding site from the enzyme after oxidation with H(2)O(2). Computer simulation supported alteration of one of the two Ca(2+)-binding sites on furin. Taken together, our results implicate that the Ca(2+)-dependent proteolytic activity of this convertase is targeted by H(2)O(2), which in turn could contribute to the reduced epidermal expression of the POMC-derived peptides alpha-MSH and beta-endorphin as documented earlier in patients with vitiligo.

Structural investigation of the HIV-1 envelope glycoprotein gp160 cleavage site.

The selective proteolytic activation of the HIV-1 envelope glycoprotein gp160 by furin and other precursor convertases (PCs) occurs at the carboxyl side of the sequence Arg508-Glu-Lys-Arg511 (site 1), in spite of the presence of another consensus sequence: Lys500-Ala-Lys-Arg503 (site 2). We report on the solution structural analysis of a 19-residue synthetic peptide, p498, which spans the two gp160-processing sites 1 and 2, and is properly digested by furin at site 1. A molecular model is obtained for p498, by means of molecular dynamics simulations, from NMR data collected in trifluoroethanol/water. The peptide N-terminal side presents a 9-residue helical segment, enclosing the processing site 2; the C-terminal segment can be described as a loop exposing the processing site 1. A hypothesis for the docking of p498 onto the catalytic domain of human furin, modeled by homology and fitting previous site-directed mutagenesis studies, is also presented. p498 site 1 is shown to have easy access to the furin catalytic site, unlike the nonphysiological site 2. Finally, on the basis of available data, we suggest a possible structural motif required for the gp160-PCs recognition.

Proprotein and prohormone convertases: a family of subtilases generating diverse bioactive polypeptides

Proproteins and prohormones are the fundamental units from which bioactive proteins and peptides as well as neuropeptides are derived by limited proteolysis within the secretory pathway. Precursors are usually cleaved at the general motif (K/R)–(X)n–(K/R)↓, where n=0, 2, 4 or 6 and X is any amino acid and usually is not a Cys. Seven mammalian precursor convertases (PCs) have been identified: PC1, PC2, furin, PC4, PC5, PACE4 and PC7. Each of these enzymes, either alone or in combination with others, is responsible for the tissue-specific processing of multiple polypeptide precursors both in the brain and in periphery. This combinatorial mechanism generates a large diversity of bioactive molecules in an exquisitively regulated manner. The production of null mice allowed the assessment of the critical role of convertases in vivo. Thus, male PC4 (−/−) mice are infertile, furin (−/−) and PC1(−/−) mice are embryonic lethal, and PC2 (−/−) mice are mildly diabetic and runted. Interestingly, animals deficient in 7B2, a PC2-specific binding protein, exhibit a Cushing-like syndrome and die soon after birth. Recently, the first member of a new class of subtilisin–kexin-like convertases, called SKI-1, was identified. Its structure is closer to pyrolysin than to mammalian PCs and it exhibits a specificity for cleavage at the motif (R/K)–X–X–(L,T)↓ as deduced from its ability to process sterol regulatory element binding proteins and pro-brain derived neurotrophic factor. Thus, while PCs are responsible for the processing of neuropeptides, adhesion molecules, receptors, growth factors, cell surface glycoprotein and enzymes, SKI-1 cleaves proproteins that are critical for the control of cholesterol and fatty acid metabolism and for neuronal protection and growth.

The RGD Motif and the C-terminal Segment of Proprotein Convertase 1 Are Critical for Its Cellular Trafficking but Not for Its Intracellular Binding to Integrin α5β1

Cellular trafficking of subtilisin/kexin-like precursor convertases (PCs) may be regulated by a number of motifs, some of which are present within the P-domain and in the C-terminal sequence. Six of the seven known PCs contain a conserved RGD sequence within the P domain. In order to investigate the functional importance of this motif, we generated mutants of PC1 that contain a Myc tag epitope inserted between the prosegment and the catalytic subunit. Cellular expression of vaccinia virus recombinants revealed that this tag did not seem to influence the autocatalytic conversion of proPC1 into PC1 or its bioactivity. The two PC1 variants produced possess either the wild type RGD sequence or its RGE mutant. Stable transfectants of these variants in AtT20 cells revealed that similar to the wild type enzyme, PC1-RGD-Myc is sorted to secretory granules. In contrast, PC1-RGE-Myc exits the cell via the constitutive secretory pathway. In vitro, a 14-mer peptide spanning the RGD sequence of PC1, but not its RGE mutant, binds to cell surface vitronectin-binding integrins of Chinese hamster ovary cells. However, within the endoplasmic reticulum and in an RGD-independent fashion, integrin alpha5beta1 associates primarily with the zymogens proPC1, proPC1-DeltaC (missing the C-terminal 137 residues), as well as proPC2. Thus, the observed discrimination between the secretion routes of PC1-RGD and PC1-RGE does not implicate integrins such as alpha5beta1.

Dynamics of proopiomelanocortin and prohormone convertase 2 gene expression in Xenopus melanotrope cells during long-term background adaptation.

The toad Xenopus laevis is able to adapt its skin color to background light intensity. In this neuroendocrine reflex, the proopiomelanocortin (POMC)-derived peptide alpha-melanophore-stimulating hormone (alphaMSH) is a key regulatory factor. In animals adapting to a black background, release of alphaMSH from the pituitary pars intermedia causes dispersal of melanin in skin melanophores. To investigate the long-term in vivo dynamics of alphaMSH production during black background adaptation, the biosynthetic rate of POMC and the contents of POMC, alphaMSH and the POMC processing enzyme precursor convertase 2 (PC2) have been studied in the pars intermedia using pulse-labeling, Western blot and radioimmunoassay. In control animals, adapted to a white background, the rate of POMC biosynthesis and the POMC content were low, while high alphaMSH and PC2 contents were found. After 1 week of adaptation to a black background, the rate of POMC biosynthesis and the POMC protein content had increased 19- and 3.7-fold respectively. These parameters attained a maximum level (28- and 5. 8-fold higher than control) after 3 weeks and remained at these elevated levels for at least 12 weeks. After 1 week, the pars intermedia content of alphaMSH was only 30% of the control level, but after 6 and 12 weeks, the alphaMSH level had increased to the control level. The PC2 content decreased to 52% of control after 1 week and stabilized after 3 weeks at a level slightly lower than the control value. The results show that during long-term background adaptation a steady-state situation is reached, with a balance between the biosynthesis, enzymatic processing and release of alphaMSH. The in vivo dynamics of the processing enzyme PC2 suggest a parallel storage and release of alphaMSH and mature PC2 in the Xenopus pituitary pars intermedia.

Identification of the Paired Basic Convertases Implicated in HIV gp160 Processing Based on in Vitro Assays and Expression in CD4+ Cell Lines

The human immunodeficiency virus HIV envelope glycoprotein gp160 is synthesized as an inactive precursor, which is processed into its fusiogenic form gp120/gp41 by host cell proteinases during its intracellular trafficking. Kexin/subtilisin-related endoproteases have been proposed to be enzyme candidates for this maturation process. In the present study, 1) we examined the ability of partially purified precursor convertases and their isoforms to cleave gp160 in vitro. The data demonstrate that all the convertases tested specifically cleave the HIV envelope glycoprotein into gp120 and gp41. 2) We demonstrated that a 19-amino acid model peptide spanning the gp120/gp41 junction is cleaved by all convertases at the same gp160 site as that recognized in HIV-infected cells. 3) In an effort to evaluate specific convertase inhibitors, we showed that the alpha1-antitrypsin variant, alpha1-PDX, inhibits equally well the ability of the tested convertases to cleave gp160 in vitro. 4) Three lymphocyte cell lines were screened by reverse transcription polymerase chain reaction in an effort to identify which are the convertases expressed in the most common HIV target, the CD4(+) lymphocytes. The data demonstrate that furin, PC5/6, and the newly cloned PC7 are the main transcribed convertases, suggesting that these proteinases are the major gp160-converting enzymes in T4 lymphocytes.

Implications of the subtilisin/kexin-like precursor convertases in the development and function of nervous tissues.

Furin, PC1, PC2, and PC5 represent mammalian convertases (PCs) found in endocrine, central and peripheral nervous tissues, which cleave a number of precursors at basic residues normally processed in vivo. Typical bonds cleaved by PCs include the pairs Lys-Arg, Arg-Arg and Arg-X-Lys/Arg-Arg. These cleavage sites have been detected following coexpression of each convertase in cell lines together with different precursors as models, including proopiomelanocortin (POMC), proinsulin and proNGF and proBDNF. The presence of PCs and different precursors was revealed by in situ hybridization or immunocytochemistry in cultured AtT-20 cells, in the developing CNS, pituitary, and pancreatic islets. In an experimental model of epilepsy in which epileptiform activities were provoked by kainic acid administration, we observed a similar transient expression of furin and PC1 as compared to that of NGF and BDNF. In conclusion, it is proposed that under different stimuli various precursors are activated by a unique cocktail of convertases, each of which either alone or in combination with others acts to process inactive precursors, and thereby playing an important role in development and in the plasticity of the neuronal system.

Structure-function studies on the biosynthesis and bioactivity of the precursor convertase PC2 and the formation of the PC2/7B2 complex

Site directed mutagenesis of the prohormone convertase PC2 was used to define the effect of certain residues on the zymogen activation of proPC2 and on its binding to the neuroendocrine protein 7B2. These included the oxyanion hole Asp 309 (D309N), the N-terminal Glu 25 (E25Q and E25K) of proPC2 and the Asp 519 (D519E) of the RGD motif within the P-domain of PC2. Heterologous vaccinia virus expression of the wild type and mutant PC2's in endocrine pituitary cells such as AtT20 and GH3 cells demonstrated that the most dramatic effect was observed with the D309N mutant which no longer bound pro7B2 and which exhibited a significant reduction in its capacity to produce β-endorphin from pro-opiomelanocortin (POMC).

Processing of two homologous precursors, pro-neuropeptide Y and pro-pancreatic polypeptide, in transfected cell lines expressing different precursor convertases

The processing of two homologous precursors, pro-neuropeptide Y (pro-NPY) and pro-pancreatic poly-peptide (pro-PP), was studied in four neuroendocrine cell lines after transfection: CA-77 medullary thyroid carcinoma cells, AtT-20 corticotrope pituitary cells, RIN2A-19 pancreatic endocrine cells, and NB1 neuroblastoma cells. Northern blot analysis indicated that the AtT-20 cells only expressed precursor convertase 3; in contrast, NB1 cells only expressed precursor convertase 2, whereas the RIN2A-19 and CA-77 cells expressed both enzymes. Despite these differences in expression pattern of precursor convertases the four cell lines were, surprisingly, indistinguishable in respect to their processing of pro-PP and pro-NPY. In all four cell lines, pro-NPY was almost completely converted to NPY, and, in all four cell lines, only around 50% of the PP precursor was converted to PP. The relatively poor processing efficiency of pro-PP was rather similar to the processing efficiency of the endogenously produced precursors in the respective cell lines, pro-calcitonin (CA-77), proopiomelanocortin (AtT-20), proinsulin (RIN2A-19), and pro-vasoactive intestinal polypeptide (NB1). At least in the CA-77 cells, NPY and PP were apparently sorted to the regulated secretory pathway, as upon stimulation with secretagogue the release of the transfected peptides increased in parallel with the endogenously expressed peptide, calcitonin gene-related peptide. Mutagenesis studies showed that on the N-terminal side of the di-basic processing site, the otherwise important difference in structure between PP and NPY, a proline for glutamine in position 34, was not responsible for the difference in processing efficiency. On the C-terminal side of the processing site, the efficient processing of pro-NPY could not be transferred to pro-PP by exchanging the whole C-terminal domains of the precursors. It is concluded that pro-NPY is processed more efficiently than pro-PP in all neuroendocrine cell lines tested independent on their expression of the two main precursor convertases and that mutagenesis data indicate that the structural element responsible for the efficient processing of pro-NPY is not located on the N-terminal side of the dibasic processing site.