ABSTRACT
A novel matrix metalloproteinase (MMP) was identified from leukocytes and found to be specifically expressed by peripheral blood leukocytes among 29 different tissues examined. Named leukolysin, it encodes for 562 residues with a conserved MMP structure, i.e, pre-, pro-, catalytic-, hinge- and hemopexin-like domains, but also a RXK/RR motif, known for its role in MMP zymogen activation, and a C-terminal hydrophobic segment. Overall, leukolysin displays the strongest homology to the newly identified MT-MMP subgroup with 45% and 39% identities to MT4- and MT1-MMPs vs 30% and 31.5% to MMP1 and 3 respectively. Unlike MT4-MMP whose proteolytic activity remains undefined, a C-terminally truncated leukolysin is expressed as a strong gelatinolytic species at 28 kDa which is derived from a cell-associated 34 kDa proenzyme, presumably by furin or proprotein convertase mediated removal of the propeptide ( ∼ 6 kDa). By green fluorescent protein (GFP) tagging, the intracellular proenzyme is localized to granules throughout the cell, suggesting that activation occur immediately prior to secretion. Taken together, leukolysin may be part of the proteolytic arsenal deployed by leukocytes during inflammatory responses.
Similar content being viewed by others
INTRODUCTION
Members of the matrix metalloproteinases (MMP) have been consistently implicated in the destruction of extracellular matrix (ECM) under many pathophysiological conditions from angiogenesis to arthritis6,7. To keep these powerful proteinases in latent form, most MMPs rely on a conserved cysteine in the prodomains to interact with the catalytic zinc according to the cysteine-switch latency model ADDIN ENRfu8. The only exception is the newly identified CA-MMP which lacks a cysteine-switch in the prodomain9. At the carboxyl-termini, a hemopexin-like domain is found in all MMPs except CA-MMP and matrilysin9, 10, 11. Recently, two additional motifs have been recognized within the MMP family: 1) a RXK/RR motif for furin or proprotein convertase (PC) mediated zymogen activation12, 13, 14; and 2) a hydrophobic segment at the carboxyl termini of MMP14-17 consistent with that of a transmembrane domain15, 16, 17, 18. Based on these functional domains, a diverse family of MMPs must have been evolved to accomplish the tasks of ECM remodeling necessary for the growth and development of multicellular organisms such as human. In this report, a novel MMP named leukolysin was identified in leukocytes. Known for their roles in inflammatory response4, white cells may deploy leukolysin when exiting the blood stream to reach the inflammatory sites and/or mediating the destruction of invading pathogens and infected host tissues.
MATERIALS AND METHODS
Cell lines and reagents
Mammalian cells including MDCK cells and COS 7 are cultured as described19, 20. Reagents associated with recombinant DNA techniques were purchased from Promega (Madison, WI). The RT-PCR/RACE kit is from Roche Diagnostics (Indianapolis, IN). Oligonucleotide primers were made by either the University of Minnesota microchemical core facility or IDT (Coralville, IA). FLAG peptide, anti-FLAG M2 monoclonal antibody and agarose beads were purchased from Sigma (St. Louis, MO).
Molecular cloning and sequence analysis of human leukolysin
Initially, EST clones (AI150017 and AA830519, both from IMAGE consortium21) were identified through a BLAST search to encode a putative MMP showing 60% identity to Leu235-Gly298 of MT4-MMP18, 22. Based on these sequences, subsequent RT-PCR and RACE reactions using RNA isolated from human leukocytes were performed to isolated a composite 2.6 kb cDNA which encodes an open reading frame. Sequencing and sequence analysis was performed as described previously20.
Tissue distribution of leukolysin
Human cDNA panels were purchased from Clontech (Palo Alto, CA) and amplified for the expression of leukolysin with two primers (TAC GCT CTG AGC GGC AGC and CCC ATA GAG TTG CTG CAG) at the following conditions: 2 min at 94°C for denaturation, 35 cycles of 10 sec at 94°C for denaturation, 30 sec at 52°C for annealing and 30 sec at 72°C for extension, followed by 10 min extension at 72°C. The house-keeping gene GAPDH was used as internal references as described previously9.
Expression vectors for leukolysin1-280, leukolysin1-280-GFP and generation of their stable transfectants
The first 280 residues of leukolysin was isolated by high-fidelity PCR with pfu polymerase (15 cycles) and inserted into two vectors: pCR3.1-FLAG and pCR3.1-GFP-FLAG (Pei, etal unpublished). The 3′ end of the insert was designed such that it is inserted in-frame with FLAG and GFP-FLAG respectively. The resulting vectors were sequenced and confirmed to be error-free and in-frame as designed. The resulting expression vectors were transfected into MDCK cells and stable clones were obtained by G418 selection19. More than 20 clones were isolated for each transfection. For screening, serum-free conditioned media from each clone were analyzed by gelatin-zymography and Western blot using M2 antibody9. For analysis of cell associated recombinant protein, cells were lysed in RIPA buffer (50 mM Tris, pH 7.5, 150 mM NaCl, 0.25% sodium deoxycholate, 0.1% Nonidet P-40, 10μM leupeptin, 0.1 μM 5-APMSF, 1 mM aprotinin). Cleared of any debris by microcentrifugation, the lysates were fractionated on SDS-PAGE and Western blotted with M2 antibody as described above.
Confocal microscopy
Cells were washed twice in PBS, fixed in 4% paraformaldehyde (30 min) and examined on a BioRad MRC confocal system maintained at the Biological Imaging and Processing Laboratory of the University of Minnesota.
RESULTS
Identification of a novel MMP named leukolysin/MMP25/MT6-MMP
Searching the EST database for novel MMP-like genes have resulted in the identification of two latest additions to the MMP family: CA-MMP/MMP23 and MT5-MMP/MMP249,11, 20,23. Continuing this effective strategy, a putative MMP gene was identified (see materials and methods), which shares considerable homology to MT4-MMP, initially reported by Puente et al18 and recently completed by Kajita and colleagues22. As shown in Fig 1, this novel MMP possesses a MMP domain structure with 1) a cysteine-switch PRCXXPD in the prodomain, 2) a HEXGHXXXXXH zinc binding motif in the catalytic domain and 3) a hemopexin-like domain at the C-terminal portion. Interestingly, with a RXR/KR motif between its pro- and catalytic domains, this novel MMP apparently joins a subfamily of MMPs with a well-defined mechanism of zymogen activation mediated by members of the proprotein convertases such as furin in the trans-Golgi network12,14,24. At the C-terminus, a hydrophobic segment is present as a potential transmembrane domain (Fig 1b). Given its origin of isolation and tissue specific expression in leukocytes (See Fig 2), this novel gene is tentatively named leukolysin in analogy to stromelysins. Following the MMP serial designation, it isassigned MMP25 (personal communications, J.F. Woessner, Jr., University of Miami, FL). On the other hand, due to its close relationship to MT4-MMP and the other MT-MMPs, MT6-MMP is also proposed for this gene.
The relationship between leukolysin and other MMPs
To further analyze the relatedness between leukolysin and known MMPs, a multiple sequence alignment was constructed and represented in Fig 1c. Based on the alignment score, leukolysin shows the highest homology to MT4-MMP (45% identity overall), a putative MMP with unknown enzymic and biological function. In addition, leukolysin has the strongest homology to the rest of the MT-MMP subgroup among all MMPs identified so far. In fact, the catalytic domain of leukolysin, the most conserved part of the MMP family, displays 56% amino acid sequence identity to MT4-MMP, compared to 46-48% for MT1, 2, 3, 5-MMPs (Fig 1c). Interestingly, the C-termini are the most divergent and generally fall into two groups. The first group, including MT1, 2, 3, and 5-MMPs, has a traditional transmembrane domain of 24 residues followed by a cytosolic domain with a conserved Valine at their termini (Fig 2a). The second group, made of MT4-MMP and leukolysin, has no visible cytosolic domains after the hydrophobic domains (Fig 1c).
Tissue specific expression of leukolysin
To investigate the distribution of leukolysin, a panel of cDNAs prepared from 26 tissues and organs were screened for leukolysin expression by PCR. As shown in Fig 2, peripheral leukocytes are the main source of leukolysin. Bone marrow and fetal kidney also express minute amounts of leukolysin, probably reflecting residual blood leukocytes in those organs at the time of sample collections.
Expression of leukolysin as a soluble enzyme
As shown in Fig 1, leukolysin possesses a hydrophobic segment which could anchor the protein on cell surface, thus, making purification of the proteinase difficult. Indeed, full-length as well as the transmembrane truncated leukolysins are expressed as cell associated forms (Pei, unpublished data). To circumvent potential problem, a vector was constructed to express leukolysin1-280 tagged with FLAG epitope, without the pexin- and putative transmembrane domains (Fig 3a). Since leukolysin contains a furin site between its pro- and catalytic-domains, it is expected that leukolysin1-280 will be expressed in latent form in the ER, transported to the Golgi where it is processed into active forms as described for MMP11 and MMP1412,13,25. The expression vector, pCR3. 1MMP25cat, was transfected into MDCK cells and stable clones were isolated and screened by zymography. As shown in Fig 3b, a 28 kDa gelatinolytic species was detected in the conditioned media of several transfectants (lanes 3, 4 and 6). This finding is in sharp contrast to the negative results obtained when similar MT4-MMP was expressed under identical conditions (Trui and Pei, unpublished data). One of the clones with high yields, 17-13 (Fig 3b, lane 3), was chosen for further characterization.
Soluble leukolysin is secreted as a processed and fully active enzyme
With a RRRR motif, leukolysin is expected to be activated by furin or related PCs intracellularly prior to secretion. Thus, the conditioned media and cell lysates were analyzed by Western blot to establish the relationship between extracellular and intracellular leukolysins. As shown in Fig 3c, the conditioned media from 17-13 contains a major immuno-reactive species at ∼ 28 kDa and a minor one at ∼ 34 kDa (Fig 3c, lanes 3), potentially corresponding to the active and pro- forms of leukolysin. In contrast, more than 97% of intracellular leukolysin is in the 34 kDa form, compared to ∼ 3% for the 28 kDa active forms (Fig 3c, lane 5), thus validating a precusor/product relationship for the 34 and 28 kDa species. The loss of ∼ 6 kDa is presumably the result of prodomain processing at the RRRR signal by furin or its related PCs12.
Proleukolysin is localized in secretory granules throughout the cell
Since almost all intracellular leukolysin is in a latent state (Fig 3c), it must be residing in the trans-Golgi network waiting to be processed by furin or related proprotein convertases12,14. To track the localization of proleukolysin, a GFP fusion construct was engineered to fuse leukolysin1-280 to the green flurorescent protein (GFP) (Fig 4a). Stable cell lines expressing the GFP fusion protein were generated from MDCK cells as described19. More than 15 positive clones were obtained and a few representatives are shown by zymographyin Fig 4b. As expected, GFP adds 22 kDa to the secreted gelatinolytic speces as a 50 kDa enzyme (Fig 4b). Clone 15-11 (lane 4 of Fig 4b) was selected for further analysis. Western blotting of the supernatants and cell lysates from 15-11 cells demonstrated that the majority of intracellular leukolysin:: GFP is still in latent form as demonstrated for leukolysin1-280 in Fig 3c (data not shown). To visualize the GFP tagged proleukolysin, confocal microscopy was performed to demonstrate that leukolysin1-280::GFP is localized in secretory granules throughout the cell body, contrary to the concentrated localization in perinuclear ER and Golgi network for most secretory proteins. Thus, the signal peptide and the prodomain of leukolysin contain the necessary information sufficient to target leukolysin to secretory granules, perhaps relevant to the ones found in leukocytes4.
DISCUSSION
As a cell type critical to inflammatory response, leukocytes are very mobile, exiting the blood stream and entering the inflamed sites to destroy invading pathogens,infected host cells and damaged tissues4. Leukolysin fits quite naturally into the role of leukocytes as part of their proteolytic arsenals, perhaps complementing the roles of two MMPs previously found in leukocytes, neutrophils in particular: MMP8 and MMP926, 27. The localization of a C-terminally truncated proleukolysin into the secretory granules of MDCK cells seems to suggest that leukolysin may be stored as zymogens in the intracellular granules of leukocytes-a depot of many powerful, yet latent, proteinases4. Although characterized as a potent proteinase against denatured collagen (Fig 3b), leukolysin's role in ECM destruction is not known at present. With the availability of purified enzymes and the full-length cDNA clone, the full potential of leukolysin as an ECM degrading enzyme is under investigation thoroughly. Furthermore, a genomic clone has been isolated from mouse SVJ129 genomic library (Yi and Pei, unpublished data). Given its tissue specific nature of expression, leukolysin deficient mice generated by genetic ablation should display functional deficiency in leukocyte- or inflammation related physiological as well as pathological processes such as inflammatory responses.
With a RRRR motif, leukolysin is apparently a new member of a MMP subgroup that can be activated by furin-type proprotein convertases12,24. Although the precise mechanism for its activation remains to be investigated, proleukolysin (34 kDa) was shown to be processed intracellular into the 28 kDa active species (Fig 3c), presumably by furin or related PCs. MMP activation mediated by furin or related proprotein convertases was first proposed during the characterization of stromelysin-312. With the recent identification of leukolysin/MMP25, MT5-MMP/MMP24 and CA-MMP/MMP23, close to 40% of known MMPs (8 out of 20) possess a RXK/RR motif, ready to be cleaved and activated by furin or related PCs5,9,11, 20,23,24. Addition of leukolysin to this group further illustrates the importance of furin- or PC- mediated MMP activation in ECM remodeling processes.
By displaying the strongest homology to the MT-MMP subgroup, especially MT4-MMP (Fig 1c), leukolysin is also named MT6-MMP. Based on the alignment in Fig 1c, it seems plausible to divide the MT-MMPs into two branches: MT1, 2, 3, 5-MMPs and MT4, 6-MMPs. The defining function for the former group is their ability to activate progelatinase A15,16,20, whereas the later can not. Current efforts are underway to address the roles of signal peptide and prodomain in targeting proleukolysin to intracellular granules (Fig 4) and that of the C-terminal hydrophobic domain in cell membrane localization. Anchored on cell surface, active leukolysin could be in close contact with substrates and secluded from the anti-proteinase shield in the extracellular milieu, thus, may exert a unique force in destroying and remodeling extracellular matrix during leukocyte-mediated inflammatory responses.
Accession codes
References
Woessner JF Jr . Matrix metalloproteinases and their inhibitors in connective tissue remodeling. Faseb J 1991; 5:2145–54.
Hahn-Dantona E, N Ramos-DeSimone, J Sipley, H Nagase, DL French, JP Quigley . Activation of proMMP-9 by a plasmin/MMP-3 cascade in a tumor cell model. Regulation by tissue inhibitors of metalloproteinases. Ann N Y Acad Sci 1999; 878:372–87.
Woolley DE, ED Harris, Jr CL Mainardi, CE Brinckerhoff . Collagenase immunolocalization in cultures of rheumatoid synovial cells. Science 1978; 200:773–5.
Weiss SJ . Tissue destruction by neutrophils [see comments]. N Engl J Med 1989; 320:365–76.
Massova I, LP Kotra, R Fridman, S Mobashery . Matrix metalloproteinases: structures, evolution, and diversification. Faseb J 1998; 12:1075–95.
Stocker W, F Grams, U Baumann, P Reinemer, FX Gomis-Ruth, DB McKay, W Bode . The metzincins-topological and sequential relations between the astacins, adamalysins, serralysins, and matrixins (collagenases) define a superfamily of zinc-peptidases. Protein Sci 1995; 4:823–40.
Nagase H, JF Woessner, Jr . Matrix metalloproteinases. J Biol Chem 1999; 274:21491–4.
Van Wart HE, H Birkedal-Hansen . The cysteine switch: a principle of regulation of metalloproteinase activity with potential applicability to the entire matrix metalloproteinase gene family. Proc Natl Acad Sci USA 1999; 87:5578–82.
Pei D . CA-MMP: a matrix metalloproteinase with a novel cysteine array, but without the classic cysteine switch(1). FEBS Lett 1999; 457:262–70.
Muller D, B Quantin, MC Gesnel, R Millon-Collard, J Abecassis, R Breathnach . The collagenase gene family in humans consists of at least four members. Biochem J 1988; 253:187–92.
Velasco G, AM Pendas, A Fueyo, V Knauper, G Murphy, C Lopez-Otin . Cloning and characterization of human MMP-23, a new matrix metalloproteinase predominantly expressed in reproductive tissues and lacking conserved domains in other family members. J Biol Chem 1999; 274:4570–6.
Pei D, SJ Weiss . Furin-dependent intracellular activation of the human stromelysin-3 zymogen. Nature 1995; 375:244–7.
Santavicca M, A Noel, H Angliker, I Stoll, JP Segain, P Anglard, M Chretien, N Seidah, P Basset . Characterization of structural determinants and molecular mechanisms involved in pro- stromelysin-3 activation by 4-aminophenylmercuric acetate and furin-type convertases. Biochem J 1996; 315:953–8.
Steiner DF . The proprotein convertases. Curr Opin Chem Biol 1998; 2:31–9.
Sato H, T Takino, Y Okada, J Cao, A Shinagawa, E Yamamoto, M Seiki . A matrix metalloproteinase expressed on the surface of invasive tumour cells [see comments]. Nature 1994; 370:61–5.
Takino T, H Sato, A Shinagawa, M Seiki . Identification of the second membrane-type matrix metalloproteinase (MT-MMP-2) gene from a human placenta cDNA library. MT-MMPs form a unique membrane-type subclass in the MMP family. J Biol Chem 1995; 270:23013–20.
Will H, B Hinzmann . cDNA sequence and mRNA tissue distribution of a novel human matrix metalloproteinase with a potential transmembrane segment. Eur J Biochem 1995; 231:602–8.
Puente XS, AM Pendas, E Llano, G Velasco, C Lopez-Otin . Molecular cloning of a novel membrane-type matrix metalloproteinase from a human breast carcinoma. Cancer Res 1996; 56:944–9.
Pei D, J Yi . A high-level mammalian expression system based on the Madin-Darby canine kidney cell line. Protein Expr Purif 1998; 13:277–81.
Pei D . Identification and characterization of the fifth membrane-type matrix metalloproteinase MT5-MMP [In Process Citation]. J Biol Chem 1999; 274:8925–32.
Lennon G, C Auffray, M Polymeropoulos, MB Soares . The I.M.A.G.E. Consortium: an integrated molecular analysis of genomes and their expression. Genomics 1996; 33:151–2.
Kajita M, H Kinoh, N Ito, A Takamura, Y Itoh, A Okada, H Sato, M Seiki . Human membrane type-4 matrix metalloproteinase (MT4-MMP) is encoded by a novel major transcript: isolation of complementary DNA clones for human and mouse mt4-mmp transcripts. FEBS Lett 1999; 457:353–6.
Llano E, AM Pendas, JP Freije, A Nakano, V Knauper, G Murphy, C Lopez-Otin . Identification and characterization of human MT5-MMP, a new membrane-bound activator of progelatinase a overexpressed in brain tumors. Cancer Res 1999; 59:2570–6.
Nagase H . Activation mechanisms of matrix metalloproteinases. Biol Chem 1997; 378:151–60.
Pei D, SJ Weiss . Transmembrane-deletion mutants of the membrane-type matrix metalloproteinase-1 process progelatinase A and express intrinsic matrix-degrading activity. J Biol Chem 1996; 271:9135–40.
Hasty KA, TF Pourmotabbed, GI Goldberg, JP Thompson, DG Spinella, RM Stevens, CL Mainardi . Human neutrophil collagenase. A distinct gene product with homology to other matrix metalloproteinases. J Biol Chem 1990; 265:11421–4.
Hibbs MS, KA Hasty, JM Seyer, AH Kang, CL Mainardi . Biochemical and immunological characterization of the secreted forms of human neutrophil gelatinase. J Biol Chem 1985; 260:2493–500.
Acknowledgements
The author wishes to thank members of the Pei laboratory for a stimulating environment and skillful assistances; Drs. Hideaki Nagase, Fred Woessner and Stephen J. Weiss for thoughtful inputs and comments for this study. This study was supported in part by grant CA76308 from the National Cancer Institute, Elsa Pardee Foundation, University of Minnesota grant-in-aid, Minnesota Medical Foundation.
Author information
Authors and Affiliations
Additional information
The nucleotide sequence reported in this paper has been submitted to the Gen Bank TM/EMBL Data Bank with accession number AF185270
Rights and permissions
About this article
Cite this article
PEI, D. Leukolysin/MMP25/MT6-MMP: a novel matrix metalloproteinase specifically expressed in the leukocyte lineage. Cell Res 9, 291–303 (1999). https://doi.org/10.1038/sj.cr.7290028
Received:
Accepted:
Issue Date:
DOI: https://doi.org/10.1038/sj.cr.7290028
Keywords
This article is cited by
-
A brain-specific angiogenic mechanism enabled by tip cell specialization
Nature (2024)
-
The roles of intracellular proteolysis in cardiac ischemia–reperfusion injury
Basic Research in Cardiology (2023)
-
The roles of extracellular vesicles in the development, microenvironment, anticancer drug resistance, and therapy of head and neck squamous cell carcinoma
Journal of Experimental & Clinical Cancer Research (2021)
-
Antifungal activity of dendritic cell lysosomal proteins against Cryptococcus neoformans
Scientific Reports (2021)
-
Thyroid hormone-induced cell-cell interactions are required for the development of adult intestinal stem cells
Cell & Bioscience (2013)