Peroxidasin forms sulfilimine chemical bonds using hypohalous acids in tissue genesis

Bhave, Gautam; Cummings, Christopher F.; Vanacore, Roberto M.; Kumagai-Cresse, Chino; Ero-Tolliver, Isi A.; Rafi, Mohamed; Kang, Jeong-Suk; Pedchenko, Vadim; Fessler, Liselotte I.; Fessler, John H.; Hudson, Billy G.

doi:10.1038/nchembio.1038

Cited by 215 publications

(290 citation statements)

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“…The animal heme peroxidase PXDN has been shown to catalyze the formation of sulfilimine links in a reaction, where the enzyme produces hypohalous acids as intermediates for the oxidation of a highly conserved Met residue in the NC1 domain (11). Although peroxidase inhibitors were previously shown to inhibit collagen IV crosslinking in a murine embryonic carcinoma cell line (11), evidence for PXDN-mediated coupling of NC1 domains being a physiological pathway of ECM formation in mammals has been lacking so far.…”

Section: Discussionmentioning

confidence: 99%

“…Collagen IV was recently identified as a substrate of PXDN (11). In a reaction thought to be universal in the animal kingdom the enzyme crosslinks the NC1 domains of collagen IV protomers through the formation of sulfilimine linkages.…”

Section: Collagen IV Crosslinking Is Absent In Pxdn-deficient Mouse Ementioning

confidence: 99%

“…Recently Bhave et al identified PXDN as the long-sought player in collagen IV biosynthesis that catalyzes crosslinking of collagen IV trimers through their NC1 domains (11). Coupling of the NC1 domains occurs through sulfilimine bonds that were only recently recognized in living organisms (12).…”

Section: Introductionmentioning

confidence: 99%

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Structure–function analysis of peroxidasin provides insight into the mechanism of collagen IV crosslinking

Lázár

Péterfi

Sirokmány

et al. 2015

Free Radical Biology and Medicine

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Basement membranes provide structural support and convey regulatory signals to cells in diverse tissues. Assembly of collagen IV into a sheet-like network is a fundamental mechanism during the formation of basement membranes. Peroxidasin (PXDN) was recently described to catalyze crosslinking of collagen IV through the formation of sulfilimine bonds.Despite the significance of this pathway in tissue genesis, our understanding of PXDN function is far from complete. In this work we demonstrate that collagen IV crosslinking is a physiological function of mammalian PXDN. Moreover, we carried out structure-function analysis of PXDN to get a better insight into its role in collagen IV synthesis. We identify conserved cysteines in PXDN which mediate the oligomerization of the protein into a trimeric complex. We also demonstrate that oligomerization is not an absolute requirement for enzymatic activity but optimal collagen IV coupling is only catalyzed by the PXDN trimers.Localization experiments of different PXDN mutants in two different cell models revealed that PXDN oligomers, but not monomers, adhere on cell-surface in "hot spots", which represent previously unknown locations of collagen IV crosslinking.

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Section: Discussionmentioning

confidence: 99%

Section: Collagen IV Crosslinking Is Absent In Pxdn-deficient Mouse Ementioning

confidence: 99%

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Structure–function analysis of peroxidasin provides insight into the mechanism of collagen IV crosslinking

Lázár

Péterfi

Sirokmány

et al. 2015

Free Radical Biology and Medicine

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“…Sulfilimine (SAN) bonds between opposing methionine and lysine residues bridge the trimer-timer interface of the NC1 hexamer and thereby structurally reinforce the collagen IV network (3). The enzyme peroxidasin (Pxdn), a basement membrane-associated heme peroxidase, catalyzes the formation of sulfilimine crosslinks, a process critical for BM and tissue integrity (4). For example, peroxidasin loss of function in Drosophila and Caenorhabditis elegans compromises gut architecture and leads to early lethality (4,5).…”

mentioning

confidence: 99%

“…The enzyme peroxidasin (Pxdn), a basement membrane-associated heme peroxidase, catalyzes the formation of sulfilimine crosslinks, a process critical for BM and tissue integrity (4). For example, peroxidasin loss of function in Drosophila and Caenorhabditis elegans compromises gut architecture and leads to early lethality (4,5). In addition to structural reinforcement, the sulfilimine cross-link also confers immune privilege to the collagen IV auto-antigen in human Goodpasture's disease, a devastating condition presenting as rapidly progressive glomerulonephritis with or without pulmonary hemorrhage.…”

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confidence: 99%

Proprotein Convertase Processing Enhances Peroxidasin Activity to Reinforce Collagen IV

Colon

Bhave

2016

Journal of Biological Chemistry

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Edited by Amanda FosangThe basement membrane (BM) is a form of extracellular matrix that underlies cell layers in nearly all animal tissues. Type IV collagen, a major constituent of BMs, is critical for tissue development and architecture. The enzyme peroxidasin (Pxdn), an extracellular matrix-associated protein, catalyzes the formation of structurally reinforcing sulfilimine cross-links within the collagen IV network, an event essential to basement membrane integrity. Although the catalytic function of Pxdn is known, the regulation of its activity remains unclear. In this work we show through N-terminal sequencing, pharmacologic studies, and mutational analysis that proprotein convertases (PCs) proteolytically process human Pxdn at Arg-1336, a location relatively close to its C terminus. PC processing enhances the enzymatic activity of Pxdn and facilitates the formation of sulfilimine cross-links in collagen IV. Thus, PC processing of Pxdn is a key regulatory step that contributes to its function and, therefore, supports BM integrity and homeostasis.

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A Biomimetic In Vitro Model of the Kidney Filtration Barrier Using Tissue‐Derived Glomerular Basement Membrane

Wang

Sant

Ferrell

2021

Adv Healthcare Materials

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The glomerular filtration barrier (GFB) filters the blood to remove toxins while retaining high molecular weight proteins in the circulation. The glomerular basement membrane (GBM) and podocytes, highly specialized epithelial cells, are critical components of the filtration barrier. The GBM serves as a physical barrier to passage of molecules into the filtrate. Podocytes adhere to the filtrate side of the GBM and further restrict passage of high molecular weight molecules into the filtrate. Here, a 3D cell culture model of the glomerular filtration barrier to evaluate the role of the GBM and podocytes in mediating molecular diffusion is developed. GBM is isolated from mammalian kidneys to recapitulate the composition and mechanics of the in vivo basement membrane. The GFB model exhibits molecular selectivity that is comparable to the in vivo filtration barrier. The GBM alone provides a stringent barrier to passage of albumin and Ficoll. Podocytes further restrict molecular diffusion. Damage to the GBM that is typical of diabetic kidney disease is simulated using hypochlorous acid and results in increased molecular diffusion. This system can serve as a platform to evaluate the effects of GBM damage, podocyte injury, and reciprocal effects of altered podocyte–GBM interactions on kidney microvascular permeability.

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Peroxidasin forms sulfilimine chemical bonds using hypohalous acids in tissue genesis

Cited by 215 publications

References 48 publications

Structure–function analysis of peroxidasin provides insight into the mechanism of collagen IV crosslinking

Structure–function analysis of peroxidasin provides insight into the mechanism of collagen IV crosslinking

Proprotein Convertase Processing Enhances Peroxidasin Activity to Reinforce Collagen IV

A Biomimetic In Vitro Model of the Kidney Filtration Barrier Using Tissue‐Derived Glomerular Basement Membrane

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