8cwl
From Proteopedia
Cryo-EM structure of Human 15-PGDH in complex with small molecule SW222746
Structural highlights
DiseasePGDH_HUMAN Defects in HPGD are the cause of hypertrophic osteoarthropathy, primary, autosomal recessive, type 1 (PHOAR1) [MIM:259100. A disease characterized by digital clubbing, periostosis, acroosteolysis, painful joint enlargement, and variable features of pachydermia that include thickened facial skin and a thickened scalp. Other developmental anomalies include delayed closure of the cranial sutures and congenital heart disease.[1] Defects in HPGD are the cause of cranioosteoarthropathy (COA) [MIM:259100. A form of osterarthropathy characterized by swelling of the joints, digital clubbing, hyperhidrosis, delayed closure of the fontanels, periostosis, and variable patent ductus arteriosus. Pachydermia is not a prominent feature.[2] Defects in HPGD are a cause of isolated congenital nail clubbing (ICNC) [MIM:119900; also called clubbing of digits or hereditary acropachy. ICNC is a rare genodermatosis characterized by enlargement of the nail plate and terminal segments of the fingers and toes, resulting from proliferation of the connective tissues between the nail matrix and the distal phalanx. It is usually symmetrical and bilateral (in some cases unilateral). In nail clubbing usually the distal end of the nail matrix is relatively high compared to the proximal end, while the nail plate is complete but its dimensions and diameter more or less vary in comparison to normal. There may be different fingers and toes involved to varying degrees. Some fingers or toes are spared, but the thumbs are almost always involved.[3] FunctionPGDH_HUMAN Prostaglandin inactivation. Contributes to the regulation of events that are under the control of prostaglandin levels. Catalyzes the NAD-dependent dehydrogenation of lipoxin A4 to form 15-oxo-lipoxin A4. Inhibits in vivo proliferation of colon cancer cells.[4] [5] [6] Publication Abstract from PubMed15-prostaglandin dehydrogenase (15-PGDH) is a negative regulator of tissue stem cells that acts via enzymatic activity of oxidizing and degrading PGE2, and related eicosanoids, that support stem cells during tissue repair. Indeed, inhibiting 15-PGDH markedly accelerates tissue repair in multiple organs. Here we have used cryo-electron microscopy to solve the solution structure of native 15-PGDH and of 15-PGDH individually complexed with two distinct chemical inhibitors. These structures identify key 15-PGDH residues that mediate binding to both classes of inhibitors. Moreover, we identify a dynamic 15-PGDH lid domain that closes around the inhibitors, and that is likely fundamental to the physiologic 15-PGDH enzymatic mechanism. We furthermore identify two key residues, F185 and Y217, that act as hinges to regulate lid closing, and which both inhibitors exploit to capture the lid in the closed conformation, thus explaining their sub-nanomolar binding affinities. These findings provide the basis for further development of 15-PGDH targeted drugs as therapeutics for regenerative medicine. Small molecule inhibitors of 15-PGDH exploit a physiologic induced-fit closing system.,Huang W, Li H, Kiselar J, Fink SP, Regmi S, Day A, Yuan Y, Chance M, Ready JM, Markowitz SD, Taylor DJ Nat Commun. 2023 Feb 11;14(1):784. doi: 10.1038/s41467-023-36463-7. PMID:36774348[7] From MEDLINE®/PubMed®, a database of the U.S. National Library of Medicine. References
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