Literature DB >> 25801024

Structure guided design of potent and selective ponatinib-based hybrid inhibitors for RIPK1.

Malek Najjar, Chalada Suebsuwong, Soumya S Ray, Roshan J Thapa, Jenny L Maki, Shoko Nogusa, Saumil Shah, Danish Saleh, Peter J Gough, John Bertin, Junying Yuan, Siddharth Balachandran, Gregory D Cuny, Alexei Degterev.   

Abstract

RIPK1 and RIPK3, two closely related RIPK family members, have emerged as important regulators of pathologic cell death and inflammation. In the current work, we report that the Bcr-Abl inhibitor and anti-leukemia agent ponatinib is also a first-in-class dual inhibitor of RIPK1 and RIPK3. Ponatinib potently inhibited multiple paradigms of RIPK1- and RIPK3-dependent cell death and inflammatory tumor necrosis factor alpha (TNF-α) gene transcription. We further describe design strategies that utilize the ponatinib scaffold to develop two classes of inhibitors (CS and PN series), each with greatly improved selectivity for RIPK1. In particular, we detail the development of PN10, a highly potent and selective "hybrid" RIPK1 inhibitor, capturing the best properties of two different allosteric RIPK1 inhibitors, ponatinib and necrostatin-1. Finally, we show that RIPK1 inhibitors from both classes are powerful blockers of TNF-induced injury in vivo. Altogether, these findings outline promising candidate molecules and design approaches for targeting RIPK1- and RIPK3-driven inflammatory pathologies.

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Year:  2015        PMID: 25801024      PMCID: PMC4494889          DOI: 10.1016/j.celrep.2015.02.052

Source DB:  PubMed          Journal:  Cell Rep            Impact factor:   9.423


  40 in total

1.  Glide: a new approach for rapid, accurate docking and scoring. 1. Method and assessment of docking accuracy.

Authors:  Richard A Friesner; Jay L Banks; Robert B Murphy; Thomas A Halgren; Jasna J Klicic; Daniel T Mainz; Matthew P Repasky; Eric H Knoll; Mee Shelley; Jason K Perry; David E Shaw; Perry Francis; Peter S Shenkin
Journal:  J Med Chem       Date:  2004-03-25       Impact factor: 7.446

2.  Structure-activity relationship study of tricyclic necroptosis inhibitors.

Authors:  Prakash G Jagtap; Alexei Degterev; Sungwoon Choi; Heather Keys; Junying Yuan; Gregory D Cuny
Journal:  J Med Chem       Date:  2007-03-16       Impact factor: 7.446

3.  Discovery of Small Molecule RIP1 Kinase Inhibitors for the Treatment of Pathologies Associated with Necroptosis.

Authors:  Philip A Harris; Deepak Bandyopadhyay; Scott B Berger; Nino Campobasso; Carol A Capriotti; Julie A Cox; Lauren Dare; Joshua N Finger; Sandra J Hoffman; Kirsten M Kahler; Ruth Lehr; John D Lich; Rakesh Nagilla; Robert T Nolte; Michael T Ouellette; Christina S Pao; Michelle C Schaeffer; Angela Smallwood; Helen H Sun; Barbara A Swift; Rachel D Totoritis; Paris Ward; Robert W Marquis; John Bertin; Peter J Gough
Journal:  ACS Med Chem Lett       Date:  2013-11-04       Impact factor: 4.345

4.  RIPK1 maintains epithelial homeostasis by inhibiting apoptosis and necroptosis.

Authors:  Marius Dannappel; Katerina Vlantis; Snehlata Kumari; Apostolos Polykratis; Chun Kim; Laurens Wachsmuth; Christina Eftychi; Juan Lin; Teresa Corona; Nicole Hermance; Matija Zelic; Petra Kirsch; Marijana Basic; Andre Bleich; Michelle Kelliher; Manolis Pasparakis
Journal:  Nature       Date:  2014-08-17       Impact factor: 49.962

5.  RIPK1 blocks early postnatal lethality mediated by caspase-8 and RIPK3.

Authors:  Christopher P Dillon; Ricardo Weinlich; Diego A Rodriguez; James G Cripps; Giovanni Quarato; Prajwal Gurung; Katherine C Verbist; Taylor L Brewer; Fabien Llambi; Yi-Nan Gong; Laura J Janke; Michelle A Kelliher; Thirumala-Devi Kanneganti; Douglas R Green
Journal:  Cell       Date:  2014-05-08       Impact factor: 41.582

6.  Structure-activity relationship study of [1,2,3]thiadiazole necroptosis inhibitors.

Authors:  Xin Teng; Heather Keys; Arumugasamy Jeevanandam; John A Porco; Alexei Degterev; Junying Yuan; Gregory D Cuny
Journal:  Bioorg Med Chem Lett       Date:  2007-10-17       Impact factor: 2.823

7.  RIP1 suppresses innate immune necrotic as well as apoptotic cell death during mammalian parturition.

Authors:  William J Kaiser; Lisa P Daley-Bauer; Roshan J Thapa; Pratyusha Mandal; Scott B Berger; Chunzi Huang; Aarthi Sundararajan; Hongyan Guo; Linda Roback; Samuel H Speck; John Bertin; Peter J Gough; Siddharth Balachandran; Edward S Mocarski
Journal:  Proc Natl Acad Sci U S A       Date:  2014-05-12       Impact factor: 11.205

8.  Phosphorylation-driven assembly of the RIP1-RIP3 complex regulates programmed necrosis and virus-induced inflammation.

Authors:  Young Sik Cho; Sreerupa Challa; David Moquin; Ryan Genga; Tathagat Dutta Ray; Melissa Guildford; Francis Ka-Ming Chan
Journal:  Cell       Date:  2009-06-12       Impact factor: 41.582

9.  Necrostatin-1 analogues: critical issues on the specificity, activity and in vivo use in experimental disease models.

Authors:  N Takahashi; L Duprez; S Grootjans; A Cauwels; W Nerinckx; J B DuHadaway; V Goossens; R Roelandt; F Van Hauwermeiren; C Libert; W Declercq; N Callewaert; G C Prendergast; A Degterev; J Yuan; P Vandenabeele
Journal:  Cell Death Dis       Date:  2012-11-29       Impact factor: 8.469

10.  Akt Regulates TNFα synthesis downstream of RIP1 kinase activation during necroptosis.

Authors:  Colleen R McNamara; Ruchita Ahuja; Awo D Osafo-Addo; Douglas Barrows; Arminja Kettenbach; Igor Skidan; Xin Teng; Gregory D Cuny; Scott Gerber; Alexei Degterev
Journal:  PLoS One       Date:  2013-03-01       Impact factor: 3.240
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  54 in total

Review 1.  Necroinflammation in Kidney Disease.

Authors:  Shrikant R Mulay; Andreas Linkermann; Hans-Joachim Anders
Journal:  J Am Soc Nephrol       Date:  2015-09-02       Impact factor: 10.121

Review 2.  Necroptosis and RIPK1-mediated neuroinflammation in CNS diseases.

Authors:  Junying Yuan; Palak Amin; Dimitry Ofengeim
Journal:  Nat Rev Neurosci       Date:  2019-01       Impact factor: 34.870

Review 3.  The Inflammatory Signal Adaptor RIPK3: Functions Beyond Necroptosis.

Authors:  K Moriwaki; F K-M Chan
Journal:  Int Rev Cell Mol Biol       Date:  2016-09-22       Impact factor: 6.813

Review 4.  Small molecule probes for cellular death machines.

Authors:  Ying Li; Lihui Qian; Junying Yuan
Journal:  Curr Opin Chem Biol       Date:  2017-06-16       Impact factor: 8.822

Review 5.  Necroptosis in cardiovascular disease - a new therapeutic target.

Authors:  Kartik Gupta; Noel Phan; Qiwei Wang; Bo Liu
Journal:  J Mol Cell Cardiol       Date:  2018-03-07       Impact factor: 5.000

6.  Receptor-interacting Ser/Thr kinase 1 (RIPK1) and myosin IIA-dependent ceramidosomes form membrane pores that mediate blebbing and necroptosis.

Authors:  Rose Nganga; Natalia Oleinik; Jisun Kim; Shanmugam Panneer Selvam; Ryan De Palma; Kristen A Johnson; Rasesh Y Parikh; Vamsi Gangaraju; Yuri Peterson; Mohammed Dany; Robert V Stahelin; Christina Voelkel-Johnson; Zdzislaw M Szulc; Erhard Bieberich; Besim Ogretmen
Journal:  J Biol Chem       Date:  2018-11-12       Impact factor: 5.157

7.  CK1α, CK1δ, and CK1ε are necrosome components which phosphorylate serine 227 of human RIPK3 to activate necroptosis.

Authors:  Sarah Hanna-Addams; Shuzhen Liu; Hua Liu; She Chen; Zhigao Wang
Journal:  Proc Natl Acad Sci U S A       Date:  2020-01-13       Impact factor: 11.205

8.  The bromodomain protein BRD4 positively regulates necroptosis via modulating MLKL expression.

Authors:  Yu Xiong; Linli Li; Liting Zhang; Yangyang Cui; Chengyong Wu; Hui Li; Kai Chen; Qiuyuan Yang; Rong Xiang; Yiguo Hu; Shile Huang; Yuquan Wei; Shengyong Yang
Journal:  Cell Death Differ       Date:  2019-01-15       Impact factor: 15.828

Review 9.  Biomarkers for the detection of necroptosis.

Authors:  Sudan He; Song Huang; Zhirong Shen
Journal:  Cell Mol Life Sci       Date:  2016-04-11       Impact factor: 9.261

Review 10.  Regulated necrosis: disease relevance and therapeutic opportunities.

Authors:  Marcus Conrad; José Pedro Friedmann Angeli; Peter Vandenabeele; Brent R Stockwell
Journal:  Nat Rev Drug Discov       Date:  2016-01-18       Impact factor: 84.694
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