Optimization of a Dibenzodiazepine Hit to a Potent and Selective Allosteric PAK1 Inhibitor

Karpov, Alexei S.; Amiri, Payman; Bellamacina, Cornelia; Bellance, Marie-Helene; Breitenstein, Werner; Daniel, Dylan; Denay, Régis; Fabbro, Doriano; Fernández, César Fernández; Galuba, Inga; Guerro-Lagasse, Stephanie; Gutmann, Sascha; Hinh, Linda; Jahnke, Wolfgang; Klopp, Julia; Lai, Albert; Lindvall, Mika K.; Ma, Sylvia; Möbitz, Henrik; Pecchi, Sabina; Rummel, Gabriele; Shoemaker, Kevin R.; Trappe, Joerg; Voliva, Charles F.; Cowan‐Jacob, Sandra W.; Marzinzik, Andreas L.

doi:10.1021/acsmedchemlett.5b00102

Cited by 84 publications

(94 citation statements)

References 27 publications

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“…For one of these, PAK1 (PDB: 3Q4Z), Wang et al . described the autophosphorylation complex, a head-to-head asymmetric complex of PAK1 in the crystal asymmetric unit (11), whereas the others were not shown or discussed in the relevant publications (25-28). Wang et al .…”

Section: Resultsmentioning

confidence: 99%

“…The newly identified autophosphorylation events include: (i) the activation loop Tyr of human nonreceptor tyrosine kinase LCK [PDB: 2PL0 (20)], which is similar to the IGF1R structure (10); (ii) a second tyrosine autophosphorylation site (Tyr 1166 ) in the activation loop of human IGF1R [PDB: 3LVP (21)]; (iii) a Tyr in the N-terminal juxtamembrane region of human colony stimulating factor 1 receptor (CSF1R) [PDB: 3LCD (22)] that is homologous to the tyrosine observed in the c-KIT complex (7); (iv) a Tyr in the N-terminal juxtamembrane region of Ephrin receptor A2 (EPHA2) [PDB: 4PDO (23)] that represents a phosphorylation site near but distinct from that in the c-KIT and CSF1R complexes; and (v) a Ser in the C-terminal tail of human CDC2/CDC28-like kinase 2 (CLK2) [PDB: 3NR9 (24)]. We also identified several additional structures of autophosphorylation complexes of PAK1: PDB: 4O0R, 4O0T (25); 4P90 (26); 4ZY4, 4ZY5, 4ZY6 (27); and 4ZLO, 4ZJI, and 4ZJJ (28). Two of these structures, PDB: 4ZY4 and 4ZY5, contain an autophosphorylation complex with a fully ordered activation loop in the substrate kinase; whereas the others, including PDB: 3Q4Z (11), are missing the coordinates of 8-11 residues within the activation loop.…”

Section: Introductionmentioning

confidence: 99%

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Identifying three-dimensional structures of autophosphorylation complexes in crystals of protein kinases

Malecka

Fink

et al. 2015

Sci. Signal.

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Protein kinase autophosphorylation is a common regulatory mechanism in cell signaling pathways. Crystal structures of several homomeric protein kinase complexes have a serine, threonine, or tyrosine autophosphorylation site of one kinase monomer located in the active site of another monomer, a structural complex that we call an “autophosphorylation complex.” We developed and applied a structural bioinformatics method to identify all such autophosphorylation kinase complexes in X-ray crystallographic structures in the Protein Data Bank (PDB). We identified 15 autophosphorylation complexes in the PDB, of which 5 complexes had not previously been described in the publications describing the crystal structures. These 5 consist of tyrosine residues in the N-terminal juxtamembrane regions of colony stimulating factor 1 receptor (CSF1R, Tyr561) and EPH receptor A2 (EPHA2, Tyr594), tyrosine residues in the activation loops of the SRC kinase family member LCK (Tyr394) and insulin-like growth factor 1 receptor (IGF1R, Tyr1166), and a serine in a nuclear localization signal region of CDC-like kinase 2 (CLK2, Ser142). Mutations in the complex interface may alter autophosphorylation activity and contribute to disease; therefore we mutated residues in the autophosphorylation complex interface of LCK and found that two mutations impaired autophosphorylation (T445V and N446A) and mutation of Pro447 to Ala, Gly, or Leu increased autophosphorylation. The identified autophosphorylation sites are conserved in many kinases, suggesting that, by homology, these complexes may provide insight into autophosphorylation complex interfaces of kinases that are relevant drug targets.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Identifying three-dimensional structures of autophosphorylation complexes in crystals of protein kinases

Malecka

Fink

et al. 2015

Sci. Signal.

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“…One possible impeding factor which is difficult to achieve is the selectivity within the PAK family, because of sequence homology among the family members. Although some Pak1 selective inhibitors like IPA-3 [9,[16][17][18][19], FRAX-597 [11,20], G-5555 [12], and Novartis compound 3 [13] have been disclosed, the successful in vivo dose optimization for target specificity and stability is yet to be tested on larger group of animals. …”

Section: Expert Opinionmentioning

confidence: 99%

“…As the earlier pharmacologic inhibitors of Pak1 are not very specific, new Pak1 selective inhibitors such as FRAX-597, G-5555, Novartis compound 3 etc. are been synthesized and are under evaluation for clinical efficacy [11][12][13]. In addition, as suggested by Baker et al [14], it would be worthwhile to identify a reliable Pak1 substrate-specific biomarker for Pak1 inhibitor antitumor activity.…”

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confidence: 99%

Targeting p21 activated kinase 1 (Pak1) to PAKup Pancreatic Cancer

Jagadeeshan

Venkatraman

Rayala

2016

Expert Opinion on Therapeutic Targets

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“…These allosteric ligands were further optimized into potent and highly selective Pak1 inhibitors, which could be used as tool compounds to investigate the role of Pak1 in tumor maintenance. [20] …”

Section: Discovery Of Allosteric Pak1 Inhibitorsmentioning

confidence: 99%

Contributions of Biomolecular NMR to Allosteric Drug Discovery

Skora

Jahnke²

2015

Chimia

Self Cite

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Drug discovery is a complex process, and a variety of technologies contribute to its success. Biophysical methods have gained widespread attention within the last decade, and in particular NMR spectroscopy as the most versatile biophysical method has seen numerous applications and significant impact to drug discovery. Here we summarize the potential of NMR to support drug discovery, and highlight a number of recent applications.

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Optimization of a Dibenzodiazepine Hit to a Potent and Selective Allosteric PAK1 Inhibitor

Cited by 84 publications

References 27 publications

Identifying three-dimensional structures of autophosphorylation complexes in crystals of protein kinases

Identifying three-dimensional structures of autophosphorylation complexes in crystals of protein kinases

Targeting p21 activated kinase 1 (Pak1) to PAKup Pancreatic Cancer

Contributions of Biomolecular NMR to Allosteric Drug Discovery

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