Your search keyword '"Caradoc-Davies, Tom T."' showing total 2 results

1. Structural basis of autoregulatory scaffolding by apoptosis signal-regulating kinase 1.

Author

Weijman, Johannes F., Kumar, Abhishek, Jamieson, Sam A., King, Chontelle M., Caradoc-Davies, Tom T., Ledgerwood, Elizabeth C., Murphy, James M., and Mace, Peter D.

Subjects

APOPTOSIS, REACTIVE oxygen species, CYTOKINES, HOMOLOGY (Biology), BIOLOGICAL evolution

Abstract

Apoptosis signal-regulating kinases (ASK1-3) are apical kinases of the p38 and JNK MAP kinase pathways. They are activated by diverse stress stimuli, including reactive oxygen species, cytokines, and osmotic stress; however, a molecular understanding of how ASK proteins are controlled remains obscure. Here, we report a biochemical analysis of the ASK1 kinase domain in conjunction with its N-terminal thioredoxin-binding domain, along with a central regulatory region that links the two. We show that in solution the central regulatory region mediates a compact arrangement of the kinase and thioredoxin-binding domains and the central regulatory region actively primes MKK6, a key ASK1 substrate, for phosphorylation. The crystal structure of the central regulatory region reveals an unusually compact tetratricopeptide repeat (TPR) region capped by a cryptic pleckstrin homology domain. Biochemical assays show that both a conserved surface on the pleckstrin homology domain and an intact TPR region are required for ASK1 activity.We propose a model in which the central regulatory region promotes ASK1 activity via its pleckstrin homology domain but also facilitates ASK1 autoinhibition by bringing the thioredoxin-binding and kinase domains into close proximity. Such an architecture provides a mechanism for control of ASK-type kinases by diverse activators and inhibitors and demonstrates an unexpected level of autoregulatory scaffolding in mammalian stress-activated MAP kinase signaling. [ABSTRACT FROM AUTHOR]

Published

2017

2. The structure of the caspase recruitment domain of BinCARD reveals that all three cysteines can be oxidized.

Author

Chen, Kai-En, Richards, Ayanthi A., Caradoc-Davies, Tom T., Vajjhala, Parimala R., Robin, Gautier, Lua, Linda H. L., Hill, Justine M., Schroder, Kate, Sweet, Matthew J., Kellie, Stuart, Kobe, Bostjan, and Martin, Jennifer

Subjects

CRYSTAL structure, CASPASES, CYSTEINE, INFLAMMATION, APOPTOSIS, SELENOMETHIONINE, MITOCHONDRIA

Abstract

The caspase recruitment domain (CARD) is present in death-domain superfamily proteins involved in inflammation and apoptosis. BinCARD is named for its ability to interact with Bcl10 and inhibit downstream signalling. Human BinCARD is expressed as two isoforms that encode the same N-terminal CARD region but which differ considerably in their C-termini. Both isoforms are expressed in immune cells, although BinCARD-2 is much more highly expressed. Crystals of the CARD fold common to both had low symmetry (space group P1). Molecular replacement was unsuccessful in this low-symmetry space group and, as the construct contains no methionines, first one and then two residues were engineered to methionine for MAD phasing. The double-methionine variant was produced as a selenomethionine derivative, which was crystallized and the structure was solved using data measured at two wavelengths. The crystal structures of the native and selenomethionine double mutant were refined to high resolution (1.58 and 1.40 Å resolution, respectively), revealing the presence of a cis-peptide bond between Tyr39 and Pro40. Unexpectedly, the native crystal structure revealed that all three cysteines were oxidized. The mitochondrial localization of BinCARD-2 and the susceptibility of its CARD region to redox modification points to the intriguing possibility of a redox-regulatory role. [ABSTRACT FROM AUTHOR]

Published

2013