Your search keyword '"Douglas R. Walker"' showing total 2 results

1. Linker Length Drives Heterogeneity of Multivalent Complexes of Hub Protein LC8 and Transcription Factor ASCIZ

Author

Douglas R. Walker, Kayla A. Jara, Amber D. Rolland, Coban Brooks, Wendy Hare, Andrew K. Swansiger, Patrick N. Reardon, James S. Prell, and Elisar J. Barbar

Subjects

hub proteins, intrinsic disorder, multivalency, transcription factor, linker length, heterogeneity, Microbiology, QR1-502

Abstract

LC8, a ubiquitous and highly conserved hub protein, binds over 100 proteins involved in numerous cellular functions, including cell death, signaling, tumor suppression, and viral infection. LC8 binds intrinsically disordered proteins (IDPs), and although several of these contain multiple LC8 binding motifs, the effects of multivalency on complex formation are unclear. Drosophila ASCIZ has seven motifs that vary in sequence and inter-motif linker lengths, especially within subdomain QT2–4 containing the second, third, and fourth LC8 motifs. Using isothermal-titration calorimetry, analytical-ultracentrifugation, and native mass-spectrometry of QT2–4 variants, with methodically deactivated motifs, we show that inter-motif spacing and specific motif sequences combine to control binding affinity and compositional heterogeneity of multivalent duplexes. A short linker separating strong and weak motifs results in stable duplexes but forms off-register structures at high LC8 concentrations. Contrastingly, long linkers engender lower cooperativity and heterogeneous complexation at low LC8 concentrations. Accordingly, two-mers, rather than the expected three-mers, dominate negative-stain electron-microscopy images of QT2–4. Comparing variants containing weak-strong and strong-strong motif combinations demonstrates sequence also regulates IDP/LC8 assembly. The observed trends persist for trivalent ASCIZ subdomains: QT2–4, with long and short linkers, forms heterogeneous complexes, whereas QT4–6, with similar mid-length linkers, forms homogeneous complexes. Implications of linker length variations for function are discussed.

Published

2023

2. Chain Alignment of Collagen I Deciphered using Computationally Designed Heterotrimers

Author

Katherine Stott, Samir W. Hamaia, Birgit Leitinger, Douglas R. Walker, Jeffrey D. Hartgerink, Douglas Sammon, Paul Brear, Richard W. Farndale, Abhishek A. Jalan, and Emma Hunter

Subjects

STRUCTURAL BASIS, Models, Molecular, Biochemistry & Molecular Biology, Protein family, VON-WILLEBRAND-FACTOR, Protein Conformation, DISCOIDIN DOMAIN RECEPTORS, 0601 Biochemistry and Cell Biology, Article, Collagen Type I, 03 medical and health sciences, Protein structure, Recognition sequence, A3 DOMAIN, Heterotrimeric G protein, DDR2, Humans, Amino Acid Sequence, Amino Acids, Molecular Biology, Peptide sequence, 030304 developmental biology, 0303 health sciences, Science & Technology, TYROSINE KINASES, IDENTIFICATION, 0304 Medicinal and Biomolecular Chemistry, Chemistry, 030302 biochemistry & molecular biology, RECOGNITION, Computational Biology, Cell Biology, Cell biology, AFFINITY BINDING, Collagen, Peptides, Life Sciences & Biomedicine, Discoidin domain, Type I collagen, Triple helix

Abstract

The most abundant member of the collagen protein family, collagen I (also known as type I collagen; COL1), is composed of one unique (chain B) and two similar (chain A) polypeptides that self-assemble with one amino acid offset into a heterotrimeric triple helix. Given the offset, chain B can occupy either the leading (BAA), middle (ABA) or trailing (AAB) position of the triple helix, yielding three isomeric biomacromolecules with different protein recognition properties. Despite five decades of intensive research, there is no consensus on the position of chain B in COL1. Here, three triple-helical heterotrimers that each contain a putative von Willebrand factor (VWF) and discoidin domain receptor (DDR) recognition sequence from COL1 were designed with chain B permutated in all three positions. AAB demonstrated a strong preference for both VWF and DDR, and also induced higher levels of cellular DDR phosphorylation. Thus, we resolve this long-standing mystery and show that COL1 adopts an AAB register.

Published

2020