J.F. Amacher scite author profile

It has been suggested that the alkaline form of cytochrome c (cyt c) regulates function of this protein as an electron carrier in oxidative phosphorylation and as a peroxidase that reacts with cardiolipin (CL) during apoptosis. In this form, Met80, the native ligand to the heme iron, is replaced by a Lys. While it has become clear that the structure of cyt c changes, the extent and sequence of conformational rearrangements associated with this ligand replacement remain a subject of debate. Herein we report a high-resolution crystal structure of a Lys73-ligated cyt c conformation that reveals intricate change in the heme environment upon this switch in the heme iron ligation. The structure is surprisingly compact, and the heme coordination loop refolds into a β-hairpin with a turn formed by the highly conserved residues Pro76 and Gly77. Repositioning of residue 78 modifies the intraprotein hydrogen-bonding network and, together with adjustments of residues 52 and 74, increases the volume of the heme pocket to allow for insertion of one of the CL acyl moieties next to Asn52. Derivatization of Cys78 with maleimide creates a solution mimic of the Lys-ligated cyt c that has enhanced peroxidase activity, adding support for a role of the Lys-ligated cyt c in the apoptotic mechanism. Experiments with the heme peptide microperoxidase-8 and engineered model proteins provide a thermodynamic rationale for the switch to Lys ligation upon perturbations in the protein scaffold.

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Specificity in PDZ-peptide interaction networks: Computational analysis and review

Amacher

Brooks

Hampton

et al. 2020

Journal of Structural Biology: X

118

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Globular PDZ domains typically serve as protein-protein interaction modules that regulate a wide variety of cellular functions via recognition of short linear motifs (SLiMs). Often, PDZ mediated-interactions are essential components of macromolecular complexes, and disruption affects the entire scaffold. Due to their roles as linchpins in trafficking and signaling pathways, PDZ domains are attractive targets: both for controlling viral pathogens, which bind PDZ domains and hijack cellular machinery, as well as for developing therapies to combat human disease. However, successful therapeutic interventions that avoid off-target effects are a challenge, because each PDZ domain interacts with a number of cellular targets, and specific binding preferences can be difficult to decipher. Over twenty-five years of research has produced a wealth of data on the stereochemical preferences of individual PDZ proteins and their binding partners. Currently the field lacks a central repository for this information.Here, we provide this important resource and provide a manually curated, comprehensive list of the 271 human PDZ domains. We use individual domain, as well as recent genomic and proteomic, data in order to gain a holistic view of PDZ domains and interaction networks, arguing this knowledge is critical to optimize targeting selectivity and to benefit human health.Amacher et. al.

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Stereochemical Determinants of C-terminal Specificity in PDZ Peptide-binding Domains

Amacher

Cushing

Bahl

et al. 2013

Journal of Biological Chemistry

101

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Background: PDZ-peptide binding specificities establish a complex network of protein-protein interactions in the cell. Results: Crystal structures of multiple PDZ-peptide complexes reveal distinct mechanisms for accommodating C-terminal ligand side chains. Conclusion: A residue in the PDZ "X⌽ 1 G⌽ 2 " signature sequence co-determines peptide carboxylate and C-terminal side-chain binding. Significance: Understanding the stereochemical determinants of peptide binding leads to an improved ability to predict PDZ interaction specificity.

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Stereochemical Preferences Modulate Affinity and Selectivity among Five PDZ Domains that Bind CFTR: Comparative Structural and Sequence Analyses

et al. 2014

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Summary PDZ domain interactions are involved in signaling and trafficking pathways that coordinate crucial cellular processes. Alignment-based PDZ binding motifs identify the few most favorable residues at certain positions along the peptide backbone. However, sequences that bind the CAL (CFTR-Associated Ligand) PDZ domain reveal only a degenerate motif that overpredicts the true number of high affinity interactors. Here, we combine extended peptide-array motif analysis with biochemical techniques to show that non-motif ‘modulator’ residues influence CAL binding. The crystallographic structures of 13 new CAL:peptide complexes reveal defined, but accommodating stereochemical environments at non-motif positions, which are reflected in modulator preferences uncovered by multi-sequence substitutional arrays. These preferences facilitate the identification of new high-affinity CAL binding sequences and differentially affect CAL and NHERF PDZ binding. As a result, they also help determine the specificity of a PDZ domain network that regulates the trafficking of CFTR at the apical membrane.

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J.F. Amacher

A Compact Structure of Cytochrome c Trapped in a Lysine-Ligated State: Loop Refolding and Functional Implications of a Conformational Switch

Specificity in PDZ-peptide interaction networks: Computational analysis and review

Stereochemical Determinants of C-terminal Specificity in PDZ Peptide-binding Domains

Stereochemical Preferences Modulate Affinity and Selectivity among Five PDZ Domains that Bind CFTR: Comparative Structural and Sequence Analyses

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