What question did this study set out to answer?

To explore how the E425K mutation in DNAJC7 impairs communication with Hsp70 chaperone systems in ALS.

February 25, 2026

Holding but not folding: How a single charge flip uncouples the DNAJC7-Hsp70 relay in amyotrophic lateral sclerosis.

Key Points

To explore how the E425K mutation in DNAJC7 impairs communication with Hsp70 chaperone systems in ALS.
High-resolution NMR to analyze the structural integrity of DNAJC7
Comparison with in vivo studies on ALS pathology
Discussion of pathway complexity related to Hsp70 function
E425K mutation maintains DNAJC7's overall structure
Mutation disrupts communication with Hsp70 chaperone machinery
Findings highlight a potential target for rescuing Hsp70 function in ALS

Abstract

Genetic mutations impact protein function through various routes: Some catalyze new oncogenic activities, while others trigger complete structural collapse. However, the E425K mutation in DNAJC7, associated with Amyotrophic Lateral Sclerosis (ALS), presents a far more subtle and intriguing case. In their recent study in The FEBS Journal, Elmaleh et al. (2026) FEBS Lett employed high-resolution NMR to demonstrate that this mutation leaves the protein's overall structure intact while selectively paralyzing its ability to communicate with the Hsp70 chaperone machinery. In this commentary, we show how their work complements in vivo studies that investigate ALS disease pathology at pathway complexity and defines a new target to rescue non-functioning Hsp70 chaperone systems.

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Holding but not folding: How a single charge flip uncouples the DNAJC7-Hsp70 relay in amyotrophic lateral sclerosis.

Key Points

Abstract

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