Driving forces in amyloidosis: How does a light chain make a heavy heart?

Light-chain amyloidosis (AL) is a fatal disorder wherein the immunoglobulin light chain misfolds and aggregates, leading to amyloid plaques in various organs. Patient-specific mutations in the light chain variable domain (V_L) are tightly linked to amyloidosis, but how these mutations drive AL is unknown. In recent work, Rottenaicher et al. analyze five mutations found in the V_L of a patient with cardiac AL. Their data suggest that decreased V_L stability and increased flexibility in the core of the V_L, caused by mutations outside of this core, could be key to aggregation and highlight the delicate balancing act required for antibody maturation to enable antigen recognition while not altering protein biophysics.

Variable domain I of nematode CLEs directs post-translational targeting of CLE peptides to the extracellular space

Effector proteins expressed in the esophageal gland cells of cyst nematodes are delivered into plant cells through a hollow, protrusible stylet. Although evidence indicates that effector proteins function in the cytoplasm of the syncytium, technical constraints have made it difficult to directly determine where nematode effector proteins are initially delivered: cytoplasm, extracellular space, or both. Recently, we demonstrated that soybean cyst nematode CLE (HgCLE) propeptides are delivered to the cytoplasm of syncytial cells. Genetic and biochemical analyses indicate that the variable domain (VD) sequence is then required for targeting cytoplasmically delivered nematode CLEs to the apoplast where they function as ligand mimics of endogenous plant CLE peptides. The fact that nematode CLEs are targeted through the gland cell secretory pathway and delivered as mature propeptides into plant cells makes it impossible for these proteins to be subsequently delivered to the extracellular space via co-translational translocation through the endoplasmic reticulum (ER) secretory pathway of the host cell. However, when expressed in transgenic plants, if the mature nematode CLE propeptide harbored a functional cryptic signal peptide, it could possibly traffic to the apoplast through the ER secretory pathway by co-translational translocation. Here, we present evidence that VDI, the N-terminal sequence of the variable domain of HgCLE2, is sufficient for trafficking CLE peptides to the apoplast and that trafficking is indeed through an alternative pathway other than co-translational translocation.