SRCP1 Conveys Resistance to Polyglutamine Aggregation.

The polyglutamine (polyQ) diseases are a group of nine neurodegenerative diseases caused by the expansion of a polyQ tract that results in protein aggregation. Unlike other model organisms, Dictyostelium discoideum is a proteostatic outlier, naturally encoding long polyQ tracts yet resistant to polyQ aggregation. Here we identify serine-rich chaperone protein 1 (SRCP1) as a molecular chaperone that is necessary and sufficient to suppress polyQ aggregation. SRCP1 inhibits aggregation of polyQ-expanded proteins, allowing for their degradation via the proteasome, where SRCP1 is also degraded. SRCP1's C-terminal domain is essential for its activity in cells, and peptides that mimic this domain suppress polyQ aggregation in vitro. Together our results identify a novel type of molecular chaperone and reveal how nature has dealt with the problem of polyQ aggregation.

Acute stress and multicellular development alter the solubility of the Dictyostelium Sup35 ortholog ERF3.

Among sequenced organisms, the genome of Dictyostelium discoideum is unique in that it encodes for a massive amount of repeat-rich sequences in the coding region of genes. This results in the Dictyostelium proteome encoding for thousands of repeat-rich proteins, with nearly 24% of the Dictyostelium proteome encoding Q/N-rich regions that are predicted to be prion like in nature. To begin investigating the role of prion-like proteins in Dictyostelium, we decided to investigate ERF3, the Dictyostelium ortholog of the well-characterized yeast prion protein Sup35. ERF3 lacks the Q/N-rich region required for prion formation in yeast, raising the question of whether this protein aggregates and has prion-like properties in Dictyostelium. Here, we found that ERF3 formed aggregates in response to acute cellular stress. However, unlike bona fide prions, we were unable to detect transmission of aggregates to progeny. We further found that aggregation of this protein is driven by the ordered C-terminal domain independently of the disordered N-terminal domain. Finally, we also observed aggregation of ERF3 under conditions that induce multicellular development, suggesting that this phenomenon may play a role in Dictyostelium development. Together, these findings suggest a role for regulated protein aggregation in Dictyostelium cells under stress and during development.IMPORTANCEPrion-like proteins have both beneficial and deleterious effects on cellular health, and many organisms have evolved distinct mechanisms to regulate the behaviors of these proteins. The social amoeba Dictyostelium discoideum contains the highest proportion of proteins predicted to be prion like and has mechanisms to suppress their aggregation. However, the potential roles and regulation of these proteins remain largely unknown. Here, we demonstrate that aggregation of the Dictyostelium translation termination factor ERF3 is induced by both acute cellular stress and by multicellular development. These findings imply that protein aggregation may have a regulated and functional role in the Dictyostelium stress response and during multicellular development.

Mechanistic Insight into the Suppression of Polyglutamine Aggregation by SRCP1.

Protein aggregation is a hallmark of the polyglutamine diseases. One potential treatment for these diseases is suppression of polyglutamine aggregation. Previous work identified the cellular slime mold Dictyostelium discoideum as being naturally resistant to polyglutamine aggregation. Further work identified serine-rich chaperone protein 1 (SRCP1) as a protein that is both necessary in Dictyostelium and sufficient in human cells to suppress polyglutamine aggregation. Therefore, understanding how SRCP1 suppresses aggregation may be useful for developing therapeutics for the polyglutamine diseases. Here we utilized a de novo protein modeling approach to generate predictions of SRCP1's structure. Using our best-fit model, we generated mutants that were predicted to alter the stability of SRCP1 and tested these mutants' stability in cells. Using these data, we identified top models of SRCP1's structure that are consistent with the C-terminal region of SRCP1 forming a ß-hairpin with a highly dynamic N-terminal region. We next generated a series of peptides that mimic the predicted ß-hairpin and validated that they inhibit aggregation of a polyglutamine-expanded mutant huntingtin exon 1 fragment in vitro. To further assess mechanistic details of how SRCP1 inhibits polyglutamine aggregation, we utilized biochemical assays to determine that SRCP1 inhibits secondary nucleation in a manner dependent upon the regions flanking the polyglutamine tract. Finally, to determine if SRCP1 more could generally suppress protein aggregation, we confirmed that it was sufficient to inhibit aggregation of polyglutamine-expanded ataxin-3. Together these studies provide details into the structural and mechanistic basis of the inhibition of protein aggregation by SRCP1.

Dictyostelium discoideum as a Model for Investigating Neurodegenerative Diseases.

The social amoeba Dictyostelium discoideum is a model organism that is used to investigate many cellular processes including chemotaxis, cell motility, cell differentiation, and human disease pathogenesis. While many single-cellular model systems lack homologs of human disease genes, Dictyostelium's genome encodes for many genes that are implicated in human diseases including neurodegenerative diseases. Due to its short doubling time along with the powerful genetic tools that enable rapid genetic screening, and the ease of creating knockout cell lines, Dictyostelium is an attractive model organism for both interrogating the normal function of genes implicated in neurodegeneration and for determining pathogenic mechanisms that cause disease. Here we review the literature involving the use of Dictyostelium to interrogate genes implicated in neurodegeneration and highlight key questions that can be addressed using Dictyostelium as a model organism.