Christopher G. Evans

Heat Shock Proteins 70 and 90 Inhibit Early Stages of Amyloid β-(1–42) Aggregation in Vitro

Alzheimer disease is a neurological disorder that is characterized by the presence of fibrils and oligomers composed of the amyloid β (Aβ) peptide. In models of Alzheimer disease, overexpression of molecular chaperones, specifically heat shock protein 70 (Hsp70), suppresses phenotypes related to Aβ aggregation. These observations led to the hypothesis that chaperones might interact with Aβ and block self-association. However, although biochemical evidence to support this model has been collected in other neurodegenerative systems, the interaction between chaperones and Aβ has not been similarly explored. Here, we examine the effects of Hsp70/40 and Hsp90 on Aβ aggregation in vitro. We found that recombinant Hsp70/40 and Hsp90 block Aβ self-assembly and that these chaperones are effective at substoichiometric concentrations (∼1:50). The anti-aggregation activity of Hsp70 can be inhibited by a nonhydrolyzable nucleotide analog and encouraged by pharmacological stimulation of its ATPase activity. Finally, we were interested in discerning what type of amyloid structures can be acted upon by these chaperones. To address this question, we added Hsp70/40 and Hsp90 to pre-formed oligomers and fibrils. Based on thioflavin T reactivity, the combination of Hsp70/40 and Hsp90 caused structural changes in oligomers but had little effect on fibrils. These results suggest that if these chaperones are present in the same cellular compartment in which Aβ is produced, Hsp70/40 and Hsp90 may suppress the early stages of self-assembly. Thus, these results are consistent with a model in which pharmacological activation of chaperones might have a favorable therapeutic effect on Alzheimer disease.

Heat Shock Protein 70 (Hsp70) as an Emerging Drug Target

Heat shock protein 70 (Hsp70) is a molecular chaperone that is expressed in response to stress. In this role, Hsp70 binds to its protein substrates and stabilize them against denaturation or aggregation until conditions improve.1 In addition to its functions during a stress response, Hsp70 has multiple responsibilities during normal growth; it assists in the folding of newly synthesized proteins,2, 3 the subcellular transport of proteins and vesicles,4 the formation and dissociation of complexes,5 and the degradation of unwanted proteins.6, 7 Thus, this chaperone broadly shapes protein homeostasis by controlling protein quality control and turnover during both normal and stress conditions.8 Consistent with these diverse activities, genetic and biochemical studies have implicated it in a range of diseases, including cancer, neurodegeneration, allograft rejection and infection. This review provides a brief review of Hsp70 structure and function and then explores some of the emerging opportunities (and challenges) for drug discovery. Hsp70 is Highly Conserved Members of the Hsp70 family are ubiquitously expressed and highly conserved; for example, the major Hsp70 from Escherichia coli, termed DnaK, is approximately 50% identical to human Hsp70s.9 Eukaryotes often express multiple Hsp70 family members with major isoforms found in all the cellular compartments: Hsp72 (HSPA1A) and heat shock cognate 70 (Hsc70/HSPA8) in the cytosol and nucleus, BiP (Grp78/HSPA5) in the endoplasmic reticulum and mtHsp70 (Grp75/mortalin/HSPA9) in mitochondria. Some of the functions of the cytosolic isoforms, Hsc70 and Hsp72, are thought to be redundant, but the transcription of Hsp72 is highly responsive to stress and Hsc70 is constitutively expressed. In the ER and mitochondria, the Hsp70 family members are thought to fulfill specific functions and have unique substrates, with BiP playing key roles in the folding and quality control of ER proteins and mtHsp70 being involved in the import and export of proteins from the mitochondria. For the purposes of this review, we will often use Hsp70 as a generic term to encompass the shared properties of the family members.

Enantioselective Organocatalytic Hantzsch Synthesis of Polyhydroquinolines

The four-component Hantzsch reaction provides access to pharmaceutically important dihydropyridines. To expand the utility of this method, we have developed a route under organocatalytic conditions with good yields and excellent ees. Through catalyst screening, we found that a BINOL-phosphoric acid allowed enantioselective synthesis of six-membered heterocycles with a variety of substitution patterns.

Binding of a Small Molecule at a Protein–Protein Interface Regulates the Chaperone Activity of Hsp70–Hsp40

Heat shock protein 70 (Hsp70) is a highly conserved molecular chaperone that plays multiple roles in protein homeostasis. In these various tasks, the activity of Hsp70 is shaped by interactions with co-chaperones, such as Hsp40. The Hsp40 family of co-chaperones binds to Hsp70 through a conserved J-domain, and these factors stimulate ATPase and protein-folding activity. Using chemical screens, we identified a compound, 115-7c, which acts as an artificial co-chaperone for Hsp70. Specifically, the activities of 115-7c mirrored those of a Hsp40; the compound stimulated the ATPase and protein-folding activities of a prokaryotic Hsp70 (DnaK) and partially compensated for a Hsp40 loss-of-function mutation in yeast. Consistent with these observations, NMR and mutagenesis studies indicate that the binding site for 115-7c is adjacent to a region on DnaK that is required for J-domain-mediated stimulation. Interestingly, we found that 115-7c and the Hsp40 do not compete for binding but act in concert. Using this information, we introduced additional steric bulk to 115-7c and converted it into an inhibitor. Thus, these chemical probes either promote or inhibit chaperone functions by regulating Hsp70-Hsp40 complex assembly at a native protein-protein interface. This unexpected mechanism may provide new avenues for exploring how chaperones and co-chaperones cooperate to shape protein homeostasis.

Synthesis of Orthogonally Reactive FK506 Derivatives via Olefin Cross Metathesis

Chemical inducers of dimerization (CIDs) are employed in a wide range of biological applications to control protein localization, modulate protein-protein interactions and improve drug lifetimes. These bifunctional chemical probes are assembled from two synthetic modules, which each provide affinity for a distinct protein target. FK506 and its derivatives are often employed as modules in the syntheses of these bifunctional constructs, owing to the abundance and favorable distribution of their target, FK506-binding protein (FKBP). However, the structural complexity of FK506 necessitates multi-step syntheses and/or multiple protection-deprotection schemes prior to installation into CIDs. In this work, we describe an efficient, one-step synthesis of FK506 derivatives through a selective, microwave-accelerated, cross metathesis diversification step of the C39 terminal alkene. Using this approach, FK506 is modified with an array of functional groups, including primary amines and carboxylic acids, which make the resulting derivatives suitable for the modular assembly of CIDs. To illustrate this idea, we report the synthesis of a heterobifunctional HIV protease inhibitor.

Improved synthesis of 15-deoxyspergualin analogs using the Ugi multi-component reaction

Spergualin is a natural product that exhibits immunosuppressive, anti-tumor and anti-bacterial activities. Its derivatives, such as 15-deoxyspergualin (15-DSG), have been clinically approved for acute allograft rejection. However, the reported syntheses are cumbersome (>10 steps) and they suffer from low overall yields (∼0.3% to 18%). Moreover, spergualin and its derivatives are chemically unstable and rapidly hydrolyzed in aqueous buffer. Here, we have re-explored these issues and report a modified synthetic route with significantly improved overall yield (∼31% to 47%). The key transformation is a microwave-accelerated Ugi multi-component reaction that is used to generate the peptoid core in a single step. Using the products of this route, we found that modifications of the hemiaminal significantly increased chemical stability. Thus, we anticipate that this synthetic route will improve access to biologically active 15-DSG derivatives.

Correction to enantioselective organocatalytic hantzsch synthesis of polyhydroquinolines.

The following changes were made to the revised Supporting Information document submitted with this correction: (1) All data referring to compound 4o has been removed. (2) HPLC traces for 4a, 4d, 4h, and 4n have been replaced with less ambiguous choices, pp 43−47. (3) Clarification of the method to confirm peak identities is now included, p 48. (4) Confirmation of peak identities is now included for compounds 4a, 4d, 4h, 4k, 4l, and 4n, pp 48−50. (5) Missing retention times for compounds 4a and 4g have been added on p 42. (6) H NMR peaks have been added for compounds 4k and 4j. These were missing in the original document, p 5. (7) The new Supplemental Figure 1 has been added (p 2), which shows that the Hantzsch reaction to produce compound 4b does not proceed in the absence of catalyst. We previously neglected to include this important data. This material is available free of charge via the Internet at http://pubs.acs.org.