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Cross-seeding between the functional amyloidogenic CRES and CRES3 family members and their regulation of Aβ assembly

Accumulating evidence shows that amyloids perform biological roles. We previously showed that an amyloid matrix composed of four members of the CRES subgroup of reproductive family 2 cystatins is a normal component of the mouse epididymal lumen. The cellular mechanisms that control the assembly of t...

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Published in:	The Journal of biological chemistry 2021-01, Vol.296, p.100250-100250, Article 100250
Main Authors:	Do, Hoa Quynh, Hewetson, Aveline, Borcik, Collin G., Hastert, Mary Catherine, Whelly, Sandra, Wylie, Benjamin J., Sutton, Roger Bryan, Cornwall, Gail A.
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Language:	English
Subjects:	amyloid Amyloid - chemistry Amyloid - genetics Amyloidogenic Proteins - chemistry Amyloidogenic Proteins - genetics Animals Benzothiazoles - chemistry Benzothiazoles - pharmacology CRES subgroup cross-seeding cystatin Cystatins - chemistry Cystatins - genetics epididymis Epididymis - chemistry Epididymis - growth & development Male Mice Microscopy, Electron, Transmission mouse X-Ray Diffraction
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description	Accumulating evidence shows that amyloids perform biological roles. We previously showed that an amyloid matrix composed of four members of the CRES subgroup of reproductive family 2 cystatins is a normal component of the mouse epididymal lumen. The cellular mechanisms that control the assembly of these and other functional amyloid structures, however, remain unclear. We speculated that cross-seeding between CRES members could be a mechanism to control the assembly of the endogenous functional amyloid. Herein we used thioflavin T assays and negative stain transmission electron microscopy to explore this possibility. We show that CRES3 rapidly formed large networks of beaded chains that possessed the characteristic cross-β reflections of amyloid when examined by X-ray diffraction. The beaded amyloids accelerated the amyloidogenesis of CRES, a less amyloidogenic family member, in seeding assays during which beads transitioned into films and fibrils. Similarly, CRES seeds expedited CRES3 amyloidogenesis, although less efficiently than the CRES3 seeding of CRES. These studies suggest that CRES and CRES3 hetero-oligomerize and that CRES3 beaded amyloids may function as stable preassembled seeds. The CRES3 beaded amyloids also facilitated assembly of the unrelated amyloidogenic precursor Aβ by providing a surface for polymerization though, intriguingly, CRES3 (and CRES) monomer/early oligomer profoundly inhibited Aβ assembly. The cross-seeding between the CRES subgroup members is similar to that which occurs between bacterial curli proteins suggesting that it may be an evolutionarily conserved mechanism to control the assembly of some functional amyloids. Further, interactions between unrelated amyloidogenic precursors may also be a means to regulate functional amyloid assembly.
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We previously showed that an amyloid matrix composed of four members of the CRES subgroup of reproductive family 2 cystatins is a normal component of the mouse epididymal lumen. The cellular mechanisms that control the assembly of these and other functional amyloid structures, however, remain unclear. We speculated that cross-seeding between CRES members could be a mechanism to control the assembly of the endogenous functional amyloid. Herein we used thioflavin T assays and negative stain transmission electron microscopy to explore this possibility. We show that CRES3 rapidly formed large networks of beaded chains that possessed the characteristic cross-β reflections of amyloid when examined by X-ray diffraction. The beaded amyloids accelerated the amyloidogenesis of CRES, a less amyloidogenic family member, in seeding assays during which beads transitioned into films and fibrils. Similarly, CRES seeds expedited CRES3 amyloidogenesis, although less efficiently than the CRES3 seeding of CRES. These studies suggest that CRES and CRES3 hetero-oligomerize and that CRES3 beaded amyloids may function as stable preassembled seeds. The CRES3 beaded amyloids also facilitated assembly of the unrelated amyloidogenic precursor Aβ by providing a surface for polymerization though, intriguingly, CRES3 (and CRES) monomer/early oligomer profoundly inhibited Aβ assembly. The cross-seeding between the CRES subgroup members is similar to that which occurs between bacterial curli proteins suggesting that it may be an evolutionarily conserved mechanism to control the assembly of some functional amyloids. Further, interactions between unrelated amyloidogenic precursors may also be a means to regulate functional amyloid assembly.</description><identifier>ISSN: 0021-9258</identifier><identifier>EISSN: 1083-351X</identifier><identifier>DOI: 10.1074/jbc.RA120.015307</identifier><identifier>PMID: 33384380</identifier><language>eng</language><publisher>United States: Elsevier Inc</publisher><subject>amyloid ; Amyloid - chemistry ; Amyloid - genetics ; Amyloidogenic Proteins - chemistry ; Amyloidogenic Proteins - genetics ; Animals ; Benzothiazoles - chemistry ; Benzothiazoles - pharmacology ; CRES subgroup ; cross-seeding ; cystatin ; Cystatins - chemistry ; Cystatins - genetics ; epididymis ; Epididymis - chemistry ; Epididymis - growth & development ; Male ; Mice ; Microscopy, Electron, Transmission ; mouse ; X-Ray Diffraction</subject><ispartof>The Journal of biological chemistry, 2021-01, Vol.296, p.100250-100250, Article 100250</ispartof><rights>2021 The Authors</rights><rights>Copyright © 2021 The Authors. 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Similarly, CRES seeds expedited CRES3 amyloidogenesis, although less efficiently than the CRES3 seeding of CRES. These studies suggest that CRES and CRES3 hetero-oligomerize and that CRES3 beaded amyloids may function as stable preassembled seeds. The CRES3 beaded amyloids also facilitated assembly of the unrelated amyloidogenic precursor Aβ by providing a surface for polymerization though, intriguingly, CRES3 (and CRES) monomer/early oligomer profoundly inhibited Aβ assembly. The cross-seeding between the CRES subgroup members is similar to that which occurs between bacterial curli proteins suggesting that it may be an evolutionarily conserved mechanism to control the assembly of some functional amyloids. 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Similarly, CRES seeds expedited CRES3 amyloidogenesis, although less efficiently than the CRES3 seeding of CRES. These studies suggest that CRES and CRES3 hetero-oligomerize and that CRES3 beaded amyloids may function as stable preassembled seeds. The CRES3 beaded amyloids also facilitated assembly of the unrelated amyloidogenic precursor Aβ by providing a surface for polymerization though, intriguingly, CRES3 (and CRES) monomer/early oligomer profoundly inhibited Aβ assembly. The cross-seeding between the CRES subgroup members is similar to that which occurs between bacterial curli proteins suggesting that it may be an evolutionarily conserved mechanism to control the assembly of some functional amyloids. 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subjects	amyloid Amyloid - chemistry Amyloid - genetics Amyloidogenic Proteins - chemistry Amyloidogenic Proteins - genetics Animals Benzothiazoles - chemistry Benzothiazoles - pharmacology CRES subgroup cross-seeding cystatin Cystatins - chemistry Cystatins - genetics epididymis Epididymis - chemistry Epididymis - growth & development Male Mice Microscopy, Electron, Transmission mouse X-Ray Diffraction
title	Cross-seeding between the functional amyloidogenic CRES and CRES3 family members and their regulation of Aβ assembly
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