Search

Your search keyword '"David C. Thorn"' showing total 37 results
Start Over Author "David C. Thorn"
37 results on '"David C. Thorn"'

1. Role of Oxidative Stress in Ocular Diseases: A Balancing Act

Author

Daisy Y. Shu, Suman Chaudhary, Kin-Sang Cho, Anton Lennikov, William P. Miller, David C. Thorn, Menglu Yang, and Tina B. McKay

Subjects
reactive oxygen species, mitochondrial dysfunction, cornea, retina, age-related macular degeneration, keratoconus, Microbiology, QR1-502
Abstract

Redox homeostasis is a delicate balancing act of maintaining appropriate levels of antioxidant defense mechanisms and reactive oxidizing oxygen and nitrogen species. Any disruption of this balance leads to oxidative stress, which is a key pathogenic factor in several ocular diseases. In this review, we present the current evidence for oxidative stress and mitochondrial dysfunction in conditions affecting both the anterior segment (e.g., dry eye disease, keratoconus, cataract) and posterior segment (age-related macular degeneration, proliferative vitreoretinopathy, diabetic retinopathy, glaucoma) of the human eye. We posit that further development of therapeutic interventions to promote pro-regenerative responses and maintenance of the redox balance may delay or prevent the progression of these major ocular pathologies. Continued efforts in this field will not only yield a better understanding of the molecular mechanisms underlying the pathogenesis of ocular diseases but also enable the identification of novel druggable redox targets and antioxidant therapies.

Published
2023
Full Text
View/download PDF

2. The Amyloid Fibril-Forming β-Sheet Regions of Amyloid β and α-Synuclein Preferentially Interact with the Molecular Chaperone 14-3-3ζ

Author

Danielle M. Williams, David C. Thorn, Christopher M. Dobson, Sarah Meehan, Sophie E. Jackson, Joanna M. Woodcock, and John A. Carver

Subjects
14-3-3 proteins, molecular chaperone, amyloid β, α-synuclein, NMR spectroscopy, amyloid fibril, Organic chemistry, QD241-441
Abstract

14-3-3 proteins are abundant, intramolecular proteins that play a pivotal role in cellular signal transduction by interacting with phosphorylated ligands. In addition, they are molecular chaperones that prevent protein unfolding and aggregation under cellular stress conditions in a similar manner to the unrelated small heat-shock proteins. In vivo, amyloid β (Aβ) and α-synuclein (α-syn) form amyloid fibrils in Alzheimer’s and Parkinson’s diseases, respectively, a process that is intimately linked to the diseases’ progression. The 14-3-3ζ isoform potently inhibited in vitro fibril formation of the 40-amino acid form of Aβ (Aβ40) but had little effect on α-syn aggregation. Solution-phase NMR spectroscopy of 15N-labeled Aβ40 and A53T α-syn determined that unlabeled 14-3-3ζ interacted preferentially with hydrophobic regions of Aβ40 (L11-H21 and G29-V40) and α-syn (V3-K10 and V40-K60). In both proteins, these regions adopt β-strands within the core of the amyloid fibrils prepared in vitro as well as those isolated from the inclusions of diseased individuals. The interaction with 14-3-3ζ is transient and occurs at the early stages of the fibrillar aggregation pathway to maintain the native, monomeric, and unfolded structure of Aβ40 and α-syn. The N-terminal regions of α-syn interacting with 14-3-3ζ correspond with those that interact with other molecular chaperones as monitored by in-cell NMR spectroscopy.

Published
2021
Full Text
View/download PDF

3. A native chemical chaperone in the human eye lens

Author

Eugene Serebryany, Sourav Chowdhury, Christopher N Woods, David C Thorn, Nicki E Watson, Arthur A McClelland, Rachel E Klevit, and Eugene I Shakhnovich

Subjects
protein aggregation, cataract, eye lens, crystallin, chemical chaperone, disulfide, Medicine, Science, Biology (General), QH301-705.5
Abstract

Cataract is one of the most prevalent protein aggregation disorders and still the most common cause of vision loss worldwide. The metabolically quiescent core region of the human lens lacks cellular or protein turnover; it has therefore evolved remarkable mechanisms to resist light-scattering protein aggregation for a lifetime. We now report that one such mechanism involves an unusually abundant lens metabolite, myo-inositol, suppressing aggregation of lens crystallins. We quantified aggregation suppression using our previously well-characterized in vitro aggregation assays of oxidation-mimicking human γD-crystallin variants and investigated myo-inositol’s molecular mechanism of action using solution NMR, negative-stain TEM, differential scanning fluorometry, thermal scanning Raman spectroscopy, turbidimetry in redox buffers, and free thiol quantitation. Unlike many known chemical chaperones, myo-inositol’s primary target was not the native, unfolded, or final aggregated states of the protein; rather, we propose that it was the rate-limiting bimolecular step on the aggregation pathway. Given recent metabolomic evidence that it is severely depleted in human cataractous lenses compared to age-matched controls, we suggest that maintaining or restoring healthy levels of myo-inositol in the lens may be a simple, safe, and globally accessible strategy to prevent or delay lens opacification due to age-onset cataract.

Published
2022
Full Text
View/download PDF

5. Amyloid fibril formation by α

Author

Elmira, Bahraminejad, Devashi, Paliwal, Margaret, Sunde, Carl, Holt, John A, Carver, and David C, Thorn

Subjects
Intrinsically Disordered Proteins, Amyloid, Protein Aggregates, Camelus, Proline, Glutamine, Goats, Animals, Caseins, Cattle, Female, Micelles
Abstract

Caseins are a diverse family of intrinsically disordered proteins present in the milks of all mammals. A property common to two cow paralogues, α

Published
2022

8. Redox chemistry of lens crystallins: A system of cysteines

Author

David C. Thorn, Liliana Quintanar, and Eugene Serebryany

Subjects
Aging, Protein aggregation, Redox, Article, Cellular and Molecular Neuroscience, Crystallin, Lens, Crystalline, Metabolome, medicine, Humans, Cysteine, Disulfides, Sulfhydryl Compounds, gamma-Crystallins, Therapeutic strategy, Glutathione Disulfide, Chemistry, Lipidome, Glutathione, Sensory Systems, Ophthalmology, medicine.anatomical_structure, Lens (anatomy), Proteome, Biophysics, Oxidation-Reduction
Abstract

The nuclear region of the lens is metabolically quiescent, but it is far from inert chemically. Without cellular renewal and with decades of environmental exposures, the lens proteome, lipidome, and metabolome change. The lens crystallins have evolved exquisite mechanisms for resisting, slowing, adapting to, and perhaps even harnessing the effects of these cumulative chemical modifications to minimize the amount of light-scattering aggregation in the lens over a lifetime. Redox chemistry is a major factor in these damages and mitigating adaptations, and as such, it is likely to be a key component of any successful therapeutic strategy for preserving or rescuing lens transparency, and perhaps flexibility, during aging. Protein redox chemistry is typically mediated by Cys residues. This review will therefore focus primarily on the Cys-rich γ-crystallins of the human lens, taking care to extend these findings to the β- and α-crystallins where pertinent.

Published
2021

9. The amyloid fibril-forming β-sheet regions of amyloid β and α-synuclein preferentially interact with the molecular chaperone 14-3-3ζ

Author

Christopher M. Dobson, David C. Thorn, Danielle M. Williams, Sarah Meehan, John A. Carver, Joanna M. Woodcock, Sophie E. Jackson, Williams, Danielle M, Thorn, David C, Dobson, Christopher M, Meehan, Sarah, Jackson, Sophie E, Woodcock, Joanna M, Carver, John A, Thorn, David C. [0000-0002-7332-2292], Meehan, Sarah [0000-0002-2778-4373], Woodcock, Joanna M. [0000-0001-5127-9687], Carver, John A. [0000-0002-2441-8108], Apollo - University of Cambridge Repository, Thorn, David C [0000-0002-7332-2292], Woodcock, Joanna M [0000-0001-5127-9687], Carver, John A [0000-0002-2441-8108], and Jackson, Sophie [0000-0002-7470-9800]

Subjects
Gene isoform, Amyloid, Protein Conformation, Beta sheet, Pharmaceutical Science, Organic chemistry, Article, Analytical Chemistry, chemistry.chemical_compound, Protein Aggregates, QD241-441, α-synuclein, NMR spectroscopy, In vivo, Drug Discovery, amyloid fibril, Humans, Protein Interaction Domains and Motifs, Physical and Theoretical Chemistry, Protein Unfolding, Amyloid beta-Peptides, Chemistry, 14-3-3 proteins, Nuclear magnetic resonance spectroscopy, molecular chaperone, In vitro, Monomer, Chemistry (miscellaneous), Biophysics, Unfolded protein response, alpha-Synuclein, Molecular Medicine, Phosphorylation, amyloid β, Protein Conformation, beta-Strand, Molecular Chaperones, Protein Binding
Abstract

14-3-3 proteins are abundant, intramolecular proteins that play a pivotal role in cellular signal transduction by interacting with phosphorylated ligands. In addition, they are molecular chaperones that prevent protein unfolding and aggregation under cellular stress conditions in a similar manner to the unrelated small heat-shock proteins. In vivo, amyloid β (Aβ) and α-synuclein (α-syn) form amyloid fibrils in Alzheimer’s and Parkinson’s diseases, respectively, a process that is intimately linked to the diseases’ progression. The 14-3-3ζ isoform potently inhibited in vitro fibril formation of the 40-amino acid form of Aβ (Aβ40) but had little effect on α-syn aggregation. Solution-phase NMR spectroscopy of 15N-labeled Aβ40 and A53T α-syn determined that unlabeled 14-3-3ζ interacted preferentially with hydrophobic regions of Aβ40 (L11-H21 and G29-V40) and α-syn (V3-K10 and V40-K60). In both proteins, these regions adopt β-strands within the core of the amyloid fibrils prepared in vitro as well as those isolated from the inclusions of diseased individuals. The interaction with 14-3-3ζ is transient and occurs at the early stages of the fibrillar aggregation pathway to maintain the native, monomeric, and unfolded structure of Aβ40 and α-syn. The N-terminal regions of α-syn interacting with 14-3-3ζ correspond with those that interact with other molecular chaperones as monitored by in-cell NMR spectroscopy.

Published
2021

10. Native disulphide-linked dimers facilitate amyloid fibril formation by bovine milk alpha(S2)-casein

Author

Glyn L. Devlin, Jitendra P. Mata, Aidan B. Grosas, Elmira Bahraminejad, Heath Ecroyd, John A. Carver, Carl Holt, Margaret Sunde, David C. Thorn, Peter Hoffmann, Tomas Koudelka, Thorn, David C, Bahraminejad, Elmira, Grosas, Aidan B, Koudelka, Tomas, Hoffmann, Peter, Mata, Jitendra P, Devlin, Glyn L, Sunde, Margaret, Ecroyd, Heath, Holt, Carl, and Carver, John A

Subjects
Circular dichroism, Dimer, 030303 biophysics, Biophysics, macromolecular substances, Fibril, Antiparallel (biochemistry), Biochemistry, 03 medical and health sciences, chemistry.chemical_compound, medicine, Intramolecular disulphide, 030304 developmental biology, 0303 health sciences, Milk casein protein, Amyloidosis, Organic Chemistry, medicine.disease, Monomer, chemistry, Intermolecular disulphide, Thioflavin, Amyloid fibril, Cysteine
Abstract

Bovine milk alpha(S2)-casein, an intrinsically disordered protein, readily forms amyloid fibrils in vitro and is implicated in the formation of amyloid fibril deposits in mammary tissue. Its two cysteine residues participate in the formation of either intra- or intermolecular disulphide bonds, generating monomer and dimer species. X-ray solution scattering measurements indicated that both forms of the protein adopt large, spherical oligomers at 20 degrees C. Upon incubation at 37 degrees C, the disulphide-linked dimer showed a significantly greater propensity to form amyloid fibrils than its monomeric counterpart. Thioflavin T fluorescence, circular dichroism and infrared spectra were consistent with one or both of the dimer isomers (in a parallel or antiparallel arrangement) being predisposed toward an ordered, amyloid-like structure. Limited proteolysis experiments indicated that the region from Ala(81) to Lys(113) is incorporated into the fibril core, implying that this region, which is predicted by several algorithms to be amyloidogenic, initiates fibril formation of alpha(S2)-casein. The partial conservation of the cysteine motif and the frequent occurrence of disulphide-linked dimers in mammalian milks despite the associated risk of mammary amyloidosis, suggest that the dimeric conformation of alpha(S2)-casein is a functional, yet amyloidogenic, structure. Refereed/Peer-reviewed

Published
2021

11. A native chemical chaperone in the human eye lens

Author

Eugene Serebryany, Sourav Chowdhury, Christopher N. Woods, David C. Thorn, Nicki E. Watson, Arthur McClelland, Rachel E. Klevit, and Eugene I. Shakhnovich

Subjects
General Immunology and Microbiology, Chemistry, General Neuroscience, General Medicine, Protein aggregation, Cataract, General Biochemistry, Genetics and Molecular Biology, law.invention, Lens (optics), Lens protein, Protein Aggregates, Metabolomics, medicine.anatomical_structure, law, Lens, Crystalline, medicine, Biophysics, Humans, Human eye, Electron microscope, Chemical chaperone, Inositol, Molecular Chaperones
Abstract

Cataract is one of the most prevalent protein aggregation disorders and still the most common cause of vision loss worldwide. The metabolically quiescent core region of the human lens lacks cellular or protein turnover; it has therefore evolved remarkable mechanisms to resist light-scattering protein aggregation for a lifetime. We now report that one such mechanism involves an unusually abundant lens metabolite, myo-inositol, suppressing aggregation of lens crystallins. We quantified aggregation suppression using our previously well-characterized in vitro aggregation assays of oxidation-mimicking human γD-crystallin variants and investigated myo-inositol’s molecular mechanism of action using solution NMR, negative-stain TEM, differential scanning fluorometry, thermal scanning Raman spectroscopy, turbidimetry in redox buffers, and free thiol quantitation. Unlike many known chemical chaperones, myo-inositol’s primary target was neither the native nor the unfolded state of the protein, nor the final aggregated state, but rather the rate-limiting bimolecular step on the aggregation pathway. Given recent metabolomic evidence that it is severely depleted in human cataractous lenses compared to age-matched controls, we suggest that maintaining or restoring healthy levels of myo-inositol in the lens may be a simple, safe, and globally accessible strategy to prevent or delay lens opacification due to age-onset cataract.

Published
2020
Full Text
View/download PDF

13. The Aggregation of αB-Crystallin under Crowding Conditions Is Prevented by αA-Crystallin: Implications for α-Crystallin Stability and Lens Transparency

Author

John A. Carver, David C. Thorn, Agata Rekas, Aidan B. Grosas, and Jitendra P. Mata

Subjects
genetic structures, Protein Conformation, Ficoll, Cataract formation, Protein Aggregation, Pathological, alpha-Crystallin A Chain, Cataract, 03 medical and health sciences, 0302 clinical medicine, Structural Biology, Crystallin, Lens, Crystalline, Animals, alpha-Crystallins, gamma-Crystallins, Molecular Biology, Lens transparency, 030304 developmental biology, 0303 health sciences, biology, Contrast variation, Chemistry, αb crystallin, alpha-Crystallin B Chain, eye diseases, Chaperone (protein), biology.protein, Biophysics, Cattle, sense organs, Macromolecular crowding, 030217 neurology & neurosurgery, Molecular Chaperones
Abstract

One of the most crowded biological environments is the eye lens which contains a high concentration of crystallin proteins. The molecular chaperones αB-crystallin (αBc) with its lens partner αA-crystallin (αAc) prevent deleterious crystallin aggregation and cataract formation. However, some forms of cataract are associated with structural alteration and dysfunction of αBc. While many studies have investigated the structure and function of αBc under dilute in vitro conditions, the effect of crowding on these aspects is not well understood despite its in vivo relevance. The structure and chaperone ability of αBc under conditions that mimic the crowded lens environment were investigated using the polysaccharide Ficoll 400 and bovine γ-crystallin as crowding agents and a variety of biophysical methods, principally contrast variation small-angle neutron scattering. Under crowding conditions, αBc unfolds, increases its size/oligomeric state, decreases its thermal stability and chaperone ability, and forms kinetically distinct amorphous and fibrillar aggregates. However, the presence of αAc stabilizes αBc against aggregation. These observations provide a rationale, at the molecular level, for the aggregation of αBc in the crowded lens, a process that exhibits structural and functional similarities to the aggregation of cataract-associated αBc mutants R120G and D109A under dilute conditions. Strategies that maintain or restore αBc stability, as αAc does, may provide therapeutic avenues for the treatment of cataract.

Published
2020

14. Cumulative deamidations of the major lens protein γS-crystallin increase its aggregation during unfolding and oxidation

Author

Calvin Vetter, Charlie C. Mundorff, Thomas E. Wales, John R. Engen, Kate Halverson, Samuel G. Wheeler, John A. Carver, Kirsten J. Lampi, Ujwal Shinde, David C. Thorn, and Larry L. David

Subjects
Full‐Length Papers, Population, Protein aggregation, Biochemistry, Lens protein, 03 medical and health sciences, chemistry.chemical_compound, Protein Aggregates, Crystallin, Lens, Crystalline, Humans, gamma-Crystallins, Deamidation, Guanidine, education, Molecular Biology, 030304 developmental biology, Protein Unfolding, 0303 health sciences, education.field_of_study, biology, 030302 biochemistry & molecular biology, Wild type, chemistry, Deamination, Chaperone (protein), Biophysics, biology.protein
Abstract

Age-related lens cataract is the major cause of blindness worldwide. The mechanisms whereby crystallins, the predominant lens proteins, assemble into large aggregates that scatter light within the lens, and cause cataract, are poorly understood. Due to the lack of protein turnover in the lens, crystallins are long-lived. A major crystallin, γS, is heavily modified by deamidation, in particular at surface-exposed N14, N76, and N143 to introduce negative charges. In this present study, deamidated γS was mimicked by mutation with aspartate at these sites and the effect on biophysical properties of γS was assessed via dynamic light scattering, chemical and thermal denaturation, hydrogen-deuterium exchange, and susceptibility to disulfide cross-linking. Compared with wild type γS, a small population of each deamidated mutant aggregated rapidly into large, light-scattering species that contributed significantly to the total scattering. Under partially denaturing conditions in guanidine hydrochloride or elevated temperature, deamidation led to more rapid unfolding and aggregation and increased susceptibility to oxidation. The triple mutant was further destabilized, suggesting that the effects of deamidation were cumulative. Molecular dynamics simulations predicted that deamidation augments the conformational dynamics of γS. We suggest that these perturbations disrupt the native disulfide arrangement of γS and promote the formation of disulfide-linked aggregates. The lens-specific chaperone αA-crystallin was poor at preventing the aggregation of the triple mutant. It is concluded that surface deamidations cause minimal structural disruption individually, but cumulatively they progressively destabilize γS-crystallin leading to unfolding and aggregation, as occurs in aged and cataractous lenses.

Published
2020

15. Accumulative deamidation of human lens protein γS-crystallin leads to partially unfolded intermediates with enhanced aggregation propensity

Author

Kirsten J. Lampi, Calvin Vetter, Charlie Mundorff, John A. Carver, Larry L. David, Kate Halverson, Samuel G. Wheeler, and David C. Thorn

Subjects
0303 health sciences, education.field_of_study, biology, Chemistry, 030302 biochemistry & molecular biology, Population, eye diseases, Light scattering, Lens protein, 03 medical and health sciences, Dynamic light scattering, Crystallin, Chaperone (protein), biology.protein, Biophysics, sense organs, Asparagine, Deamidation, education, 030304 developmental biology
Abstract

Age-related cataract is a major cause of blindness worldwide. Yet, the molecular mechanisms whereby large, light scattering aggregates form is poorly understood, because of the complexity of the aggregates isolated from human lenses. The predominant proteins in the lens are structural proteins called crystallins. The γS-crystallin is heavily modified in cataractous lenses by deamidation, which introduces a negative charge at labile asparagine residues. The effects of deamidation at asparagines, N14, N76, and N143, were mimicked by replacing the asparagine with aspartate using site-directed mutagenesis. The effects of these surface deamidations on the stability, unfolding, and aggregation properties of γS were determined using dynamic light scattering, chemical and thermal-denaturation, and hydrogen-deuterium exchange with mass spectrometry. We found that a small population of all the deamidation mimics aggregated directly into large light scattering bodies with a radius greater than 10 nm that contributed 14-60% of the total scattering intensity compared to 7% for WT under the same conditions. A possible mechanism was identified under partially denaturing conditions, where deamidation led to significantly more rapid unfolding and aggregation particularly for N76D compared to WT. The triple mutant was further destabilized, reflecting the enhanced aggregation properties of N14D and N143D. Thus, the effects of deamidation were both site-specific and cumulative. αA-crystallin was ineffective at acting as a chaperone to prevent the aggregation of destabilized, deamidated γS. It is concluded that surface deamidations, while causing minimal structural disruption individually, progressively destabilize crystallin proteins, leading to their unfolding and precipitation in aged and cataractous lenses.

Published
2020
Full Text
View/download PDF

16. Crystallins, cataract, and dynamic lens proteostasis. A commentary on P.W.N. Schmid, N.C.H. Lim, C. Peters, K.C. Back, B. Bourgeois, F. Pirolt, B. Richter, J. Peschek, O. Puk, O.V. Amarie, C. Dalke, M. Haslbeck, S. Weinkauf, T. Madl, J. Graw, and J. Buchner (2021) Imbalances in the eye lens proteome are linked to cataract formation, Nat. Struct. Mol. Biol. 28, 143–151. doi: 10.1038/s41594-020-00543-9

Author

Aidan B. Grosas, David C. Thorn, and John A. Carver

Subjects
Cellular and Molecular Neuroscience, Ophthalmology, Proteome, Lens, Crystalline, Proteostasis, Humans, Crystallins, Cataract, Sensory Systems
Published
2021
Full Text
View/download PDF

17. The Effect of Milk Constituents and Crowding Agents on Amyloid Fibril Formation by κ-Casein

Author

David C. Thorn, Heath Ecroyd, John A. Carver, Yanqin Liu, Francis C. Dehle, Elmira Bahraminejad, and Ji-Hua Liu

Subjects
0301 basic medicine, Amyloid, Phospholipid, macromolecular substances, Micelle, 03 medical and health sciences, chemistry.chemical_compound, Phosphatidylcholine, Casein, Animals, Lactose, 030102 biochemistry & molecular biology, Circular Dichroism, Temperature, Caseins, General Chemistry, Heparan sulfate, Kinetics, Milk, 030104 developmental biology, chemistry, Biochemistry, Thioflavin, General Agricultural and Biological Sciences, Oxidation-Reduction
Abstract

When not incorporated into the casein micelle, κ-casein, a major milk protein, rapidly forms amyloid fibrils at physiological pH and temperature. In this study, the effects of milk components (calcium, lactose, lipids, and heparan sulfate) and crowding agents on reduced and carboxymethylated (RCM) κ-casein fibril formation was investigated using far-UV circular dichroism spectroscopy, thioflavin T binding assays, and transmission electron microscopy. Longer-chain phosphatidylcholine lipids, which form the lining of milk ducts and milk fat globules, enhanced RCM κ-casein fibril formation irrespective of whether the lipids were in a monomeric or micellar state, whereas shorter-chain phospholipids and triglycerides had little effect. Heparan sulfate, a component of the milk fat globule membrane and catalyst of amyloid deposition in extracellular tissue, had little effect on the kinetics of RCM κ-casein fibril formation. Major nutritional components such as calcium and lactose also had no significant effect. Macromolecular crowding enhances protein-protein interactions, but in contrast to other fibril-forming species, the extent of RCM κ-casein fibril formation was reduced by the presence of a variety of crowding agents. These data are consistent with a mechanism of κ-casein fibril formation in which the rate-determining step is dissociation from the oligomer to give the highly amyloidogenic monomer. We conclude that the interaction of κ-casein with membrane-associated phospholipids along its secretory pathway may contribute to the development of amyloid deposits in mammary tissue. However, the formation of spherical oligomers such as casein micelles is favored over amyloid fibrils in the crowded environment of milk, within which the occurrence of amyloid fibrils is low.

Published
2016
Full Text
View/download PDF

18. The Structure and Stability of the Disulfide-Linked γS-Crystallin Dimer Provide Insight into Oxidation Products Associated with Lens Cataract Formation

Author

David C. Thorn, Colin J. Jackson, Aidan B. Grosas, Peter D. Mabbitt, John A. Carver, and Nicholas J. Ray

Subjects
genetic structures, Protein Conformation, Dimer, Cataract formation, Oxidative phosphorylation, medicine.disease_cause, Crystallography, X-Ray, Cataract, law.invention, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, Structural Biology, law, Crystallin, Lens, Crystalline, medicine, Humans, Disulfides, gamma-Crystallins, Molecular Biology, 030304 developmental biology, 0303 health sciences, Disulfide bond, Glutathione, eye diseases, Lens (optics), Oxidative Stress, chemistry, Biophysics, sense organs, Dimerization, Oxidation-Reduction, 030217 neurology & neurosurgery, Oxidative stress, Protein Binding
Abstract

The reducing environment in the eye lens diminishes with age, leading to significant oxidative stress. Oxidation of lens crystallin proteins is the major contributor to their destabilization and deleterious aggregation that scatters visible light, obscures vision, and ultimately leads to cataract. However, the molecular basis for oxidation-induced aggregation is unknown. Using X-ray crystallography and small-angle X-ray scattering, we describe the structure of a disulfide-linked dimer of human γS-crystallin that was obtained via oxidation of C24. The γS-crystallin dimer is stable at glutathione concentrations comparable to those in aged and cataractous lenses. Moreover, dimerization of γS-crystallin significantly increases the protein's propensity to form large insoluble aggregates owing to non-cooperative domain unfolding, as is observed in crystallin variants associated with early-onset cataract. These findings provide insight into how oxidative modification of crystallins contributes to cataract and imply that early-onset and age-related forms of the disease share comparable development pathways.

Published
2018

19. Proteostasis and the Regulation of Intra- and Extracellular Protein Aggregation by ATP-Independent Molecular Chaperones: Lens α-Crystallins and Milk Caseins

Author

Carl Holt, John A. Carver, Roger J.W. Truscott, David C. Thorn, and Heath Ecroyd

Subjects
0301 basic medicine, Cell, Protein aggregation, Biological pathway, 03 medical and health sciences, Protein Aggregates, Adenosine Triphosphate, Lens, Crystalline, medicine, Extracellular, Animals, Humans, Viability assay, alpha-Crystallins, 030102 biochemistry & molecular biology, Chemistry, Caseins, General Medicine, General Chemistry, Cell biology, 030104 developmental biology, medicine.anatomical_structure, Proteostasis, Milk, Lens (anatomy), Proteome, Molecular Chaperones
Abstract

Molecular chaperone proteins perform a diversity of roles inside and outside the cell. One of the most important is the stabilization of misfolding proteins to prevent their aggregation, a process that is potentially detrimental to cell viability. Diseases such as Alzheimer's, Parkinson's, and cataract are characterized by the accumulation of protein aggregates. In vivo, many proteins are metastable and therefore under mild destabilizing conditions have an inherent tendency to misfold, aggregate, and hence lose functionality. As a result, protein levels are tightly regulated inside and outside the cell. Protein homeostasis, or proteostasis, describes the network of biological pathways that ensures the proteome remains folded and functional. Proteostasis is a major factor in maintaining cell, tissue, and organismal viability. We have extensively investigated the structure and function of intra- and extracellular molecular chaperones that operate in an ATP-independent manner to stabilize proteins and prevent their misfolding and subsequent aggregation into amorphous particles or highly ordered amyloid fibrils. These types of chaperones are therefore crucial in maintaining proteostasis under normal and stress (e.g., elevated temperature) conditions. Despite their lack of sequence similarity, they exhibit many common features, i.e., extensive structural disorder, dynamism, malleability, heterogeneity, oligomerization, and similar mechanisms of chaperone action. In this Account, we concentrate on the chaperone roles of α-crystallins and caseins, the predominant proteins in the eye lens and milk, respectively. Intracellularly, the principal ATP-independent chaperones are the small heat-shock proteins (sHsps). In vivo, sHsps are the first line of defense in preventing intracellular protein aggregation. The lens proteins αA- and αB-crystallin are sHsps. They play a crucial role in maintaining solubility of the crystallins (including themselves) with age and hence in lens proteostasis and, ultimately, lens transparency. As there is little metabolic activity and no protein turnover in the lens, crystallins are very long lived proteins. Lens proteostasis is therefore very different to that in normal, metabolically active cells. Crystallins undergo extensive post-translational modification (PTM), including deamidation, racemization, phosphorylation, and truncation, which can alter their stability. Despite this, the lens remains transparent for tens of years, implying that lens proteostasis is intimately integrated with crystallin PTMs. Many PTMs do not significantly alter crystallin stability, solubility, and functionality, which thereby facilitates lens transparency. In the long term, however, extensive accumulation of crystallin PTMs leads to large-scale crystallin aggregation, lens opacification, and cataract formation. Extracellularly, various ATP-independent molecular chaperones exist that exhibit sHsp-like structural and functional features. For example, caseins, the major milk proteins, exhibit chaperone ability by inhibiting the amorphous and amyloid fibrillar aggregation of a diversity of destabilized proteins. Caseins maintain proteostasis within milk by preventing deleterious casein amyloid fibril formation via incorporation of thousands of individual caseins into an amorphous structure known as the casein micelle. Hundreds of nanoclusters of calcium phosphate are sequestered within each casein micelle through interactions with short, highly phosphorylated casein sequences. This results in a stable biofluid that contains a high concentration of potentially amyloidogenic caseins and concentrations of calcium and phosphate that can be far in excess of the solubility of calcium phosphate. Casein micelle formation therefore performs vital roles in neonatal nutrition and calcium homeostasis in the mammary gland.

Published
2018

20. Casein structures in the context of unfolded proteins

Author

Heath Ecroyd, John A. Carver, Carl Holt, and David C. Thorn

Subjects
0303 health sciences, animal structures, fungi, Mucin, 0402 animal and dairy science, Context (language use), Sequence (biology), 04 agricultural and veterinary sciences, Amyloid fibril, Phosphate, Fibril, 040201 dairy & animal science, Applied Microbiology and Biotechnology, 03 medical and health sciences, chemistry.chemical_compound, Biochemistry, chemistry, Casein, Amorphous calcium phosphate, 030304 developmental biology, Food Science
Abstract

Caseins were among the first proteins to be recognised as functional but unfolded. Many others are now known, providing better models of casein behaviour than either detergents or folded proteins. Caseins are members of a paralogous group of unfolded phosphoproteins, some of which share the ability to sequester amorphous calcium phosphate through phosphate centres. Non-covalent interactions of caseins can be through Pro- and Gln-rich sequences. Similar sequences in other unfolded proteins can also form open and highly hydrated structures such as gels, mucus and slimes. Many unfolded proteins, including κ- and αS2-caseins, can form amyloid fibrils under physiological conditions. The sequence-specific interactions that lead to fibrils can be reduced or eliminated by low specificity interactions among a mixture of caseins to yield, instead, amorphous aggregates. The size of amorphous whole casein aggregates is limited by the C-terminal half of κ-casein whose sequence resembles that of a soluble mucin.

Published
2015
Full Text
View/download PDF

21. Monitoring Early-Stage Protein Aggregation by an Aggregation-Induced Emission Fluorogen

Author

John A. Carver, Manjeet Kumar, Yuning Hong, Heath Ecroyd, and David C. Thorn

Subjects
0301 basic medicine, Amyloid, Chemistry, Fluorescence Polarization, Protein aggregation, 010402 general chemistry, 01 natural sciences, Fluorescence, 0104 chemical sciences, 3. Good health, Analytical Chemistry, Congo red, 03 medical and health sciences, chemistry.chemical_compound, Protein Aggregates, 030104 developmental biology, Biochemistry, Phenols, Humans, Thioflavin, Aggregation-induced emission, Cytotoxicity, Fluorescence anisotropy, Fluorescent Dyes
Abstract

Highly ordered protein aggregates, termed amyloid fibrils, are associated with a broad range of diseases, many of which are neurodegenerative, for example, Alzheimer's and Parkinson's. The transition from soluble, functional protein into insoluble amyloid fibril occurs via a complex process involving the initial generation of highly dynamic early stage aggregates or prefibrillar species. Amyloid probes, for example, thioflavin T and Congo red, have been used for decades as the gold standard for detecting amyloid fibrils in solution and tissue sections. However, these well-established dyes do not detect the presence of prefibrillar species formed during the early stages of protein aggregation. Prefibillar species have been proposed to play a key role in the cytotoxicity of amyloid fibrils and the pathogenesis of neurodegenerative diseases. Herein, we report a novel fluorescent dye (bis(triphenylphosphonium) tetraphenylethene (TPE-TPP)) with aggregation-induced emission characteristics for monitoring the aggregation process of amyloid fibrils. An increase in TPE-TPP fluorescence intensity is observed only with ordered protein aggregation, such as amyloid fibril formation, and not with stable molten globules states or amorphously aggregating species. Importantly, TPE-TPP can detect the presence of prefibrillar species formed early during fibril formation. TPE-TPP exhibits a distinctive spectral shift in the presence of prefibrillar species, indicating a unique structural feature of these intermediates. Using fluorescence polarization, which reflects the mobility of the emitting entity, the specific oligomeric pathways undertaken by various proteins during fibrillation could be discerned. Furthermore, we demonstrate the broad applicability of TPE-TPP to monitor amyloid fibril aggregation, including under diverse conditions such as at acidic pH and elevated temperature, or in the presence of amyloid inhibitors.

Published
2017

22. Letter to the Editor: A response to Horne and Lucey (2017)

Author

Carl Holt, Heath Ecroyd, David C. Thorn, and John A. Carver

Subjects
0301 basic medicine, 030103 biophysics, 03 medical and health sciences, 030104 developmental biology, Information retrieval, Letter to the editor, Chemistry, Genetics, Animal Science and Zoology, Data mining, computer.software_genre, computer, Food Science
Abstract

No abstract available.

Published
2017

23. Invited review: Caseins and the casein micelle: Their biological functions, structures, and behavior in foods

Author

John A. Carver, Carl Holt, David C. Thorn, and Heath Ecroyd

Subjects
Calcium Phosphates, Amyloid, Protein Folding, Chaperonins, Protein Conformation, Matrix (biology), Fibril, Micelle, Nanoclusters, Casein, Genetics, medicine, Animals, Amorphous calcium phosphate, Micelles, Chemistry, Amyloidosis, Caseins, medicine.disease, Milk, Biochemistry, Phosphorylation, Animal Science and Zoology, Dairy Products, Hydrophobic and Hydrophilic Interactions, Food Science
Abstract

A typical casein micelle contains thousands of casein molecules, most of which form thermodynamically stable complexes with nanoclusters of amorphous calcium phosphate. Like many other unfolded proteins, caseins have an actual or potential tendency to assemble into toxic amyloid fibrils, particularly at the high concentrations found in milk. Fibrils do not form in milk because an alternative aggregation pathway is followed that results in formation of the casein micelle. As a result of forming micelles, nutritious milk can be secreted and stored without causing either pathological calcification or amyloidosis of the mother's mammary tissue. The ability to sequester nanoclusters of amorphous calcium phosphate in a stable complex is not unique to caseins. It has been demonstrated using a number of noncasein secreted phosphoproteins and may be of general physiological importance in preventing calcification of other biofluids and soft tissues. Thus, competent noncasein phosphoproteins have similar patterns of phosphorylation and the same type of flexible, unfolded conformation as caseins. The ability to suppress amyloid fibril formation by forming an alternative amorphous aggregate is also not unique to caseins and underlies the action of molecular chaperones such as the small heat-shock proteins. The open structure of the protein matrix of casein micelles is fragile and easily perturbed by changes in its environment. Perturbations can cause the polypeptide chains to segregate into regions of greater and lesser density. As a result, the reliable determination of the native structure of casein micelles continues to be extremely challenging. The biological functions of caseins, such as their chaperone activity, are determined by their composition and flexible conformation and by how the casein polypeptide chains interact with each other. These same properties determine how caseins behave in the manufacture of many dairy products and how they can be used as functional ingredients in other foods.

Published
2013
Full Text
View/download PDF

24. 1H, 13C and 15N backbone resonance assignments of the β-lactamase BlaP from Bacillus licheniformis 749/C and two mutational variants

Author

Alessandra Corazza, Jennifer Kay, Noureddine Rhazi, Christian Damblon, Mireille Dumoulin, and David C. Thorn

Subjects
0301 basic medicine, Stereochemistry, Sequence (biology), Protein aggregation, BlaP hybrid proteins, Biochemistry, 03 medical and health sciences, chemistry.chemical_compound, Polyglutamine diseases, 0302 clinical medicine, Basic research, Structural Biology, Polyglutamine model proteins, Resonance assignment, Bacillus licheniformis, Dipeptide, biology, biology.organism_classification, Resonance (chemistry), Amyloid fibril, Restriction site, 030104 developmental biology, chemistry, 030217 neurology & neurosurgery
Abstract

Class A β-lactamases have been widely used as versatile scaffolds to create hybrid (or chimeric) proteins for a series of applications ranging from basic research to medicine. We have, in particular, used the β-lactamase BlaP from Bacillus licheniformis 749/C (BlaP) as a protein scaffold to create model polyglutamine (polyQ) proteins in order to better understand the mechanism(s) by which an expanded polyQ sequence triggers the formation of amyloid fibrils. The model chimeras were designed by inserting a polyQ sequence of various lengths at two different locations within BlaP (i.e. position 197 or position 216) allowing a detailed comparison of the effects of subtle differences in the environment of the polyQ sequence on its ability to trigger protein aggregation. In order to investigate the effects of the polyQ insertion at both positions on the structure, stability and dynamics of BlaP, a series of NMR experiments including H/D exchange are foreseen. Accordingly, as necessitated by these studies, here we report the NMR assignment of the wild-type BlaP (BlaP-WT) and of the two reference proteins, BlaP197Q0 and BlaP216Q0, wherein a Pro-Gly dipeptide has been introduced at position 197 and 216, respectively; this dipeptide originates from the addition of the Sma1 restriction site at the genetic level to allow further polyQ sequence insertion.

Published
2017

25. The dissociated form of κ-casein is the precursor to its amyloid fibril formation

Author

David C. Thorn, Yanqin Liu, John A. Carver, and Heath Ecroyd

Subjects
Amyloid, In Vitro Techniques, Protein aggregation, Fibril, Biochemistry, Micelle, chemistry.chemical_compound, Microscopy, Electron, Transmission, Casein, medicine, Animals, Benzothiazoles, Disulfides, Molecular Biology, Micelles, Amyloidosis, Temperature, Caseins, Cell Biology, Hydrogen-Ion Concentration, medicine.disease, Molecular Weight, Thiazoles, Monomer, chemistry, Critical micelle concentration, Cattle, Protein Multimerization, Oxidation-Reduction
Abstract

Bovine milk kappa-casein forms a self-associating oligomeric micelle-like species, in equilibrium with dissociated forms. In its native form, intra- and inter-molecular disulfide bonds lead to the formation of multimeric species ranging from monomers to decamers. When incubated under conditions of physiological pH and temperature, both reduced and non-reduced kappa-casein form highly structured beta-sheet amyloid fibrils. We investigated whether the precursor to kappa-casein fibril formation is a dissociated state of the protein or its oligomeric micelle-like form. We show that reduced kappa-casein is capable of forming fibrils well below its critical micelle concentration, i.e. at concentrations where only dissociated forms of the protein are present. Moreover, by regulating the degree of disulfide linkages, we were able to investigate how oligomerization of kappa-casein influences its propensity for fibril formation under conditions of physiological pH and temperature. Thus, using fractions containing different proportions of multimeric species, we demonstrate that the propensity of the disulfide-linked multimers to form fibrils is inversely related to their size, with monomeric kappa-casein being the most aggregation prone. We conclude that dissociated forms of kappa-casein are the amyloidogenic precursors to fibril formation rather than oligomeric micelle-like species. The results highlight the role of oligomerization and natural binding partners in preventing amyloid fibril formation by disease-related proteins in vivo.

Published
2010
Full Text
View/download PDF

26. Dissociation from the Oligomeric State Is the Rate-limiting Step in Fibril Formation by κ-Casein

Author

David C. Thorn, Danielle M. Williams, Glyn L. Devlin, Peter Hoffmann, Heath Ecroyd, Thomas Koudelka, John A. Carver, Ecroyd, Heath, Koudelka, Tomas, Thorn, David C, Williams, Danielle M, Devlin, Glyn, Hoffmann, Peter, and Carver, John A

Subjects
Amyloid, Biochemistry & Molecular Biology, Nucleation, macromolecular substances, Fibril, Biochemistry, Mass Spectrometry, Dissociation (chemistry), chemistry.chemical_compound, Nephelometry and Turbidimetry, Casein, medicine, Animals, Trypsin, Benzothiazoles, Molecular Biology, oligomeric states, biology, Caseins, Cell Biology, Rate-determining step, Proteinase K, Thiazoles, kappa casein, Crystallography, Spectrometry, Fluorescence, Models, Chemical, chemistry, Protein Structure and Folding, biology.protein, Cattle, Thioflavin, Endopeptidase K, medicine.drug
Abstract

Amyloid fibrils are aggregated and precipitated forms of protein in which the protein exists in highly ordered, long, unbranching threadlike formations that are stable and resistant to degradation by proteases. Fibril formation is an ordered process that typically involves the unfolding of a protein to partially folded states that subsequently interact and aggregate through a nucleation-dependent mechanism. Here we report on studies investigating the molecular basis of the inherent propensity of the milk protein, kappa-casein, to form amyloid fibrils. Using reduced and carboxymethylated kappa-casein ( RCM kappa-CN), we show that fibril formation is accompanied by a characteristic increase in thioflavin T fluorescence intensity, solution turbidity, and beta-sheet content of the protein. However, the lag phase of RCM kappa-CN fibril formation is independent of protein concentration, and the rate of fibril formation does not increase upon the addition of seeds ( preformed fibrils). Therefore, its mechanism of fibril formation differs from the archetypal nucleation-dependent aggregation mechanism. By digestion with trypsin or proteinase K and identification by mass spectrometry, we have determined that the region from Tyr(25) to Lys(86) is incorporated into the core of the fibrils. We suggest that this region, which is predicted to be aggregation-prone, accounts for the amyloidogenic nature of kappa-casein. Based on these data, we propose that fibril formation by RCM kappa-CN occurs through a novel mechanism whereby the rate-limiting step is the dissociation of an amyloidogenic precursor from an oligomeric state rather than the formation of stable nuclei, as has been described for most other fibril-forming systems. Refereed/Peer-reviewed

Published
2008
Full Text
View/download PDF

27. Monitoring the prevention of amyloid fibril formation by α-crystallin

Author

Roberto Cappai, Lucy Jankova, Agata Rekas, David C. Thorn, and John A. Carver

Subjects
Amyloid, Magnetic Resonance Spectroscopy, Peptide, Biochemistry, chemistry.chemical_compound, Fibril formation, Microscopy, Electron, Transmission, Crystallin, Animals, Humans, Benzothiazoles, Molecular Biology, Chromatography, High Pressure Liquid, chemistry.chemical_classification, biology, Chemistry, Temperature, Caseins, alpha-Crystallin B Chain, Cell Biology, Nuclear magnetic resonance spectroscopy, Amyloid fibril, beta-Crystallins, Recombinant Proteins, Kinetics, Thiazoles, Monomer, Chaperone (protein), alpha-Synuclein, biology.protein, Biophysics, Cattle, Molecular Chaperones, Protein Binding
Abstract

The molecular chaperone, alpha-crystallin, has the ability to prevent the fibrillar aggregation of proteins implicated in human diseases, for example, amyloid beta peptide and alpha-synuclein. In this study, we examine, in detail, two aspects of alpha-crystallin's fibril-suppressing ability: (a) its temperature dependence, and (b) the nature of the aggregating species with which it interacts. First, the efficiency of alpha-crystallin to suppress fibril formation in kappa-casein and alpha-synuclein increases with temperature, despite their rate of fibrillation also increasing in the absence of alpha-crystallin. This is consistent with an increased chaperone ability of alpha-crystallin at higher temperatures to protect target proteins from amorphous aggregation [GB Reddy, KP Das, JM PetrashWK Surewicz (2000) J Biol Chem275, 4565-4570]. Second, dual polarization interferometry was used to monitor real-time alpha-synuclein aggregation in the presence and absence of alphaB-crystallin. In contrast to more common methods for monitoring the time-dependent formation of amyloid fibrils (e.g. the binding of dyes like thioflavin T), dual polarization interferometry data did not reveal any initial lag phase, generally attributed to the formation of prefibrillar aggregates. It was shown that alphaB-crystallin interrupted alpha-synuclein aggregation at its earliest stages, most likely by binding to partially folded monomers and thereby preventing their aggregation into fibrillar structures.

Published
2007
Full Text
View/download PDF

28. Contributors

Author

Marie-Isabel Aguilar, Maria Andreasen, Neil R. Anthony, Fernando Teran Arce, Florian Arnhold, Shruti Arya, Aida Attar, Silvia Barbosa, Manja A. Behrens, Innocent B. Bekard, Georges Belfort, Martin L. Bennink, Magdalena Bereza, Keith M. Berland, Gal Bitan, Mischa Bonn, Hugo M. Botelho, Joana Branco dos Santos, Leonid Breydo, Yi Cao, Roberto Cappai, Isabel Cardoso, Mariano Carrión-Vázquez, Sofia B. Carvalho, John A. Carver, Fiona T.S. Chan, W. Seth Childers, Jason C. Collins, Laura Connelly, Cyril Curtain, Vijit Dalal, Alfonso De Simone, Athene M. Donald, Dave E. Dunstan, Heath Ecroyd, Jan Johannes Enghild, Laura Esther Abelleira, Marcus Fändrich, María del Carmen Fernández-Ramírez, Vito Foderà, Günter Fritz, Yoshiaki Furukawa, Shirin D. Ghodke, Stefano Gianni, Armin Giese, Cláudio M. Gomes, Susana Gonçalves, Lesley H. Greene, Michael D.W. Griffin, Amy M. Griggs, Christian Haass, Per Hammarström, J. Robin Harris, Federico Herrera, Rubén Hervás, Shannon E. Hill, Xu Hou, Geoffrey J. Howlett, Tsuneya Ikezu, Hyunbum Jang, Grethe V. Jensen, Bruce L. Kagan, Clemens F. Kaminski, Shigeko Kawai-Noma, Alexei Klechikov, Gijsje H. Koenderink, Ratnesh Lal, Douglas V. Laurents, Chi Le Lan Pham, Harry LeVine, Dusan Losic, David G. Lynn, Kirsten G. Malmos, Lisandra L. Martin, Adam I. Mechler, Anil K. Mehta, Derya Meral, Nathaniel G.N. Milton, Yee-Foong Mok, Ludmilla A. Morozova-Roche, Víctor Mosquera, Samrat Mukhopadhyay, Mentor Mulaj, Martin Muschol, Niels Chr Nielsen, R. Nilsson, Georg Nübling, Ruth Nussinov, Daniel E. Otzen, Tiago Fleming Outeiro, Jan Skov Pedersen, Jesper Søndergaard Pedersen, K. Peter, Dorothea Pinotsi, Meng Qin, Srinivasan Ramachandran, Agata Rekas, Annalisa Relini, Jean-Christophe Rochet, Sophie Rothhämel, Nikita Rudinskiy, Markus Sauer, Gabriele S. Kaminski Schierle, Michael Schleeger, Bettina Schmid, David H. Small, Anne Søndergaard, Mirco Sorci, Tara L. Spires-Jones, Marcel Stenvang, Martin Stöckl, Katrin Strecker, Vinod Subramaniam, Anna S.P. Svane, Kim K.M. Sweers, Pablo Taboada, Hideki Taguchi, Chai Lean Teoh, David C. Thorn, Kiyotaka Tokuraku, Robert Tycko, Brigita Urbanc, Vladimir N. Uversky, Corianne C. van den Akker, Michele Vendruscolo, Anna von Mikecz, Vladana Vukojević, Wei Wang, Katrin Weise, Roland Winter, Jessica W. Wu, Wei-Feng Xue, Kiran Yanamandra, Daniel Ysselstein, Eva Žerovnik, and Dawei Zou

Published
2014
Full Text
View/download PDF

29. Polymorphism in Casein Protein Aggregation and Amyloid Fibril Formation

Author

John A. Carver, David C. Thorn, and Heath Ecroyd

Subjects
Biochemistry, Polymorphism (materials science), Transmission electron microscopy, law, Chemistry, Casein, Protein folding, Nuclear magnetic resonance spectroscopy, Protein aggregation, Electron microscope, Micelle, law.invention
Abstract

Caseins are a diverse group of proteins present in milk. They exhibit a strong tendency to associate with themselves and with each other, generating a variety of oligomeric species and structures. In mammary tissue, this tendency leads to the synthesis and secretion in milk of the casein micelle, the primary functional state of caseins. In the absence of their micellar counterparts, at least two of the four bovine caseins, κ- and α s2 , preferentially form rope-like amyloid fibrils which themselves display a considerable degree of polymorphism. The heterogeneity of casein assemblies, along with the intrinsic flexibility and dynamism of their polypeptide chains, preclude detailed characterization by high-resolution techniques such as X-ray crystallography and NMR spectroscopy, while small-angle X-ray and neutron-scattering techniques provide limited information without recourse to modeling. In this chapter we describe the use of transmission electron microscopy and complementary techniques to examine and differentiate between casein assemblies formed under various conditions, with particular focus on the formation of κ- and α s2 -casein amyloid fibrils. The ribbons, loops, spheres, rods and other structures observed highlight the polymorphism in casein fibril formation and aggregation in general, and the utility of bio-nanoimaging techniques, such as electron microscopy, for the characterization of aggregation-prone, misfolded proteins.

Published
2014
Full Text
View/download PDF

30. Amyloid fibrils from readily available sources: milk casein and lens crystallin proteins

Author

Heath, Ecroyd, Megan, Garvey, David C, Thorn, Juliet A, Gerrard, and John A, Carver

Subjects
Amyloid, Caseins, Chromatography, Ion Exchange, Crystallins, Methylation, Solutions, Dithiothreitol, Milk, Reducing Agents, Chromatography, Gel, Animals, Cattle, Protein Multimerization, Oxidation-Reduction
Abstract

Amyloid fibrils are a highly ordered and robust aggregated form of protein structure in which the protein components are arranged in long fibrillar arrays comprised of β-sheet. Because of these properties, along with their biocompatibility, amyloid fibrils have attracted much research attention as bionanomaterials, for example as template structures (in some cases following modification) that can be used as biosensors, encapsulators, and biomimetic materials. To use amyloid fibrils for such a range of applications will require them to be obtained relatively easily in large quantities. In this chapter, we describe methods for isolating crystallin and casein proteins from readily available sources that contain abundant protein, i.e., the eye lens and milk, respectively, and the subsequent conversion of these proteins into amyloid fibrils.

Published
2013

31. Amyloid Fibrils from Readily Available Sources: Milk Casein and Lens Crystallin Proteins

Author

Juliet A. Gerrard, David C. Thorn, John A. Carver, Heath Ecroyd, and Megan Garvey

Subjects
Lens protein, medicine.anatomical_structure, Protein structure, Biochemistry, Amyloid, Chemistry, Crystallin, Casein, Lens (anatomy), medicine, macromolecular substances, Protein aggregation, Fibril
Abstract

Amyloid fibrils are a highly ordered and robust aggregated form of protein structure in which the protein components are arranged in long fibrillar arrays comprised of β-sheet. Because of these properties, along with their biocompatibility, amyloid fibrils have attracted much research attention as bionanomaterials, for example as template structures (in some cases following modification) that can be used as biosensors, encapsulators, and biomimetic materials. To use amyloid fibrils for such a range of applications will require them to be obtained relatively easily in large quantities. In this chapter, we describe methods for isolating crystallin and casein proteins from readily available sources that contain abundant protein, i.e., the eye lens and milk, respectively, and the subsequent conversion of these proteins into amyloid fibrils.

Published
2013
Full Text
View/download PDF

32. The chaperone action of bovine milk αS1- and αS2-caseins and their associated form αS-casein

Author

John A. Carver, David C. Thorn, Teresa M. Treweek, and William E. Price

Subjects
animal structures, Hot Temperature, Biophysics, Biochemistry, Heat shock protein, Casein, Animals, HSP70 Heat-Shock Proteins, Molecular Biology, chemistry.chemical_classification, biology, Clusterin, Caseins, Enzyme assay, Hsp70, Heat-Shock Proteins, Small, Enzyme, Milk, chemistry, Chaperone (protein), Hsp33, biology.protein, Cattle, Oxidation-Reduction
Abstract

α(S)-Casein, the major milk protein, comprises α(S1)- and α(S2)-casein and acts as a molecular chaperone, stabilizing an array of stressed target proteins against precipitation. Here, we report that α(S)-casein acts in a similar manner to the unrelated small heat-shock proteins (sHsps) and clusterin in that it does not preserve the activity of stressed target enzymes. However, in contrast to sHsps and clusterin, α-casein does not bind target proteins in a state that facilitates refolding by Hsp70. α(S)-Casein was also separated into α- and α-casein, and the chaperone abilities of each of these proteins were assessed with amorphously aggregating and fibril-forming target proteins. Under reduction stress, all α-casein species exhibited similar chaperone ability, whereas under heat stress, α-casein was a poorer chaperone. Conversely, α(S2)-casein was less effective at preventing fibril formation by modified κ-casein, whereas α- and α(S1)-casein were comparably potent inhibitors. In the presence of added salt and heat stress, α(S1)-, α- and α(S)-casein were all significantly less effective. We conclude that α(S1)- and α-casein stabilise each other to facilitate optimal chaperone activity of α(S)-casein. This work highlights the interdependency of casein proteins for their structural stability.

Published
2011

33. Amyloid fibril formation by bovine milk alpha s2-casein occurs under physiological conditions yet is prevented by its natural counterpart, alpha s1-casein

Author

David C. Thorn, Stephen Poon, Margaret Sunde, John A. Carver, and Heath Ecroyd

Subjects
Circular dichroism, Amyloid, animal structures, Ultraviolet Rays, Alpha (ethology), macromolecular substances, Fibril, Biochemistry, Dithiothreitol, chemistry.chemical_compound, Microscopy, Electron, Transmission, X-Ray Diffraction, Casein, Animals, Benzothiazoles, Chemistry, Circular Dichroism, Temperature, Caseins, Hydrogen-Ion Concentration, Chromatography, Ion Exchange, In vitro, Thiazoles, Thioflavin, Cattle, Female, Oxidation-Reduction
Abstract

The calcified proteinaceous deposits, or corpora amylacea, of bovine mammary tissue often comprise a network of amyloid fibrils, the origins of which have not been fully elucidated. Here, we demonstrate by transmission electron microscopy, dye binding assays, and X-ray fiber diffraction that bovine milk alpha s2-casein, a protein synthesized and secreted by mammary epithelial cells, readily forms fibrils in vitro. As a component of whole alpha s-casein, alpha s2-casein was separated from alpha s1-casein under nonreducing conditions via cation-exchange chromatography. Upon incubation at neutral pH and 37 degrees C, the spherical particles typical of alpha s2-casein rapidly converted to twisted, ribbon-like fibrils approximately 12 nm in diameter, which occasionally formed loop structures. Despite their irregular morphology, these fibrils possessed a beta-sheet core structure and the ability to bind amyloidophilic dyes such as thioflavin T. Fibril formation was optimal at pH 6.5-6.7 and was promoted by higher incubation temperatures. Interestingly, the protein appeared to be less prone to fibril formation upon disulfide bond reduction with dithiothreitol. Thus, alpha s2-casein is particularly susceptible to fibril formation under physiological conditions. However, our findings indicate that alpha s2-casein fibril formation is potently inhibited by its natural counterpart, alpha s1-casein, while is only partially inhibited by beta-casein. These findings highlight the inherent propensity of casein proteins to form amyloid fibrils and the importance of casein-casein interactions in preventing such fibril formation in vivo.

Published
2008

34. Amyloid fibril formation by bovine milk kappa-casein and its inhibition by the molecular chaperones alphaS- and beta-casein

Author

David C. Thorn, Agata Rekas, Sarah Meehan, Sally L. Gras, Christopher M. Dobson, Mark R Wilson, Margaret Sunde, Cait E. MacPhee, and John A. Carver

Subjects
Amyloid, animal structures, macromolecular substances, Protein aggregation, Fibril, Biochemistry, Dithiothreitol, Anilino Naphthalenesulfonates, chemistry.chemical_compound, Microscopy, Electron, Transmission, X-Ray Diffraction, Heat shock protein, Casein, Animals, Denaturation (biochemistry), Benzothiazoles, Mercaptoethanol, Temperature, Caseins, Serum Albumin, Bovine, Milk Proteins, In vitro, Thiazoles, Spectrometry, Fluorescence, chemistry, Models, Chemical, Thioflavin, Cattle, Oxidation-Reduction, Molecular Chaperones
Abstract

Caseins are a unique and diverse group of proteins present in bovine milk. While their function is presumed to be primarily nutritional, caseins have a remarkable ability to stabilize proteins, i.e., to inhibit protein aggregation and precipitation, that is comparable to molecular chaperones of the small heat-shock protein (sHsp) family. Additionally, sHsps have been shown to inhibit the formation of amyloid fibrils. This study investigated (i) the fibril-forming propensities of casein proteins and their mixture, sodium caseinate, and (ii) the ability of caseins to prevent in vitro fibril formation by kappa-casein. Transmission electron microscopy (TEM) and X-ray fiber diffraction data demonstrated that kappa-casein readily forms amyloid fibrils at 37 degrees C particularly following reduction of its disulfide bonds. The time-dependent increase in thioflavin T fluorescence observed for reduced and nonreduced kappa-casein at 37 degrees C was suppressed by stoichiometric amounts of alphaS- and beta-casein and by the hydrophobic dye 8-anilino-1-naphthalene sulfonate; the inhibition of kappa-casein fibril formation under these conditions was verified by TEM. Our findings suggest that alphaS- and beta-casein are potent inhibitors of kappa-casein fibril formation and may prevent large-scale fibril formation in vivo. Casein proteins may therefore play a preventative role in the development of corpora amylacea, a disorder associated with the accumulation of amyloid deposits in mammary tissue.

Published
2005

35. Small heat-shock proteins and clusterin: intra- and extracellular molecular chaperones with a common mechanism of action and function?

Author

Mark R. Wilson, David C. Thorn, John A. Carver, and Agata Rekas

Subjects
Protein Folding, Protein Conformation, Protein subunit, Clinical Biochemistry, Protein aggregation, Biochemistry, Models, Biological, Protein structure, Genetics, Animals, Chemical Precipitation, Humans, Tissue Distribution, Molecular Biology, Heat-Shock Proteins, Glycoproteins, biology, Clusterin, Cell Biology, Cell biology, Molecular Weight, Chaperone (protein), biology.protein, Unfolded protein response, Protein folding, Chemical chaperone, Molecular Chaperones, Protein Binding
Abstract

Small heat-shock proteins (sHsps) and clusterin are molecular chaperones that share many functional similarities despite their lack of significant sequence similarity. These functional similarities, and some differences, are discussed. sHsps are ubiquitous intracellular proteins whereas clusterin is generally found extracellularly. Both chaperones potently prevent the amorphous aggregation and precipitation of target proteins under stress conditions such as elevated temperature, reduction and oxidation. In doing so, they act on the slow, off-folding protein pathway. The conformational dynamism and aggregated state of both proteins may be crucial for their chaperone function. Subunit exchange is likely to be important in regulating chaperone action; the dissociated form of the protein is probably the chaperone-active species rather than the aggregated state. They both exert their chaperone action without the need for hydrolysis of ATP and have little ability to refold target proteins. Increased expression of sHsps and clusterin accompanies a range of diseases that arise from protein misfolding and deposition of highly structured protein aggregates known as amyloid fibrils, e.g., Alzheimer's, Creutzfeldt-Jakob and Parkinson's diseases. The interaction of sHsps and clusterin with fibril-forming species is discussed along with their ability to prevent fibril formation.

Published
2004

37. The Land Racket, The Real Costs of Property Speculation

Author

Leonie Sandercock, Sheila Shaver, Leslie Kilmartin, David C. Thorn, and Hal Kendig

Subjects
Organizational Behavior and Human Resource Management, History, Property (philosophy), Sociology and Political Science, Land use, Economy, Inner city, Urban planning, Industrial relations, Racket, Post war, Speculation, computer, computer.programming_language
Published
1982
Full Text
View/download PDF

Catalog

Books, media, physical & digital resources
See catalog results