Your search keyword '"Michelle Yu Sung, Hooi"' showing total 9 results

1. AOVSM Symposia Abstracts

Author

Roger Jw Truscott, Michelle Yu Sung Hooi, Michael G. Friedrich, and Brian Lyons

Subjects

Ophthalmology, Pediatrics, medicine.medical_specialty, business.industry, Medicine, business, Age-related cataract

Published

2013

2. Age-dependent deamidation of glutamine residues in human γS crystallin: Deamidation and unstructured regions

Author

Roger J.W. Truscott, Mark J. Raftery, and Michelle Yu Sung Hooi

Subjects

Glutamine, Lens protein, A-site, Protein structure, Biochemistry, Crystallin, Age dependent, sense organs, Biology, Deamidation, Molecular Biology, Peptide sequence

Abstract

Human aging is associated with the deterioration of long-lived proteins. Gradual cumulative modifications to the life-long proteins of the lens may ultimately be responsible for the pronounced alterations to the optical and physical properties that characterize lenses from older people. γS crystallin, a major human lens protein, is known to undergo several age-dependent changes. Using proteomic techniques, a site of deamidation involving glutamine 92 has been characterized and its time course established. The proportion of deamidation increased from birth to teen-age years and then plateaud. Deamidation at this site increased again in the eighth decade of life. There was no significant difference in the extent of deamidation between cataract and age-matched normal lenses. Gln92 is located in the linker region between the two domains, and the introduction of a negative charge at this site may alter the interaction between the two regions of the protein. Gln170, which is located in another unstructured part of γS crystallin, showed a similar deamidation profile to that of Gln92. As the other Gln residues in β-sheet regions of γS crystallin appear to remain as amides, modification of Gln92 and Gln170 thus conforms to a pattern whereby deamidation is localized to the unstructured regions of long-lived proteins.

Published

2012

3. Racemisation and human cataract. d-Ser, d-Asp/Asn and d-Thr are higher in the lifelong proteins of cataract lenses than in age-matched normal lenses

Author

Michelle Yu Sung Hooi, Roger J.W. Truscott, Hooi, Michelle Yu Sung, and Truscott, Roger JW

Subjects

Adult, Aging, genetic structures, human lens, Sus scrofa, Polypeptide chain, In Vitro Techniques, racemisation, Article, Cataract, law.invention, Crystallin, law, Lens, Crystalline, Animals, Humans, Denaturation (biochemistry), Amino Acids, Amino acid content, Aged, Aged, 80 and over, chemistry.chemical_classification, posttranslational modification, Chemistry, temperature, General Medicine, Middle Aged, Crystallins, eye diseases, Amino acid, Prolonged exposure, Lens (optics), Biochemistry, sense organs, Geriatrics and Gerontology, Age-related cataract, age-related cataract, blindness

Abstract

Several amino acids were found to undergo progressive age-dependent racemisation in the lifelong proteins of normal human lenses. The two most highly racemised were Ser and Asx. By age 70, 4.5% of all Ser residues had been racemised, along with >9% of Asx residues. Such a high level of inversion, equivalent to between 2 and 3 d - amino acids per polypeptide chain, is likely to induce significant denaturation of the crystallins in aged lenses. Thr, Glx and Phe underwent age-dependent racemisation to a smaller degree. In model experiments, d - amino acid content could be increased simply by exposing intact lenses to elevated temperature. In cataract lenses, the extent of racemisation of Ser, Asx and Thr residues was significantly greater than for age-matched normal lenses. This was true, even for cataract lenses removed from patients at the earliest ages where age-related cataract is observed clinically. Racemisation of amino acids in crystallins may arise due to prolonged exposure of these proteins to ocular temperatures and increased levels of racemisation may play a significant role in the opacification of human lenses Refereed/Peer-reviewed

Published

2010

4. Interconversion of the peptide isoforms of aspartate: Stability of isoaspartates

Author

Mark J. Raftery, Michelle Yu Sung Hooi, Roger J.W. Truscott, Hooi, Michelle Y.S., Raftery, Mark J, and Truscott, Roger J.W.

Subjects

Aging, Hot Temperature, Time Factors, Alpha-Crystallin A Chain, Peptide, alpha-Crystallin A Chain, racemisation, Protein Structure, Secondary, Substrate Specificity, Isoaspartate, Crystallin, Protein D-Aspartate-L-Isoaspartate Methyltransferase, Aspartic acid, medicine, Humans, Protein Isoforms, Trypsin, Isoaspartic Acid, Chromatography, High Pressure Liquid, chemistry.chemical_classification, Aspartic Acid, biology, Chemistry, aspartate isoforms, isoaspartic acid, Hydrogen-Ion Concentration, Biochemistry, age, Chaperone (protein), biology.protein, Peptides, protein isoaspartate methyl transferase, Developmental Biology, medicine.drug

Abstract

A common modification of human long-lived proteins is spontaneous isomerisation of aspartate residues, and its biological importance can be inferred from the ubiquitous presence of protein isoaspartate methyl transferase (PIMT), that repairs this damage. Cyclisation of l-Asp residues yields four isomers: l-Asp, l-isoAsp, d-Asp and d-isoAsp, however little is known about their rate of formation or interconversion. This is important because PIMT is inactive towards d-isoAsp. Peptides containing the four Asp isoforms corresponding to a susceptible site (Asp 151) in the chaperone, αA-crystallin, were examined for their interconversion at pH 7. d-Asp formed from l-Asp readily, whereas l-isoAsp was not detected until significantly later. d-isoAsp formed very slowly, with just 1% present after 8 days at 60 °C. These findings can be used to rationalise the substrate specificity of PIMT. In addition, both the d-isoAsp and l-isoAsp peptides were found to be remarkably stable, showing little conversion to other isomers, even after weeks of incubation. Therefore l-isoAsp and d-isoAsp appear to represent “terminal” stages of l-Asp modification. If PIMT is present, l-isoAsp may be reverted to l-Asp, however there appears to be no prospect of reversing d-isoAsp formation in aged proteins. Interestingly, Asp 151 in recombinant αA crystallin isomerised more rapidly than in the l-Asp peptide. Refereed/Peer-reviewed

Published

2013

5. Age-dependent racemization of serine residues in a human chaperone protein

Author

Mark J. Raftery, Roger J.W. Truscott, Michelle Yu Sung Hooi, Hooi, Michelle YS, Raftery, Mark J, and Truscott, Roger JW

Subjects

Models, Molecular, Aging, human lens, Alpha-Crystallin A Chain, Stereoisomerism, Biochemistry, alpha-Crystallin A Chain, Serine, protein denaturation, Heat shock protein, Lens, Crystalline, accelerated aging, Humans, Denaturation (biochemistry), Molecular Biology, Racemization, chemistry.chemical_classification, biology, Articles, eye diseases, Amino acid, chemistry, cataract, Chaperone (protein), biology.protein, sense organs, blindness

Abstract

Racemization is one of the most abundant modifications in long‐lived proteins. It has been proposed that the accumulation of such modifications over time could lead to changes in tissues and ultimately human age‐related diseases. Serine is one of the main amino acids involved in racemization; however, the site of D‐Ser in any aged protein has yet to be reported. In this study, racemization of two residues, Ser 59 and Ser 62, has been demonstrated in an unstructured region of the small heat shock protein, αA‐crystallin. αA‐crystallin is also the most abundant structural protein in the human lens. D‐Ser increased linearly with age in normal lenses, until it accounted for approximately 35% of the Ser at both sites by the age of 75 years. In agreement with a possible role in human age‐related disease, levels were significantly higher in cataract lenses. It is likely that such prevalent age‐related changes contribute to the denaturation of α‐crystallin, and therefore its ability to act as a chaperone. Racemization of amino acids, such as serine, in flexible regions of long‐lived proteins, could be associated with the development of human age‐related conditions such as cataract. Refereed/Peer-reviewed

Published

2012

6. Accelerated aging of Asp 58 in αA crystallin and human cataract formation

Author

Roger J.W. Truscott, Mark J. Raftery, Michelle Yu Sung Hooi, Hooi, Michelle YS, Raftery, Mark J, and Truscott, Roger John Willis

Subjects

Adult, medicine.medical_specialty, Aging, Spectrometry, Mass, Electrospray Ionization, genetic structures, Adolescent, Racemases and Epimerases, Cataract formation, racemisation, alpha-Crystallin A Chain, Cataract, protein denaturation, Cellular and Molecular Neuroscience, Young Adult, Crystallin, Heat shock protein, Lens, Crystalline, medicine, Humans, human age-related cataract, Child, Chromatography, High Pressure Liquid, Aged, chemistry.chemical_classification, Aged, 80 and over, posttranslational modification, Aspartic Acid, Isoaspartic Acid, Blindness, Chemistry, Infant, Newborn, Infant, Middle Aged, medicine.disease, Accelerated aging, Sensory Systems, eye diseases, Peptide Fragments, Surgery, Amino acid, Ophthalmology, Biochemistry, Child, Preschool, Posttranslational modification, sense organs, blindness

Abstract

Racemisation of amino acids is one of the most abundant modifications in long-lived proteins. In this study racemisation of Asp 58 in the small heat shock protein, αA crystallin, was investigated. In normal human lenses, levels of l-isoAsp, d-isoAsp and d-Asp increased with age, such that by age 70 they accounted for approximately half of the total Asp at this site. Levels of d-isoAsp were significantly higher in all cataract lenses than age-matched normal lenses. The introduction of d-isoAsp in αA crystallin could therefore be associated with the development of cataract. Its more rapid formation in cataract lenses may represent an example of accelerated protein aging leading to a human age-related disease. Refereed/Peer-reviewed

Published

2012

7. Age-dependent deamidation of glutamine residues in human γS crystallin: deamidation and unstructured regions

Author

Michelle Yu Sung, Hooi, Mark J, Raftery, and Roger John Willis, Truscott

Subjects

Adult, Aged, 80 and over, Models, Molecular, Aging, Adolescent, Glutamine, Infant, Newborn, Articles, Middle Aged, Amides, Cataract, Protein Structure, Secondary, Young Adult, Lens, Crystalline, Humans, sense organs, Amino Acid Sequence, gamma-Crystallins, Child

Abstract

Human aging is associated with the deterioration of long-lived proteins. Gradual cumulative modifications to the life-long proteins of the lens may ultimately be responsible for the pronounced alterations to the optical and physical properties that characterize lenses from older people. γS crystallin, a major human lens protein, is known to undergo several age-dependent changes. Using proteomic techniques, a site of deamidation involving glutamine 92 has been characterized and its time course established. The proportion of deamidation increased from birth to teen-age years and then plateaud. Deamidation at this site increased again in the eighth decade of life. There was no significant difference in the extent of deamidation between cataract and age-matched normal lenses. Gln92 is located in the linker region between the two domains, and the introduction of a negative charge at this site may alter the interaction between the two regions of the protein. Gln170, which is located in another unstructured part of γS crystallin, showed a similar deamidation profile to that of Gln92. As the other Gln residues in β-sheet regions of γS crystallin appear to remain as amides, modification of Gln92 and Gln170 thus conforms to a pattern whereby deamidation is localized to the unstructured regions of long-lived proteins.

Published

2012

8. Racemization of two proteins over our lifespan: Deamidation of asparagine 76 in yS crystallin is greater in cataract than in normal lenses across the age range

Author

Michelle Yu Sung Hooi, Mark J. Raftery, Roger J.W. Truscott, Hooi, Michelle Yu Sung, Raftery, Mark J, and Truscott, Roger John Willis

Subjects

Aging, genetic structures, Cataract formation, Cataract, Crystallin, Lens, Crystalline, Humans, Electrophoresis, Gel, Two-Dimensional, Denaturation (biochemistry), gamma-Crystallins, Asparagine, Deamidation, Racemization, Chromatography, High Pressure Liquid, Lens crystalline, Aged, Chemistry, Significant difference, Keywords, Articles, Middle Aged, eye diseases, Biochemistry, Spectrometry, Mass, Matrix-Assisted Laser Desorption-Ionization, sense organs

Abstract

PURPOSE. Long-lived proteins are widespread in man, yet little is known about the processes that affect their function over time,or their role in age-related diseases. METHODS. Racemization of two proteins from normal and cataract human lenses were compared with age using tryptic digestion and LC/mass spectrometry. Asp 151 in aA crystallin and Asn 76 in γS crystallin were studied. RESULTS. Age-dependent profiles for the two proteins from normal lenses were different. In neither protein did the modifications increase linearly with age. For aA crystallin, racemization occurred most rapidly during the first 15 years of life, with approximately half of L-Asp 151 converted to D-isoAsp, L-isoAsp, and D-Asp in a ratio of 3:1:0.5. Values then changed little. By contrast, racemization of Asn 76 in γS crystallin was slow until age 15, with isoAsp accounting for only 5%. Values remained relatively constant until age 40 when a linear increase(1%/year) took place. When cataract lenses were compared with age-matched normal lenses, there were marked differences in the time courses of the two crystallins. For aA crystallin, there was no significant difference in Asp 151 racemization between cataract and normal lenses. By contrast, in γS crystallin the degree of conversion of Asn 76 to isoAsp in cataract lenses was approximately double that of normals at every age. CONCLUSIONS. Modification of Asn and Asp over time may contribute to denaturation of proteins in the human lens. An accelerated rate of deamidation/racemization at selected sitesin proteins, such as γS crystallin, may contribute to cataractformation. Refereed/Peer-reviewed

Published

2012

9. Is protein methylation in the human lens a result of non-enzymatic methylation by S-adenosylmethionine?

Author

Joanne F. Jamie, Jasminka Mizdrak, Michelle Yu Sung Hooi, Roger J.W. Truscott, Larry L. David, Michael G. Friedrich, Michael J. Davies, Phillip A. Wilmarth, Brian Lyons, Truscott, Roger JW, Mizdrak, Jasminka, Friedrich, Michael G, Hooi, Michelle Y, Lyons, Brian, Jamie, Joanne F, Davies, Michael, Wilmarth, Phillip A, and David, Larry L

Subjects

Adult, Proteomics, Aging, S-Adenosylmethionine, Adolescent, Biology, Methylation, Mass Spectrometry, Article, beta-Crystallin A Chain, Lens protein, Cellular and Molecular Neuroscience, chemistry.chemical_compound, Young Adult, Crystallin, Lens, Crystalline, Protein methylation, medicine, Humans, Histidine, Cysteine, Protein Methyltransferases, Cysteine metabolism, Chromatography, High Pressure Liquid, Aged, Middle Aged, Trypsin, Molecular biology, Sensory Systems, Tissue Donors, eye diseases, lens protein, Ophthalmology, Biochemistry, chemistry, age, post-translational modification, sense organs, methylation, Protein Processing, Post-Translational, medicine.drug

Abstract

Since crystallins in the human lens do not turnover, they are susceptible to modification by reactive molecules over time. Methylation is a major post-translational lens modification, however the source of the methyl group is not known and the extent of modification across all crystallins has yet to be determined. Sites of methylation in human lens proteins were determined using HPLC/mass spectrometry following digestion with trypsin. The overall extent of protein methylation increased with age,and there was little difference in the extent of modification between soluble and insoluble crystallins.Several different cysteine and histidine residues in crystallins from adult lenses were found to bemethylated with one cysteine (Cys 110 in γD crystallin) at a level approaching 70%, however, methylation of crystallins was not detected in fetal or newborn lenses. S-adenosylmethionine (SAM) was quantified at significant (10e50 mM) levels in lenses, and in model experiments SAM reacted readily with N-α-tBoccysteineand N-α-tBoc-histidine, as well as βA3-crystallin. The pattern of lens protein methylation seen in the human lens was consistent with non-enzymatic alkylation. The in vitro data shows that SAM can actdirectly to methylate lens proteins and SAM was present in significant concentrations in human lens.Thus, non-enzymatic methylation of crystallins by SAM offers a possible explanation for this majorhuman lens modification. Refereed/Peer-reviewed

Published

2012