Ontogeny of Human Lens Crystallins (original) (raw)
proteins in ageing human lens
Bob Augusteyn
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new method for studying lens protein changes
Bob Augusteyn
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A change in the stoichiometry of assembly of bovine lens α-crystallin subunits in relation to cellular differentiation
John Papaconstantinou
Biochemical and Biophysical Research Communications, 1974
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A change in α-crystallin subunit composition in relation to cellular differentiation in adult bovine lens
John Papaconstantinou
Biochemical and Biophysical Research Communications, 1970
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Classification of Rat Lens Crystallins and Identification of Proteins Encoded by Rat Lens mRNA
Frans Ramaekers
European Journal of Biochemistry, 2005
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Age-related changes in normal and cataractous human lens crystallins, separated by fast-performance liquid chromatography
Maria JoãO Mota
Ophthalmic Research, 1994
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Correlated Changes in ?-Crystallin Synthesis and Ion Concentrations in the Embryonic Chick Lens: Summary, Current Experiments and Speculations
Raymond Jones
Annals of the New York Academy of Sciences, 1980
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Rat lens γ-crystallinsCharacterization of the six gene products and their spatial and temporal distribution resulting from differential synthesis
Roland Siezen
Journal of Molecular Biology - J MOL BIOL, 1988
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Lens differentiation and crystallin regulation: a chick model
Hasan Mahmud Reza
The International Journal of Developmental Biology, 2004
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Analysis of normal human fetal eye lens crystallins by high-performance liquid chromatography/mass spectrometry
Kaili Wu
Journal of Mass Spectrometry, 1995
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A comparative study of vertebrate eye lens crystallins using isoelectric focusing and densitometry
Dario Di Luca
Comparative biochemistry and physiology. B, Comparative biochemistry, 1993
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Induction of de novo synthesis of crystalline lenses in aphakic rabbits
Arlene Gwon
Experimental Eye Research, 1989
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Reliability of delta-crystallin as a marker for studies of chick lens induction
Judith Thorn
Differentiation, 1998
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Effect of aging on the water-soluble and water-insoluble protein pattern in normal human lens
P. Ringens
Experimental Eye Research, 1982
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A-Crystallin and B-Crystallin Reside in Separate Subcellular Compartments in the Developing Ocular Lens
Rajendra Kumar Gangalum
Journal of Biological Chemistry, 2012
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Physical-chemical studies on bovine eye lens proteins
Frank De Voeght
Experimental Eye Research, 1982
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Crystallins and their synthesis in human lens epithelial cells in tissue culture
Takaya Arita
Experimental Eye Research, 1988
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αA-Crystallin and αB-Crystallin Reside in Separate Subcellular Compartments in the Developing Ocular Lens
Rajendra Gangalum
2012
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Electrophoretic variation in low molecular weight lens crystallins from inbred strains of rats
Loren Skow
Biochemical Genetics, 1985
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Distribution of proteins across the porcine lens
Andrew Jobling
Clinical and Experimental Optometry, 1995
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Eye-lens proteins: The three-dimensional structure of β-crystallin predicted from monomeric γ-crystallin
William DeJong
FEBS Letters, 1981
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Differential synthesis and degradation of protein in the hereditary Philly mouse cataract
Peter F Kador
Experimental Eye Research, 1980
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Proteomic analysis of regenerated rabbit lenses reveal crystallin expression characteristic of adult rabbits
Pedro Gonzalez
Molecular vision, 2008
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MACROMOLECULAR STRUCTURE OF THE EYE LENS
Bob Augusteyn
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Primary sequence contribution to optical function of the eye lens
Jean-Christophe Nebel
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Primary sequence contribution to the optical function of the eye lens
Jean-Christophe Nebel
Scientific Reports, 2014
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Aging of the Human Crystalline Lens and Presbyopia
Ver Gence
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Ubiquitous Lens α-, β-, and γ-Crystallins Accumulate in Anuran Cornea as Corneal Crystallins
Rajeev Raman
Journal of Biological Chemistry, 2007
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pig lens proteins
Bob Augusteyn
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Lens Crystallin Modifications and Cataract in Transgenic Mice Overexpressing Acylpeptide Hydrolase
Murugesan Raju
Journal of Biological Chemistry, 2014
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refractive increments of lens proteins
Bob Augusteyn
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Kinetic Stability of Long-Lived Human Lens γ-Crystallins and Their Isolated Double Greek Key Domains
Melissa Kosinski-Collins
Biophysical Journal, 2019
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The Major in vivo Modifications of the Human Water-insoluble Lens Crystallins are Disulfide Bonds, Deamidation, Methionine Oxidation and Backbone Cleavage
Azeem As
Experimental Eye Research, 2000
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Radiocarbon dating of the human eye lens crystallines reveal proteins without carbon turnover throughout life
Christina Jacobsen
PLoS One, 2008
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A rabbit lens epithelial cell line supports expression of an exogenous crystallin gene characteristic of lens fiber cell differentiation
Susan Meakin
Experimental Eye Research, 1989
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