• γ-crystallin
• mutation
• polymorphism
• cataract

Cataract is an opacification of the eye lens that frequently results in visual impairment or blindness during infancy and early childhood.¹ An estimated 200 000 children are blind with bilateral cataract world wide and 20 000-40 000 children with developmental cataract are born each year.² In the developed nations of Europe and Northern America, national surveillance or cross sectional studies suggest a prevalence of 1-4 cases per 10 000 children.^3–6 In southern India the prevalence is higher, at approximately 6.5 cases per 10 000 children⁷ and bilateral childhood cataract accounts for about 12% of all ocular disorders registered.⁸

The lens is a unique tissue as it is separated from the surrounding fluids by the lens capsule and there is life long persistence of its cells and their proteins. The β- and γ-crystallins were biochemically characterised as major lens proteins by Mörner⁹ over a century ago. They belong to a superfamily of proteins, which were considered for a long time to be present only in the lens. However, it has recently been reported that β- and γ-crystallin mRNA and protein are also present in other tissues, in particular in the retina, brain, and testis.^10–12

The common signature of all β- and γ-crystallins is the so called Greek key motif. Crystallography has shown that each of the β- and γ-crystallins is composed of two domains, each built up by two Greek key motifs. It is widely accepted that β/γ-crystallins evolved in two duplication steps from an ancestral gene coding for a protein folded like a Greek key. The γ-crystallin encoding genes (Cryg/CRYG genes) in all mammals consist of three exons: the first one codes only for three amino acids, and the subsequent two are responsible for two Greek key motifs each. …