Ontogeny of the 38K epsilon-polypeptide during lens development of the duck Anas platyrhynchos

Tau-crystallin/alpha-enolase: one gene encodes both an enzyme and a lens structural protein

tau-Crystallin has been a major component of the cellular lenses of species throughout vertebrate evolution, from lamprey to birds. Immunofluorescence analysis of the embryonic turtle lens, using antiserum to lamprey tau-crystallin showed that the protein is expressed throughout embryogenesis and is present at high concentrations in all parts of the lens. Partial peptide sequence for the isolated turtle protein and deduced sequences for several lamprey peptides all revealed a close similarity to the glycolytic enzyme enolase (E.C. 4.2.1.11). A full-sized cDNA for putative duck tau-crystallin was obtained and sequenced, confirming the close relationship with alpha-enolase. Southern blot analysis showed that the duck genome contains a single alpha-enolase gene, while Northern blot analysis showed that the message for tau-crystallin/alpha-enolase is present in embryonic duck lens at 25 times the abundance found in liver. tau-Crystallin possesses enolase activity, but the activity is greatly reduced, probably because of age-related posttranslational modification. It thus appears that a highly conserved, important glycolytic enzyme has been used as a structural component of lens since the start of vertebrate evolution. Apparently the enzyme has not been recruited for its catalytic activity but for some distinct structural property. tau-Crystallin/alpha-enolase is an example of a multifunctional protein playing two very different roles in evolution but encoded by a single gene.

The enzyme lactate dehydrogenase as a structural protein in avian and crocodilian lenses

The major components of mammalian lenses are tissue-specific, soluble proteins, the alpha-, beta- and gamma-crystallins. The lenses of other vertebrate classes often contain other major proteins, notably delta-crystallin in birds and reptiles. A fourth distinct type, described as epsilon-crystallin, is prominent in many bird and crocodile lenses. Here we show that epsilon-crystallin is an active glycolytic enzyme, lactate dehydrogenase (LDH) (EC 1.1.1.27) and that duck epsilon-crystallin appears to be identical to duck LDH-B4. LDH is a normal metabolic component in other lenses, but in duck is present in amounts far exceeding the requirements of any likely catalytic role. It appears that an active enzyme has been recruited, unchanged, to an extra role as a structural protein in the lens without gene duplication and sequence divergence. This surprising discovery raises the possibility that other crystallins may similarly be enzymes expressed at high levels in lens as structural proteins.

Ontogeny of the 35K epsilon crystallin during Rana temporaria lens development

Epsilon is a recently described eye lens protein from Rana temporaria, an anuran amphibian. It is oligomeric with a subunit M.W. of 35K. The cDNA coding for 35K E- in frog lens does not show any homology with cDNA's coding for alpha-, beta-, gamma-, and delta-crystallins. Immunologically, it also does not react with antibodies directed against alpha-, beta-, and gamma-crystallins. The ontogeny of this 35K E-protein has been investigated in R. temporaria lens development by the indirect immunofluorescence staining method with an antibody specific for the 35K E-protein. The purity of the isolated 35K protein and the specificity of the antibody were controlled by Tris-SDS gel electrophoresis and immuno-blotting, respectively. The first positive immunofluorescence reaction was observed in the inner cell wall of a stage V lens. In the external layer/epithelium the reaction was first detected in a single cell of a stage VII lens. Additional positive cells in the external layer/epithelium were detected at an early state VIII and the reaction appeared to be patchy. This type of patchy reaction was also observed in the epithelium of froglet (sub-adult) eye lens.