Amelogenin: lessons from evolution

Summary enin plays a crucial role in enamel structure and mineralization, but the function of its various domains is far to be understood. Evolutionary analysis seems to be a promising way to approach structure/function relationships. In this paper, we review the knowledge of amelogenin with a particular focus on what we have learnt from evolution, and we bring new data on the origin and evolution of this molecule. mparison of amniote (reptiles and mammals) amelogenin sequences reveals that, in contrast to the well-conserved C- and N-terminal domains, the central region (most of exon 6) is highly variable. The evolutionary analysis indicates that it was created by repeated insertion of three amino acids (triplets ProXGlu or ProXX). In several mammalian lineages a new run of triplet insertions and deletions has occurred independently in a locus considered a hot spot of mutation for mammalian amelogenin. In lizard and snake amelogenin evolves rapidly. Sequence alignment reveals that several residues in the N- and C-terminal regions were kept unchanged during 250 million years (MY), proving their importance for amelogenin structure and function. This alignment permits a rapid validation of the amelogenin mutations in human. sequencing and gene mapping permitted to refine the amelogenin story, in relation to the common location (chromosome 4 in human) of several genes coding for dental proteins and SPARCL1, a SPARC (osteonectin) relative. Amelogenin shares a similar organisation with these genes and a blast search in databanks indicates a strong relationship between amelogenin, ameloblastin and enamelin. Taken together these data suggest that amelogenin could have originated from either ameloblastin or enamelin, themselves being created from SPARCL1, which itself originated from a SPARC duplication, 600 millions years ago.