Kawasaki Kazuhiko, Suzuki Tohru, Weiss Kenneth M
Department of Anthropology, 409 Carpenter Building, Pennsylvania State University, University Park, PA 16802, USA.
Proc Natl Acad Sci U S A. 2004 Aug 3;101(31):11356-61. doi: 10.1073/pnas.0404279101. Epub 2004 Jul 22.
Mineralized tissue is vital to many characteristic adaptive phenotypes in vertebrates. Three primary tissues, enamel (enameloid), dentin, and bone, are found in the body armor of ancient agnathans and mammalian teeth, suggesting that these two organs are homologous. Mammalian enamel forms on enamel-specific proteins such as amelogenin, whereas dentin and bone form on collagen and many acidic proteins, such as SPP1, coordinately regulate their mineralization. We previously reported that genes for three major enamel matrix proteins, five proteins necessary for dentin and bone formation, and milk caseins and salivary proteins arose from a single ancestor by tandem gene duplications and form the secretory calcium-binding phosphoprotein (SCPP) family. Gene structure and protein characteristics show that SCPP genes arose from the 5' region of ancestral sparcl1 (SPARC-like 1). Phylogenetic analysis on SPARC and SPARCL1 suggests that the SCPP genes arose after the divergence of cartilaginous fish and bony fish, implying that early vertebrate mineralization did not use SCPPs and that SPARC may be critical for initial mineralization. Consistent with this inference, we identified SPP1 in a teleost genome but failed to find any genes orthologous to mammalian enamel proteins. Based on these observations, we suggest a scenario for the evolution of vertebrate tissue mineralization, in which body armor initially formed on dermal collagen, which acted as a reinforcement of dermis. We also suggest that mammalian enamel is distinct from fish enameloid. Their similar nature as a hard structural overlay on exoskeleton and teeth is because of convergent evolution.
矿化组织对于脊椎动物许多典型的适应性表型至关重要。在古代无颌类动物的体甲和哺乳动物的牙齿中发现了三种主要组织,即牙釉质(类牙釉质)、牙本质和骨骼,这表明这两个器官是同源的。哺乳动物的牙釉质由牙釉蛋白等牙釉质特异性蛋白形成,而牙本质和骨骼则由胶原蛋白和许多酸性蛋白(如SPP1)形成,这些蛋白协同调节它们的矿化。我们之前报道过,三种主要牙釉质基质蛋白、牙本质和骨骼形成所需的五种蛋白以及乳清蛋白和唾液蛋白的基因通过串联基因复制从一个共同祖先演化而来,形成了分泌型钙结合磷蛋白(SCPP)家族。基因结构和蛋白质特征表明,SCPP基因起源于祖先sparcl1(类SPARC 1)的5'区域。对SPARC和SPARCL1的系统发育分析表明,SCPP基因在软骨鱼和硬骨鱼分化之后出现,这意味着早期脊椎动物的矿化并不使用SCPPs,并且SPARC可能对初始矿化至关重要。与这一推断一致,我们在硬骨鱼基因组中鉴定出了SPP1,但未能找到与哺乳动物牙釉质蛋白直系同源的任何基因。基于这些观察结果,我们提出了一个脊椎动物组织矿化的演化场景,其中体甲最初在真皮胶原蛋白上形成,起到强化真皮的作用。我们还认为哺乳动物的牙釉质与鱼类的类牙釉质不同。它们作为外骨骼和牙齿上坚硬结构覆盖物的相似性质是趋同进化导致的。