Comparative microanatomical and histochemical biodistribution profiles of different types of mucins in the intestinal mucosa of some tetrapod representatives.

The microanatomical features of the intestinal tract mucosa layer in different species of tetrapoda vary according to the type of species, tissue, and function of the targeted cells. In the present study, we have evaluated the histological and histochemical variations of the intestinal tract in four species representing superclass tetrapoda. Bufo regularis (toad), Trachylepis quinquetaeniata (lizard), Columba livia domestica (pigeon) and Mus musculus (mouse) were used as representatives for amphibians, reptilians, avians and mammalians respectively. Histologically, the ileum's mucosal layer of the lower tetrapods (toad and lizard) was almost similar and consists of elongated finger-like shape villi lined with simple columnar epithelium and goblet cells. Similarly, the microanatomical features in ileum of higher tetrapod representatives (pigeon and mouse) were characterized by the presence of villi lined with simple columnar epithelium and scattered goblet cells as well as intestinal glands (crypts of Lieberkühn) at the bases of the intestinal villi. In the toad rectum, the mucosal layer was similar to that of the ileum but with shorter villi and more numerous goblet cells. However, the mucosal layer of the rectum in the lizard had low numbers of absorptive columnar epithelial cells with abundant goblet basal cells. Comparatively, the pigeon's rectal mucosa had almost a similar structure to that of ileum but in leaf-like shaped villi. Finally, the rectum of the mouse has narrow rectal pits, instead of villi, lined with goblet cells and absorptive epithelial cells. Histochemically, the ileum in the four studied tetrapod representatives showed varying biodistribution profiles of neutral, sulfated and carboxylated mucins. There are variations encountered in the intestinal brush border and goblet cells of villi in all species as well as the crypts of Lieberkühn in higher tetrapods. Also, the rectum of all tetrapod species showed weak to strong positive signals for the three types of mucins in the brush border and goblet cells of villi in all species and crypts of Lieberkühn in higher tetrapods as well. In addition, the brush border of toad's rectum was lacking sulfated mucins and that of the lizard did not have any type of mucins. The data of this study will contribute to understand the relationship between the microanatomical features and mucins biodistribution profiles in the mucosal layer of tetrapod intestinal tract and their functions.