Macroscopic, microscopic, and immunofluorescent characterization of the Greek tortoise (Testudo graeca graeca) oropharyngeal floor with concern to its feed adaptation as a herbivorous land reptile
Mohamed A. M. Alsafy, Nermin K. A. El-sharnobey, Samir A. A. El-Gendy, Mohamed A. Abumandour, Samar M. Ez Elarab, Ahmed M. Rashwan, Basma G. Hanafy
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引用次数: 0
Abstract
The current investigation focuses on gross anatomy, light, and scanning electron microscopy (SEM) of the Testudo graeca oropharyngeal floor, with particular reference to the immunofluorescence technique to examine its tongue. The T. graeca oropharyngeal floor showed many anatomical structures: the lower rhamphotheca, paralingual ridge, lower alveolar ridge, tongue, laryngeal mound, and glottis. The lower rhamphotheca appeared as a V-shaped jaw line with a highly serrated edge and a median tomium (beak). SEM observations of the lingual apex and the lingual body showed rectangular and conical filiform papillae with porous surfaces and taste pores. Meanwhile, the lingual root had two wings that carried papillae with different shapes: dagger-shaped, conical, bifurcated, and leaf-like papillae, and these papillae lacked taste pores. The laryngeal mound had openings for the laryngeal mucus gland and its secretions. Light microscopy findings showed mucous glands in the propria submucosa and near the mucosal surface of the lingual apex. The lingual root had lingual papillae and two hyaline cartilaginous skeletons between skeletal muscles, and the lingual papillae were elongated filiform, rectangular filiform papillae, and fungiform papillae. The lamina propria constituted the core of the lingual papillae and the mucous gland, they had a positive reaction with the periodic acid schiff (PAS) reagent. The apical surface of the fungiform papillae had taste pores. Under immunofluorescence, the vimentin was detected in taste bud cells, and synaptophysin reacted to the taste buds and nerve bundles. The current study of the Greek tortoise oropharyngeal floor investigated its herbivorous eating habits using its serrated lower rhamphotheca, a large tongue with differently shaped papillae, and numerous mucous glands.
Research Highlights
The Greek tortoise (T. graeca graeca) oropharyngeal floor showed many anatomical structures: lower rhamphotheca, paralingual ridge, lower alveolar ridge, tongue, laryngeal mound, and glottis.
SEM and light microscopy observations of the tongue revealed varied types and shapes of lingual papillae with a porous surface on the tongue apex (rectangular or conical filiform papillae), on the tongue body (filiform and fungiform papillae), and on the tongue root (dagger-shaped, conical, bifurcated, and leaf-like papillae).
Light microscopy findings: the lamina propria constituted the core of the lingual papillae and had numerous mucous glands that had a slightly magenta-red color with PAS reagent.
The apical surface of the fungiform papillae had taste pores. Vimentin and synaptophysin gave a reaction to the taste buds.
希腊陆龟(Testudo graeca graeca)口咽底板的宏观、微观和免疫荧光特征,关注其作为草食性陆地爬行动物对饲料的适应性。
本次研究的重点是颚蟾口咽底部的大体解剖、光镜和扫描电子显微镜(SEM),尤其是采用免疫荧光技术检查其舌头。颚蟾口咽底显示出许多解剖结构:下齿状突、副齿状突、下齿槽突、舌、喉丘和声门。下齿龈呈 V 形,边缘呈高锯齿状,中间有一个喙。对舌尖和舌体的扫描电镜观察显示,舌乳头呈矩形和锥形丝状,表面多孔,并有味觉孔。同时,舌根有两翼,两翼的乳头形状各异:匕首形、锥形、分叉形和叶状乳头,这些乳头没有味孔。喉丘有喉粘液腺及其分泌物的开口。光学显微镜检查结果显示,固有粘膜下层和舌尖粘膜表面附近有粘液腺。舌根部有舌乳头和骨骼肌之间的两个透明软骨骨架,舌乳头有细长的丝状乳头、矩形丝状乳头和菌状乳头。固有层构成了舌乳头和粘液腺的核心,它们与周期性酸希夫(PAS)试剂呈阳性反应。菌状乳头的顶端表面有味觉孔。在免疫荧光下,味蕾细胞中检测到了波形蛋白,味蕾和神经束中检测到了突触素。目前对希腊陆龟口咽底的研究利用其锯齿状的下齿龈、具有不同形状乳头的大舌和大量粘液腺来调查其草食习性。研究亮点:希腊陆龟(T. graeca graeca)的口咽底板显示出许多解剖结构:下齿龈、副齿龈、下齿槽嵴、舌、喉丘和声门。对舌头的扫描电镜和光学显微镜观察发现,舌乳头的类型和形状各不相同,舌尖(矩形或锥形丝状乳头)、舌体(丝状和菌状乳头)和舌根(匕首状、锥形、分叉和叶状乳头)表面多孔。光学显微镜检查结果:固有层构成舌乳头的核心,有许多粘液腺体,用 PAS 试剂显微品红色。菌状乳头的顶端表面有味觉孔。波形蛋白和突触素对味蕾有反应。
期刊介绍:
Microscopy Research and Technique (MRT) publishes articles on all aspects of advanced microscopy original architecture and methodologies with applications in the biological, clinical, chemical, and materials sciences. Original basic and applied research as well as technical papers dealing with the various subsets of microscopy are encouraged. MRT is the right form for those developing new microscopy methods or using the microscope to answer key questions in basic and applied research.