牦牛和柴达木黄牛颈动脉体的组织微细结构比较

doi:10.16098/j.issn.0529-1356.2016.03.015

解剖学报 ›› 2016 ›› Issue (3) : 374-380. DOI: 10.16098/j.issn.0529-1356.2016.03.015

组织学胚胎学发育生物学

牦牛和柴达木黄牛颈动脉体的组织微细结构比较

常兰¹张寿¹ 雷乃虎¹ 马艳芳¹ 白振忠²沈明华¹ 格日力^2*

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Comparison of microstructures of the carotid body between yaks and chaidamu yellow cattles

CHANG Lan¹ZHANG Shou¹ LEI Nai-hu¹MA Yan-fang¹BAI Zhen-zhong² SHEN Ming-hua¹ GE Ri-li^2*

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摘要

目的比较牦牛和柴达木黄牛颈动脉体(CB)的组织微细结构特征。方法选择健康成年牦牛和柴达木黄牛各5头，采用组织学染色、免疫组织化学SP法和透射电子显微镜技术，观察CB的显微及超微结构特征，并运用显微体视学方法比较两种动物CB中Ⅰ型细胞(明细胞、暗细胞)、Ⅱ型细胞和血管的体积密度（Vv）、面密度（Sv）、比表面（δ）、面数密度（NA）。结果牦牛和柴达木黄牛CB均由实质和间质构成，实质由大量的圆形或椭圆形的小球密集组合而成，小球内有丰富的实质细胞。牦牛Ⅰ型细胞数量多于柴达木黄牛，但其胞质内含的线粒体和特有的电子致密核心囊泡(EDCV)相对小而多。柴达木黄牛小球之间的结缔组织及内含的间质细胞明显多于牦牛，而牦牛CB中血管数量多于柴达木黄牛，而且管腔较大。牦牛CB明细胞的Vv、Sv、NA显著大于柴达木黄牛 (P<0.01)；牦牛δ小于柴达木黄牛(P>0.05)。牦牛暗细胞的Vv、Sv显著小于柴达木黄牛(P<0.05)，两组中NA和δ差异不显著(P> 0.05)。两种动物CB中Ⅱ型细胞的Vv、Sv、NA、δ差异均不显著(P>0.05)。牦牛微血管的Vv、Sv、NA显著大于柴达木黄牛(P<0.01)，而δ显著小于柴达木黄牛(P<0.01)。结论牦牛CB形成了固有的组织细胞成分和血管网形态特征以增强对高原低氧环境的适应能力。

Abstract

Objective To compare the structural characteristics of the carotid body （CB） between yaks and chaidamu yellow cattles. Methods Health adult yaks (n=5) and chaidamu yellow cattles (n =5) were used in this study. The microstructure and ultrastructure of CB were observed by histologial, immunohistochemical SP methods and transmission electron microscopy techniques. The volume density(Vv), surface density(Sv), numerical density on area(NA) and specific surface(δ) of type Ⅰ cells(light and dark) and type Ⅱ cells and microvessels of carotid body were compared by light microscopy and microstereology between yaks and chaidamu yellow cattles. Results The CBs of yak and chaidamu yellow cattle were composed of parenchyma and mesenchyme. There were many round or oval gloubs with rich parenchymal cells. There were more type Ⅰ cells in yaks than in chaidamu yellow cattles, but there were less and smaller mitochondria and electron densecored vesicles(EDCV) of the type I cells in yaks than in chaidamu yellow cattles. The connective tissue among gloubs and interstitial cells in chaidamu yellow cattles were significantly more than yaks, but there were more rich capillaries in mesenchyme and bigger vascular lumen in yaks than in chaidamu yellow cattles. The Vv、Sv、NAof CB light cells in yaks were significantly greater than that in chaidamu yellow cattles (P<0.01),while δ of CB light cells in yaks was less than in chaidamu yellow cattles(P>0.05). The Vv、Sv of CB dark cells in yaks were significantly less than in chaidamu yellow cattles (P<0.05), and there was no significant difference of NAand δ between yaks and chaidamu yellow cattles(P>0.05). In type Ⅱ cells, there was no significant difference in Vv、Sv、NA、δ between two groups (P>0.05). The Vv、Sv、NA of the CB microvessels in yaks were obviously greater than that in chaidamu yellow cattles (P<0.01), while δ in yaks CB was significantly less than in chaidamu yellow cattle (P<0.01). Conclusion The inheret tissue cell composition and vascular net of yak CB are formed to enhance the adaptability to plateau hypoxic environment.

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常兰张寿雷乃虎马艳芳白振忠沈明华格日力*. 牦牛和柴达木黄牛颈动脉体的组织微细结构比较[J]. 解剖学报. 2016(3): 374-380 https://doi.org/10.16098/j.issn.0529-1356.2016.03.015

CHANG Lan ZHANG Shou LEI Nai-hu MA Yan-fang BAI Zhen-zhong SHEN Ming-hua GE Ri-li*. Comparison of microstructures of the carotid body between yaks and chaidamu yellow cattles[J]. Acta Anatomica Sinica. 2016(3): 374-380 https://doi.org/10.16098/j.issn.0529-1356.2016.03.015

参考文献

［1］Bu FZh, Tu DT, Cheng ZhM, et al. Light microscopic observation study of carotid bodies at human［J］. Chinese Journal of Pathophysiology, 1999, 15(3):287-293.(in Chinese)
卜凤珍,屠道同, 程仲谋,等. 高原成人颈动脉体的光镜观察和体视学研究［J］. 中国病理生理杂志,1999,15(3):287-293.
［2］Wang X, Zhang XJ, Li X, et al. Expression of interleukin-1β and its type I receptor mRNA in rat carotid body［J］. Acta Anatomica Sinica, 2006, 37(6):677-680.(in Chinese)
王曦, 张西京, 李鑫, 等. 白细胞介素-1β及其I型受体mRNA在大鼠颈动脉体中的表达［J］.解剖学报, 2006,37(6):677-680.
［3］Machiko S, Eric WK, Luis EP. Carotid chemoreceptor development in mice［J］. Resp Physiol Neurobi, 2013, 185(1):20-29.
［4］Ding YF, Li YL, Schultz HD. Role of blood flow in carotid body chemoreflex function in heart failure［J］. J Physiol, 2011, 589(1):245-258.
［5］Najafi G, Soltanalinejad F, Hasanzadeh H. A preliminary anatomical study on carotid body of Makouei sheep［J］. Vet Res Forum, 2013, 4(2):129-131.
［6］Zheng FSh. Solid Metrology of Cell Morphous ［M］. Beijing:Beijing Medical University, Peking Union Medical College United Publishing House,1990:19-86. (in Chinese)
郑富盛.细胞形态立体计量学［M］.北京:北京医科大学中国协和医科大学联合出版社,1990:19-86.
［7］Dhillon DP. The enlarged carotid body of the chronically hypoxia and hypercapnic rat: morphometric analysis［J］. Quart J Exper Physjol,1984, 69(2):301-302. 
［8］Vinhaes ENG, Dolhnikoff M, Saldiva PHN. Morphological changes of carotid bodies in acute respiratory distress syndrome: a morphometric study in humans［J］. Braz J Med Biol Res, 2002, 35(10): 1119-1125.
［9］Tu DT, Bu FZh, Cheng ZhM. A morphologic study on human carotid bodies at high altitue［J］. Journal of High Altitude Medicine,1992, 2(2):20-23. (in Chinese)
屠道同,卜风珍,程仲谋.高原人的颈动脉体形态学研究［J］. 高原医学杂志,1992, 2(2):20-23.
［10］Smith DP, Heath D, Williams D, et al. The earliest histopathological response to hypobaric hypoxia in rabbits in the refugio Torino(3370 m) on Monte Bianco［J］. J Pathol, 1993, 170（4）: 485-491. 
［11］Luengo AP, Granero SG, Durán R, et al. An O2-sensitive glomus cell-stem cell synapse induces carotid body growth in chronic hypoxia［J］. Cell, 2014, 156(1-2):291-303.
［12］Pardal R, Sáenz PO, Durán R, et al. Glia-like setm cells sustain physiologic neurogenesis in the adult mammalian carotid body［J］. Cell, 2007,131(2):364-377.
［13］Clarke JA, Daly MDB, Ead HW. Dimensions and volume of the carotid body in the adult cat and their relation to the specific blood flow through the organ. A histological and morphometric study［J］. Acta Anat (Basel), 1986,126(2):84-86.
［14］Yang FX, Xue DH, Zhu JG. A stereological study of the carotid bodies exposed to high-altitued hypoxid［J］. Journal of Qinghai Medical, 1993,14(3,4):145-151.(in Chinese)
杨风乡,薛大海，朱建刚.高原低氧大鼠颈动脉体的体视学研究［J］.青海医学院学报,1993, 14(3,4):145-151.
［15］Keith J，Buckler. TASK channels in arterial chemoreceptors and their role in oxygen and acid sensing［J］. Eur J Physiol,2015,467(5):1013-1025.
［16］McGregor KH, Gil J, Lahiri S. A morphometric study of the carotid body in chronically hypoxic rats［J］. J Appl Physiol Respir Environ Exerc Physiol, 1984,57(5):1430-1438.
［17］Rio RD, Mu?oz C, Arias P, et al. Chronic intermittent hypoxia-induced vascular enlargement and VEGF up regulation in the rat carotid body is not prevented by antioxidant treatment［J］. Am J Physiol Lung Cell Mol Physiol， 2011,301(5):L702-711.
［18］Raffaele DC, Veronica M, Martina MS, et al. Structural and neurochemical changes in the maturation of the carotid body［J］. Resp Physiol Neurobi, 2013, 185(1): 9-19. 
［19］Donovan LM, Chai S, Gillombardo CB, et al. Ventilatory behavior and carotid body morphology of Brown Norway and Sprague Dawley rats［J］. Resp Physiol Neurobi, 2011, 178(2): 250-255.