Browse > Article

Light and Electron Microscopical Changes of Corpus Luteum during the Course of Pregnancy in Korean Native Cows  

Pyo, Byong-min (College of Veterinary Medicine, Geongsang National University)
Koh, Phil-ok (Institute of Agriculture-Life Sciences, Geongsang National University)
Yang, Je-hoon (College of Veterinary Medicine, Geongsang National University)
Won, Chung-kil (Institute of Agriculture-Life Sciences, Geongsang National University)
Cho, Gyu-wan (College of Veterinary Medicine, Geongsang National University)
Kang, Chung-boo (Institute of Agriculture-Life Sciences, Geongsang National University)
Kwak, Soo-dong (Institute of Agriculture-Life Sciences, Geongsang National University)
Publication Information
Korean Journal of Veterinary Research / v.43, no.3, 2003 , pp. 349-359 More about this Journal
Abstract
Corpus luteum (CL) is the primary productive organ of progesterone in pregnant cows. Progesterone levels in bovine plasma depend on the volume, weight and shape of the CL. Progesterone productions during the late stages of gestation occur both in the CL and placenta, and placentas producted more progesterone than CL on progesterone prcduction. Because division of progesterone production of these two organs is impoxxible, the CL function can not be determined by plasma progesterone levels following gestation stages. This study was carried out to evaluate histological findings on the CL spurium and CL verum, and also on the CL following the pregnant stages by histological and immunohistochemical and electron microscopical methods and then we expect to assume the functions of CL by histological findings. 1. Proliferations of luteal cells occur by day 120 of gestation, vessel hyperplasia occur by day 90 of gestation, and the walls and lumens of vessels developed by day 120 of pregnancy. 2. Sizes of CL cells increased to maximum around day 200 of gestation and similarly maintained by day 240. So these findings indicated that the function of Cl is most active around day 200 of gestation. 3. On parturation day, the number and size of luteal cells were maintained but stain intensity of the luteal cells and vessels are declined or disappeared, and fibrosis of luteal cells increased, and the vessel lumens are emptied. These findings indicate that CL is inactive. 4. In immunohistochemical findings, proliferative positive cells by PCNA antibody appeared more in number during early stages of gestation but appeared less following course of pregnant stages and not nearly appeared on day 120 of gestation. Apoptotic positive cells by TUNEL methods not nearly appeared on the early pregnant stages and a few appeared at late pregnant stages. So developments of CL proceed until day 120 of gestation and regression of CL was occurred by transform of luteal cells into fibrocytes than by luteal cell apoptosis. 5. In electron microscopical findings, the size of luteal cells increased more in CL verum than in CL spurium. During gestation stages, the size of luteal cells increased, mitochondria in the luteal cell cytoplasms densely and abundantly developed and also swelled mitochondria increased. The interspace of luteal cells are also dilated, transformation of luteal cells into fibrocytes are more number. The lumens and walls of peripheral capillaries of large luteal cells more broadened and thickened, and transformation of large and small luteal cells to fibrocytes are increased. The above findings suggest that function of pregnant CL more developed by day 120 of gestation and are most active around day 200 of gestation and similarly maintained by day 240 and are promptly regressed on paturation day.
Keywords
Korean native cows; pregnancy; morphology; luteal cells;
Citations & Related Records
연도 인용수 순위
  • Reference
1 Al-Zi'abi, M. 0., Fraser, H. M. and Watson, E. D. Cell death during natural and induced luteal regression in mares. Reproduc. 2002, 123(1), 67-77
2 Anderson, M. R, Vaupel, M. R. and Shenwod, 0. D. Pregnant mouse corpora lutea: Immunohistochemical localization of relaxin and ultrastructure. Biol. Reprodu. 1984, 31, 391-397
3 Bloom, W. and Fawcett, D. W. Formation of the corpus luteum in 'Textbook of Histology'. pp. 871-873, lOth ed., W. B. Saunder Co., Philadelphia. 1975
4 Bruce, N. W., Hisheh, S. and Dharmarajan, A. M. Patterns of apoptosis in the corpora lutea of the rat during the oestrous cycle, pregnancy and in vitro culture. Reprod. Fertil. Dev. 2001, 13, 105-109
5 Glock, J. L., Nakajima, S. T., Stewwart, D. R. and Brumsted, J. R. The relationship of corpus luteum volume to relaxin, estradiol, progesterone, 17-hydroxyprogesterone and human chorionic gonadotropin levels in early normal pregnancy. Early Pregnan. 1995, 1(3), 206-211
6 O'Shea, J. D. and McCoy, K. Weight, composition, mitosis, cell death and content of progesterone and DNA in the corpus luteum of pregnancy in the ewe. J. Reprod. Fert. 1988, 83, 107-117
7 Parry, D. M., and Willcox Thorburn, G. D. Ulrtastructural and cytochemical study of the bovine corpus luteum. J. Reprod. Fertil. 1997, 60(2), 349-357
8 Patel, 0. V., Hirako, M., Takahashi, T. and Domeki, I. Hirato Sex steroid levels throughout gestation in cow carrying normal and malformed fetuses, J. Vet. Med. Sci. 1995, 57(4), 659-663
9 Sawyer, H. R. Structural and functional propties of the corpus luteum of pregnancy. J. Reprod. Fertil. Suppl. 1995, 49, 97-110
10 Stoelk, E., Chegini. N., Lei, Z. M., Rao, C. H. and Bryant-Greenwood, G. Immunocytochemical localization of relaxin in human corpora lutea: Celluar and Suhcellular distribution and dependence on reproductive state. Biology of Reprodcution, 1991, 44, 1140-1147
11 Vaughan, L., Fitzpatrick, E., and Boland, M. P. 1996. A histological study of corpus lutea from superwulated beef heifers. An. Reprod. Sci. 1996, 43, 1-14
12 Yamada, 0., Abe, M., Takehanam, K., Iwasa, K. and Haraga, T. Scanning Electron microscopical observation of the intramitochondrial body in the bovine corpus luteum during pregnancy and after parturition. J, Vet. Med. Sci., 1994, 56(3), 459-464
13 Fields, M. J., Barros, C. M., Watkins, W. B. and Fields P. A. Characterization of large lutel cells and their secretory ganules during the estrous cycle of the cow. Biol. Reprod. 1992, 46(4), 535-545
14 Okuda, K., Sato, K., Ono, H. and Miyake, M. Die beziehung zwischen den morphologischen eigenschaften des corpus luteum und dem progestesteronehalt im bluteserum bei Kuehen. Obihiro Univ. Report. 1981, 12, 115-124
15 Bacci, M. L., Barazzoni, A. M., Forni, M. and Costerbosa, G. L. In situ detection of apoptosis in regressing corpus luteum of pregnant sow: evidence of an early presene of DNA fragmentation. Domest. Anim. Endocrinol. 1996, 13(4), 361-372
16 Chegini, N., Ramani, N., and Rao, C V. Morphological and biochemical charecterization of small and large bovine luteal cells during pregnancy. Mol. Cell Endocrinol. 1984, 37(1), 89-102
17 Yuan, W. and Guiudice, L. C. Programed cell death in human ovary is a function of follicle and corpus luteum status. J. Clin. Endocrinol. Metab. 1997, 82(9), 3148-55
18 Fields, M. J., Dubois, W., and Fields, P. A. Dynamic features of luteal secretory granules: Ultrastructural changes during the course of pregnancy in the cow. Endocrinol. 117, 1675-1682
19 Paavola, L. G. and Boyd, C. 0. Cytoplasmic granules in luteal cells of pregnant and non-pregnant guinea pigs. A cytochemical study. Anatomical Record, 1981, 201, 127-140
20 Rodgerts, R. J., Rodgerts, H. F., Waterman, M. R, and Simpson, E. R. Immunolocalization of cholesterol side-chain-cleavage cytochrome P-450 and ultrastructural studies of bovine corpus lutea. J. Reprod. Fert. 1986, 78, 639-652
21 O'shea, J. D., Rodgers, R. J. and D,0cchio, M. J. Cellular composition of the cyclic corpus luteum of the cow. J. Reprod. Fert. 1989, 483-487
22 양재훈, 표병민, 서득록, 고필옥, 강정부, 김종섭, 곽수동. 경남지방의 도태우에 불임과 관련된 난소의 형태학적 관찬 1, 난포와 황체의 출현에 대하여. J. Vet. Clin. 2002, 19(2), 147-152
23 Dharmarajan, A. M., Bruce, N. W., and Waddell, B. J. Quantitative changes in steroidogenic organelles in the corpus luteum of the pregnant rat in relation to progestin secretion on day 16 and in the morning and afternoon of day 22. Am. J. Anatom. 1991, 190, 273- 278
24 Gaytan, F., Morales, C., Bellido, C. and Aguilar, E. Proliferalive activeity in the different ovarian compartments in cycling rat estimated by the S-bromodeoxyuridine technique. Biol. Reporod. 1996, 54(6), 1356-1365
25 Gunther, J. D,, Foley, C. W., Gavenck, H. A. and Plotka, E. D. Comparision of milk and blood plasma progesterone concemtrations in cycling and pregnant mares. J. Anim. Sci. 1980, 51(5), 1131-1138Norman, A. W. and Litwack, G. Steroid hormone in Hormones. Academic Press INC, Orlando. 1987, pp. 578- 583
26 Rashael, S. S. Gomori's silver impregnation stain for reticulum in 'Lynch's medical laboratory technology'. 3th, WB Saunders, Philadelphia. 1976, pp. 994-995
27 Dellmann, H. D. and Eurell, J. A. Female repro- ductive system in 'Textbook of veterinary histology'. pp. 247-269, 5th ed, Lippincott Williams, Philadelphia. 1998
28 Fields, P. A. and Fields, M. J. Ultrastructural localization of relaxin in the corpus luteum of the nonpregnant, and pregnant pig. Biol. Reprod. 32, 1169- 1179
29 강종구, 곽수동, 김무강, 김성호, 신태균. 태아태령측정, 가축발생학. 대구, 경북대학교 출판부. 2001,79-83
30 곽수동, 표병민, 양재훈, 김철호, 서득록, 고필옥, 강정부. 경남지방의 도태우에 불임과 관련된 난소의 형태학적 관찰. 2. 난소낭종의 발생과 낭종형태에 대하여. J. Vet. Clin. 2002, 19(2), 153-158
31 Friedman, A., Weiss, S., Levy, N. and Meidan, R. Role of tumor necrosis factor a and its type 1 receptor in luteal regression: Induction of programmed cell death in bovine corpus luteum-derived endothelial cells. Biol. Reprod. 2000, 63, 1905-101
32 Dilys, M, Parry, D. L., Willcox, D. L. and Thorburn, G. D. Ultrastructural and cytochemical study of the bovine corpus luteum. J. Reprod. Fert. 1980, 349-357
33 Takehana, K., Abe, M., Yamada, 0. Lida-Abe, M., and Iwasa, K. Marphological study of bovine pregnant corpus luteum cells. Anat. Histol. Embryol. 1997, 26(3), 231-235