Hostname: page-component-586b7cd67f-rcrh6 Total loading time: 0 Render date: 2024-11-25T17:13:38.522Z Has data issue: false hasContentIssue false

Physiological and practical effects of progesterone on reproduction in dairy cattle

Published online by Cambridge University Press:  04 April 2014

M. C. Wiltbank*
Affiliation:
Department of Dairy Science, University of Wisconsin-Madison, Wisconsin, USA
A. H. Souza
Affiliation:
Department of Dairy Science, University of Wisconsin-Madison, Wisconsin, USA University of California Cooperative Extension, University of California-Davis, Tulare, California, USA
P. D. Carvalho
Affiliation:
Department of Dairy Science, University of Wisconsin-Madison, Wisconsin, USA
A. P. Cunha
Affiliation:
Department of Dairy Science, University of Wisconsin-Madison, Wisconsin, USA
J. O. Giordano
Affiliation:
Department of Dairy Science, University of Wisconsin-Madison, Wisconsin, USA Department of Animal Science, Cornell University, New York, USA
P. M. Fricke
Affiliation:
Department of Dairy Science, University of Wisconsin-Madison, Wisconsin, USA
G. M. Baez
Affiliation:
Department of Dairy Science, University of Wisconsin-Madison, Wisconsin, USA
M. G. Diskin
Affiliation:
Animal and Bioscience Research Department, Animal and Grassland Research and Innovation Centre, Teagasc, Ireland
*
Get access

Abstract

The discovery of progesterone (P4) and elucidation of the mechanisms of P4 action have an important place in the history of endocrinology and reproduction. Circulating P4 concentration is determined by a balance between P4 production, primarily by the corpus luteum (CL), and P4 metabolism, primarily by the liver. The volume of luteal tissue and number and function of large luteal cells are primary factors determining P4 production. Rate of P4 metabolism is generally determined by liver blood flow and can be of critical importance in determining circulating P4 concentrations, particularly in dairy cattle. During timed artificial insemination (AI) protocols, elevations in P4 are achieved by increasing number of CL by creating accessory CL or by supplementation with exogenous P4. Dietary manipulations can also alter circulating P4, although practical methods to apply these techniques have not yet been reported. Elevating P4 before the timed AI generally decreases double ovulation and increases fertility to the timed AI. Near the time of AI, slight elevations in circulating P4, possibly due to inadequate luteal regression, can dramatically reduce fertility. After AI, circulating P4 is critical for embryo growth and establishment and maintenance of pregnancy. Many studies have attempted to improve fertility by elevating P4 after timed AI. Our recent meta-analysis and manipulative study indicated small fertility benefits (3% to 3.5%) mostly in primiparous cows. Thus, previous research has provided substantial insight into mechanisms regulating circulating P4 concentrations and actions. Understanding this prior research can focus future research on P4 manipulation to improve reproductive success.

Type
Full Paper
Copyright
© The Animal Consortium 2014 

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Allen, W 1974. Recollections of my life with progesterone. Gynecological Investigation 5, 142182.Google Scholar
Allen, WM, Butenandt, A, Corner, GW and Slotta, KH 1935. Nomenclature of corpus luteum hormone. Nature 136, 303.Google Scholar
Arck, P, Hansen, PJ, Jericevic, BM, Piccinni, M-P and Szekeres-Bartho, J 2007. Progesterone during pregnancy: endocrine-immune cross talk in mammalian species and the role of stress. American Journal of Reproductive Immunology 58, 268279.CrossRefGoogle ScholarPubMed
Atli, MO, Bender, RW, Mehta, V, Bastos, MR, Luo, W, Vezina, CM and Wiltbank, MC 2012. Patterns of gene expression in the bovine corpus luteum following repeated intrauterine infusions of low doses of prostaglandin F2 alpha. Biology of Reproduction 86, 113.CrossRefGoogle Scholar
Baird, DT 1992. Luteotrophic control of the corpus luteum. Animal Reproduction Science 28, 95107.Google Scholar
Bazer, FW, Kim, J, Song, G, Ka, H, Tekwe, CD and Wu, G 2012. Select nutrients, progesterone, and interferon tau affect conceptus metabolism and development. Annals of the New York Academy of Sciences 1271, 8896.Google Scholar
Belfiore, CJ, Hawkins, DE, Wiltbank, MC and Niswender, GD 1994. Regulation of cytochrome P450scc synthesis and activity in the ovine corpus-luteum. Journal of Steroid Biochemistry and Molecular Biology 51, 283290.Google Scholar
Bilby, TR, Bruno, RGS, Lager, KJ, Chebel, RC, Moraes, JGN, Fricke, PM, Lopes, G, Giordano, JO, Santos, JEP, Lima, FS, Stevenson, JS and Pulley, SL 2013. Supplemental progesterone and timing of resynchronization on pregnancy outcomes in lactating dairy cows. Journal of Dairy Science 96, 70327042.CrossRefGoogle ScholarPubMed
Bisinotto, RS, Chebel, RC and Santos, JE 2010a. Follicular wave of the ovulatory follicle and not cyclic status influences fertility of dairy cows. Journal of Dairy Science 93, 35783587.Google Scholar
Bisinotto, RS, Ribeiro, ES, Martins, LT, Marsola, RS, Greco, LF, Favoreto, MG, Risco, CA, Thatcher, WW and Santos, JEP 2010b. Effect of interval between induction of ovulation and artificial insemination (AI) and supplemental progesterone for resynchronization on fertility of dairy cows subjected to a 5-d timed AI program. Journal of Dairy Science 93, 57985808.Google Scholar
Bisinotto, RS, Ribeiro, ES, Lima, FS, Martinez, N, Greco, LF, Barbosa, L, Bueno, PP, Scagion, LFS, Thatcher, WW and Santos, JEP 2013. Targeted progesterone supplementation improves fertility in lactating dairy cows without a corpus luteum at the initiation of the timed artificial insemination protocol. Journal of Dairy Science 96, 22142225.Google Scholar
Bogan, RL and Niswender, GD 2007. Constitutive steroidogenesis in ovine large luteal cells may be mediated by tonically active protein kinase A. Biology of Reproduction 77, 209216.CrossRefGoogle ScholarPubMed
Bouin, P and Ancel, P 1910. Recherches sur les fonctions du corps jaune gestatif. I. Sur le determinisme de la preparatiotion de l'uterus al fixation d l'oeuf. Journal de physiologie et de pathologie generale 12, 116.Google Scholar
Brusveen, DJ, Souza, AH and Wiltbank, MC 2009. Effects of additional prostaglandin F-2 alpha and estradiol-17 beta during Ovsynch in lactating dairy cows. Journal of Dairy Science 92, 14121422.Google Scholar
Brusveen, DJ, Cunha, AP, Silva, CD, Cunha, PM, Sterry, RA, Silva, EP, Guenther, JN and Wiltbank, MC 2008. Altering the time of the second gonadotropin-releasing hormone injection and artificial insemination (AI) during Ovsynch affects pregnancies per AI in lactating dairy cows. Journal of Dairy Science 91, 10441052.CrossRefGoogle ScholarPubMed
Bulman, DC and Lamming, GE 1978. Milk progesterone levels in relation to conception, repeat breeding and factors influencing acyclicity in dairy cows. Journal of Reproduction and Fertility 54, 447458.Google Scholar
Butenandt, A and Westphal, U 1934. Zur isolierung und characterisierung des corpus-luteum-hormons. Berichte der deutschen chemischen Gesellschaft 67, 14401442.Google Scholar
Carter, F, Forde, N, Duffy, P, Wade, M, Fair, T, Crowe, MA, Evans, ACO, Kenny, DA, Roche, JF and Lonergan, P 2008. Effect of increasing progesterone concentration from day 3 of pregnancy on subsequent embryo survival and development in beef heifers. Reproduction, Fertility and Development 20, 368375.Google Scholar
Carter, F, Rings, F, Mamo, S, Holker, M, Kuzmany, A, Besenfelder, U, Havlicek, V, Mehta, JP, Tesfaye, D, Schellander, K and Lonergan, P 2010. Effect of elevated circulating progesterone concentration on bovine blastocyst development and global transcriptome following endoscopic transfer of in vitro produced embryos to the bovine oviduct. Biology of Reproduction 83, 707719.Google Scholar
Cerri, RLA, Chebel, RC, Rivera, F, Narciso, CD, Oliveira, RA, Thatcher, WW and Santos, JEP 2011a. Concentration of progesterone during the development of the ovulatory follicle: I. Ovarian and embryonic responses. Journal of Dairy Science 94, 33423351.Google Scholar
Cerri, RLA, Chebel, RC, Rivera, F, Narciso, CD, Oliveira, RA, Amstalden, M, Baez-Sandoval, GM, Oliveira, LJ, Thatcher, WW and Santos, JEP 2011b. Concentration of progesterone during the development of the ovulatory follicle: II. Ovarian and uterine responses. Journal of Dairy Science 94, 33523365.Google Scholar
Chebel, RC, Al-Hassan, MJ, Fricke, PM, Santos, JEP, Lima, JR, Martel, CA, Stevenson, JS, Garcia, R and Ax, RL 2010. Supplementation of progesterone via controlled internal drug release inserts during ovulation synchronization protocols in lactating dairy cows. Journal of Dairy Science 93, 922931.Google Scholar
Christenson, RK, Ford, JJ and Redmer, DA 1985. Metabolic-clearance and production-rates of estradiol and progesterone during pubertal and postpubertal development in gilts. Journal of Reproduction and Fertility 75, 247253.Google Scholar
Clemente, M, de la Fuente, J, Fair, T, Al Naib, A, Gutierrez-Adan, A, Roche, JF, Rizos, D and Lonergan, P 2009. Progesterone and conceptus elongation in cattle: a direct effect on the embryo or an indirect effect via the endometrium? Reproduction 138, 507517.CrossRefGoogle ScholarPubMed
Corner, GW and Allen, WM 1929. Physiology of the corpus luteum. II. Production of a special uterine reaction (progestational proliferation) by extracts of the corpus luteum. American Journal of Physiology 88, 326399.Google Scholar
Couet, J, Martel, C, Dupont, E, Luuthe, V, Sirard, MA, Zhao, HF, Pelletier, G and Labrie, F 1990. Changes in 3-beta hydroxysteroid dehydrogenase-delta-5-delta-4 isomerase mRNA, activity, and protein levels during estrous cycle in the bovine ovary. Endocrinology 127, 21412148.Google Scholar
Cummins, SB, Lonergan, P, Evans, ACO and Butler, ST 2012. Genetic merit for fertility traits in Holstein cows: II. Ovarian follicular and corpus luteum dynamics, reproductive hormones, and estrus behavior. Journal of Dairy Science 95, 36983710.Google Scholar
Cunha, AP, Guenther, JN, Maroney, MJ, Giordano, JO, Nascimento, AB, Bas, S, Ayres, H and Wiltbank, MC 2008. Effects of high vs. low progesterone concentrations during Ovsynch on double ovulation rate and pregnancies per AI in high producing dairy cows. Journal of Dairy Science 91 (suppl. 1), 246. (Abstract).Google Scholar
De Silva, AWMV, Anderson, GW, Gwazdauskas, FC, McGilliard, ML and Lineweaver, JA 1981. Interrelationships with estrous behavior and conception in dairy-cattle. Journal of Dairy Science 64, 24092418.CrossRefGoogle ScholarPubMed
del Rio, NS, Kirkpatrick, BW and Fricke, PM 2006. Observed frequency of monozygotic twinning in Holstein dairy cattle. Theriogenology 66, 12921299.Google Scholar
Denamur, R, Martinet, J and Short, RV 1973. Pituitary control of ovine corpus luteum. Journal of Reproduction and Fertility 32, 207220.Google Scholar
Denicol, AC, Lopes, G Jr, Mendonça, LGD, Rivera, FA, Guagnini, F, Perez, RV, Lima, JR, Bruno, RGS, Santos, JEP and Chebel, RC 2012. Low progesterone concentration during the development of the first follicular wave reduces pregnancy per insemination of lactating dairy cows. Journal of Dairy Science 95, 17941806.CrossRefGoogle ScholarPubMed
Diaz, FJ, Anderson, LE, Wu, YL, Rabot, A, Tsai, SJ and Wiltbank, MC 2002. Regulation of progesterone and prostaglandin F-2 alpha production in the CL. Molecular and Cellular Endocrinology 191, 6580.Google Scholar
Diskin, MG, Murphy, JJ and Sreenan, JM 2006. Embryo survival in dairy cows managed under pastoral conditions. Animal Reproduction Science 96, 297311.Google Scholar
Ellmann, S, Sticht, H, Thiel, F, Beckmann, MW, Strick, R and Strissel, PL 2009. Estrogen and progesterone receptors: from molecular structures to clinical targets. Cellular and Molecular Life Sciences 66, 24052426.Google Scholar
Erb, RE, Garverick, HA, Randel, RD, Brown, BL and Callahan, CJ 1976. Profiles of reproductive hormones associated with fertile and nonfertile inseminations of dairy cows. Theriogenology 5, 227242.CrossRefGoogle ScholarPubMed
Farin, CE, Nett, TM and Niswender, GD 1990. Effects of LH on luteal cell populations in hypophysectomized ewes. Journal of Reproduction and Fertility 88, 6170.Google Scholar
Fels, E, Slotta, KH and Ruschig, H 1934. Preparation of pure hormones of the corpus luteum. Klinische Wochenschrift 13, 12071208.CrossRefGoogle Scholar
Fernandez-Valdivia, R, Mukherjee, A, Mulac-Jericevic, B, Conneely, OM, DeMayo, FJ, Amato, P and Lydon, JP 2005. Revealing progesterone’s role in uterine and mammary gland biology: insights from the mouse. Seminars in Reproductive Medicine 23, 2237.Google Scholar
Folman, Y, Rosenber, M, Herz, Z and Davidson, M 1973. Relationship between plasma progesterone concentration and conception in postpart dairy cows maintained on 2 levels of nutrition. Journal of Reproduction and Fertility 34, 267278.Google Scholar
Fonseca, FA, Britt, JH, Mcdaniel, BT, Wilk, JC and Rakes, AH 1983. Reproductive traits of Holsteins and Jerseys – effects of age, milk yield, and clinical abnormalities on involution of cervix and uterus, ovulation, estrous cycles, detection of estrus, conception rate, and days open. Journal of Dairy Science 66, 11281147.Google Scholar
Forde, N, Beltman, ME, Duffy, GB, Duffy, P, Mehta, JP, O’Gaora, P, Roche, JF, Lonergan, P and Crowe, MA 2011. Changes in the endometrial transcriptome during the bovine estrous cycle: effect of low circulating progesterone and consequences for conceptus elongation. Biology of Reproduction 84, 266278.Google Scholar
Forde, N, Carter, F, Fair, T, Crowe, MA, Evans, ACO, Spencer, TE, Bazer, FW, McBride, R, Boland, MP, O’Gaora, P, Lonergan, P and Roche, JF 2009. Progesterone-regulated changes in endometrial gene expression contribute to advanced conceptus development in cattle. Biology of Reproduction 81, 784794.Google Scholar
Fraenkel, L 1910. Neue experiment zur function des corpus luteum. Archiv fur Gynakologie 91, 705730.Google Scholar
Fraenkel, L and Cohn, F 1901. Experimentelle untersuchungen des corpus luteum auf die insertion des eies (Theorie von Born). Anatomischer Anzeiger 20, 294300.Google Scholar
Fricke, PM and Wiltbank, MC 1999. Effect of milk production on the incidence of double ovulation in dairy cows. Theriogenology 52, 11331143.Google Scholar
Fricke, PM, Reynolds, LP and Redmer, DA 1993. Effect of human chorionic gonadotropin administered early in the estrous cycle on ovulation and subsequent luteal function in cows. Journal of Animal Science 71, 12421246.Google Scholar
Ghanem, ME, Nakao, T, Nakatani, K, Akita, M and Suzuki, T 2006. Milk progesterone profile at and after artificial insemination in repeat-breeding cows: effects on conception rate and embryonic death. Reproduction in Domestic Animals 41, 180183.Google Scholar
Giordano, JO, Wiltbank, MC, Guenther, JN, Ares, MS, Lopes, G Jr, Herlihy, MM and Fricke, PM 2012a. Effect of presynchronization with human chorionic gonadotropin or gonadotropin-releasing hormone 7 days before resynchronization of ovulation on fertility in lactating dairy cows. Journal of Dairy Science 95, 56125625.CrossRefGoogle ScholarPubMed
Giordano, JO, Wiltbank, MC, Guenther, JN, Pawlisch, R, Bas, S, Cunha, AP and Fricke, PM 2012b. Increased fertility in lactating dairy cows resynchronized with Double-Ovsynch compared with Ovsynch initiated 32 d after timed artificial insemination. Journal of Dairy Science 95, 639653.Google Scholar
Giordano, JO, Wiltbank, MC, Fricke, PM, Bas, S, Pawlisch, R, Guenther, JN and Nascimento, AB 2013a. Effect of increasing GnRH and PGF2α dose during Double-Ovsynch on ovulatory response, luteal regression, and fertility of lactating dairy cows. Theriogenology 80, 773783.Google Scholar
Giordano, JO, Wiltbank, MC, Fricke, PM, Bas, S, Pawlisch, RA, Guenther, JN and Nascimento, AB 2013b. Effect of increasing GnRH and PGF2α dose during Double-Ovsynch on ovulatory response, luteal regression, and fertility of lactating dairy cows. Theriogenology 80, 773783.Google Scholar
Grummer, RR and Carroll, DJ 1988. A review of lipoprotein cholesterol metabolism – importance to ovarian function. Journal of Animal Science 66, 31603173.Google Scholar
Gumen, A, Guenther, JN and Wiltbank, MC 2003. Follicular size and response to Ovsynch versus detection of estrus in anovular and ovular lactating dairy cows. Journal of Dairy Science 86, 31843194.Google Scholar
Hanlon, DW, Jarratt, GM, Davidson, PJ, Millar, AJ and Douglas, VL 2005. The effect of hCG administration five days after insemination on the first service conception rate of anestrous dairy cows. Theriogenology 63, 19381945.Google Scholar
Hartmen, M and Wettstein, A 1934. Ein krystallisiertes hormon aus corpus luteum. Helvetica Chimica Acta 17, 878882.Google Scholar
Haughian, JM, Ginther, OJ, Diaz, FJ and Wiltbank, MC 2013. Gonadotropin-releasing hormone, estradiol, and inhibin regulation of follicle-stimulating hormone and luteinizing hormone surges: implications for follicle emergence and selection in heifers. Biology of Reproduction 88, 165177.Google Scholar
Hawkins, DE, Belfiore, CJ, Kile, JP and Niswender, GD 1993. Regulation of mRNA encoding 3-beta hydroxysteroid dehydrogenase delta(5)-delta(4) isomerase in ovine corpus luteum. Biology of Reproduction 48, 11851190.Google Scholar
Hayashi, KG, Matsui, M, Shimizu, T, Sudo, N, Sato, A, Shirasuna, K, Tetsuka, M, Kida, K, Schams, D and Miyamoto, A 2008. The absence of corpus luteum formation alters the endocrine profile and affects follicular development during the first follicular wave in cattle. Reproduction 136, 787797.Google Scholar
Herrick, JB 1953. Clinical observation of progesterone therapy in repeat breeding heifers. Veterinary Medicine 48, 489490.Google Scholar
Hunter, RHF 2005. The fallopian tubes in domestic mammals: how vital is their physiological activity? Reproduction Nutrition Development 45, 281290.Google Scholar
Jocelyn, HD and Setchell, BP 1972. An annotated translation of Regnier deGraaf’s new treatise concerning the generative organs of women (1672). Journal of Reproduction and Fertility Supplement 17, 77206.Google Scholar
Juengel, JL, Meberg, BM, McIntush, EW, Smith, MF and Niswender, GD 1998. Concentration of mRNA encoding 3 beta-hydroxysteroid dehydrogenase delta(5), delta(4) isomerase (3 beta-HSD) and 3 beta-HSD enzyme activity following treatment of ewes with prostaglandin F-2 alpha. Endocrine 8, 4550.Google Scholar
Kaltenbach, CC, Graber, JW, Niswender, GD and Nalbandov, AV 1968. Effect of hypophysectomy on formation and maintenance of corpora lutea in ewe. Endocrinology 82, 753.Google Scholar
Kendall, NR, Flint, APF and Mann, GE 2009. Incidence and treatment of inadequate postovulatory progesterone concentrations in repeat breeder cows. Veterinary Journal 181, 158162.Google Scholar
Kinsel, ML, Marsh, WE, Ruegg, PL and Etherington, WG 1998. Risk factors for twinning in dairy cows. Journal of Dairy Science 81, 989993.Google Scholar
Larson, JE, Krisher, RL and Lamb, GC 2011. Effects of supplemental progesterone on the development, metabolism and blastocyst cell number of bovine embryos produced in vitro. Reproduction Fertility and Development 23, 311318.CrossRefGoogle ScholarPubMed
Larson, SF, Butler, WR and Currie, WB 1997. Reduced fertility associated with low progesterone postbreeding and increased milk urea nitrogen in lactating cows. Journal of Dairy Science 80, 12881295.Google Scholar
Li, XL, Peegel, H and Menon, KMJ 1998. In situ hybridization of high density lipoprotein (scavenger, type 1) receptor messenger ribonucleic acid (mRNA) during folliculogenesis and luteinization: evidence for mRNA expression and induction by human chorionic gonadotropin specifically in cell types that use cholesterol for steroidogenesis. Endocrinology 139, 30433049.Google Scholar
Lonergan, P, Woods, A, Fair, T, Carter, F, Rizos, D, Ward, F, Quinn, K and Evans, A 2007. Effect of embryo source and recipient progesterone environment on embryo development in cattle. Reproduction, Fertility and Development 19, 861868.Google Scholar
Lopez, H, Sartori, R and Wiltbank, MC 2005a. Reproductive hormones and follicular growth during development of one or multiple dominant follicles in cattle. Biology of Reproduction 72, 788795.Google Scholar
Lopez, H, Caraviello, DZ, Satter, LD, Fricke, PM and Wiltbank, MC 2005b. Relationship between level of milk production and multiple ovulations in lactating dairy cows. Journal of Dairy Science 88, 27832793.Google Scholar
Magnus, V 1901. Ovariets betydning for svangerskabet med saerligt hensyntil corpus luteum. Norsk Magazin for Laegevidenskaben 62, 11381142.Google Scholar
Magnus, V and Simmer, HH 1972. The first experiments to demonstrate an endocrine function of the corpus luteum. II. Ludwig Fraenkel versus Vilhelm magnus. Sudhoffs Archiv 56, 7699.Google Scholar
Mann, GE and Lamming, GE 1999. The influence of progesterone during early pregnancy in cattle. Reproduction in Domestic Animals 34, 269274.Google Scholar
Martins, JP, Policelli, RK, Neuder, LM, Raphael, W and Pursley, JR 2011a. Effects of cloprostenol sodium at final prostaglandin F2alpha of Ovsynch on complete luteolysis and pregnancy per artificial insemination in lactating dairy cows. Journal of Dairy Science 94, 28152824.Google Scholar
Martins, JPN, Policelli, RK, Neuder, LM, Raphael, W and Pursley, JR 2011b. Effects of cloprostenol sodium at final prostaglandin F-2 alpha of Ovsynch on complete luteolysis and pregnancy per artificial insemination in lactating dairy cows. Journal of Dairy Science 94, 28152824.Google Scholar
McNeill, RE, Sreenan, JM, Diskin, MG, Cairns, MT, Fitzpatrick, R, Smith, TJ and Morris, DG 2006. Effect of systemic progesterone concentration on the expression of progesterone-responsive genes in the bovine endometrium during the early luteal phase. Reproduction, Fertility and Development 18, 573583.Google Scholar
McNeilly, AS, Crow, WJ and Fraser, HM 1992. Suppression of pulsatile LH secretion by GnRH antagonist does not affect episodic progesterone secretion or corpus luteum function in ewes. Journal of Reproduction and Fertility 96, 865874.Google Scholar
Meisterling, EM and Dailey, RA 1987. Use of concentrations of progesterone and estradiol-17-beta in milk in monitoring postpartum ovarian function in dairy cows. Journal of Dairy Science 70, 21542161.Google Scholar
Moreira, F, de la Sota, RL, Diaz, T and Thatcher, WW 2000. Effect of day of the estrous cycle at the initiation of a timed artificial insemination protocol on reproductive responses in dairy heifers. Journal of Animal Science 78, 15681576.Google Scholar
Morris, D and Diskin, M 2008. Effect of progesterone on embryo survival. Animal 2, 11121119.Google Scholar
Mullen, MP, Elia, G, Hilliard, M, Parr, MH, Diskin, MG, Evans, ACO and Crowe, MA 2012a. Proteomic characterization of histotroph during the preimplantation phase of the estrous cycle in cattle. Journal of Proteome Research 11, 30043018.Google Scholar
Mullen, MP, Forde, N, Parr, MH, Diskin, MG, Morris, DG, Nally, JE, Evans, ACO and Crowe, MA 2012b. Alterations in systemic concentrations of progesterone during the early luteal phase affect RBP4 expression in the bovine uterus. Reproduction, Fertility and Development 24, 715722.Google Scholar
Nascimento, AB, Souza, AH, Keskin, A, Sartori, R and Wiltbank, MC 2013a. Lack of complete regression of the day 5 corpus luteum after one or two dose of PGF2α in nonlactating Holstein cows. Theriogenology (in press).Google Scholar
Nascimento, AB, Souza, AH, Guenther, JN, Costa, FPD, Sartori, R and Wiltbank, MC 2013b. Effects of treatment with human chorionic gonadotrophin or intravaginal progesterone-releasing device after AI on circulating progesterone concentrations in lactating dairy cows. Reproduction, Fertility and Development 25, 818824.Google Scholar
Nascimento, AB, Bender, RW, Souza, AH, Ayres, H, Araujo, RR, Guenther, JN, Sartori, R and Wiltbank, MC 2013c. Effect of treatment with human chorionic gonadotropin on day 5 after timed artificial insemination on fertility of lactating dairy cows. Journal of Dairy Science 96, 28732882.Google Scholar
Niswender, GD, Juengel, JL, Mcguire, WJ, Belfiore, CJ and Wiltbank, MC 1994. Luteal function – the estrous-cycle and early-pregnancy. Biology of Reproduction 50, 239247.Google Scholar
Niswender, GD, Juengel, JL, Silva, PJ, Rollyson, MK and McIntush, EW 2000. Mechanisms controlling the function and life span of the corpus luteum. Physiological Reviews 80, 129.Google Scholar
Parr, RA, Davis, IF, Fairclough, RJ and Miles, MA 1987. Overfeeding during early pregnancy reduces periperpheral progesterone concentration and pregnancy in sheep. Journal of Reproduction and Fertility 80, 317320.Google Scholar
Parr, RA, Davis, IF, Miles, MA and Squires, TJ 1993. Liver blood flow and metabolic clearance rate of progesterone in sheep. Research in Veterinary Science 55, 311316.Google Scholar
Peluso, JJ 2006. Multiplicity of progesterone’s actions and receptors in the mammalian ovary. Biology of Reproduction 75, 28.Google Scholar
Pereira, MHC, Sanches, CP, Guida, TG, Rodrigues, ADR, Aragon, FL, Veras, MB, Borges, PT, Wiltbank, MC and Vasconcelos, JLM 2013. Timing of prostaglandin F-2 alpha treatment in an estrogen-based protocol for timed artificial insemination or timed embryo transfer in lactating dairy cows. Journal of Dairy Science 96, 28372846.Google Scholar
Pescador, N, Soumano, K, Stocco, DM, Price, CA and Murphy, BD 1996. Steroidogenic acute regulatory protein in bovine corpora lutea. Biology of Reproduction 55, 485491.Google Scholar
Plym Forshell, K, Andersson, L and Pehrson, B 1991. The relationships between the fertility of dairy cows and clinical and biochemical measurements, with special reference to plasma glucose and milk acetone. Zentralbl Veterinarmed A 38, 608616.Google Scholar
Prime, GR and Symonds, HW 1993. Influence of plane of nutrition on portal blood-flow and the metabolic-clearance rate of progesterone in ovariectomized gilts. Journal of Agricultural Science 121, 389397.Google Scholar
Rajamahendran, R and Sianangama, PC 1992. Effect of human chorionic gonadotrophin on dominant follicles in cows: formation of accessory corpora lutea, progesterone production and pregnancy rates. Journal of Reproduction and Fertility 95, 577584.Google Scholar
Rajapaksha, W, McBride, M, Robertson, L and Oshaughnessy, PJ 1997. Sequence of the bovine HDL-receptor (SR-BI) cDNA and changes in receptor mRNA expression during granulosa cell luteinization in vivo and in vitro. Molecular and Cellular Endocrinology 134, 5967.Google Scholar
Ribeiro, ES, Bisinotto, RS, Favoreto, MG, Martins, LT, Cerri, RLA, Silvestre, FT, Greco, LF, Thatcher, WW and Santos, JEP 2012. Fertility in dairy cows following presynchronization and administering twice the luteolytic dose of prostaglandin F-2 alpha as one or two injections in the 5-day timed artificial insemination protocol. Theriogenology 78, 273284.Google Scholar
Rivera, FA, Mendonca, LGD, Lopes, G, Santos, JEP, Perez, RV, Amstalden, M, Correa-Calderon, A and Chebel, RC 2011. Reduced progesterone concentration during growth of the first follicular wave affects embryo quality but has no effect on embryo survival post transfer in lactating dairy cows. Reproduction 141, 333342.Google Scholar
Sangsritavong, S 2002. Studies of steroid metabolism in dairy cattle. PhD Dissertation, University of Wisconsin, Madison, WI, USA.Google Scholar
Sangsritavong, S, Combs, DK, Sartori, R, Armentano, LE and Wiltbank, MC 2002. High feed intake increases liver blood flow and metabolism of progesterone and estradiol-17 beta in dairy cattle. Journal of Dairy Science 85, 28312842.Google Scholar
Santos, JEP, Rutigliano, HM and Filho, MFS 2009. Risk factors for resumption of postpartum estrous cycles and embryonic survival in lactating dairy cows. Animal Reproduction Science 110, 207221.Google Scholar
Santos, JEP, Thatcher, WW, Pool, L and Overton, MW 2001. Effect of human chorionic gonadotropin on luteal function and reproductive performance of high-producing lactating Holstein dairy cows. Journal of Animal Science 79, 28812894.Google Scholar
Santos, JEP, Thatcher, WW, Chebel, RC, Cerri, RLA and Galvão, KN 2004. The effect of embryonic death rates in cattle on the efficacy of estrus synchronization programs. Animal Reproduction Science 82–83, 513535.Google Scholar
Santos, JEP, Narciso, CD, Rivera, F, Thatcher, WW and Chebel, RC 2010. Effect of reducing the period of follicle dominance in a timed artificial insemination protocol on reproduction of dairy cows. Journal of Dairy Science 93, 29762988.Google Scholar
Schmitt, EJ, Barros, CM, Fields, PA, Fields, MJ, Diaz, T, Kluge, JM and Thatcher, WW 1996. A cellular and endocrine characterization of the original and induced corpus luteum after administration of a gonadotropin-releasing hormone agonist or human chorionic gonadotropin on day five of the estrous cycle. Journal of Animal Science 74, 19151929.Google Scholar
Silva, CC and Knight, PG 2000. Effects of androgens, progesterone and their antagonists on the developmental competence of in vitro matured bovine oocytes. Journal of Reproduction and Fertility 119, 261269.Google Scholar
Silva, CC, Groome, NP and Knight, PG 1999. Demonstration of a suppressive effect of inhibin alpha-subunit on the developmental competence of in vitro matured bovine oocytes. Journal of Reproduction and Fertility 115, 381388.CrossRefGoogle ScholarPubMed
Silva, E, Sterry, RA, Kolb, D, Wiltbank, MC and Fricke, PM 2007. Effect of pretreatment with prostaglandin F-2 alpha before resynchronization of ovulation on fertility of lactating dairy cows. Journal of Dairy Science 90, 55095517.CrossRefGoogle Scholar
Simmer, HH 1971. The first experiments to demonstrate an endocrine function of the corpus luteum. On the occasion of the 100th birthday of Ludwig Fraenkel (1870–1951). Sudhoffs Archiv 55, 392417.Google Scholar
Souza, AH, Ayres, H, Ferreira, RM and Wiltbank, MC 2008. A new presynchronization system (Double-Ovsynch) increases fertility at first postpartum timed AI in lactating dairy cows. Theriogenology 70, 208215.Google Scholar
Souza, AH, Gumen, A, Silva, EPB, Cunha, AP, Guenther, JN, Peto, CM, Caraviello, DZ and Wiltbank, MC 2007. Supplementation with estradiol-17 beta before the last gonadotropin-releasing hormone injection of the Ovsynch protocol in lactating dairy cows. Journal of Dairy Science 90, 46234634.Google Scholar
Souza, AH, Silva, EPB, Cunha, AP, Gumen, A, Ayres, H, Brusveen, DJ, Guenther, JN and Wiltbank, MC 2011. Ultrasonographic evaluation of endometrial thickness near timed AI as a predictor of fertility in high-producing dairy cows. Theriogenology 75, 722733.Google Scholar
Sterry, RA, Welle, ML and Fricke, PM 2006. Treatment with gonadotropin-releasing hormone after first timed artificial insemination improves fertility in noncycling lactating dairy cows. Journal of Dairy Science 89, 42374245.Google Scholar
Stevenson, JS, Portaluppi, MA and Tenhouse, DE 2007a. Factors influencing upfront single- and multiple-ovulation incidence, progesterone, and luteolysis before a timed insemination resynchronization protocol. Journal of Dairy Science 90, 55425551.CrossRefGoogle ScholarPubMed
Stevenson, JS, Portaluppi, MA, Tenhouse, DE, Lloyd, A, Eborn, DR, Kacuba, S and DeJarnette, JM 2007b. Interventions after artificial insemination: conception rates, pregnancy survival, and ovarian responses to gonadotropin-releasing hormone, human chorionic gonadotropin, and progesterone. Journal of Dairy Science 90, 331340.Google Scholar
Stevenson, JS, Pursley, JR, Garverick, HA, Fricke, PM, Kesler, DJ, Ottobre, JS and Wiltbank, MC 2006. Treatment of cycling and noncycling lactating dairy cows with progesterone during Ovsynch. Journal of Dairy Science 89, 25672578.CrossRefGoogle ScholarPubMed
Stevenson, JS, Tenhouse, DE, Krisher, RL, Lamb, GC, Larson, JE, Dahlen, CR, Pursley, JR, Bello, NM, Fricke, PM, Wiltbank, MC, Brusveen, DJ, Burkhart, M, Youngquist, RS and Garverick, HA 2008. Detection of anovulation by heatmount detectors and transrectal ultrasonography before treatment with progesterone in a timed insemination protocol. Journal of Dairy Science 91, 29012915.Google Scholar
Stocco, DM and Clark, BJ 1996. Role of the steroidogenic acute regulatory protein (StAR) in steroidogenesis. Biochemical Pharmacology 51, 197205.Google Scholar
Stocco, DM, Wang, X, Jo, Y and Manna, P 2005. Multiple signaling pathways regulating steroidogenesis and steroidogenic acute regulatory protein expression: more complicated than we thought. Molecular Endocrinology 19, 26472659.Google Scholar
Stronge, AJH, Sreenan, JM, Diskin, MG, Mee, JF, Kenny, DA and Morris, DG 2005. Post-insemination milk progesterone concentration and embryo survival in dairy cows. Theriogenology 64, 12121224.Google Scholar
Tandeski, TR, Juengel, JL, Nett, TM and Niswender, GD 1996. Regulation of messenger RNA encoding low density lipoprotein receptor and high density lipoprotein-binding protein in ovine corpora lutea. Reproduction Fertility and Development 8, 11071114.Google Scholar
Vasconcelos, JL, Sa Filho, OG, Justolin, PL, Morelli, P, Aragon, FL, Veras, MB and Soriano, S 2011. Effects of postbreeding gonadotropin treatments on conception rates of lactating dairy cows subjected to timed artificial insemination or embryo transfer in a tropical environment. Journal of Dairy Science 94, 223234.Google Scholar
Vasconcelos, JLM, Sangsritavong, S, Tsai, SJ and Wiltbank, MC 2003. Acute reduction in serum progesterone concentrations after feed intake in dairy cows. Theriogenology 60, 795807.Google Scholar
Waldmann, A, Reksen, O, Landsverk, K, Kommisrud, E, Dahl, E, Refsdal, A and Ropstad, E 2001. Progesterone concentrations in milk fat at first insemination - effects on non-return and repeat-breeding. Animal Reproduction Science 65, 3341.Google Scholar
Walton, JS, Halbert, GW, Robinson, NA and Leslie, KE 1990. Effects of progesterone and human chorionic-gonadotropin administration 5 days postinsemination on plasma and milk concentrations of progesterone and pregnancy rates of normal and repeat breeder dairy cows. Canadian Journal of Veterinary Research 54, 305308.Google Scholar
Wiltbank, JN, Hawk, HW, Kidder, HE, Black, WG, Ulberg, LC and Casida, LE 1956. Effect of progesterone therapy on embryos survival in cows of lowered fertility. Journal of Dairy Science 39, 456461.Google Scholar
Wiltbank, M, Lopez, H, Sartori, R, Sangsritavong, S and Gumen, A 2006. Changes in reproductive physiology of lactating dairy cows due to elevated steroid metabolism. Theriogenology 65, 1729.Google Scholar
Wiltbank, MC 1994. Cell types and hormonal mechanisms associated with mid-cycle corpus luteum function. Journal of Animal Science 72, 18731883.Google Scholar
Wiltbank, MC, Belfiore, CJ and Niswender, GD 1993. Steroidogenic enzyme activity after acute activation of protein-kinase (PK) A and PKC in ovine small and large luteal cells. Molecular and Cellular Endocrinology 97, 17.Google Scholar
Wiltbank, MC, Diskin, MG, Flores, JA and Niswender, GD 1990. Regulation of the corpus luteum by protein kinase C 2. Inhibition of lipoprotein-stimulated steroidogenesis by prostaglandin-F2-alpha. Biology of Reproduction 42, 239245.Google Scholar
Wiltbank, MC, Fricke, PM, Sangsritavong, S, Sartori, R and Ginther, OJ 2000. Mechanisms that prevent and produce double ovulations in dairy cattle. Journal of Dairy Science 83, 29983007.Google Scholar
Wiltbank, MC, Salih, SM, Atli, MO, Luo, W, Bormann, CL, Ottobre, JS, Vezina, CM, Mehta, V, Diaz, FJ, Tsai, SJ and Sartori, R 2012a. Comparison of endocrine and cellular mechanisms regulating the corpus luteum of primates and ruminants. Animal Reproduction 9, 242259.Google Scholar
Wiltbank, MC, Souza, AH, Giordano, JO, Nascimento, AB, Vasconcelos, JM, Pereira, MHC, Fricke, PM, Surjus, RS, Zinsly, FCS, Carvalho, PD, Bender, RW and Sartori, R 2012b. Positive and negative effects of progesterone during timed AI protocols in lactating dairy cattle. Animal Reproduction 9, 231241.Google Scholar
Wintersteiner, O and Allen, W 1934. Crystaline progestin. Journal of Biological Chemistry 107, 321336.Google Scholar