Early Pregnancy Factor (EPF): A Link between Fertilization and Immunomodulation

Morton, H. Craig

doi:10.1071/bi9840393

Cited by 39 publications

(30 citation statements)

References 35 publications

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“…The range ofconcentrations over which EPF is able to affect lymphocytes is thus extended, suggesting a possible biological function for the regulator. That this substance does have a role is reinforced by the observation that production of the inhibitor is under hormonal control, being produced by the oviduct during oestrus and early pregnancy (Morton et ai, 1980; see also Morton (1984) for an illustration of the effect of the oestrous cycle on EPF-A in serum). A larger Mr binding protein (or group of proteins; Mr > 100 000) also associates with EPF in serum during the pre-and periimplantation period.…”

Section: Discussionmentioning

confidence: 99%

Identification of a putative inhibitor of early pregnancy factor in mice

Cavanagh

Morton²,

Athanasas‐Platsis³

et al. 1991

Reproduction

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Section: Discussionmentioning

confidence: 99%

Identification of a putative inhibitor of early pregnancy factor in mice

Cavanagh

Morton²,

Athanasas‐Platsis³

et al. 1991

Reproduction

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“…In this retrospective analysis we have determined that EPF is synthesized in the red deer (Cervus elaphus) and is consistent with reports from other species (1-5). However, during our investigations, it became apparent that the biphasic response of increased EPF previously associated with the periimplantation period in other mammals (8)(9)(10) was associated with blastocyst formation and not implantation. As there is a well-defined period between blasto-cyst formation and implantation in the red deer (11-13), it was possible to determine clearly that the biphasic switch, which increases EPF synthesis, was blastocyst mediated and did not occur during implantation.…”

Section: Discussionmentioning

confidence: 91%

“…This change in EPF synthesis can be detected by a biphasic response using the rosette inhibition test, which indicates an increase in EPF synthesis (8)(9)(10). However, as blastocyst development in most mammals is closely associated with implantation, it has been difficult to identify whether the proposed switch in EPF synthesis from the ovary is associated with blastocyst development, implantation, or both events.…”

Section: Introductionmentioning

confidence: 99%

Synthesis of early pregnancy factor using red deer (Cervus elaphus) as a delayed implantation model

Lash

Legge

Fisher

1997

J Assist Reprod Genet

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“…Investigations into the presence of EPF in blood serum of women~ for example~ made it possible to detect the mechanism of action of intrauterine devices during early pregnancy (Smart et al 1982) and to define more clearly the contribution of embryonic death to prenatal losses (Smart et al 1982a;Morton 1984). This factor appears in blood serum shortly after conception (in 4 to 6 hours in mice - Morton et al 1976; in 6 hours in sheep - Morton et al 1979; in about 48 hours in women - Morton et al 1979; after 4 hours in sows - Koch et al 1982).…”

Section: Discussionmentioning

confidence: 99%

Demonstration of Early Pregnancy Factor in Gilts During the Reproductive Cycle

Knotek¹

1990

Acta Vet. Brno

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Knotek, Z.: Demonstration of Early Pregnancy Factor in Gilts During the ReproductiveCycle. Acta vet. Brno, 59, 1990: 35-40. Studies of factors affecting the success of conception and the course of pregnancy are of major importance in the physiology of reproduction. Therefore methods are needed for early detection of pregnancy in farm animals. The object of the present study was to test the usefulness of a modified rosette inhibition test for detection of early pregnancy factor (EPF) in the sera of 40 gilts in different phases of the reproductive cycle. The presence of EPF in serum was confirmed practically throughout the gestation period. The relation between the serum rosette inhibition titres and the phase of the reproductive cycle for groups of inseminated and unmated gilts and for groups of pregnant and non-pregnant gilts was highly significant (X' = 77.26 and 81.38 respectively; P < 0.01). Upon triplicate examination of all blood serum samples the detection of pregnancy by determination ofEPF was successful in 85.7 % of the inseminated gilts. In unmated gilts and primiparous sows the presence of EPF in blood serum was not confirmed. The described method for demonstration of EPF in blood serum of gilts can be of practical value in detecting non-pregnant animals as early as one week after insemination and in assessing the extent of embryonic death. Pregnancy, embryonic mortality, giltStudies of factors affecting the success of conception and the course of pregnancy are of major importance in the physiology of reproduction. The underlying difficulty is the necessity to investigate an increasingly larger number of newly defined environmental factors whose possible adverse effects on pregnancy have neither been confirmed nor excluded. A key to the resolution of the problem is the possibility to detect pregnancy as early as possible after conception because the heaviest embryonic loss can be expected to occur between fertilization and completed implantation.Early pregnancy factor (EPF) was detected in blood serum of pregnant mice ( The present study was designed to look for the presence of EPF in blood serum of gilts during different phases of the reproductive cycle and find whether demonstration of EPF could be used for detection of non-pregnant gilts shortly after insemination. Materials and MethodsThe experimental animals were 40 Large White and Landrace gilts divided into three groups. Group 1 comprised five 8-month-old unmated gilts. Group 2 comprised gilts 7 days after insemination (5 animals), 31 to 56 days after insemination (10 animals), 63 to 65 days after insemination (5 animals) and 80 to 85 days after insemination (5 animals). Group 3 included primiparous sows 7 to 12 days after farrowing (5 animals) and 28 to 32 days after farrowing (5 animals).Serum. Blood samples were collected from the cranial vena cava and the jugular vein in the morning. The sera were inactivated at 56 DC for 30 minutes and then cooled and frozen.

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Early Pregnancy Factor (EPF): A Link between Fertilization and Immunomodulation

Cited by 39 publications

References 35 publications

Identification of a putative inhibitor of early pregnancy factor in mice

Identification of a putative inhibitor of early pregnancy factor in mice

Synthesis of early pregnancy factor using red deer (Cervus elaphus) as a delayed implantation model

Demonstration of Early Pregnancy Factor in Gilts During the Reproductive Cycle

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