Embryonic Diapause: Advances in Understanding the Enigma of Seasonal Delayed Implantation

Contents Embryonic diapause is an evolutionary strategy by which a reversible arrest in embryo development occurs. In its two forms, facultative and obligate, it assures that offspring are born when optimal maternal and environmental conditions are present to ensure maximal survival. We have explore...

Full description

Saved in:
Bibliographic Details
Published in:Reproduction in domestic animals 2012-12, Vol.47 (s6), p.121-124
Main Author: Murphy, BD
Format: Article
Language:English
Subjects:
Animals
Embryo Implantation - physiology
Embryo, Mammalian - physiology
Embryonic Development - physiology
Embryos
Female
Mink - physiology
Ovary - physiology
Pituitary Gland - physiology
Polyamines - metabolism
Seasons
Transplants & implants
Uterus - physiology
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Contents Embryonic diapause is an evolutionary strategy by which a reversible arrest in embryo development occurs. In its two forms, facultative and obligate, it assures that offspring are born when optimal maternal and environmental conditions are present to ensure maximal survival. We have explored obligate delayed implantation in the mink (Neovison vison) over four decades: first by evaluation of the environmental regulation, then by determination of the pituitary factors that maintain diapause and provoke implantation followed by exploration of the ovarian contribution to the process. As the uterine environment is the proximal regulator of diapause, we employed a strategy of global gene analysis to discover differentially expressed pathways during embryo arrest and reactivation. These trials revealed that the synthesis of polyamines was increased in the uterus with reactivation of the embryo in vivo. Subsequent experiments demonstrated that the polyamine, putrescine, was capable of inducing escape of the embryo from obligate diapause, providing strong evidence that the paucity of polyamines induces developmental arrest, and reactivation is coupled to renewed uterine and/or embryonic synthesis of these polycations.
ISSN:0936-6768
1439-0531
DOI:10.1111/rda.12046