Experimental Approaches to Controlled Diapause in Mammals

Diapause is a coping strategy characteristic to many invertebrates and vertebrates including more than 100 mammalian species. Preserving the genetic diversity of rare and endangered diapausing species is important for maintaining ecological systems. The purpose of this work was to compare the surgic...

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Bibliographic Details
Published inRussian journal of ecology Vol. 55; no. 4; pp. 308 - 318
Main Authors Brusentsev, E. Yu, Rakhmanova, T. A., Rozhkova, I. N., Okotrub, S. V., Kozeneva, V. S., Amstislavsky, S. Ya
Format Journal Article
LanguageEnglish
Published Moscow Pleiades Publishing 01.08.2024
Springer Nature B.V
Subjects
Biomedical and Life Sciences
Blastocysts
Diapause
Dormancy
Ecology
Eflornithine
Embryos
Endangered species
Environment
Genetic diversity
Life Sciences
Mammals
Pharmacology
Putrescine
Rare species
Species diversity
Uterus
Vertebrates
DL-α-difluoromethylornithine
diapausing embryos
genome resource banking
mice
putrescine
in vitro culture
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Summary:Diapause is a coping strategy characteristic to many invertebrates and vertebrates including more than 100 mammalian species. Preserving the genetic diversity of rare and endangered diapausing species is important for maintaining ecological systems. The purpose of this work was to compare the surgical model of diapause and the pharmacological model based on injecting DL-α-difluoromethylornithine (DL-α-DFMO) into mice. Another goal was to investigate the intriguing possibility of controlling the state of diapause in vitro by exposing murine embryos to putrescine and/or DL-α-DFMO. Although the pharmacological model a priori seems to be attractive for applying it to other mammalian species besides mice, since it does not require surgical intervention, our results on mice demonstrated that this model is less effective compared to the traditional surgical model of diapause. Our data indicates that the effects of DL-α-DFMO on mouse embryos are mediated via its effect on the uterus, as it was not possible to maintain dormancy state in diapausing embryos in vitro by this agent. Meanwhile, in vitro exposure to putrescine facilitates the re-activation of diapausing embryos, as evidenced by the higher rate of blastocysts adhesion and the more advanced stages of ICM outgrowth compared to controls. Our results on mice presented hereby indicate that the surgical model is more reliable than DL-α-DFMO diapause model. Moreover, our results proved that putrescine is a potent tool to re-activate murine diapausing embryos in vitro; this may be considered an ecologically important issue relevant to the conservation problem.
ISSN:1067-4136
1608-3334
DOI:10.1134/S1067413624700097