Theriogenology Wild (Jan 2023)

Pregnancy length and health in giant pandas: What can metabolic and urinary endocrine markers unveil?

  • Jella Wauters,
  • Kirsten S. Wilson,
  • Tom Cools,
  • Catherine Vancsok,
  • Tim Bouts,
  • Baptiste Mulot,
  • Antoine Leclerc,
  • Marko Haapakoski,
  • José Kok,
  • Ragnar Kühne,
  • Andreas Ochs,
  • W. Colin Duncan,
  • Simon J. Girling,
  • Thomas B. Hildebrandt,
  • Qiang Zhou,
  • Rengui Li,
  • Yingmin Zhou,
  • Kailai Cai,
  • Yuliang Liu,
  • Rong Hou,
  • Mick Rae,
  • Iain Valentine,
  • Lynn Vanhaecke,
  • Desheng Li

Journal volume & issue
Vol. 3
p. 100063

Abstract

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Mature female giant pandas usually ovulate once a year. This is followed by an obligatory luteal phase, consisting of a long-lasting corpus luteum dormancy phase (CLD; primary increase in progestogens) and a much shorter active luteal phase (AL; secondary increase in progestogens). Varying duration of both the dormant (embryonic diapause) and AL (post-embryo reactivation) phases has hampered unambiguous pregnancy length determination in giant pandas until today. Additionally, progestogen profiles have been considered not to differ between pregnant and pseudopregnant cycles. Only ceruloplasmin, 13,14-dihydro-15-keto-PGF2α (PGFM) and – more recently – estrogens have been assigned diagnostic power so far. Our study investigated the competence of metabolic (fecal output) and Urinary Specific Gravity (USpG)-normalized urinary endocrine (progestogens, PGFM, glucocorticoids (GCM) and ceruloplasmin) markers for pregnancy monitoring including defining the duration of the AL phase length. Research on 24 (6 pregnant, 8 pseudopregnant and 10 non-birth) cycles of 6 giant pandas revealed a fixed AL phase length of 42 days in giant pandas, e.g. representing 6 weeks of post- diapause development in case of pregnancy. Progestogen concentrations were significantly higher in pregnant cycles throughout the majority of the AL phase, with significant higher values during the AL phase in healthy twin compared to singleton pregnancies. GCM concentrations were also markedly higher in giant pandas expecting offspring, with a clear increase towards birth in the final 2 weeks of pregnancy. This increase in GCM was running in parallel with elevating estrogen and PGFM concentrations, and decreasing progestogens. In addition, during the AL phase, a more pronounced decrease in fecal output was obvious for pregnant females. The combined profiles of non-invasive metabolic and endocrine markers, the latter normalized based on USpG, showed a true pregnancy signature during the AL phase. The findings of this study are applicable to retrospective evaluations of non-birth cycles facilitating categorizing those into pseudopregnant or lost pregnancies, with USpG-normalization of the urinary endocrine markers as a prerequisite.

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