Squamate metabolic rates decrease in winter beyond the effect of temperature
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Sep 05, 2023 version files 39.48 KB
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Abstract
- The reptilian form of hibernation (brumation) is much less studied than its mammalian and insect equivalents. Hibernation and brumation share some basic features but may differ in others. Evidence for hypometabolism in brumating reptiles beyond the effect of temperature is sporadic and often ignored.
- We calculated the standard metabolic rates (SMR, oxygen uptake during inactivity), in winter and/or summer, of 156 individuals representing 59 species of Israeli squamates across all 17 local families. For 32 species, we measured the same individuals during both seasons. We measured gas exchange continuously in a dark metabolic chamber, under the average January high and low temperatures (20°C and 12°C), during daytime and nighttime. We examined how SMR changes with season, biome, body size, temperature, and time of day, using phylogenetic mixed models.
- Metabolic rates increased at sunrise in the diurnal species, despite no light or other external cues, while in nocturnal species the metabolic rates did not increase. Cathemeral species shifted from a diurnal-like diel pattern in winter to a nocturnal-like pattern in summer. Regardless of season, Mediterranean species SMRs were 30% higher than similar-sized desert species. Summer SMR of all species together scaled with body size with an exponent of 0.84 but dropped to 0.71 during brumation. Individuals measured during both seasons decreased their SMR between summer and winter by 47%, on average, at 20°C and by 70% at 12°C. Q10 was 1.75 times higher in winter than in summer, possibly indicating an active suppression of metabolic processes under cold temperatures.
- Our results challenge the commonly held perception that squamate physiology is mainly shaped by temperature, with little role for intrinsic metabolic regulation. The patterns we describe indicate that seasonal, diel, and geographic factors can trigger remarkable shifts in metabolism across squamate species.
Dubiner, Shahar; Jamison, Simon; Meiri, Shai; Levin, Eran. (2023).
Squamate metabolic rates decrease in winter beyond the effect of temperature [Dataset].
Dryad. https://doi.org/10.5061/dryad.tdz08kq52.
Tables 1-4 show the data used for all analyses in the paper.
- Table 1: Respirometric measurement results for the individuals measured during both seasons.
- Table 2: Respirometric measurement results for all individuals measured in this study at 20°C.
- Table 3: Respirometric measurement results for all individuals measured in this study at 12°C.
- SMR = standard metabolic rate, given as ml O2 / hour. Values are the geometric mean for all n individuals of the species.
- Mass is in grams (the geometric mean for all n individuals of the species).
- Table 4: Daily changes in the resting metabolic rate of the 32 individuals measured during both seasons.
- “Value” is the mean normalized (mean=0, SD=1) resting metabolic rate at 12°C calculated from CO2 production for each of the categories (diurnal/nocturnal/cathemeral) divided into 1-hour segments.
- Statistics are comparisons of each segment to the segment with the lowest value.