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Organisms living in arctic and alpine environments are increasingly impacted by human activities. To evaluate the potential impacts of global change, a better understanding of the demography of organisms in extreme environments is needed. In this study, we compare the age-specific demography of willow ptarmigan (Lagopus lagopus) breeding at arctic and subalpine sites, and white-tailed ptarmigan (L. leucurus) breeding at an alpine site. Rates of egg production improved with age at the alpine and subalpine sites, but the stochastic effects of nest and brood predation led to similar rates of annual fecundity among 1-, 2-, and 3+-year-old females. All populations had short generation times (T<2.7 years) and low net reproductive rates (R0<1.2). Stable age distributions were weighted towards 1-year-old females in willow ptarmigan (>59%), and to 3+-year-old females in white-tailed ptarmigan (>47%). High damping ratios (rho>3.2) indicated that asymptotic estimates were likely to match natural age distributions. Sensitivity and elasticity values indicated that changes in juvenile survival would have the greatest impact on the finite rate of population change (lambda) in willow ptarmigan, whereas changes to the survival of 3+-year-old females would have a greater effect in white-tailed ptarmigan. High survivorship buffers white-tailed ptarmigan in alpine environments against the potential effects of climate change on annual fecundity, but may make the species more sensitive to the effects of pollutants or harvesting on adult survival. Conversely, processes that reduce annual fecundity would have a greater impact on the population viability of willow ptarmigan in arctic and subalpine environments. If these same demographic patterns prove to be widespread among organisms in extreme environments, it may be possible to develop general recommendations for conservation of the biological resources of arctic and alpine ecosystems.
Organisms living in arctic and alpine environments are increasingly impacted by human activities. To evaluate the potential impacts of global change, a better understanding of the demography of organisms in extreme environments is needed. In this study, we compare the age-specific demography of willow ptarmigan (Lagopus lagopus) breeding at arctic and subalpine sites, and white-tailed ptarmigan (L. leucurus) breeding at an alpine site. Rates of egg production improved with age at the alpine and subalpine sites, but the stochastic effects of nest and brood predation led to similar rates of annual fecundity among 1-, 2-, and 3+-year-old females. All populations had short generation times (T<2.7 years) and low net reproductive rates (R0<1.2). Stable age distributions were weighted towards 1-year-old females in willow ptarmigan (>59%), and to 3+-year-old females in white-tailed ptarmigan (>47%). High damping ratios (rho>3.2) indicated that asymptotic estimates were likely to match natural age distributions. Sensitivity and elasticity values indicated that changes in juvenile survival would have the greatest impact on the finite rate of population change (lambda) in willow ptarmigan, whereas changes to the survival of 3+-year-old females would have a greater effect in white-tailed ptarmigan. High survivorship buffers white-tailed ptarmigan in alpine environments against the potential effects of climate change on annual fecundity, but may make the species more sensitive to the effects of pollutants or harvesting on adult survival. Conversely, processes that reduce annual fecundity would have a greater impact on the population viability of willow ptarmigan in arctic and subalpine environments. If these same demographic patterns prove to be widespread among organisms in extreme environments, it may be possible to develop general recommendations for conservation of the biological resources of arctic and alpine ecosystems.
The tissues of willow ptarmigan in some Norwegian mountain areas contain elevated concentrations of cadmium (Cd). It is not known whether such high Cd levels would have negative impacts in otherwise healthy populations of this species. The aim of the current study was to clarify relationships between hepatic and renal metallothionein (MT) and Cd concentrations in willow ptarmigan to assess effects from this metal. The study reported here was undertaken on willow ptarmigan from the Kongsvoll area, with a naturally high Cd load, and the Essand area, with a naturally low Cd load. Cd values in liver and kidney in willow ptarmigan from Kongsvoll were significantly higher than in willow ptarmigan from Essand. The MT content in both tissues was also highest in willow ptarmigan from Kongsvoll. The MT concentration in kidney was twice that in liver for ptarmigan from both areas and at all times of the year. The MT level in both liver and kidney varied greatly throughout the season, with the highest content in spring (May). The variation was greatest in liver. The total material showed a significant linear relationship between Cd and MT levels in both liver and kidney, but a breakdown of the material into seasons and areas gave a varying degree of significance. MT in willow ptarmigan may be an important mechanism for detoxifying Cd, and populations exposed to high load may "respond" to the loads by increasing MT synthesis in tissues such as liver and kidney. There is no evidence that willow ptarmigan from areas with high natural Cd loads have reached a limit for MT synthesis in either liver or kidney.
The objective of this study was to examine effects of sublethal cadmium (Cd) contamination on parental behaviour and chick survival in willow ptarmigan (Lagopus lagopus) in an area that does not have high environmental levels of Cd due to geology but have high environmental levels of Cd due to anthropogenic deposition and acidification. One group of willow ptarmigan hens were exposed to Cd (83.2 mg Cd/L) after egg-laying using osmotic minipumps; whereas, another group given saline served as a control. No statistically significant difference in Cd concentration between the two groups was found. There was a significant correlation between the Cd concentrations in the liver and kidney of the birds and between Cd and metallothionein (MT) concentration in the kidney. No significant differences were found between the control hens and the Cd-contaminated hens with respect to any of the behaviour parameters. Age seemed to be more important than Cd treatment as adult hens showed more distraction display, had lower flushing distance, and higher brood attendance than juveniles. There were no difference in chick survival between Cd-contaminated and control hens, and there was no correlation between Cd concentrations and chick survival. The non-significant effects of Cd concentrations on parental behaviour may be due high environmental levels of Cd caused by anthropogenic deposition and acidification. We suggest that willow ptarmigan in the area have gradually evolved abilities to cope with high environmental levels of Cd, for instance, by binding Cd to MT in kidney and liver. This may suggest that Cd exerts a strong selection pressure on birds causing a relatively rapid evolution of protection mechanisms.
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