Domestic Dogs (Canis Familiaris)

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Dogs have become increasingly popular as model organisms in longevity research due to their diverse breeds, sizes, and lifespans. This makes them excellent subjects for studying aging and its related processes.[1]

Reasons for Choosing Dogs

Dogs share many environmental exposures with humans and exhibit a wide range of lifespans and physiological traits. This diversity provides a unique opportunity to study the genetic and environmental factors affecting longevity.

Comparative Biology of Aging in Dogs

 
Survivorship (a) and hazard curves for (b) for human (left) and dogs (right). Human data are from the U.S. Census Bureau (1972–2002), and canine data come from the VetCompass database (2010–2013). For both species, colors represent the two sexes, female (red) and male (blue). [1]

The biology of aging in dogs varies significantly across breeds, offering insights into how genetic diversity influences aging. Studies on canine aging also help in understanding age-related diseases and their progression.

Genetic Factors in Canine Longevity

Research into the canine genome has identified various genetic factors that contribute to their longevity. These findings are crucial for understanding the genetic basis of aging and developing interventions to extend healthy lifespan.

Environmental and Lifestyle Factors

Factors such as diet, exercise, and living conditions play a significant role in the longevity of dogs. These aspects offer valuable insights into how lifestyle choices impact aging and healthspan.

See Also

References

  1. 1.0 1.1 Hoffman JM et al.: The companion dog as a model for human aging and mortality. Aging Cell 2018. (PMID 29457329) [PubMed] [DOI] [Full text] Around the world, human populations have experienced large increases in average lifespan over the last 150 years, and while individuals are living longer, they are spending more years of life with multiple chronic morbidities. Researchers have used numerous laboratory animal models to understand the biological and environmental factors that influence aging, morbidity, and longevity. However, the most commonly studied animal species, laboratory mice and rats, do not experience environmental conditions similar to those to which humans are exposed, nor do we often diagnose them with many of the naturally occurring pathologies seen in humans. Recently, the companion dog has been proposed as a powerful model to better understand the genetic and environmental determinants of morbidity and mortality in humans. However, it is not known to what extent the age-related dynamics of morbidity, comorbidity, and mortality are shared between humans and dogs. Here, we present the first large-scale comparison of human and canine patterns of age-specific morbidity and mortality. We find that many chronic conditions that commonly occur in human populations (obesity, arthritis, hypothyroidism, and diabetes), and which are associated with comorbidities, are also associated with similarly high levels of comorbidity in companion dogs. We also find significant similarities in the effect of age on disease risk in humans and dogs, with neoplastic, congenital, and metabolic causes of death showing similar age trajectories between the two species. Overall, our study suggests that the companion dog may be an ideal translational model to study the many complex facets of human morbidity and mortality.