Robert McMahon scite author profile

Invasive species have been characterized as tolerant of environmental extremes. This hypothesis was evaluated for invasive aquatic species in North America, particularly Asian clams, Corbicula fluminea, and zebra mussels, Dreissena polymorpha. Both species have rapid growth, early maturity, short life spans, and elevated fecundity, allowing rapid population recovery after reductions by rarefractive, environmental extremes. Extensive resistance capacities offer little adaptive value to invasive, r-selected species, because population reductions occur in their unstable habitats regardless of degree of stress tolerance. Thus, both species have relatively poor physiologic resistance, depending instead on elevated growth and fecundity for rapid population recovery. In contrast, native North American bivalve species are often adapted to stable habitats where perturbation is infrequent (i.e., freshwater unionoidean bivalves). They are characterized by slow growth, extended life spans, and low effective fecundities, slowing population recoveries (K-selected), and have evolved extensive resistance adaptations to avoid extirpation during environmental extremes. Review of resistance adaptations in other North American aquatic invaders revealed poorer or equivalent physiological tolerance relative to taxonomically related native species, suggesting that extensive physiological tolerance is not required for invasive success.

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Mollusca: Bivalvia

McMahon

Bogan

2001

166

156

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The Physiological Ecology of the Zebra Mussel,Dreissena polymorpha, in North America and Europe

McMahon

1996

Am Zool

195

133

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Ecology of an Invasive Pest Bivalve, Corbicula

McMahon

1983

126

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Mutational bias provides a model for the evolution of Huntington's disease and predicts a general increase in disease prevalence

Rubinsztein¹,

Amos

Leggo³

et al. 1994

Nat Genet

134

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Huntington's disease (HD) correlates with abnormal expansion in a block of CAG repeats in the Huntington's disease gene. We have investigated HD evolution by typing CAG alleles in several human populations and in a variety of primates. We find that human alleles have expanded from a shorter ancestral state and exhibit unusual asymmetric length distributions. Computer simulations are used to show that the human state can be derived readily from a primate ancestor, without the need to invoke natural selection. The key element is a simple length-dependent mutational bias towards longer alleles. Our model can explain a number of empirical observations, and predicts an ever-increasing incidence of HD.

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Robert McMahon

Evolutionary and physiological adaptations of aquatic invasive animals: r selection versus resistance

Mollusca: Bivalvia

The Physiological Ecology of the Zebra Mussel,Dreissena polymorpha, in North America and Europe

Ecology of an Invasive Pest Bivalve, Corbicula

Mutational bias provides a model for the evolution of Huntington's disease and predicts a general increase in disease prevalence

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