Abstract
Is it possible to know anything about life we have not yet encountered? We
know of only one example of life: our own. Given this, many scientists are
inclined to doubt that any principles of Earth’s biology will generalize to other
worlds in which life might exist. Let’s call this the “N = 1 problem.” By
comparison, we expect the principles of geometry, mechanics, and chemistry
would generalize. Interestingly, each of these has predictable consequences
when applied to biology. The surface-to-volume property of geometry, for
example, limits the size of unassisted cells in a given medium. This effect is real,
precise, universal, and predictive. Furthermore, there are basic problems all life
must solve if it is to persist, such as resistance to radiation, faithful inheritance,
and energy regulation. If these universal problems have a limited set of possible
solutions, some common outcomes must consistently emerge.
In this chapter, I discuss the N = 1 problem, its implications, and my
response (Mariscal 2014). I hold that our current knowledge of biology can
justify believing certain generalizations as holding for life anywhere. Life on
Earth may be our only example of life, but this is only a reason to be cautious in
our approach to life in the universe, not a reason to give up altogether. In my
account, a candidate biological generalization is assessed by the assumptions it
makes. A claim is accepted only if its justification includes principles of
evolution, but no contingent facts of life on Earth.