Ants are arguably the greatest succ

Ants are arguably the greatest success
story in the history of terrestrial metazoa.
On average, ants monopolize 15–20%
of the terrestrial animal biomass, and in
tropical regions where ants are especially
abundant, they monopolize 25% or more.
But ants did not always run the world. They
do not appear in the fossil record until the
mid-Cretaceous, and for more than the first
half of their history—a period spanning 60
to 80 million years—ants occupied a relatively
modest position in the terrestrial biosphere.
To understand the factors, both
ecological and historical, that contributed to
the rise of the ants, we require a clearer
picture of the stepwise evolution of the
major ant lineages. Now, Grimaldi and Agosti
(1) report in a recent issue of PNAS the
remarkable discovery of a worker ant, preserved
in amber for over 90 million years,
that is clearly assignable to a modern ant
subfamily that contains many familiar extant
species, including carpenter ants. Combined
with other paleontological and phylogenetic
information, this unexpected fossil strongly
indicates that the diversification of many ant
subfamilies occurred earlier and more rapidly
than previously suspected.
Ants represent the family Formicidae in
the insect order Hymenoptera and, like the
yellow jackets, hornets, and paper wasps to
which they are closely related, ants are stinging
wasps. All ants are eusocial, that is, they
live in colonies in which a wingless neuter
daughter caste cooperates to raise subsequent
generations of their mother queen’s
offspring. Like all of its descendants, the
ancestral ant was almost certainly eusocial,
with colonies made up of small bands of
hunter–gatherers living in simple temporary
nests in the soil. From this modest
beginning arose the current diversity of the
family Formicidae, numbering over 9,500
described species and an estimated 3,000 to
9,000 additional species as yet unknown to
science. Today ants occupy keystone positions
in most terrestrial environments, serving
as major conduits of energy and organic
material. They are, for example, important
turners of the soil, matching or exceeding
the activity of earthworms in this role. They
are among the leading predators of invertebrates
in most ecosystems, and in the
Neotropics they are the leading herbivores
as well, with leaf-cutter ants taking more
than 15% of the fresh vegetation (feeding it to a symbiotic fungus, which they in turn
eat).
Interactions with ants have shaped the
evolution of diverse organisms to an astonishing
degree. Ants participate in symbioses—
some facultative, some obligate—with
over 465 plant species in over 52 families (2),
with thousands of arthropod species (3, 4),
and with as-yet-unknown numbers of fungi
and microorganisms (5, 6). Clearly, the
study of most ecosystems must include the
study of the resident ant species. Because of
their complex colony-level behaviors, ants
serve as model organisms for the highly
visible disciplines of behavioral ecology and
sociobiology, particularly in studies focused
on the dynamics of kin selection, with in colony
conflicts of interest, caste differentiation,
and division of labor.