For about 70 years, Trichoderma spp

For about 70 years, Trichoderma spp. have been known to be
able to attack other fungi, to produce antibiotics that affect other
microbes, and to act as biocontrol microbes (44,45). During this
time, we have learned much about their mechanisms of action and
how they might be used commercially for various purposes.
Some landmarks along the way include the discoveries that
these fungi frequently increase plant growth and productivity (30)
either in the presence (9) or absence (30) of other microorganisms
and that they can induce disease suppression in soils (11). Composted
materials may be suppressive and that suppression may
occur in part as a consequence of activities of Trichoderma spp.
by several different mechanisms (25), as will be discussed in this
session (Hoitink). Further, strains differ remarkably in their abilities
to colonize roots (i.e., to be rhizosphere competent) (1) and
the most effective strains will colonize roots and provide benefits
for at least the life of annual crops (20). In addition, the complex
mechanisms of mycoparasitism, which include directed growth of
Trichoderma toward target fungi, attachment and coiling of Trichoderma
on target fungi, and the production of a range of antifungal
extracellular enzymes, were elucidated, initially in large part by
I. Chet and his students and colleagues (summarized in Chet [10]
and Chet et al. [12]).
Indeed, Trichoderma spp. were demonstrated to be very efficient
producers of extracellular enzymes, with cellulases as the
first example (36,37). Later, these fungi were found to produce a
wide range of other extracellular enzymes and some of these were
implicated in the biological control of plant diseases (17). In the
early 1990s, a series of papers by a range of labs demonstrated
that the mixtures of biocontrol enzymes were very complex, and
the genes encoding many of these were isolated and sequenced