detoxify tomatine, and tomatinase (from S. lycopersici)
had negligible ability to detoxify avenacin. So it seems
that these pathogenic fungi have evolved saponin-
detoxifying enzymes with quite specific activity
against the saponins of their hosts.Yeast killer systemsWith this topic we return to the role of viral dsRNA.
Individual species of at least eight genera of yeasts
(Saccharomyces, Candida, Kluyveromyces, etc.) have
been found to contain killer strains. These strains
secrete a protein that kills other strains of the same
species but not of unrelated species. The toxin binds
to a receptor on the wall of susceptible cells, then passes
to the membrane where it causes leakage of H+, and
the cells die owing to loss of transmembrane poten-
tial and disruption of amino acid uptake, K+balance,
etc. The toxins are stable only at low pH and are
thought to give a significant advantage to killer strains
over nonkiller strains of the same species in acidic
environments.
In Kluyveromyces lactisthe toxin is encoded by a
linear DNA plasmid, but in all other cases it is encoded
by dsRNA. Both the killer and nonkiller strains cancontain virus-like particles (VLPs) so this feature alone
does not correlate with killer activity. However, these
particles are found to be of two types: the dsRNA in
the “L type” encodes the virus coat protein, whereas
the dsRNA in the “M type” codes for the toxin. The M
dsRNA depends on the L dsRNA for the coat protein,
but the L dsRNA can occur alone with no effect on
the cells.
The molecular biology of the killer system in S. cere-
visiaehas been studied intensively and has shown
why the toxin producers are not affected by their own
toxin. They produce the toxin as a large precursor pro-
tein which undergoes changes during passage through
the secretory system to produce a protoxin. This
protoxin is finally cleaved at the cell membrane, to
release the active toxin but leave part of the molecule
in the membrane. This residual part seems to interact
with a toxin receptor, making the cell resistant to
active toxin in the external environment.
Similar dsRNA killer systems are found in the yeast
phase of Ustilago maydis(Basidiomycota) which causes
smut disease of maize. A killer system might also
occur in the take-all fungus Gaeumannomyces graminis,
because some dsRNA-containing strains can markedly
inhibit the growth of other strains at low pH. However
the mechanism in this case remains unknown.FUNGAL GENETICS, MOLECULAR GENETICS, AND GENOMICS 173
Fig. 9.12Structures of two saponins that are pre-formed resistance compounds in plants: avenacin in roots of oats,
and α-tomatine in tomato. Pathogens with the appropriate enzymes can detoxify these compounds by cleaving some
of the terminal sugar residues.