98 CHAPTER 5
the spores and were surrounded by flagellarmembranes.
This difference in origin of the flagellar membrane and
the plasma membrane that surrounds the rest of the
zoospore body could be significant for zoospore func-
tion, because there is evidence that different putative
chemoreceptors occur on the flagella compared with
on the body of a zoospore (Chapter 10).
The cleavage and release of zoospores of the
Oomycota is strongly influenced by environmental
factors; typically, the sporangia must be washed
to remove nutrients and then flooded with water to
induce the cleavage and release of zoospores. Most
members of the Oomycota have remained essentially
aquatic, producing zoospores from sporangia that
remain attached to the hyphae; but some of the
plant-pathogenic Phytophthoraspecies and the related
downy mildew fungi have detachable, wind-dispersed
sporangia. In the case of Phytophthora infestans (potato
blight; Fig. 5.17) and P. erythroseptica(pink rot of
potatoes) these wind-dispersed sporangia will undergo
cleavage and release their zoospores when incubated
in water at a temperature of 12° or lower, but at higher
temperatures (around 20°) the detached sporangia
exhibit “direct” germination by producing a hypha.
This temperature-regulated development seems to
be functionally significant. In Britain and other cool
regions, zoosporesare thought to be the main infect-ive agents of P. infestansbecause the sporangia are pro-
duced, dispersed and land on potato leaves early in the
growing season when the cool, wet conditions would
favor zoospore production. But “direct” germination
of sporangia (by hyphal outgrowth) might be more
important for infection of the tubers later in the
growing season when the temperatures are warmer.
Some of the downy mildew pathogens such as
Pseudoperonospora humulion hops and Plasmopara
viticolaon grapevine typically produce zoospores for
infection through the host stomata. However, some
other downy mildew pathogens (Bremia lactucaeon let-
tuce, Peronospora parasiticaon cruciferous hosts) have
sporangia that usually or always germinate by hyphae,
which then invade through the host epidermal walls.
Several Oomycota are sensitive to the antibacterial
agent streptomycin. At high concentrations this
compound is toxic, but at sublethal concentrations
it interferes with zoospore cleavage, causing the spo-
rangium contents to be released as a multinucleate
mass with several flagella and incapable of coordin-
ated swimming. For this reason, streptomycin was used
at one time to control Pseudoperonospora humuli(hop
downy mildew), although now it has been replaced
by conventional fungicides (Chapter 17). The mode
of action of streptomycin on sporangia is unclear,
but it does not necessarily involve the inhibition ofFig. 5.16(a) Sporangia of Mucorcontaining darkly pigmented spores. (b) Mid-cleavage stage in the sporangium of
Gilbertella persicaria(Zygomycota). Cleavage vesicles (CV) fuse and extend between the nuclei (N) to separate the
sporangium contents into uninucleate spores. ER =endoplasmic reticulum; L =lipid; M =mitochondrion. (Courtesy of
C.E. Bracker; from Bracker 1968.)
(a) (b)