The role of cyanobacterial crusts i

The role of cyanobacterial crusts in arid soil water retention is
complex. Semi-arid, loamy soil environments enjoy increased
infiltration and retention of water when biological soil crusts are
present. In these climates, cyanobacteria prevent physical surface
sealing (Morin and Benyamini, 1977). In the arid desert climate,
where sandy soils naturally experience even infiltration, cyanobacterial
crusts seem to decrease infiltration and cause runoff much
like physical soil crust. This runoff, in turn causes redistribution of
water resources, imparting diversity to the soil systems within the
desert ecosystem (Yair, 2001). It is, however, very important to note
that previously desiccated cyanobacteria absorb a great deal of
water prior to saturation before facilitating runoff. Campbell (1979)
and Wang et al. (1981) report cyanobacterial sheaths may absorb
up to 12 times their dry weight and increase their volume up to 10
times (Yair, 2001).
6. Toxin production by microorganisms and prokaryotes in
desert environments
While the viral and bacterial constituents of desert soil have
been extensively studied due to their presence in dust storms, little
is known about toxin-producing microorganisms other than cyanobacteria.
Vastly diverse communities of fungi have been
discovered living within biological soil crusts. These fungi most
likely play a role in organic plant material breakdown in a symbiotic
or mutualistic relationship with plant species. Taxa of fungal species
in cyanobacterial crusts in Utah and Wyoming included
Aspergillus spp., Fusarium spp. and Cladosporium spp. (States et al.,
2001). The presence of these fungal species and their adverse
health effects in human domiciles has been extensively studied
(Cabral, 2010; Hedayati et al., 2010). Although most health effects