FUNGAL GENETICS, MOLECULAR GENETICS, AND GENOMICS 181
used ESTs to compare the types of genes expressed by
mycelial cultures of two mycorrhizal fungi (Laccaria
bicolorand Pisolithus microcarpus) and also to compare
the genes expressed in symbiotic tissues of Pisolithus
mycorrhizas (Fig. 9.17). By comparison with EST
databases, several of the ESTs could be assigned to func-
tional groups such as genes involved in metabolism,
cell defense, or cell structure. But the majority of ESTs
showed no homology to known genes (as is also true
for whole genome sequences).
A similar EST analysis was reported by Freimoser
et al. (2003), comparing two subspecies of the common
insect-pathogenic fungus Metarhizium anisopliae– one
subspecies (M. anisopliae anisopliae) has a broad host
range and the other (M. anisopliae acridum) is a specific
grasshopper pathogen. Both strains were grown under
conditions that maximize the secretion of insect
cuticle-degrading enzymes, and a surprisingly high
proportion of ESTs could be assigned to functional
categories (Fig. 9.18). Both subspecies had ESTs for
virtually all the pathogenicity-related genes cloned to
date from M. anisopliae.
DNA microarray technology
Essentially, a DNA microarray is a small solid support
such as a microscope slide or a nylon membrane
onto which DNA is spotted (or printed by robotic
techniques) to produce hundreds or thousands of tiny
spots representing different types of DNA, arranged
in a specific order. Messenger RNAs from a sample to
be analyzed are then used to generate cDNAs, which
are fluorescently labeled so that any binding of the
cDNA to the immobilized spots on the microarray
(through complementary base-pairing) can be scanned
automatically by laser technology. There are several
types of microarray, designed for different purposes, but
the main ones usually measure one of the following:
- Changes in the level of gene expression, monitored
automatically by mixing samples of a test DNA
(tagged with red fluorescence) and control DNA
(tagged with green fluorescence) so that the laser
differentiates between the levels of expression of the
test and control DNA. - Changes in genomic gains and losses, again detected
by different levels of red or green fluorescence depend-
ing on the number of copies of a particular gene. - Mutations in DNA, often involving only one or a few
nucleotides.
Most of these applications are used in medicine,
including disease diagnosis, drug development and
tracking disease development, but they are equally
applicable to many aspects of basic biology and they
are becoming ever more widely used because the same
basic techniques can be done cheaply by manual spot-
ting of DNA onto solid supports. They can reveal pat-
terns of differential or coordinated expression of genes
in almost any biological system.Online resourcesGenome News Network – a quick guide to sequenced
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Microarrays: National Center for Biotechnology Infor-
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microarrays.html
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