Lichens are amazing organisms, drawing out our curiosity
both because of their aesthetic appeal and their novel ecological and
evolutionary characteristics. For over a hundred years, biologists have
supposedly known about their basic composition: they are one of nature’s best examples of a symbiosis, a tight coupling of two or more evolutionarily distinct organisms that can function like a single unit. In the case of lichens, the
two coupled organisms are a fungus and a photosynthetic alga.
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| Encrusting lichens at Newberry National Monument, Deschutes Co., OR, June 2011. |
That basic understanding of lichens as an evolutionary
marriage between alga and fungus remains fact. However, a paper published this
summer significantly expanded the overall picture. Lead author Toby Spribille
and his colleagues provide evidence in the journal Science that many lichens
are symbioses of not just two groups of organisms, but three! How could such a
basic aspect of lichen biology go undetected for so long?
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| Letharia vulpina on tree bark at Diamond Peak Wilderness, OR, May 2013. |
Their surprising discovery came about by careful observation
and testing of what might otherwise pass as a rather mundane question in lichen
biology. The authors were investigating differences in two closely related
species of lichen, Bryoria tortuosa
and B. fremontii. The former species
produces a compound called vulpinic acid that causes the lichen to have a
yellowish color. B. fremontii,
however, lacks (or has reduced production of) the acid and is brown in color.
What had baffled researchers, however, was the failure to find genetic
differences between the two supposed species. Both the ascomycete fungus and
the photosynthetic partner (a green alga called Trebouxia simplex) in the two species had identical sequences when
several genes were studied. Species are expected to have fixed genetic
differences even if their phenotype (their appearance) is very similar.
Spribille and colleagues decided to study the genetic
structure again of the two species by sequencing the mRNA transcriptome. They
confirmed the genetic similarity that had been observed before and also found
little difference in gene expression between B. tortuosa and B. fremontii.
However, when the researchers broadened their search to consider whether the
transcripts they sequenced might match any other types of fungi, they found
that the acid-producing B. tortuosa
produced sequences associated with basidiomycetes, a very different group of
fungi than are typically seen in lichens. The evidence pointed to a third
symbiont in B. tortousa!
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| Apothecia (spore-producing structures) on encrusting lichens. Left: Alpine bloodspot, Ophioparma ventosa, Deschutes National Forest, OR, May 2012. Right: Ochrolechia sp., Bear Valley, Tahoe National Forest, CA, Dec 2009. |
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| Usnea longissima, hanging from a vine maple in the Menagerie Wilderness, Linn Co., OR, Oct 2012. |
With this new finding, the researchers asked whether other
lichen species might potentially harbor basidiomycetes as well. Surveying a
variety of other lichen lineages, they found basidiomycete sequences in 52
different genera distributed across six continents! The basidiomycete lineages
in the lichens seemed to be diverse group of fungi, but they were associated
with specific species. The new group of basidiomycete symbionts is called the
Cyphobasidiales.
Up until now, it had been known that some lichens deviated
from the classic model of two partners in the lichen symbiosis. For instance, some
species have two algal hosts in addition to the fungal partner – both a green
alga and a cyanobacterium (Henskens et al. 2012). However, Spribille et al.’s research
suggests that the typical lichen association is made up of two distinct fungal
lineages and one or two algae. Thus, lichens may typically be threesomes, and
sometimes, even foursomes. As if this wasn’t complicated enough, DNA sequencing
work by Bates et al. (2011) showed that lichens can also have bacterial
communities associated with them. They found unique groups of alpha
proteobacteria associated with the lichen body in 4 species they studied. Apparently
the more that lichens are studied, the more we could describe these remarkable
organisms as comprising their own little ecological worlds!
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| The lichen Cladonia in a residential yard, Humboldt Co., CA, Dec 2009. |
With the relative ubiquity of the third symbiont evident in
sequence data, why haven’t previous researchers seen these basidiomycete
symbionts when looking through the microscope at lichen specimens? It turns out
that the cells are difficult to detect by microscopy. They are small, and on
the periphery of the lichen body, being embedded in a matrix of
polysaccharides. Using florescent molecular tags on rRNA sequences specific to
the basidiomycete partner, however, the new cells and their location in the
lichen thallus (body) became readily apparent.
Interestingly, the new results explain one of the mysteries
that lichen biologists have confronted for a long time, namely that it has been
difficult to recreate the lichen symbiosis in the lab by combining only a
single fungal host and alga. The typical lichen shape was hard to reproduce
with only two partners.
It is fascinating to ponder the evolutionary history that
could lead to such a complex and intimate association of distinct organisms. Green
algae, cyanobacteria, and fungi are not closely related. During the early evolution
of lichens, how did algae first become associated with the body of fungi? Did
early lichens start with two fungal partners plus an alga, or were today’s
lichen ancestors more simple in composition?
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| Lichens covering a rock in coastal scrub near Muir Beach, Marin Co., CA, Oct 2016. |
Whatever the exact evolutionary sequence of events, the
lichen symbiosis appears to have proved to be very successful in terms of
survival and reproductive success. In fact, fossils suggest that associations
of algae and fungi are at least a half billion years old, stretching back to
about the time that invertebrate animals diversified in the Cambrian Explosion,
and before the arrival of vascular plants on land (Yuan et al. 2005). Today,
there are many thousands of species of lichens, inhabiting ecosystems as
diverse as deserts, coniferous rainforests, and coastlines.
References
Brodo IM, Sharnoff
SD North
America . Yale
University
Spribille T, Touvinen V, Resl P, et al. 2016. Basidiomycete
yeasts in the cortex of ascomycete lichens. Science 353:488-492.
Yuan X, Xiao S, Taylor TN. 2005. Lichen-like symbiosis 600
million years ago. Science 308:1017-1020.
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| Lichen (perhaps Amandinea) on wood fence, Pt. Reyes National Seashore, CA, Nov 2008. |
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| Fruticose lichen in redwood forest, Van Duzen County Park, Humboldt Co., CA, 2006. |
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