Our
survey work in Oregon 's coastal wetlands
showed patterns of species distribution suggesting how and which species might
be vulnerable to climate change on the Pacific Northwest
coast. In previous posts, I discussed
some of our findings relative to wetland algae and plants. However it was
important to extend our knowledge of climate impacts by conducting controlled
experiments too. During the summer of 2012 I was fortunate to work with an
enthusiastic summer intern who participated in an EPA program that gives
undergraduate students from smaller liberal arts colleges opportunities to work
in federal research labs.
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| Seedlings. |
The
project we conducted was a short-term experiment to assess the dual effects of
salinity and flooding on wetland plant productivity. We used seven species that
were easily grown from seed; most are commonly found in Oregon
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| Some of the experimental pots placed at three tidal elevations at one of our sites. A blue salinity sensor can be seen at bottom center; a tall white stilling well with a water level sensor is at the right. |
To
conduct the experiment with a range of salinities, we planned to work at three
sites in the Yaquina estuary - one near the mouth of the estuary and two
farther inland. We placed salinity/temperature sensors in the field track
conditions over the course of the experiment and the data time confirmed that
our sites had quite different salinity profiles.
To
create differences in flooding intensity among treatments, we planned to set out
plants at three tidal elevations at each site. We used mean higher high water
(MHHW) as our baseline, which is about a mid-marsh elevation on the Oregon US
In mid June, with some welcome help from another summer intern, we excavated terraces from the channel banks to place several hundred potted seedlings into the field. It was two long and very muddy days of field work!
Our
plants grew under different salinities and flooding levels for five weeks. This
was a relatively short length of time - constrained by the limited period of
the internship - but long enough to assess treatment effects on the seedlings.
We checked on the plants about every week and some were lost to the vagaries of
field experimentation. (I think a few were uprooted by birds.) During our
checks we noted which plants browned, probably due to physiological intolerance
of environmental conditions.
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| Above ground dry mass (means and SE) of Grindelia stricta seedlings grown at 3 tidal elevations in low, moderate and high salinity wetlands. Like Grindelia, most species we investigated had lower above- and below- ground growth with greater flooding and/or greater salinity. |
By mid
summer, the experimental results were pretty unequivocal. All species,
including one that we expected to be most tolerant of flooding and salinity
stress based on its field distribution, grew less with higher salinity and/or
greater flooding. Species seemed to differ in terms of their sensitivity to one
experimental factor or the other, but all showed the same trend.
One
concept we explored in the study was idea that "salinity exposure" -
the combined effects of both flooding and salinity - could account for
differences in plant productivity. In other words, we tested whether plants
exposed to low salinity for long periods of time might be stressed as much as plants
exposed to higher salinity for shorter periods of time. We created a simple
index to quantify this total exposure and found that it correlated reasonably
well with plant biomass for a number of species in the study.
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| Change in shoot dry mass in Plantago maritima seedlings with increasing salinity exposure. Our salinity index combined the length of exposure to flooding with absolute levels of local salinity. The index would be 0 in wetlands that are never flooded by salt water and ~33 for at a site continuously submerged in full seawater. Intermediate values could be due to long exposure to low salinity water or brief flooding by higher salinity water. |
In
terms of future sea-level rise, the overall results seemed pretty clear: for the
species we investigated, if vertical marsh growth cannot match sea-level rise,
plant production is expected to decline. Of course any increase in flooding or
salinity at a given site would occur over the scale of decades, not the short
time scale of our study. Yet declines in plant production in future wetlands
might result in less food for marsh consumers and less detritus for the
formation of new wetland soils.
I
really enjoyed conducting this study. I was nervous about whether our seedlings
would grow in the lab or whether they would quickly get destroyed once
transplanted in the field. But the plants were hardy enough (or we had enough
luck) to give us a good data set. Conducting this research, I had an opportunity
to think about plant physiology and environmental stress. I read about some
basic ideas in plant ecology such as how plants may trade off allocation of
resources to above (shoot) or below-ground (root) production.
Though
exciting, manipulative field experiments are challenging! The goal is to
isolate factors to determine cause and effect, but at the same time maintain
conditions that are as realistic as possible. Also, ecologists often want to be
able to derive broad conclusions about such experiments, but various
constraints often mean it is necessary to work at a single site, with a limited
number of species, or only for a limited period of time. After conducting
experiments such as these, it is important to ask: would different species or
locations or seasons give different results? Extracting generalities from such
complex ecosystems is a rewarding, but heavy intellectual challenge.
Reference
Janousek CN, Mayo C. 2013. Plant responses to increased inundation and salt exposure: interactive effects on tidal marsh productivity. Plant Ecology 214:917-928.
Reference
Janousek CN, Mayo C. 2013. Plant responses to increased inundation and salt exposure: interactive effects on tidal marsh productivity. Plant Ecology 214:917-928.
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