<div dir="ltr"><div>A couple of new climate change articles along with some older related ones as food for thought...</div><div><br></div><div><div>Patricia S. De Angelis, Ph.D.</div><div>Botanist, Division of Scientific Authority-US Fish & Wildlife Service-International Affairs</div>
<div>Chair, Medicinal Plant Working Group-Plant Conservation Alliance</div><div>4401 N. Fairfax Dr., Suite 110</div><div>Arlington, VA 22203</div><div>703-358-1708 x1753</div><div>FAX: 703-358-2276</div><div><br></div><div>
Promoting sustainable use and conservation of our native medicinal plants. </div><div><<a href="http://www.nps.gov/plants/medicinal" target="_blank">www.nps.gov/plants/medicinal</a>></div><div><br></div><div>Follow International Affairs</div>
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</div><div><br></div><div>--------------------</div><div><br></div><div><br></div><div><p class=""><a name="_GoBack"></a><b><a href="http://pubs.usgs.gov/of/2013/1150/" target="_blank">Abundance,
distribution, and population trends of the iconic Hawaiian Honeycreeper, the
ʻIʻiwi (Vestiaria coccinea) throughout the Hawaiian Islands</a>:</b> Based
on the most recent surveys (up to 2012), approximately 50 percent of ʻIʻiwi
live in a narrow, 500-meter band at elevations of 1,200–1,700 meters,
suggesting that ʻIʻiwi are vulnerable to future shifts in climate. <i>(Paxton,
E.H., Gorresen, P.M., and Camp, R.J., 2013, U.S. Geological Survey Open-File
Report 2013-1150, 59 p. The URL for this publication is </i><a href="http://pubs.usgs.gov/of/2013/1150/" target="_blank"><i>http://pubs.usgs.gov/of/2013/1150/</i></a><i>)</i></p>
<p class="">RELATED: </p><p class=""><b><u>Evolutionary Consequences of Extinctions in
Populations of a Hawaiian Honeycreeper</u>: </b><span lang="EN">We report on the
evolutionary change in bill size of a species of Hawaiian honeycreeper
resulting from an apparent dietary shift caused by dramatic declines and
extinctions of lobelioids, a historically favored nectar source. Although it
now feeds mainly on the flowers of the ohia tree (<i>Metrosideros polymorpha</i>),
early Hawaiian avifaunal accounts report that the i’iwi (<i>Vestiaria coccinea</i>),
which has a long decurved bill, fed primarily on the flowers of Hawaiian
Lobelioideae, which typically have long decurved corollas. A coevolutionary
association of i’iwi bill and flower morphology has often been asserted. We
test the hypothesis that the shift in the i’iwi’s diet from the long corolla
lobelioid flowers to ohia flowers, which lack corollas, resulted in directional
selection for shorter bills. We evaluate this hypothesis by comparing the
morphological characters of museum specimens from the island of Hawaii
collected before 1902 with recent specimens from the Hakalau National Wildlife
Refuge, Hawaii. We examine evidence of change in morphological characters using
multivariate analysis and a nonparametric cubic spline technique. Results from
all analyses are congruent: bill length is shorter in recent specimens. </span><i>(Thomas B. Smith, Leonard A. Freed, Jaan
Kaimanu Lepson and John H. Carothers</i><i>. 1995. Conservation BIology 9(1):107-113. Available
for a fee at <a href="http://www.jstor.org/stable/2386392">http://www.jstor.org/stable/2386392</a>)</i></p><p class=""></p><p class="">
</p><p class="">----- </p><p class=""><a href="http://onlinelibrary.wiley.com/doi/10.1002/ece3.720/abstract?systemMessage=Wiley+Online+Library+will+be+disrupted+on+31+August+from+10%3A00-12%3A00+BST+%2805%3A00-07%3A00+EDT%29+for+essential+maintenance" target="_blank"><b>Dramatic response to climate change in the Southwest: Robert
Whittaker's 1963 Arizona Mountain plant transect revisited</b></a><b>:</b> <span lang="EN">This research provides the first
documentation of significant upward shifts of lower elevation range boundaries
in Southwestern montane plant species over decadal time, confirming that
previous hypotheses are correct in their prediction that mountain communities
in the Southwest will be strongly impacted by warming, and that the Southwest
is already experiencing a rapid vegetation change. Researchers reexamined
Robert Whittaker's 1963 plant transect in the Santa Catalina Mountains of
southern Arizona, finding that this process is already well underway. Our
survey, five decades after Whittaker's, reveals large changes in the
elevational ranges of common montane plants, while mean annual rainfall has
decreased over the past 20 years, and mean annual temperatures increased
0.25°C/decade from 1949 to 2011 in the Tucson Basin. Although elevational
changes in species are individualistic, significant overall upward movement of
the lower elevation boundaries, and elevational range contractions, have
occurred. </span><i>(Brusca et al., Ecology and Evolution, 2013;
DOI: </i><a href="http://dx.doi.org/10.1002/ece3.720" target="_blank"><i>10.1002/ece3.720</i></a><i>)</i><br></p><p class=""></p>
<p class="">RELATED: <br></p>
<p class=""><b><a href="http://pielkeclimatesci.files.wordpress.com/2009/10/r-198.pdf">Evidence
that local land use practices influence regional climate, vegetation, and
stream flow patterns in adjacent natural areas</a>. </b><span lang="EN">Stohlgren et al. presented evidence that land use
practices, in the plains of Colorado, influence regional climate and vegetation
in adjacent natural areas of the Rocky Mountains in predictable ways. The
results of the mesoscale climate model simulations were consistent with coarser
resolution RAMS simulations for the coterminous United States, that indicated
that land use change caused July temperatures to decrease in the vicinity of
the southern Rocky Mountains and increase in the eastern central Great Plains.
Those coarser-resolution simulations also showed July precipitation to increase
over the mountains of Colorado and decrease over the eastern Colorado plains
under current landscapes compared to natural vegetation cover. The authors
corroborate the RAMS simulations with three independent sets of data: (1)
climate records from 16 weather stations, (2) the distribution of seedlings of
five dominant conifer species in Rocky Mountain National Park, which suggested
that cooler, wetter conditions occurred over roughly the same time period; and
(3) increased stream flow during the summer months in four river basins, which
also indicates cooler summer temperatures and lower transpiration at landscape
scales. Combined, the mesoscale atmospheric/land-surface model, short-term
trends in regional temperatures, forest distribution changes, and hydrology
data indicate that the effects of land use practices on regional climate may
overshadow larger-scale temperature changes commonly associated with observed
increases in CO2 and other greenhouse gases.</span><b><span lang="EN"> </span></b>(Stohlgren, T.J., T.N. Chase, R.A. Pielke,
T.G.F. Kittel, and J. Baron, 1998: <b>
</b>Global Change Biology, 4, 495-504. <a href="http://pielkeclimatesci.files.wordpress.com/2009/10/r-198.pdf">http://pielkeclimatesci.files.wordpress.com/2009/10/r-198.pdf</a>)<b></b></p>
<p class="">RELATED: <br></p>
<p class=""><b><span lang="EN"><a href="http://www.sciencemag.org/content/331/6015/324.full.pdf">Changes in
Climatic Water Balance Drive Downhill Shifts in Plant Species’ Optimum
Elevations</a></span></b> Uphill
shifts of species’ distributions in response to historical warming are well
documented, which leads to widespread expectations of continued uphill shifts
under future warming. Conversely, downhill shifts are often considered
anomalous and unrelated to climate change. By comparing the altitudinal distributions
of 64 plant species between the 1930s and the present day within California, we
show that climate changes have resulted in a significant downward shift in
species’ optimum elevations. This downhill shift is counter to what would be
expected given 20th-century warming but is readily explained by species’ niche
tracking of regional changes in climatic water balance rather than temperature.
Similar downhill shifts can be expected to occur where future climate change
scenarios project increases in water availability that outpace evaporative
demand. <span lang="EN">(Shawn M. Crimmins, Solomon
Z. Dobrowski, Jonathan A. Greenberg, John T. Abatzoglou, Alison R.
Mynsberge, 2011:. Science, 21 January 2011: 324-327. <a href="http://www.sciencemag.org/content/331/6015/324.full.pdf">http://www.sciencemag.org/content/331/6015/324.full.pdf</a>)</span></p>
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