Summary information for Papua New Guinea Fishes.

<p>Fished and Non-fished refer to the number of species within each of these categories. Fished species are >30 cm SL while non-fished are <30 cm SL.</p

Regression analyses of human population size and the number of either fished or not-fished species.

<p>Human population has been log transformed.</p

Results of nestedness analyses.

<p>NODF stands for “Nested metric based on overlap and decreasing fill” for the whole data set, NODFc focuses on individual sites, and NODFr focuses on species.</p

Location of sampling areas.

<p>Map downloaded and used with permission from <a href="http://www.d-maps.com" target="_blank">http://www.d-maps.com</a>.</p

Species found in museum collections from 1881–1889 not present in modern species datasets at any of five sampled reef sites.

<p>Maximum Length is reported for the Standard Length (tip of snout to the posterior end of the midlateral portion of the hypural plate).</p

Szucs et al 2014_Data_for_Dryad

The three sheets in the file contain all the data used to assess establishment success, population growth, and dispersal rates of the populations described in the methods section of the manuscript

ANOVA results of the effect of leaf age, maternal line (ML), and the interaction of leaf age and maternal line on the percent dry weight of the iridoid glycosides aucubin and catalpol, the percent dry weight of total iridoid glycosides (aucubin + catalpol), the proportion of iridoids composed of catalpol, trichome length, and leaf strength.

<p>Significant terms are in bold.</p

Iridoid glycoside levels in <i>Verbascum thapsus</i>.

<p>Untransformed means of the percent leaf dry weight of a) aucubin, b) catalpol, c) total iridoids glycosides, and d) the proportions of iridoids composed of catalpol in young, medium, and old leaves of 10 maternal lines (M1-M10) of <i>Verbascum thapsus</i> (common mullein). Reaction norms show lines connecting maternal lineages. Standard error bars are omitted for clarity and are presented in <a href="http://www.plosone.org/article/info:doi/10.1371/journal.pone.0104889#pone.0104889.s005" target="_blank">Tables S5</a>-<a href="http://www.plosone.org/article/info:doi/10.1371/journal.pone.0104889#pone.0104889.s008" target="_blank">S8</a>.</p

Consumption of <i>Verbascum thapsus</i> leaves by a generalist herbivore.

<p>Means and standard errors of the absolute leaf area consumed (in cm²) by <i>Trichoplusia ni</i> (cabbage looper) larvae when presented with a choice between a) young and old leaves (<i>P</i> = 0.001) of <i>V. thapsus</i> and b) a single young leaf, half of which had intact trichomes, and half of which had trichomes removed with a razor blade (<i>P</i><0.0001). Means for the young/old comparison are back-transformed. Means for trichomes intact/removed are un-transformed. See <a href="http://www.plosone.org/article/info:doi/10.1371/journal.pone.0104889#pone.0104889.s003" target="_blank">Tables S3</a> and <a href="http://www.plosone.org/article/info:doi/10.1371/journal.pone.0104889#pone.0104889.s004" target="_blank">S4</a> for feeding trial data.</p

Relationship between feeding damage and chemical defense in <i>Verbascum thapsus</i>.

<p>Scatterplot showing the relationship between <i>Trichoplusia ni</i> feeding damage to <i>V. thapsus</i> and different levels of percent leaf dry weight (arcsin-square-root transformed) composed of catalpol. This defense explained the most variation in caterpillar damage to plants when averaging levels of defense over leaf age (see text for details of the statistical approach).</p