Abstract
Alternative metrics exist for representing variation in plant body size, but the vast majority of previous research for herbaceous plants has focused on dry mass. Dry mass provides a reasonably accurate and easily measured estimate for comparing relative capacity to convert solar energy into stored carbon. However, from a “plant's eye view”, its experience of its local biotic environment of immediate neighbors (especially when crowded) may be more accurately represented by measures of “space occupancy” (S–O) recorded in situ—rather than dry mass measured after storage in a drying oven. This study investigated relationships between dry mass and alternative metrics of S–O body size for resident plants sampled from natural populations of herbaceous species found in Eastern Ontario. Plant height, maximum lateral canopy extent, and estimated canopy area and volume were recorded in situ (in the field)—and both fresh and dry mass were recorded in the laboratory—for 138 species ranging widely in body size and for 20 plants ranging widely in body size within each of 10 focal species. Dry mass and fresh mass were highly correlated (r 2 > .95) and isometric, suggesting that for some studies, between‐species (or between‐plant) variation in water content may be unimportant and fresh mass can therefore substitute for dry mass. However, several relationships between dry mass and other S–O body size metrics showed allometry—that is, plants with smaller S–O body size had disproportionately less dry mass. In other words, they have higher “body mass density” (BMD) — more dry mass per unit S–O body size. These results have practical importance for experimental design and methodology as well as implications for the interpretation of “reproductive economy”—the capacity to produce offspring at small body sizes—because fecundity and dry mass (produced in the same growing season) typically have a positive, isometric relationship. Accordingly, the allometry between dry mass and S–O body size reported here suggests that plants with smaller S–O body size—because of higher BMD—may produce fewer offspring, but less than proportionately so; in other words, they may produce more offspring per unit of body size space occupancy.
Highlights
Competition is one of the most important processes affecting the structure of plant communities (Tilman, 1982)
We tested whether relationships between dry mass and “space occupancy” (S–O) body size metrics are proportional, and we assessed the implications of proportionality when using relative body size to predict reproductive success, and consequent success in gene transmission, when body size is limited by neighborhood crowding
The important question is as follows: To what extent are fresh and dry mass correlated? Schamp and Aarssen (2014) found, in a greenhouse study, that a 10-fold variation in fresh mass across 10 study species was uncorrelated with dry mass
Summary
Competition is one of the most important processes affecting the structure of plant communities (Tilman, 1982). Body size in plants has been measured most commonly in terms of height, stem diameter, and dry mass Relationships between these metrics have been studied both between- and within-species (Anten & Hirose, 1999; Henry & Aarssen, 1999; Mandak & Pysek, 1999; Nagashima & Terashima, 1995; Niklas, 1995; Reddy, Pachepsk, & Whisler, 1998; Weiner & Fishman, 1994; Weiner & Thomas, 1992). We tested whether relationships between dry mass and “space occupancy” (S–O) body size metrics are proportional (isometric vs. allometric), and we assessed the implications of proportionality (or departure from it) when using relative body size to predict reproductive success, and consequent success in gene transmission, when body size is limited by neighborhood crowding
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