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Population structure, growth rates and spatial distribution of two dioecious tree species in a wet forest in Puerto Rico

Published online by Cambridge University Press:  28 May 2010

Jimena Forero-Montaña ,
Jess K. Zimmerman  and
Jill Thompson
Jimena Forero-Montaña*
Affiliation:
Department of Biology, University of Puerto Rico, Rio Piedras, San Juan, P.R.USA00936-8377
Jess K. Zimmerman
Affiliation:
Institute for Tropical Ecosystem Studies, University of Puerto Rico, Rio Piedras, San Juan, P.R. 00936-8377USA
Jill Thompson
Affiliation:
Institute for Tropical Ecosystem Studies, University of Puerto Rico, Rio Piedras, San Juan, P.R. 00936-8377USA
*
1Corresponding author. Email: jimefore@yahoo.com
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Abstract:

Dioecious plants often exhibit male-biased sex ratios and sexual differences in life history traits such as plant size, growth rate and frequency of flowering, which arise from the different costs of reproduction for male and female plants. In tropical dioecious species sexual differences in reproductive costs have been demonstrated for several subcanopy species, but few canopy dioecious trees have been studied. We recorded the sexual expression of c. 2600 trees of Cecropia schreberiana and Dacryodes excelsa, two canopy dioecious species, during several censuses over 2 y in a 16-ha plot located in ‘subtropical wet forest’ in the Luquillo Mountains, Puerto Rico. There were similar numbers of male and female trees of C. schreberiana but D. excelsa had a female-biased population. Cecropia schreberiana showed no differences in male and female diameter distributions or growth rates, suggesting that reproductive maturation and longevity are similar for both sexes. This lack of differences in size and growth rate in C. schreberiana may result from mechanisms to compensate for the higher cost of reproduction in females, no resource limitation related to its pioneer life-history, or similar male and female reproductive costs. In contrast, D. excelsa males were larger than females, probably because males grow slightly faster than females. This sexual difference in D. excelsa may reflect a higher cost of reproduction in females than in males. Spatial segregation of males and females into different habitats is not common in tropical forest and neither C. schreberiana nor D. excelsa males and females exhibited significant spatial segregation. The contrasting results for these two canopy species reflect their different life history strategies in this hurricane-affected forest.

Keywords

BurseraceaeCecropiaceaedioecyLuquillo Forest Dynamics Plotsexual dimorphismsex ratiosize distributiontropical trees
Type
Research Article
Information
Journal of Tropical Ecology , Volume 26 , Issue 4 , July 2010 , pp. 433 - 443
Copyright
Copyright © Cambridge University Press 2010

INTRODUCTION

Dioecious plants may exhibit sex-dependent life-history traits if females allocate a greater proportion of their resources to reproduction and a smaller amount to maintenance and growth than males (Lloyd & Webb Reference LLOYD and WEBB1977, Obeso Reference OBESO2002). Sex differences in reproductive costs arise because the resources required per seed are usually greater than per pollen grain. Differential resource allocation to vegetative versus reproductive processes could produce a male-biased dioecious population if females face a higher risk of mortality than males particularly when resources are limited (Bierzychudeck & Eckhart Reference BIERZYCHUDEK and ECKHART1988, Meagher & Antonovics Reference MEAGHER and ANTONOVICS1982). In addition, females may appear to be underrepresented in a population if they delay flowering and reproduction (Nicotra Reference NICOTRA1998, Thomas & LaFrankie Reference THOMAS and LAFRANKIE1993), or if they flower less frequently than males (Bullock & Bawa Reference BULLOCK and BAWA1981, Cipollini & Stiles Reference CIPOLLINI and STILES1991). Among tropical dioecious trees, male-biased sex ratios have been more frequently observed than equal sex ratios (Thomas & LaFrankie Reference THOMAS and LAFRANKIE1993). Female-biased populations have only been reported in the genus Garcinia (Clusiaceae) in the Palaeotropics (Thomas Reference THOMAS1997) and in two polygonaceous species Coccoloba caracasana (Opler & Bawa Reference OPLER and BAWA1978) and Triplaris americana in the Neotropics (Melampy & Howe Reference MELAMPY and HOWE1977, Opler & Bawa Reference OPLER and BAWA1978).

Spatial segregation of the sexes (SSS) at local scales has been associated with an environmental gradient of a limiting resource such as soil water or nutrients (Bierzychudek & Eckhart Reference BIERZYCHUDEK and ECKHART1988, Dawson & Ehleringer Reference DAWSON and EHLERINGER1993). This SSS is linked to the differential costs of reproduction in dioecious plants and may reflect sexual differences in resources required for growth, reproduction and survival in different habitats, or environmental sex determination (Bierzychudek & Eckhart Reference BIERZYCHUDEK and ECKHART1988). In species that exhibit SSS, females predominate in habitats with higher resource levels, while males occupy less favourable sites (Bierzychudek & Eckhart Reference BIERZYCHUDEK and ECKHART1988, Freeman et al. Reference FREEMAN, KLIKOFF and HARPER1976, Shea et al. Reference SHEA, DIXON and SHARITZ1993). Although SSS has been demonstrated in approximately 66% of the species examined (Bierzychudek & Eckhart Reference BIERZYCHUDEK and ECKHART1988), there is little evidence of SSS in tropical dioecious tree and shrub species (Queenborough et al. Reference QUEENBOROUGH, BURSLEM, GARWOOD and VALENCIA2007).

This study documents the sexual expression of all potentially reproductive individuals of two dioecious canopy species native to Puerto Rico, by conducting several censuses of reproductive behaviour over 2 y in the Luquillo Forest Dynamics Plot (LFDP), a 16-ha permanent forest plot located in the subtropical wet forest of the Luquillo Mountains (Thompson et al. Reference THOMPSON, BROKAW, ZIMMERMAN, WAIDE, EVERHAM, LODGE, TAYLOR, GARCÍA-MONTIEL and FLUET2002). We describe the population structure and compare the growth rates and the spatial distribution of the sexes, using 15 y of LFDP census data. Based upon theoretical considerations of trade-offs between reproduction and other life-history traits we hypothesized that because females face higher costs of reproduction than males: (1) populations will be male-biased; (2) males should be more abundant in small size classes because they start reproduction earlier; (3) males should grow faster than females and become over-represented in large size classes; and (4) populations will exhibit SSS. We infer the latter for our site because of well-studied gradients in nutrients and water associated with soil type and topography (Johnston Reference JOHNSTON1992, Soil Survey Staff 1995, Thompson et al. Reference THOMPSON, BROKAW, ZIMMERMAN, WAIDE, EVERHAM, LODGE, TAYLOR, GARCÍA-MONTIEL and FLUET2002), and variation in the light environment (Queenborough et al. Reference QUEENBOROUGH, BURSLEM, GARWOOD and VALENCIA2007) caused by hurricane damage (Brokaw et al. Reference BROKAW, FRAVER, GREAR, THOMPSON, ZIMMERMAN, WAIDE, EVERHAM, HUBBELL, CONDIT, , Losos and Leigh2004).

METHODS

Study site

The 16-ha Luquillo Forest Dynamics Plot (LFDP) is located in the El Verde Research Area (18°20′ N, 65°49′ W) in the Luquillo Experimental Forest, Puerto Rico (Thompson et al. Reference THOMPSON, BROKAW, ZIMMERMAN, WAIDE, EVERHAM, LODGE, TAYLOR, GARCÍA-MONTIEL and FLUET2002, Zimmerman et al. Reference ZIMMERMAN, EVERHAM, WAIDE, LODGE, TAYLOR and BROKAW1994). It is part of the Luquillo Long-Term Ecological Research (LTER) Program and the Center for Tropical Forest Science (CTFS) network of forest plots (Losos & Leigh Reference LOSOS and LEIGH2004, Zimmerman et al. Reference ZIMMERMAN, THOMPSON, BROKAW, Carson and Schnitzer2008). The LFDP is in the Dacryodes excelsa Vahl forest zone (below 600 m in the Luquillo Mountains; Ewel & Whitmore Reference EWEL and WHITMORE1973). Rainfall at El Verde averages 3500 mm y−1. March and April tend to have less rainfall, but all months have ≥ 200 mm. Daily average maximum air temperature is 25.2 °C, minimum is 20.5 °C, and the yearly average is 22.8 °C (Brown et al. Reference BROWN, LUGO, SILANDER and LIEGEL1983). This forest is classified as ‘subtropical wet forest’ in the Holdridge System (Ewel & Whitmore Reference EWEL and WHITMORE1973). The plot topography has north-west-running drainages forming steep north-east- and south-west-facing slopes. Elevation ranges from 333 m at the northern end of the LFDP to 428 m at the south (Thompson et al. Reference THOMPSON, BROKAW, ZIMMERMAN, WAIDE, EVERHAM, LODGE, TAYLOR, GARCÍA-MONTIEL and FLUET2002). The soils are clays formed from volcaniclastic sandstone (Soil Survey Staff 1995) that vary from well-drained soils on the ridges to less well-drained soils on some slopes and valleys (Johnston Reference JOHNSTON1992, Soil Survey Staff 1995). The present tree species composition and distribution on the LFDP strongly reflects the impact of past human disturbances in the 1920s, ‘30s and ‘40s that affected approximately 11 ha, leaving about 5 ha relatively free from human disturbance (Thompson et al. Reference THOMPSON, BROKAW, ZIMMERMAN, WAIDE, EVERHAM, LODGE, TAYLOR, GARCÍA-MONTIEL and FLUET2002). The Luquillo forest has a long history of hurricane disturbance as well. The plot was established in 1990, a year after Hurricane Hugo impacted the area, and Hurricane Georges struck the forest in 1998.

Every 5 y all self-supporting woody stems ≥ 1.0 cm dbh (diameter at 1.3 m from the ground) are tagged, identified, mapped and measured to assess growth, mortality and recruitment of new individuals (Thompson et al. Reference THOMPSON, BROKAW, ZIMMERMAN, WAIDE, EVERHAM, LODGE, TAYLOR, GARCÍA-MONTIEL and FLUET2002, Reference THOMPSON, BROKAW, ZIMMERMAN, WAIDE, EVERHAM III, SCHAEFER, Losos and Leigh2004). We used 15 y of inventory data from censuses conducted in 1990, 1995, 2000 and 2005 to describe the population structure, growth rates and spatial distributions of the sexes of two dioecious trees in the LFDP, Cecropia schreberiana Miq. and Dacryodes excelsa.

Species

Cecropia schreberiana (Cecropiaceae) is a pioneer species of medium size (up to 21 m tall) found in the humid forest of Puerto Rico between 50 and 1300 m asl (Silander & Lugo Reference SILANDER, LUGO, Francis and Lowe2000) that is currently abundant in the Luquillo Mountain forests because of recent hurricanes (Brokaw Reference BROKAW1998). In the LFDP it is distributed relatively uniformly throughout the plot, but is somewhat more frequent in the more human-disturbed portion of the plot (Thompson et al. Reference THOMPSON, BROKAW, ZIMMERMAN, WAIDE, EVERHAM, LODGE, TAYLOR, GARCÍA-MONTIEL and FLUET2002). Most of the individuals recruited following Hurricane Hugo in 1990 (Zimmerman et al. Reference ZIMMERMAN, EVERHAM, WAIDE, LODGE, TAYLOR and BROKAW1994). Cecropia schreberiana flowers from November to May with a peak in February, and drops fruits from November to June, with a peak in April (Zimmerman et al. Reference ZIMMERMAN, WRIGHT, CALDERÓN, APONTE-PAGÁN and PATON2007). It is pollinated by wind and dispersed by birds and bats (Brokaw Reference BROKAW1998, Silander & Lugo Reference SILANDER, LUGO, Francis and Lowe2000).

Dacryodes excelsa (Burseraceae) is a large tree (30–35 m tall) dominant in the Luquillo Mountains between 200–900 m asl (Lugo & Wadsworth Reference LUGO, WADSWORTH, Francis and Lowe2000). This species prefers ridges and upper slopes (Basnet Reference BASNET1992, Lugo & Wadsworth Reference LUGO, WADSWORTH, Francis and Lowe2000). In the LFDP it is most often found in the southern portion that was relatively free of human disturbance, with scattered individuals throughout the remainder of the plot (Thompson et al. Reference THOMPSON, BROKAW, ZIMMERMAN, WAIDE, EVERHAM, LODGE, TAYLOR, GARCÍA-MONTIEL and FLUET2002). Dacryodes excelsa flowers from July to November, with the fruits maturing throughout the year and falling mainly during January to July (Estrada Pinto Reference ESTRADA PINTO, Odum and Pigeon1970, Zimmerman et al. Reference ZIMMERMAN, WRIGHT, CALDERÓN, APONTE-PAGÁN and PATON2007). It is likely pollinated by small insects, and the seeds dispersed by large birds and bats (J. Forero-Montaña pers. obs. 2006).

Flowering censuses

We conducted several censuses during the reproductive period of both species in 2006 and 2007. Censuses of C. schreberiana were conducted in June and October 2006 and in February and April 2007 corresponding to a single reproductive event. Dacryodes excelsa was censused in June and November 2006, and in May, August and October 2007 representing two consecutive reproductive events. In order to include all the potentially reproductive individuals, all stems ≥ 5 cm dbh for C. schreberiana and all stems ≥ 10 cm dbh for D. excelsa were censused.

Sexual expression

We identified the sexual expression of individual trees by examining the presence of fruits and flowers in tree crowns using binoculars. There are relatively few lianas in the forest (Rice et al. Reference RICE, BROKAW and THOMPSON2004) such that they did not severely limit our view. Males and females of C. schreberiana can be clearly distinguished by sight in the forest as the inflorescences are large and dimorphic. In contrast, flowers of D. excelsa are minute (approximately 4 mm across), and morphological differences between staminate (male) and pistillate (female) flowers are impossible to see in the tree crowns. It was also not possible to determine the sexual expression of individuals by collecting abscised flowers in plots or baskets located beneath the crown of each D. excelsa individual (Queenborough et al. Reference QUEENBOROUGH, BURSLEM, GARWOOD and VALENCIA2007), as trees are abundant in the LFDP (64.8 stems ha−1 ≥ 10 cm, Thompson et al. Reference THOMPSON, BROKAW, ZIMMERMAN, WAIDE, EVERHAM, LODGE, TAYLOR, GARCÍA-MONTIEL and FLUET2002) and their crowns are highly overlapping. Thus, we categorized the sexual expression of D. excelsa individuals based upon careful observations of patterns of flowering and fruiting during the 2 years of censuses (‘reproductive category’ hereafter). Trees that produced only flowers in both years and never fruits were considered ‘males’, and trees that produced fruits in both years were considered ‘females’. Trees that were reproductive in a single year and produced abundant fruits were considered ‘potential females’ and trees that produced only flowers in a single year but no fruits as ‘potential males’. Trees that produced abundant flowers in a single year but bore only a few fruits (< 10) were considered ‘inconsistent males’, and those trees that produced many fruits in one year, but only flowers in the other year were considered ‘inconsistent females’.

Sex ratio

Deviations of a sex ratio (male/female) from 1:1 were tested using the G-test for goodness of fit (Sokal & Rohlf Reference SOKAL and ROHLF1995). For D. excelsa, we conducted three separate analyses for each of the different reproductive categories, beginning, first, with only trees that showed consistent patterns of flowering and fruiting in both years of observation (males vs. females). Second, we added potential males and potential females to the first analysis and finally, in the third analysis, we added inconsistent males and inconsistent females to the previous two groups.

Size distributions

The size distributions of each sex (C. schreberiana) or reproductive category (D. excelsa) within species were described using the dbh recorded in the most recent census of the LFDP (2005–2006; Thompson et al., unpubl. data). Differences in cumulative size distributions between males and females of C. schreberiana were tested using the Kolmogorov–Smirnov two-sample test (Sokal & Rohlf Reference SOKAL and ROHLF1995). Differences among the reproductive categories of D. excelsa were examined using a one-way test, a procedure that is equivalent to a one-way ANOVA but does not require equal variances for all groups (Dalgaard Reference DALGAARD2002). Specific comparisons between groups were performed using a pairwise t-test (Crawley Reference CRAWLEY2007, Dalgaard Reference DALGAARD2002). To correct for multiple comparisons we used Holm, which is a less conservative variant of the Bonferroni correction method (Crawley Reference CRAWLEY2007, Dalgaard Reference DALGAARD2002).

Growth rates

Growth rates were calculated for each separate 5-y census period, from LFDP censuses starting in 1990, 1995 and 2000 and also over 15 y from 1990 to 2005. Annual growth rates were calculated as ((dbh2 – dbh1/date2 – date1) × 365)), where subscripts refer to consecutive censuses and time was measured in days. Differences in growth rates between males and females of C. schreberiana and among reproductive categories of D. excelsa were compared using ANCOVA (Quinn & Keough Reference QUINN and KEOUGH2002). The response variable in each analysis was diameter growth rate with dbh as the covariate, and the explanatory factor was sex for C. schreberiana or reproductive category for D. excelsa. Before the analysis we checked homogeneity of variances in growth rates and dbh between male and female trees of C. schreberiana and among reproductive categories of D. excelsa, and used the homogeneity of variances in growth rates to test the hypothesis that one sex experienced greater habitat variability than the other. To identify the best covariate, we examined the correlation between growth rate, and both initial and final dbh. The models for C. schreberiana were best fitted with final dbh, while the models for D. excelsa were best fitted with initial dbh. The ANCOVA models tested the effect of sex and size separately, in addition to their interaction. We compared a full model with an interaction term, and a reduced model without an interaction, and retained the interaction term when it was significant. A significant interaction term means that, for trees of a similar diameter range, the relationship between growth and dbh was different for each sex. To investigate differences among reproductive categories of D. excelsa, we simplified the model for the entire growth period 1990–2005 by combining groups with similar intercepts to find the model with the best fit. All models were compared with ANOVA (Crawley Reference CRAWLEY2007). The growth rate and size data for D. excelsa were log-transformed to improve normality of the residuals. The P values of all the analyses were adjusted with the sequential Bonferroni test to reduce Type I error of multiple comparisons (Rice Reference RICE1989).

Spatial segregation

Spatial segregation between male and female trees of C. schreberiana, and among the six reproductive categories of D. excelsa, were tested using interpoint distance methods based on Ripley's K (Ripley Reference RIPLEY1981) and Distance to Neighbour functions (Diggle Reference DIGGLE1983) following the methods of Barot et al. (Reference BAROT, GIGNOUX and MENAUT1999). The spatial pattern analyses involved three complementary functions based on the following measurements: (1) the distance from each tree to its nearest conspecific neighbour (Diggle's G function); (2) the distance from a randomly chosen point to the nearest tree of the test species (Diggle's F function); and (3) the average number of conspecific trees located within a given distance of each sampled tree (Ripley's K function, Barot et al. Reference BAROT, GIGNOUX and MENAUT1999). Each function has a different sensitivity to a specific type of spatial distribution, therefore we compared the result of the three functions and if a conflict in the results occurred we selected the test with the highest power (for more details see Barot et al. Reference BAROT, GIGNOUX and MENAUT1999).

Tests to describe the spatial pattern and tests to infer spatial associations between two types of events (trees) were conducted separately using univariate and bivariate methods. The univariate methods test whether a group of trees exhibits a regular, random or aggregated pattern, and the bivariate methods test whether the relationship between two types of trees suggests association (trees growing in the same habitat), repulsion (trees growing in different habitats) or independence (no relationship to habitat). For D. excelsa, spatial pattern analyses were conducted for each reproductive category separately, then the spatial association between each of the reproductive categories was tested by conducting separate bivariate analyses for each pair of associations. The bivariate analyses of spatial association between two types of trees used versions of Diggle's G nearest neighbour and Ripley's K functions where the distances are calculated between trees of two groups (1 and 2), instead of trees within the same group. The nearest-neighbour relationship is not reciprocal (Barot et al. Reference BAROT, GIGNOUX and MENAUT1999), therefore G1–2 and G2–1 were evaluated separately for each pair of associations. This allows us to detect asymmetric relationships. For example, females could be spatially associated with males, but the spatial distribution of males could be independent from that of females. On the other hand, the bivariate K function is symmetrical and K1–2 and K2–1 are equivalent (Barot et al. Reference BAROT, GIGNOUX and MENAUT1999). Therefore, only one K test was performed for each pair of association. The spatial analyses were performed using Spatstat, a statistical package of the software R (Baddeley & Turner Reference BADDELEY and TURNER2005, www.spatstat.org). Edge-effect bias corrections were performed for all spatial tests (Baddeley & Turner Reference BADDELEY and TURNER2005). The test significance was evaluated using Monte Carlo procedures with 500 simulations to calculate rejection limits. The null hypothesis was rejected if the estimated function values lay outside the rejection limits. For Diggle's G function and Ripley's K function positive departures indicate a tendency towards aggregation/association, while negative departures indicate a tendency towards regularity/segregation (Baddeley & Turner Reference BADDELEY and TURNER2005). For Diggle's F function the interpretation is the opposite, positive deviations indicate regularity/segregation, while negative deviations indicate aggregation-association (Baddeley & Turner Reference BADDELEY and TURNER2005).

RESULTS

General patterns of reproduction

The C. schreberiana population included 1566 individuals, and although the censuses covered only one reproductive event, we are confident that our estimation of the reproductive pattern is robust because 75% of the trees flowered during the censuses, and 89% of the non-reproductive individuals were trees smaller than 15 cm dbh (Figure 1). The population of D. excelsa was composed of 1038 individuals. The majority of the trees (74%) were reproductive over the 2 y of observations; among those trees 74% flowered in both years, while 26% flowered in only 1 y. Within the reproductive categories, 46% were females (produced fruit over 2 y of observations), 24% were males (produced only flowers over 2 y), 6% produced fruits in only 1 y (potential females), 19% produced only flowers in 1 y (potential males), 3% produced many fruits in 1 y but in the next year were observed only with flowers (inconsistent females), and 2% produced mainly flowers, but in at least one of the censuses were observed with a few fruits (inconsistent males). Most of the non-reproductive individuals (80%) were trees smaller than 20 cm dbh (Figure 1).

Figure 1. Cumulative distributions of stem diameter (dbh) for reproductive and non-reproductive trees in the LFDP. Cecropia schreberiana, trees ≥ 5 cm dbh (a), and Dacyodes excelsa, trees ≥10 cm dbh (b). Note different scales for the x-axes.

Sex ratios

The cumulative sex ratio of C. schreberiana was not different from unity. In contrast, the cumulative sex ratio of D. excelsa was significantly female-biased and this biased sex ratio was significant for all three sex-ratio analyses, including the following: (1) only the trees that consistently produced flowers and fruits over the 2 y; (2) trees that were reproductive in 1 or 2 y and showed consistent sexual expression in both years; or (3) when all the reproductive trees were included using the criteria established in the methods. As more individuals were included in the analyses the sex ratio became less female-biased, but it was always significantly female-biased (Table 1).

Table 1. Number of male and female trees and cumulative sex ratios (male/female) for Cecropia schreberiana and Dacryodes excelsa in the LFDP, Puerto Rico. G-test statistic and significance tests are shown. For D. excelsa we conducted three tests: (a) only individuals that consistently produced flowers or fruits over 2 y (males and females); (b) individuals that were reproductive in 1 or 2 y, (individuals in (a) plus potential males and potential females); and (c) all individuals that were reproductive at some time (individuals in (a) and (b) plus inconsistent males and inconsistent females).

Differences in cumulative size distributions

Cecropia schreberiana did not show significant sexual differences in size, as the cumulative distributions of male and female diameters were almost identical (D = 0.126, P > 0.05; Figure 2). In contrast, D. excelsa exhibited significant differences in size distributions among reproductive categories (F = 44.4, P < 0.0001). Pairwise comparisons indicated that males had the largest average diameter among all reproductive categories (mean dbh = 43.8 ± 14 cm). Inconsistent females (mean dbh = 38.4 ± 11.6 cm), females (mean dbh = 35.6 ± 11.2 cm) and inconsistent males (mean dbh = 32.7 ± 9.8 cm) formed the second group with the largest diameter. Size of inconsistent males, however, was significantly similar to potential males (mean dbh = 27.8 ± 10.7 cm) that formed a third group, the smallest, with potential females (mean dbh = 23.0 ± 9.1 cm).

Figure 2. Cumulative distributions of stem diameter (dbh) for male and female trees in the LFDP. Cecropia schreberiana, trees ≥ 5 cm dbh (a), and Dacyodes excelsa, trees ≥ 10 cm dbh (b). Potential females (Pot. Females), potential males (Pot. Males), inconsistent females (Inc. Female) and inconsistent males (Inc. Male). Note different scales of the x- and y-axes.

Growth rates

Variances in growth rates between the sexes of C. schreberiana were not significantly different (F = 1.014, P > 0.05), but the reproductive categories of D. excelsa exhibited significant heterogeneity of variances in all census periods (F = 0.711, P < 0.05). Variances in growth rates of D. excelsa tended to be greater for male (mostly non-fruiting) categories than for female categories over all the census periods (not shown).

Growth rates of C. schreberiana showed no significant differences between the sexes (Table 2). The best-fitting model had regression lines with identical slopes for male and female trees and explained more than 65% of the variation in growth (F = 1096, R2 = 0.66, P <0.001). (Table 2, Figure 3). For this species, however, there was a significant effect of diameter, with growth rates tending to increase with tree size (Figure 3).

Table 2. Results for the ANCOVAs comparing differences in growth rates between male and female trees of Cecropia schreberiana and reproductive categories of Dacryodes excelsa. Bold P values indicate significant results after the sequential Bonferroni correction (Rice Reference RICE1989) was applied.

Figure 3. Growth rates of male and female trees for (a) Cecropia schreberiana and (b) reproductive categories (male, female, potential females, potential males, inconsistent females and inconsistent males) of Dacryodes excelsa in the LFDP from 1990–2005. Similar results were found for the other periods (not shown). Note different scales of the x- and y-axes for each species.

Growth rates (log-transformed) of D. excelsa among reproductive categories were significantly different over all census periods. Mean annual growth of male groups exceeded female groups in all the census periods by more than 0.1 cm y−1. For D. excelsa the effect of the covariate (log-transformed dbh) was significant, but in contrast to C. schreberiana, the slope of the regression between dbh and growth rate was small and negative (Figure 3), and explained only a small proportion of the variance in growth rates (R2 = 4–11% among periods). For the first period (1990–1995) the best-fitting model included the interaction term between groups and size, while for the other periods, including the entire period of 1990–2005, an additive model was the best-fit model (Table 2).

The best-fitting model (F = 39.35, R2 = 0.168, P = 0.001) indicated that males and inconsistent males exhibited similar growth rates and grew slightly faster than all other reproductive categories. Males were followed by inconsistent females, then by potential males and females, which formed a third statistical group, and lastly, by potential females, the group with the lowest growth rate (Table 3, Figure 3).

Table 3. Coefficients and significance test for the ANCOVA comparing differences in growth rates between male and female trees of Cecropia schreberiana and among reproductive categories of Dacryodes excelsa for the entire period (1990–2005).

Spatial segregation between the sexes

There was no evidence for either species that trees of different sexes or belonging to different reproductive categories exhibited significant spatial segregation. Males and females of C. schreberiana exhibited significant aggregation and symmetrical associations, at all spatial scales (Figure 4). Similarly, there was a tendency towards aggregation and association for all D. excelsa reproductive categories. When the relationship between males and females alone was tested it was significant and symmetrical at all spatial scales, but the relationships among each of the other reproductive categories were not significant nor symmetrical at all spatial scales, in part because these groups had small sample sizes. Because there was no evidence that males and females had repulsed distributions for either species, which would be consistent with the hypothesis of SSS, we did not investigate the habitat associations of the two sexes any further.

Figure 4. Spatial association between male and female trees of Cecropia schreberiana (above) and Dacryodes excelsa (below) in the LFDP, showing (a and d) bivariate Ripley's K analysis, (b and e) bivariate G function for males to females, and (c and f) bivariate G function for females to males. For D. excelsa only trees that exhibited consistency in the sexual expression over 2 years of observations are shown. Solid lines show test statistic, dashed lines show the theoretical function for an independent pattern (middle curve) and 99% confidence envelopes. Note different scales of the x- and y-axes for each species.

DISCUSSION

This study was conducted to understand the ecological implications and significance of dioecy for two canopy tree species, C. schreberiana and D. excelsa, that have different life-history strategies, and potential sex differences in size, growth rate and spatial distributions. Sex ratios of tropical dioecious trees frequently differ from equality, with male bias more frequently reported than female bias (Thomas & LaFrankie Reference THOMAS and LAFRANKIE1993). In our study C. schreberiana had similar numbers of male and female trees, while the sex ratio of D. excelsa was significantly female-biased. Although we were not able to directly identify the sex of D. excelsa trees, we conducted a sensitivity analysis of the sex ratio that took into account the limitations of our ability to determine tree gender. Our results for D. excelsa consistently indicated a female-biased sex ratio in the population.

Female-biased sex ratios in plants are uncommon and have been linked to the presence of heteromorphic sexual chromosomes, gametic selection (Stehlik et al. Reference STEHLIK, KRON, BARRETT and HUSBAND2007) and apomixis (Thomas Reference THOMAS1997). In the tropics, female-biased sex ratios have only been previously reported in three studies (Melampy & Howe Reference MELAMPY and HOWE1977, Opler & Bawa Reference OPLER and BAWA1978, Thomas Reference THOMAS1997). In a lowland rain forest in Malaysia, a population of Garcinia scortechinii that consists entirely of pistillate individuals has the most extremely female-biased sex ratio reported in the tropics, and perhaps among all flowering plants (Thomas Reference THOMAS1997). Embryological evidence suggested that female-biased sex ratios in Garcinia may result from apomixis (Thomas Reference THOMAS1997). Apomitic plants are able to produce seeds without fertilization via adventive embryony that usually results in more than one seedling per seed (Thomas Reference THOMAS1997). Although two seedlings per seed have been observed in D. excelsa, apomixis is not the likely explanation for the female-biased sex ratio detected here because this phenomenon occurs in < 1% of the seedlings in the LFDP (J. K. Zimmerman, per. obs.).

In tropical dioecious species, it has been frequently observed that males begin flowering at smaller sizes than females (Queenborough et al. Reference QUEENBOROUGH, BURSLEM, GARWOOD and VALENCIA2007, Thomas & LaFrankie Reference THOMAS and LAFRANKIE1993). We found no differences in the size distributions of male and female C. schreberiana, but trees of D. excelsa, when grouped by pattern of fruit and flower production, showed significant differences in diameter, indicating that size is an important factor determining reproductive activity. In a number of tropical dioecious trees larger individuals tend to flower more frequently than smaller trees (Bullock & Bawa Reference BULLOCK and BAWA1981, Clark & Clark Reference CLARK and CLARK1987, Nicotra Reference NICOTRA1998, Queenborough et al. Reference QUEENBOROUGH, BURSLEM, GARWOOD and VALENCIA2007, Thomas & LaFrankie Reference THOMAS and LAFRANKIE1993). Similarly, in D. excelsa, trees that consistently produced flowers or fruits over the 2 y of observation were larger than trees that were reproductive only in a single year.

Cecropia schreberiana did not exhibit sexual differences in growth rates. The pattern of similar male–female growth rates in C. schreberiana suggests the presence of compensatory mechanisms that counteract the reproductive allocation effects (Nicotra Reference NICOTRA1999a, Reference NICOTRA1999b). Theory indicates that greater reproductive allocation by females should result in slower female growth rates. However, greater resource use efficiency and carbon assimilation rates, or more effective resource allocation may help females to compensate for the greater costs of reproduction (Nicotra Reference NICOTRA1999b). Moreover, the lack of sexual differences in C. schreberiana in size distribution and growth rates suggests that the sexes may have similar life expectancies. On the other hand, males of D. excelsa tended to grow faster (mean 0.1 cm y−1) than females, representing 20% of the overall mean diameter growth rate of 0.5 cm y−1. This result suggests that there are reproductive constraints that affect female trees more than males (Obeso Reference OBESO2002).

We tested homogeneity in the variances of growth rate of male and female trees of each species not only to verify the assumptions of the statistical analyses we used, but also to determine sexual differences in the variance of growth rate. Sexual differences in variance of growth rate would be expected if the sexes experienced different habitats or site quality. Cecropia schreberiana showed no significant sexual differences in the variance of growth rate, but in D. excelsa males and potential males exhibited higher variance than females and potential females, suggesting that male categories may experience a greater variation in site quality. Our spatial analyses, however, did not indicate that the sexes of our two study species occurred in spatially segregated habitats, thus SSS does not explain the greater variation in growth rate among male versus female trees of D. excelsa and other factors must be involved.

Spatial segregation of the sexes has been reported in plant species growing in heterogeneous environments with steep gradients in water, elevation, light, nutrients, pH or temperature (Bierzychudek & Eckhart Reference BIERZYCHUDEK and ECKHART1988), and is more likely to occur in habitats where a critical resource is distributed along an extreme gradient (Nicotra Reference NICOTRA1998). Although in the Luquillo Experimental Forest the distribution of soil moisture and nutrients are related to slope and elevation (Johnston Reference JOHNSTON1992), we found no evidence that this affected the spatial distribution of the sexes of either species. Most of the analyses indicated the opposite pattern in that the sexes or reproductive categories tend to be spatially aggregated. The absence of SSS among tropical dioecious shrubs has been attributed to the greater spatial and temporal variability of the light regime in the forest understorey (Nicotra Reference NICOTRA1998, Queenborough et al. Reference QUEENBOROUGH, BURSLEM, GARWOOD and VALENCIA2007). Similarly, in the subtropical wet forest of the Luquillo Mountains hurricanes, tropical storms and droughts (Beard et al. Reference BEARD, VOGT, VOGT, SCATENA, COVICH, RAGNHILDUR, SICCAMA and CROWL2005) may have created such variability in environmental conditions that it may have precluded the evolution of SSS in these canopy dioecious species.

The lack of sexual dimorphisms in size and growth rates reported here for C. schreberiana suggests that resources are not strongly limiting for either sex, or they support similar reproductive costs (Obeso Reference OBESO2002). Male-biased sex ratios and associated patterns of sexual dimorphisms in tropical rain forests have been primarily observed among subcanopy species that inhabit strongly light-limited environments (Thomas & LaFrankie Reference THOMAS and LAFRANKIE1993). Cecropia schreberiana trees are unlikely to become reproductive until they reach a position in the canopy where light becomes less limiting for growth and reproduction. The high population density of C. schreberiana in this forest results from post Hurricane Hugo (in 1989) recruitment (Zimmerman et al. Reference ZIMMERMAN, EVERHAM, WAIDE, LODGE, TAYLOR and BROKAW1994) and the forest canopy was again heavily damaged by Hurricane Georges (in 1998). Thus, the relatively open forest canopy prevalent during our study may have reduced the competition for light, such that the costs of reproduction for the different sexes were not readily apparent.

While males do not face the costs of provisioning seeds and associated structures, it is still not clear to what extent males and females differ with respect to reproductive costs (Opler & Bawa Reference OPLER and BAWA1978). In some woody species males allocate more biomass to flowers than females (Bullock & Bawa Reference BULLOCK and BAWA1981, Nicotra Reference NICOTRA1999a, Wheelwright & Bruneau Reference WHEELWRIGHT and BRUNEAU1992). In tropical rain forests the scarcity of anemophilous species has been attributed to the low effectiveness of this type of pollination system in environments with high humidity and dense vegetation that constrain the free movement of pollen through the air (Turner Reference TURNER2001). Cecropia schreberiana is wind-pollinated and males may produce large amounts of pollen to successfully compete for mates (Forero-Montaña & Zimmerman in press). Thus, high levels of pollen production in C. schreberiana may impose equivalent male and female reproductive costs.

The lack of sexual dimorphism in C. schreberiana may reflect its life-history strategy of rapid growth and early reproduction where any differences in reproductive costs between males and females may be only weakly expressed in the relatively competition-free period that follows hurricane disturbance. Conversely the sexual dimorphism of D. excelsa likely reflects the large difference in resources required to grow slowly in the forest understorey until eventually reaching the canopy where relatively few large seeds, when compared with pollen, are produced. The untypical female bias of D. excelsa in particular, needs further investigation, and some aspects will be covered by future studies of these and other dioecious species in this forest.

ACKNOWLEDGEMENTS

We thank Raina Domínguez, Zara Dowling and Maria Moskalenko for their helpful field assistance during the censuses of flowering trees. We thank Simon A. Queenborough for very useful comments during the analysis and writing. We also thank Nick Brokaw, Chris Nytch, Silvana Marten-Rodriguez, Alberto Sabat, Jim Ackerman and two anonymous reviewers for constructive criticism of earlier drafts. The censuses of the LFDP used for growth analysis were funded by the Luquillo Long-Term Ecological Research Program, funded by the National Science Foundation (NSF) grants BSR-8811902, DEB-9411973, DEB-008538, DEB-0218039 and DEB-0620910, the University of Puerto Rico and the USDA Forest Service's International Institute of Tropical Forestry. Additional funding was provided by NSF grant DEB-0516066 and the Andrew Mellon Foundation. We thank the large numbers of volunteers who contributed to the censuses of the LFDP, Nick Brokaw, Edwin Everham, Jean Lodge and Robert Waide, who were the original founders of this forest plot, and John Thomlinson who assisted with the LFDP tree mapping. Forero-Montaña gratefully acknowledges support from two fellowships from the Office of the Dean of Graduate Studies and Research, University of Puerto Rico.

References

LITERATURE CITED

BADDELEY, A. & TURNER, R. 2005. Spatstat: an R package for analyzing spatial point patterns. Journal of Statistical Software 12:142.CrossRefGoogle Scholar
BAROT, S., GIGNOUX, J. & MENAUT, J. C. 1999. Demography of a savanna palm tree: predictions from comprehensive spatial pattern analyses. Ecology 80:19872005.CrossRefGoogle Scholar
BASNET, K. 1992. Effect of topography on the pattern of trees in tabonuco (Dracryodes excelsa) dominated rain forest of Puerto Rico. Biotropica 24:3142.CrossRefGoogle Scholar
BEARD, K. H., VOGT, K. A., VOGT, D. J., SCATENA, F. N., COVICH, A. P., RAGNHILDUR, S., SICCAMA, T. G. & CROWL, T. A. 2005. Structural and functional responses of a subtropical forest to 10 years of hurricanes and droughts. Ecological Monographs 75:345361.CrossRefGoogle Scholar
BIERZYCHUDEK, P. & ECKHART, V. 1988. Spatial segregation of the sexes of dioecious plants. American Naturalist 132:3443.CrossRefGoogle Scholar
BROKAW, N. V. L. 1998. Cecropia schreberiana in the Luquillo Mountains of Puerto Rico. The Botanical Review 64:94120.CrossRefGoogle Scholar
BROKAW, N., FRAVER, S., GREAR, J. S., THOMPSON, J., ZIMMERMAN, J. K., WAIDE, R. B., EVERHAM, E. M., HUBBELL, S. P., CONDIT, R. & , FOSTER. R. B. 2004. Disturbance and canopy structure in two tropical forests. Pp. 177194 in Losos, E. C. & Leigh, E. G. (eds.). Tropical forest diversity and dynamism: results from a long-term tropical forest network. The University of Chicago Press, Chicago.Google Scholar
BROWN, S., LUGO, A. E., SILANDER, S. & LIEGEL, L. 1983. Research history and opportunities in the Luquillo Experimental Forest. USDA Forest Service General Technical Report SO-44, Southern Forest Experimental Station, New Orleans. 128 pp.CrossRefGoogle Scholar
BULLOCK, S. H. & BAWA, K. S. 1981. Sexual dimorphism and the annual flowering pattern in Jacaratia dolichaula (D. Smith) Woodson (Caricaceae) in a Costa Rican rain forest. Ecology 62:14941504.CrossRefGoogle Scholar
CIPOLLINI, M. L. & STILES, E. 1991. Costs of reproduction in Nyssa sylvatica: sexual dimorphism in reproductive frequency and nutrient flux. Oecologia 86:585593.CrossRefGoogle ScholarPubMed
CLARK, D. A. & CLARK, D. B. 1987. Temporal and environmental patterns of reproduction in Zamia skinneri, a tropical rain forest cycad. Journal of Ecology 75:135149.CrossRefGoogle Scholar
CRAWLEY, M. J. 2007. The R book. John Wiley and Sons Ltd, Chichester. 942 pp.CrossRefGoogle Scholar
DALGAARD, P. 2002. Introductory statistics with R. Springer, New York. 267 pp.Google Scholar
DAWSON, T. E. & EHLERINGER, J. R. 1993. Gender specific physiology, carbon isotope discrimination, and habitat distribution in box-elder, Acer negundo. Ecology 74:798815.CrossRefGoogle Scholar
DIGGLE, P. J. 1983. Statistical analysis of spatial point patterns. Academic Press, London. 288 pp.Google Scholar
ESTRADA PINTO, A. 1970. Phenological studies of trees at El Verde. Pp. D237D269 in Odum, H. T. & Pigeon, R. F. (eds.). A tropical rain forest: a study of irradiation and ecology at El Verde, Puerto Rico. US Atomic Energy Commission, Division of Technical Information Extension, Oak Ridge.Google Scholar
EWEL, J. J. & WHITMORE, J. L. 1973. The ecological life zones of Puerto Rico and the United States Virgin Islands. Forest Service Research Papers ITF-18. International Institute of Tropical Forestry, Rio Piedras. 72 pp.Google Scholar
FORERO-MONTAÑA, J. & ZIMMERMAN, J. K. In press. Sexual dimorphism in the timing of flowering of two dioecious trees in a subtropical wet forest, Puerto Rico. Caribbean Journal of Science.Google Scholar
FREEMAN, D. C., KLIKOFF, L. G. & HARPER, K. T. 1976. Differential resource utilization by the sexes of dioecious plants. Science 193:597599.CrossRefGoogle ScholarPubMed
JOHNSTON, M. H. 1992. Soil–vegetation relationships in a tabonuco forest community in the Luquillo Mountains of Puerto Rico. Journal of Tropical Ecology 8:253263.CrossRefGoogle Scholar
LLOYD, D. G. & WEBB, C. J. 1977. Secondary sex characters in plants. The Botanical Review 43:177216.CrossRefGoogle Scholar
LOSOS, E. C. & LEIGH, E. G. (eds.). 2004. Tropical forest diversity and dynamism: findings from a large-scale plot network. University of Chicago Press, Chicago. 645 pp.Google Scholar
LUGO, A. E. & WADSWORTH, F. H. 2000. Dacryodes excelsa Vahl. Tabonuco. Pp. 186189 in Francis, J. K. & Lowe, C. A. (eds.). Silvics of native and exotic trees of Puerto Rico and the Caribbean Islands. General Technical Report IITF – 15. US Department of Agriculture, Forest Service, International Institute of Tropical Forestry, Rio Piedras. 582 pp.Google Scholar
MEAGHER, T. R. & ANTONOVICS, J. 1982. The population biology of Chamaelirium luteum, a dioecious of the lily family: life history studies. Ecology 63:16901700.CrossRefGoogle Scholar
MELAMPY, M. & HOWE, H. 1977. Sex ratio in the tropical tree Triplaris americana (Polygonaceae). Evolution 31:867872.CrossRefGoogle ScholarPubMed
NICOTRA, A. B. 1998. Sex ratio variation and spatial distribution of Siparuna grandiflora, a tropical dioecious shrub. Oecologia 115:102113.CrossRefGoogle ScholarPubMed
NICOTRA, A. B. 1999a. Reproductive allocation and long-term reproductive costs of reproduction in Siparuna grandiflora, a dioecious neotropical shrub. Journal of Ecology 87:138149.CrossRefGoogle Scholar
NICOTRA, A. B. 1999b. Sexually dimorphic growth in the dioecious tropical shrub, Siparuna grandiflora. Functional Ecology 13:322331.CrossRefGoogle Scholar
OBESO, J. R. 2002. The cost of reproduction in plants. New Phytologist 115:321348.CrossRefGoogle Scholar
OPLER, P. & BAWA, K. S. 1978. Sex ratios in tropical forest trees. Evolution 32:812821.CrossRefGoogle ScholarPubMed
QUEENBOROUGH, S. A., BURSLEM, D. F.R. P., GARWOOD, N. C. & VALENCIA, R. 2007. Determinants of biased sex ratios and inter-sex costs of reproduction in dioecious tropical forests trees. American Journal of Botany 94:6778.CrossRefGoogle Scholar
QUINN, G. P. & KEOUGH, M. J. 2002. Experimental design and data analysis. Cambridge University Press, Cambridge. 537 pp.Google Scholar
RICE, K., BROKAW, N. & THOMPSON, J. 2004. Liana abundance in a Puerto Rican forest. Forest Ecology and Management 190:3341.CrossRefGoogle Scholar
RICE, W. R. 1989. Analyzing tables of statistical test. Evolution 43:223225.CrossRefGoogle Scholar
RIPLEY, B. D. 1981. Spatial statistics. Wiley, New York. 274 pp.CrossRefGoogle Scholar
SHEA, M. M., DIXON, P. M. & SHARITZ, R. R. 1993. Size differences, sex ratio, and spatial distribution of male and female water tupelo, Nyssa aquatica (Nyssaceae). American Journal of Botany 80:2630.CrossRefGoogle Scholar
SILANDER, S. R. & LUGO, A. E. 2000. Cecropia schreberiana Miq. Yagrumo hembra, Trumpet-tree. Pp. 122127 in Francis, J. K. & Lowe, C. A. (eds.). Silvics of native and exotic trees of Puerto Rico and the Caribbean Islands. General Technical Report IITF – 15. U.S. Department of Agriculture, Forest Service, International Institute of Tropical Forestry, Rio Piedras. 582 pp.Google Scholar
SOIL SURVEY STAFF 1995. Order 1 Soil Survey of the Luquillo Long-Term Ecological Research Grid, Puerto Rico. USDA, Natural Resources Conservation Service, Lincoln, Nebraska, USDA. 92 pp.Google Scholar
SOKAL, R. R. & ROHLF, J. E. 1995. Biometry. (Third edition). W. H. Freeman and Company, New York. 887 pp.Google Scholar
STEHLIK, I., KRON, P., BARRETT, S. C. & HUSBAND, B. C. 2007. Sexing pollen reveals female bias in a dioecious plant. New Phytologist 175:185194.CrossRefGoogle Scholar
THOMAS, S. C. 1997. Geographic parthenogenesis in a tropical forest tree. American Journal of Botany 84:10121015.CrossRefGoogle Scholar
THOMAS, S. C. & LAFRANKIE, J. V. 1993. Sex, size and interyear variation in flowering among dioecious trees of the Malayan rain forest. Ecology 74:15291537.CrossRefGoogle Scholar
THOMPSON, J., BROKAW, N. V. L., ZIMMERMAN, J. K., WAIDE, R. B., EVERHAM, E. M., LODGE, D. J., TAYLOR, C. M., GARCÍA-MONTIEL, D. & FLUET, M. 2002. Land use history, environment, and tree composition in a tropical forest. Ecological Applications 12:13441363.CrossRefGoogle Scholar
THOMPSON, J., BROKAW, N., ZIMMERMAN, J. K., WAIDE, R. B., EVERHAM III, E. M. & SCHAEFER, D. A. 2004. Luquillo Forest Dynamics Plot, Puerto Rico, United States. Pp. 540550 in Losos, E. C. & Leigh, E. G. (eds.). Tropical forest diversity and dynamism: results from a long-term tropical forest network. The University of Chicago Press, Chicago.Google Scholar
TURNER, I. M. 2001. The ecology of trees in the tropical rain forest. Cambridge University Press, Cambridge. 298 pp.CrossRefGoogle Scholar
WHEELWRIGHT, N. T. & BRUNEAU, A. 1992. Population sex ratios and spatial distribution of Ocotea tenera (Lauraceae) trees in a tropical forest. Journal of Ecology 80:425432.CrossRefGoogle Scholar
ZIMMERMAN, J. K., EVERHAM, E. M., WAIDE, R. B., LODGE, D. J., TAYLOR, C. M. & BROKAW, N. V. L. 1994. Responses of tree species to hurricane winds in subtropical wet forest in Puerto Rico: implications for tropical tree life histories. Journal of Ecology 82:911922.CrossRefGoogle Scholar
ZIMMERMAN, J. K., THOMPSON, J. & BROKAW, N. 2008. Large tropical forest dynamics plots: testing the explanations for the maintenance of species diversity. Pp. 98117 in Carson, W. & Schnitzer, S. (eds.), Tropical forest community ecology. Blackwell, Oxford.Google Scholar
ZIMMERMAN, J. K., WRIGHT, S. J., CALDERÓN, O., APONTE-PAGÁN, M. & PATON, S. 2007. Flowering and fruiting phenologies of seasonal and asesonal neotropical forests: the role of annual changes in irradiance. Journal of Tropical Ecology 23:231251.CrossRefGoogle Scholar
Figure 0

Figure 1. Cumulative distributions of stem diameter (dbh) for reproductive and non-reproductive trees in the LFDP. Cecropia schreberiana, trees ≥ 5 cm dbh (a), and Dacyodes excelsa, trees ≥10 cm dbh (b). Note different scales for the x-axes.

Figure 1

Table 1. Number of male and female trees and cumulative sex ratios (male/female) for Cecropia schreberiana and Dacryodes excelsa in the LFDP, Puerto Rico. G-test statistic and significance tests are shown. For D. excelsa we conducted three tests: (a) only individuals that consistently produced flowers or fruits over 2 y (males and females); (b) individuals that were reproductive in 1 or 2 y, (individuals in (a) plus potential males and potential females); and (c) all individuals that were reproductive at some time (individuals in (a) and (b) plus inconsistent males and inconsistent females).

Figure 2

Figure 2. Cumulative distributions of stem diameter (dbh) for male and female trees in the LFDP. Cecropia schreberiana, trees ≥ 5 cm dbh (a), and Dacyodes excelsa, trees ≥ 10 cm dbh (b). Potential females (Pot. Females), potential males (Pot. Males), inconsistent females (Inc. Female) and inconsistent males (Inc. Male). Note different scales of the x- and y-axes.

Figure 3

Table 2. Results for the ANCOVAs comparing differences in growth rates between male and female trees of Cecropia schreberiana and reproductive categories of Dacryodes excelsa. Bold P values indicate significant results after the sequential Bonferroni correction (Rice 1989) was applied.

Figure 4

Figure 3. Growth rates of male and female trees for (a) Cecropia schreberiana and (b) reproductive categories (male, female, potential females, potential males, inconsistent females and inconsistent males) of Dacryodes excelsa in the LFDP from 1990–2005. Similar results were found for the other periods (not shown). Note different scales of the x- and y-axes for each species.

Figure 5

Table 3. Coefficients and significance test for the ANCOVA comparing differences in growth rates between male and female trees of Cecropia schreberiana and among reproductive categories of Dacryodes excelsa for the entire period (1990–2005).

Figure 6

Figure 4. Spatial association between male and female trees of Cecropia schreberiana (above) and Dacryodes excelsa (below) in the LFDP, showing (a and d) bivariate Ripley's K analysis, (b and e) bivariate G function for males to females, and (c and f) bivariate G function for females to males. For D. excelsa only trees that exhibited consistency in the sexual expression over 2 years of observations are shown. Solid lines show test statistic, dashed lines show the theoretical function for an independent pattern (middle curve) and 99% confidence envelopes. Note different scales of the x- and y-axes for each species.