3. Materials and methods3.1. Specie

3. Materials and methods
3.1. Species selection
We established a preliminary list of 130 species of trees native to the PCW with reforestation/restoration value and/or usefulness to rural people (Aguilar and Condit, 2001). Since number of species fruiting may vary tremendously from year to year, depending on amount of seasonal rainfall and on some other factors such as insect damage (Francis, 2003), the final set of species (Table 1) was dictated by nature. Frequent field checks indicated the occurrence of a good fruiting season for species on the list. For each of the 100 species, author, common name (in Spanish), family, reported fruiting period, month of collection, and number of trees from which fruits/seeds were collected are presented in Appendix A.
Pseudosamanea guachapele, Dialium guianense, Guetarda foliacea, Lafoensia punicifolia, Beilschmiedia pendula, and Sapindus saponaria were collected and germination assays run in 1993–1994. Methodology used for germination assays of these species was the same as that used for the other species reported in this paper except that studies on longevity, moisture content, and number of seeds per kg were not carried out in all cases.
3.2. Seed collection
Seeds were collected within the PCW and adjacent areas near the Pacific Ocean and Caribbean Sea, on both coastal sides of the canal corridor (block of forest east and west of the Canal). Seed collection was carried out from 1996 to 1999. Weekly fieldtrips were made to select seed trees and to monitor fruit set and degree of ripening.Most fruits were collected directly from the tree using a climbing system or a telescopic pole. Other fruits were collected from the ground if they were not decayed (Appendix B). Phenological data for individual tree species on nearby Barro Colorado Island (Croat, 1978; Foster, 1982) were used in organizing the collection effort. Collection and processing problems are species-driven, and many poorly known species in the tropics represent a challenge to handle (Francis, 2003). Thus, in each case trees were identified by number, their location recorded, and fruit/seed collecting and cleaning methods used. Seeds/diaspores were separated from the fruits and mixed.
The best method for collecting seeds was to use a telescopic pole, which allowed access to the crown of 88 (of 100) species of trees less than 20 m tall. Enough seeds of only 8 species were collected from the ground, and for 23 species both methods were needed. For 18 species, the trees had to be climbed to complete seed collection, 6 of which were only accessible by climbing (Appendix B). Unfortunately, seeds of Platymiscium pinnatum and Couratari guianensis, two species that required climbing to collect, did not germinate at all, probably due to inviability caused by insect attack.
For 75 species, fruits were collected from five or more healthy individuals that had fruits ripening at the same time, and for eight, six, three, and eight species fruits(s) were(was) collected from four, three, two, and one tree(s), respectively. Seeds of Luehea speciosa were collected from 30 individuals due to scarce fruit production (Appendix A).
For many species, exact timing of fruit maturation was unknown, and approximately 20% of those with fruiting phenology records were collected in a season different from that in which the fruits were reported to ripen. In agreement with data for canopy and understory trees from BCI (Foster, 1982), there were two peaks of fruiting: January–June and August–October. Only four species were collected in July, five in December, and one in November.
Seeds were collected from a total of 100 species, and for 94 of these results were obtained that allow discussion of length of germination time and dormancy. The species from which seeds were collected belong to 34 families (Appendix A). Families represented by the most species are Fabaceae (21, including all three subfamilies), Rubiaceae (8), Meliaceae (7), Tiliaceae s. str. (5), Bombacaceae s. str. (5), and Anacardiaceae (4).

3.3. Number of seeds per kg/seed mass
Following the recommended protocols of the International Seed Testing Association rules (ISTA, 1993), 8 groups of 100 seeds of 95 species were weighed and averaged to calculate the number of seeds per kilogram, after mixing seeds from parent trees. The number was also expressed as individual seed mass for comparison.We delimited six categories for seed size based on seed mass following Foster (1982) for all these species. In addition, we included four other species within these categories. Salazar (2000) reported seed mass for Dipteryx panamensis, and Pearson et al. (2002) reported it for Alseis blackiana. The seed mass category (1–10 g) for Beilschmiedia pendula and Guettarda foliacea was inferred fromseed size and fruit type (drupes), respectively.
3.4. Moisture content
Moisture content for freshly collected diaspores of 94 species was calculated immediately after cleaning, following recommended protocols of the International Seed Testing Association rules (ISTA, 1993). Two replicates of 4–5 g were weighed, dried for 17 h at 103 8C, and then reweighed. Seeds larger than 1 cm were cut into smaller pieces for drying. Both diaspores (samaras) and seeds were evaluated for Platymiscium pinnatum. Moisture content of Trattinnickia aspera corresponds to seeds collected for the first time, which did not germinate at all, and germination data are for seeds from a second collection whose moisture content was not evaluated. Tachigalia versicolor moisture content is for the samaras (diaspores) of the five trees fromwhich they were collected, and germination data are for seeds from only two trees, since those from the other three trees appeared not to be viable. Thus, moisture content does not correspond to the unit evaluated in germination.

3.5. Germination tests
Seeds of 100 specieswere evaluated in germination tests done in Panama. Fruits collected from all trees were cleaned, and dispersal units (diaspores) were mixed and sown within the 1–7 days after cleaning. Throughout this paper, ‘‘seed’’ means a true seed or a diaspore. Species whose diaspores included endocarps of drupes were Anacardium excelsum, Andira inermis, Beilsch- miedia pendula, Dipteryx oleifera, Guettarda foliacea, Spondias mombin, and S. radlkoferi. Only diaspores of Spondias spp.were multiseeded. Althoughmultiple germination occurred in the two Spondias spp., it was very infrequent; thus, the count was done only once per diaspore (i.e. counted as one).
Four replicates of 100 seeds were sown on oven-sterilized sand in plastic trays. Large seeds were pushed into the sand for one-half of their thickness. Small seedswere covered by 3–5 mm of sand, but after watering most of them became partially uncovered. Thus, they were exposed to light. However, due to shortage of seeds for Calophyllum longifolium, Lonchocarpus latrifolius, Luehea speciosa, Dipteryx oleifera, and Gustavia superba, we sowed 5 replicates of 25 seeds, and for Hymenaea courbaril we sowed 4 replicates of 50 seeds. Two species, Carapa guianense and Prioria copaifera, had large seeds that did not fit into the trays; thus, we sowed 4 replicates of 50 seeds directly into pots. Conditions in the nursery were similar to those in commercial production nurseries in Panama, i.e. ambient temperature (25–31 8C), 30% full sunlight, and watering twice daily with an automated sprinkler system. The studies were done without any seed pretreatment to learn about natural dormancy. Exceptions were removal of the aril from seeds of Sapium glandulosum, Virola surinamensis, V. sebifera,and Lindackeria laurina and of the wing (by cutting) from those of Swietenia macrophylla, Pterocarpus rorhii, and Aspidosperma cruenta,to avoid fungal growth and to economize space.
Germination, defined as radicle emergence, was monitored weekly until 4 weeks without germination (after a clear peak occurred) to a maximum of 10 months, except for Enterolobium cyclocarpum, E. schomburgkii, andFaramea occidentalis,which were monitored for 11 months. Total germination, standard deviation of total germination, and coefficient of variation of total germination between replicates were calculated.Median (MLG) and mean (Mean LG) lengths of germination period for all seeds that germinated were calculated as measures of dormancy. Standard deviation of mean germination time (STD MLG) and total germination time (STD Germ) (time until the last seed that did so germinated)were calculated. Seedswith a fully-developed embryo and a median length of germination time (MLG) 30 days were considered to be nondormant, and those with an underdeveloped or a fully-developed embryo and anMLG > 30 days or an underdeveloped embryo and a MLG 30 days were considered to be dormant (Baskin and Baskin, 2004).
In some cases where germination percentages were low and number of seeds collected sufficient, we tested pretreatments to break dormancy, using mechanical scarification for Colubrina glandulosa (Ramalho Carvalho, 1994), Pseudosamanea guachapele, Enterolobium cyclocarpum, E. schkomburgkii (Salazar, 2000), Cassia grandis, and Sapindus saponaria; submergence for 2 min inwarmwater (80 8C) for Apeiba aspera, A. tibourbou, and Luehea seemannii (Acun ˜a and Garwood, 1987), then allowing them to cool to room temperature before sowing; and the latter treatment followed by 24 h in running tap water for Guazuma ulmifolia (Salazar, 2000).
3.6. Longevity studies
Ninety species were evaluated for seed longevity. Seeds were stored in paper bags at 20 8C and 60% relative humidity. Storage conditions were chosen considering the best conditions in many local field projects, where cold rooms are not available. Since many seeds had high moisture content, paper bags were preferred to plastic ones to avoid fungal growth. Fungicide (Vitavax) was applied to Copaifera aromatica, Trema micrantha, and Virola surinamensis. For each species with enough seeds coll