Effects of light,moisture, temperature,and litter on the regeneration of five tree species in the tropical montane wet forest of Puerto Rico

Field experiments were conducted to investigate the effects of light, moisture, temperature, and litter on the regeneration of two early-, one mid-, and two late-successional tropical tree species. High light and litter seem to be universally good cues for regeneration, increasing seed/seedling survival for all species except for Cecropia (an early-successional species) whose small seeds may not be able to penetrate the litter layer. In addition, the high temperature environment in both artificially shaded and nonshaded areas of a natural gap exhibits less seed loss, an increase in the percent and rate of germination, and an increase in seedling survival for Dacryodes (a late-successional species), than the lower temperature environment under an intact canopy. Low soil water is also a good cue for Dacryodes germination as it is for Prestoea and Cecropia. Finally, the lower temperature environment found under the forest canopy (compared to the natural gap) leads to less seed loss and more germination for Guarea (a mid-successional species). Our results suggest that a good patch for regeneration of many species in this forest, early- as well as late-successional species, would have high light and a litter layer that moderates temperature and moisture extremes. The substantial variation in suitability among regeneration filters and species could: (1) contribute to low establishment success, i.e., most dispersed propagules do not become trees, (2) make it difficult to group species into germination strategies, and (3) make it hard to generalize about a net effect of any specific environmental variable on establishment. We suggest that tropical disturbances should be viewed in terms of their impact on a variety of environmental cues, which may signal germination and impact subsequent growth and survival.     

Contrasting litter effects on old field tree germination and emergence

Because the fate of seeds is critical to understanding the invasion of old fields by trees, and plant litter is an important component defining the old field microsite of dispersed seeds, I investigated the effects of litter type (Solidago spp./goldenrod,Quercus spp./oak, mixed) and litter amount (100–800 g/m²) on tree seed germination and seedling emergence. I found that at all densities bothSolidago andQuercus litter greatly reduced emergence of the small-seeded, bird-dispersed species,Juniperus virginiana andCornus florida. For one of the large-seeded, mammal-dispersed species,Carya tomentosa, high densitySolidago litter and high density mixed litter treatments reduced emergence. For the other large-seeded species,Quercus rubra, the high density mixed litter treatment and all levels ofSolidago litter reduced emergence.Quercus seedlings emerged twice as often as the other three species in control pots without litter.Carya emerged before the other species but the high density oak treatment delayed the expansion of its cotyledons. My results suggest that litter may contribute to the slow rate of tree invasion and the low probability of tree establishment in old fields. However, old field litter studies taken together point to the difficulty in drawing general conclusions about any net effect of litter on old field tree establishment.     

Tree invasion and establishment in old fields at Hutcheson Memorial Forest

In this review I present results from pattern analysis and field experiments in New Jersey, United States concerning tree invasion and establishment in old fields. Hutcheson Memorial Forest Center (HMF) is the New Jersey study site and a logical choice to anchor a review of this topic. HMF contains the longest and largest old field permanent plot study in the USA including extensive data concerning tree invasion and establishment. HMF has also been the site of considerable old field tree experimental research. In addition, I review other investigations of old field tree invasion and establishment of the eastern deciduous biome and contrast them with HMF. I identify critical questions concerning tree invasion and establishment, indicate what progress has been made towards answering these questions and propose future experimentation. I also synthesize results into a conceptual model and investigate the relative importance of seed and seedling processes in determining tree dynamics in old fields. The idea of a possibility or “window” for tree invasion and establishment and its variation form the basis for this review. For example, the temporal variation of windows is reflected in tree establishment patterns at HMF because wind- and bird-dispersed species invaded one year after cessation of cultivation while mammal-dispersed species were not present until year 12. Although analysis of size classes of individual HMF trees imply that windows close quickly, studies are of too short duration to tell definitely. Spatial variation in invasion and establishment pattern includes exponential decline in seed and stem density with distance from forest edge which deteriorates with time as the old field becomes more structurally complex. Additional spatial heterogeneity occurs when seeds and seedlings of bird-dispersed species clump which conversely becomes more pronounced with time. Many of these HMF patterns are seen in other eastern United States old field sites. When reviewing field experiments from my site and others, I focus on the spatial and temporal variation and the difference between species in the effect of processes on tree seeds and seedlings. I do this because this variation relates directly to the dynamic nature of windows whose quantification is necessary for modeling. Combining my pattern analysis with a survey of variation in seed and seedling mortality caused by different successional processes in old fields, I conclude that seed dispersal, conditions necessary for seed germination and seed and seedling predation are the critical processes controlling and constraining tree invasion and establishment in old fields. Competition and indirect effects of litter and the environment, which modify how these processes affect tree dynamics, are also important. Therefore, processes involving the interaction of species with the environment and with other species form the principal filters on and limitations to tree invasion and establishment and not the non-interactive life-history traits of individual tree species such as growth rate or longevity. The interaction of pattern and process and the affect of many of these processes on old field community structure are also discussed.     

Effects of Species, Density, Patch-type, and Season on Post-dispersal Seed Predation in a Puerto Rican Pasture1

An experimental study of seed removal of four woody species in an abandoned pasture revealed significant main effects of species, density (higher densities survived more than lower densities), and patch‐type (seeds under shrub patches survived more than in grass patches), but no effects of season. Rates of seed loss decreased with seed size across species. Significant interactions between species and density and between species and patch‐type were also observed.     

Genetic and bioinformatic analysis of 41C and the 2R heterochromatin of Drosophila melanogaster: a window on the heterochromatin-euchromatin junction

Genomic sequences provide powerful new tools in genetic analysis, making it possible to combine classical genetics with genomics to characterize the genes in a particular chromosome region. These approaches have been applied successfully to the euchromatin, but analysis of the heterochromatin has lagged somewhat behind. We describe a combined genetic and bioinformatics approach to the base of the right arm of the Drosophila melanogaster second chromosome, at the boundary between pericentric heterochromatin and euchromatin. We used resources provided by the genome project to derive a physical map of the region, examine gene density, and estimate the number of potential genes. We also carried out a large-scale genetic screen for lethal mutations in the region. We identified new alleles of the known essential genes and also identified mutations in 21 novel loci. Fourteen complementation groups map proximal to the assembled sequence. We used PCR to map the endpoints of several deficiencies and used the same set of deficiencies to order the essential genes, correlating the genetic and physical map. This allowed us to assign two of the complementation groups to particular "computed/curated genes" (CGs), one of which is Nipped-A, which our evidence suggests encodes Drosophila Tra1/TRRAP.     

Individualistic patterns of annuals and biennials in early successional oldfields

The importance of Gleasonian species individuality, with its relation to life history strategies in succession, has been implied by studies lasting only a few years, or studies relying on chronosequences. Even in long-term studies, it has been addressed without statistical tests. Here, we examine the first six years of succession in permanent plots on ten contrasting oldfields to statistically determine the role of species individuality in early oldfield succession.Percent cover data were collected each summer in 48 permanent plots in ten oldfields as part of the Buell Succession Study at the Hutcheson Memorial Forest on the New Jersey Piedmont, USA. Congruent patterns of mean percent cover over time clearly reflect life history strategies of annuals and biennials. Kendall's coefficient of concordance, calculated for population patterns of annuals or biennials in each oldfield, confirms that population patterns within life form groups are similar and supports the contention that life history strategies are important in determining successional pattern once species become established in an oldfield.Profile analysis, a statistical test for parallelism among species patterns, performed on all population patterns in each oldfield, confirms that these patterns are individualistic. The individualistic pattern implies that succession may be driven by the different strategies of dispersal, growth, and resource use of the species involved.     

Thermo- and Photoperiodicity and Involvement of Gibberellins during Day and Night Cycle on Elongation Growth of Begonia x hiemalis Fotsch

The effects of thermo- and photoperiodicity on elongation growth and on endogenous level of gibberellins (GAs) in Begonia x hiemalis during various phases of the day-night cycle have been studied. Plant tissue was harvested during the day and night cycle after temperature and photoperiodic treatments and analyzed for endogenous GAs using combined gas chromatography and mass spectrometry. Elongation growth increased when the difference between day and night temperature (DIF = DT − NT) increased from a negative value (−9.0 and −4.5°C) to zero and with increasing photoperiod from 8 to 16 h. When applied to the youngest apical leaf, gibberellins A₁, A₄, and A₉ increased the elongation of internodes and petioles. GA₄ had a stronger effect on elongation growth than GA₁ and GA₉. In relative values, the effect of these GAs decreased when DIF increased from −9 to 0°C. The time of applying the GAs during a day and night cycle had no effect on the growth responses. In general, endogenous levels of GA₁₉ and GA₂₀ were higher under negative DIF compared with zero DIF. The level of endogenous GA₁ in short day (SD)-grown plants was higher under zero DIF than under negative DIF, but this relationship did not appear in long day (LD)-grown plants. The main effects of photoperiod seem to be a higher level of GA₁₉ and GA₁ at SD compared with LD, whereas GA₂₀ and GA₉ show the opposite response to photoperiod. No significant differences in endogenous level of GA₁, GA₉, GA₁₉, and GA₂₀ were found for various time points during the diurnal day and night cycle. Endogenous GA₂₀ was higher in petiole and leaf compared with stem, whereas there were no differences of GA₁, GA₉, and GA₁₉ between plant parts. No clear relationship was found between elongation of internodes and petioles and levels of endogenous GAs. Received December 26 1996; accepted July 1, 1997     

Seed Inputs to Microsite Patch Recovery on Two Tropandean Landslides in Ecuador

To understand landslide regeneration and provide information necessary for restoration, we sampled seed rain, seed pool, and plant cover on two Ecuadorian landslides. We trapped 1304 seeds and found that, while most seeds were in the family Asteraceae, there was substantial variation in seed rain among plant families. Four hundred and seventy-five seedlings emerged from soil samples, including nonvascular and vascular families; again, species in Asteraceae dominated, with species in Piperaceae also very common. Plant cover, consisting of members of four fern families and 20 vascular plant families—with species in Asteraceae, Melastomataceae and Poaceae most common—was scored as a percentage of the total plot area. Principal components analysis (PCA) showed that, for all three of these plant life stages (seed rain, seed-propagule pool, plant cover), spatial variation was dominated by differences between the two landslides rather than within-landslide plot differences. PCA also showed that plots separated best on axes defined by the families Cecropiaceae, Urticaceae, Melastomataceae, Papilionaceae, Asteraceae, and Araceae with clumping of families in PCA space suggesting common successional strategies. Another multivariate technique, canonical correspondence analysis (CCA), showed that the combined seed rain and seed pool data could predict the percent cover of the family Verbenaceae and that the current plant cover families could predict Asteraceae seeds and seedlings. Finally, we use our past and present landslide data, along with multivariate modeling results, to suggest strategies for successful landslide restoration.