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Post-Agricultural Invasion, Establishment, and Growth
of Neotropical Trees
10/1/2004
The Botanical Review
By Randall W. Myster
I. Abstract/Resumen
II. Introduction
III. Clearing, Farming, and Abandonment Practices in the Neotropics
IV. The Post-Agricultural Environment and Disturbance Regime
V. Patterns of Tree Invasion, Establishment, and Growth
VI. Processes Affecting Tree Patterns
A. Crop Signatures
B. Seed Processes
C. Seedling Processes
D. Tree Processes
VII. Synthesis
VIII. Restoration, Management, and Conclusions
IX. Acknowledgments
X. Literature Cited
I. Abstract
Because clearing forest for agriculture is the most common disturbance in
the Neotropics, studies of post-agricultural recovery need to be conducted,
both to understand rain-forest function and structure and to address important
social issues such as deforestation, restoration, and sustainability. To assist
that effort, the clearing, planting, cultivation, harvesting, and abandonment
practices for common crops in the Neotropics, the post-agricultural environment
and disturbance regime, and the recovery mechanisms are reviewed for their
influence on the succession that follows abandonment. An important focus is on
the four historical effects, or signatures, of crops: crop persistence, crop
root exudate persistence, persistence of associated species, and indirect
effects of herbicide and fertilization regimes. In addition, the effects of
cattle introduced after cropping, such as hummock creation, soil compaction,
and dung deposition, are discussed. Further, permanent plot tree data from
Puerto Rico and Ecuador
are summarized to guide an understanding of how trees invade and replace
themselves. Finally, tabular summaries of completed Neotropical
seed/seedling/sapling field experiments are used, both to examine what is known
about the mechanisms of old-field succession in the Neotropics and to suggest
research directions and successful restoration strategies. A species-specific
and field type-specific investigation of tree-replacement mechanisms in the
future is suggested, leading to replacement modeling using data from permanent
plots.
II. Introduction
The study of post-agricultural (i.e., old-field) succession has helped
ecologists understand the processes that structure plant communities (Strong et
al., 1984) and the role of history and initial condition in community
development (Myster & Pickett, 1990b, 1994). In addition, old-field research
has led to important ecological theories, such as the initial floristic
composition hypothesis (Egler, 1954; Paine, 1977) and the resource ratio
hypothesis (Tilman, 1988). Using permanent plots established at abandonment as
the backbone of old-field research (e.g., the Buell-Small succession study in
New Jersey: Buell et al., 1971; Myster & Pickett, 1990a), scientists have
been successful in finding both the pattern of response over time after
abandonment from crops (e.g., plant cover: Myster & Pickett, 1990b) and
many of the mechanisms determining that pattern (see Myster, 1993; Bazzaz,
1996).
Unfortunately, a disproportionate number of these old-field and pasture
studies (see Castro et al., 1986; Hill et al., 1992) have taken place in the
temperate-forest regions of the United States (e.g., Oosting, 1942; Bazzaz,
1968; Buell et al., 1971; Pickett, 1982; Tilman, 1988; Myster, 1993) and Europe
(Grime, 1977; Miles, 1979), even though recovery of agricultural areas is
critical to ecosystems all over the world (Borhidi, 1988; Matson et al., 1997).
This is particularly the case in the Neotropics, where the conversion of
tropical forest to agriculture and then, usually, to pasture is the most common
kind of disturbance (Buschbacher, 1986; Uhl et al., 1988; Fearnside, 1993;
Thomlinson et al., 1996). Not surprisingly, recovery of these areas after
agriculture (Donfack et al., 1995; Fernandes & Sanford, 1995;
Quintana-Ascencio et al., 1996) addresses important Neotropical issues, such
as: deforestation and forest regeneration (Lanty, 1981; Grainger, 1988; Brown
& Lugo, 1990a; Myers, 1991; Singh, 1993; Skole & Tucker, 1993); forest
ecosystem restoration (Brown & Lugo, 1990b; Lugo, 1991); sustainability of
agriculture (Brown & Lugo, 1990a; Serrao & Toledo, 1990); maintenance
of biodiversity (Brown & Lugo, 1990a; Aide & Cavelier, 1994); and
impacts of global climate change on forest dynamics (Padoch & Vayda, 1983;
Hobble, 1992; Mabberley, 1992; Keller et al., 1993; Keller & Reiners,
1994). In addition, these areas may help create a buffer between primary forest
and more intensely human-impacted areas (Brown & Lugo, 1990a).
Studies of post-agricultural recovery may have been neglected because of an
implicit assumption that all disturbances have the same effect--opening
canopies in the forest--so only studies of tree-fall gap dynamics (Ewel, 1980;
Gomez-Pompa & Vazquez-Yanes, 1981; Denslow, 1987) or "secondary"
forests (Guariguata & Ostertag, 2001) are required. However, research in
Neotropical forest-succession areas other than treefall gaps, such as
landslides (Myster & Fernandez, 1995; Myster, 1997; Myster & Walker,
1997), abandoned plantations (Lugo, 1991; Myster, 2003a), and old fields /
pastures (Purata, 1986; Uhl et al., 1988; Donfack et al., 1995; Fernandez &
Sanford, 1995; Nepstad et al., 1996, Quintana-Ascencio et al., 1996; Rivera et
al., 2000; Chinea, 2002; Ferguson et al., 2003; Myster, 2003a, 2003b, 2003c),
has shown that both the abiotic environment and the biotic recovery mechanisms
vary widely between disturbances. In particular, post-agricultural areas are
likely to be starkly different from treefall gaps because they are larger in
area than are treefall gaps and, therefore, have a greater effect on dispersing
animals (Janzen, 1990), they remove most of the intact aboveground vegetation,
they have exotic species grown in them at high density for an extended period
of time (the duration of cultivation), they may undergo burning and recurrent
weeding, and they can have lasting historical effects of past crop use after
abandonment (crop signature: Myster & Pickett, 1990b, 1994).
For scientific, social, political, and ecological reasons, then, research is
needed in Neotropical old fields. To help guide this research effort, important
issues concerning post-agricultural recovery in the Neotropics, such as common
clearing, planting, cultivation, harvesting, and abandonment practices, are
examined, along with the post-agricultural environment and disturbance regime
and the successional mechanisms that control tree replacements. This review
goes farther than more general secondary-forest succession reviews that have
been published in the past decade (e.g., Finegan, 1996; Holl & Kapelle,
1999; Aide, 2000; Guariguata & Ostertag, 2001) by focusing directly on Neotropical
old fields and including data on successional pattern and mechanisms, working
definitions of old-field function and structure, comparisons with disturbances
of both greater and lesser severity for better synthesis, no false dichotomies
such as primary vs. secondary forest, natural vs. manmade, pioneer vs. climax
species, new growth vs. old growth, and a comprehensive framework of tree-tree
replacement mechanisms that all old-field studies can feed into. Plantations
will not be discussed directly; good reviews of their dynamics include Lugo (1991) and
Guariguata et al. (1995).
The focus is on the common crops of maize (Zea mays), sugarcane (Saccharum
officinarum), banana (Musa spp.), coffee (Coffea spp.) cassava (Manihot
esculenta), beans (Phaseolus spp.), and rice (Oryza spp.) and on pastures
usually established after cropping. How these crops and other aspects of
agricultural practices may affect the tree succession that follows abandonment
is a major focus. Furthermore, I argue that pastures are a kind of old-field
succession because they are usually converted from depleted agricultural fields
when cows are allowed to enter. Finally, extensive data tables from completed
mechanistic studies show key successional mechanisms and important variation in
how they produce tree replacements.
III. Clearing, Farming, and Abandonment Practices in the Neotropics
Archaeologists have evidence that maize was grown in the Amazon Basin
some 6000 years ago. All crops were first propagated vegetatively and then by
seed (Mabberley, 1992; Gomez-Pompa & Bainbridge, 1997). Since the invasion
of the Spanish and the subsequent genocide of the native "Indians,"
additional techniques such as the use of plowing animals, exotic cultivars, and
mechanization have been practiced.
Currently, two general forest-clearing techniques are found in the
Neotropics, both of which increase light quantity and contact of rainfall with
the soil but eventually decrease soil fertility. The first is mechanical
clearing (e.g., use of a bulldozer), with the removal of the woody biomass. It
is the most severe method practiced in the Neotropics and often leads to
changes in soil physical properties, but a similar manual clearing technique
can reduce these effects (Purata, 1986). The second forest-clearing technique
is shifting agriculture (slash and burn: Uhl, 1987; Tinker et al., 1996). It is
a common clearing method that existed long before mechanical clearing, but it
is being replaced by more technologically advanced farming in many areas. This
method usually involves the cutting down to the ground, or slashing, of the
natural vegetation and then burning it, a rotation of fields rather than crops,
and long fallow periods to help maintain soil fertility by allowing vegetation
to regenerate (Grigg, 1978). Although burning can produce a short pulse of some
nutrients, like phosphorus, it also volatilizes both organic matter and
nitrogen and raises soil temperature. In the long term this kind of farming
produces nutrient-poor soil and reduces the soil seed bank. Consequences of
these clearing and plowing methods include carbon loss, combination of the soil
organic and mineral horizons, and more soil aeration influencing microbial
activities such as nutrient release and mineralization (Bazzaz, 1996).
Table I highlights farming practices for common crops after clearing,
showing the great variety of both techniques and use of natural processes to
maximize production. In addition to varying fallow and crop periods (shorter
fallow periods are often used when the cost of land clearing is low), farming
practices can include growing a mix of crops and using a variety of both
traditional "low-input" (e.g., seed planting with digging sticks
called "dibbles") and modem "high-input" (e.g., mechanical
clearing with application of fertilizer and water) planting methods (Scatena et
al., 1996). Intercropping is another practice used for some crops; in this
method additional crops are planted between rows of existing crop. The decision
as to when to rotate fields and for how long to leave them fallow includes
consideration of weed (Qiang & Hu, 1999) and insect numbers, levels of both
soil fertility and productivity, labor availability, and dietary needs (Staver,
1989).
Further, there is a common synergism among agricultural uses in the
Neotropics because most often an area is cropped first and then, with declining
productivity, becomes pasture as livestock grazing leads to domination by
grasses (Scatena et al., 1996). Grass species can be either seeded into the
pasture (e.g., Setaria sphacelata in Ecuador: Myster & Sarmiento,
1998) or colonize naturally (Panicum maximum, Brachiaria humidicola, Paspalum
spp., and Hyparrhenia rufa in Amazonia: Nepstad et al., 1996). Because
commercial fertilizer is expensive, many of these fields are first converted to
pasture by letting in cattle and become truly abandoned only years later, when
cattle are excluded.
IV. The Post-Agricultural Environment and Disturbance Regime
The Neotropics consist of the American landmass and associated islands lying
between the Tropic of Cancer (23.5 [degrees] N) and the Tropic of Capricorn
(23.5[degrees] S; see Figure 1 for locations of major research sites). Between
these latitudes the sun has its least declination north and south, greatly
reducing light and temperature seasonally and allowing year-round plant growth.
Within the Neotropics temperatures can attain 38 [degrees]C but have a usual
range between 17[degrees]C and 27[degrees]C, and annual precipitation can reach
6m with seasonal wet and dry cycles (Mabberley, 1992). However, rainfall is
influenced by El Nino southern oscillations that occur every 3-7 years and can
cause floods, droughts, and fires (Sanford et al., 1985).
[FIGURE 1 OMITTED]
Many Neotropical soils are old, highly weathered, and leached oxisols and
ultisols, well drained, with a thin litter layer (Richter & Mammer, 1991;
Mabberley, 1992; Finegan, 1996) and low organic matter content. Also common in
the Neotropics are andisols derived from volcanic activity, which are very fertile
and support intensive agriculture (Vitousek & Sanford, 1986). Many
Neotropical soils have a higher clay content than do temperate soils and are
low in phosphorus. Consequently, plant growth in the Neotropics may be more
limited more by phosphorus than by other nutrients (Vitousek, 1984).
Biomes in the Neotropics that could be cleared for cultivation include
deserts, grasslands, and forests (some forests are evergreen moist; others are
seasonally dry). However, forests are most often used for cultivation. These
forests have high plant diversity where mycorrhizae are common, effectively
helping plants forage for phosphorus and other soil nutrients (Lugo & Lowe,
1995). Deserts are typically nonarable, tropical grasslands usually have
periodic droughts, and large areas are often under water, making cultivation
much more difficult (Mabberley, 1992).
At the moment of abandonment the abiotic environment is affected by the lack
of woody vegetation, even though a few large trees and shrubs, which may have
been too difficult to remove originally, may remain. Therefore, these areas
will have high light quantity and quality and substantial rainfall contact with
the soil. However, there may be low soil fertility and losses of fine roots (Da
Oliveira Carvalheiro & Nepstad, 1996), mycorrhizae, and soil
horizon/structure (Purata, 1986) resulting from the mechanical clearing of the
area for crops. If shifting agriculture (slash and bum: Uhl, 1987) was used
there may also have been a short pulse of some nutrients, like phosphorus, but
with a volatilization of both organic matter and nitrogen (Montagnini &
Sancho, 1994) and with an increase in soil temperature (Grigg, 1978). Such loss
of soil organic matter can also lead to reduced soil fertility. These
slash-and-burn methods produce, in general, nutrient-poor soils with carbon
loss and a poor soil seed bank. In addition, slash and burn may lead to a
mixing of the soil organic and mineral horizons and increased soil
aeration/oxidation, which can influence microbial activities affecting nutrient
release and mineralization (Bazzaz, 1996). Finally, application of fertilizer,
herbicide, or water may have other consequences (see Scatena et al., 1996)
following cropping.
Air temperature, vapor pressure deficit, and photon flux density have been
shown to be much higher in post-agricultural areas than in the adjacent rain
forest (Holl, 1999). The range of light intensity at ground level is 121-223
micromoles per [cm.sup.2] per second of photosynthetic active radiation [PAR]
for a 15-second average (Myster, 2003a), with higher average air and soil
temperature but lower average relative humidity than in forest (Uhl et al.,
1988).
Nitrogen may be a key soil nutrient (Neill et al., 1995, 1997; Piccolo et
al., 1997) and has been found to range between 0.027 and 0.080 in dry soil in
kg/[m.sup.2] to 9-cm depth (Myster, 2004). Rhodes et al. (1998) and Rhoades and
Coleman (1999) found less than 20% of nitrogen in old-field soils compared with
nearby forest soils, but under Inga spp. trees soil N[O.sub.3] was four times
higher, nitrification was five times higher, and soil organic matter was 7%
higher compared with open microsites. However, these soils are generally
wetter, with higher bulk densities (Rhodes et al., 1998). Ellingson et al.
(2000) found a dramatic but short-term increase in inorganic nitrogen (up to 57
kg per ha) and in soil pH (as much as 2.3 pH units) after slash and burn in a
Mexican pasture. Further, Reiners et al. (1994) report that pastures show a
decrease in acidity and an increase in some base exchange properties, an
increase in bulk density with its decrease in porosity, higher concentrations
of N[H.sup.4], lower concentrations of N[O.sup.-3], lower rates of nitrogen
mineralization, and lower rates of nitrification showing mixed soil fertility
signals, higher cation concentration, and higher pH than forest soils.
There is a depletion of potassium in pasture soils but an increase in
percentage of phosphorus retention compared with forest soils (Holl, 1999).
Holl (1998a) also found clear patch differences in potassium, and Myster (2004)
found that potassium ranged between .022 and .059 in pastures and fields.
Phosphorus ranged between .002 and .005 in pastures and fields as well (Myster
2004), but high earthworm densities in pastures compared with the mature forest
(Zou & Gonzalez, 1997, Leon & Zou, 2004) may help increase phosphorus
availability (Aide & Cavelier, 1994). Soil carbon, an important control of
nutrient availability (Brown & Lugo, 1990b; Desjardins et al., 1994; Veldkamp,
1994; Trumbore et al., 1995; Neill et al., 1996; Fearside & Barbosa, 1998),
was reduced after 15 years of succession, but pasture soils showed a 26%
increase in soil bulk density compared with forest soils (Rhoades et al.,
1998).
All studies point to old-field succession as a patch dynamic process where
shrub patches have higher levels of soil and litter nutrients than do grass
patches (Vieira et al., 1994). As time passes, light quantity at ground level
should decrease, but nutrients, soil organic matter, and litter should increase
(Webb et al., 1972; Opler et al., 1977). Due to year-round vegetative growth
and other favorable climatic features, responses and rate of recovery for
pastures may be faster in the Neotropics (especially in areas that were once
evergreen moist rain forest) than in the temperate zone, with nutrient cycling
and water retention recovering more quickly than diversity and species
composition (D. Schaefer, pets. comm.).
In general, a disturbance regime is characterized by its severity, size,
spatial location, and frequency (Myster & Pickett, 1990a; Myster, 2001).
The recovery that occurs after agriculture can also be conceptualized this way.
First, old-field disturbance is of relatively moderate severity because,
although most aboveground vegetation is cleared (or burned) and removed
(Myster, 2003d), fields keep both an intact soil profile and, if not burned, a
humus layer. Landslides (Myster & Fernandez, 1995; Myster, 1997; Myster
& Walker, 1997) would be an example of a more severe disturbance because
soil layers are lost. Second, plots used for agriculture in the Neotropics are
often no more than a few to tens of hectares in size, with larger combined
areas reserved for use as pastures after crop productivity decreases (Uhl et al.,
1988; Scatena et al., 1996). Third, many crops are specific to certain spatial
locations and elevations in Neotropical landscapes (Patzelt, 1996). For
example, coffee (Coffea spp.) is often grown in mountainous areas between 1000
m and 2000 m, with banana/plantain (Musa spp.), maize (Zea mays), and sugarcane
(Saccharum officinarum, Purata, 1986; Scatena et al., 1996) grown in the wetter
valleys between 0 m and 1000 m. And finally, the frequency of old-field
disturbance includes the number of times a field has been cultivated, the
length of each cropping period (e.g., duration, which for pastures is the
number of years cattle are present), its fallow time, and the order of crop
rotation. Furthermore, fields are usually fallow longer than they are in crop, are
reused with different crops and fallow periods until abandoned, are used for
5-10 years (shorter than temperate fields) until productivity declines (Uhl et
al., 1988), and are not plowed when abandoned (Scatena et al., 1996).
The disturbance regime should also include aspects of cattle usage. Use of
the land as pasture often begins when cattle (and sometimes horses) are let
into cleared areas that were recently used for cultivation and ends when cattle
are excluded (Humphreys, 1978; Whiteman, 1980). The longer cattle are present,
the more pronounced are the effects (Hecht, 1993), such as trampling of
vegetation, creation of hummocks, deposition of dung, and compaction of the
soil, which increases soil bulk density and leads to resistance to penetration,
to the formation of sesquioxides, and to the retardation of soil nitrogen
transformations due to waterlogged conditions (Rhoades et al., 1998). Finally,
because some of these areas have seasonal dry periods, recurrent fires are a
possibility, in which case grasses, with their soil-level meristems, would be
favored.
V. Patterns of Tree Invasion, Establishment, and Growth
Succession studies both in the temperate zone and the Tropics suggest that
research should focus primarily on the dynamics of the functionally and
structurally dominant species that were there before the disturbance and that
will subsequently reinvade, reestablish, and regrow. Because most agricultural
areas in the Neotropics were once forested, this means the invasion,
establishment, and growth of trees (McDonnell & Stiles, 1983; Myster, 1993;
Nepstad et al., 1996). A critical part of that investigation must be permanent
vegetation plots where individual trees are marked and followed through time, a
technique that has proved invaluable in temperate old-field studies.
Unfortunately, there have been only two such Neotropical studies, with
recurrent tree sampling at the same time intervals in plots established at
abandonment (in Puerto Rico: Myster, 2003b; in Ecuador: Author, unpub, data--which
has limited what can be said about how these areas change over time.
However, based on temperate old-field studies (for reviews, see Myster,
1993; Bazzaz, 1996) and Neotropical succession studies in gaps (e.g., Denslow,
1987; Everham et al., 1996), in landslides (Myster & Fernandez, 1995;
Myster, 1997; Myster & Walker, 1997), and in abandoned crop fields (Purata,
1986; Donfack et al., 1995; Fernandes & Sanford, 1995; Quintana-Ascencio et
al., 1996: Myster, 2003a, 2003b, 2003c), it is expected that after agriculture
there would be increases in species richness, biomass, density, height, basal
area, vertical structure, and productivity over time (Author, unpub. data). In
addition, invading species have greater mycorrhizal association, larger seeds
size, and more shade tolerance (Bazzaz & Pickett, 1980; Finegan, 1996).
Pasture plot data sampled in Puerto Rico
show that Neotropical old-field trees enter, peak, and decline in an
individualistic pattern, present for long periods with overlapping population
curves (Myster, 2003b). On Neotropical islands, trees common in other seres
(e.g., Cecropia spp., Schefflera spp.: Myster & Walker, 1997) may be absent
after agriculture, replaced by trees such as Syzygium jambos, Calophyllum
calaba, Clidemia strigilliosa, Miconia prasina, M. impetiolaris, Tabebuia
heterophylla, and Piper hispidum (Myster, 2003b). However, chronosequences both
in Puerto Rico (Aide et al., 1995, 2000) and in Brazil (Uhl et al., 1988) suggest
that this may be only temporary. Common successional species and genera,
however, such as Cecropia monostachya, Acalypha spp., Swartzia spp., and
Psidium spp., have been found since abandonment on the Neotropical mainland
(Author, unpub, data). In all cases the type of past crop (e.g., coffee,
banana, sugarcane, pastures) in a field leads to individual plant responses,
arguing strongly for fields to be investigated separately and for old-field
succession not to be viewed as a single process. For example, in recovering
coffee plantations, unique residual coffee (Coffea arabica) trees dominate, as
do Guarea guidonia, Andira inermis, Homalium racemosum, and Casearia decandra
(Myster, 2003b). As more data come in from the permanent plots, we may see more
tree species in the Melastomataceae and Rubiaceae and such genera as Alchornea,
Cordia, Inga, Trema, and Ceiba, as found in older Neotropical landslide
permanent plots (Myster & Walker, 1997).
Permanent plots on abandoned pastures also show life-form changes such as a
domination by grass (e.g., Panicum sp., Axonopus compressus) that peaks in
cover in year three and then declines, fern (Nephrolepsis sp., Thelpteris
deltoidea) and herbaceous (e.g., Commelina sp., Desmodium adscendens. Clidemia
hirta) cover that also peaks in year three but at lower cover levels than grass,
woody vines (e.g., Ipomea sp.) that continue to increase in cover over the
first five years, and trees and shrubs that enter, peak, and decline in an
individualistic pattern. Permanent plots in sugarcane fields show similar
trends of grass dominating early (mostly sugarcane itself, Saccharum
officinarum) and then declining to 50% cover levels, with Panicum spp. and
Brachiaria subquadripara also present, ferns (e.g., Nephrolepsis sp.,
Thelypteris deltoidea) and forbs (e.g., Desmodium sp., Bidens pilosa, Lantana
camara) as a small part of the flora that begins to decline immediately with
cover of woody species increasing steadily, trees showing this gradual increase
with members of the family Melastomataceae most common, and P. aduncum more
common here than in other fields. In the plots located in recovering banana
fields, grass and Musa sp. dominate early and then decline, but to greater
cover levels than in the sugarcane. Ferns attain greater cover levels in banana
than in sugarcane but forbs are a small part of the flora. Also, woody species
increase, but at smaller cover levels than in sugarcane. There were many of the
same tree species in banana fields as in sugarcane fields, but with additional
species (e.g., C. monostachyma) present. Finally, in the seeded pastures, grass
dominated almost completely (mainly the planted grass Setaria sphacelata), with
a few woody plants showing in year five. Fern and forb cover was small, and
pastures had few trees, but the species they did have were common to the sugarcane
and banana fields.
Community parameters in pasture plots show after five years: two or three
strata or horizontal levels that developed quickly; total stems at 200 per 250
[m.sup.2] plot (compared with 48-152 stems per 100 [m.sup.2] plot in Brazil;
Uhl et al., 1988); tree richness constant at 20 species (also, 20 in Brazil but
in a 100[m.sup.2] plot; Uhl et al., 1988); tree-stem evenness approximately
0.7; productivity peaking at year two at 0.5 kg/[m.sup.2]/yr (10 tons per ha
per yr in Brazilian pastures; Uhl et al., 1988) and then declining slightly;
turnover (for the formula, see Myster & Pickett, 1994) decreasing over the
first five years to 50%; and mean height at 250 cm and total basal area of
stems at 1000 [cm.sup.2]. For the sugarcane fields, total cover, an indicator
of stratification and developing structure, was greater compared with the other
fields, and banana greater than pasture, starting at 200% cover and gradually
declining with time. Species richness was also greater in the sugarcane fields
compared with the other fields, and banana had more species than did pasture.
Total stems were slightly more in the banana fields compared with the sugarcane
fields, and pastures had few stems. Compared with banana, mean stem height was
also greater in the sugarcane and increased through time, while pasture stems
remained small. Basal area stabilized at 500 [cm.sup.2] for sugarcane and
banana fields (Buschbacher et al., 1988).
There is a critical need for more long-term plots after agriculture in the
Neotropics in order to capture the complete range of successional responses.
Puerto Rican and Ecuadorean study plots begin an exploration of the pattern of
post-agricultural succession in the Neotropics, but more plots are needed (best
at the other active research sites; Fig. 1) in order to examine whether these
tree patterns continue in other old fields and pastures. Ideally, these plots
should be started at abandonment, researchers should tag individual tree stems,
and include replication of fields with the same crop history.
VI. Processes Affecting Tree Patterns
Critical in old-field investigation are the mechanisms that control
individual tree replacements (Myster & Pickett, 1992a; Myster, 2001),
because mechanisms work on individual plants, not on whole species. Individual
replacements may lead to the temporal change in species composition called
"succession," if all individuals of a species are replaced and
individuals of new species enter the sere. These compositional changes may then
define much of old-field patch dynamics. The resulting plant-based functions,
such as productivity and decomposition, within those patches are dominant in
defining ecosystems and landscapes (Myster, 2002a). Finally, replacement
mechanisms have many sources of variation in the way they operate where
neighborhood plants work to either increase or decrease the action of
mechanisms. For example, in the case of dispersal, plants next to the plant
being replaced may either attract dispersal agents (McDonnell & Stiles, 1983;
Holl, 1998b) or repel them, as when mammals prefer certain patches to others.
No plant lives forever. Every plant will eventually be replaced, usually by
one with a longer life span and a larger mature size. However, when plants
become large enough to form a canopy, they enter a thinning phase in which,
even though plants continue to die, they are not replaced by other individuals.
Instead, living plants nearby adjust their growth to fill in the gap left by
the dead plant. At some point plants reach a critical size where their death
can no longer be compensated for by this "neighborhood growth," and
they are then replaced by faster-growing, smaller plants. This is the
fundamental cycle of terrestrial vegetation and continues indefinitely, unless
underlying environmental gradients change or the species pool changes through
loss or gain of species (Myster, 2001). Because the world's terrestrial
vegetation is constantly undergoing replacement processes, plan-plant
replacements are one of the most fundamental ecological processes on earth and
a key element in vegetation dynamics, the mechanisms of which are most critical
at the seed and seedling stages of plant development (the regeneration niche;
Grubb, 1977).
A. CROP SIGNATURES
One important way in which agriculture differs from other kinds of
Neotropical disturbance (e.g., landslides, hurricanes, tree-fall gaps) is the
potential lingering effect of previous crops after abandonment (Myster &
Pickett, 1990b). These signatures may occur in at least four ways. First, crops
with extensive root systems and large root-to-shoot ratios can persist for long
periods of time, especially if fields are not plowed before abandonment (e.g.,
grasses grown for hay [Daclylis glomerata] persist in the temperate zone;
Myster & Pickett, 1990b, 1994). Second, crop root exudates may persist and
affect litter chemistry, fungus, soil microbes, decomposition, and seed
predators (Bazzaz, 1996). Third, species that were associated with the crop may
persist (e.g., Inga spp. and Guarea guidonia [planted for shade in coffee
plantations; Barros et al., 1995], Citrus spp. [planted fruit trees;
Garcia-Montiel & Scatena, 1994], or unwanted weeds [Vengris, 1953]) and
compete well with the native plants (Myster & Pickett, 1992a) or affect succession
by altering soil-nutrient availability (Inga spp. can fix nitrogen: Myster,
2003a; Myster & Walker, 1997). And fourth, fertilization and herbicide
practices may produce both residual abiotic (e.g., higher than normal levels of
phosphorus or nitrogen) and biotic effects (e.g., lower abundances and loss of
some microbe and insect species).
Because pastures are usually not plowed when abandoned (Scatena et al.,
1996), grasses persist after abandonment and may have a host of long-term
effects or signatures, as has been seen in temperate old fields (reviewed in
Myster, 1993). These effects include reduction of annual and biennial cover,
exclusion of woody species, and alteration of whole successional pathways
(Myster & Pickett, 1990a, 1990b) and have been seen in Neotropical pasture
plots (Myster, 2003b). While pastures may be viewed as crops of grass (e.g.,
Setaria sphacelata in Ecuador [Myster & Sarmiento, 1998], and Panicum
maximum and Brachiaria spp. in Brazil [Uhl et al., 1988]) that are later
abandoned when livestock are excluded, there are at least two fundamental
differences between pastures and old fields: the grass may not be planted (as
crops are) but may result from natural colonization (e.g., Panicum spp. and
Brachiaria subquadripara in Puerto Rico [Myster, 2003b] and Paspalum spp. and
ttyparrhenia rufa in Amazonia [Nepstad et al., 1996]); and livestock can alter
pastures dramatically by depositing dung, trampling vegetation, creating
hummocks, and compacting the soil, thereby increasing soil bulk density and
resistance to water penetration.
B. SEED PROCESSES
Completed field studies (Table II) show how the amount or strength of tree
replacement mechanisms at the seed stage vary among microsites, species, and
field types. Such data exploring variation in the working of individual
mechanisms can begin to weight different mechanisms against each other to help
decide which ones may be most important in determining a particular tree
replacement. Such replacements are bound to be due to the action of multiple
mechanisms, as expressed in Table II. Other benefits include the identification
of gaps in our knowledge of these mechanisms and, ultimately, how mechanisms
might be incorporated in future probabilistic replacement models. It is at
first clear that both the seed bank (Garwood, 1989) and seed pathogens need to
be investigated more and at other sites (see Figure 1). There is some evidence
that tree seeds are rare in the seed bank but that grasses and herbs are common
(Uhl, 1987; Nepstad et al., 1996). Variation is wide among sites for number of
seeds dispersed, suggesting that more detail is needed, especially for
microsites and species (Table II). Data do show that wind dispersal is more
common than animal dispersal (Guevara & Laborde, 1993; Cardoso et al.,
1996), probably because animals wish to avoid open areas, and that areas next
to forests and under woody patches are favored (Gorchov et al., 1993;
Galindo-Gonzalez et al., 2000). Further exploration is also needed for
germination, which has been shown to vary greatly among species and microsites
(Aide & Cavelier, 1994; Holl, 1999; Myster, 2004).
Seed-predation studies are most numerous and well designed among the
tree-replacement mechanism studies. Results show heavy seed losses everywhere.
Because seed predation is so important, issues, such as density of predators in
these areas, their behavior, and the availability and structure of cover where
they hide, are probably very important. For example, predators seem to prefer
the thick grass of pastures to the relative openness of a coffee plantation
(Myster, 2003a). Although pathogenic diseases may not be as important as
predation and other mechanisms, they may be key in specific field types such as
sugarcane plantations, with their mats of decaying cane biomass. Reviewed
results are comparable in strength and variation to these other Neotropical
succession studies that examine many of the same mechanisms (Purata, 1986;
Rico-Gray & Garcia-Franco, 1992; Donfack et al., 1995; Fernandes &
Sanford, 1995; Garcia, 1995; Everham et al., 1996; Quintana-Ascencio et al.,
1996; Myster, 1997; Medellin & Gaona, 1999).
C. SEEDLING PROCESSES
Completed field studies (Table III) show how the amount or strength of
tree-replacement mechanisms at the seedling/sapling stage vary among microsites
and field types. Such data explore the same variation in the working of
individual mechanisms as those for seeds in Table II and also help identify
gaps in our knowledge. Just as with seed pathogens, disease at the
seedling/sapling stage needs to be investigated more and at other sites (see
Figure 1). Although significant areas of leaf tissue can be lost to herbivory,
which may even cause some seedling mortality (Holl & Quiros-Nietzen, 1999),
competition seems to be the major mechanism working at this stage (Table III).
However, herbivory and pathogenic disease may be important in terms of their
effect on competition, even by altering competitive outcome among trees. Future
field experiments should examine these interactions, along with resource
availability. For example, persistence of past crops like coffee trees or
large-leaved banana may increase competition for light, while pasture grasses
may increase competition for water and soil nutrients. Competition for nitrogen
and its patchy availability may also be key, especially where nitrogen-fixing
trees like Inga spp. have been planted (coffee plantations; Myster, 2003a).
D. TREE PROCESSES
Even though studies on the seed/seedlings stages are most important, studies
with larger individuals are needed for a complete understanding of old-field
succession. Permanent plots in place now should help fill in those information
gaps in the future, such as the pattern of succession. In addition, analysis of
those data can implicate mechanisms among trees. However, field experiments
need to include later stages. Those experiments can be physically demanding,
but several manipulations can be performed; for example, removing species in
field plots and manipulating herbivory and pathogenic levels. Also, patch
effects often translate into effects of trees.
Because these areas were once rain forests, the dynamics of the old-field
trees is a major concern. Indeed, the most obvious succession pattern may be
the slow rate of invasion by trees into many of these areas. Tree seedlings and
saplings may overcome these "barriers" and invade successfully in
several ways: after incomplete clearing of woody vegetation (Nepstad et al.,
1994, 1996), leading to tree sprouting from coppiced tree trunks or root stocks
(Rico-Gray, 1991); as original trees remain and function as "nurse"
trees facilitating seed dispersal and other regeneration mechanisms (McDonnell
& Stiles, 1983; Myster, 1993; Holl, 1998b); or forest-edge shrubs spreading
into the field asexually (e.g., Miconia spp. in Puerto Rican fields) and
thereby allowing trees to invade quickly from the forest edges, independent of
reproduction from dispersed seed or from the weak seed bank (Garcia, 1995).
These early asexual woody plants can then facilitate later tree invasion by
overtopping and killing the grass or other remaining crops. Some of these
dynamics may be size-dependent because of post-abandonment human firewood
collection of "useful"-sized trees or browsing of small trees by
mammals, leading to an extended or arrested mid-succession old-field phase.
VII. Synthesis
Based on what we know now about regeneration mechanisms, tree succession in
the Neotropics seems to be controlled by: competition with trees, shrub and
large herbs for light (Holl, 1998a) and with grasses for water and soil
nutrients, due in part to the high grass root mass per volume of soil (Gerhardt
& Fredriksson, 1995; Holl, 1998a); drought stress (Gerhardt, 1993); high
loss of seeds to predators (and at various spatial scales; Myster, 2003a); a
high loss of seedlings to competition (Myster, 2004) or herbivory (Reader,
1992; Holl & Quiros-Nietzen, 1999); and a lack of seed input from the
surrounding area or from the soil (Gomez-Pompa & Vazquez-Yanes, 1981; Hammond,
1995; Nepstad et al., 1996; da Silva et al., 1996; Holl, 1998b, 1999;
Sarmiento, 1997; Myster, 2003a, 2004).
Taken together, plot data and experimental results suggest that successional
development in these fields follows this timeline: early succession is dominated
by the continuation of the past crop; after that, the edge effect of the
adjacent rain forest dominates (Gorchov et al., 1993); then shrubs and woody
vines invade, creating patch structure; and, finally, trees invade in
microsites created by the shrubs and grow to form a canopy (for a similar model
of temperate old fields, see Myster, 1993). Shrubs and their dynamics play a
key role in Neotropical old-field succession; that is, the species and the
cover or biomass of shrubs in a pasture largely determine its environmental
conditions and regeneration mechanisms (Zahawi & Augspurger, 1999). The
ability of many shrubs to attract seeds and shade out grasses, thereby
facilitating tree invasion, and to spread asexually (e.g., Miconia spp.) leads
to their domination in defining pasture dynamics. Consequently, aboveground
competition dominates over belowground (Holl, 1998a). Such positive woody
effects can also be seen near downed trees or logs (Peterson & Haines,
2000; Slocum, 2000). However, grass/herb patches may reduce drought stress in
some cases (Aide & Cavelier, 1995). This was also true in New
Jersey old fields, where the grass species was Dactylis and the
shrubs included Rhus glabra and Rosa
multiflora (Myster & Pickett, 1992a). However, it should be true everywhere
that the inhibiting presence of grasses in pastures leads to a slow recovery
(Aide et al., 1995, 1996; Myster, 2003b) compared with other post-agricultural
areas.
As the length of time an area is in crop, or its duration, increases, the
length of successional or recovery time may also lengthen (Purata, 1986; Waller
et al., 1986). For example, a short cropping period can lead to large
contributions from the seed bank, and trees may regenerate quickly from stump
or root sprouts (Uhl et al., 1988; Rico-Gray, 1991). As the cropping period
increases, decay of rootstocks and tree stumps leads to grass invasion and
prolonged tree invasion (Nepstad et al., 1996). However, old fields may
overcome this to a degree through regeneration from clonal shrubs such as
Miconia spp. and the creation of suitable microsites by these shrubs for the
advancing trees (Vieira et al., 1994; Myster, 2003b).
In general, these studies and others in Neotropical fields confirm many of
the expectations from temperate studies (see Myster, 1993) where major
successional mechanisms seem to be seed rain (Myster & Pickett, 1992b),
seed predation, and seedling herbivory/competition. The recovering grass fields
of New Jersey
showed key mechanisms of seed predation and competition, but also seedling
predation, frost heaving, and damage from falling stems and branches (Myster,
1993). In comparison, Neotropical permanent plots show similar life-form
changes, such as: domination by grass (e.g., Panicum sp., Axonopus compressus)
that peaks in year three and then declines (compared with eight-year grass
dominance in New Jersey old fields grown in Dactylis glomerata, see references
in Myster, 1993); fern (Nephrolepsis sp., Thelpteris deltoidea) and herbaceous
(e.g., Commelina sp., Desmodium adscendens, Clidemia hirta) cover that also
peaks in year three but at lower cover levels than grass; woody vines (e.g.,
Ipomea sp.) that continue to increase in cover over the first five years; and
trees and shrubs that enter, peak, and decline in an individualistic pattern
(seen also in the Dactylis spp. fields in New Jersey [Myster, 1993], where tree
invasion was suppressed until Dactylis declined).
Finally, for further synthesis we need to compare old-field results and
mechanisms with those from a more severe disturbance. During the recovery from
landslides, for example, seed rain showed 48 seeds per [m.sup.2] over a similar
time interval as studies in Table II and the seed bank was 3 seedlings for a
similar soil sample, there was only a 10% loss of seeds to predators with 50%
of the seeds lost to pathogens and 25% of them germinating, and 20% tree stem
survival over a one-year period and leaf area losses to pathogens in the 1-3%
range and to herbivory as much as 34% (Myster & Fernandez, 1995; Myster, 1997,
2002b). This shows a reduced seed rain and seed bank as the severity of the
disturbance increases, with more seeds lost to pathogens but fewer seeds lost
to predators.
VIII. Restoration, Management, and Conclusions
Restoration ecology attempts to manage natural succession processes toward
an end that better satisfies human needs (Moran et al., 1996). In these
old-fields, managers may want, for example, to retard succession, to quicken
the rate of recovery, perhaps by increasing facilitating mechanisms such as
dispersal and decreasing inhibitory mechanisms such as predation and
competition, in order to generate rain-forest timber for use as a sustainable
resource or to create rain-forest habitat for rare species, to hold succession
(Niering & Goodwin, 1974) in a state where agricultural is less costly to
maintain, or to alter the natural successional trajectory itself (Myster &
Walker, 1997) to match soil conditions for maximum crop production. Mechanisms
of tree replacement, as discussed in this review, can be manipulated toward any
of these ends, either as inhibitors or facilitators.
Returning land to high productivity in as short a period of time as possible
and then maintaining its sustainability are major concerns (Nepstad et al.,
1991). In all these cases post-agricultural successional studies are critical
for a complete understanding of how these Neotropical areas regenerate and
function. At least two restoration methods have had success after other
disturbances (for landslides, see Myster & Sarmiento, 1998): the planting
of native seedlings and nurse trees (particularly if they can fix nitrogen),
and the addition of fertilizer (Guariguata et al., 1995; Rhoades et al., 1998).
A special issue of the journal Restoration Ecology (see Aide, 2000 and papers
therein, such as Holl et al., 2000; Peterson & Haines, 2000; Silver et al.,
2000; Slocum, 2000; Zimmerman et al., 2000) dealt with pastures. Many of the
suggestions there have been made for the restoration of other tropical
disturbed areas (e.g., for landslides, see Myster & Sarmiento, 1998) and
revolve around finding both suitable microsites for recruitment (Malo &
Suarez, 1995; Myster, 2003a) and identifying recovery "barriers"
(Nepstad et al., 1990; Aide & Cavelier, 1994). The planting of native seedlings
in good microsites is a common approach and should include a few larger trees
or shrubs to act as recruitment foci, by attracting bird dispersers (McDonnell
& Stiles, 1983; Howe, 1984; Holl, 1998b) and acting as "nurse"
trees (e.g., Guevara et al., 1992; Vieira et al., 1994; Rhoades & Coleman,
1999), creating positive tree feedback mechanisms. Another restoration strategy
is the addition of nutrients, especially if soil was removed or damaged. One
may do both, of course, by adding nitrogen-fixing species such as Inga spp.
However, it needs to be kept in mind that old-field succession must be
understood scientifically in order for it to be managed well and that,
consequently, the successional processes and mechanisms reviewed here should be
a key part of any restoration efforts.
An important thrust of future research should then be on both the pattern
and the processes of tree invasion and establishment, with a significant focus
on crop signatures. This review of old-field and pasture studies in the Neotropics
can help that effort by assisting in the construction of hypotheses and
predictions about key species-specific and field-type-specific regeneration
mechanisms after agriculture. Researchers need to be interested in how
mechanisms vary over space and time and how they are affected by the resident
tree species and by a field's history, including its crop signature. For those
studies showing species variation in mechanisms, summaries such as Tables II
and III could then be used to construct replacement probabilities among species
in each field type for each specific mechanism. From there, mathematical
analysis could lead to predictions of tree-replacement sequences and their
comparison with actual replacement sequences found in permanent plot data.
Old-field studies are paramount for an understanding of how Neotropical rain
forests regenerate and function. To date we have some understanding of the
pattern of their recovery, but it is limited to only two sites, making
establishment of permanent plots at other sites (see Figure 1) critical for a
more complete examination of pasture succession. In addition, we have a fair
amount of information about mechanisms driving those patterns of recovery and
tree replacement; however, a primary thrust of future research should also be
on the processes of tree invasion and establishment (see Myster, 1993). This
would naturally lead to additional modeling, both of individual tree
replacements and of tree composition and abundance. With these models,
prediction of tree densities in entire pastures is then possible if the number
and starting tree abundance in each patch type, as well as the number of
patches of each type in the pasture, are known.
Finally, I suggest that the ecophysiology of the dominant species needs to
be better investigated (Gerhardt & Fredriksson, 1995) as a possible driver
of the replacements (tolerance model: Myster & Pickett, 1992a), focusing on
how individual tree species grow in the presence of different resources. Also,
environmental conditions need to be sampled in more sites, and investigations
need to be carried out in a patchwise manner (for patch differences in
regeneration mechanisms, see Vieira et al., 1994). Understanding mechanisms of
old-field succession and uncovering gaps in our knowledge may in turn lead to
construction of hypotheses and predictions about pasture regeneration, to be
tested in field experiments and in comparative pattern analysis using permanent
plots. Results show that future research should have a more exact within-patch
(Myster, 2003c) and individual tree species focus.
IX. Acknowledgments
I wish to thank O. Mironova, P. Burton, M. Palmer. D. Gorchov, J. Parrotta,
S. Gleeson, N. Brokaw, and K. Holl for commenting on a previous version of this
article. I also wish to thank G. Reyes for her help in finding reference
material and T. Bower for his help with the map. This research was performed
tinder grant DEB-9411973 from the National Science Foundation to the Institute
for Tropical Ecosystem Studies, University
of Puerto Rico, and to the
International Institute of Tropical Forestry, as part of the long-term
Ecological Research Program in the Luquillo
Experimental Forest.
Table I
Planting, cultivation, and harvesting practices of common crops
in the Neotropics
Crop Planting Cultivation
Sugarcane Hand planted from Stumps cleared of
cuttings at wet sprouts; rows of
season vines tilled;
grasses resprout
Corn Seeds hand planted Crop rotation;
intercropping with
clover and beans
Coffee Grown seedlings Legumes often
planted in deep provide shade
holes
Bananas Corms and root Weak roots, so
suckers placed in weeds hand cut
cleared areas at
wet season
Pasture Cows let in; grass Fire can reduce
seed may be added woody growth
Cassava Hand tilled, then Grows well on
stem cuttings low-fertility soils;
planted in holes intercropped with
with organic beans
matter added;
grafting common
Beans Planted by stick Commonly intercropped
or hoe; seeds then with corn and other
added but need crops
tilled soil to
germinate
Rice Flooded areas Flooding regime
tilled; seedlings must be maintained;
then hand planted some weeding
Crop Harvesting General references
Sugarcane Stems hand cut; Husz, 1972; Fauconnier,
15-20 years of 1992
yields
Corn Cobs harvested by Schrimpf, 1966;
hand Rouanet, 1987
Coffee Hand picked; trees Wellman, 1961;
last for decades Cambrony, 1992
Bananas Bunches hand cut; Seelig, 1969; Reynolds,
may last 5-20 1981
years
Pasture Livestock excluded Humphreys, 1978;
Whiteman, 1980
Cassava Best in cooler Hall, 1984; Cock,
months; variable 1985
after 7-18 months
of growth
Beans Hand picked, then Duke, 1981;
hoed under Schoonhoven &
Voysest, 1991
Rice All aboveground Chandler, 1979;
biomass harvested, Lang, 1991
then machine
picked
Table II
Replacement mechanisms in completed seed studies of Neotropic oldfields and pastures. Consult the specific references for details both on methodology and on species and other sources of variation in the workings of each mechanism.
Mechanism, Time Field
amount period Microsite type Reference
Seed dispersal
6-92/[m.sup.2] 1 year Grass/ Pasture Vieira et al.,
shrub 1994
23-100/[m.sup.2] 1 year Grass/ Pasture Holl, 2002
shrub
190/[m.sup.2] 1 year Pasture Holl, 1999
39-4610/[m.sup.2] 1 year Pasture Sarmiento,
1997
0-8/[m.sup.2] 1 month Pasture Aide &
Cavelier, 1994
10/[m.sup.2] 2 weeks Pasture Holl, 1998b
2-990/[m.sup.2] 1 year Pasture Nepstad et
al., 1996
400/[m.sup.2] 3 months Edge Oldfields Myster, 2004
Seed bank
1676 6 months Pasture Zahawi &
Augspurger,
1999
10/10g soil 2 months Edge Oldfields Myster, 2004
Seed predation
95% loss 1 month Oldfields Notman &
Gorchov, 2001
90%loss Edge Pasture Sarmiento,
1997
4-100% loss 19 days Pasture Aide &
Cavelier, 1994
59-68% loss 24 days Grass/ Pasture Holl, 2002
shrub
50-75% loss 14 days Coffee/ Myster, 2003a
pasture
50-79% loss 14 days Grass/ Pasture Myster, 2003c
shrub
63% loss 30 days Edge Pasture Holl & Lulow,
1997
>80% loss 20 days Pasture Nepstad et
al., 1990
67-90% loss 14 days Edge Oldfield, Myster, 2004
Seed pathogenic disease
20-45% loss 14 days Coffee/ Myster, 2003a
pasture
5-10% loss 21 days Edge Oldfields Myster, 2004
Germination
0-53% 6 months Pasture Holl, 1999
77% Pasture Vieira et al.,
1994
15-35% 14 days Coffee/ Myster, 2003a
pasture
9-77% 3 months Grass/ Pasture Holl, 2002
shrub
5-10% 21 days Edge Oldfields Myster, 2004
Table III
Replacement mechanisms in completed seedling/sapling studies of Neotropic oldfields and pastures. Stem disease and stem herbivory are given as percentages of leaf area lost, and competition refers to percentage of stem survival. Consult the specific references for
details both on methodology and on species and other sources of variation in the workings of each mechanism.
Process, Time Microsite Field Reference
amount period type
Stem disease
3% 6 months Edge Oldfields Myster, 2004
Stem herbivory
35% 16 days Pasture Nepstad et al., 1996
<25% Pasture Gerhardt, 1993 33% Nepstad et al., 1990 5% 6 months Edge Oldfields Myster, 2004 Stem competition 40% 5 months Aide & Cavelier, 1994 95% 1 year Grass/shrub Pasture Holl, 1998a ><5% 3 year Pasture Gerhardt, 1993 100% Pasture Vieira et al., 1994 1-10% loss 18 months Grass/shrub Pasture Holl, 2002 30-50% 6 months Edge Oldfields Myster, 2004 >
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RANDALL W. MYSTER
Department of Biology
University of Central Oklahoma
Edmond, OK 73034, U.S.A.
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