One perceives a forest of jagged,gnarled trees protruding from chored in deep, black, foul-smelling mud, verdant crowns arching toward a blazing sun, the whole mass buzzing with insects. These are the ?rst impres- sions a visitor develops when approach- ing one of the most common sights on tropical shores?a mangrove swamp. Here is where land and sea intertwine, where the line dividing ocean and con- tinent blurs. In this setting the marine biologist and forest ecologist both must work at the extreme reaches of their disciplines. Naturalists have long struggled to de- ?ne, in proper ecological terms, the en- vironment of a mangrove swamp. Is it an extreme form of coral reef or a ?ood- ed coastal forest? Compared with the tropical timberlands of some continen- tal interiors (which can house as many as 100 species of tree on a single hec- tare), a mangrove forest appears puny, monotonous and depauperate. Even the relatively rich Indo-Paci?c coasts boast only some 40 mangrove species along their entire length. In the Western Hemi- sphere only eight or so mangrove spe- cies can be found. And of this small set just three kinds of mangrove tree are truly common. The word ?mangrove? itself is some- what misleading. It is not a formal tax- onomic term; rather, it applies to those vascular plants that share a set of phys- iological mechanisms for living in shal- low seawater. For example, mangrove trees are able either to exclude or to ex- crete salt from their tissues. These plants can also sprout aerial roots that permit the exchange of gas for aerobic respiration. This adaptation allows the trees to survive despite being ?rmly rooted in oxygen-deprived intertidal soils. Although a salty habitat is not strictly required for growth, mangrove communities develop only near the sea because they cannot compete success- fully with freshwater ?ora. Mangroves are also limited by a need for rather balmy conditions. As is the case with corals, these trees cannot sur- vive in places where the average water temperature falls below about 23 de- grees Celsius (73 degrees Fahrenheit). This requirement causes bands of man- grove and coral to grow largely in par- allel swaths along the world?s tropical coastlines. But deviations from this simple pattern occur commonly. For instance, coasts that are continuously subjected to large in?uxes of sediment (such as the shores of western Africa) or areas where deep, cold water rises to the surface (such as the coastal wa- ters o? eastern Venezuela) lack coral reefs but can support extensive man- grove swamps. Conversely, some coral islands in the central Paci?c lack an ac- companying fringe of mangroves, ap- parently because the ?oating propa- gules that serve as seeds for these trees cannot reach such remote isles. Mangrove swamps typically fall with- in one of two broad categories of clas- si?cation: mainland or oceanic island. The former group includes those com- munities that border continental coasts and are thus permanently sandwiched between salty ocean water and freshwa- ter carried by streams from the interior. Hence, mainland mangroves must usu- ally cope with a pronounced variation in salinity across their width. This situa- tion is quite distinct from that of ocean- 94 SCIENTIFIC AMERICAN March 1996 Caribbean Mangrove Swamps Despite their ubiquity and prominent position between land and sea, these tropical ecosystems still hold countless surprises for researchers by Klaus R?tzler and Ilka C. Feller TROPICAL SHORES around the world are commonly lined with mangrove swamps (above). Salt-tolerant mangrove trees thrive along coasts where the average temperature remains su?ciently warm. Mangroves on the barrier reef bordering Belize (inset) are central to the authors? long-term research. These swamps (opposite page) host rich communities of plants and animals within the shady tree canopy and around the permanently submerged mangrove roots. The swamps also support a distinctive group of creatures that have adapt- ed to life in the thin zone between high and low tide levels. ROBERTO OSTI BELIZE Copyright 1996 Scientific American, Inc. SCIENTIFIC AMERICAN March 1996 95 CHIP CLARK Smithsonian Institution Copyright 1996 Scientific American, Inc. ic-island mangroves, which form on shallow banks or in lagoonal areas well separated from the mainland. They are normally less a?ected by freshwater carried laterally than by the intermittent shifts in salinity that result from in- tense evaporation or from frequent tropical downpours. Although interest in mangrove biol- ogy reaches back in history at least as far as Alexander the Great?s expeditions to the Arabian Sea, scienti?c knowledge of this intriguing ecosystem is still ru- dimentary, and key questions remain largely unanswered. Are mangrove com- munities as rich and productive as oth- er tropical environments? Is their role in protecting juvenile ?sh indeed as im- portant to commercial ?sheries as many people have speculated? Do mangrove swamps serve to protect coastlines from erosion? Although researchers have made detailed observations of many di?erent mangrove swamps around the world, a huge gap exists in the under- standing of how the di?erent compo- nents of such intricate natural systems work together. A Cay is Key Concerns about the limited under- studies of mangrove swamps motivat- ed us to mount a long-term research campaign at one place. We chose to ex- amine the biodiversity and ecology of a locale that was relatively accessible? the spectacular barrier reef o? the coast of Belize. We are fortunate to have been able to conduct our ?eldwork there from a permanent station situated on a tiny coral island about 10 miles o?- shore. One of us (R?tzler) discovered this site on a memorable morning in February 1972. It was something of a serendipitous ?nd during an excursion with a colleague, Arnfried Antonius. We had chartered a small boat out of Belize City, some 50 miles to the north, and were looking for a passage through the shoals?one through which we had traveled several times before. But our boat?s crew was unfamiliar with the lo- cal waters and misguided us in our search for the break in the reef. As we motored seaward, we could hear the splash of waves breaking on the shal- low coral, but neither of the two is- lands in front of us matched what we remembered from our previous visits. To our astonishment we noticed several buildings on the smaller island ahead and decided to make a closer examina- tion of this curious display of civiliza- tion within a rather remote wilderness. A few moments later we tied up our ves sel on the island?s concrete dock and walked toward the largest house. No in- habitants greeted us (other than a few mildly disturbed pelicans), but hanging above the main gate was a sign: ?Wel- come to Carrie Bow Island.? Little did we know then that this speck of sand containing three cottages and two outhouses was the property of Hen- ry T. A. Bowman, a citrus planter with a passion for the sea who had acquired the island in 1943 in order to build a summer home for his wife, Carrie. Nor could we then imagine that within eight years the Bowman family?s appreciation and support for the natural sciences would transform this remote vacation retreat into a permanent laboratory? one that has since hosted more than 70 scientists from 40 institutions, en- abling hundreds of scholarly studies of the surrounding reefs to be conducted. Having Carrie Bow Island available as a convenient base, we decided to center our examination of mangroves on the nearby Twin Cays, a largely untouched mangrove range covering more than a square kilometer of a shallow lagoon. More than 20 other researchers from the Smithsonian Institution?s National Museum of Natural History (and at least as many colleagues from collaborating 96 SCIENTIFIC AMERICAN March 1996 CARRIE BOW ISLAND (foreground) and Twin Cays (center) have served the au- thors as a permanent base and natural laboratory. Straight, dashed lines on the bot tom of the lagoon mark scars in the sea-grass bed where oil-exploration crews used explosives to make seismic surveys during the 1960s. BELIZE?S BARRIER REEF is separated from the coast by a wide, shallow lagoon. Mainland mangrove communities (left) endure a permanent lateral gradient in the saltiness of ambi- ent waters, where freshwater (blue in band) gives way to salty conditions (red). Mangroves situated o?shore (right) more often cope with erratic ?uctuations in salinity. ROBERTO OSTI LAGOONCONTINENT RAIN FOREST MAINLAND MANGROVES CORAL REEF OCEAN OCEANIC MANGROVES SALINITY REGIME JIMMY SMITH Islands from the Sky Copyright 1996 Scientific American, Inc. institutions in the Americas, Europe and Australia) also conduct regular research on the mangrove communities there. A Natural Landscaping The mangroves of Twin Cays belong tribution of such scattered mangrove islands among the patches of reef with- in the wide lagoon suggested to us that the ?rst trees at Twin Cays may have settled on isolated coral clusters. But work by our geologist colleague Ian G. Macintyre disproved this surmise. Sev- eral ?vibracores? (geological samples obtained by pushing a vibrating pipe into the unconsolidated sediment bot- tom) indicated that the mangroves at Twin Cays did not begin growing on cor- al. Rather the community established itself some 7,000 years ago on what was then just elevated ground. This man- grove swamp has since built a founda- tion of seven meters of peaty soil as it reacted to rising sea level. The topography of Twin Cays re?ects several thousand years of natural histo- ry and provides a testament to the pow- er of the countless storms and hurri- canes that have bu?eted this tiny for- est. For instance, clear evidence of at least one dramatic event in the past re- mains in the shallow channel that bi- sects the island and then splits, with one branch that has no outlet. At the bends in the dead-end extension lie deep cuts that have not yet ?lled with peat or sediment. These submerged ex- cavations indicate that strong currents must have ?owed freely through the passage before an unrecorded tempest deposited enough sediment to dam one end of the channel. The periphery of Twin Cays and its canals is bordered by tall red mangroves (Rhizophora mangle) that extend stilt- like roots into the deeper water, beyond the peat bank that supports the trees. Toward the interior, ?rst black man- grove (Avicennia germinans) and then white mangrove (Laguncularia racemo- sa) mark zones of shallow ?oodwater and extended mud?ats that develop as the tide moves in and out. Because evaporation under the intense sun can rapidly remove much of the standing water, the brine that remains in pools often contains a high concentration of salt. Karen L. McKee of Louisiana State University has found that hypersaline conditions in the upper reaches of the intertidal zone favor black mangrove seedlings because that species has the greatest tolerance for salt. White man- grove seedlings cannot survive the sa- linity and the periodic ?ooding that sweeps this region, and hence these trees are restricted to higher ground. Red mangrove dominates the lower reaches of the intertidal zone not only because it stands on stilt roots but also because its seedlings can better survive the rigors of the fringing environment (hardships that include a dearth of nu- trients and an abundance of possible predators). The interior of Twin Cays is lined with numerous shallow ponds and mud?ats. Some of these areas are now without growing trees; some places contain erod- ed stumps of large trees that must have towered there in the past. Other ?ats are covered by dwarf forms of red man- grove. These tiny trees are barely one meter tall, yet our studies indicate that they may be several decades old. Initial ly we assumed that the physiological stresses associated with the increased salinity and high temperature of the mud?ats accounted for the slow growth of these bonsai-like mangrove trees. But SCIENTIFIC AMERICAN March 1996 97 SUPRATIDAL RESIDENTS of a mangrove swamp include a variety of plants, arthro- pods, snails and insects, and it is no surprise that the marbled godwit (bird shown in drawing) has little trouble ?nding food. MOLLY KELLY RYAN Smithsonian Institution SANDY CANUPP Copyright 1996 Scientific American, Inc. by direct experimentation, one of us (Feller) proved that this stunted growth on Twin Cays and similar Belizean man- grove islands resulted from the lack of a single critical nutrient, phosphorus. Life from Top to Bottom Naturalists have traditionally placed eral transition of mainland mangrove forests, from the near-oceanic realm of the coast, through the estuarine envi- ronment of river mouths, and upstream into regions of freshwater?the domain of the rain forest. Such horizontal vari- ation is not particularly pronounced on Twin Cays. But there is on the island a well-developed vertical strati?cation that encompasses the forest canopy, the intertidal region and a ree?ike zone below even the slackest water. A sub- stantial part of our research has sought to examine the ?ora and fauna of these three distinctive environments. Living within the upper forest levels at Twin Cays are countless insects, liz- ards, snakes and birds. Although the insects are the most abundant group, the ferocity of the sun and lack of fresh- water create a harsh environment for them. Only a few types are active during the day. Most insect species avoid the sun?s rays by feeding at night or by liv- ing entirely within plants. Consequent- ly, the traditional methods for collect- ing insects?trapping, baiting, or fog- ging vegetation with pesticides?yield few specimens. But by dissecting plant parts and by collecting larvae and rear- ing them, we have found that the man- grove insect fauna is much more di- verse and ecologically important than previously suspected. For example, the live branches of red mangrove host several species of spe- cialized wood-boring moths and bee- tles. Larval stages of these insects feed internally within twigs, creating hollow cylinders of deadwood. After these pri- mary excavators emerge, some 70 other species of ants, spiders, mites, moths, roaches, termites and scorpions use the hollowed twigs for food and as sites in which to hunt, nest and take refuge from the burning sun. As diverse and interesting as they are, the animal communities suspended above the high watermark are in many ways similar to those found in other tropical woodlands. But the deeper for- est environments of tangled red man- grove stilt roots, black mangrove pneu- matophores, peat banks and mud?ats host inhabitants that are unique to man- grove swamps. Although the normal tidal range at Twin Cays is only about 20 centimeters, these mangrove forests have distinctive intertidal communities occupying the dank stratum between the high and low tide levels. Aerial roots are typical- ly covered with a combination of red algae that is especially adapted to re- taining water when the tide withdraws. Such hard surfaces also support barna- cles, oysters and crabs. A rather unusu- al inhabitant of the intertidal zone is a small ?sh called the mangrove rivulus (Rivulus marmoratus). William P. Davis of the Environmental Research Labora- tory of the Environmental Protection Agency and D. Scott Taylor of the Mos- quito Control District in Brevard Coun- ty, Florida, along with several of their colleagues, found that Twin Cays har- bors this hermaphroditic species?one of nature?s rare examples of a verte- brate that can clone itself. By far the richest and most densely populated habitat in the mangrove swamp surrounds the subtidal area of the red mangrove stilt roots. Successful colonizers of this space include various species of algae, sponges and anemo- nes. These organisms form biological coatings that cover the stilt roots and o?er food and refuge to a variety of fau na, such as mangrove oysters and crabs. Interestingly, our experiments have demonstrated that the roots do not es- pecially attract the ?fouling? organisms. After a week of exposure to these wa- ters, any nontoxic material?di?erent woods, plastic or glass?becomes simi- larly covered, ?rst with a mucous, mi- crobial coating and then by a variety of algae and invertebrates. Mangrove roots seem to bene?t from this process: Aaron M. Ellison of Mount Holyoke College and Elizabeth J. Farnsworth of Harvard University have shown that the fouling community protects the trees, at least partially, from the attack of root-boring animals. The sedimentary bottom of the sub- tidal swamp is covered with thick stands of sea grass, particularly in well-sunlit channels. In some places on the bottom, algae and jelly?sh thrive. The sediment consists of a mixture of sand, mud and detritus that is constantly stirred by the moving water and by the actions of various organisms. Such large bottom feeders as manatees often plow the channel, as do speeding motorboats. Less obvious but much more important, the sediment is continuously being turned over by burrowing animals such as polychaete worms and crustaceans. These creatures act much as earthworms and moles do on land. Peter Dworschak and J?rg Ott of the University of Vien- na have shown that some crustaceans can dig and maintain complex burrows of branching tunnels that extend near- 98 SCIENTIFIC AMERICAN March 1996 INTERTIDAL MANGROVE stilt roots are ubiquitously coated by a mixture of al- gal species called bostrychietum. Such surfaces also host many invertebrates such as the mangrove oyster (Isogno- mon) and mangrove-tree crab (Aratus). ILKA C. FELLER Smithsonian Institution CHIP CLARK Smithsonian Institution Copyright 1996 Scientific American, Inc. ly two meters into the muddy bottom. Examinations of algae, aquatic inver- tebrates and insects on Twin Cays have revealed an astonishing number of new species. Even for relatively well studied groups, such as crustaceans, some 10 percent of the species found there have proved to be novel. We estimate that perhaps as many as 20 to 30 percent of the microbes, algae, sponges and worms living on Twin Cays may also be among as yet undiscovered species. Biodiversity at Risk The richness of life contained within raises immediate concern for the risk to biodiversity that develops as such delicate environments are lost to hu- man hands. After mangrove forests are cut, it may be di?cult or even impossi- ble for them to recover because irre- versible changes in the fundamental structure of the ecosystem ensue once the trees are destroyed. We were able to observe such unfor- tunate consequences on a black man- grove plot that was illegally clear-cut by ?shermen on the western side of Twin Cays. The remaining barren tidal ?at was rapidly overrun by saltwort (a small shrub that can tolerate high salin- ity), reducing the space available for new black mangrove trees, which repro- duce more slowly. Where the natural red mangrove fringe was disturbed, cur- rents driven by wind and tides rapidly eroded the peat-rich soil and left a bot- tom surface on which the seedling prop- agules had di?culty anchoring. Some of our ?eld experiments show another impediment that prevents new mangrove trees from establishing them- selves after a forest is downed. We found that mangrove seedlings take hold and grow much better in the shade than in the open, indicating that the natural repair of damaged swamps may prove too slow to keep up with the erosion of denuded land. Such observations demonstrate that mangrove forests indeed constitute ex- tremely delicate natural systems. Al- though the government of Belize has enacted laws protecting its mangrove species, these trees have nonetheless proved vulnerable because they are sit- uated so directly in the path of commer cial development. As on other coasts around the world, people often cut trees and ?ll low-lying areas to construct housing and industrial facilities. Because mangrove swamps destroyed in this way would have otherwise sup- ported countless varieties of animals, including juvenile deepwater ?sh, it seems clear that these losses will in- creasingly threaten the natural wealth of the ocean, both near and far from shore. But mounting concern about en- vironmental degradation within the world?s developing nations has brought renewed scienti?c attention to man- grove forests. Although much work re- mains to be done, the research conduct ed at Twin Cays is slowly but steadily building a body of critical long-term ob- servations. This knowledge should aid future attempts to predict the fate of the earth?s fragile tropical shorelines and to foster legislation that might ulti- mately serve to protect the fascinating mangrove communities found there. SCIENTIFIC AMERICAN March 1996 99 The Authors KLAUS R?TZLER and ILKA C. FELLER study mangroves together, but from comple- mentary points of view. R?tzler is a marine biologist, Feller a forest ecologist. R?tzler be gan his research in submarine caves of the Croatian Adriatic. In 1963 he earned a Ph.D. at the University of Vienna and in 1965 moved to the Smithsonian Institution?s National Museum of Natural History, where he now directs the museum?s research program on Caribbean coral reef ecosystems. Feller earned a B.A. as a botanist and scienti?c illustra- tor. In the 1980s she worked at the Smithsonian?s natural history museum. In 1993, after completing a Ph.D. at Georgetown University, she shifted to the Smithsonian Environ- mental Research Center in Edgewater, Md., where she is currently a postdoctoral fellow. Further Reading THE ECOLOGY OF MANGROVES. A. E. Lugo and S. C. Snedaker in Annual Review of Ecology and Systematics, Vol. 5, pages 39?64; 1974. MANGROVE SWAMP COMMUNITIES. K. R?tzler and I. C. Feller in Oceanus (Woods Hole Oceanographic Institution), Vol. 30, No. 4, pages 16?24; Winter 1987/1988. THE BOTANY OF MANGROVES. P. B. Tomlinson. Cambridge University Press, 1995. SUBTIDAL COMMUNITIES include sabellid worms living among the great quantities of decaying leaf litter (left) and the Caribbean ?re- sponge (Tedania ignis), a beautiful but toxic species (above) that can cause severe skin inflammation. KLAUS R?TZLER MOLLY KELLY RYAN Smithsonian Institution Copyright 1996 Scientific American, Inc.