Drift Seeds And Drift Fruits
Seeds That Ride The Ocean Currents
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|I magine yourself floating helplessly on the open sea, thousands of miles from land, your destination at the mercy of the wind and currents. Perhaps eventually you may drift ashore on the coral sand beaches of a remote tropical island or distant continent. This is precisely what happens to countless thousands of tropical drift seeds and fruits, a remarkable flotilla of flowering plants that travel the oceans of the world. The following map shows the path of some drift seeds and fruits in the world’s oceans:
S eeds provide the vital genetic link and primary dispersal agent between successive generations of plants. They are produced and packaged in botanical structures called fruits, and come in an endless variety of shapes and sizes. Tropical drift seeds and fruits are especially remarkable because they can survive months or even years at sea. They are very buoyant, with thick protective shells which are impervious to salt water. In some drift fruits, such as the coconut, the seed embryo and fleshy white “meat” (endosperm) is enclosed within a hard, bony layer (endocarp) surrounded by a thick fibrous husk. Other drift seeds have thick woody seed coats and internal air cavities which produce their buoyancy. During their long voyages they often cross entire oceans, perhaps colonizing the shores of a coral atoll or isolated volcanic island. Sea dispersal is a hit-or-miss method; after a long, perilous journey, other dangers await the vulnerable seedlings. They may perish in the parched sand without adequate moisture or be quickly devoured by ravenous land crabs. Drift seeds carried by the Gulf Stream from the Caribbean to beaches of northern Europe may find themselves in another precarious situation–aliens in a hostile climate much too cold for them to survive.
T he tropical islands of Indonesia, Polynesia and the Caribbean probably have the greatest variety of drift seeds. They are especially abundant along wave-swept beaches following the hurricane season, and may be carried inland by tidal waters. The Cayman Islands and Yucatan Peninsula lie directly in the path of the Equatorial Current, bringing thousands of unique drift disseminules from the Amazon and Orinoco deltas and across the Atlantic from river deltas of tropical west Africa. In the Pacific region drift seeds may be deposited well above the inhospitable beach zone by enormous tidal waves known as tsunamis. The tsunami emanates from an earthquake or volcano epicenter and moves at great speed across the Pacific Ocean.
Legend: A. Mango ( Mangifera indica ), B. beach bean ( Canavallia maritima ), C. coin plant (probably Dalbergia monetaria ), D. hog plum ( Spondias mombin ), E. West Indian locust ( Hymenaea courbaril ), F. tropical almond ( Terminalia catappa ), G. tamanu ( Calophyllum inophyllum ), H. manchineel tree ( Hippomane mancinella ), I. seaside hibiscus ( Thespesia populnea ), J. nothing nut ( Cassine xylocarpa ), K. sugar apple ( Annona squamosa ), L. sandbox tree ( Hura crepitans ), M. sea coconut ( Manicaria saccifera ), N. mammee apple ( Mammea americana ), O. oak acorn ( Quercus sp.), P. grenade pod ( Sacoglottis amazonica ), Q. Asian swamp lily (probably Crinum asiaticum ), R. beach morning-glory ( Ipomoea pes-caprae ), S. sea heart ( Entada gigas ), T. pod in the Sterculiaceae (possibly Sterculia sp.), U. red mangrove ( Rhizophora mangle ), V. sea bean ( Mucuna urens ), W. gray nickernut ( Caesalpinia bonduc ), X. yellow nickernut (probably Caesalpinia ciliata or C. major ), Y. dog almond ( Andira inermis ), Z. coconut endocarp ( Cocos nucifera ), AA. calabash ( Crescentia cujete ), and AB. box fruit ( Barringtonia asiatica ).
|Edible Fruits That Drift In Ocean currents See Article About The Mango |
See Article About The Sugar Apple
|“Nothing nut” ( Cassine xylocarpa ) on the leeward shore of St. John in the U.S. Virgin Islands. The common name is derived from the Creole name of “not’ing nut,” so called because no useful purpose is known for the “nuts” of this endemic shrub. This shrub (or small tree) is also called “marble tree” because of the hard, woody, seed-bearing endocarps. Cassine (syn. Eleodendron ) is a member of the staff tree family (Celastraceae). The genus includes the Asian false olive ( C. orientalis ), the African C. capensis , the Australian C. australis , the Bermudian C. laneana , and the Cuban C. attenuata .|
Charles Darwin & Ocean Dispersal Of Seeds
Plant dispersal by ocean currents has fascinated many famous explorers, including Charles Darwin and Thor Heyerdahl. Sea currents have also been studied by the U.S. Coast and Geodetic Survey using stoppered bottles containing a numbered postcard. When a bottle is found on a beach the finder fills out the card and drops it in the mail. It takes about one year for a drift bottle to float from Yucatan to Ireland. A bottle launched near Caracas, Venezuela reached the Florida Keys four months later, traveling at an average speed of 16 statute miles per day. It is estimated that tropical seeds found on European shores probably have been adrift for a year or longer.
During his famous voyage around the world on the H.M.S. Beagle, Charles Darwin championed the idea of drift seeds and fruits colonizing distant islands, particularly isolated volcanic islands which have never been connected to the mainland. Darwin studied the role ocean currents played in the flora of Cocos Keeling Islands in the Indian Ocean, and concluded that most of the endemic vascular flora was derived from drift seeds and fruits. His original article published in 1836 was reprinted in chapter 20 of Journal of Researches , D. Appleton & Company, New York, 1883.
After he returned to England, Darwin conducted flotation experiments with cultivated plants. In the Journal of the Proceedings of the Linnaean Society (Vol. 1, 1857) Darwin stated: “I soon became aware that most seeds, in accordance with the common experience of gardeners, sink in water; at least I have found this to be the case, after a few days, with the 51 kinds of seeds which I have myself tried; so that such seeds could not possibly be transported by sea-currents beyond a very short distance.” Darwin also mentioned rafting as a dispersal mechanism for seeds that generally don’t float well in sea water. In addition, he stated that seeds contained within pods, capsules and the heads of Asteraceae may be carried by ocean currents and washed ashore on distant beaches. In his Origin of Species , 1859 (Chapter 12 Geographical Distribution: Means of Dispersal), Darwin summarized his experimental data on seed dispersal in salt water, and expressed a higher confidence in dried seeds: “Therefore it would perhaps be safer to assume that the seeds of about 10/100 plants of a flora, after having been dried, could be floated across a space of sea 900 miles in width, and would then germinate.”
Of all the 250,000 species of seed plants on earth, only about 250 species (0.1 percent) are commonly collected as drift disseminules on tropical beaches; and only about half of these are known to produce seeds that can float in seawater for more than a month and still be viable. This relatively small number of drift seed species does not include seed plants which are dispersed on vegetation rafts, drift garbage from ships, or true marine seagrasses which live totally submersed in seawater. Although the total number of drift seed species with long viability periods may be relatively small, they nonetheless form a floral flotilla comprising countless thousands of individuals riding the ocean currents of the world.
The Hawaiian archipelago has been isolated from continental land masses during the past 30 million years, and yet the 1,000 species of indigenous Hawaiian angiosperms are believed to stem from natural introduction by long-distance dispersal of 280 ancestral plant colonists (Wagner, Herbst and Sohmer, 1990). According to Sherwin Carlquist ( Hawaii: A Natural History , 1980), only about 14 percent of the original flowering plant immigrants to the Hawaiian Islands are clearly adapted to oceanic drift. If dispersal by birds and air currents are ruled out, it appears that seeds were carried thousands of miles to these islands, possibly by rafting or within protective capsules and pods. For example, California tarweeds are not included with tropical drift seeds, and yet an ancestral tarweed traveled at least 3,000 miles to the Hawaiian Islands where it gave rise to a remarkable group of endemics known as the “Silver Sword Alliance.” The small seeds from ancestral members of the lobelia family (Campanulaceae) also reached these islands giving rise to an unusual group of Hawaiian lobelioids. One of these is the pachycaul Brighamia insignis that grows on steep sea cliffs on the island of Kauai.
A n interesting coral tree endemic to dry, leeward slopes of all the main Hawaiian islands is called wiliwili ( E. sandwicensis ). This Hawaiian endemic belongs to a group of closely related passerine species in the section Erythraster , including E. tahitensis , endemic to Tahiti; E. variegata , a widespread species in tropical Asia and the South Pacific; and E. velutina , another widespread species in northern South America, the West Indies and the Galapagos Islands. Although the seeds of wiliwili sink in water, it may have originated from an ancestral species with buoyant seeds that reached these islands many thousands of years ago. In fact, a related tropical Asian species ( E. variegata ), which is commonly planted as a street tree in Hawaii, has seeds that float in water. The seeds of this species sometimes show up along Hawaiian beaches and tidal waters; however, they are usually of local origin. Trees of E. variegata are fairly easy to identify because the pods are longer than most cultivated coral trees, often up to 12 inches or more in length.
A ccording to Sherwin Carlquist (1980), the seeds of wiliwili ( Erythrina sandwicensis ) have gradually lost their ability to float in seawater. Although the reasons are not identical, Carlquist compares this with the loss of flight in certain insects and birds. “If a plant shifts its ecological preference, it will tend to lose contact with the agent responsible for its dispersal.”
|Seeds of the Asian coral tree ( Erythrina variegata ) are buoyant in seawater and may have drifted to distant shores of the tropical Pacific. In fact, this species (or its progenitor) may have given rise to several species of endemic coral trees in the tropical Pacific region.|
The Hawaiian Silver Sword
T he Hawaiian islands are thousands of miles from the nearest continent or island mass. Even though they include some of the most isolated islands on earth, they contain numerous endemic species of plants, many of which evolved from ancestral seeds that reached the islands by drifting. Some striking members of the sunflower family evolved on the Hawaiian Islands from an ancestral California tarweed ( Hemizonia ) that colonized these isolated Pacific islands millions of years ago. This group of plants, called the Silver Sword Alliance, includes three genera and about 30 endemic species, an excellent example of adaptive radiation. One of the most amazing of all these Hawaiian endemics is the silver sword ( Argyroxiphium sandwicense ssp. macrocephalum ) that only grows in the cinders of Haleakala Crater on the island of Maui. The rosettes of sword-shaped leaves are covered with silvery hairs that reflect light and heat and provide insulation against the intense solar radiation and extreme aridity of this 10,000 foot (3,000 m) volcanic mountain.
|A silver sword ( Argyroxiphium sandwicense ssp. macrocephalum ) in full bloom inside the lunar-like crater of Haleakala on the island of Maui. This remarkable plant and its relatives are descendents of an ancestral California tarweed ( Hemizonia ) that reached these islands millions of years ago, presumably by drifting.|
S ome of the most ubiquitous drift seeds that readily germinate on tropical beaches are the gray and yellow nickernuts, Caesalpinia bonduc, C. ciliata , C. major. All are climbing, sprawling beach shrubs armed with vicious, recurved thorns and prickly pods bearing gray or yellow seeds. The smooth, marble-like seeds are commonly strung into necklaces and bracelets, often mixed with other colorful seeds. In Guayaquil, Ecuador, drilled nickernuts are sold by street vendors as amulets to ward off evil spirits. On some Caribbean islands nickernuts are used in a strategy board game called “Island Waurie.” Two players sit on opposite sides of a hardwood board with six depressions (wells) on each side, each well with four nuts. Through a series of carefully planned moves, players attempt to empty all six of their wells before their opponent can do so. Legend has it that Island Waurie was originally introduced to the Cayman Islands by Blackbeard the Pirate on one of his voyages from South Africa. The game became popular with Cayman Islanders and was enjoyed by Ernest Hemingway whenever he visited the islands. Know in Africa as “mancala,” the games were played for thousands of years in Egypt, where boards have been found carved into the stone of the pyramid of Cheops and the temples at Luxor and Karnak.
P robably the best known of all plant drifters is the coconut (Cocos nucifera). In fact, it is hard to imagine a tropical beach without coconut palms. The origin of the coconut and whether it floated to islands of the tropical Pacific has been debated for more than a century. T.H. Everett (Encyclopedia of Horticulture, Vol. 3, 1981) flatly states: “. it has never been found truly wild, every coconut palm is planted by man or derived from such a planting.” According to the world authority on palms, E.J.H. Corner (The Natural History of Palms, 1966), “There is no island or shore where its presence is not due directly or indirectly to its having been planted by man.” Probably under most situations, coconut seedlings require watering and other attention from humans; however, J.V. Dennis and C.R. Gunn (Economic Botany 25, 1971) cite several localities where coconuts appear to have seeded themselves naturally, including cays in British Honduras (Belize), rocky islets in the Fiji group, the east coast of Trinidad, Cocos-Keeling Atoll in the Indian Ocean, and Krakatau and adjacent islets following the catastrophic eruption of 1883. In addition, I have photographed coconut palms sprouting on Tetiaroa Atoll in French Polynesia. Whether these would survive the ravaging effects of land crabs and intense sunlight and grow into mature palms is hard to say, but there appeared to be palms of different ages along the beaches. I have also observed self-seeded coconut palms growing among mangrove thickets on cays off the coast of Belize.
|The end of a long journey: Box fruits (Barringtonia asiatica) and a sprouting coconut (Cocos nucifera) on the coral sand beach of Tetiaroa Atoll, French Polynesia.|
H ugh C. Harries (Botanical Review Vol. 44, 1978) argues convincingly that coconuts have naturally established themselves on beaches of the tropical Pacific. According to Harries, there are many varieties of coconuts, but they all belong to either of two major types known as niu kafa and niu vai. The niu kafa types have an elongate, angular fruit, up to 6 inches in diameter, with a small egg-shaped nut surrounded by an unusually thick husk. Niu vai types have a larger more spherical fruit, up to 10 inches in diameter, with a large, spherical nut inside a thin husk. The niu kafa type represents the ancestral, naturally-evolved, wild-type coconut, disseminated by floating. The niu vai type was derived by domestic selection for increased endosperm (“meat” and “milk”) and is widely dispersed and cultivated by humans. Both types of fruit can float, but the thicker, angular husk adapts the niu kafa type particularly well to remote atoll conditions where it can be found today. The presence of “undesirable” wild-type coconuts growing in mangrove swamps is clear evidence that they were self-sown and not planted by farmers. In two fascinating papers by Harries and his colleagues, W.S. Gruezo and R. Buckley (Biotropica Vol. 16, 1984), wild-type, self-sown coconuts have been documented in the Philippines and as far away as Australia. In addition, throughout the humid tropics intermediate types have arisen by hybridization with the commonly cultivated niu vai coconuts.
|Angular, small-seeded coconuts on Ambergris Caye, off the coast of Belize. These coconuts resemble the wild-type niu kafa coconuts discussed by Harries and his colleagues. They were probably introduced to the Caribbean region of Central America by Portuguese traders.|
T he argument for a New World origin of the coconut centers around the presence of coconut palms on Cocos Island off the coast of Costa Rica and parts of the Pacific Coast at the time of Columbus. One of the proponents of the New World origin is Thor Heyerdahl, citing his own experience on the Kon Tiki and legends handed down by early Polynesian voyagers. In his book, Sea Routes to Polynesia (1968), Heyerdahl expresses great confidence in Polynesian sailors who crossed vast stretches of the Pacific Ocean carrying staple foods from the New World, such as sweet potato, plantain and the coconut.
A major factor in Hyerdahl’s argument comes from the distribution of the sweet potato (Ipomoea batatas). Archaeological evidence shows that sweet potatoes were cultivated in South America by 2400 B.C. and fossilized sweet potatoes from the Andes have been dated at 8,000 to 10,000 years old. Although the sweet potato is clearly native to South America, it was cultivated in Polynesia as early as 1200 A.D. In fact, the sweet potato had already become the principle food of the Maoris in New Zealand by the time of Captain Cook’s historic voyage to that part of the world in 1769. It is interesting to note that the sweet potato is known as “kumar” or “kumal” in the Lima region of coastal Peru, and it is called “kumara” by the Maoris of New Zealand. Heyerdahl (1968) postulated that sweet potatoes were carried across the Pacific by Peruvian Indians before Europeans began to sail the world’s oceans. He tested his hypothesis in 1947 by sailing a balsa wood raft, the Kon-Tiki, fashioned after the reed rafts of the Oru Indians living on Lake Titicaca in Bolivia. Although Heyerdahl’s hypothesis about the transoceanic exchange of sweet potatoes by skillful pre-Columbian sailors remains an enigma (at least to some skeptics), his New World origin for the coconut has been rejected by most botanists.
Muñoz-Rodriguez et al. 2018. “Reconciling Conflicting Phylogenies in the Origin of Sweet Potato and Dispersal to Polynesia” Current Biology 28: 1�11 (April 23, 2018). https://doi.org/10.1016/j.cub.2018.03.020
A ccording to J.V. Dennis and C.R. Gunn (Economic Botany 25, 1971), the coconut is indigenous to the Indo-Malaysian region. It spread by sea currents to many Pacific Island groups with adequate rainfall and moderate temperatures where the seedlings became established along beaches. Coconuts prefer the well-drained coral sand beaches of tropical islands and atolls, and are poorly established along shores of continents. In a recent article by F. Rosengarten, Jr. (Principes 30, 1986), naturally dispersed coconuts can withstand occasional brief salt water flooding. Developing coconut palms obtain fresh water and mineral nutrients from a lens (soil layer) of fresh water (derived from island rainfall) which literally floats above the denser salt water beneath the beach sand.
A ccording to Dennis and Gunn, 3,000 miles seems to be the average maximum distance that a coconut will remain afloat and still remain viable. These limitations greatly diminish the chance of a coconut reaching the New World, let alone sprouting on a continental shore. Most authorities agree that the coconut was introduced to the New World by Portuguese and Spanish traders. Although the coconut is the best known drift fruit it is also one of the world’s most valuable trees, providing thatching, food, drink, coir, copra, oil, and hard endocarps which are fashioned into all sorts of decorative and useful articles.
Coconut on a beach in Belize.
P erhaps the best physical evidence for an Indo-Pacific origin of the coconut comes from New Zealand and India, where fossil specimens of a species of Cocos have been dated to the late Tertiary, at least two million years ago. According to Hugh Harries (Principes Vol. 36, 1992), fossil coconuts of an extinct Miocene palm (Cocos zeylandica) have been found in North Island, New Zealand. Fossil evidence from such far-flung areas suggests that the coconut had ample time to disperse naturally in the Indo-Pacific, before humans came along to speed up the process.
B ut of all the arguments for a transoceanic dispersal of coconuts, perhaps the most interesting comes from the widespread distribution of the coconut crab (Birgus latro). According to Harries (Principes Vol. 27, 1983), this large land crab could not have achieved its present widespread inter-island distribution with only a 30 day aquatic larval stage unless they rafted to distant islands. Harries postulates that the tiny post-larval (glaucothoe) stage was spent in the moist husk of floating coconuts. Ancestors of today’s coconut crabs may have literally migrated on floating coconuts to remote islands and atolls of the South Pacific.
|The widespread distribution of the coconut crab (Birgus latro) coincides with coconut palms throughout the tropical Pacific region. The post-larval stage of these crabs may have actually rafted on coconuts from island to island.|
The Galapagos Islands
T he Galapagos Islands, always a provocative place for students of natural history, offer a wide variety of examples of drift dissemination, including the independent transport of seeds and fruits floating in the ocean and the transport of seeds and animals on vegetation rafts from the mainland. Several species of mangroves grow on these islands, including the ubiquitous red mangrove ( Rhizophora mangle ) with its conspicuous prop or stilt roots descending from its limbs. The cigar-shaped disseminule, known as a “sea pencil,” is unusual because it is a germinated seedling and not a seed or fruit. The seedling, with its long, pendant taproot (mostly hypocotyl), drops from the parent plant, where it may be automatically planted in the mud of shallow water or washed away to a distant shore. Beach vines, such as beach morning glory ( Ipomoea pes-caprae ), gray nickernut ( Caesalpinia bonduc ) and beach bean ( Canavalia maritima ), occur on several of the islands. Their durable seeds ride the currents of the world’s oceans, resulting in enormous pantropic distributions.
|Drift seeds and fruits from the shores of Floreana Island in the Galapagos Archipelago. A. Nickernut ( Caesalpinia bonduc ), B. Manchineel ( Hippomane mancinella ), C. Beach Morning Glory ( Ipomoea pes-caprae ), D. Sea Purse ( Dioclea sp.), E. Sea Bean ( Mucuna sp.) and F. Prickly Palm ( Acrocomia sp.). D, E, and F are mainland species that probably drifted to this island.|
I an Thornton, a zoologist at La Trobe University in Melbourne, Australia, has calculated that, based on the speed of the currents and winds of the area, it would take about two weeks for a floating log or vegetation raft to reach the Galapagos Islands from mainland Ecuador. Considering that the archipelago is over 3 million years old, the drift seed scenario offers a plausible explanation for how some plants made the 600-mile (965-km) journey.
S uccessful dissemination by drifting would not have to occur often for it to have a profound effect on the ecology of the islands. Taking into account all methods of dispersal, including transport by wind, birds, and drifting on the ocean surface, Duncan Porter, a botanist at Virginia Polytechnic Institute and State University, estimates that 378 original introductions could account for the 522 indigenous plant species known to grow on the islands. Of these natural introductions, 59% were a result of transport by birds, 32% by wind transport, and 9% by drifting on the ocean surface. If only one species successfully drifted to the islands and germinated there every 50,000 years, this would still account for the introduction of roughly 10 percent of the islands’s flora. According to D.M. Porter ( Nature Vol. 264, 1976), for 378 introductions to account for the present flora, it would require only one species to arrive and become established every eight to ten thousand years.
A ncestors of present-day Galapagos reptiles, such as the remarkable marine iguanas, may have also drifted to the islands. In the swift current of Ecuador’s Guayas River, trees, branches, and large mats of vegetation broken loose from riverbeds are commonly carried out to sea. Reptiles now on the Galapagos may have ridden such rafts from the mainland many thousands of years ago. For example, in 1827 a large boa constrictor reportedly arrived on the island of St. Vincent in the West Indies, wrapped around the trunk of a floating tree.
|A marine iguana ( Amblyrhynchus cristatus ) on the rocky shoreline of Hood Island in the Galapagos Archipelago. These unusual sea-dwelling iguanas are descendants of an ancestral mainland species that rafted to these islands thousands of years ago. In the distance is the infamous M/N Bucanero.|
The Pantropical Mangroves
M angroves include several dozen species of trees and shrubs that grow along tidal swamplands throughout tropical regions of the world. Since their roots are emersed in water-logged silt and mud, often deficient in oxygen, the buttressed trunks and aerial roots of mangroves are typically dotted with numerous lenticels–small pores which provide gas exchange between the roots and the atmosphere. Lenticels are especially conspicuous on the prop roots of the ubiquitous red mangrove ( Rhizophora mangle ) and on the deeply-fluted trunk of the tea mangrove ( Pelliciera rhizophorae ), an interesting swamp tree of the tea family (Theaceae) along the Pacific coast of Costa Rica. The lateral roots of some mangroves produce upright, slender outgrowths called pneumatophores which extend above the mud and water like snorkel tubes. The porous pneumatophores are covered with lenticels and provide additional aeration for the root systems. The black mangrove ( Avicennia germinans ), of Central America and the Caribbean region, produces literally hundreds of pencil-like pneumatophores around its base.
M angroves survive in seawater with a salinity that would be lethal to most trees and shrubs. Like celery or carrot sticks placed in saltwater, the roots of most plants rapidly lose water if they are suddenly emersed in seawater. Halophytes (salt-loving plants), such as mangroves, generally have a lower concentration of water molecules (lower water potential) in their root cells so they can take in water. They maintain lower water potentials in their roots by having higher internal salt concentrations than seawater and by losing water at the leaf surface. Since high internal salt concentrations can be lethal to plant cells, some species such as the black mangrove and white mangrove ( Laguncularia racemosa ), can excrete excess salt through special glands in their leaf blades and petioles. Red mangroves have root cell membranes which prevent the absorption of excess salt.
T he seeds of mangroves are especially remarkable because they commonly germinate within their fruit while still attached to the parent plant, a condition known as “viviparous seeds.” Having their embryonic root (hypocotyl) already elongated gives them a better chance of establishing themselves in soft mud during low tide. Called “sea pencils,” the cigar-shaped seedlings (disseminules) of red mangrove may have an elongate taproot up to 10 inches long when they drop from the parent tree. The unusual, top-shaped fruit of tea mangrove contains one of the largest seeds in the world (excluding palms). It floats with the elongate, embryonic root pointing downward, and readily becomes implanted in soft mud. Germinated seedlings and sprouted fruits of the black mangrove and white mangrove are also dispersed by ocean currents.
|Left: Red mangrove ( Rhizophora mangle ) with two viviparous (germinated) seedlings which have emerged from their fruits. The elongate embryonic axis called the hypocotyl develops into an extended taproot; Center: Onion-sized fruits of the tea mangrove ( Pelliciera rhizophorae ). The pointed beak encloses the embryonic root (hypocotyl). The fruit floats with the beak facing downward. When it becomes stranded in shallow water at low tide, the beak becomes implanted in the soft mud or silt, thus fascilitating the establishment of the seedling; Right: A sprouted fruit of black mangrove ( Avicennia germinans ) showing an elongated root.|
|Red mangrove ( Rhizophora mangle ) with a viviparous (germinated) seedling still attached to the fruit on the parent shrub. The seedling drops into the water where it is automatically planted in the soft mud or floats away.|
Polynesian Box Fruit
B eaches of French Polynesia are often littered with a buoyant drift fruit resembling a small coconut with flattened sides. It is called box fruit (Barringtonia asiatica) and is one of the most durable and widespread of all drifters, remaining buoyant for at least two years. In fact, they are used as fishing floats in Southeast Asia. This was one of the first tropical drifters to reach Krakatau after the catastrophic volcanic eruption of August 1883.
|Box fruits (Barringtonia asiatica) are widespread drift fruits in the tropical Pacific, remaining buoyant for more than two years. They are common in the turquoise-blue waters of French Polynesia.|
A n equally common drift fruit of the tropical Pacific is called “tamanu” (Calophyllum inophyllum) by the Polynesians. The smooth, gray fruits resemble ping-pong balls strewn along wave-swept beaches. This tree belongs to the garcinia family (Clusiaceae syn. Guttiferae). On Marlon Brando’s spectacular atoll of Tetiaroa, strings of tamanu balls on fishing line are used for decorative “lamp shades.” Another common drifter, called tropical almond (Terminalia catappa), resembles an oversized unshelled almond. It is one of the most distinctive trees of tropical beaches with tiered, pagodalike limbs and colorful red and yellow leaves reminiscent of a deciduous forest in autumn. Seeds of the Polynesian “tianina” or lantern tree (Hernandia nymphaeifolia) are produced in fleshy red or white “lanterns” which float like colorful boats in the clear blue water. The woody, seed-bearing endocarps are polished by native islanders and made into shiny brown leis and necklaces.
|The smooth, ping-pong ball fruits of tamanu ( Calophyllum inophyllum ) commonly drift ashore on beaches of French Polynesia. On the atoll of Tetiaroa they are strung on fishing line to make unusual lamp shades.|
|Flowers of tamanu ( Calophyllum inophyllum ). The stamens occur in five bundles. On the small East-Indonesian island of Alor, this pantropic tree is called “camplung.” Here the sticky seed within the dried pericarp is used for lighting. It burns with a clean flame and reportedly fends off mosquitoes. According to S. Facciola ( Cornucopia II , 1998) the ripe fruits and seeds are edible. According to C.R. Gunn and J.V. Dennis ( World Guide to Tropical Drift Seeds and Fruits , 1976), this is one of the first trees to colonize newly formed Islands in the Pacific region.|
The Polynesian Pandanus
A nother widespread Polynesian plant called screw pine ( Pandanus tectorius ) is also dispersed by ocean currents. The large multiple fruit (resembling a pineapple) is composed of buoyant, one-seeded sections called “keys.” The hard, woody keys are also polished and made into necklaces and leis.
|The multiple fruit of Pandanus tectorius , showing the individual one-seeded sections called “keys.” In addition to the edible seeds (one inside each key), the keys are polished and used for necklaces and leis. The keys are very buoyant and water-resistant, and remain viable for months. They are dispersed by ocean currents to shores of distant atolls and islands throughout the tropical Pacific.|
S ome of the most beautiful of all drift seeds are called “sea beans.” They come from large climbing vines (called lianas) throughout rain forests of the New and Old World tropics. The seeds are produced in large pods and resemble round, flattened beans with hard, woody seed coats. In species of Mucuna the pods are covered with whiskerlike, stinging hairs–presumably to discourage ravenous seed predators. The pods develop from clusters of greenish, bat-pollinated blossoms at the end of long, ropelike branches which hang from the forest canopy. Sea beans are also called “hamburger seeds” because they have two rounded halves enclosing a conspicuous central connection layer (hilum). In Mexico and Central America they are also called “ojo de buey” because of their uncanny resemblance to the eye of a steer. Another species of sea bean (M. argyrophylla) called “ojo de venado” (deer eyes) has a most remarkable use in Central America. According to the Flora of Guatemala by P.C. Standley (Fieldiana Vol. 24, 1946), “male” and “female” seeds from this rain forest liana are carried by natives to prevent hemorrhoids. The sex of the seed is determined by whether they sink or float in water. Those that sink in water are called “hembras” (female) and those that float are “macho” (male). The hemorrhoidal treatment requires the sufferer to carry a “male” and a “female” seed in their back pocket. Some species of sea beans are called sea purses (Dioclea) because they are shaped like a purse, including a circular hilum along the edge that superficially resembles a zipper.
|Velvety pods of the sea bean (Mucuna argyrophylla) hang from long, ropelike stems in the rain forests of Belize. The hard, black seeds are called “ojo de buey” (eye of the steer) and “ojo de venado” (eye of the deer) by local residents.|
The Sea Heart
P erhaps the most remarkable of all drift seeds resemble large wooden hearts and are called “sea hearts” (Entada gigas). The heart-shaped seeds are produced in huge bean pods up to six feet long, the longest of any legume. In the rain-soaked tropical forest near Golfito, Costa Rica, enormous sea heart lianas twine through the forest canopy like a gigantic botanical boa constrictor. The vine is known locally as “escalera de mono” or monkey ladder because it provides a maze of arboreal thoroughfares for New World monkeys. Torrential rains wash the seeds into streams and rivers where they reach the sea, and perhaps eventually the shores of a distant continent. Sea hearts are highly prized by beach combers and make beautiful pendants when polished. Sea hearts and a similar rectangular Old World species (E. phaseoloides) were commonly used in Norway and northern Europe for snuffboxes and lockets. The seeds were cut in half, the contents removed, and the woody seed coats hinged together.
S ea hearts have a long and colorful history in fact and fiction. Early naturalists thought the unusual seeds came from strange underwater plants whose origin was shrouded in mystery. In England sea hearts were carried as good luck charms by sailors embarking on a long ocean voyage. It was thought that if sea hearts could survive a long and perilous journey across the ocean, perhaps they could also protect their owner. Christopher Columbus was fascinated with objects that drifted ashore on beaches of the Azores, off the coast of Portugal. It is said that a sea heart provided inspiration to Christopher Columbus and led him to set forth in search of new lands to the west. In fact, the sea heart is called “fava de Colom,” or Columbus bean, by Portuguese residents of the Azores.
The Mary’s Bean
A nother drift seed called Mary’s bean (Merremia discoidesperma) was a special find to pious beachcombers. Named after the Virgin Mary, it is also called crucifixion bean because of a cross etched on one side. The distinctive seeds are produced in papery capsules on a climbing tropical vine. The cross is actually an impression where the seed was attached inside the capsule. Because of a thick, woody seed coat and internal air cavities, the seeds are very buoyant and may drift for months or even years at sea. Historically, the unique seeds have been used for good luck charms and to ward off evil spirits. A woman in labor was assured an easy delivery if she clenched a Mary’s bean in her hand. Seeds were handed down from mother to daughter as treasured keepsakes. To this day Mary’s beans are occasionally sold by street vendors in Costa Rica.
|Some drift seeds and fruits on the Caribbean shores of Costa Rica. A. Starnut Palm ( Astrocaryum sp.), B. Mary’s Bean ( Merremia discoidesperma ), C. Oxyrhynchus trinervias , D. Crabwood ( Carapa guianensis ), E. Prioria copaifera , F. Sea Bean ( Mucuna sp.), G. Sea Coconut ( Manicaria saccifera ), and H. Calatola costaricensis .|
I n its native habitat, the Mary’s bean is known from only a few locations in Mexico and Central America. It is a lovely vine of the Morning Glory Family (Convolvulaceae) with beautiful yellow, funnel-shaped blossoms. As drift seeds, the Mary’s bean is known from the Marshall Islands to beaches of Norway, a total distance of more than 15,000 miles (24,000 km). According to Charles R. Gunn (Economic Botany Vol. 31, 1977), this constitutes the widest drift range of any seed or fruit which has been documented. Other pantropical drift seeds may drift as far or farther, but their precise point of origin cannot be determined with certainty.
Large Neotropical Drift Fruits
W ith the exception of introduced cattle, donkeys and horses, no native mammals of the New World tropics can crush the hard, thick-walled pods of many rain forest trees in their jaws. Livestock apparently like the sweet pulp inside the pods of West Indian locust (Hymenaea courbaril) and disperse the hard, viable seeds in their excrement. In areas without livestock, the rotting pods litter the ground beneath large trees. Agoutis, tapirs and peccaries chew open the rotting pods and eat the sweet pulp and seeds, but are not major agents of seed dispersal like the larger hoofed mammals. According to the authority on Central American rain forests, Daniel H. Janzen (Science Vol. 215, 1982), large grazing mammals, including extinct pleistocene elephants called gomphotheres, may have once eaten the pods and dispersed the seeds in lowland forests. In Africa, the large woody pods of related species are quickly devoured by large herbivores. There are other Central American rain forest trees that also appear to be missing their natural herbivorous dispersal agents. Their hard, woody, indehiscent fruits pile up beneath the branches and slowly rot away in the soggy, moldy layer of soil and debris. The lack of natural dispersal agents may also apply to devil’s claw pods that litter the ground in temperate regions of the New World.
|Hard, woody fruits of some Central and South American rain forest trees were likely dispersed by large prehistoric herbivores thousands of years ago. A. Cassia grandis (legume family–Fabaceae); B. Crescentia alata (bignonia family–Bignoniaceae); C. Hymenaea courbaril (legume family–Fabaceae); and the palms (Arecaceae): D. Attalea speciosa (one fruit cut open to reveal thick, woody pericarp); E. Raphia taedigera; and F. Orbignya cohune.|
The Manchineel Tree
T here are dozens of unusual drift seeds that wash ashore on Caribbean islands, each with fascinating stories about them. One of the most interesting is an intricately-sculptured star that comes from the fruit of a native tree called the manchineel tree ( Hippomane mancinella ). The fruit of the manchineel tree resembles a small green apple, except this “apple” has a woody, seed bearing endocarp and is quite poisonous. Manchineel trees are common along Caribbean shores, and the fruits often fall into the water. The outer fleshy layer rots away and the buoyant, woody endocarp starts a new career as a drift disseminule. After many months of wave action and abrasion in tropical waters, the endocarp gradually becomes eroded into an intricate star. It is a beachcomber’s delight to find one of these beautifully-sculptured stars.
|Fruits of the manchineel tree ( Hippomane mancinella ) resemble small green apples. The seed-bearing pits (endocarps) float in tropical waters and gradually become eroded into intricately-sculptured stars.|
T he manchineel tree belongs to the diverse Euphorbia Family (Euphorbiaceae), and like many members of this family, it contains a poisonous milky-latex sap. The toxin is a mixture of diterpene esters, and contact with the skin may cause inflammation and a blistering rash. The caustic terpenes are structurally similar to phorbol, a potent carcinogen listed among organic compounds in the Merck Index . One of the earliest written accounts of the manchineel tree appeared in memoirs of Columbus’ second voyage to the West Indies in 1493. On November 3 a landing party went ashore on the island of Marie Galante. The fleet physician, Dr. Chanca, writes: “There were wild fruits of various kinds, some of which our men, not very prudently, tasted; and upon only touching them with their tongues, their countenances became inflamed, and such great heat and pain followed, that they seemed to be mad, and were obliged to resort to refrigerants to cure themselves.”
|A young manchineel tree ( Hippomane mancinella ) that has sprouting in the sand of a Costa Rican beach. The beach was littered with the green, apple-like fruits of this ocean-dispersed species.|
Sea Coconuts & Hand Grenade Pod
T wo more interesting drift fruits that wash ashore along beaches of the Caribbean and the southeastern United States are sea coconut ( Manicaria saccifera ) and grenade pod ( Sacoglottis amazonica ). Both drift fruits come from trees that are native to the Amazon River, and are often carried by the Gulf Stream to beaches of Northern Europe. The sea coconut is a tall, unusual palm with leaves nearly 30 feet (8 meters) long. This palm has been listed by some authors as the longest undivided leaf of any plant; however, according to Chuck Hubbuch of Fairchild Tropical Garden, Coral Gables, Florida, the leaf is typically divided shallowly at the tip and is not truly entire. The tuberculate fruit wall contains one to three globose seeds which become sun-bleached and resemble golf balls strewn along beaches. This striking palm is more closely related to the coco-de-mer ( Lodoicea maldivica ) of the Seychelles Islands rather than the true coconut ( Cocos nucifera ).
|A three-seeded fruit and two seed-bearing endocarps of the sea coconut ( Manicaria saccifera ), a palm native to the Amazon basin. Sometimes the tuberculate fruits contain only one or two seeds.|
T he buoyant fruits of grenade pod contain numerous hollow pockets which permit them to float for great distances. The raised pocket areas, which are exposed when the outer exocarp layer is eroded away, produce the faceted (bumpy) surface of the endocarp which superficially resembles a hand grenade. In Mexico these unusual fruits are often called “cojon de burro,” a descriptive name that is probably not as appropriate as hand grenade. They are produced by a small tree native to the Amazon and Orinoco River basins of South America.
|Two types of grenades: Fruits (endocarps) of the Amazonian tree Sacoglottis amazonica compared with a World War II hand grenade.|
L ike the migrations of ancient mariners, seafaring seeds have traveled to tropical beaches throughout the world. Collecting drift seeds can be a rewarding hobby–botanical treasures from exotic beaches to be admired for years to come. Some seeds (such as sea beans and sea hearts) can be polished in a stone tumbler, as you would polish agates and other precious stones, and different seeds can be strung together to make attractive necklaces and leis. Who knows–they might even bring you health and good fortune, like the fabulous tales from courageous explorers many centuries ago.
Other Drift Seed Articles:
Drift Seed References
Armstrong, W.P. 1998. “Seagrasses of the Pacific Coast.” Ocean Realm Spring 1998: 72-81.
Armstrong, W.P. 1998. “Unusual Drift Fruit From Costa Rica.” The Drifting Seed 4 (2): 7-8.
Armstrong, W.P. 1997. “Morning Glories.” Pacific Horticulture 58: 15-21.
Armstrong, W.P. 1996. “Seafaring Seeds.” Ocean Realm Summer 1996: 89-96.
Armstrong, W.P. 1994. “Floaters.” Sea Frontiers 40 (3): 24-31.
Armstrong, W.P. 1994. “Remarkable Swamp Trees.” Zoonooz 67: 24-27.
Armstrong, W.P. 1994. “Time Traveling With A Locust Tree.” Zoonooz 67: 28-31.
Armstrong, W.P. 1993. “Voyages of the Sea Hearts.” Zoonooz 66: 21-23.
Armstrong, W.P. 1991. “Seed Voyagers.” In: Popular Science Annual 1992, Grolier Inc., Danbury, Conn.
Armstrong, W.P. 1990. “Nickernuts: Travelers of the Open Sea.” Pacific Horticulture 51: 39-45.
Armstrong, W.P. 1990. “Seed Voyagers.” Pacific Discovery 43: 32-39.
Armstrong, W.P. 1990. “Valentines of the Sea.” National Geographic World Number 174: 3.
Armstrong, W.P. 1989. “Floral Flotilla.” Zoonooz 64: 17-19.
Armstrong, W.P. and R.F. Thorne. 1989. “California Seagrasses.” Fremontia 16: 15-21.
Armstrong, W.P. 1987. “The Seagrasses.” Environment Southwest Number 516: 6-11.
Buckley, R. and H. Harries. 1984. “Self-Sown Wild-Type Coconuts from Australia.” Biotropica 16: 148-151.
Corner, E.J.H. 1966. The Natural History of Palms. University of California Press, Berkeley.
Darwin, C. 1883. Journal of Researches . D. Appleton & Company, New York.
Darwin, C. 1859. On the Origin of Species by Means of Natural Selection, or the Preservation of Favoured Races in the Struggle for Life . London.
Darwin, C. 1857. “On the Action of Sea-Water on the Germination of Seeds.” Journal of the Proceedings of the Linnean Society 1: 130-140.
Darwin, C. 1855. “Effect of Salt-Water on the Germination of Seeds.” Gardeners’ Chronicle and Agricultural Gazette 47: 773.
Dennis, J.V. and C.R. Gunn. 1974. “Sea-Beans: Long-Distance Drifters From the South.” The Cape Naturalist 3: 40-45.
Dennis, J.V. and C.R. Gunn. 1971. “Case Against Trans-Pacific Dispersal of the Coconut by Ocean Currents.” Economic Botany 25: 407-413.
Everett, T.H. 1981. The New York Botanical Garden Encyclopedia of Horticulture Volume 3. Garland Publishing, Inc., New York.
Gruezo, W. Sm. and H.C. Harries. 1984. “Self-Sown, Wild-Type Coconuts in the Philippines.” Biotropica 16: 140-147.
Gunn, C.R. 1977. “Merremia discoidesperma: Its Taxonomy and Capacity of Its Seeds for Ocean Drifting.” Economic Botany 31: 237-252.
Gunn, C.R. 1968. “Stranded Seeds and Fruits From the Southeastern Shore of Florida.” Garden Journal 18: 43-54.
Gunn, C.R. and J.V. Dennis. 1976. “World Guide to Tropical Drift Seeds and Fruits.” Quadrangle/New York Times Book Co., New York.
Gunn, C.R. and J.V. Dennis. 1973. “Tropical and Temperate Stranded Seeds and Fruits From the Gulf of Mexico.” Contributions in Marine Science 17: 111-121.
Harries, H.C. 1992. “Biogeography of the Coconut Cocos nucifera L.” Principes 36: 155-162.
Harries, H.C. 1983. “The Coconut Palm, the Robber Crab and Charles Darwin: April Fool or a Curious Case of Instinct?” Principes 27: 131-137.
Harries, H.C. 1978. “The Evolution, Dissemination and Classification of Cocos nucifera L.” Botanical Review 44: 265-320.
Heyerdahl, T. 1968. Sea Routes to Polynesia. Rand McNally, Chicago.
Jackson, M.H. 1989. Galapagos: A Natural History Guide. The University of Calgary Press, Calgary, Alberta, Canada.
Muñoz-Rodriguez et al. 2018. “Reconciling Conflicting Phylogenies in the Origin of Sweet Potato and Dispersal to Polynesia” Current Biology 28: 1�11 (April 23, 2018). https://doi.org/10.1016/j.cub.2018.03.020
Porter. D.M. 1979. “Endemism and Evolution in Galapagos Islands Vascular Plants.” In: Plants and Islands, Edited by D. Bramwell. Academic Press, New York.
Porter, D.M. 1976. “Geography and Dispersal of Galapagos Islands Vascular Plants.” Nature 264: 745-46.
Rosengarten, F., Jr. 1986. “Coconut.” Principes 30: 47-62.
Wagner, W.L., Herbst, D.R. and S.H. Sohmer. 1990. Manual of the Flowering Plants of Hawai’i . Vol. 1. University of Hawaii Press and Bishop Museum Press, Honolulu.
Seed Jewelry References
Armstrong, W.P. 1991. “Beautiful Botanicals: Seeds For Jewelry.” Ornament 15: 66-69.
Armstrong, W.P. 1992. “Jewels of the Tropics.” Terra 30: 26-33.
Armstrong, W.P. 1992. “Nature’s Bounty.” Ornament 16: 66-69.
Armstrong, W.P. 1993. “Botanical Jewelry.” Herbalgram 29: 26-33.
Armstrong, W.P. 1993. “Neotropical Amber.” Ornament 17: 58-61.
Armstrong, W.P. 1994. “Job’s Tears.” Ornament 18: 104-105.
Armstrong, W.P. 1995. “Indian Shot.” Ornament 18: 70-71.
Armstrong, W.P. 1997. “Indian Shot.” The New Forester (Dominica Minister of Agriculture) 9: 32-33.
Francis, Peter, Jr. 1984. “Plants as Human Adornment in India.” Economic Botany 38 (2): 194-209.
Drift seed Drift Seeds And Drift Fruits Seeds That Ride The Ocean Currents See Botanical Jewelry & Drift Fruits: Jewelry Drift Fruits Sea Beans For more
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By Stephanie Labaff
They can travel for thousands of miles, are said to have mystical powers and right now is the best time to collect the elusive sea bean as you walk along our local beaches.
Sea beans are seeds or seed pods grown on land that somehow make it into the ocean currents where they start their journey to new lands. The travelling seedlings were first recorded in 25 B.C. and since that time a legion of collectors have scoured beaches looking for rare finds.
“If these drift seeds could talk, imagine the stories they could tell,” says Ed Perry, Florida native and a 25-year veteran park ranger at the Sebastian Inlet.
Perry has been collecting sea beans most of his life. As a youngster growing up in Cocoa Beach he would spend time combing the beaches near his grandmother’s shell shop on the Canaveral Pier.
“She called it the Sea Bean Boutique and sold surfboard wax, suntan lotion, shells, art and t-shirts, but not sea beans. You could always find ‘something unique at the Sea Bean Boutique,” recalls Perry.
The name of the shop always attracted questions and Perry’s grandmother would keep several sea beans in the cash drawer so she could share them with the tourists. It was Perry’s job to keep the shop stocked with sea beans.
“She gave me a quarter for every sea bean I brought back to her,” says Perry. “I would wander along the beach when I wasn’t fishing on the pier and only pick up the hamburger sea beans,” he cringes as he remembers tossing sea beans aside that he now realizes were rare finds.
“There are 250,000 species of seed bearing, flowering plants on earth. Only about 250 of those species make drift seeds or seeds that are capable of floating on ocean currents,” explains Perry. “That’s one-tenth of one percent, it’s pretty special to be a drift seed.”
Perry’s interest in sea beans was revived when he returned to Brevard County after finishing his degree at the University of Florida in criminology.
“In the early 90s I started reading books by Cathie Katz who wrote about sea beans and many other neat things on our beaches,” shares Perry.
If you’ve ever walked along the beach, you have probably seen a sea bean and not even known it. The pods are carried to the ocean along rivers and streams, and then hitch a ride on ocean currents drifting their way to faraway places.
“We think most of the seeds that wind up on our beaches here are from about a three-month drift area to the south of us but sea beans from as far away as Africa have been found on Florida beaches,” says Perry. “Most of the sea beans found are from Cuba, Jamaica and Mexico.”
It can take as long as three years for a sea bean to travel all the way around the Atlantic Ocean, sometimes never making its way on to shore. The beans or pods lie among the flotsam and jetsam washed up onto the beach with the incoming tide.
September and October are the best months for sea bean hunting due to currents traveling more closely to shore. High winds and an onshore breeze help the seeds make their way onto the beach.
The best time to hunt for sea beans is early morning, as the high tide during the night tends to wash them ashore.
Myths and legends abound about the sea bean and the powers it is said to contain. The earliest written record refers to jewelry made from the grey nickernut or sea pearl. It was worn as a pendant to ward off evil spirits.
Another popular belief is that the Mary’s bean or crucifix bean, which has a cross on one side and is passed from mother to daughter helps to ease the pain and discomfort of childbirth. Women clench the seed in their hand while having their baby.
“The Mary’s bean originates from only one place in the world so when we find it here, 2,000 miles from its origin we know it’s a rare find,” says Perry. “The Mary’s bean holds the record for the longest drift.”
Finding the sea bean is just the beginning of the “drifters” experience. The real fun begins when you identify the type of bean or seed you’ve found and map its journey.
“It happens to all of us. First it’s curiosity about this thing you’ve found on the beach. Next comes enlightenment and you realize there’s a story for each bean,” says Perry. “Then we move into the hoarding phase where the collector keeps every bean they can put their hands on. Fortunately, most move on to sharing and educating others.
“Finally, we get to the Zen phase.”
That’s where Perry is with his love of sea beans. He wants to share his knowledge and will gladly hand over a few beans from his collection. He’s content to pass by the more common beans that he’s come across over the years.
The best part of searching for sea beans according to Perry is that it’s something you can do as a family. He spent a great deal of time over the years combing the beaches with his daughter Gayle.
“I started taking my daughter searching for sea beans when she was one-year-old. It’s something we still share.”
To further share his passion for sea beans, Perry co-authored a book with John Dennis entitled Sea Beans from the Tropics: A Collector’s Guide to Sea Beans and Other Tropical Drift on Atlantic Shores.”
The book is one of the few on the topic of sea beans and offers scientists and novices alike useful information on hunting and identifying sea beans.
It’s the one or two elusive beans that keep Perry going.
“There are just a few beans that I’d still love to find,” he shares. “The Canavalia nitida or Cathie’s Bean is one of them.”
The bean was named after Cathie Katz, founder of The Drifting Seed newsletter and Sea Bean symposium. Katz passed away several years ago from cancer, leaving behind a legacy for sea bean enthusiasts.
“I’ve picked up about 240 different species on Florida’s beaches and I’ve been able to identify about 220 of those species.”
Each year as many as 1,500 “drifters” from as far away as Japan, converge on the east coast of Florida for a convention to compare rare finds, discuss drift conditions and have some fun.
The 18th Annual International Sea Bean Symposium and Beachcombers festival will take place at the Cocoa Beach Public Library on October 18 and 19.
In addition to the speakers, they will conduct a bean-a-thon on Saturday morning. Participants will scour from 8 to 10 a.m. any beach between Sebastian Inlet and Canaveral National Seashore.
They must return by 10:30 a.m. with their haul. The judges are looking for a variety in species and unique items found washed up along the beach.
“Be prepared to learn a little bit of science and have a whole lot of fun,” says Perry.
They can travel for thousands of miles, are said to have mystical powers and right now is the best time to collect the elusive sea bean as you walk along our local beaches.