Most oceanic islands harbor unusual and vulnerable biotas as a result of isolation. As many groups, including dominant competitors and predators, have not naturally reached remote islands, others were less constrained to evolve novel adaptations and invade adaptive zones occupied by other taxa on continents. Land crabs are an excellent example of such ecological release, and some crab lineages made the macro-evolutionary transition from sea to land on islands. Numerous land crabs are restricted to, although widespread among, oceanic islands, where they can be keystone species in coastal forests, occupying guilds filled by vertebrates on continents. In the remote Hawaiian Islands, land crabs are strikingly absent.
Here we show that absence of land crabs in the Hawaiian Islands is the result of extinction, rather than dispersal limitation. Analysis of fossil remains from all major islands show that an endemic Geograpsus was abundant before human colonization, grew larger than any congener, and extended further inland and to higher elevation than other land crabs in Oceania.
Land crabs are major predators of nesting sea birds, invertebrates and plants, affect seed dispersal, control litter decomposition, and are important in nutrient cycling; their removal can lead to large-scale shifts in ecological communities. Although the importance of land crabs is obvious on remote and relatively undisturbed islands, it is less apparent on others, likely because they are decimated by humans and introduced biota. The loss of Geograpsus and potentially other land crabs likely had profound consequences for Hawaiian ecosystems.
Citation:Paulay G, Starmer J (2011) Evolution, Insular Restriction, and Extinction of Oceanic Land Crabs, Exemplified by the Loss of an Endemic Geograpsus in the Hawaiian Islands. PLoS ONE 6(5): e19916. doi:10.1371/journal.pone.0019916
Editor: Mark Briffa, University of Plymouth, United Kingdom
Received: June 3, 2009; Accepted: April 21, 2011; Published: May 16, 2011
Copyright: © 2011 Paulay, Starmer. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Funding:Partially supported with funding from the US National Science Foundation (NSF DEB-0529724), Leila & William Brayfield Scholarship, and the Southwest Florida Fossil Club. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Competing interests: The authors have declared that no competing interests exist.
Isolation leads to disharmonic biotas on islands, because poor dispersers are absent or under-represented relative to good dispersers , . Low starting diversity and absence of various major taxa generally lead to ecosystems with fewer types of biotic interactions than on continents. This in turn provides ecological release for some colonizers, while preventing the establishment of others. Some strong ecological interactors, such as mammals and ants, are characteristically underrepresented on or absent from many oceanic islands. Terrestrial flightless mammals do not naturally extend east of the Solomon Islands in the Pacific, while ants appear to have been naturally absent from the Hawaiian, and possibly other remote, island groups , , but see . The lower intensity of some biotic interactions on oceanic islands has striking consequences. First, islands can be “safe places”  for taxa that cannot survive in the face of biotic interactions characteristic of continental settings. For example several land snail and insect families, as well as species of wide-ranging sea birds, are restricted to islands , . These taxa appear to be especially vulnerable and suffer massive extinctions following introduction of continental predators , , . Second, ecological release on islands has fostered macroevolutionary transitions – the invasions of novel adaptive zones. Examples include evolution of terrestrial larval habits by damselflies in the Hawaiian, New Caledonian, and Pohnpeian faunas , , raptorial carnivory in Hawaiian caterpillars , and colonization of land by Caribbean truncatellid snails  and Jamaican sesarmid crabs . Third, the low initial diversity of insular biotas has fostered diversification, thus evolutionary radiations are a hallmark of island life: Galápagos finches and Hawaiian fruit flies are celebrated examples , .
Ecological distinctiveness of oceanic island habitats is reflected in distributional patterns: many taxa are distributed widely among, but restricted to, oceanic islands. For example, while species of achatinellid land snail species have restricted ranges, the family extends from the Juan Fernandéz Islands near South America, to Lord Howe Island near Australia, to the Ogasawara Islands near Japan, and to oceanic islands in the Indian Ocean, yet is absent (except for recent human-facilitated introductions) from the four neighboring continents . Similar wide ranges and oceanic restriction characterizes the land snail families Endodontidae and Partulidae, as well as the beetle family Proterhinidae . Many sea bird species are likewise widespread across one or several ocean basins, yet restricted to islands . Oceanic restriction is also common among shallow, benthic marine species with good dispersal powers, such as hermit crabs, lobsters, and gastropods, a pattern long noted , ,  and debated , , , .
Oceanic restriction is especially striking among “land crabs” . Level of terrestriality varies substantially among crabs, from species that live strictly intertidally to those that have lost all connections with the sea. In this paper we define land crabs as species that live inland of the supratidal fringe, in coastal vegetation, not including mangroves. We exclude ghost crabs (Ocypode), as they are primarily beach inhabitants, although some species enter vegetated zones at beach margins. We include both anomuran and brachyuran crabs. Most land crab species in remote Oceania (Polynesia, Micronesia, and island Melanesia) have wide ranges (all have marine larvae), yet are restricted to islands. Of the 18 or so land crab species widespread in remote Oceania, only one is recorded from the Australian mainland, yet 13 occur on adjacent offshore islands (Table 1) . All four major families of oceanic land crabs include species with such distributions. The omnivorous, terrestrial Coenobitidae (Anomura), comprised of terrestrial hermit crabs (Coenobita) and the shell-less coconut crab (Birgus), “skip” Australia except for the endemic Coenobita variabilis. The conspicuous, large-bodied, detritivorous to omnivorous, and often strikingly abundant land crabs of the family Gecarcinidae (Brachyura) follow a similar pattern: only Cardisoma carnifex is known from mainland Australia. The Sesarmidae (Brachyura), a diverse group with a broad range of terrestrial adaptations, has repeatedly invaded land; the three terrestrial species known in Oceania appear to be absent in continental Australia, although others occur there. Among the Grapsidae (Brachyura) only some Geograpsus qualify as land crabs (as defined here); this predominantly predatory genus is also absent from the Australian mainland. Peter Davie, who compiled the ABIF  crustacean checklist, noted (in litt. 12 April 2004) that “as far as I can find there are no records of Geograpsus from the mainland Australia. The catalogue was primarily based on literature, but I have no Geograpsus in the QM from northern Australia. … My impression of Geograpsus is that it has a mostly insular distribution avoiding the continental land masses, rather like the many gecarcinids and Birgus. Perhaps it is the result of predator pressure?”
Oceanic land crabs are similarly under-represented in Southeast Asia, although the ranges of all but one of the 18 species listed straddle the area. Peter Ng (in litt. 25 March 1998) noted that Geograpsus is absent “in SE Asia per se. It occurs only on islands or peninsulas in areas washed by more oceanic waters. I have caught these guys in southern Taiwan and adjacent islands though! They are apparently affected badly by human activities, especially pests. In one island in Taiwan, their population is decreasing, possibly because of human activities. They are very vulnerable when they move en masse to sea to spawn. I suspect like most island crabs (e.g. many gecarcinids and Birgus), they are vulnerable to predators, native or introduced at some stage of their life. I believe in many cases, it is the young which are very vulnerable to things like rats, civets, squirrels, monitors etc. and the pressure of these predators on the juveniles forces them to small islands where such predators are absent.” Similarly, in their massive treatise on Chinese crabs, Dai & Yang  record Geograpsus grayi only from Taiwan, and Geograpsus crinipes only from Xisha Island (Paracel Islands), in China. Similarly Sakai  records G. crinipes only from offshore islands around Japan, and G. grayi mostly from offshore islands except for records from Kagoshima and Tosa Bay.
Oceanic land crabs are also under-represented on the African mainland, although diverse and common in the Seychelles and other Indian Ocean islands. Only two records of G. crinipes, and single records each of Coenobita perlatus, Coenobita brevimanus, and Discoplax rotunda are known from Africa; “their extreme rarity along the East African coastline confirms their insular character” . Among gecarcinids, Cardisoma carnifex is the only species common on the African mainland, as in Australia , .
While many land crabs are restricted to islands, they are dominant members of the terrestrial biota there, with major ecological impacts. They can be important predators on young birds, invertebrates and seeds, affect seed dispersal, control litter decomposition, and are important in nutrient cycling , , ,  (see below). Loss of land crabs can lead to large-scale shifts in community structure , .
Almost all tropical islands are occupied by land crabs; in the tropical Pacific only the Hawaiian Islands “lack” them. However this is a secondary phenomenon, as land crabs were present in Hawai'i before human colonization. Here we describe an abundant, highly terrestrial, large, presumably carnivorous-omnivorous, extinct land crab, and review records of other terrestrial and semi-terrestrial decapods recorded from these islands. Fossils of this species have been known for many years, but their identity has not been clearly established . We also consider the evolutionary origin of this land crab, which apparently was endemic to the Hawaiian Islands. Finally we explore the origin and consequences of some macroevolutionary and macroecological biases associated with land crabs and their relatives.
Geograpsus Stimpson, 1858.
Four species of Geograpsus are currently recognized: G. lividus in the Atlanto-East Pacific, and G. stormi, G. crinipes and G. grayi in the Indo-West Pacific region . They can be arranged in a series reflected both in morphology and habitat, with the morphologically and ecologically very similar, supratidal G. lividus and G. stormi at one end, mostly coastal G. crinipes in the middle, and most terrestrial G. grayi at the other end. Increased terrestriality is accompanied by greater inflation and posterior narrowing of the carapace, as the branchial chamber becomes modified for air breathing. Remarkably, three species are represented by material from Hawaiian Islands.
Geograpsus severnsi new species.
- Geograpsus species: Burney et al., 2001 
- Geograpsus aff. geayi [sic]: Burney & Kikuchi, 2006 
Holotype: USNM 539,738: Maui: Pu'u Naio Cave, 305 m elevation, Quadrat W15.0–15.5, Unit III G. 4.V.1988. H James. 2 sets of cheliped dactyli, propodi, carpi, and meri, pieces of ambulatory legs including meri, portion of carapace, endostome, 4th and 3rd thoracic sternites, pterygostomial plates; presumably from a single male specimen (Fig. 1)
All from Maui, Pu'u Naio Cave. USNM 539,739: W17.0–17.5, Unit III I. 22.VI.1988. H James. 1 chela, 1 fixed finger. USNM 539,740: W15.0–15.5, Unit IV F I. 9.V.1988 H James. 1 dactyl, 1 sternite, 1 endostome, chelar merus, carapace fragments. USNM 539,741: W16.5–17.0, Unit III I, 16.III.1988. H James. Male 4th sternite. UF IP 168,821: 1984. M Severns. male 4th and 5th sternites. UF IP 168,822: 1984. M Severns. female 4th and 5th sternites. UF IP 168,823: 1984. M Severns. male 4th and 5th sternites.
Kaua'i: USNM 539,742: Pa'a sand dunes at Poipu. 25.V.1988, S Olson, Gage, P Fiene, M Severns. 2 partial carapaces, 3 articulated chelipeds. USNM 539,743: Kealia, 26.V.1988. P Fiene, M Severns. 2 claws, 1 dactyl, 1 fixed finger. UF IP 168,827: Makawehi Dunes, S Kaua'i coast, 21°52′51″N, 159°26′03″W, late Pleistocene to early Holocene, lithified carbonate dunes. 20.IX.1997. D Burney, S Olson. 1 claw.
O'ahu: USNM 539,744: Barber's Point: Bishop Museum site 50-0a-B6-22, sqM4, TP1 extension, layer II. 4.IV.1980. 1 claw, 4 chelar dactyli.
Moloka'i: USNM 539,745: Mo'omomi Dunes, west end of old sand mine. 4.VI.1998. 1 chela. S Olson, J Aidem, P Hearty. USNM 539,746: Mo'omomi Dunes, 5-10-11. 29.VII.1990. H James, Aidem, T Stafford, Hume. 2 chelae, 1 chelar propodus.
Maui: USNM 539,747: Waiehu, sand dunes being sand-mined at “Leisure Estates”. 1.VI.1988. S Olson. various claw pieces. USNM 539,748: Lua Lepo, D1W, W1/2 Unit 5. 2 claw fragments, carapace fragments. UF IP 168,824: Pu'u Naio. 1984. M Severns. Pterygostomian fragments. UF IP 168,825: Pu'u Naio. 1984. M Severns. 1 claw dactyl. UF IP 168,826: Maui: Pu'u Naio. 1984. M Severns. Carapace pieces.
Hawai'i: USNM 539,749: Point caves, cave on road towards/into subdivision (near Mark Twain Tree) ca. 5 miles near main highway (Makai), ca. 4.4 mi. NE of S Point Road on left side of dirt road. Crabs from deep in cave, many present. E Paxinos, J Wilcox, R Basona, J Lilly. leg carpus, endostome with associated mandible, carapace fragment, 2 entire claws, 4 cheliped carpi, 2 cheliped meri, 8 ambulatory leg meri, 4 ambulatory leg carpi, 2 male 4th sternites, fragments. USNM 539,750: Makalawena cave. 2.VI.1991. H James, J Earle. 1 male 4th sternite, 2 claws, 2 cheliped carpi, leg fragments; same crab? USNM 539,751: Hawai'i, new cave system, ca. 12m south of and parallel to Owl Cave system, below 213m asl. 3.III.1993. H James, Lopez, Cooper, Griffen, Cobb, B Schaefer. 1 claw, 2 chelar carpi, leg and chelar meri. USNM 539,752: Makalawena cave, 646 m, upslope of first entrance, near third entrance. 2.VI.1991. H James, J Earl. 4 claws, 2 partial chelar meri, 1 dactylus, 1 partial chelar carpus. USNM: 539,753: Kau Kaaluau-Waiohinu Road Cave, 4.5 mi. from HWY 11 through Mark Twain subdivision down slope from Y in road. 1.VIII.1998. E Paxinos, S Olson, H James, B Slikas, B Schaefer. 2 claws, most of male 4th sternite, leg fragments; same crab?
Numerous additional specimens from several of these localities (USNM, UF).
Large Geograpsus species with chelae smoother and higher than in congeners, with fixed finger markedly bent downward and with straight cutting surface. Cheliped carpus nearly smooth, with small inner spine; merus with inner margin expanded forming a marked angle, with 4–6 large teeth anterior to angle. Ambulatory meri longer, narrower, and less compressed than in other Geograpsus species. Fourth sternites lacking anterior constriction; pubescent as in G. grayi.
Cheliped (Figs. 1, 2, 3): Chelae large (L = 34.1±8.7 mm; range: 20.4–49.1 mm; N = 37), higher than in other Geograpsus species (H/T = 1.58±0.11; range: 1.39–2.00; N = 41), inflated, dimorphic. Large chelae with dactylus conspicuously arched relative to fixed finger; fixed finger extending ventrally at an angle from palm; angle and arising gap between fixed and movable fingers both increasing with size (Fig. 3). Smaller chelae with dactylus slightly arched to straight, with little gap. Cutting margin of fixed finger straight to slightly concave. Palm smoother than in other Geograpsus species, becoming smoother with increasing size; dorsal margin bearing 0–3 granules near base; ventral margin marked by row of transversely-elongated granules; outer surface smooth; inner surface with a patch of low, scaly ridges on basal half. Fixed finger with 7 or 8 rows of punctae on inner surface, some rows incised as grooves, and with slightly- to markedly-raised, smooth to granular ridge; sculpture more pronounced in small chelae. Dactylus smooth, with rows of punctae most pronounced in smaller specimens.
Carpus relatively smooth, with a few, low granules and low ridges when small, to completely smooth when large; inner spine smaller than in G. crinipes or G. grayi.
Merus with well developed, markedly angular flange with toothed margin, bearing 4–6 large teeth distal to, and several, much small teeth basal to, angle. Merus smooth ventrally except near outer border; with a conspicuous transverse ridge distally; ventral portion of ridge low and smooth, dorsal portion higher and granular. Dorsal and outer face of merus with well-developed, imbricating ridges.
Ambulatory legs (Fig. 1): Meri narrower, more elongated, and less compressed than in other Geograpsus species; equally broad at proximal and distal ends; distoposterior margin not expanded as in other Geograpsus species and lacking spinules; with compressed, well delineated ridge forming dorsal margin; with fine, imbricating ridges along upper and lower surfaces. Carpi typical of genus.
Carapace: (partial specimens available only) Frontal margin of adult straight or slightly convex from anterior aspect; with single anterolateral tooth behind exorbital angle; outer margin of exorbital angle strongly inturned; frontal area with fine, scale-like pattern typical of genus; hepatic and branchial areas with numerous transverse ridges; intestinal area smooth. Posterolateral parts of carapace not preserved among available specimens.
Sternites (Figs. 1, 4): Fourth sternite trapezoidal in shape, lacking anterior constriction of Grapsus species and G. stormi; with convex anterolateral, and straight anterior margins; densely punctate, thus densely pubescent as punctures hold setae in life; punctae densest in paired tracks that diverge anteriorad around middle of sternite and also abundant along anterolateral margin; punctae generally aligned in short, oblique, postero-lateral to antero-medial, rows. Third sternite typical of genus (Fig. 1).
Endostome (Fig. 5): Upper buccal ridge tuberculate, straight, close to anterior margin of endostome.
Named for Mike Severns, who discovered the Pu'u Naio Cave on Maui, where most of the material came from; for his long-standing interest in and collections of this species.
Hawaiian Islands: known from Hawai'i, Maui, O'ahu, and Kaua'i; nearshore to 905 m elevation; Holocene (Table 2).
In all the three specimens examined with associated claws the right claw is the major one. Among all claws examined there is a strong bias toward larger size in right claws (Fig. 6).
The fourth sternites of males have a more strongly demarcated and narrower depression than those of mature females for accommodating the telson. This is also expressed in the meristic BW/S ratio, which is >2 in all male and <2 in all female Geograpsus species (Table 3). Fossil sternites of G. severnsi clearly show this sexual dimorphism and provide a means of sexing the population. Immature females have sternites similar to that of males. In G. grayi, females develop mature sternite and abdomen morphology at ca. 6 mm anterior (TW) and 10 mm posterior (BW) sternite width (e.g., UF 4987). The smallest fossil G. severnsi sternites are 9.5 mm/20 mm (TW/BW) wide, with two clearly female sternites 10.8 and 10.9 mm (TW) wide. Thus it is likely that all fossil sternites (TW = 12.4+/−1.9, range: 9.5–17, N = 28; TW = 23.9+/−3.0, range: 20–29.5 mm, N = 18) are from mature individuals and thus can be used to sex the crabs. Furthermore, all sternites complete enough to allow measurement of BW and S (N = 17) had male shapes and BW/S ratios appropriate for male Geograpsus species(Table 3). According to shape and morphometrics, of 31 sternites examined, 28 were from males and 3 from females.
Geograpsus severnsi appears to be an offshoot of G. grayi, a hypothesis supported by overall morphological resemblance, as well as phylogenetic analysis (see below). Notably both species have 1) relatively high and lightly ornamented chelae, unlike the elongated and markedly tuberculate chelae of other Geograpsus species, 2) a pubescent fourth abdominal sternite (shown by punctures in fossils), 3) appear to have (preservation of G. severnsi carapaces too limited to be certain) a more inflated carapace, with the lateral ridge separating the dorsal and lateral parts of the carapace terminating about halfway as in G. grayi, rather than continuing to posterolateral corner as in other congeners, and 4) upper buccal ridge on endostome straight and close to the anterior margin, rather than convex and considerably more posteriorad as in G. crinipes (Fig. 5). Geograpsus severnsi can be readily differentiated from G. grayi by its smoother and higher (Fig. 2) chelae, smoother chelar carpi that bear a smaller inner spine than in G. grayi, and relatively straight, rather than arched, cutting surface on the fixed finger. The ambulatory meri of G. severnsi are more elongated, less distally expanded, and thicker than in other Geograpsus species.
Claws are the most common fossils and show clear meristic differences among Geograpsus species. The claw of G. severnsi is proportionately taller (i.e., greater H/L but especially H/T) than of other Geograpsus species and bears a relatively longer fixed finger (i.e., lower B/F) than the claw of congeners (Table 4, Figs. 7, 8, 9). The lesser accentuation of the H/L than H/T ratio is the result of the opposite effects of palm heightening and finger lengthening. The 4th sternite of G. severnsi also tends to be broader (i.e., greater TW/H) than those of G. grayi and G. crinipes, but substantially narrower than those of G. stormi and G. lividus (Table 4, Fig. 10).
Geograpsus severnsi may have been the largest species in the genus. There is a tight correlation between width of 4th sternite and width of carapace across all Geograpsus species (y = 2.3247x - 1.2084, r2 = 0.88; Fig. 11). If we assume this relationship also held for G. severnsi, then we can estimate carapace width from size of sternites. Sternites of these fossils slightly exceed the width of even the largest G. crinipes (Fig. 11), even though only 18 G. severnsi sternites were available, while the sample size for whole G. crinipes was much greater and included the largest specimens we have seen. The largest G. crinipes measured (UF 2383: Pitcairn I, CW = 63 mm, CL = 55 mm) were close to the maximum recorded size for the species (CL = 61 mm ). The estimated carapace width of the largest G. severnsi is 66 mm (Fig. 11). Griffin  records fossil carapaces up to 55 mm wide. The size of G. severnsi is also reflected by its large claws, although claw shapes are too variable to allow an accurate estimation of body size in Geograpsus species.
Hawaiian workers have been aware of this species for some time. Frank Howarth sent specimens he collected at 430 m elevation, 5 km inland on Oahu to Fenner Chace, which were identified by Chace (in litt., 20.VI.1975) as Geograpsus cf. crinitus. A similar query was made by Bill Haus (in litt., 17.III.1980)(Assistant in Invertebrate Zoology at Bishop Museum) to John S. Garth, in which he noted that the fossils “were discovered by John Earle in a burial mound located inside a cave c.a. 1200 ft. above sea level (Honokoa Gulch, Hawai'i).” and that “it is possible that we are dealing with an extinct species”. Garth's reply (24.III.1980), does not add much to Haus' thoughtful analysis.
Geograpsus crinipes (Dana, 1851).
Fossil: USNM 539,761: Maui, Kiakeana Cave, 1.VII.1990. H James, P Fiene, M Severns, F Grady: 2 claws, 10 fixed fingers, 10 dactyli, and fragments. USNM 539,762: Maui, Kahawaihapapa Cave, 50 ft. 22.III.1988. M Severns, P Fiene, S Olson, H James, T Stafford. 2 chelar fixed fingers, 3 chelar dactyli.
Recent: BPBM 5288: Laysan, tide pools. 26.IV.1928. S Ball. 1 female, BPBM-S 255: O'ahu. V.1915. J Stokes. 2 specimens; BPBM-S 3149: O'ahu; Waikiki. 1930. CH Edmondson. 1 specimen; BPBM-S 3677: O'ahu; Black Point. XI.1933. CH Edmondson. Numerous specimens from non-Hawaiian localities (UF, USNM, BPBM).
Several eroded chelar propodi and dactyli attributable to G. crinipes are among crab remains at Kiakeana Cave on Maui, together with remains attributable to G. severnsi. Chelae are recognizable as G. crinipes by their well-developed tuberculation. Chelar tubercles are absent in G. severnsi and G. grayi, and finer and largely restricted to the upper half of the chelae in G. stormi and G. lividus. Geograpsus crinipes has also been recorded historically , , , , but appears to be quite rare today. The BPBM card catalog lists specimens from Hawai'i, Maui, O'ahu, and Laysan; however only four lots from O'ahu and one from Laysan could be located in the collections. Two of these are of small juveniles, and the other two are also of small animals. Two additional lots, collected in the 19th century by H. Mann and A. Garrett respectively , are reported to be at the MCZ. We asked several naturalists active in marine and shore habitats in Hawai'i whether they have ever encountered Geograpsus species; most (L. Eldredge, A. Fields, J. Hooper, C. Pittman, C. Zabin) indicated that they have not. Reassuringly, a single specimen was collected in 2004–5 by Scott Godwin on Moloka'i , indicating that the species still survives in the area. Interestingly, the photograph taken of the specimen shows a mottled color pattern, unlike the uniform color of G. crinipes elsewhere in the Pacific, a difference warranting a phylogeographic examination of the species. Surveys for the species, especially in less impacted habitats, like offshore satellite islands and the Northwest Hawaiian Islands, would be worthwhile.
Geograpsus crinipes is widely distributed in the Indo-West Pacific from the eastern Indian Ocean to Easter Island , , . It is supratidal and ventures into coastal forests. In uplifted karst islands in the South Pacific (Tonga, Niue, Cook Islands, Henderson Island), we have found it to be a characteristic occupant of coastal karst cliffs, where it runs rapidly from just above to many meters above, tide level. It is also common in coastal forests on karstic terrain, to about 100 m inland. Restriction of this species to a <300 m wide coastal belt has been noted in most areas , , pers. obs., with two notable exceptions. A single specimen was collected by Thor Heyerdahl on Easter Island in a crevice at 250 m elevation . On volcanic Pitcairn Island, the species extends as far as 500 m inland, to 150 m elevation, in moist coastal to interior forest (JS pers. obs.).
Geograpsus crinipes was only encountered in the Hawaiian fossil crab material from Kiakeana Cave, at 73 m elevation (H. James, pers. comm.), and Kahawaihapapa Cave at 15 m elevation. These records are substantially more coastal than most G. severnsi collections, but also at a substantial elevation compared to other records of the species. Together with the unusual color pattern of Hawaiian crabs, it suggests that G. crinipes may be a species complex, with the nominal species potentially restricted to the Hawaiian Islands.
On some remote and relatively undisturbed islands G. crinipes can be diurnal, while at other, more disturbed localities (e.g. Guam), it is predominantly nocturnal (GP, JS pers. obs.). In karst it occupies the ubiquitous crevices when hiding. On volcanic islands it does not always burrow, and is found either simply associated with leaf litter (Pitcairn) or on lava outcroppings with crevices (Pitcairn and Tutuila islands). It appears not to burrow on sandy cays, and was associated with leaf litter or fallen trees (e.g., Oeno Atoll and Mañagaha Islet, Saipan). Geograpsus crinipes is a voracious omnivore, often preying on other land crabs, including small coenobitids, ocypodids , and G. grayi  (pers. obs.), insects , and even birds  (Fig. 12).
Geograpsus lividus (H. Milne Edwards, 1837) complex.
- Geograpsus stormi 
Recent: MCZ 6107 (Original No 65): Sandwich Islands, Coll. A. Garrett, presented by J.M. Barnard, formalin fixed, 2 males.
Remarkably, a third Geograpsus species is also recorded from the Hawaiian Islands, based on two males collected by Andrew Garrett in the 19th century. They were first listed by Rathbun  as G. lividus, repeated by Edmondson , , who noted that “there are no records of the species having been observed in Hawai'i in recent years, and there are no specimens in Bishop Museum.” Banerjee  did not examine these specimens, but reassigned them to G. stormi based on his recognition of G. stormi as the Indo-West Pacific species in the G. lividus complex, and assuming an Atlanto-East Pacific restriction to G. lividus proper. Although the G. lividus complex requires further work because the two species have few morphological differences , they are clearly differentiated by color. Thus G. stormi has a dark red carapace, while East Pacific and West Atlantic G. lividus are tan with dark, variegated patterning.
Banerjee  lists 6 characters that differentiate these species; however we were not able to substantiate a number of these as reliable when comparing typical G. stormi (UF 10621, etc) with G. lividus (UF 8424, 8291, etc). Thus G. stormi examined show lividus-type ridges at the anterior branchial region of the carapace (Banerjee's character 1); the external maxilliped palps of the two are equally hairy (character 3), and the antero-distal angle of the second walking leg (character 4) in some G. lividus we examined are as pointy as illustrated for G. stormi by Banerjee. We noted some, but not profound differences in the shape of the upper buccal margin (character 2), mostly as a result of the fusion of the central three teeth on the upper buccal ridge in G. stormi, with the resulting larger tooth accentuating the posterior arching of the ridge. The legs of G. lividus appear generally shorter, and Banerjee may be correct that this is especially noteworthy for the dactyli (character 5), although we have not quantified this. Colors (character 6) are strikingly different. In addition the carapace of G. stormi tends to diverge more posteriorly, while that of G. lividus has more subparallel margins. We were not able to confidently assign Garrett's specimens to species. The ridge along the upper border of the buccal cavern are closer to typical G. lividus than G. stormi, as are the teeth along the anterodistal angle of the second walking legs. The carapace of the larger specimen diverges posteriorly, while that of the smaller is subparallel. As the Hawaiian biota includes some East Pacific elements, the possibility that Garrett's specimens are G. lividus remains. However G. stormi is known from the adjacent Line Islands (UF 10621). Although distributed across the Indo-West Pacific, G. stormi is rather cryptic, typically uncommon, and rarely collected. Thus lack of records since Garrett's  (L. Eldredge, A. Fields, S. Godwin, J. Hooper, C. Pittman, C. Zabin, pers. comm.) are less conclusive for this species than for others discussed here, but so is the Hawaiian origin of the material, being a single lot, with little collection information, dating from the 19th century.
This species is restricted to the supratidal fringe, and thus is less terrestrial than other crabs discussed in this paper. Given that G. severnsi appears to be an offshoot of the widespread G. grayi (see below), all three Indo-West Pacific Geograpsus lineages may thus have reached Hawai'i.
Other Hawaiian land crabs
The only other (marginally) terrestrial crab unambiguously documented from the Hawaiian Islands is “Chiromantes” obtusifrons (Dana, 1852) (see  for discussion of generic assignment). Described from Maui , it ranges to the eastern Indian Ocean . On Guam it lives under rocks and in karstic crevices in sparsely vegetated coastal platforms, up to ca. 50 m inland and ca. 10 m elevation. Edmondson  notes it to be intertidal and “even above the high water mark”, suggesting that the Hawaiian population may not be as terrestrial as populations in Micronesia. We have found this species in a supratidal boulder field on O'ahu. Additional observations on its ecology in Hawai'i would be useful.
Five additional species of land crabs (as defined above) have been recorded from the Hawaiian Islands; however all are based on single collections from the 19th century and are questionable. Two species of gecarcinid crabs, Discoplax hirtipes (Dana, 1851) and Discoplax rotundum (Quoy & Gaimard, 1824) were recorded from O'ahu based on a single lot (MCZ 5769) attributed to H. Mann, 1864. Rathbun , Edmondson , and Türkay  have commented on this lot, comprised of a male and a female specimen. The last author concluded, in his revision of the group, that the male represents D. hirtipes and the female D. rotundum. We have not reexamined these specimens. We are not aware of any other records of gecarcinids from the Hawaiian Islands, living or fossil, although both species extend well into the central Pacific, reaching eastern Polynesia . If indeed two species are represented in MCZ 5769, then it seems unlikely that this lot originated in the Hawaiian Islands, as the chance that both species would have been recorded but once, by the same person at the same place, seems remote, especially because they have rather different ecology and habitats.
“Geosesarma” angustifrons (A. Milne Edwards, 1869) was described from the Hawaiian Islands, but never subsequently collected there . It has also been recorded from the Society Islands ,  and Java . The species belongs to Sesarmops Serène & Soh, 1970 (PKL Ng and T Naruse, pers. comm.), a genus of typically stream-associated crabs, a habitat also characteristic of S. angustifrons  (pers. obs. on Moorea & Raiatea, Society Islands). Labuanium rotundatum (Hess, 1865) is another sesarmid that remains poorly documented from the Hawaiian Islands. Edmondson  notes “a specimen was collected near [sic] Oahu nearly 100 years ago but, in so far as we know, there are no recent records from this locality.” It is an arboreal crab of coastal forests that is rarely encountered because of its secretive habits. It extends eastward to the Marshall and Tokelau Islands ,  (as Sesarma (Labuanium) gardineri). Finally, “Sesarma” trapezium Dana, 1852 is known from the holotype supposedly collected in the Hawaiian Islands , . Abele  considered the limited description to fit the west Atlantic Armases rubripes (Rathbun, 1897), a conclusion deemed premature by Bayer , but not easily resolved, because the type and only specimen has been lost.
Analysis of fossil species cannot take into account characters widely used in modern brachyuran phylogenetics (G1, G2, male abdomen, vulva, protection of penis, etc.). The following discrete characters were identified that serve to differentiate Geograpsus species and are discernible in the fossil material. The character states for each species are summarized in Table 5.
- Frontal margin of adult: a) straight, b) dorsally convex, c) ventrally convex
- Fourth thoracic sternite: a) largely glabrous/apunctate, b) mostly glabrous/few punctures, c) densely pubescent/punctate
- Lateral margin of 4th thoracic sternite: a) straight or convex, b) concave
- Anterior margin of 4th thoracic sternite: a) sinuous, b) markedly concave, c) straight to slightly concave
- Outer margin of exorbital angle: a) inturned, b) straight
- Intestinal region of carapace: a) grooved, b) smooth
- Merus of 4th pereopod: a) with distal half about same height as basal half, b) with distal half higher than basal half
- Inner surface of merus of 4th pereopod: a) vertically ridged, b) smooth except near upper margin
- Merus of 4th pereopod: a) wide, b) compressed
- Distal ventral margin of merus of 4th pereopod: a) not expanded, b) expanded
- Claw height: a) low (H/T~1.2), b) medium (H/T~1.4), c) high (H/T>1.5), d) very high (H/T>2)
- Cutting surface of fixed finger in adults: a) straight to slightly concave, b) convex
- Dorsal margin of claw: a) largely smooth, b) with fine granules, c) with coarse granules, d) with granules and teeth
- Lateral side of socket for articulation of chelar dactylus: a) grooved, b) jagged, c) smooth
- Ventral claw surface: a) single axial ridge of granules, b) scattered coarse granules, c) fine oblique ridges, d) coarse oblique ridges
- Inner face of fixed finger: a) with few or no hairs/punctae, b) with hairs/punctae in row or groove
- Sculpture on inner surface of palm: a) with strong ridging, b) smooth or with slight ridging, c) with patch of scaly ridges near base
- Inner, toothed flange of merus of cheliped: a) arcuate, b) angular
- Vertical ridge on inner face of cheliped merus: a) absent, b) without coarse granules at dorsal end, c) with one coarse granule at dorsal end, d) with several coarse granules at dorsal end
- Dorsal surface of cheliped carpus: a) with granules or ridges, b) nearly smooth
An exhaustive search on these characters using the criteria of maximum parsimony algorithm resulted in a single most parsimonious tree (Fig. 13, CI = 0.886, RI = 0.714). Eleven of the 20 characters scored were parsimony informative. The estimated phylogeny shows two clades within Geograpsus supported by bootstrap values >70%: G. lividus-G. stormi, and G. grayi-G. severnsi.
Distribution and ecology
Geograpsus severnsi was widespread among, but apparently endemic to, the Hawaiian Islands. Fossils are known from Hawai'i, Maui, O'ahu, and Kaua'i. Its sister species, G. grayi, ranges from the western Indian Ocean to the neighboring Line and Marshall Islands.
Geograpsus severnsi extended further inland than any other Geograpsus or other land crab in Oceania (see Table 2 for range of localities and elevations). Fossils are known from nearshore settings to 950 m elevation . Crab remains are abundant at 305 m elevation in the Pu'u Naio lava tube, Maui, located ca. 2 km inland. In the Pu'u Wa'awa'a area of Hawai'i, fossil “land-dwelling crabs were found from 120 to 3,160 feet elevation. Remains were most numerous, however, at about 500 feet elevation” . At 73 m elevation at Kiakeana Cave on Maui, remains of G. severnsi are common and co-occur with those of G. crinipes, indicating that like G. grayi, it overlapped in habitat with G. crinipes shoreward. The terrestriality of G. severnsi further supports its relation to G. grayi, the most terrestrial living grapsid.
It is unlikely that G. severnsi had the highly male-biased (8:1) sex ratio) observed among 4th thoracic sternites (N = 18); rather this suggests preservation bias. It is also unlikely that female 4th thoracic sternites would be less likely to be preserved under the same conditions as male sternites. Rather, the biased sex ratio suggests a difference in where males vs. females were most likely to molt or die. All oceanic land crabs rely on the sea for the development of larval stages, and females undertake coastal migrations to release larvae (e.g. ). These migrations as well as the larval release are risky, as they are exposed to a variety of predators first from land and sea, as well as the chance of getting washed away while releasing larvae . We suggest that this is the cause of the biased sex ratio: males, not having to leave the crevices where these deposits formed, tended to die there, whereas females more often died during reproductive migration, at or en route to the sea. Similarly biased sex ratio was observed as a result of reproductive migrations in the Ascension Island gecarcinids crab Johngarthia lagostoma . This implies that G. severnsi had a typical life history for the genus that included a marine larval stage. This provides evidence against the hypothesis that the extinction of G. severnsi was driven by a change toward an entirely terrestrial life history, a life history pattern that has evolved in some other terrestrial grapsoids , .
The occurrence and loss of Hawaiian land crabs has been noted, but the identity of the species previously remained unresolved , . All fossils examined were attributable to Geograpsus, most to G. severnsi, a few to G. crinipes. None of the fossils were attributable to other land crabs putatively recorded from the Hawaiian Islands. However the most deposits from which material was examined are located further inland that the habitat range of other potential species. Thus while Geograpsus species were clearly well represented in Hawai'i before human arrival, evidence for other land crabs remains equivocal.
There is little doubt that G. severnsi is extinct. The species is known only from the Hawaiian Islands, where it extended far inland. The terrestrial biota and ecosystems of the Hawaiian Islands are as well documented as that of any tropical archipelago , and no inland crabs have been recorded during historic times. In contrast the coastal G. crinipes, much less common in the fossil record than G. severnsi, is known from multiple historical specimens, although it appears to be quite rare today. The survival and even occurrence of G. stormi is the most poorly constrained.
Abundant Geograpsus fossils have been taken from two excavations with well-dated stratigraphic context, which were studied to document changes in the Hawaiian biota and landscape following human colonization: the Pu'u Naio lava tube on Maui  and the Māhā'ulepū Caves and Sinkhole on Kaua'i . Deposits at Pu'u Naio extend back to >7,750+/−500 BP across four major stratigraphic units. Unit I is youngest, corresponding roughly to historic times, Unit II dates from the Polynesian expansion, with humans arriving late in Unit III. Most of Units III and IV predate human colonization. The majority of the crab remains we studied are from Unit III, with a few from Unit IV. Cory Pittman (in litt. 11.IV.2004) quantified the abundance of crab fragments at Pu'u Naio and found the last fragments in the basal-most layer of Unit II. Thus at this site G. severnsi survived to, but disappeared rapidly after, human arrival. Burney et al. ,  came to a similar conclusion for Māhā'ulepū, where crabs are present in all pre-human layers, show a decrease in size during the early human period, and are absent from more recent strata.
G. severnsi appears to be the first documented crab extinction in the Holocene. IUCN's Red List (http://www.redlist.org/search/search-basic.html, accessed 10.IV.2004) records 7 crustacean species as historically extinct, all freshwater taxa. No terrestrial or marine crustaceans have been documented to have become extinct in historic times. That the first documented crab extinction is of a land crab in the Hawaiian Islands is not surprising. The Hawaiian terrestrial biota suffered a veritable mass extinction following human arrival, and this mass extinction continues today. Prehistoric extinctions following the human colonization have been documented in all terrestrial taxa with an appreciable fossil record. Thus over 50% of the Hawaiian bird fauna have gone extinct , . Some bird fossils are from the same deposits as the land crab remains reported on here , , . Predation by humans, introduced rats, pigs, dogs, and habitat destruction, especially of most of the lowland forests, have been implicated in prehistoric extinction of Hawaiian birds, and many additional agents of extinction, such as introduction of avian pox and avian malaria , are implicated in historic times , . Land snails also suffered catastrophic extinctions, again substantially accelerated during historical times , , .
Oceanic restriction of many land crabs suggests that they are especially vulnerable to continental predators. Although island land crabs remain understudied, they do appear to be more resilient than many other terrestrial taxa. Marine larval stages, wide dispersal capacity, and wide ranges provide rescue mechanisms against population extinction. In contrast, G. severnsi was a Hawaiian endemic, although its life history is not known. Marine larval stages have been lost in sesarmid crabs in Jamaica and SE Asia (e.g., , ). No grapsid crab is known to have evolved such abbreviated development, and the biased sex ratio observed suggests that G. severnsi also had marine larvae.
Although oceanic land crabs remain common on many Pacific islands, they appear to be frequently in decline, from a variety of causes. Some are sought after for food, with the very large and long-lived coconut crab most impacted by human predation , . Gecarcinids are also often heavily targeted, but at least some species appear to sustain considerable harvesting pressure (pers. obs.). Geograpsus species do not appear to be as favored for food as these other terrestrial decapods, and appear to be less commonly harvested  (pers. obs.). In the Cook Islands, there is superstition that “killing this crab in the house results in boils because the crab at this time is possessed by the spirit of an ancestor” . Yaldwyn & Wodzicki  note that in the Tokelaus G. crinipes “are eaten, but are reputed to cause constipation.”
Continental terrestrial predators, most likely mammals, appear to have an especially negative impact on land crabs. The recent introduction of black rats (Rattus rattus) to Clipperton Island has resulted in a rapid decline of the abundant Gecarcinus planatus there; the same crab suffered substantial decrease in abundance in the first half of the 20th century when feral pigs were introduced to (but subsequently eliminated from) the island , . Yaldwyn & Wodzicki  noted pigs and humans as the main predators on land crabs in the Tokelaus, where the introduced, but relatively benign, Pacific rat (Rattus exulans) was the only rat species present. A devastating loss of gecarcinid crabs is currently unfolding on Christmas Island (Indian Ocean) as a result of the spread of the invasive yellow crazy ant (Anoplolepis gracilipes), which readily kills crabs and completely clears areas of forest of these keystone animals . While Geograpsus remains common on many less-developed Pacific islands, on more impacted islands, such as Guam it appears to have declined. On Guam G. crinipes is now relatively uncommon, while we never saw G. grayi during the 1990's when we both lived on Guam, although it is known from neighboring, less-developed islands in the archipelago . Similarly, the nearshore land hermit crab Coenobita perlatus has become very uncommon on the main island of Guam, although it remains abundant on offshore Cocos Islet. It is noteworthy that both G. grayi and G. crinipes were recorded on Mañagaha Island, a small, sandy coral cay lying 2.5 km from Saipan, about a year after the eradication of rats and cats from the island. G. grayi has yet to be recorded from Saipan and G. crinipes is uncommon.
The agent of extinction for G. severnsi remains to be established, although the crab's demise is clearly associated with, and occurred rapidly after, the arrival of humans. Titcomb et al.  note that G. crinipes (pai'ea) was eaten by indigenous Hawaiians, so it is likely that G. severnsi was also. Considerable indigenous knowledge accumulates about land crabs on Pacific islands, with detailed understanding of their migration patterns, life cycles, habitat use, etc., and this information is used for harvesting these animals .
Polynesian colonists also introduced numerous animals and plants, including pigs, dogs, Pacific rats, jungle fowls, various lizards, insects, and land snails . Rats in particular are known to be important predators on island life , although only R. exulans arrived with native Hawaiians, and this species coexists with other Geograpsus (see above). Major alteration of especially lowland habitats also had devastating affects. Finally, Giffin  suggests that the disappearance of large sea bird rookeries, on which the crabs may have partly depended for food, may also be implicated in their extinction. However, the same package of introduced taxa and similar environmental problems were transported to other oceanic islands en route to Hawaii and are not known to have led to the extinction of Geograpsus or other land crabs there. The highly terrestrial G. grayi, the likely sister species of G. severnsi, remains common on many islands that have received the same suite of Polynesian introductions. Thus either some unusual combination of factors made pressure on land crabs greater in the Hawaiian Islands than elsewhere, and/or G. severnsi was especially vulnerable.
Macroevolutionary transitions to land
Macroevolutionary transitions between marine and non-marine habitats are uncommon and rarely lead to long-term success in the invaded habitat . Overall, decapod crustaceans have not been particularly successful on land. Nevertheless decapods have become terrestrial on numerous occasions: four families are represented among oceanic land crabs listed in Table 1, several other lineages have evolved onto land elsewhere, and many others show lesser degrees of terrestriality . So if land crabs have evolved so many times, what prevents them from becoming a major player in the terrestrial biome? Predation by terrestrial carnivores, especially vertebrates, is likely important in limiting their success, as are life history ties to the sea, at least during the initial stages of invasion , . Planktonic larval stages (zoeae and megalopae) are plesiomorphic for crabs, have rarely been lost in marine crabs, but have been lost in several freshwater/terrestrial lineages , . All land crabs in Oceania have marine larvae. Such life history limits dispersion inland, and likely makes crabs more vulnerable to terrestrial enemies because of the predictable, mass migrations they undertake to the coast for larval release. However, marine larvae also allow colonization of islands, where absence of many predators allows greater levels of ecological experimentation, and thus may be conducive to the evolution of increased terrestriality.
Life histories independent of the sea had evolved on fewer occasions than terrestriality in crabs. Aside from the lineage(s) of ancient, diverse “freshwater crabs” (i.e. Potamoidea, Pseudothelphosoidea, and Trichodactyloidea; ), non-marine, abbreviated life histories are known in the freshwater, west Pacific Trogloplacinae, freshwater-terrestrial, Indo-Malayan Geosesarma, several species of cave-dwelling Sesarmoides in Indonesia, and a remarkable radiation of sesarmid crabs in Jamaica  , . A noteworthy aspect of the Jamaican land crab radiation is that terrestriality evolved in situ, and only there within the Caribbean. Unlike other Greater Antilles, Jamaica is thought to have undergone partial or complete submergence, cleansing the island of most if not all continental taxa . This example demonstrates importance of islands in the origin of terrestriality in crabs. Presumably because of the imperfection of their macroevolutionary transition onto land, land crabs are ecologically important mostly on, and many species are limited to, oceanic islands, where continental predators and competitors (e.g. mammals, large reptiles) are absent. However a consequence of the evolution of fully terrestrial/freshwater life histories, as in this Jamaican sesarmid radiation, is that it may restrict crabs to the island they evolved on, rendering them evolutionary dead ends from a global perspective.
Adaptations for semi-terrestrial existence may also make it difficult for crabs to return to subtidal habitats; alternatively, intertidal habitats may be a safe place for lineages that have not faired well in more diverse, and biologically intense, subtidal settings. We are struck by the lack of free-living, subtidal representatives in the major intertidal-terrestrial brachyuran clades. The closely related (and potentially not reciprocally-monophyletic) Grapsoidea and Ocypodoidea include most intertidal and land crabs outside the “freshwater crabs”. While these crabs are diverse, abundant, and dominate in intertidal and coastal habitats, they are scarce in subtidal habitats with a few exceptions: the deep water Euchirograpsus, hot-spring associated Xenograpsus, a few Varunidae, and some species of Percnon and Macrophthalmus (e.g., , , ). Furthermore, these superfamilies are united with pea crabs (Pinnotheroidea) and coral gall crabs (Cryptochiroidea), both symbiotic crab families that live within their host, into the Thoracotremata . If the Thoracotremata is indeed monophyletic, it is remarkable that this diverse group has virtually no free-living shallow marine representatives. Intertidal, non-marine, deep water, and endo-symbiotic habitats are all “safe places” in the struggle for life, and may imply that survival (and diversification) of thoracotrematan crabs has been possible by their remarkable adaptability toward novel environment, rather than to an ability to compete in the face of biological pressures associated with the highly escalated shallow subtidal environment. Similar evolutionary lability, yet exclusion from “normal” shallow marine habitats are demonstrated by a few other taxa, for example the Neritomorpha among gastropods .
Ecological roles of land crabs
The importance of land crabs in the terrestrial ecology of tropical islands, particularly atolls has long been recognized. As noted by Hedley (in : 127–128, quoted in ): “The dominant note in the life of a coral atoll … struck me as the abundance and ubiquity of Crustacea. The Avifauna were but sea fowl, the indigenous Mammalia but rats, the Reptilia only a stray skink and gecko, while insects and land Mollusca … were barely represented. Into the vacant places swarmed Crustacea. Not an inch of the atoll world is secure from them.” The feeding habits of land crabs break down largely along taxonomic lines. Gecarcinids and many sesarmids are largely herbivorous/detritivorous (although with some tendency to omnivory, T. Naruse, pers. comm.), eating living and dead plant parts. Coenobitids (including Birgus) are omnivorous scavengers, feeding on vegetation, carrion, insects, etc. Geograpsus and the largely beach-restricted Ocypode are voracious carnivores/omnivores , , , .
Gecarcinids hold the record in terms of crab biomass per area, as they are large and often very abundant. On tiny Clipperton Island Gecarcinus planatus has reached population densities of 6 m−2 at times, literally reddening the island . Although this represents the largest population density recorded for land crabs , it may not be uncommon in undisturbed settings. Clipperton is the only island we are aware that lacked all terrestrial mammals at the time land crab censuses were taken. Thus these numbers are indicative of the potential abundance of land crabs on islands prior to human influence. Nevertheless the abundance of crabs has changed markedly over time even on this ~1.6 km2 island as a result of depredations by introduced mammals. Pigs were introduced in 1897 and proliferated, feeding heavily on the crabs. As a result Clipperton changed from virtually/completely unvegetated to having substantial plant cover, because the impact of crabs on the vegetation was reduced by pigs preying on crabs . Removal of pigs in 1958 led to major increase in crabs and loss of vegetation, only to be reversed again with the recent introduction of black rats, which again led to a rapid decline of gecarcinids and concomitant rebound of vegetation .
Lower, but still large numbers of crabs are known from other islands that harbor some introduced mammals. On Christmas Island (Indian Ocean), the large (500 grams), endemic Gecarcoidea natalis occurs at densities of >1/m2, for an estimated population size of 100 million crabs . They consume most accessible plant matter, including seeds, seedlings, and leaf litter, keeping the forest floor unusually clean and clear , , , , . The loss of this crab from areas as a result of crazy ant invasion has lead to a doubling of litter cover, 30-fold increase in density and 3.5-fold increase in diversity of seedlings . Gecarcinids are also important seed dispersers .
Several species of land crabs have been implicated as predators on bird chicks and eggs, and Atkinson  argues that land crabs may have made birds on tropical islands behaviorally more resilient to rats, than birds were on temperate islands, where land crabs are absent. Although a predominantly herbivorous omnivore , Birgus is known to prey on vertebrates, including tortoise and turtle hatchlings ,  and even rats . Coenobita have a broad diet, feeding on plants, carrion, insects and just about any available organic matter . Geograpsus species are also important predators. They have the largest claws among the Grapsidae, well adapted to raptorial feeding. They prey on coenobitids, other land crabs (including congeners), insects and birds , ,  (Fig. 12) (pers. obs.).
While sesarmids are relatively uncommon and/or small on Pacific islands, gecarcinids, Birgus, Coenobita, and Geograpsus are major ecological players in island ecosystems. However as noted above, the roles of these animals are quite different, ranging from largely herbivory with some omnivory (gecarcinids), through omnivory (coenobitids), to scavenging and carnivory (Geograpsus). While most islands in Oceania have all four taxa present, there is only reliable evidence for the prehistoric existence of Geograpsus in the Hawaiian Islands, and thus the role of crabs in Hawaii was likely limited accordingly. In this the Hawaiian Islands still differ from most other central Pacific islands, where gecarcinids and coenobitids are also abundant.
Materials and Methods
Fossil crab specimens were studied from collections assembled by Helen James & Storrs Olson (USNM), Mike Severns (Maui), David Burney (National Tropical Botanical Garden, Kaua'i), and their coworkers, and compared with the four known extant species of Geograpsus as represented in the collections of the American Museum of Natural History (AMNH), Bernice P. Bishop Museum, Honolulu (BPBM), Florida Museum of Natural History, University of Florida (UF), and US National Museum of Natural History (USNM). Chelae, carapace, and 4th sternite (Fig. 14) were measured in selected specimens, to develop meristic criteria that discriminate species. Twenty discrete characters were also identified and coded in each Geograpsus species and in Grapsus tenuicrustatus, representing the putative sister genus . Discrete character data were analyzed with PAUP v4.0, using maximum parsimony, with characters unweighted, character states unordered, with ACCTRAN character state optimization, treating multiple states as polymorphism, and running an exhaustive search. Bootstrap analysis with 10,000 replicates was used to evaluate clade robustness. Previous records of land crabs from the Hawaiian Islands were reviewed based on literature and selected specimen records.
This study was made possible by the wealth of fossil material collected and assembled by Mike Severns, David Burney, Cory Pittman, Storrs Olson, and especially Helen James. We thank Peter Davie, Lu Eldredge, Anne Fielding, Scott Godwin, John Hooper, Tohru Naruse, Peter Ng, Cory Pittman, and Chela Zabin for information on land crabs and Hawaiian records, Cory Pittman for sharing data on the occurrence of the crabs at Pu'u Naio, and Peter Castro, Helen James, Tohru Naruse, and Storrs Olson for comments. Mandy Etpison kindly allowed us to reproduce her photograph of a predatory G. crinipes.
Analyzed the data: GP JS. Contributed reagents/materials/analysis tools: GP. Wrote the paper: GP JS.
- 1. Carlquist S (1974) Island biology. New York: Columbia University Press.
- 2. Paulay G,Meyer C (2002) Diversification in the tropical Pacific: comparisons between marine and terrestrial systems and the importance of founder speciation. Integrative & Comparative Biology 42: 922–934.
- 3. Zimmerman EC (1948) Insect of Hawaii. Volume 1. Introduction. Honolulu, Hawaii: University of Hawaii Press.
- 4. Wilson EO,Taylor RW (1967) The ants of Polynesia (Hymenoptera, Formicidae). Pacific Insects Monographs 14: 1–109.
- 5. Wetterer JK (2006) Ants (Hymenoptera: Formicidae) of Niue, Polynesia. Pacific Science 60: 413–416.
- 6. Vermeij GJ (1987) Evolution and escalation, an ecological history of life. Princeton NJ: Princeton University Press.
- 7. Paulay G (1994) Biodiversity on oceanic islands: its origin and extinction. American Zoologist 34: 134–144.
- 8. Steadman DW (2006) Extinction and biogeography of tropical Pacific birds. Extinction and biogeography of tropical Pacific birds 1–480.
- 9. Hadfield MG (1986) Extinction in Hawaiian achatinelline snails. Malacologia 27: 67–81.
- 10. Murray J,Murray E,Johnson MS,Clarke B (1988) The extinction of Partula on Moorea. Pacific Science 42: 150–153.
- 11. Paulson DR,Buden DW (2003) The Odonata of Pohnpei, Eastern Caroline Islands, Micronesia. International Journal of Odonatology 6: 39–64.
- 12. Jordan S,Simon C,Polhemus D (2003) Molecular systematics and adaptive radiation of Hawaii's endemic damselfly genus Megalagrion (Odonata: Coenagrionidae). Systematic Biology 52: 89–109.
- 13. Montgomery SL (1982) Biogeography of the moth genus Eupithecia in Oceania and the evolution of ambush predartion in Hawaiian caterpillars (Lepidoptera: Geometridae). Entomologia Generalis 8: 27–34.
- 14. Rosenberg G (1996) Independent evolution of terrestriality in Atlantic truncatellid gastropods. Evolution 50: 682–693.
- 15. Schubart CD,Diesel R,Hedges SB (1998) Rapid evolution of terrestrial life in Jamaican crabs. Nature 393: 363–365.
- 16. Carson HL (1983) Chromosomal sequences and interisland colonizations in Hawaiian Drosophila. Genetics 103: 465–482.
- 17. Grant PR,Grant BR (2007) How and why species multiply: The radiation of Darwin's finches. Princeton NJ: Princeton University Press. 272 p.
- 18. Solem A (1979) Biogeographic significance of land snails, Paleozoic to Recent. In: Gray J,Boucot AJ, editors. Historical biogeography, plate tectonics, and the changing environment. Corvallis, OR: Oregon State University Press. pp. 277–287.
- 19. Abbott RT (1960) The genus Strombus in the Indo-Pacific. Indo-Pacific Mollusca 1: 33–146.
- 20. George RW (1974) Coral reefs and rock lobster ecology in the Indo-West Pacific region. Proceedings of the Second International Coral Reef Symposium, Brisbane 1: 321–325.
- 21. Malay MCD,Paulay G (2010) Peripatric speciation drives diversification and distributional pattern of reef hermit crabs (Decapoda: Diogenidae: Calcinus). Evolution 64: 634–662.
- 22. Springer VG (1982) Pacific plate biogeography, with special reference to shorefishes. Smithsonian Contributions to Zoology 367: iv + 182.
- 23. Kay EA (1984) Patterns of speciation in the Indo-West Pacific. In: Radovsky FJ,Raven PH,Sohmer SH, editors. Biogeography of the tropical Pacific. pp. 15–31. Bishop Museum Special Publication No. 72: Honolulu.
- 24. Paulay G (1997) Diversity and distribution of reef organisms. In: Birkeland CE, editor. Life and death of coral reefs. New York: Chapman & Hall. pp. 298–353.
- 25. Williams ST,Reid DG (2004) Speciation and diversity on tropical rocky shores: A global phylogeny of snails of the genus Echinolittorina. Evolution 58:
- 26. Hartnoll RG (1988) Evolution, systematics, and geographical distribution. In: Burggren WW,McMahon BR, editors. Biology of land crabs. Cambridge: Cambriudge University Press. pp. 6–54.
- 27. ABIF (2004) Australian Biodiversity Information Facility. accessed 12 May 2004. http://www.deh.gov.au/biodiversity/abrs/online-resources/abif/index.html.
- 28. Dai A,Yang S (1991) Crabs of the China Seas. Beijing, Berlin: China Ocean Press, Springer Verlag.
- 29. Sakai T (1976) Crabs of Japan and the adjacent seas. Tokyo: Kodansha.
- 30. Innocenti G,Vannini M (2007) The first record of the land crab, Discoplax rotunda (Quoy & Gaymard, 1824) (Decapoda, Brachyura, Gecarcinidae) from East Africa: The problem of the island species. Crustaceana (Leiden) 80: 635–637.
- 31. Türkay M (1974) Die Gecarcinidae Asiens und Ozeaniens (Crustacea: Decapoda). Senckenbergiana Biologica 55: 223–259.
- 32. Whitelegge T (1897) The Crustacea of Funafuti. Australian Museum Memoir 3: 127–151, pls. VI–VII.
- 33. Atkinson IAE (1985) The spread of commensal species of Rattus to oceanic islands and their effects on island avifaunas. International Council for Bird Preservation Technical Publication 35–81.
- 34. Green PT,O'Dowd DJ,Lake PS (1997) Control of seedling recruitment by land crabs in rain forest on a remote oceanic island. Ecology 78: 2474–2486.
- 35. O'Dowd DJ,Green PT,Lake PS (2003) Invasional ‘meltdown’ on an oceanic island. Ecology Letters 6: 812–817.
- 36. Pitman RL,Ballance LT,Bost C (2005) Clipperton Island: Pig sty, rat hole and booby prize. Marine Ornithology 33: 193–194.
- 37. Howarth FG (1990) Hawaiian terrestrial arthropods: an overview. Bishop Museum Occ Papers 30: 4–26.
- 38. Banerjee SK (1960) Biological results of the Snellius Expedition. XVIII. The genera Grapsus, Geograpsus and Metopograpsus (Crustacea, Brachyura). Temminckia 10: 132–199.
- 39. Giffin JG (2003) Pu'u Wa'a Wa'a biological assessment. Pu'u Wa'a Wa'a, North Kona, Hawaii. State of Hawaii Department of Land and Natural Resources, Division of Forestry and Wildlife ii + 92.
- 40. Burney DA,James HF,Burney LP,Olson SL,Kikuchi W,et al. (2001) Fossil evidence for a diverse biota from Kaua'i and its transformation since human arrival. Ecological Monographs 71: 615–641.
- 41. Burney DA,Kikuchi WKP (2006) A millennium of human activity at Makauwahi Cave, Maha Ulepu, Kaua'i. Human Ecology 34: 219–247.
- 42. Dana JD (1851) Conspectus crustaceorum quae in orbis terrarum circumnavigatione, Carolo Wilkes e classe Reipublicae Foederatae Duce, lexit et descripsit J. D. Dana. Crustacea Grapsoidea, (Cyclometopa, Edwardsii). Proceedings of the Academy of Natural Sciences of Philadelphia 5: 247–254.
- 43. Dana JD (1852) Crustacea, Part I. United States Exploring Expedition, During the Years 1838, 1839, 1840, 1841, 1842, under the Command of Charles Wilkes, U.S.N. Philadelphia: C. Sherman.
- 44. Kingsley JS (1880) Synopsis of the Grapsidae. Carcinological notes, no. IV. Proceedings of the Academy of Natural Sciences of Philadelphia 32: 187–224.
- 45. Rathbun MJ (1906) The Brachyura and Macrura of the Hawaiian Islands. Bulletin of the United States Fish Commission 23: 829–930, pls. 821–824, text-figs. 821–879; 1903.
- 46. Edmondson CH (1946) Reef and shore fauna of Hawaii. Honolulu: Bernice P. Bishop Museum.
- 47. Edmondson CH (1959) Hawaiian Grapsidae. Occasional Papers of the Bernice Pauahi Bishop Museum 22: 153–202.
- 48. Titcomb M,Fellows DB,Pukui MK,Devaney DM (1978) Native use of marine invertebrates in Old Hawaii. Pacific Science 32: 325–386.
- 49. Godwin S,Bolick H (2006) Inventory of intertidal and shallow subtidal marine invertebrates at Kalaupapa National Historic Park, Moloka'i, Hawai'i. Final Report. Honolulu: Bishop Museum. 58 p.
- 50. Garth JS (1973) The brachyuran crabs of Easter Island. Proceedings of the California Academy of Sciences, Fourth Series 39: 311–336.
- 51. Grubb P (1971) Ecology of terrestrial decapod crustaceans on Aldabra. Philosophical Transactions of the Royal Society of London 260 B: 411–416.
- 52. Hicks J,Rympff H,Yorkston H (1990) Christmas crabs. 2nd ed. Christmas Island: Christmas Island Naturas History Association.
- 53. Alexander HGL (1979) A preliminary assessment of the rôle of the terrestrial decapod crustaceans in the Aldabran ecosystem. Philosophical Transactions of the Royal Society of London 286B: 241–246.
- 54. Etpison M (2004) Palau: Natural History. Koror, Palau: Tkel Corporation. 272 p.
- 55. Ng PKL,Guinot D,Davie PJF (2008) Systema brachyurorum: part I. Annotated checklist of the extant brachyuran crabs of the world. Raffles Bulletin of Zoology Supplement 17: 1–286.
- 56. Ng PKL,Liu H-C (1999) The taxonomy of Sesarma tangi Rathbun, 1931 and S. stormi De Man, 1895 (Crustacea: Decapoda: Brachyura: Grapsidae: Sesarminae), with establishment of a new genus for S. stormi. Zoological Studies 38: 228–237.
- 57. Edmondson CH (1962) Hawaiian Crustacea: Goneplacidae, Pinnotheridae, Cymopoliidae, Ocypodidae, and Gecarcinidae. Occasional Papers of Bernice P Bishop Museum 23: 1–27.
- 58. Poupin J (1998) Crustacea Decapoda and Stomatopoda of French Polynesia (Dendrobranchiata, Stenopodidea, Caridea, Thalassinidea, and Stomatopoda, with additions to Astacidea, Palinuridea, Anomura, and Brachyura). Atoll Research Bulletin 451: i–iv.1–62
- 59. De Man JG (1889) Ueber einige neue oder seltene indopacifische Brachyuren. Zoologische Jahrbücher Abteilung für Systematik 4: 409–452.
- 60. Marquet G (1991) Freshwater crustaceans of French Polynesia: Taxonomy, distribution and biomass (Decapoda). Crustaceana 61: 125–140.
- 61. Tesch JJ (1917) Synopsis of the genera Sesarma, Metasesarma, Sarmatium and Clistocoeloma, with a key to the determination of Indo-Pacific species. Zoologische Mededelingen 3: 127–260.
- 62. Holthuis LB (1953) Enumeration of the decapod and stomatopod Crustacea from Pacific coral islands. Atoll Research Bulletin 24: 1–66, Maps 61–62.
- 63. Yaldwyn JC,Wodzicki K. (1979) Systematics and ecology of the land crabs (Decapoda: Coenobitidae, Grapsidae and Gecarcinidae) of the Tokelau Islands, central Pacific. Atoll Research Bulletin 235: 1–58.
- 64. Abele LG (1974) Sesarma trapezium Dana, 1852 (Crustacea: Decapoda): proposed suppression under the plenary powers Z.N.(S.) 2016. Bulletin of Zoological Nomenclature 31: 49–50.
- 65. ICZN (1979) Opinion 1140 Sesarma rubripes Rathbun, 1897 (Crustacea Decapoda) given precedence over Sesarma trapezium Dana, 1852, under the plenary powers. Bulletin of Zoological Nomenclature 36: 119–121.
- 66. Liu H-C,Jeng M-S (2005) Reproduction of Epigrapsus notatus (Brachyura: Gecarcinidae) in Taiwan. Journal of Crustacean Biology 25: 135–140.
- 67. Hartnoll RG,Broderick AC,Godley BJ,Saunders KE (2009) Population Structure of the Land Crab Johngarthia lagostoma on Ascension Island. Journal of Crustacean Biology 29: 57–61.
- 68. Eldredge LG,Evenhuis NL (2003) Hawaii's biodiversity: a detailed assessment of the numbers of species in the Hawaiian Islands. Bishop Museum Occasional Papers 76: 1–28.
- 69. James HF,Olson SL (1991) Descriptions of thirty-two new species of birds from the Hawaiian Islands: Part II. Passeriformes. Ornithological Monographs 46: 1–88.
- 70. Olson SL,James HF (1991) Descriptions of thirty-two new species of birds from the Hawaiian Islands: Part I. Non-Passeriformes. Ornithological Monographs 45: 1–88.
- 71. James HF,Stafford TW Jr,Steadman DW,Olson SL,Martin PS,et al. (1987) Radiocarbon dates on bones of extinct birds from Hawaii. Proceedings of the National Academy of Sciences 84: 2350–2354.
- 72. Warner RE (1968) The role of introduced diseases in the extinction of the endemic Hawaiian avifauna. Condor 70: 101–120.
- 73. Olson SL,James HF (1982) Fossil birds from the Hawaiian Islands: evidence for wholesale extinction by man before western contact. Science 217: 633–635.
- 74. Christensen CC,Kirch PV (1986) Nonmarine mollusks and ecological change at Barbers Point, O'ahu, Hawai'i. Bishop Museum Occasional Papers 26: 52–80.
- 75. Diesel R,Schubart CD,Schuh M (2000) A reconstruction of the invasion of land by Jamaican crabs (Grapsidae: Sesarminae). Journal of Zoology 250: 141–160.
- 76. Amesbury SS (1980) Biological studies on the coconut crab (Birgus latro) in the Mariana Islands. University of Guam Marine Laboratory, Technical Report 66: 39.
- 77. Wolcott TG (1988) Ecology;. In: Burggren WW,McMahon BR, editors. pp. 55–96.
- 78. McCormack G (2007) Cook Islands Biodiversity Database, Version 2007.2. Available: http://cookislands.bishopmuseum.org. Rarotonga, Cook Islands: Cook Islands Natural Heritage Trust.
- 79. Sachet MH (1962) Geography and land ecology of Clipperton Island. Atoll Research Bulletin 86: 1–115.
- 80. Paulay G,Kropp R,Ng P,Eldredge L (2003) The crustaceans and pycnogonids of the Mariana Islands. Micronesica 35–36: 456–513.
- 81. Foale S (1999) Local ecological knowledge and biology of the land crab Cardisoma hirtipes (Decapoda: Gecarcinidae) at West Nggela, Solomon Islands. Pacific Science 53: 37–49.
- 82. Kirch PV (1982) The impact of prehistoric polynesians on the Hawaiian ecosystem. Pacific Science 36: 1–14.
- 83. Vermeij GJ,Dudley R (2000) Why are there so few evolutionary transitions between aquatic and terrestrial ecosystems? Biological Journal of the Linnean Society 70: 541–554.
- 84. Anger K (1995) The conquest of freshwater and land by marine crabs: adaptations in life-history patterns and larval bioenergetics. Journal of Experimental Marine Biology and Ecology 193: 119–145.
- 85. Yeo DCJ,Ng PKL,Cumberlidge N,Magalhaes C,Daniels SR,et al. (2008) Global diversity of crabs (Crustacea: Decapoda: Brachyura) in freshwater. Hydrobiologia 595: 275–286.
- 86. Hedges SB (1996) Historical biogeography of West Indian vertebrates. Annual Review of Ecology and Systematics 27: 163–196.
- 87. Naruse T,Kosuge T (2008) A new species of Macrophthalmus (Crustacea: Decapoda: Brachyura: Macrophthalmidae) from Iriomote Island, Ryukyu Islands, Japan. Species Diversity 13: 117–122.
- 88. Naruse T,Clark PF (2009) Establishment of a new genus for Asthenognathus gallardoi Serene & Soh, 1976 within Gaeticinae Davie & N.K. Ng, 2007 (Crustacea: Decapoda: Brachyura: Varunidae). Zootaxa 1987: 61–68.
- 89. Holthuis BV (1995) Evolution between marine and freshwater habitats: a case study of the gastropod suborder Neritopsina. Seattle: University of Washington.
- 90. Ehrhardt JP,Niaussat P (1970) Ecologic et physiologic du brachyoure terrestre Gecarcinus planatus Stimpson (d'apres les individus de l'atoll de Clipperton). Bulletin de Societé Zoologique de France 95: 41–54.
- 91. Green PT (1997) Red crabs in rain forest on Christmas Island, Indian Ocean: activity patterns, density and biomass. Journal of Tropical Ecology 13: 17–38.
- 92. Green PT,Lake PS,O'Dowd DJ (1999) Monopolization of litter processing by a dominant land crab on a tropical oceanic island. Oecologia 119: 435–444.
- 93. O'Dowd DJ,Lake PS (1989) Red crabs in rain forest, Christmas Island: removal and relocation of leaf-fall. Journal of Tropical Ecology 5: 337–348.
- 94. O'Dowd DJ,Lake PS (1990) Red crabs in rain forest, Christmas Island: differential herbivory of seedlings. Oikos 58: 289–292.
- 95. O'Dowd DJ,Lake PS (1991) Red crabs in rain forest, Christmas Island: removal and fate of fruits and seeds. J Tropical Ecol 7: 113–122.
- 96. Lee MAB (1985) The dispersal of Pandanus tectorius by the land crab Cardisoma carnifex. Oikos 45: 169–173.
- 97. Kolinski SP (1994) Chelonia mydas (green turtle). Predation. Herpetological Review 25: 120.
- 98. Kessler C (2005) Observation of a coconut crab, Birgus latro (Linnaeus, 1767) predation on a Polynesian rat, Rattus exulans (Peale, 1848). Crustaceana (Leiden) 78: 761–762.
- 99. Schubart CD,Cuesta JA,Diesel R,Felder DL (2000) Molecular phylogeny, taxonomy, and evolution of nonmarine lineages within the American grapsoid crabs (Crustacea: Brachyura). Molecular Phylogenetics and Evolution 15: 179–190.