All introduced ampullariids in the continental U.S. fell into five well-supported clades based on analysis of the 46 unique mtDNA haplotypes (Fig. 1). Based on comparison with native-range samples and type material, and knowledge of type localities (see below), these clades represented three apple snail species with channeled sutures (Pomacea insularum, Pomacea canaliculata, and Pomacea haustrum), and, also, Pomacea diffusa and Marisa cornuarietis. Pomacea canaliculata was strongly supported as sister to P. insularum, with Pomacea paludosa robustly supported as sister to these two species.

Discrete P. haustrum and P. diffusa clades formed a clade that was sister to the P. insularum, P. canaliculata, and P. paludosa clade. The position of Pomacea camena was not as robustly supported and varied among gene regions analyzed. Marisa cornuarietis haplotypes formed a well-supported monophyletic clade that was sister to a clade of Marisa planogyra and Asolene spixii, indicating that Marisa is not monophyletic.

Of the three apple snail species with channeled sutures in the continental U.S., Pomacea canaliculata occurred only in California and Arizona, P. insularum occurred in Texas, Georgia, and Florida, and P. haustrum was restricted to Florida.

Our results indicated that: 1) South American Pomacea were not monophyletic and 2) apple snails with channeled sutures were not monophyletic. This latter result is perhaps not surprising. The shells of many Pomacea species are similar in overall shape; unadorned spirally coiled tubes with overlapping whorls that do not depart appreciably from the axis of coiling. Given these general constraints, simple changes in the rate of shell whorl expansion and translation down the axis of coiling will affect the degree of overlap of shell whorls, and consequently the degree of channelling of the suture. The degree of channeling may also be affected by changes in the cross-sectional shape of the whorl. Convergence in channeled shells is thus not unexpected among the fifty or so species within the genus Pomacea.

Our results indicate that five species of non-native ampullariids have been introduced to the continental U.S. Below, we assess their probable geographic origins, the timing of their initial introductions, their spread, and current distribution. We conclude with an assessment of the risks to environments, native species, agriculture, and human health that these species pose.

Pomacea haustrum is currently of relatively minor concern in the U.S., given its failure to spread beyond Palm Beach County after 30 years or more in Florida. It should be noted, however, that many species have maintained limited distributions, sometimes for decades, before becoming invasive 36. Pomacea diffusa has generally been assumed also to pose little threat in the U.S. and it is the only apple snail for which interstate transport is permitted. This lack of concern may be unwarranted. The U.S. Department of Agriculture considered it (as P. bridgesii) to be innocuous 37, presumably based on a study that concluded that it feeds primarily on aufwuchs, not macrophytes 38. The potential effects of Pomacea diffusa in natural habitats are unknown, but a conflicting study reports that, in addition to macrophytes, it will feed readily on animal carcasses, live worms, and the eggs of planorbid snails 39. It may therefore have direct effects on both aquatic vegetation and native snails and compete for food with native scavengers such as crayfish, shrimp, and fish.

Pomacea insularum and P. canaliculata pose the greatest threat to agriculture and native wetland ecosystems in the U.S. One of the better predictors of the effect of an invasive species is the effect of the species or related species in other areas where it has been introduced 40. The potential of P. canaliculata has been clearly demonstrated in Southeast Asia where its introduction into a tropical wetland ecosystem in Thailand resulted in dramatic changes in biodiversity and ecosystem functioning 134142, and by its devastating effects on agriculture, especially wetland rice production 456. Currently, the occurrence of P. canaliculata has been confirmed in California and Arizona in the continental U.S. However, it has the potential to spread into other areas, including the rice-growing parts of California, where it could cause serious damage.

Some of the ecological and agricultural impacts in Asia associated with P. canaliculata are almost certainly attributable to Pomacea insularum. This species is also widespread in the region [2743, K.A. Hayes, R.C. Joshi, S.C. Thiengo, and R.H. Cowie, in prep.; see below], but has not been explicitly acknowledged as a serious pest because of the confusion in identification of these two species, with most of the literature referring to P. canaliculata. Pomacea insularum may therefore be likely to have a significant impact on aquatic ecosystems and pose a threat to crops in the southeastern U.S. 10, particularly given the potential for it to spread through parts of Alabama, Mississippi, Louisiana and Texas.

The match of introduced haplotypes of P. canaliculata and P. insularum to native Argentinean samples from approximately 35°S suggests that the introduced populations of these species may be cold tolerant and capable of surviving occasional frosts. Moreover, P. canaliculata occurs as far as 38–39°S, and topography rather than climate may set the natural southern limit of this species 4445. The average minimum monthly temperature in Buenos Aires is 4–6 degrees Celsius (39–43 degrees Fahrenheit) from May to September, slightly lower than the average minimum winter monthly temperatures in Charleston, South Carolina. Consequently, P. insularum could potentially spread at least this far north on the Atlantic Coastal Plain, and through parts of Alabama, Mississippi, Louisiana, and Texas on the Gulf Coastal Plain. Similarly, P. canaliculata may be able to spread from its current introduced locations in California at least as far north as San Francisco. Ecological niche modeling based on the native and introduced range of these species [e.g. 46] will permit a more refined estimate of potential introduced ranges. An important caveat here is that reports of the native ranges of these two species may be commingled.

P. insularum also poses threats for the native apple snail, Pomacea paludosa, and the species that rely on it for food. Pomacea paludosa is recognized by its size (40–70 mm height), low spire, absence of a channel at the suture, and distinctive egg masses 8. Mature egg masses have an average of thirty round pale pink to white eggs averaging 4 mm in size in grape-like clusters 47 (Fig. 3d), although when freshly laid, the eggs are pale orange salmon colored and in a thick mucus matrix (Fig. 11). Those planning control measures aimed at non-native apple snails in Florida must ensure they have not inadvertently targeted the native apple snails or their eggs.

In addition to collateral damage from control of non-native species, "extinction by hybridization" 48 could result from hybridization of P. paludosa with non-native species, which seems possible given the close phylogenetic relationship of P. insularum and P. paludosa. There is also the possibility of competitive interactions between native and non-native snails 49. Introduced Pomacea spp. have been reported to consume the eggs of both congenerics and other snails and invertebrates 395051. We have anecdotally noted a decline in abundance or the apparent disappearance of P. paludosa following introduction of P. insularum (Collins and Rawlings, pers. obs.). Pomacea paludosa is the primary food of the endangered Everglade Snail Kite 52, and an important food for other birds, including the limpkin, as well as fish, turtles, and alligators. At Lake Tohopekaliga (Collins and Rawlings, pers. obs.), limpkins are routinely taking P. insularum for food.

Finally, introduction of all non-native ampullariids is a concern because of the suite of associated parasites and their potential effects on apple snail predators and humans. We know nothing at present about the parasites of introduced ampullariids in the continental U.S. Ampullariids, including Pomacea canaliculata, are intermediate hosts of important vertebrate parasites 53, most notably nematodes in the genus Parastrongylus (=Angiostrongylus). Parastrongylus cantonensis causes eosinophilic meningoencephalitis 54, and P. costaricensis causes abdominal angiostrongyliasis in humans 55. Transmission of Parastrongylus infections to mammalian hosts requires development to the L3 larval stage in an intermediate gastropod host. The spread of Pomacea species may therefore facilitate the spread of Parastrongylus species by completing the life cycle required to infect mammalian hosts. In Beijing, China, consumption of snails identified as Pomacea canaliculata resulted in 131 cases of human Parastrongylus cantonensis infection during a 4-month period 56. Parastrongylus cantonensis and/or P. costaricensis are established in Florida and Louisiana 55575859, so the potential interaction of Pomacea insularum with Parastrongylus species is a concern.

We sampled native Pomacea paludosa in Florida and non-native apple snails in Florida, Georgia, Texas, California, Arizona, Hawaii, Cuba, and Guadeloupe in the Lesser Antilles [see Additional file 1]. These included taxa identified as Pomacea canaliculata or Pomacea canaliculata-group, Pomacea bridgesii, Pomacea haustrum, Marisa cornuarietis, Pila conica and Pila polita. We also sampled native-range populations of Pomacea canaliculata-group snails, Pomacea haustrum, Pomacea diffusa, Pomacea camena, Asolene spixii, Marisa planogyra, and Pila polita. Pila conica was used as an outgroup for phylogenetic analyses 6061. Specimens were also obtained from the Bishop Museum (Honolulu, BPBM), Field Museum of Natural History (Chicago, FMNH), Florida Museum of Natural History (Gainesville, FLMNH), the Muséum National d'Histoire Naturelle (Paris, MNHN), and the Natural History Museum (London, BMNH) for both molecular and morphological comparisons.

DNA was isolated from ~50 mg of tissue using standard phenol/chloroform methods 62, or Qiagen's Dneasy extraction kit. The polymerase chain reaction (PCR) was used to amplify two portions of the mitochondrial genome. The first consisted of ~1,900 nucleotides spanning the 3'end of the 12S rRNA, the intervening tRNA valine and the 5'end of the 16S rRNA. This region was amplified in two overlapping portions using the primers 12Sai [5'-AAACTAGGATTAGATACCCTATTAT-3'; 63] with 16Srgast [5'-GCCATGATGCAAAAGGTAC-3'], and 12Sf [5'-GCACACATCGCCCGTCGCTCT-3'; reverse complement of 12Sb' in 63] with 16SbrH-alt [5'-CCGGTCTGAACTCAGATCATGT-3'; slight modification of 16Sbr in 63]. The second region was a ~658 nucleotide portion of the cytochrome c oxidase subunit I (COI) gene amplified using slightly degenerate versions of standard primers 64. Reactions were performed in a MJ Research PTC-200 thermal cycler in 50 μl volumes with 1.5 mM MgCl₂, each dNTP at 200 micromolar, 10–100 nanograms of genomic DNA, and 1X Promega buffer B, and 1 U of Taq polymerase (Promega, Madison, Wisconsin). PCR products were purified with a GeneClean III Kit (Bio 101, Carlsbad, California), and cycle-sequenced with Big Dye version 3.1 chemistry following the manufacturer's protocol (PE-ABI). Sequencing reactions were analyzed on an ABI Prism 3100 Genetic Analyzer. All samples were sequenced on both strands and sequences have been deposited in GenBank: rRNAs [GenBank: EF519073–EF519181, AY449500] and COI [GenBank: EF514942–EF515081].

COI sequences were generated for 141 snails. The 12S-16S region was sequenced for representatives of each unique COI haplotype and locality combination, for a data set of 108 individuals. For some specimens, primarily museum specimens, amplification did not work for all gene regions, and different gene regions failed to amplify in different snails, resulting in snails with no sequence in common. This resulted in significant degradation of support values. We therefore selected the 95 individuals with both gene regions completely sequenced, representing 46 unique haplotypes, for the among-species phylogenetic analysis. Nevertheless, some individuals with a great deal of missing data were important for matching introduced haplotypes to native ranges, and were therefore used for within-species analyses and haplotype networks.

COI sequences were aligned at the amino-acid level and back aligned to nucleotides without indels in MacClade 65. The rRNA sequences were aligned using T-Coffee 66 on the IGS server with default settings 67. We tested alignment sensitivity by repeating phylogenetic analyses on a data set in which ambiguously aligned regions were removed by excluding positions in each direction until we came to nucleotides that were invariant in all taxa in the analysis 68.

We used maximum parsimony and Bayesian methods for phylogenetic analyses. Maximum parsimony bootstrap analyses were performed using PAUP* 4.0b10 69 with equal weighting, uninformative characters excluded, and gaps treated as missing data. Three hundred bootstrap replicates with 10 random sequence additions per replicate (RSAs) and TBR branch swapping were performed using the heuristic search option. We used the Akaike Information Criterion (AIC) to select the most appropriate model of sequence evolution using Modeltest 3.07 70. Results indicated that the 12S-16S sequence and the intervening tRNA sequence could be combined in one partition. The COI sequence was divided into 3 partitions by codon position. The parameters determined by Modeltest were used to specify the models of sequence evolution, and as priors for the Bayesian analyses, which were performed using MRBAYES 3.1.2 71. The prior distributions for the Bayesian analyses were as follows: topology uniform; branch lengths exponential with parameter = 10.0; gamma shape parameter exponential with parameter = 5; proportion invariant sites uniform over the interval (0, 1); and substitution rate matrix and base frequencies Dirichlet with starting values from Modeltest. We employed 4 Markov chains for 3–6 million generations and the partition-specific models described. Trees were sampled every 100th generation, discarding the first 33% of sampled trees as burn-in. We initiated two simultaneous runs from different random starting trees, and convergence was inferred when the average standard deviation of split frequencies approached 0.01, and the potential scale reduction factor for all parameters approached 1.0.

To explore further the relationships among introduced haplotypes of P. insularum from Florida, Texas, Georgia, and native-range populations, we performed a statistical parsimony analysis using TCS [version 1.20, 72]. We included 48 individuals based on the results of phylogenetic analyses (below). Some museum specimens did not amplify for all regions, resulting in significant missing data for a few individuals. Because missing data may cause problems related to calculated distances and collapsing of haplotypes in the program TCS, we eliminated characters with missing data or individuals with excessive missing data, and performed the TCS analysis based on 1781 nucleotides for which there are no missing data, with a parsimony limit of 90%.