Subfamilies Acridinae, Gomphocerinae and Oedipodinae are "fuzzy sets": a proposal for a common African origin.
Previously, we described evolutionary and biogeographic relationships among selected genera within the subfamilies Gomphocerinae (Contreras et al. 2006) and Oedipodinae (Fries et al. 2007). Phylogenetic analyses of mitochondrial DNA sequences led us to conclude, provisionally, that each subfamily was monophyletic and that most tribes, as listed in the Orthoptera Species File 2, or OSF2 (Eades et al. 2011), were polyphyletic. Lacking in those studies was a sufficient sampling of the Acridinae, a subfamily possessing several morphological features that overlap those of the other two subfamilies. The inclusion of this group could have further supported, or challenged, our claims of subfamilial monophyly.
Currently, the OSF2 recognizes Acridinae, Gomphocerinae and Oedipodinae as legitimate subfamilies. Truxalinae, formerly considered a bona fide subfamily, has been subsumed within the Acridinae (Jago 1996, OSF2). Not that long ago, different subsets of these four groups were collapsed into single subfamilies. To cite a few examples: both gomphocerines and acridines--the so-called "slantheads"--formed the Acridinae (Bei-Bienko & Mishchenko 1951, Brooks 1958, Rehn 1958); acridines and oedipodines were combined within the Acridinae, with gomphocerines and truxalines placed within the Truxalinae (Dirsh 1965). Jago (1971, 1996a) provided a good account of the early history of the different taxonomic systems. More recently, Rentz et al. (2004), following Key (1993) and to some extent Rehn above, took a different view, maintaining that the amount of anatomical overlap between Acridinae and Oedipodinae (both sensu OSF2) is simply too great to accord them subfamily status; instead, each was downgraded to tribe within a larger, redefined, Acridinae. Otte (1981, 1984) did recognize the existence ofcertain annectant genera, such as Stethophyma, Melanotettix and Machaerocera. Nonetheless, each was assigned to a subfamily in his books; these placements have since been incorporated into the OSF2. Otte (1981) also regarded Acridinae as polyphyletic, owing to the ease with which stridulatory pegs, a trait commonly used to separate Gomphocerinae (pegs present) from Acridinae (pegs missing), could be lost (see also Jago 1996a). The borders separating these major groups still remain fuzzy and the question of their integrity and of their inter-relationships is far from resolved.
Our earlier studies also made inferences about the biogeographic origins of Gomphocerinae and Oedipodinae, primarily of their northern taxa. In both cases we proposed that North American genera had arisen from ancestors migrating from Eurasia. For the Oedipodinae (Fries et al. 2007), there was also some indication of more recent migrations from Eurasia to Australia and Africa. Vickery (1987, 1989) had made similar claims about the Eurasian origin of the Nearctic gomphocerines and oedipodines, and in the case of the former, added that some genera also had Neotropical origins. Still earlier, and contrasting with the last view, Carbonell (1977) proposed that Neotropical Acridinae, Gomphocerinae and Oedipodinae (among other subfamilies) were recently derived from incursives from the Old World via North America.
Gomphocerinae, Oedipodinae and Acridinae (including the Truxalinae), are clearly related (Rowell & Flook 1998). Apart from the aforementioned writings of Vickery, Rehn and Carbonell, very little has been written about the biogeographic origins of these subfamilies, individually or as a group--or indeed, of the family Acrididae in general. For the latter, Amedegnato (1993) did speculate that possibly the family radiated from the " Old World". Lovejoy et al. (2006) implied a time frame for the family's diversification in their statement: " ... most subfamilies of the acridid grasshoppers have either exclusively Eastern or Western Hemisphere distributions ... suggesting that much of the diversification of Acrididae occurred after Africa and South America were separated". That is, acridid diversification took place around 100-80 mya. Rowell and Flook (2004) made similar statements about a rapid proliferation of taxa within the Acridoidea during this time. Fossils potentially hold a clue, but here the record is rather exiguous. Reports on the earliest appearance of reliable fossils representing Acrididae range somewhat wildly from about 150 mya (Labandeira 1994) to about 55 mya (Zeuner 1939) to 24 mya (Carpenter 1992).
Molecular phylogenetic methods, however, have provided some independent insights into the date and order of appearance of taxa. In one such study involving one or a few representatives from each of these four subfamilies among a wide collection of Orthoptera, Rowell and Flook (1998) concluded that Acridinae (including Truxalinae) and Gomphocerinae are more recently evolved than Oedipodinae (see also Flook & Rowell 1997, Rowell & Flook 2004). Finally, we should mention, as a point of historical interest, Jago's (1979) novel approach to the subject of branching order. Using present day distributions of subfamily members and plate tectonic area measurements, he proffered this order of first appearance: Gomphocerinae (180 mya), Acridinae (120 mya) and then Oedipodinae (80 mya). As in the Flook and Rowell studies, continental origins are not mentioned.
The current study expands on our earlier research by including considerably more genera from the southern continents, particularly grasshoppers belonging to the Acridinae (sensu OSF2). Our objectives are to revisit the hypotheses of subfamily monophyly and, by including material from South America, Africa and Australia, to shed some light on the biogeographical origins of the entire group and its members. Of possible interest to orthopterists is the independent testing of relationships among genera, previously unexamined by molecular methods.
Materials and Methods
Species, along with sources and their biogeographic ranges, are listed in Table 1. Included, mostly from the Southern Hemisphere, are 22 species of Acridinae and 37 species of Gomphocerinae. For a few genera such as Acrida, Aeropedellus, Amblytropidia and Gastrimargus, two or more species were sampled, some from different continents. For phylogenetic analyses, Pyrgomorpha conica was employed as the outgroup.
Methodologies pertaining to DNA extraction, purification, amplification and sequencing are described elsewhere (Litzenberger & Chapco 2001a, 2001b; Contreras & Chapco 2006). Analyses were based on sequencing portions of mitochondrial genes encoding, cytochrome oxidase subunit I (CO1) and II (C02), cytochrome b (cytb), NADH dehydrogenase subunit V (ND5) and 16S ribosomal RNA (16S). For these genes, the maximum numbers of base pairs sequenced were 609, 378, 618, 642 and 502 respectively. These genes were used because in our previous studies, their analysis yielded topologies with reasonably high resolutions.
Sequences were aligned by visual inspection, imported into Mac-Clade (Maddison & Maddison 2004) and analyzed using the software packages PAUP * (version 4.0b8-Swofford 2003) and MrBayes (MB) (Version 3.0b4--Huelsenbeck & Ronquist 2001). Both standard maximum parsimony (MP) and weighted maximum parsimony (wMP), following Farris' (1969) iterative weighting scheme, were used. Searches were repeated using all substitutions at the first 2 codon positions but only tranversional substitutions at the third position (methods referred to as MP123TV and wMP123TV). For the method of maximum likelihood, implemented through PAUP *, inputted parameter estimates consisted of output values obtained from the program Modeltest (Version 3.6--Posada & Crandall 1998). [Modeltest identified the GTR + G +I model as the "best".] Bootstrapping using ML was not pursued owing to the inordinately long run times required. Levels of support for parsimony-derived relationships were estimated through 1000 bootstrap replicates. Bayesian analysis also used the GTR + G + I model and provided measures of nodal support in the form of posterior probabilities (% PP). For the MB analysis, 8 Monte Carlo Markov chains, one cold and 7 heated, were run simultaneously for 15 million generations and sampled every 500 generations, yielding 30,000 trees.
For all analyses, the 5 sequences were treated as a concatenated unit, a procedure that, as in all our previous studies (Chapco et al. 2001; Litzenberger & Chapco 2001a, 2001b), always yielded trees with greater resolution and support when compared to those based on single genes. Before proceeding with the analyses, sequences were evaluated to determine if they were in fact nuclear sequences of mitochondrial origin or "Numpts" (Bensasson et al. 2000). All sequences analyzed in this paper met the criteria set out by Zhang and Hewitt (1996) for excluding that possibility.
In order to place biogeographic events within an interpretably geological context, it was essential to estimate the times ofdivergence for various nodes. We initially applied the maximum likelihood ratio test (Page & Holmes 1998) to determine whether sequences evolved in a clock-like manner. Because sequences did not in fact conform to a model of rate constancy, we estimated divergence times by employing a semiparametric penalized likelihood (PL) method, which can accommodate rates that vary over lineages (Sanderson 2002). To this end, the program r8s, version 1.70 (Sanderson 2004) was used. As recommended by Sanderson, the TN (Truncated Newton) algorithm was applied in conjunction with PL. A cross-validation analysis was first performed to determine the most likely smoothing parameter (a measure of the relative contributions of parametric and nonparametric models that underlie PL), a procedure necessary for estimating optimal divergence times. Zero-length branches were collapsed. A more extensive description of the method and theory is given by Sanderson (2002). The program yields estimates of absolute times of divergence if at least one known divergence date is provided as input. In this case, and as had been done previously (Fries et al. 2007), we relied on Gaunt and Miles' (2002) estimate of 100 mya for the Gomphocerinae-Oedipodinae split (this value in turn was based on dated ancient cockroach fossils). This calibration point was then employed to estimate times of divergence for various nodes of interest--but with some degree of caution because, strictly speaking, the two subfamilies (sensu OSF2) proved not to be monophyletic, as will be demonstrated below. In addition, derived dates of events should only be viewed as very approximate, given the equally rough underpinnings behind the calibration.
Ancestral geographic areas were preliminarily reconstructed with the assistance of the program "DIVA" (Version 1.1) (Ronquist 1996, 1997). Each genus was coded with a string of 1s and 0s according to its recorded presence or absence in Africa, Australia, Eurasia, North America, South America or Oceana. For genera involving more than one species, we applied the 0/1 coding to each such species. For "maxareas", a parameter that limits the range of ancestral distributions, 2 sets of values were employed: 4 (the default--which favors vicariance) and 2 (which favors dispersal). While the results from DIVA proved helpful as a guide, further interpretation was performed in conjunction with the temporal analyses. For instance, for the node connecting A to F (see Results and Fig. 1), DIVA assigned to that node, among other possible land mass areas, "North America-South America-Africa", clearly not a possibility given the 99 mya suggested for that node by the temporal analysis.
Among the different parsimony procedures used, wMP123TV yielded a tree with the greatest amount of resolution. Nevertheless, bootstrap support was generally poor, particularly at deeper levels. For the Bayesian procedure, the first 25,000 trees (burn-in value) were discarded, resulting in the 5000 trees that were used to obtain the consensus tree; this is depicted as chronograms in Figures 1 (a summary tree) and 2 (parts thereof). By comparison with parsimony, Bayesian methods yielded a highly resolved tree, with most nodes having sizeable PP values. Where there was good bootstrap support, PP values were also high. Relationships uncovered by ML were very similar to those in the MB topology.
To facilitate discussion, clusters of taxa are labelled A through N (Figs 1, 2). Overall, genera fall into three broad categories. The first group, spanning clades A to F, mostly comprises members of the Gomphocerinae; the single exception, clade E, consists of a melange of acridines and gomphocerines. Support for clades A to F is somewhat weak (PP = 45 %) as is support for A to E (PP = 38%). For the inner subgroup A to D, however, support is very strong (PP = 88%). The second group (PP = 86%) spans clades G to M (plus Duroniella) and mostly comprises genera of Oedipodinae along with 2 genera of Acridinae (Caledia and Froggattina) and Melanotettix, a lone member of the Gomphocerinae. These two large clusters are labeled Gomphocerinae* and Oedipodinae*, respectively, and together are supported with a PP value of 99%. Basal and paraphyletic to the 2 groups is a third assemblage, labeled Acridinae*, which includes Orthochtha, clade N and a succession of taxa. Collectively, they form a set of acridine genera and one gomphocerine, Pnorisa. All are African, the significance of which will be discussed later.
Choice of topology.--It is generally acknowledged that bootstrap and Bayesian support values are respectively conservative and liberal in their estimates of nodal confidence, and this is reflected in the present study with the Bayesian tree showing considerably greater resolution than the parsimony tree. Where parsimony does reveal good sorting of taxa, there is generally no disagreement with the Bayesian topology. The matter as to which approach is more accurate, however, is somewhat equivocal, given the opposite conclusions derived from various simulation studies (Suzuki et al. 2002, Wilcox et al. 2002, Alfaro et al. 2003, Simmons et al. 2004, Kelly 2005). As will be seen later, the Bayesian approach does yield numerous clades that "make sense" in terms of comprising large clusters of taxa from the same subfamily and/or continent. That is, recovered groupings are interpretable, as opposed to consisting of a gallimaufry of genera with no meaningful connections.
But this is not the only reason for favoring the Bayesian approach and downplaying the parsimony tree. There are, in fact, a few legitimate reasons for parsimony's poor resolution. Fuller et al. (2005) have pointed out that lower bootstrap support may be the result of comparatively higher AT content typically found in mitochondrial DNA, leading to a reduction in the number of informative sites in parsimony analysis. In the current study, the average AT was indeed relatively high at 70.3%. Other factors, pointed out by Flook and Rowell (1997), pertain to data which consist of a large number of taxa and involve sequences that exhibit significant departures from rate homogeneity. Both situations can lead to high levels of homogeneity and poor bootstrap support, as is the case here.
For our best parsimony tree (wMP123TV), the consistency index was in fact quite low, equaling 27.9%. The number of taxa in this study is fairly small, at least relative to the numbers in our previous studies and for which bootstrap support and resolution were respectably high. Furthermore, our data depart significantly from the molecular clock hypothesis. By contrast, the Bayesian method does use all the data and is able to accommodate rate heterogeneity with a proper choice of model. [As an added note, we should point out that a certain measure of confidence in the tree's robustness is provided by considering a study made by Yang and Rannala (2005), who showed that Bayesian phylogenies may be sensitive to choice of the prior probability distribution for branch length. Accordingly, we re-analyzed our data using different branch length priors and discovered that the resultant topologies were virtually the same as the one presented here.] Admittedly, a better resolved parsimony tree would have been desirable, especially one that turned out to be concordant with the Bayesian tree, if for no other reason than to provide greater overall confidence in the statements that follow. However, this not being the case, we would suggest that the Bayesian tree as it stands serve as a working hypothesis for further study.
Subfamily monophyly.--On the surface, it would appear that Gomphocerinae* is not monophyletic in terms of representing an uninterrupted subset of gomphocerine grasshoppers. One could regard the acridines within clade E as "peg-less gomphocerines"-a possibility, given Otte's (1981) statement concerning the relative ease with which stridulatory pegs can be lost over evolutionary time. Moreover, it should be noted that other genera in clade E, unequivocally classified as Gomphocerinae, do have elements (some populations within species, some species, one or both sexes) that also lack pegs (Jago 1971, Otte 1981). A case could therefore be made for regarding Gomphocerinae* as a monophyletic subset of gomphocerine grasshoppers, but not one centred around the "peg-trait". Nevertheless, the monophyletic status of the subfamily as a whole is still questionable because 2 other gomphocerines occur outside A to F: Melanotettix (part of clade L) and Pnorisa (part of clade N).
Similar reservations about the monophyly of Oedipodinae* (G-M plus Duroniella) can be expressed, given the presence of acridines within clades J, K and M and of Melanotettix within L. Interestingly, Oedipodinae* would appear to fit Rentz etal.'s (2004) broader view of Acridinae. Regarding their definition of tribes Acridini and Oedipodini, however, our analysis shows that neither is a unified group. As for the gomphocerine Melanotettix, it too could be considered part of Acridinae (sensu OSF2). The genus does lack stridulatory pegs, typical of the latter. It is noteworthy to mention that Otte (1981), having previously expressed some ambivalence about the genus' subfamily affiliation, "tentatively" (author's qualification) placed it within the Gomphocerinae. Melanotettix is part of a clade that also includes Machaerocera, another "bridge-genus" between Acridinae and Oedipodinae (Otte 1984).
There still remain the genera at the base of the entire phylogeny, clade N plus Holopercna to Sherifuria. All, except Pnorisa, are acridines (sensu OSF2) and all are African.
In light of these collective findings, we propose the following:
Let Clades A to F define a "new" Gomphocerinae that is monophyletic; let Clades G to M define Acridinae, also monophyletic; and let N plus the basal taxa define-in this case, a paraphyletic group --perhaps labelled as "the ancient Acridinae". A more detailed morphological examination of fine structures using, for example, scanning electron microscopy (e.g., Scali & Massimo 1977) or atomic-force microscopy (e.g., Zhang et al. 2010) could potentially reveal characters that unify the monophyletic clusters.
Biogeographic origins of the subfamilies.--Gaunt and Miles (2002) estimated the age of common ancestry for, in their case, Chorthippus (a member of our Gomphocerinae*) and Locusta (a member of our Oedipodinae*) to be roughly 100 my. Accordingly, in calibrating our clock, we assigned that date to the node connecting our cluster of mostly gomphocerine grasshoppers with that of mostly oedipodine grasshoppers.
The following scenario points to an African origin for the Acridinae, Gomphocerinae and Oedipodinae. This interpretation, arrived at with the aid of DIVA, is consistent with the observation that all the taxa which are basal and paraphyletic to the Gomphocerinae* -Oedipodinae* node, are all unequivocally African. Their common ancestor was probably a proto-acridine. Diversification into two major lineages took place almost instantaneously, in geological terms, after the primary split. One subset of pre-acridines migrated to, and diversified within, South America about 99 mya, and then somewhat later some elements went on to establish the Gomphocerinae* in other continents (see below). About 96 mya, another subset entered Eurasia and radiated from there to form the Oedipodinae*. The connection between Africa and South America would still have been intact at the time (Sanmartin & Ronquist 2004, Smith et al. 2004), their disjunction not being completed until the end of the Late Cretaceous (Pitman et al. 1993); movement from Africa to Eurasia was made possible by several transitory connections that spanned the narrow Tethys sea (Goldblatt 1993). It is interesting to note that these almost concurrent, early events support Rowell and Flook's (1998) conclusion of a "single explosive radiation"having occurred within the Acridoidea, which appeared to correlate with--or to paraphrase their later words (Rowell & Flook 2004) be "triggered by"--the spread of flowering plants in the Cretaceous. Leys et al. (2002) made similar comments about another group of insects, the Apida, which perhaps, might be reflective of a general phenomenon. The acridines at the base of the tree had fairly ancient ancestors preceding the Gomphocerinae* --Oedipodinae* split by 10-70 my.
As a footnote, we should like to re-affirm our belief that dispersal rather than vicariance, accounted for the establishment of continental taxa, even though, to quote Voelker (1989), "... some dispersal across barriers is almost certainly required to explain the occurrence of the widespread ancestor". Notwithstanding this incisive remark, it is tempting to view the evolution of the two groups as a result of vicariance since the Oedipodinae*-Gomphocerinae* split roughly coincided with the breakup of Western Gondwanaland. That is, pre-acridines, having spread throughout the conjoined African -South American continent, became separated into two groups postfragmentation, one group giving rise to the gomphocerine acridine complex that spread throughout South America and the other evolving into the oedipodine-acridine complex in Africa. However, given the overwhelming evidence that all the basal and paraphyletic taxa in the tree are African, the center of origin would have to be in Africa. Dispersion would have taken place from there.
Gomphocerinae*.--The South American elements of clades F and E branched off in rapid succession 99 and 98 mya, respectively, from their African ancestors, with divergence within clades taking place in both cases, about 90 mya.
Members of clade F remained and diversified within South America. All but one genus, Rhammatocerus, are restricted to that continent. Of its 23 species, 21 are also endemic to South America (Otte 1981), including the 3 studied here. The other 2 occur throughout North America, but without knowing their sequences we cannot easily (see below) estimate the time of ancestral incursion.
Genera comprising clade E are more widespread. Many, such as Orphulella, include species, or populations within species, found in North America. Amblytropidia is another far-ranging genus, but here we do have sequences for continentally separated species. The program r8s estimates their time of divergence at about 50 mya, which would have been well within the time during which the two continents were intermittently connected by a series of land bridges (Pitman et al. 1993). One might speculate that the incursions of Orphulella and perhaps, Rhammatocerus (above), into North America had also taken place at this time and by this means.
About 92 mya, there was an unexpected reverse migration to Africa, still possible then, leading to the genera comprising clade D. The common ancestor of A to D could have been South American with, as stated, one branch leading to D and another to North America (clades A and C), with one offshoot from clade A moving on to Eurasia (clade B). This is an appealing scenario, given the relatively easy access between continents at the time. DIVA, however, identifies Africa as the ancestral area for clades A to D, and Eurasia as the common ancestral area for clades A to C. This implies three things: first, a movement from Africa to Eurasia would be required, still feasible as previously stated; second, the bulk of the North American gomphocerines had Eurasian ancestors; and third, genera such as Eritettix and Opeia, believed to have had a Neotropical origin (Vickery 1989), had instead a Holarctic origin.
Oedipodinae*.--The second major group that migrated from Africa comprised mostly ancestors ofthe oedipodine grasshoppers, which, based on DIVA, initially settled in Eurasia. Incursion took place "soon" after the Gomphocerinae*- Oedipodinae* split, about 96 mya. In relatively short order, clades M (94 mya) to G (72 mya) were established. Movement into North America took place at least twice: 81 mya (clade L) and 53 mya (clade I). About 63 mya, there was a reverse dispersal to Africa (clade G). Certain elements of clades G, H, K and M have descendants in Australia and the Oriental region and represent more recent incursions. These will be discussed below.
Other subfamilies.--Similar studies of other subfamilies of Acrididae are few in number. Holarctic melanopline grasshoppers appear to have a South American origin (Amedegnato et al. 2003, Chapco 2006), but see Chintauan-Marquier et al. (2011) for a modification of this view. Whether the Melanoplinae also have an African link is presently unknown, although Lovejoy et al. (2006) did establish such a connection for Pan-American species of Schistocerca, a member of the Cyrtacanthacridinae, a subfamily related to the melanopline grasshoppers. Rowell and Flook (2004), using similar methods, described possible places of origin for the more spatially restricted Neotropical subfamily Proctolabinae. Outside of the Acrididae, the orthopteroid literature is not voluminous (i.e., Huang et al. 2006, Maekawa et al. 2002) with respect to biogeographical origins.
Clade A.--This clade (PP = 88%) is entirely North American, having evolved from Eurasian ancestors about 79 mya. Clade A includes genera/species not previously studied by Contreras and Chapco (2006): Brunneria yukonensis, Bootettix argentatus, Eritettix simplex, Psoloessa delicatula, Opeia obscura and the "banded-winged" gomphocerine, Acrolophitus.
Brunneria yukonensis, endemic to the Yukon Territory (Vickery 1997), is directly linked to B. brunnea, not a surprise in contrast to the case of Chloealtis below. According to our chronogram, the 2 species diverged about 8.3 mya. The northern region at that time would have been sufficiently warm for insects to survive, but it was predominantly forested (Reinink-Smith & Leopold 2005) and probably inhospitable to gramnivorous grasshoppers. More likely, the ancestor of B. yukonensis evolved in the grassland-dominated south (Jacobs et al. 1999), eventually migrating-perhaps "island hopping" between successive and numerous "nunataks"-and adapting to northern conditions during the intervening periods of glaciation.
There is a strong association among Eritettix, Opeia and Psoloessa. Vickery (1989) maintained that they, among other genera, are united in having a Neotropical origin. They are indeed linked, but their South American counterparts, at least of the last 2 genera, arose from the north. Somewhat earlier, Carbonell (1977) expressed a similar view on the origin of Neotropical gomphocerines. While Eritettix and Opeia belong to the same tribe, Eritettigini, Psoloessa belongs to another tribe, Aulocarini. Neither tribe is monophyletic. Eritettigini includes Amphitornus, part of clade C, and the South American Sinipta, part of clade F; Aulocarini includes Aulocara and Ageneotettix, both ofwhich are positioned within clade B. Curiously, Eritettix and Psoloessa shared a very recent common ancestor (4.5 mya), whereas Eritettix and Opeia shared an ancestor long before that, 51.4 mya. Jago (1971) had pointed out a resemblance between Eritettix and the African genus Pnorisa, but given the phylogeny, the phenotypic similarity is probably the result of convergence.
OSF2 assigns Bootettix and Acrolophitus to the tribe Acrolophitini. Our results indicate that both are part of the same subclade, but they are not directly connected and are separated by members of other tribes. Their positions, however, should be regarded as tenuous, given that support for Bootettix's location is weak (PP < 50 %) and the number of sequenced base pairs for Acrolophitus is rather low (1386 bp).
Clade B.--Clade B, a sister clade of A, consists almost entirely of Eurasian and Eurasian-derived North American Gomphocerinae. In its entirety, clade B is weakly supported (PP = 55%). In a previous study (Contreras & Chapco 2006), Dociostaurus and Arcyptera (different species) were closely linked and, apart from Ramburiella (see below), formed a sister group to other Eurasian gomphocerines and their North American derivatives. Pseudogmothela's topological location is quite equivocal, given that in repeated MB runs, the genus emerges elsewhere. Confidence in the integrity of the remaining assemblage encompassing Aeropedellus to Mermiria is, however, much greater (PP = 82%). Divergence within this subclade occurred about 73 mya.
Out of roughly 20 species of Aeropedellus, four were analyzed. At one time, A. arcticus was considered a subspecies of A. variegatus (Hebard 1935), but subsequent work by Vickery (1967, 1997) showed them to be quite morphologically distinct, a difference reinforced by our molecular data. The two Eurasian species are paraphyletic to the two North American species, as are the Eurasian genera Glyptobothrus and Gomphocerippus. It is therefore probable that A. reuteri or its ancestor gave rise to the North American species, about 10 mya, during a warm interglacial period when Beringia was in place (Vickery 1989).
The discovery that two species of the North American genus Chloealtis are not directly related is somewhat unexpected, given their similar appearance (Otte 1981) [but not, apparently, with respect to choice of oviposition site-see Stauffer & Whitman 1997]. Each is directly connected to a different Eurasian genus: C. abdominalis to Chrysochroan (both members of the tribe Chrysochranotini) and C. conspersa to Ptygonotus (tribe Arcypterini). In both cases, times of separation predate that of the Aeropedellus radiation by about 20-30 my. Either Beringia or one of the north Atlantic bridges could have served as conduits to the Nearctic.
An association among the three Eurasian genera Myrmeleotettix, Omocestus and Stenobothrus is strongly supported, and appears to agree with morphologically-based phylogenies provided by Jago (1971) and Clemente et al. (1990). Although Jago (1971) regards the 3 as subgenera of Stenobothrus, the OSF2, curiously, assigns them to different tribes: Myrmeleotettix to tribe Gomphocerini and the other 2 to tribe Stenobothrini. Contreras and Chapco (2006) proposed combining the 2 tribes.
Mermiria is the first genus to branch off from the base of the aforementioned subclade. It belongs to the Mermiriini, as does Achurum, but as can be seen from Figure 2a, the two are quite far apart. According to Vickery (1989), Mermiria is related to the South American genus Staurorhectus (clade F) (see also Jago 1971), but undoubtedly the resemblance must be the result of convergence.
Clade C.--Clade C is basal to A and B and is strongly supported (PP = 85%). Its sole Eurasian genus, Ramburiella, is also basal to the bulk of gomphocerines in Contreras and Chapco (2006). Ramburiella and the two North American genera, according to DIVA, shared a common Eurasian ancestor, splitting from one another about 77 mya. Amphitornus and Boopedon evolved from a common ancestor about 70 mya; they belong to different tribes, Eritettigini and Amblytropidiniini respectively. Other members of these tribes occur elsewhere in the tree. Two other species of Ramburiella are found in Africa, probably the result of recent migrations.
Clade D.--This interesting clade represents a "return" to Africa from South America about 92 mya, well within a time period during which dispersal across the chasm separating the two southern continents was still possible for some organisms (Pitman et al. 1993). Diversification took place about 80 mya. Support for this aggregate of five African gomphocerine genera is very strong (PP = 93%). The group is external to clades A, B and C. Stenohippus and Thyridota have not yet been assigned to tribe by the OSF2. The remaining three genera belong to different tribes. Jago (1996a) erected the Dnopherula Complex, defined by a geophilous lifestyle and morphologically, by a fronto-vertical angle >40[degrees], placing within it, among other genera, Pnorisa, Rhaphotittha, Pseudogmothela, Ramburiella and Stenohippus. Of these, only Rhaphotittha and Stenohippus are closely related, albeit not directly. Other members of clade D (Amesotropis, Ochrilidia and Thyridota) are regarded as phytophilous and are not included in Jago's Dnopherula Complex.
The genus Ochrilidia is centered in Africa, but some species also occur in southern Europe and south-west Asia including India (BeiBienko & Mishchenko 1951, Dirsch 1965, OSF2). The two species studied here occupy somewhat different ranges, but overlap in northern Africa; they diverged about 15 mya, coinciding with a time of transition from tropical forest habitat to that of open grasslands (Micheels et al. 2009).
Stenohippus is phylogenetically older than Ochrilida, having diverged about 58 mya. Ranges of S. harteri and S. mundus overlap in west-central Africa, perhaps the genus' place of origin. The genus itself has a broader African distribution, encompassing the Arabian peninsula, and extends into southwest India. For this genus and Ochrilidia above, estimation of times of entry outside Africa would require having sequences for species from those continents.
Clade E.--This clade (PP = 99%) diversified about 90 mya from a common neotropical ancestor and is external to A-D, consisting of a mixture of acridine and gomphocerine genera. Most genera including Metaleptea-the eponymous title of the Orthoptera Society newsletter-had not been studied previously by Contreras and Chapco (2006). These taxa are well represented in South America with some elements of Amblytropidia, Dichromorpha and Orphulella appearing in North America. O. speciosa, the species studied here, is found entirely within North America.
Most tribes within the clade are not monophyletic. Achurum belongs to the tribe Mermiriini, but is far removed from another member, Mermiria (part of clade A). In contrast, the unified trio Dichromorpha, Orphulella and Orphulina all belong to one tribe, Orphulellini, an association supported here. Amblytropidia belongs to the tribe Amblytropidini, which also includes, among others, the genus Sinipta (part ofF), Boopedon (part ofClade C) and Syrbula (part of Clade B). Interestingly, some reservations about the legitimacy of Amblytropidini had been previously expressed by Otte (1981). Although Eutryxalis and Covasacris have not been assigned to tribe by OSF2, Donato (2003a, 2003b) placed them in the tribe Hyalopterygini along with Metaleptea and Parorphula (some species of which have been synonymized with C. pallidinota), a union which agrees with our phylogenetic findings.
It is worth noting that most gomphocerines that make up this gomphocerine/acridine mix lack stridulatory files on their hind femora. For example, some species of Orphulella (not speciosa) and some populations of Achurum carinatum lack this acridine-defining trait (Otte 1981).
The two species of Amblytropidia separated about 50 mya. A. mysteca occurs in the southern US and parts of Mexico and Central America, whereas A. australis is found in southern South America. A series of island arcs, in place at the time, periodically linked the two continents (Pitman et al. 1993) and could have served as a conveyance for a South American ancestor of A. mysteca.
The two closely linked genera, Orphulella and Orphulina, together with Dichromorpha form part of the tribe Orphulellini, an association supported here. They arose from a common South American ancestor about 60 mya, spreading to different extents into Central and North America.
The genus Achurum occurs in south, southeastern US and Mexico. The two species analyzed here separated about 33 mya and presently have nonoverlapping distributions. A. minimipenne is found in the southern US (excluding Florida); A. carinatum is in Florida. Their common ancestor must have occurred elsewhere since the Florida Peninsula would have been submerged (Lane 1994) at that time.
Clade F.--This clade branched off from a common South American stock about 99 mya and soon after (90 mya) diverged into five genera. All taxa making up this group are gomphocerines and most are exclusively restricted to that continent. Jagomphocerus, Parapellopedon and Rhammatocerus belong to the tribe Scyllini and that association is strongly supported here. Rhammatocerus, however, is not monophyletic. Sinipta (tribe Amblytropidiini) and Staurorhectus (tribe Compsacrini) are linked and external to the Scyllini. Other members of Amblytropidiini (Boopedon, Amblytropidia) analyzed here, are far removed from this clade. In Carbonell's (1977) morphological descriptions of some South American tribe members, he acknowledges that these aggregations are not necessarily of phylogenetic significance.
Clade G.--Oedipoda is external to all other taxa comprising Clade G, but its phylogenetic location is weakly supported (PP = 59%); in Fries et al. (2007), the genus' position is somewhat ambivalent. The remaining cluster by contrast, has maximal support (PP = 100%). Relationships among genera previously studied (Fries et al. 2007) appear unaltered with the inclusion of Morphacris and additional species of Heteropternis and Gastrimargus. Analysing trees based on 12S and 16S rDNA sequences, Rowell and Flook (2004) also united Oedipoda, Locusta and Morphacris, but not in the same branching order as that here. Yin et al. (2008), using the latter's 16S data set and adding sequences from Gastrimargus and Heteropternis, also revealed the same associations, except that the position of Heteropternis was external to all the oedipodine genera studied (see Lu & Huang 2006 for a similar study but without Heteropternis). More recently, Ma et al. (2009) in their phylogenetic analysis of complete mitochondrial genomes involving seven genera of Acrididae, directly linked Oedaleus with Gastrimargus, two genera which are also very similar morphologically (Ritchie 1981, 1982). The two particular species analyzed by Ma et al. differed from ours. In their analysis, Locusta was external to the pair. Other findings by Ma et al. are discussed under clade M.
A small point of interest: Acrotylus, Morphacris, (perhaps) Locusta and Oedaleus, although belonging to different tribes (OSF2), appear unified in possessing a common defence mechanism (Whitman 1990). The point in mentioning this is to illustrate the need for probing more deeply into these insects' biology in order to discover other commonly inherited traits which our molecular phylogeny, if accurate, would suggest must exist. Morphacris has not yet been assigned to tribe according to the OSF2, although Petit et al. (2006) place the genus within the (North American) tribe Tropidolophini, clearly an error.
The two African species of Gastrimargus are directly linked, sharing an ancestor about 31 mya. The genus, however, is not monophyletic. The Australian G. musicus is somewhat phylogenetically removed from the pair, despite its striking resemblance to G. africanus (Ritchie 1982). Like G. musicus, the species, Heteropternis obscurella, is autochthonous to Australia-Australasia (Rentz et al. 2004); at one time they were believed to be descendants of fairly recent invaders (Key 1959, Ritchie 1981). Our phylogeny shows however, that they descended from African ancestors further back in time: 44 mya for H. obscurella and 56 mya for G. musicus. Fries et al. (2007) describe possible colonization scenarios, one involving "long-distance island hopping" and the northward moving "island" India. Oedaleus is another wide-ranging genus (Ritchie 1981) and its only Australian species, australis, may have had a similar ancient history, given that the two species of Oedaleus analyzed by Fries et al. (2007)-one African and the other Asian-separated about 35 mya.
Clade H.--These are the same Eurasian genera studied previously (Fries et al. 2007); there are no changes to their relative associations within the present, larger body of data. Diversification within the clade took place about 55 mya, roughly within the same time frame as noted in Fries et al. Its close relationship to clade I also remains unchanged.
Clade I.--All members of clade I (PP = 100%) are North American, having split off from a Eurasian ancestor about 60 mya. Most tribes of Oedipodinae were shown not to be monophyletic by Fries et al. (2007), and with the addition of Camnula and Pardalophora, that conclusion may be extended to include the Hippiscini to which both genera belong. The relative positions of genera in Fries et al. (2007) remain approximately the same. Otte (1984) does point out Camnula's apparent lack of a nearest relative within the tribe. Here, it would seem that the genus' nearest relative is Trachyrhachys, a member of the tribe Psinidiini.
Clade J.--This clade is external to Clades G-I, having branched off from a Eurasian ancestor about 80 mya. Most genera of Clade J have wide-ranging members; at least three dispersals have occurred. One led to the African acridine, Anaeolopus, another to the North American Stethophyma gracile and at least one migration established Aiolopus strepens throughout the Old World and Asia-Australia. Aiolopus and Stethophyma were previously shown (Fries et al. 2007) to be linked and remain so here. Aiolopus's closer relationship with Anaeolopus is interesting and was perhaps adumbrated by Hollis (1967) who, in re-examining synonymies within the genus Aiolopus, transferred one species, A. tamulus, to Anaelopus. The scheme presented by Rentz et al. (2004) would undoubtedly have placed all members of clade J, a mix of Oedipodinae and Acridinae (sensu OSF2), into a redefined Acridinae.
Clade K.--Clade K diverged from a common Eurasian ancestor about 81 mya, preceding the previous division by 1 my. Within clade K, a split occurred 12 my later, giving rise to the Eurasian/African genus Paracinema and the remaining taxa, all centered in Australia. One possible route to that distant continent could have been achieved via a series of steps from Eurasia to Africa to India (on its northward drift) and on to Australia. Fuller et al. (2005) had proposed just such a long-range pathway for the allodapine bee genus Braunsapis, which may well have served as a dispersal route for other insects capable of long-distance migration.
The tight relationship between the oedipodines, Austroicetes and Chortoicetes, previously established (Fries et al. 2007), remains the same with successive links to the acridines, Caledia and Froggattina. As a matter of historical interest, Colgan (1989, 1991) had demonstrated the same close association using the older technologies of allozyme and restriction enzyme analyses. With respect to tribal affiliation, Caledia and Froggattina both belong to the Acridini, but are not directly linked; other tribal members appear elsewhere in the phylogeny. The tribe Epacromiini, of which Paracinema is a member, is also nonmonophyletic with other genera such as Aiolopus, Duroniella and Heteropternis scattered throughout the tree.
Clade L.--The evolution of these North American genera predates those comprising clade I (Arphia to Pardalophora) by about 30 my. At the time of divarication, Laurasia, still intact, would have facilitated movement between regions. All but the gomphocerine Melanotettix are oedipodines. Otte (1981, 1984) had expressed some ambivalence about the subfamily affiliation of Melanotettix, as well as that of Machaerocera, both sharing some features (absence of stridulatory pegs and habitat type, respectively) with the Acridinae.
Clade M and Duroniella.--Clade M, comprising two acridine genera, is basal to clades G-L. Its ancestor, probably Eurasian in origin, diverged soon after the Oedipodine* explosion, 96 mya. One genus, Acrida, is distributed worldwide, excluding the Americas, and comprises over 40 species, of which three were studied here. The genus is at least 39 my old. A. conica occurs in Australia and New Guinea, and, according to DIVA, shared a common ancestor with the largely African A. turitta about 30 mya. Migration to the Australian region would have been more recent than the time of dispersal for the ancestor of the Australian genera in clade K. Also, the pathways were likely different. By 39 mya, India would have reached its northern limit, cutting off that part of the route to Australia. Given the widespread distribution of the genus, the ancestor of A. conica could well have come from Southeast Asia from whence we know island-hopping would have been possible (J0nsson & Fjeldsa 2006). Truxalis is similarly widely distributed, but without having samples from other geographical regions, all we can propose is that diversification took place since about 71 mya.
Others have examined the phylogenetic position of Acrida with respect to a limited number of acridines, gomphocerines and oedipodines. Acrida's relationship to Truxalis had already been demon strated by Rowell and Flook (1998) in their phylogenetic analysis of mitochondrial 12S + 16S rDNA sequences for a very wide sample of Acridoidea. Directly linked to one another, the two genera were part of a large, mostly unresolved, tree. Liu et al. (2008), in their analysis of a 795 bp portion of the same two rDNA sequences, showed that Acrida (sp = willemsei) was external to four genera of Oedipodinae, a result broadly similar to that in our present work. A recent phylogenetic analysis (Fenn et al. 2008) of the complete mitochondrial genomes of a small number of orthopteran taxa, including three species of Acrididae, showed that Acrida (willemsei) was directly linked to a member of the Calliptaminae (genus Calliptamus); both were associated with Locusta, an unexpected result. Expanding on the latter study, Ma et al. (2009) analyzed four additional Acrididae. Their investigation showed that Acrida was external to the trio Chorthippus-Calliptamus-Oxya, and that this set emerged as a sister group to the aggregate, Locusta-OedaleusGastrimargus. The relative positions of Chorthippus, Acrida and the oedipodines appear to be reversed to the topology uncovered in the present study in which Acrida is shown to be more closely aligned with the Oedipodinae.
Given the vast amount of data that complete sequences do provide, it is tempting to regard their phylogenies as being somewhat more accurate, but Zwickl and Hillis (2002) have shown, through simulation studies, that increased taxon sampling is perhaps more important than increasing the number of sequences in achieving greater phylogenetic confidence. Whether the relationships revealed in this paper will remain invariant with greater genomic scrutiny, however, remains to be seen.
Duroniella is located in southwestern Asia, the Middle East and north Africa, probably derived from a Eurasian or African ancestor about 96 mya. Over its taxonomic history, this genus has been assigned to various subfamilies from Acridinae (Bei-Bienko & Mishchenko 1951, Jago 1971) to Oedipodinae (OSF2) to Gomphocerinae (Fries et al. 2007). From the present phylogeny, which encompasses a greater sampling of the three subfamilies, it would appear that Duroniella is more closely aligned with a complex of taxa composed of members of Oedipodinae and (a subset of) the Acridinae, but not of the Gomphocerinae.
Orthochtha, Clade N and remaining taxa.--These genera diverged before the Gomphocerinae*-Oedipodinae* split at different times, ranging from the more recent offshoot, Orthochtha (111 mya), to those of clade N (118 mya) to the genus with the most ancient ancestor, Sherifuria (174 mya). This basal group, a mixture of resolved and unresolved relationships, is paraphyletic to all the preceding taxa. All are African and, except for Pnorisa (Gomphocerinae-see Clade D above), all belong to the Acridinae. Orthochtha is the only genus with species outside the continent (four are in southern India -OSF2); they are probably the descendants of (not necessarily recent) incursives from Africa.
Clade N consists of six genera. The two species of Odontomelus, are not directly linked but instead are connected through the genus Parga. In Jago's (1983) study of several African acridine genera, both are placed within the Parga genus group, which also includes Comacris, Duroniella, Gymnobothrus, Holopercna and Zacompsa. Apart from Duroniella, Holopercna and Pnorisa, our results concur approximately with Jago's grouping. Jago (1983) defines yet another genus group, Phlaeoba, for which we unfortunately have analyzed only one genus, Sherifuria. Jago alludes to yet another (unnamed) group to which Orthochtha belongs, and in our study, the genus is phylogenetically apart from the others, internal to clade N, albeit with weak support.
We thank the late C. Amedegnato (CNRS, France), A. Bugrov and M. Sergeev (both, Novosibirsk State University, Novosibirsk, Russia), J. Capinera (University of Florida, USA), M. Cigliano (Museo de La Plata, Argentina), B. Ciplak (Akdeniz University, Turkey), T. McNary, D. Rentz (CSIRO, Australia), S. Schell (University of Wyoming, USA), and C. Yong-Lin (Academia Sinica, China) for kindly providing grasshopper specimens. We are especially grateful to J.- P. Camacho (University of Granada, Spain), I. Chintauan-Marquier and P. Pompanon (both Universite J. Fourier, France), and A. Foucart and M. LeCoq (both, CIRAD, France) for their extensive help in collecting and identifying specimens. We thank E. Chapco for helpful comments on the manuscript. This research was funded by a grant (W.C.) and a postgraduate scholarship (D.C.) from the Natural Sciences and Engineering Research Council of Canada.
Appendix 1. The following sequences, owing to Genbank's limitations regarding length, are reproduced here.
Acrida turrita 16S ribosomal RNA gene
ATTGAGCTACTGCACCCAAAAATAATCTTAATCCAACATCGAGGTCGCACTCTGCTTTGTCGATAAGAGCT CTCAAAAACAATTACGCTGTTATCCCTAAGGTAACTTAATCTTATAATCATAAATTATGGATCATAAAAAC ATAAATTAATGAATTCATAATGAAGAGTTTATTTATTCTTCATGTCACCCCAA
Thyridota dispar 16S ribosomal RNA gene
ATTGGGCTACTGCACCCTAAAACTTTTCTTAATCCAACATCGAGGTCGCAATTTATTTTGTCGATATGAGC TCTCAAAAATAATTACGCTGTTATCCCTAAGGTAACTTAATCTTATGATCATAAATTATGGATCAAAATTA ACATAAATTAATGATTATATAAATGAAGAGTTTATTGATTCTAC
Gymnobothrus temporalis COII gene (translation starts at base 1)
GATACATATATAACACCAGAAAGAGATCTTAATAATGAAGGATTTCGACTATTAGATGTAGACAACCGGAC AATTTTACCTATAAATACAGAAGTACGTATTCTTACCAGAGCATCAGACGTACTTCACTCATGAGCAGTAC CAGCATTAGGGATTAAAATTGATGCCACACCAGGACGACTAAAC
Achurum minimipenne cytb gene (translation starts at base 1)
Amphitornus coloradus cytb gene (translation starts at base 3)
Jagomphocerus amazonicus cytb gene (translation starts at base 3)
Stethophymagrossum cytb gene (translation starts at base 1) GGATCATATAT ACATATAAATACATGAATAATTGAAACGCTAATTCTATTTTTAGTTATACCAACAGCATTTATAGGTTATG TATTACCATGAGGACAAATATCATTCTGAGGAGCAACAGTAATTACAAATTTATTATCAGCTATCCCTTAT CTTGCAACAGAATTAGTACAAA
Alfaro M.E., Zoller S., Lutzoni F. 2003. Bayes or bootstrap? A simulation study comparing the performance of Bayesian Markov Chain Monte Carlo sampling and bootstrapping in assessing phylogenetic confidence. Molecular Biology and Evolution 20: 255-266.
Amedegnato C. 1993. African-American relationships in the Acridians (Insecta, Orthoptera), pp. 59-75. In: George W., Lavocat R. (Eds) The Africa-South America Connection. Clarendon Press, Oxford.
Amedegnato C., Chapco W., Litzenberger G. 2003. Out of South America? Additional evidence for a southern origin of melanopline grasshoppers. Molecular Phylogenetics and Evolution 29: 115-119.
Bei-Bienko G.Ya., Mishchenko L.L. 1951. Locusts and Grasshoppers of the USSR and Adjacent Countries. Part II. (In Russian). English translation (1964) by Israel Program for Scientific Translations. Jerusalem.
Bensasson D., Zhang D.-X., Hewitt G.M. 2000. Frequent assimilation of mitochondrial DNA by grasshopper nuclear genomes. Molecular Biology and Evolution 17: 406-415.
Brooks A.R. 1958. Acridoidea of southern Alberta, Saskatchewan and Manitoba (Orthoptera). Canadian Entomologist Supplement 9: 1-92.
Carbonell C. S. 1977. Origin, evolution, and distribution of the Neotropical acridomorph fauna (Orthoptera): a preliminary hypothesis. Revista de la Sociedad Entomologica Argentina 36: 153-175.
Carpenter F.M. 1992. Superclass Hexapoda. Treatise on Invertebrate Paleontology. Part R. Arthropoda 4. Geological Society of America, Inc. and The University of Kansas.
Chapco W., Litzenberger G., Kuperus W. R. 2001. A molecular biogeographic analysis of the relationship between North American melanoploid grasshoppers and their Eurasian and South American relatives. Molecular Phylogenetics and Evolution 18: 460-466.
Chintauan-Marquier I.C., Jordan S., Berthier P., Amedegnato C., Pompanon F. 2011. Evolutionary history and taxonomy of a short-horned grasshopper subfamily: the Melanoplinae (Orthoptera: Acrididae). Molecular Phylogenetics and Evolution 58: 22-32.
Clemente M.E., Garcia M.D., Presa J.J., Santos J.L. 1990. Consideraciones sobre la morfologia, biologia y relaciones geneticas de los Gomphocerinae de la peninsula Iberica: Stenobothrus Fischer, 1983; Omocestus Bolivar, 1878 y Myrmeleotettix Bolivar, 1914. (Orth., Caelifera).
Colgan D.J. 1989. Developmental variation and allozymic polymorphism in the enzymes of glycolysis in grasshoppers. Journal of Evolutionary Biology 2: 141-151.
Colgan D.J. 1991. Phylogenetic studies of acridoid grasshoppers comparing 2n2- and 4-base recognizing endonucleases. Journal of Evolutionary Biology 4: 575-591.
Contreras D., Chapco W. 2006. Molecular phylogenetic evidence for multiple dispersal events in gomphocerines grasshoppers. Journal of Orthoptera Research 15: 91-98.
Dirsh V.M. 1965. The African Genera of Acridoidea. Cambridge University Press. Cambridge, UK.
Donato M. 2003a. Revision del genero Covasacris (Orthoptera: Acrididae: Acridinae: Hyalopterygini). Revesta de la Sociedad Entomologica Argentina 62: 27-34.
Donato M. 2003b. Revision of the South American genera Allotruxalis Rehn and Eutryxalis Bruner (Orthoptera: Acrididae: Hyalopterygini). Caldasia 25: 381-402.
Eades D. C., Otte D., Cigliano M. M., Braun, H. . Orthoptera Species File Online. Version 2.0/4.0. . http://osf2.orthoptera.org.
Farris J.S. 1969. A successive approximations approach to character weighting. Systematic Zoology 18: 374-385.
Fenn J.D., Song H., Cameron S.L., Whiting M.F. 2008. A preliminary mitochondrial genome phylogeny of Orthoptera (Insecta) and approaches to maximizing phylogenetic signal found within mitochondrial genome data. Molecular Phylogenetics and Evolution 48: 59-68.
Flook P.K., Rowell C.H.F. 1997. The phylogeny of the Caelifera (Insecta, Orthoptera) as deduced from mtrRNA gene sequences. Molecular Phylogenetics and Evolution 8: 89-103.
Fries M., Chapco W., Contreras D. 2007. A molecular phylogenetic analysis of the Oedipodinae and their intercontinental relationships. Journal of Orthoptera Research 16: 115-125.
Fuller S., Schwarz M., Tierney S. 2005. Phylogenetics of the allodapine bee genus Braunsapis: historical biogeography and long-range dispersal over water. Journal of Biogeography 32: 2135-2144.
Gaunt M.W., Miles M.A. 2002. An insect molecular clock dates the origin of the insects and accords with palaeontological and biogeographic landmarks. Molecular Biology and Evolution 74: 748-761.
Goldblatt P. 1993. Biological relationships between Africa and South America: An overview, pp. 3-14. In: Goldblatt P. (Ed.) Biological relationships between Africa and South America. Yale University Press. New Haven, Connecticut.
Hebard M. 1935. Notes on the Group Gomphoceri and a key to its genera, including one new genus (Orthoptera, Acrididae, Acridinae). Entomological News 46: 184-188.
Hollis D. 1967. New combinations affecting the genus Aiolopus (Orthoptera: Acridoidea) and a description of a related new genus and species from Australia. Journal of Natural History 1: 157-162.
Huang Y., Orti G., Sutherlin M., Duhachek A., Zera A. 2000. Phylogenetic relationships of North American field crickets inferred from mitochondrial DNA data. Molecular Phylogenetics and Evolution 17: 48-57.
Huelsenbeck J.P., Ronquist F. 2001. MRBAYES: Bayesian inference of phylogenetic trees. Bioinformatics 8: 754-755.
Jacobs B.F., Kingston J.D., Jacobs L.L. 1999. The origin of grass-dominated ecosystems. Annals Missouri Botanical Garden 86: 590-643.
Jago N.D. 1971. A review of the Gomphocerinae of the world with a key to the genera (Orthoptera: Acrididae). Proceedings Academy of Natural Sciences of Philadelphia 1234: 205- 343.
Jago N.D. 1983. The breakup of Pangaea and prediction of numbers of subfamily elements, living and extinct, in Acridoidea. Proceedings 2nd Triennial Meeting. Pan American Acridological Society. Bozeman. Montana. 1979.
Jago N.D. 1996a. Song, sex and synonymy: the Palaearctic genus Acrida Linnaeus (Orthoptera, Acrididae, Acridinae) and synonymy of the subfamily Truxalinae under the subfamily Acridinae. Journal of Orthoptera Research 5: 125-129.
Jago N.D. 1996b. Review ofwestern and eastern African genera of the Dnopherula complex (Orthoptera, Acridoidea, Gomphocerinae) with description of new genera and species. Journal of Orthoptera Research 5: 69-124.
Jonsson K.A., Fjeldsa J. 2006. Determining biogeographical patterns of dispersal and diversification in oscine passerine birds in Australia, Southeast Asia and Africa. Journal of Biogeography 33: 1155-1165.
Kelly C.D. 2005. Understanding mammalian evolution using Bayesian phylogenetic inference. Mammalian Review 35: 188-198.
Key K. H. L. 1959. The ecology and biogeography of Australian grasshoppers and locusts. Monographie Biologicae 8: 192-210.
Labandeira C.C. 1994. A compendium of fossil insect families. Milwaukee Public Museum Contributions in Biology & Geology. Number 88.
Lane E. (Ed.) 1994. Florida's geological history and geological resources. Special Publication No 35. Florida Geological Survey, Tallahassee, FL.
Leys R., Cooper S.J.B., Schwarz M.P. 2002. Molecular phylogeny and historical biogeography of the large carpenter bees, genus Xylocopa (Hymenoptera: Apidae). Biological Journal of the Linnean Society 77: 240-266.
Litzenberger G., Chapco W. 2001a. Molecular phylogeny of selected Eurasian podismine grasshoppers (Orthoptera: Acrididae). Annals Entomological Society of America 94: 505-551.
Litzenberger G., Chapco W. 2001b. A molecular phylogeographic perspective on a fifty-year-old taxonomic issue in grasshopper systematics. Heredity 86: 54-59.
Lovejoy N.R., Mullen S.P., Sword G.A., Chapman R.F., Harrison R.G. 2006. Ancient trans-Atlantic flight explains locust biogeography: molecular phylogenetics of Schistocerca. Proceedings Royal Society B 273: 767-774.
Lu H.-H., Huang Y. 2006. Phylogenetic relationship of 16 Oedipodidae species (Insecta: Orthoptera) based on the 16S rRNA gene sequences. Insect Science 13: 103-108.
Lui D., Dong Z., Zhang D., Gu Y., Guo P., Han R., Hang G. 2008. Molecular phylogeny ofthe higher category of Acrididae (Orthoptera: Acridoidea). Zoological Research 29: 585-591.
Ma C., Liu C., Yang P., Kang L. 2009. The complete mitochondrial genomes of two band-winged grasshoppers, Gastrimargus marmoratus and Oedaleus asiaticus. Genomics 10: 156-173.
Maddison W.P., Maddison D.R. 2004. MacClade: analysis of phylogeny and character evolution. Version 4.05. Sinauer, Sunderland, MA.
Maekawa K., Lo N., Rose H.A., Matsumoto T. 2003. The evolution of soilburrowing cockroaches (Blattaria: Blaberidae) from wood-burrowing ancestors following an invasion of the latter from Asia into Australia. Proceedings Royal Society of London B 270: 1301-1307.
Micheels A., Eronen J., MosbruggerV. 2009. The late Miocene climate response to a modern Sahara desert. Global and Planetary Change 67: 193-204.
Otte D. 1981. The North American Grasshoppers. Volume I. Acrididae. Gomphocerinae and Acridinae. Harvard University Press. Cambridge, Massachusetts.
Otte D. 1984. The North American Grasshoppers. Volume II. Acrididae. Oedipodinae. Harvard University Press. Cambridge, Massachusetts.
Page R.D.M., Holmes E.C. 1998. Molecular Evolution. A Phylogenetic Approach. Blackwell, Oxford.
Petit D., Picaud F., Elghadraoui L. 2006. Geometrie morphologique des ailes des Acrididae (Orthoptera: Caelifera): sexe, stridulation, caractere. Annales Societe Entomologique de France (Nouvelle Serie) 42: 63-73.
Pitman W.C., Cande S., LaBrecque J., Pindell J. 1993. Fragmentation of Gondwana: The separation of Africa from South America, pp 15-34. In: Goldblatt P. (Ed.) Biological relationships between Africa and South America. Yale University Press. New Haven, Connecticut.
Posada D., Crandall K.A. 1998. Modeltest: testing the model of DNA substitution. Bioinformatics 14: 817-818.
Rehn J.A.G. 1958. The origin and affinities ofthe Dermaptera and Orthoptera of western North America. In: Hubbs C.L. (Ed.) Zoogeography 12. Horn-Shafer, Baltimore, MD.
Reinink-Smith L.M., Leopold E.B. 2005. Warm climate in the late Miocene of the south coast of Alaska and the occurrence of Podocarpaceae pollen. Palynology 29: 205-262.
Rentz D.C.F., Lewis R.C., Su Y. N., Upton M. S. 2004. A Guide to Australian Grasshoppers and Locusts. Natural History Publications. Borneo.
Ritchie J.M. 1981. A taxonomic revision of the genus Oedaleus Fieber (Orthoptera: Acrididae). Bulletin British Museum of Natural History (Entomology) 42: 83-183.
Ritchie J.M. 1982. A taxonomic revision ofthe genus Gastrimargus Saussure (Orthoptera: Acrididae). Bulletin British Museum of Natural History (Entomology) 44: 239-329.
Ronquist F. 1996. DIVA, Version 1.1 Computer program and manual available by anonymous FTP from Uppsala University at ftp.uu.se or ftp.sysbot.uu.se.
Ronquist F. 1997. Dispersal-vicariance analysis: a new approach to the quantification ofhistorical biogeography. Systematic Biology 46: 195-203. Rowell C.H.F., Flook P.K. 1998. Phylogeny of the Caelifera and the Orthoptera as derived from ribosomal gene sequences. Journal of Orthoptera Research 7: 147-156.
Rowell C.H.F., Flook P.K. 2004. A dated molecular phylogeny of the Proctolabinae (Orthoptera: Acrididae), especially the Lithoscirtae, and the evolution of their adaptive traits and present biogeography. Journal of Orthoptera Research 13: 35-56.
Sanderson M.J. 2002. Estimating absolute rates of molecular evolution and divergence times: a penalized likelihood approach. Molecular Biology and Evolution 19: 101-109.
Sanderson M.J. 2004. r8s. Published privately, Davis. Available from: http://ginger.ucdavis.edu/r8s/.
Sanmartin I., Ronquist R. 2004. Southern hemisphere biogeography inferred by even-based models: plant versus animal patterns. Systematic Biology 53: 216-243.
Simons M.P., Pickett K.M., Miya M. 2004. How meaningful are Bayesian support values? Molecular Biology and Evolution 21: 188-199.
Smith A.G., Smith D.G., Funnell B.M. 2004. Atlas ofMesozoic and Cenozoic Coastlines. Cambridge University Press. Cambridge, UK.
Stauffer T.W., Whitman D.W. 1997. Grasshopper oviposition, pp 231-280. In: Gangwere S.K., Muralirangan M.C., Muralirangan M. (Eds) The Bionomics of Grasshoppers, Katydids and their Kin. CAB International, New York, NY.
Suzuki Y., Glazko G.V., Nei M. 2002. Overcredibility ofmolecular phylogenies obtained by Bayesian phylogenetics. Proceedings National Academy of Sciences 99: 16138-16143.
Swofford D. L. 2003. PAUP*: Phylogenetic Analysis Using Parsimony (*and Other Methods). Version 4.0b10. Sinauer, Sunderland, MA.
Vickery V.R. 1967. The Orthoptera of Alaska, Yukon and the Mackenzie district of the Northwest Territories. Transactions American Entomological Society 93: 249-278.
Vickery V.R. 1987. The northern Nearctic Orthoptera: their origins and survival. In: Baccetti B.C. (Ed.) Evolutionary Biology of Orthopteroid Insects. Ellis Horwood Limited, West Sussex, UK.
VickeryV.R. 1989. The biogeography ofCanadian Grylloptera and Orthoptera. Canadian Entomologist 121: 389-424.
Voelker G. 1999. Dispersal, vicariance, and clocks: historical biogeography and speciation in a cosmopolitan passerine genus (Anthus: Motacillidae). Evolution 53: 1536-1552.
Whitman D.W. 1990. Grasshopper chemical communication, pp 357-391. In: Chapman R.F., Joern A. (Eds) Biology of Grasshoppers. John Wiley and Sons. New York, NY.
Wilcox T.P., Zwickl D.J., Heath T.A., Hillis D.M. 2002. Phylogenetic relationships of the dwarf boas and a comparison of Bayesian and bootstrap measures of phylogenetic support. Molecular Phylogenetics and Evolution 25: 361-371.
Yang Z., Rannala B. 2005. Branch-length prior influences Bayesian posterior probability of phylogeny. Systematic Biology 54: 455-470.
Yin X.-C., Li X.-J., Wang W.-Q., Yin H., Cao C.-Q., Ye B.-H., Yin Z. 2008. Phylogenetic analyses of some genera in Oedipodinae (Orthoptera: Acridoidea) based on 16S mitochondrial partial gene sequences. Insect Science 15: 471-476.
Zeuner F.E. 1939. Fossil Orthoptera Ensifera. British Museum, London, UK.
Zhang D.-X., Hewitt G.M. 1996. Nuclear integrations: challenges for mitochondrial DNA markers. Trends in Ecology and Evolution 11: 247-251.
Zwickl D.J., Hillis D.M. 2002. Increased taxon sampling greatly reduces phylogenetic error. Systematic Biology 51: 588-598.
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William Chapco and Daniel Contreras
Department of Biology, University of Regina, Regina, Saskatchewan, Canada S4S 0A2. [WC] Email: William.Chapco@uregina.ca [DC] Email: email@example.com
Table 1. Species analyzed, locations and GenBank Accession numbers of mtDNA sequences. Subfamily/Tribe ([dagger]) Species Oedipodinae /Acrotylini Acrotylus insubricus /Aiolopini Aiolopus strepens Duroniella fracta Heteropternis couloniana Heteropternis obscurella Paracinema tricolor /Arphiini Arphia conspersa /Bryodemini Angaracris barabensis Bryodema luctuosum Circotettix carlinianus /Chortophagini Chorthophaga viridifasciata Encoptolophus costalis /Hippiscini Camnula pellucida Pardalophora apiculata /Locustini Gastrimargus africanus Gastrimargus determinatus Gastrimargus musicus Locusta migratoria Oedaleus decorus /Macherocerini Machaerocera mexicana /Oedipodini Celes variabilis Oedipoda miniata /Parapleurini Stethophyma gracile Stethophyma grossum /Psinidiini Trachyrhachys kiowa /Sphingonotini Dissosteira carolina Spharagemon campestris Spharagemon collare Sphingonotus caerulans Sphingonotus pachecoi Trimerotropis pallidipennis Trimerotropis pistrinaria /Unassigned Austroicetes sp. Chortoicetes terminifera Morphacris fasciata Gomphocerinae /Acrolophitini Acrolophitus hirtipes Bootettix argentatus /Amblytropidiini Amblytropidia australis Amblytropidia mysteca Boopedon nubilum Sinipta dalmani Syrbula admirablis /Arcypterini Arcyptera fusca Ptygonotus gansuensis Ramburiella turcomana Rhaphotittha levis /Aulocarini Ageneotettix deorum Aulocara elliotti Psoloessa delicatula /Chorthipini Chorthippus curtipennis Chorthippus parallelus Euchorthippus pulvinatus Glyptobothrus binotatus Glyptobothrus jacobsi /Chrysochraontini Chloealtis abdominalis Chloealtis conspersa Chrysochraon dispar Euthystira brachyptera /Compsacrini Staurorhectus longicornus /Dnopherulaini Amesotropis valga /Dociostaurini Dociostaurus jagoi /Eritettigini Amphitornus coloradus Eritettix simplex Opeia obscura /Gomphocerini Aeropedellus arcticus Aeropedellus clavatus Aeropedellus reuteri Aeropedellus variegatus Brunneria brunnea Bruneria yukonensis Gomphocerippus rufus Myrmeleotettix maculatus Phlibostroma quadrimaculatum /Melanotettigini Melanotettix dibelonius /Mirmiriini Achurum carinatum Achurum minimipenne Mermiria bivittata /Ochrilidini Ochrilidia harterti Ochrilidia tibialis /Orphulelini Dichromorpha viridis Orphulella speciosa Orphulina balloui /Paropomala Paropomala wyomingensis group /Scyllinini Jagomphocerus amazonicus Parapellopedon uniformis Rhammatocerus peragrans Rhammatocerus pictus Rhammatocerus schistocercoides /Stenobothrini Omocestus panteli Stenobothrus lineatus /unassigned Pnorisa angulata Pseudogmothela yonlii Stenohippus aequus Stenohippus mundus Thyridota dispar Acridinae /Acridini Acrida bicolor Acrida conica Acrida turrita Caledia captiva Comacris lamottei Froggattina australis /Hyalopterygini Metaleptea adspersa Parorphula graminea /Phlaeobini Holopercna gerstaeckerii /Truxalini Truxalis nasuta /unassigned Anaeolopus socius Cannula karschi Covasacris pallidinota Duronia chloronota Eutryxalis filata Gymnobothrus temporalis Odontomelus scalatus Odontomelus togoensis Orthochtha dasycnemis Parga lamottei Sherifuria haningtoni Zacompsa festa Outgroup Pyrgomorpha conica Subfamily/Tribe ([dagger]) Source Oedipodinae /Acrotylini Malatya, Turkey (CD) /Aiolopini Sierra Nevada, Spain (CDEF) Malatya, Turkey (CD) Mt Nimba, Guinea (D) Newcastle, Australia (F) [double dagger]loc?, South Africa (CD) /Arphiini Jameson, SK, Can (A) /Bryodemini Gansu Prov., China (C) Gansu Prov., China (C) Condie, SK, Can (A) /Chortophagini Jameson, SK, Can (A) Regina, SK, Can (A) /Hippiscini Bummer, SK, Can (A) Jameson, SK, Can (A) /Locustini Niamey, Niger (DE) Mt Nimba, Guinea (D) Newcastle, Australia (F) Genbank (CDEF) Massif Central, France (CDEF) /Macherocerini Oaxaca, Mexico (A) /Oedipodini Massif Central, France (C) Erzingan, Turkey (C) /Parapleurini Last Mountain, SK, Can (A) Massif Central, France (C) /Psinidiini Condie, SK, Can (A) /Sphingonotini Bimidji, WI, USA Condie, SK, Can (A) Jameson, SK, Can (A) Sierra Nevada, Spain (BCDEF) El Llano, Canary Is. (CD) Uspallata, Argentina (AB) Findlater, SK, Can (A) /Unassigned Canberra, Australia (F) Merriwah, Australia (F) Niamey, Niger (CDE) Gomphocerinae /Acrolophitini Findlater, SK, Can (A) Las Tablas, Mexico (A) /Amblytropidiini Cerro Azul, Argentina (B) loc?, FL, USA (B) Newcastle, WY, USA Benito Juarez, Argentina (B) loc?, FL, US (AB) /Arcypterini Massif Central, France (C) Gansu Prov, China (C) Mulatya, Turkey (CD) loc?, South Africa (CDE) /Aulocarini Torrington, WY, USA Torrington, WY, USA Last Mnt, SK, Can (A) /Chorthipini Pinawa, MB, Can (A) Budapest, Hungary (C) Sierra Nevada, Spain (C) Sierra Nevada, Spain (C) Sierra Nevada, Spain (C) /Chrysochraontini Jameson, SK, Can (A) Dilke, SK, Can (A) Massif Central, France (AC) Budapest, Hungary (C) /Compsacrini La Pampa, Argentina (B) /Dnopherulaini 06" 13'N, 05" 02'W, Ivory Coast (D) /Dociostaurini Sierra Nevada, Spain (CDE) /Eritettigini Dilke, SK, Can (A) Cypress Hills, SK, Can (A) Last Mountain, SK, Can (A) /Gomphocerini McKinley Park, AK, US (A) Dilke, SK, Can (A) Khakasia, Russia (C) Montpellier, France (C) Dilke, SK, Can (A) Kluane Nat'l Park, YT, Can (A) Massif Vercors, France (C) Bledwowska Desert, Poland (C) Dilke, SK, Can (A) /Melanotettigini Guerrero, Mexico (AB) /Mirmiriini loc?, FL, US (A) Tamaulipas, Mexico (A) Goshen County, WY, US (A) /Ochrilidini Niamey, Niger (CD) loc? Chad (CD) /Orphulelini loc? FL, US (AB) Wellington, KS, US (AB) Brasilia, Brazil (B) /Paropomala Torrington, WY, US (A) group /Scyllinini Rio Ucayali, Peru (B) Savannah loc, Brazil (B) Manabi, Equador (B) Ojeda, La Pampa, Argentina (B) Cajamarca, Peru (B) /Stenobothrini Sierra Nevada, Spain (CD) Budapest, Hungary (CE) /unassigned loc?, South Africa (D) Tamou Reserve, Niger (D) Tapoa, Niger Niamey, NigerCD loc?, South AfricaD Acridinae /Acridini Malatya, TurkeyCD Silver Valley, QLD, AustraliaF Mt Nimba, GuineaD Moomin, QLD, AustraliaF Mt Nimba, GuineaD Kuranda, QLD, AustraliaF /Hyalopterygini Minas, UruguayAB Rio de Janeiro, BrazilB /Phlaeobini Mt Nimba, GuineaD /Truxalini Gran Canaria, Canary IslandsCDE /unassigned loc?, South AfricaD Mt Nimba, GuineaD Benito Juarez, ArgentinaB Niamey, NigerD Madre de Dios, PeruB Mt Nimba, GuineaD Mt Nimba, GuineaD Mt Nimba, GuineaD Lac Tanma, SenegalDE Mt Nimba, GuineaD Niamey, NigerD La Tapoa, NigerD Outgroup Malatya, TurkeyABCDEF Subfamily/Tribe ([dagger]) Accession Nos CO1, CO2, cytb, nd5, 16S Oedipodinae /Acrotylini EF151836, EF151816, EF151870, EF151904, JF932395 /Aiolopini EF151841, EF151821, EF151875, EF151907, JF932400 DQ230738, DQ230807, DQ230827, DQ230774, -- EF151858, EF151830, EF151892, EF151920, JF932431 JN167816, --, JN167889, JN016776, JF932432 JN167829, JN002142, --, JN016786, JF932444 /Arphiini EF151839, EF151819, EF151873, --, U18065 /Bryodemini EF151856,--, EF151890, --, -- EF151854, EF151829, EF151888, EF151917, JF932410 EF151845, --, EF151879, EF151909, U18068 /Chortophagini EF151864, --, EF151899, EF151924, JF932415 EF151850, EF151827, EF151884, EF151913, JF932419 /Hippiscini JN167804, --, JN167870, JN016767, JF932411 --, --, JN167905, JN016789, JF932446 /Locustini JN167812, EF151831, EF151893, --, JF932425 JN167813, JN002130, JN167883, --, JF932426 JN167814, JN002131, JN167884, JN016774, -- X80245 EF151834, EF151814, EF151868, EF151903, -- /Macherocerini EF151861, --, EF151896, EF151923, JF932435 /Oedipodini EF151855, JN002120, EF151889, EF151918, -- EF151840, EF151820, EF151874, EF151906, JF934441 /Parapleurini DQ230737, DQ230806, DQ230826, DQ230773, -- DQ230735, DQ230804.-- , DQ230771, JF932460 /Psinidiini EF151846, --, EF151880, EF151910, JF932461 /Sphingonotini EF151851, EF151828, EF151885, EF151914, JF932417 EF151838, EF151818, EF151872, --, U18070 EF151852, --, EF151886, EF151915, U18071 EF151844, EF151824, EF151878, EF151908, -- EF151857, --, EF151891, EF151919, JF932463 EF151863, --, EF151898, --, -- EF151848, EF151825, EF151882, EF151911, U18069 /Unassigned EF185880, --, EF185881, --, JF932406 EF185877, EF185876, EF185878, EF185879, -- JN167821, JN002136, JN167894, --, JF932437 Gomphocerinae /Acrolophitini JN167787, --, JN167852, JN016751, -- JN167802, JN002117, JN167866, JN016765, JF932408 /Amblytropidiini JN167794, JN002111, JN167859, JN016757, -- JN167795, --JN167860, JN016758, JF932401 JN167801, JN002116, --, JN016764, JF932407 JN167842, --, JN167916, JN016796, -- JN167846, JN002157, JN167920, JN016800, -- /Arcypterini JN167800, --, JN167864, JN016763, JF932404 DQ230736, DQ230805, -- , DQ230772, -- DQ230710, DQ230780, JN167912, DQ230744, JF932453 JN167835, JN002147, JN167908, --, JF932449 /Aulocarini DQ230718, DQ230789, --, DQ230753, JF932399 DQ230719, JN002115, JN167865, DQ230754, JF932405 JN167838, JN002150, JN167911, JN016793, JF932452 /Chorthipini DQ230709, DQ230779, JN191382, DQ230743, JF932414 DQ230723, DQ230793, JN167873, DQ230758, -- DQ230711, DQ230781, JN167879, DQ230745, JF932421 DQ230724, DQ230794, JN167885, DQ230759, JF932427 DQ230725, DQ230795, JN167886, DQ230760, JF932428 /Chrysochraontini JN167823, DQ230787, DQ230817, DQ230751, -- JN191385, JN002121, JN167872, JN016768, JF932413 DQ230730, DQ230800, JN191383, DQ230766, -- DQ230726, DQ230796, JN167880 , DQ230761, JF932422 /Compsacrini JN167843, --, JN167917, JN016797, -- /Dnopherulaini JN167796, JN002112, JN167861, JN016759, JF932402 /Dociostaurini DQ230734, JN002125, JN167876, DQ230770, JF932418 /Eritettigini JN167798, JN002114, * (in appendix), JN016761, JF932403 JN167809, JN002127, JN167878, JN016772, JF932420 JN167827, JN002140, JN167900, JN016783, JF932443 /Gomphocerini JN167792, JN002109, -- , JN016754, JF932396 DQ230708, DQ230777, EF565468, DQ230741, JF932397 JN167793, JN002110, JN167858, JN016755, JF932398 DQ230712, DQ230782, DQ230812, JN016756, -- DQ230707, DQ230776, JN167867, DQ230740, JF932409 JN167803, JN002118, JN167868, JN016766, -- DQ230733, DQ230803, JN167887, DQ230769, JF932429 JN167822, JN002137, JN167895, JN016781, JF932438 JN167834, DQ230778, DQ230808, DQ230742, JF932448 /Melanotettigini JN167818, JN002134, JN167891, JN016778, -- /Mirmiriini DQ230717, DQ230788, JN167853, DQ230752, -- JN167788, JN002105, JN167854, --, JF932394 JN167819, JN002135, JN167892, JN016779, JF932436 /Ochrilidini JN167824, --, JN167896, --, JF932439 JN167825, --, JN167897, --, -- /Orphulelini JN167807, JN002124, JN167875, JN016770, -- JN167828, JN002141, JN167901, JN016784, -- --, --, JN167902, JN016785, -- /Paropomala JN167831, JN002144, JN167904, group JN016788, JF932445 /Scyllinini -- , JN002133, * (in appendix), -- , -- JN167830, JN002143, JN167903, JN016787, -- JN167841, JN002153, JN167915, --, JF932456 JN167839, JN002151, JN167913, JN016794, JF932454 JN167840, JN002152, JN167914, JN0167895, JF932455 /Stenobothrini DQ230728, DQ230798, JN167899, DQ230763, JF932442 DQ230729, JN002154, DQ230820, DQ230764, JF932457 /unassigned JN167836, JN002148, JN167909, JN016791, JF932450 JN167837, JN002149, JN167910, JN016792, JF932451 JN167844, JN002155, JN167918, JN016798, JF932458 JN167845, JN002156, JN167919, JN016799, JF932459 JN167847, JN002158, JN167921, --, (* in appendix) Acridinae /Acridini JN167789, JN002106, JN167855, JN016752, -- JN167790, JN002107, JN167856, JN016753, -- JN167791, JN002108, JN167857, -- (* in appendix) -- , JN002119, JN167869, --, -- JN167806, JN002122, JN167874, JN016769, -- JN167811, JN002129, JN167882, --, JF932424 /Hyalopterygini JN167820, --, JN167893, JN016780, -- JN167833, JN002146, JN167907, --, JF932447 /Phlaeobini JN167817, --, JN167890, JN016777, JF932433 /Truxalini JN167848, JN002159, JN167922, JN016801, JF932462 /unassigned JN167799, --, JN167863, JN016762, -- JN167805, --, JN167871, JN016767, JF932411 DQ230739, JN002123, JN191384, DQ230775, JF932416 JN167808, JN002126, JN167877, JN016771, -- JN167810, JN002128, JN167881, JN016773, JF932423 JN167815, -- (* in appendix), JN167888, JN016775, JF932430 JN167797, JN002113, JN167862, JN016760, -- JN167826, JN002139, JN167898, JN016782, JF932440 JN167851, JN002162, JN167925, JN016803, JF932466 JN167832, JN002145, JN167906, JN016790, -- JN167850, JN002161, JN167924, --, JF932465 JN167849, JN002160, JN167923, JN016802, JF932464 Outgroup EU031777, EU031776, EU031778, EU031779, JF932467 [dagger]- according to the OSF2; [double dagger] - loc? = unknown location; dashes signify no sequence obtained; * sequences placed in Appendix; Biogeographical Regions: A = Nearctic, B = Neotropics, C = Palaearctic, D = Africa, E = Oriental, F = Australia; Can = Canada; US = United States; MB - Manitoba, SK - Saskatchewan, YT - Yukon Territories, WI - Wisconsin, WY - Wyoming, FL - Florida, AK - Alaska, KS - Kansas.
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|Author:||Chapco, William; Contreras, Daniel|
|Publication:||Journal of Orthoptera Research|
|Date:||Jul 1, 2011|
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