Bembridae

Bembridae View in CoL View at ENA , Hoplichthyidae , Platycephalidae , and Triglidae .—

Traditionally, the Bembridae , Hoplichthyidae , and Platycephalidae have been treated as a single evolutionary unit ( Matsubara, 1943; Washington et al., 1984; Fig. 1 View FIG ). As first noted by Imamura (1996), explicit analyses of ‘‘platycephaloid’’ relationships do not recover bembrids in a clade with the hoplichthyids and platycephalids. Instead, Imamura’s (1996) study demonstrated that Platycephalidae was sister to a clade of Hoplichthyidae þ Triglidae . These three families were then hypothesized to be sister to Bembras , and that clade was subsequently hypothesized to be sister to Parabembras ( Imamura, 1996; Fig. 1 View FIG ). Our results support Imamura’s (1996) hypothesis that Platycephalidae is sister to a clade composed of Hoplichthyidae þ Triglidae . However, our results place this Hoplichthyidae þ Platycephalidae þ Triglidae clade sister to all other scorpaenoids. This relationship supports the view that the less flattened bembrids are more closely related to scorpionfishes and stonefishes than to hoplichthyids, platycephalids, and triglids.

The Bembridae View in CoL is a small, deep-water Indo-Pacific marine family whose limits have varied across studies. Jordan and Hubbs (1925) first separated the Parabembridae View in CoL from the Bembridae View in CoL , but this separation was not followed in most subsequent studies. For example, Washington et al. (1984) and Nelson (2006) included Bambradon View in CoL , Bembradium View in CoL , Bembras View in CoL , Brachybembras View in CoL (not discussed in Washington et al. [1984]), and Parabembras View in CoL in their Bembridae View in CoL . Imamura (1996) not only recognized a separate Bembridae View in CoL and Parabembridae View in CoL , but he also classified one traditional bembrid, Bembradium View in CoL , as a member of the Plectrogeniidae View in CoL . Molecular studies have not sufficiently sampled the Bembridae View in CoL , and they have recovered their included bembrids sister to Congiopodidae View in CoL , Hoplichthyidae View in CoL , Platycephalidae View in CoL , Plectrogeniidae View in CoL , Synanceiidae View in CoL , or a clade composed of the Bembropidae þ Scorpaenidae View in CoL ( Smith and Wheeler, 2004, 2006; Smith and Craig, 2007; Lautredou et al., 2013; Near et al., 2013; Smith et al., 2016; Betancur-R. et al., 2017). Molecular studies that have included Bembras View in CoL and Parabembras View in CoL have consistently resulted in these genera forming a clade ( Near et al., 2013, 2015; Betancur-R. et al., 2017), thus not requiring the recognition of a separate family-level status for Parabembridae View in CoL . The current study is the first study with molecular data that included Bembradium View in CoL , Bembras View in CoL , and Parabembras View in CoL . Given the alignment of Bembradium View in CoL with Plectrogenium View in CoL and the separate grouping of Bembras View in CoL and Parabembras View in CoL , we recommend classifying Bambradon View in CoL , Bembras View in CoL , Brachybembras View in CoL , and Parabembras View in CoL as a revised Bembridae View in CoL (Appendix 2). Further, and as discussed below, our findings support the results of Imamura (1996) who placed Bembradium View in CoL and Plectrogenium View in CoL in the Plectrogeniidae View in CoL . We recovered the Bembridae View in CoL sister to a clade composed of Neosebastidae View in CoL þ Plectrogeniidae View in CoL þ Scorpaenidae View in CoL þ Synanceiidae View in CoL ( Fig. 3 View FIG ). This sister group relationship is supported by the loss of the lateral-line canal on the pterotic (character 22, state 0), two spines on the first dorsal-fin pterygiophore (character 56, state 0), and the presence of an adductor dorsalis (character 100, state 0).

The Hoplichthyidae View in CoL is an Indo-Pacific marine family of 17 species that has been variously classified among mail-cheeked fishes but has been allied generally with the platycephalids. Traditional higher-level phylogenetic studies (e.g., Gill, 1888; Regan, 1913; Matsubara, 1943; Quast, 1965; Washington et al., 1984) placed the hoplichthyids as a separate family, closely related to the platycephalids. Greenwood et al. (1966) had a similar classification, but they treated the hoplichthyids as their own suborder, Hoplichthyoidei. Winterbottom (1993) suggested that the hoplichthyids might even be close relatives to the gobioids, so the family’s placement has been historically varied. As noted above, Imamura (1996) first suggested that hoplichthyids are more closely related to the triglids than the platycephalids, and his results suggested that Hoplichthys View in CoL was sister to a clade composed of Peristedion View in CoL þ Satyrichthys View in CoL . Molecular data, beginning with Smith and Wheeler (2004), have suggested alternative placements for the hoplichthyids ranging from a close relationship with Ovalentaria to sister to the Bembridae View in CoL , Normanichthyidae View in CoL , Synanceiidae View in CoL , a clade composed of Bembridae View in CoL þ Platycephalidae View in CoL , a clade composed of the ‘‘cottoids and allies’’ (Anoplopomatoidei, Cottoidei, Gasterosteioidei, Hexagrammoidei, and Zaniolepidoidei) þ Triglidae View in CoL , a clade composed of Cottoidei þ Gasterosteioidei þ Hexagrammoidei þ Triglidae View in CoL þ Zoarcoidei, and a clade composed of the ‘‘cottoids and allies’’ þ Scorpaenidae View in CoL þ Triglidae View in CoL ( Smith, 2005; Smith and Wheeler, 2006; Smith and Craig, 2007; Lautredou et al., 2013; Near et al., 2013, 2015; Smith et al., 2016; Betancur-R. et al., 2017; Fig. 2 View FIG ). Our results ( Fig. 3 View FIG ) place the Hoplichthyidae View in CoL sister to the Triglidae View in CoL , similar to the findings of Imamura (1996, 2004; Fig. 1 View FIG ). This sister group relationship is supported by the presence of tubercles on the neurocranium (character 13, state 1), the loss of one postcleithrum (character 48, state 1), the increase in the number of free pectoral-fin rays to three or more (character 49, state 3), the fusion of the cartilaginous caps on the anterior portion of the pelvis (character 51, state 1), the presence of a hyohyoides inferioris (character 84, state 1), the attachment of dorsal elements of pelvic-fin muscles to the pectoral girdle (character 97, state 1), and the obliquus superioris bypassing and lying ventrally to Baudelot’s ligament (character 104, state 1). As with the Congiopodidae View in CoL , the placement of the hoplichthyids is inconsistent across studies. Most studies ally the hoplichthyids more with the Triglidae View in CoL (often combined with the included ‘‘cottoids and allies’’). Given the ambiguity, we recommend treating the Hoplichthyidae View in CoL , diagnosed by 20 morphological synapomorphies (Appendix 2), as a separate scorpaenoid family.

The Platycephalidae View in CoL is a modestly large family of 84 species that is found in brackish and marine environments in the Indo-Pacific region ( Nelson, 2006). As has been found in previous studies, the Hoplichthyidae View in CoL and Platycephalidae View in CoL were recovered as independent monophyletic groups with the traditional limits ( Keenan, 1991; Imamura, 1996; Appendix 2; Fig. 3 View FIG ). The interrelationships of the family have been discussed above, and our results support the findings of Imamura (1996) that the Triglidae View in CoL þ Hoplichthyidae View in CoL is recovered as the sister group to the platycephalids. This sister group relationship is supported by the presence of a tooth plate on the second epibranchial (character 39, state 1). Additionally, our limited sampling of platycephalids corroborates the phylogeny and classification presented in Imamura (1996).

The Triglidae View in CoL is a large family of 171 species that are found in tropical, temperate, and deep-water habitats across all oceans ( Nelson, 2006). Traditional classifications (e.g., Gill, 1888; Matsubara, 1943; Washington et al., 1984; Imamura, 1996; Eschmeyer View in CoL et al., 2017) often treat the Peristediidae View in CoL and Triglidae View in CoL as independent, closely related families. Our study corroborates the findings of Smith (2005) and Portnoy et al. (2017) that place the traditional peristediids (our peristediines) within the Triglidae View in CoL . Other than the placement of peristediines inside the triglids, our hypothesized relationships support the phylogenies of Imamura (1996) and Richards and Jones (2002). Similarly, our phylogeny supports the phylogeny of Portnoy et al. (2017), including the placement of peristediines inside the Triglidae View in CoL . This placement and resulting expansion (and monophyly) of the Triglidae View in CoL is supported by both morphological and molecular data, and our study recovers seven characters supporting the monophyly of this expanded family (Appendix 2).

Neosebastidae View in CoL and Plectrogeniidae View in CoL .— The placement of Neosebastidae View in CoL and Plectrogeniidae View in CoL has been historically problematic; they are often represented as early diverging scorpaenoid lineages or ‘‘ancestral’’ forms ( Matsubara, 1943; Imamura, 1996). Although the current study is the first study to unite these two families ( Fig. 3 View FIG ), Imamura (2004), Smith and Wheeler (2004, 2006), Smith and Craig (2007), and Smith et al. (2016) have often found them relatively closely related. In this study, this sister-group relationship was supported by the separation of the first and second hypurals (character 68, state 0).

The Neosebastidae View in CoL is a predominantly anti-tropical Indo-Pacific marine family of 18 species that has been often separated from the core scorpionfishes in a separate family or subfamily in modern phylogenies and classifications ( Imamura, 2004; Motomura, 2004; Nelson, 2006). Beginning with Matsubara (1943) and supported by Washington et al. (1984) and Nelson (2006), the Neosebastidae View in CoL has been treated as a separate subfamily (Neosebastinae) of the Scorpaenidae View in CoL . Matsubara (1943) hypothesized that the neosebastids were allied with the sebastines, and Ishida (1994; Fig. 1 View FIG ) allied the neosebastids with the setarchines and recognized them as a separate family. Imamura (2004; Fig. 1 View FIG ) also recognized the clade as a separate family and suggested a non-scorpaenid relationship for the neosebastids; he resolved them with the more flattened scorpaenoids in the families Bembridae View in CoL , Hoplichthyidae View in CoL , Platycephalidae View in CoL , Plectrogeniidae View in CoL , and Triglidae View in CoL . Molecular studies have grouped the neosebastids with several non-scorpaenoid groups (e.g., Acanthistius View in CoL or bembropids; Smith and Wheeler, 2006; Smith et al., 2016) or with congiopodids ( Smith and Wheeler, 2004; Smith and Craig, 2007). Our finding of a Neosebastidae View in CoL þ Plectrogeniidae View in CoL clade adds additional complications to the placement of the Neosebastidae View in CoL , but this result is closer to the findings of Imamura (2004) and several molecular studies (e.g., Smith and Wheeler, 2004, 2006) that have plectrogeniids among the closest relatives of the neosebastids.

Species in the Plectrogeniidae View in CoL are relatively widespread with collections ranging from the western Indian Ocean to Hawaii despite the family including just four species ( Imamura, 1996; Nelson, 2006; Eschmeyer View in CoL et al., 2017). Fowler (1938) first emphasized the distinctiveness of Plectrogenium View in CoL . Matsubara (1943) supported Fowler’s (1938) assertion, suggesting that the genus may represent the ancestral condition of some of the deeper water, flattened scorpaenoids. He noted that Plectrogenium View in CoL shared the loss of the gas bladder and the presence of several rows of prominent head spines and notched pectoral fins with some scorpaenids (e.g., Sebastolobus View in CoL ) while also showing characteristics in common with the bembrids. Washington et al. (1984) further corroborated this hypothesis by pointing to similarities in the scales and caudal fin between Parabembras View in CoL and Plectrogenium View in CoL . Subsequently, Imamura (1996, 2004) supported a placement of an expanded Plectrogeniidae View in CoL (including Bembradium View in CoL ) sister to the clade composed of Bembridae View in CoL þ Hoplichthyidae View in CoL þ Platycephalidae View in CoL þ Triglidae View in CoL that was united by the presence of a posterior pelvic fossa. Molecular studies have not fully supported or refuted these morphological hypotheses. Smith and Wheeler (2004) and Smith and Craig (2007) recovered Plectrogenium View in CoL sister to Bembridae, Lautredou et al. (2013) View in CoL recovered Bembradium View in CoL sister to Synanceiidae View in CoL (their analysis did not include any bembrids), and Smith et al. (2016) recovered Plectrogenium View in CoL sister to the Scorpaenidae View in CoL . This is the first molecular study to include both Bembradium View in CoL and Plectrogenium View in CoL , and we found a unique relationship for plectrogeniids sister to Neosebastidae View in CoL . The monophyly of the Plectrogeniidae View in CoL (Appendix 2) is supported by five characters and corroborates Imamura’s (1996) hypothesis and the recognition of this distinct family.

Scorpaenidae View in CoL and Synanceiidae View in CoL .— The scorpaenids and synanceiids are the most species-rich clades of scorpaenoids, and the species in these families have often been classified together in whole or in part. Gill (1888) grouped these clades together to the exclusion of all other mail-cheeked fishes. Regan (1913) modified Gill’s (1888) arrangement and united scorpaenids, synanceiids, and triglids in his Scorpaeniformes View in CoL (their studies did not include any representatives of the Neosebastidae View in CoL or Plectrogeniidae View in CoL ). Matsubara (1943; Fig. 1B View FIG ) distributed the core scorpionfishes across his ‘‘ Cocotropus- stem,’’ ‘‘ Scorpaena- stem,’’ and ‘‘ Sebastes View in CoL -stem’’ based primarily on circumorbital differences. His ‘‘ Cocotropus View in CoL -stem’’ was composed of the Japanese synanceiids. His ‘‘ Scorpaena View in CoL -stem’’ was composed of Plectrogenium View in CoL and all non-sebastine scorpaenids. Finally, his ‘‘ Sebastes View in CoL - stem’’ was composed of the Neosebastidae View in CoL and Sebastinae. The classification of Washington et al. (1984) largely followed Matsubara (1943) except that they combined his ‘‘ Scorpaena View in CoL - stem,’’ ‘‘ Sebastes View in CoL -stem,’’ Synanceiinae , Apistus View in CoL , and Cheroscorpaena View in CoL into their more inclusive Scorpaenidae View in CoL . They distributed the remaining synanceiids across four additional families ( Aploactinidae View in CoL , Gnathanacanthidae View in CoL , Pataecidae View in CoL , and Tetrarogidae View in CoL ) and recognized Caracanthus View in CoL as a distinct family from the Scorpaenidae View in CoL . Ishida’s (1994) phylogenetic hypothesis ( Fig. 1C View FIG ) and classification recognized 12 families. As noted above, this phylogeny included Congiopodidae View in CoL , Neosebastidae View in CoL , and Plectrogenium View in CoL nested among the included representatives of the Scorpaenidae View in CoL and Synanceiidae View in CoL . Ishida’s (1994) major groupings largely followed Washington et al. (1984) except that Ishida often recognized clades at higher taxonomic levels. Ishida (1994) elevated Washington et al.’s (1984) Apistinae, Neosebastinae, and Setarchinae to the family level. Ishida’s (1994) Sebastidae View in CoL included Washington et al.’s (1984) Plectrogeniinae, Sebastolobinae, and Sebastinae. Ishida’s (1994) classification included a Synanceiidae View in CoL that incorporated Washington et al.’s (1984) Choridactylinae , Minoinae , and Synanceiinae . Finally, his Scorpaenidae View in CoL was restricted to Washington et al.’s (1984) Pteroinae and Scorpaeninae . As noted by Smith and Wheeler (2004), a computer-aided re-analysis of Ishida’s (1994) matrix recovered many equally optimal trees that were shorter than the tree presented by Ishida (1994). This large assortment of most parsimonious trees resulted in a poorly resolved phylogeny with just three of his families represented by more than one species being recovered as monophyletic: Aploactinidae View in CoL , Congiopodidae View in CoL , and Pataecidae View in CoL . Relative to Ishida (1994), Imamura (2004; Fig. 1D View FIG ) increased the taxon sampling among closely related groups (e.g., Platycephalidae View in CoL , Triglidae View in CoL ) and recovered a largely complementary phylogenetic classification with a few changes. Imamura (2004) recognized a Sebastolobidae at the family level and relegated the Setarchidae View in CoL of Ishida (1994) to a clade within Scorpaenidae View in CoL . Subsequent work by Shinohara and Imamura (2005) also placed Caracanthus View in CoL into the Scorpaenidae View in CoL . Most recently, Honma et al. (2013) recognized a new family Perryenidae View in CoL for a member of Mandrytza’s (2001) Tetrarogidae View in CoL . This new family and Mandrytza’s (2001) earlier treatment of Eschmeyeridae View in CoL as an additional monotypic family based on former waspfishes casts doubt on tetrarogid monophyly. The proliferation of new waspfish families and Smith and Wheeler’s (2004) re-analysis of Ishida’s (1994) dataset that recovers 5–6 distinct clades of tetrarogids (sensu Ishida, 1994) highlights that traditional ‘‘stonefish’’ taxonomy is becoming complicated with substantial evidence for tetrarogid polyphyly and a diversity of families with three or fewer species (traditional Apistidae View in CoL , Eschmeyeridae View in CoL , Gnathanacanthidae View in CoL , Pataecidae View in CoL , and Perryenidae View in CoL ).

As seen with the morphological studies, molecular phylogenies that have included representatives of both the Scorpaenidae View in CoL and Synanceiidae View in CoL have recovered varied phylogenetic results, but the clades themselves have been largely repeated. These studies have also echoed some morphological results. For example, molecular studies, like morphological studies, consistently recover a polyphyletic Tetrarogidae (sensu Ishida, 1994) View in CoL and Plectrogenium View in CoL separate from the sebastines ( Smith and Wheeler, 2004, 2006; Smith and Craig, 2007; Smith et al., 2016). The molecular results have also largely recovered reciprocally monophyletic scorpaenid and synanceiid clades. Smith and Wheeler (2004) recovered independent clades of the Scorpaenidae View in CoL and Synanceiidae View in CoL with a diversity of included taxa (including non-scorpaeniforms) in the MRCA. Smith and Wheeler (2006) recovered the scorpaenids sister to epinephelids and synanceiids sister to the triglids with an MRCA that includes the ‘‘cottoids and allies’’ as well as scorpaenoid and serranid fishes. Smith and Craig (2007) recovered relationships similar to Smith and Wheeler (2006) except that the MRCA excluded the Epinephelidae and included the Anthiadidae , Niphonidae , Percidae View in CoL , Serranidae View in CoL , and Trachinidae View in CoL . With more families sampled, Lautredou et al. (2013) and Smith et al. (2016) recovered a clade composed of Plectrogeniidae View in CoL þ Scorpaenidae View in CoL þ Synanceiidae View in CoL . Finally, Betancur-R. et al. (2017) recovered a clade composed of Scorpaenidae View in CoL þ Synanceiidae View in CoL , but their analysis only included two synanceiids and did not include any congiopodids, neosebastids, or plectrogeniids, so their phylogeny is of limited comparative value. Our current analysis is the first to recover a clade composed of Neosebastidae View in CoL þ Plectrogeniidae View in CoL þ Scorpaenidae View in CoL þ Synanceiidae View in CoL , and this clade was supported by the loss of the fourth circumorbital (character 9, state 1).

Despite continued iterative improvement, the march toward a monophyletic taxonomy based on morphological and molecular data has been incompletely accepted by the major fish classifications (e.g., Nelson, 2006; Nelson et al., 2016; Eschmeyer et al., 2017). For example, Nelson (2006) largely follows the pre-phylogenetic study of Washington et al. (1984) except for the placement of Ishida’s (1994) Tetrarogidae in their Scorpaenidae . Nelson et al. (2016) followed Nelson (2006) except they placed Caracanthus in the Scorpaenidae and recognized Eschmeyeridae as a separate family from their Tetraroginae. Curiously, they left the Tetraroginae within the Scorpaenidae and continued to recognize Perryena in the Congiopodidae despite the evidence for both tetrarogine changes being presented in the same study ( Mandrytza, 2001). In contrast, Eschmeyer et al. (2017) largely followed Ishida (1994) except for the placement of Caracanthus in the Scorpaenidae (presumably following Shinohara and Imamura, 2005) and the recognition of a separate Plectrogeniidae (presumably following Imamura, 1996), Eschmeyeridae (presumably following Mandrytza, 2001), and Perryenidae (presumably following Honma et al., 2013). Betancur-R. et al. (2017) largely followed Eschmeyer et al. (2017) including the retention of a nonmonophyletic (in their study) Scorpaenidae . Presumably, their minimal changes relative to Eschmeyer et al. (2017) are due to limited sampling where only 11 of their 21 platycephaloid, scorpaenoid, or trigloid families were examined. All of these previous studies highlight the need to combine molecular and morphological data to generate a complete and holistic phylogenetic hypothesis that can become stable and more widely accepted.

The Scorpaenidae View in CoL is a worldwide marine family of 370 species that have been collected in environments ranging from shallow to deep water and from the poles to the tropics ( Nelson, 2006; Eschmeyer View in CoL et al., 2017). This group includes the traditional Caracanthidae , Scorpaenidae View in CoL , Sebastidae View in CoL , and Setarchidae View in CoL (sensu Ishida, 1994; Appendix 2) and includes animals with reproductive modes ranging from more traditional broadcast spawning to live birth ( Breder and Rosen, 1966; Muñoz, 2010). Most inexplicit and explicit morphological studies and one large-scale molecular study generally have resolved the rockfishes (Sebastinae) as an ancestral or stem grade within the scorpaenoid radiation ( Matsubara, 1943; Ishida, 1994; Imamura, 1996, 2004; Lautredou et al., 2013). In contrast, Smith and Wheeler (2004, 2006), Smith and Craig (2007), Smith et al. (2016), and Betancur-R. et al. (2017) have recovered the Sebastinae as a deeply nested lineage. This revised phylogenetic hypothesis implies that the scorpaenoids originated in warmer waters and transitioned to deeper (e.g., Setarchinae) and colder habitats (e.g., Sebastinae) rather than the previous hypotheses that would necessitate transitioning from cooler waters into more temperate and tropical regions. This more traditional hypothesis may have been largely driven by the evolutionary perspective that the colder, overwhelmingly North Pacific cottoids and allies were the closest allies to a sebastine-stem scorpaenoid radiation ( Smith and Busby, 2014). This Sebastinae was resolved as the sister group to a clade composed of Adelosebastes View in CoL þ Sebastolobus View in CoL , which have generally been allied with or nested among the core sebastines in previous morphological and molecular studies ( Figs. 1 View FIG , 2 View FIG ). As might be expected with the revised placement of these core rockfishes, we recover this clade nested within a larger assemblage that includes all other sampled deeper and cooler water genera (i.e., Ectreposebastes View in CoL , Pontinus View in CoL , Setarches View in CoL , and Trachyscorpia View in CoL ). In this study, this colder-habitat clade of scorpaenids was recovered as the sister group to a Scorpaenodes View in CoL þ Pteroinae clade. This is in contrast to several previous studies (e.g., Imamura, 2004; Smith and Craig, 2007) that have found multiple clades of deep-water scorpaenoids sister to the pteroine lionfishes and allies ( Figs. 1 View FIG , 2 View FIG ). One of the most consistent results across scorpaenid studies is the sister-group relationship between Scorpaenodes View in CoL and pteroine lionfishes (e.g., Ishida, 1994; Imamura, 2004; Lautredou et al., 2013; Smith et al., 2016; Betancur-R. et al., 2017). The final scorpaenid clade recovered in our analysis is a primarily tropical and subtropical clade composed of Caracanthus View in CoL , Pteroidichthys View in CoL , Scorpaena View in CoL , Scorpaenopsis View in CoL , and Taenionotus . This clade was sister to the cold-water scorpaenoids þ lionfishes and allies and has been consistently recovered in molecular studies ( Smith and Craig, 2007; Lautredou et al., 2013; Smith et al., 2016; Betancur-R. et al., 2017). In contrast, morphological studies have typically recovered these fishes as a grade with Scorpaenodes View in CoL and Pteroinae (and potentially other genera) nested within the group ( Ishida, 1994; Shinohara and Imamura, 2005). It is clear that the inversion of scorpaenid relationships with sebastines deeply nested with the family that is recovered in this combined study and several other molecular studies ( Smith and Wheeler, 2004, 2006; Smith and Craig, 2007; Smith et al., 2016; Betancur-R. et al., 2017) has dramatically altered the polarity of morphological transformations and the impact this has on the evolutionary relationships in this commercially important clade.

The Synanceiidae View in CoL , a family of 133 species, is primarily a marine clade with a few fresh- or brackish-water representatives (e.g., Gymnapistes View in CoL , Neovespicula View in CoL ) that is distributed from the western Indian Ocean to the South Pacific Ocean ( Eschmeyer View in CoL and Rama-Rao, 1973; Nelson, 2006). The largest taxonomic change we are recommending in this study is the consolidation of the traditional Apistidae View in CoL , Aploactinidae View in CoL , Eschmeyeridae View in CoL , Gnathanacanthidae View in CoL , Pataecidae View in CoL , Perryenidae View in CoL , Synanceiidae View in CoL , and Tetrarogidae View in CoL (all sensu Eschmeyer View in CoL et al., 2017) into a monophyletic Synanceiidae View in CoL . This expanded Synanceiidae View in CoL is diagnosed by the evolution of the lachrymal saber as well as five additional morphological transformations (Appendix 2). Additionally, Leis and Rennis (2000) provided evidence from larval morphology that separates these fishes from the remainder of the core scorpaenoids. We recommend this higher-level change because of the proliferation of family-level names that are already emanating from the former Tetrarogidae View in CoL (i.e., Eschmeyeridae View in CoL , Perryenidae View in CoL ) and that are likely to continue. Our results, previous molecular studies ( Smith and Wheeler, 2004, 2006; Smith and Craig, 2007; Smith et al., 2016), and the computer aided re-analysis of Ishida’s (1994) scorpaenoid study in Smith and Wheeler (2004) that have all sampled multiple species of tetrarogids (sensu Eschmeyer View in CoL et al., 2017) have suggested that upwards of four or five additional small or monogeneric families will likely be needed to generate a monophyletic taxonomy. Instead of describing a diversity of new waspfish families, the alternative strategy is chosen here where the diversity of existing comparatively small families of stonefishes and waspfishes can be consolidated into a single, well supported, consistently supported, and taxonomically stable family with the retention of subfamilies as warranted and needed (e.g., Apistinae, Aploactininae, Pataecinae, Synanceiinae ). Further, our classification largely returns the subfamilial taxonomy to that recommended by Matsubara (1943). Our results recover the typical placement for the Apistinae as the earliest diverging lineage in the Synanceiidae View in CoL . Regan (1913) included this group among his Scorpaenidae View in CoL , which was composed of our Scorpaenidae View in CoL , Apistus View in CoL , Erisphex View in CoL (an aploactine), and six genera of ‘‘tetrarogids’’ (sensu Ishida, 1994). Matsubara (1943), Ishida (1994), and Imamura (2004) all treated Apistus View in CoL as the earliest branching lineage in his clade that is largely equivalent to our Synanceiidae View in CoL . The placement of Apistinae is one of the most consistently recovered relationships in scorpaenoid phylogenetics, but it is important to note that Washington et al. (1984) highlighted a number of features that potentially group the Apistinae with the Triglidae View in CoL : a bilobed gas bladder with an intrinsic muscle, elongate pectoral-fin rays (also found in hoplichthyids, Choridactylus View in CoL , Inimicus View in CoL , and Minous View in CoL ), and an expansion of the circumorbitals. Thus, continued work is warranted. Our phylogeny, like previous morphological studies ( Ishida, 1994; Imamura, 2004), recovers a monophyletic Synanceiinae deeply nested within the Synanceiidae View in CoL . Our study recovers a clade composed of the Aploactininae and Pataecinae sister to the restricted Synanceiinae . Other than his inclusion of the Congiopodidae View in CoL in this clade, Ishida (1994) recovered this same relationship. Finally, we have a grade composed of the various ‘‘tetrarogid’’ or formerly ‘‘tetrarogid’’ genera and Gnathanacanthus View in CoL as a diversity of lineages more closely related to Synanceiinae than to Apistinae.

Evolution of the Scorpaenoidei .— The combined morphological and molecular phylogeny presented herein provides an opportunity to reconcile the often conflicting datasets and look at the implications for this updated hypothesis on the evolution of this species-rich clade. One of the major findings in this study was the discovery of the lachrymal saber. As noted above, this specialization is hypothesized to have a primarily defensive role. The maxillary rotation of the lachrymal saber has two major anti-predator impacts. First, it expands the width of the head by projecting the spine(s) outward ( Figs. 4– 7 View FIG View FIG View FIG View FIG ). This expansion increases the rostral width of the fish by 10– 25% and would greatly increase the gape required by a would-be predator ( Price et al., 2015). Second, the presence of an outwardly directed and sharp spine should reduce predation because of the potential for the saber to pierce a would-be predator. Cowan (1969) described a similar defensive role for the outward projection of the preopercular spines in the closely allied psychrolutids that have enlarged antler-like modifications (e.g., Enophrys View in CoL , Icelinus View in CoL ; Yabe, 1985). In addition to its role in avoiding or reducing predation, it is possible that the lachrymal saber is used for intraspecific competition. As seen in the evolution of antlers and horns ( Chapman, 1975), the lachrymal saber could play a role when synanceiids compete for mates or territories. The one synanceiid species examined for biofluorescence ( Centropogon australis View in CoL ) had a green fluorescent lachrymal saber that contrasted with nonfluorescent or red-fluorescent regions on the head of these animals ( Fig. 9 View FIG ). Recent studies (e.g., Sparks et al., 2014; Anthes et al., 2016; Gruber et al., 2016) have demonstrated that a number of fish groups have green and red fluorescence that appears to be playing an ecological and/or evolutionary role. As such, it is possible that the synanceiids could be advertising or highlighting this specialization with this fluorescence in a similar role as the bioluminescence associated with the defensive dorsal spines in etmopterid sharks ( Claes et al., 2013) or that the lachrymal saber is involved in intraspecific competition and mate choice where synanceiid species are advertising their sabers to conspecifics.

In addition to exploring the evolution of the lachrymal saber, the revised scorpaenoid hypothesis has implications for the evolution of viviparity in this clade. The deeply nested placement of Sebastinae within the Scorpaenidae corroborates Wourms’ (1991) assertion about the evolution of live birth and corresponding intermediate stages in the transition from an ovuliparous (classical oviparous) ancestor among the non-scorpaenid scorpaenoids. As noted by Smith and Wheeler (2004), there appears to be an evolutionary transition from a more common ovuliparous ancestor in the platycephalids, synanceiids, and triglids to an oviparous species that releases fertilized eggs within a gelatinous egg mass in genera such as Dendrochirus , Pterois , Scorpaena , Scorpaenodes , Scorpaenopsis , and Sebastolobus ( Wourms, 1991; Koya and Muñoz, 2007). This intermediate reproductive mode is further modified in Helicolenus where species in the genus have internal fertilization and zygoparity where fertilized ova are held by the mother before being released into the ocean ( Wourms, 1991). The reproductive mode of Hozukius is unknown, but it shares a II-3 ovarian type with most scorpaenids (e.g., Caracanthus , Dendrochirus , Helicolenus , Scorpaena ; Cole, 2003; Koya and Muñoz, 2007). The more derived viviparous sebastine rockfishes ( Sebastes and Sebastiscus ) have a type II-1 ovarian type ( Koya and Muñoz, 2007). This suggests that Hozukius is likely to be more similar to Helicolenus or Scorpaena and not be live bearing. The evolution of reproductive modes and live birth in scorpaenoids has been discussed in considerably more detail in other studies ( Wourms, 1991; Koya and Muñoz, 2007; Muñoz, 2010; Pavlov and Emel’yanova, 2013), but their interpretations have implicitly or explicitly relied on the hypothesized placement of sebastines at the base of the scorpaenoid tree. The inversion of the phylogeny of scorpaenoids proposed in this study is more consistent with traditional views on the evolution of viviparity where there is a transition from external fertilization to internal fertilization with the retention of either the developing eggs or embryos within the mother ( Wourms, 1991; Wourms and Lombardi, 1992). These are two examples demonstrating the impact of the proposed phylogeny on the evolution of the scorpaenoid fishes. We hope that this revised hypothesis for the relationships of scorpionfish and allies will allow researchers to test additional evolutionary hypotheses for this important percomorph clade.