Abstract
Robust keys exist for the family-level groups of Cynipoidea. However, for most regions of the world, keys to genera are not available. To address this gap as it applies to North America, a fully illustrated key is provided to facilitate identification of the tribes and genera of rose gall, herb gall, and inquiline gall wasps known from the region. For each taxon covered, a preliminary diagnosis and an updated overview of taxonomy, biology, distribution, and natural history are provided.
Key words: Cecidology, identification, taxonomy
Introduction
Gall wasps (Hymenoptera: Cynipidaesensu lato) comprise a fascinating group of gall inducers and inquilines that are associated with a tremendous diversity of host plants, including at least eight families (Ronquist et al. 2015; Azmaz and Katılmış 2020; Buffington et al. 2020). However, the taxonomy of these insects is poorly resolved, and few resources exist to enable their identification. Some recent keys (e.g., Buffington et al. 2020) stand as milestones within systematics of Cynipoidea, as they are heavily illustrated and feature images that highlight important diagnostic characters, but these products only address family-level taxa. Within the gall wasps in particular, no comparable keys exist for genera, and virtually no useful diagnostic tools exist for the North American fauna specifically. The last generic key broadly covering North American cynipids is that of Weld (1952), privately published more than 70 years ago. As a result, a new key is necessary to enable tribal and generic identification of North American cynipids.
Part and parcel to this dilemma is a general observation that the current limits of many cynipid genera themselves are in flux, leaving a difficult situation for providing effective keys. Towards this end, we have addressed this challenge by focusing herein on inquilinous cynipids and those inducing galls on herbaceous and rosaceous plants, therein leaving the oak galling cynipids (tribe Cynipini) for future projects.
Recent revisionary works (e.g., Lobato-Vila and Pujade-Villar 2021) have made the North American cynipid fauna more approachable. Additionally, the cynipid fauna of the United States, Canada, and Mexico exclusive of Cynipini was recently cataloged by Nastasi and Deans (2021). An overview of North American cynipid taxonomy as treated therein is provided in Table 1.
Table 1.
Overview of North American gall wasp fauna. Species numbers refer to those known from North America; taxonomy, species numbers, and biological data are based on Nastasi and Deans (2021) except for Cynipini, which is derived from Melika et al. (2021). * = raised to subfamily Diplolepidinae in the family Diplolepididae by Hearn et al. (2023).
| Taxon | Biology | Nr of spp. |
|---|---|---|
| Tribe Aulacideini | Gall inducers on Asteraceae; Lamiaceae | 21 |
| Genus Antistrophus Walsh | Gall inducers on Chrysothamnus, Lygodesmia, Microseris, Silphium (Asteraceae) | 10 |
| Genus Aulacidea Ashmead | Gall inducers on Hieracium, Lactuca, Nabalus, Pilosella, Rhaponticum (Asteraceae) | 10 |
| Genus Liposthenes Förster | Gall inducers on Glechoma (Lamiaceae) | 1 |
| Tribe Ceroptresini | Inquilines of Cynipini | 19 |
| Genus Buffingtonella Lobato-Vila & Pujade-Villar | Unknown; presumed inquilines of Cynipini as in Ceroptres | 1 |
| Genus Ceroptres Hartig | Inquilines of Cynipini | 18 |
| Tribe Cynipini | Gall inducers on Fagaceae, especially Quercus | ~ 680 |
| Tribe Diastrophini | Gall inducers on Rosaceae or inquilines of Diastrophus or Diplolepidini | 25 |
| Genus Diastrophus Hartig | Gall inducers on Fragaria, Potentilla, Rubus (Rosaceae) | 14 |
| Genus Periclistus Förster | Inquilines in galls induced by Diplolepis | 7 |
| Genus Synophromorpha Ashmead | Inquilines in galls induced by Diastrophus | 4 |
| Tribe Diplolepidini* | Gall inducers on Rosa | 34 |
| Genus Diplolepis Geoffroy | Gall inducers on Rosa | 34 |
| Tribe Phanacidini | Gall inducers on Asteraceae | 2 |
| Genus Phanacis Förster | Gall inducers on Hypochaeris, Taraxacum (Asteraceae) | 2 |
| Tribe Synergini | Inquilines of Cynipini | 69 |
| Genus Saphonecrus Dalla Torre & Kieffer | Inquilines of Cynipini | 2 |
| Genus Synergus Hartig | Inquilines of Cynipini | 67 |
Materials and methods
Our taxonomic framework follows Nastasi and Deans (2021); nomenclatural, biological, and distributional data are provided therein for each species in the genera treated in the present work. The skeleton of this key was based on Buffington et al. (2020). Other characters in the present work follow Ronquist et al. (2015) or have been developed through the authors’ taxonomic work on North American Cynipoidea.
For those unfamiliar with cynipoid morphology, we recommend consulting the line drawings of ‘Hymenoptera of the World’ (Goulet and Huber 1993) and Melika (2006). Those more advanced in their knowledge may opt to reference the Hymenoptera Anatomy Ontology (Yoder et al. 2010) or the Phenotype and Trait Ontology (PATO curators 2023), the former of which serves as the primary foundation of the morphological terminology applied herein (Table 2).
Table 2.
Overview of morphological terminology employed in the key to genera. URLs link to entries in the Hymenoptera Anatomy Ontology (Yoder et al. 2010) or the Phenotype and Trait Ontology (PATO curators 2023).
Each character is illustrated by color micrographs of museum specimens, which enables stronger recognition of relevant morphology. Images were captured using a Macroscopic Solutions ‘microkit’ (Tolland, CT) imaging station, stacked using Zerene Stacker LLC (Richland, WA), and edited using Adobe Photoshop and/or Adobe Illustrator (San Jose, CA).
Specimens referenced during the production of this key, including those photographed to produce figures, are housed in the Frost Entomological Museum (PSUC; University Park, PA) or the United States National Museum of Natural History (USNM; Washington, DC). Unique specimen identifiers in the form of catalog numbers (USNMENT or PSUC_FEM numbers with corresponding barcodes) link each image to specimens housed at the corresponding collection.
Results
Key to the tribes and genera of herb, rose, bramble, and inquiline gall wasps of North America (Hymenoptera: Cynipoidea)
To verify the applicability of this key to a given specimen, first run unknown individuals through the superfamily key in Goulet and Huber (1993) to confirm the specimen belongs to Cynipoidea, then Buffington et al. (2020) to confirm placement in Cynipidae. This process is critical in that a few North American Figitidae can superficially resemble Cynipidae. We recommend the use of good lighting, diffused through mylar, when using the key; this is especially essential for viewing patterns of cuticular sculpture and characters involving the pronotal plate.
Some North American genera are problematic with regard to their taxonomic status or their true occurrence in the region. Where applicable, these taxa are present in the key or otherwise mentioned in the systematic treatment below. Additionally, many undescribed taxa within the scope of these keys are known, and many taxonomic acts are necessary to stabilize the fauna covered here. Future iterations of the key in this work will address updated taxonomy as it is published, but the present key has been written to be as compatible as possible with all upcoming taxonomic changes known to the authors. We provide provisional taxon diagnoses in the below taxon treatments to facilitate identification of the tribes and genera as they are currently defined; these diagnoses are based only on North American members of each taxon. We expect these diagnoses to change as taxonomic work on the North American cynipid fauna progresses.
| 1 | Pronotum distinctly short dorsomedially, forming a narrow strip behind head, with medial height (Figs 1–4, pmh) approximately 1/7 or less the lateral height (Figs 3, 4, plh). Pronotal submedial pits absent (Figs 1, 2). Gall inducers on Rosa (Rosaceae) or several genera of Fagaceae, especially Quercus | 2 |
| – | Pronotum taller and broader dorsomedially, with medial height (Figs 5, 6, pmh) usually approximately 1/3 the lateral height (Figs 7, 8, plh). Pronotal submedial pits usually present and well-impressed (mep, Fig. 6). Gall inducers on other plants or inquilines in galls | 3 |
| 2 | Mesopleuron medially with broad, crenulate transverse impression (Fig. 9, mci). Female hypopygium always distinctly plowshare-shaped (Fig. 10, hyp). Scutellar foveae faint or absent (Fig. 11, scf). Fore wing vein 2r usually with distinct median vein stump projecting distally (Fig. 12, 2r). Gall inducers on Rosa | Diplolepididae: Diplolepis Geoffroy |
| – | Mesopleuron usually without broad crenulate impression (Fig. 13). Female hypopygium usually not plowshare-shaped (Fig. 14, hyp); if plowshare-shaped (only in Protobalandricus Melika, Nicholls & Stone, 2018), then mesopleuron entirely smooth. Scutellar foveae usually distinct (Fig. 15, scf). Fore wing vein 2r usually without distinct stump (Fig. 16, 2r). Gall inducers on Fagaceae, especially Quercus | Cynipini (not keyed further; see taxonomic treatment below) |
| 3 | Metasomal tergites 2 and 3 partially or completely fused into a syntergite, resulting in a metasoma composed of one or two segments (Figs 17, 18, arrows indicate length of syntergite). Inquilines in galls on Quercus or female inquilines in galls on Rosaceae | 4 |
| – | Metasomal postpetiolar terga free and articulated, not forming syntergite and with no single segment especially enlarged (Figs 19, 20, arrows indicate length of longest tergite). Gall inducers on Rosaceae, Asteraceae, or Lamiaceae, or male inquilines in galls on Rosaceae | 8 |
| 4 | Metasomal tergites 2 and 3 entirely fused into syntergite (Fig. 22, T2+T3). Head and mesosoma generally roughly sculptured (Fig. 23). Pronotal plate incomplete, at most weakly defined dorsally, and with marginal sutures never reaching anterior margin of mesoscutum (Fig. 21, ppt). Inquilines in galls on Quercus | Synergini: Synergus Hartig |
| – | Metasomal tergites 2 and 3 often delineated by a distinct suture, with tergite 2 much smaller than tergite 3 and appearing ligulate (Fig. 25), although occasionally entirely fused into syntergite. Body usually less roughly sculptured, often smooth and/or shining (Fig. 26). Pronotal plate complete, well-defined both dorsally and ventrally, and with marginal sutures reaching anterior margin of mesoscutum (Fig. 24, ppt.). Inquilines in galls on Quercus or female inquilines in galls on Rosaceae | 5 |
| 5 | Metasomal tergites 2 and 3 delineated by a distinct suture, with tergite 2 much smaller than tergite 3 and appearing ligulate (Fig. 27). Mesoscutum with or without abundant setigenous punctation. Female or male inquilines in galls on Quercus | 6 (Ceroptresini) |
| – | Metasomal tergites 2 and 3 entirely fused into syntergite, at most with a slight indication of a suture delimiting tergite 2 but never with tergites fully separated (Fig. 28). Mesoscutum with distinct setigenous punctation at least anteriorly (Fig. 29). Female inquilines in galls on Rosaceae | 7 (Diastrophini, in part) |
| 6 | Area between toruli depressed and often pubescent (Fig. 30, dep). Metasomal tergite 1 mostly concealed, smooth (Fig. 31, T1). Frons with distinct facial carinae ventral to toruli apparent at least as short ridges below toruli (Fig. 30, fac). Frequently collected | Ceroptres Hartig |
| – | Area between toruli not depressed and not strongly pubescent (Fig. 32). Metasomal tergite 1 relatively large and ring-like, not concealed, and longitudinally striate (Fig. 33). Frons entirely without facial carinae ventral to toruli (Fig. 32). Very rarely collected | Buffingtonella Lobato-Vila & Pujade-Villar |
| 7 | Fore wing with marginal cell closed, with a distinct, complete vein along anterior wing margin (Fig. 34, mcl). Notauli incomplete, absent anteriorly, well developed posteriorly, not apparently widened posteriorly (Fig. 35). Mesoscutum (Fig. 35) coriaceous and punctate-setigenous throughout, and more densely pubescent. Inquilines in galls on Rosa | Periclistus Förster (females) |
| – | Fore wing with marginal cell open, without distinct vein along anterior wing margin (Fig. 36, mcl). Notauli usually complete, always distinctly widened posteriorly relative to anterior width (Fig. 37). Mesoscutum (Fig. 37) smooth to granulate and with fewer setigenous punctures, and less densely pubescent. Inquilines in galls on Rubus | Synophromorpha Ashmead (females) |
| 8 | Pronotal plate complete, well-defined both dorsally and ventrally, and with marginal sutures distinctly reaching anterior margin of mesoscutum (Fig. 38, ppt). Metatarsal claws with distinct basal lobe (Fig. 39, mtl). Gall inducers or male inquilines in galls on Rosaceae | 9 (Diastrophini, in part) |
| – | Pronotal plate usually poorly defined dorsally, never with marginal sutures clearly reaching anterior margin of mesoscutum (Fig. 40, ppt). Metatarsal claws simple and without distinct basal lobe (Fig. 41). Gall inducers on Asteraceae or Lamiaceae | 11 |
| 9 | Fore wing with marginal cell closed, with a distinct, complete vein along anterior wing margin (Fig. 42, mcl). Notauli weakly developed, never distinctly complete, and not distinctly widened posteriorly (Fig. 43, not). Mesoscutum more or less densely pubescent throughout (Fig. 43). Male inquilines in galls on Rosa | Periclistus Förster (males) |
| – | Fore wing with marginal cell open, without distinct vein along anterior wing margin (Fig. 44, mcl). Notauli well-developed, usually distinctly complete, and always distinctly widened posteriorly relative to anterior width (Fig. 45, not). Mesoscutum much less pubescent (Fig. 45). Female or male gall inducers on Rosaceae or male inquilines in galls on Rubus | 10 |
| 10 | Mesoscutum mostly to entirely coriaceous and with distinct setigenous punctures, especially medially (Fig. 46). Male inquilines of Diastrophus galls on Rubus (females with metasomal tergites 2 and 3 fused into a syntergite, causing metasoma to appear mostly as one large segment) | Synophromorpha Ashmead (males) |
| – | Mesoscutum mostly smooth and shining, at most weakly coriaceous, and without abundant strong setigenous punctures (Fig. 47). Female or male gall inducers on Rosaceae (females with metasomal tergites 2 and 3 free and articulated and without syntergite) | Diastrophus Hartig |
| 11 | Pronotum with submedial pits reduced, usually apparent as a continuous linear depression (Fig. 48). Fore wing with marginal cell partially open, with vein R1 reaching anterior margin of fore wing and continuing along wing margin but not meeting vein Rs (Fig. 49, arrow indicates end of vein R1). Gall inducers on Taraxacumofficinale or Hypochaerisradicata (Asteraceae) | Phanacidini: Phanacis Förster |
| – | Pronotum with submedial pits distinct and well-defined (Fig. 50, mep). Fore wing with marginal cell either entirely open (Fig. 51, arrow indicates end of vein R1 and dotted line indicates margin of fore wing along marginal cell), with vein R1 clearly not reaching wing margin, or entirely closed, with vein Rs reaching wing margin and distinctly reaching vein Rs to enclose cell. Gall inducers on several genera of Asteraceae, or Glechomahederacea (Lamiaceae) | 12 (Aulacideini) |
| 12 | Mesopleuron with sculpture primarily or entirely reticulate (Fig. 52, msp), often with fine striae intermediate to rows of reticulate cells (Fig. 53, msp). Second metasomal tergite without distinct patch of setae, at most with a few scattered setae (Fig. 52, 53). Marginal cell of fore wing always open (Fig. 54, mcl). Gall inducers on Chrysothamnus, Lygodesmia, Microseris, or Silphium (Asteraceae) | Antistrophus Walsh |
| – | Mesopleuron with sculpture primarily or entirely transversely striate (Fig. 55, msp). Second metasomal tergite usually with distinct anterolateral patch of pale setae (Fig. 56, T2p). Marginal cell of fore wing usually closed (Fig. 57, mcl), open only in Liposthenes Förster. Gall inducers on several genera of Asteraceae or on Glechomahederacea (Lamiaceae) | 13 |
| 13 | Fore wing with marginal cell closed and usually with areolet distinct (Fig. 58, mcl and aro). Mesoscutum pubescent throughout, always with abundant, closely-set setae and often appearing densely silky (Fig. 59). Gall inducers primarily on Cichorieae (Asteraceae), especially Lactuca L | Aulacidea Ashmead |
| – | Fore wing with marginal cell open and areolet indistinct (Fig. 60). Mesoscutum mostly bare, at most with a few scattered setae (Fig. 61). Gall inducers on Glechomahederacea (Lamiaceae) | Liposthenes Förster |
Figures 1–8.
1Andricusquercuscalifornicus, anterodorsal view (USNMENT01231839) 2Diplolepisbicolor, anterodorsal view (USNMENT01231831) 3Dryocosmuskuriphilus, lateral view (USNMENT01231861) 4Diplolepisbicolor, lateral view (USNMENT01231831) 5Synergusatripennis, anterodorsal view (USNMENT01231845) 6Antistrophuslaciniatus, anterodorsal view (USNMENT01448496) 7Phanacis sp., lateral view (USNMENT01448498) 8Antistrophuslaciniatus, lateral view (USNMENT01448496). Abbreviations: mep = pronotal submedial pits, plh = pronotum lateral height, pmh = pronotum medial height.
Figures 9–16.
9Diplolepisbicolor, lateral view (USNMENT01231831) 10Diplolepisbicolor, lateral view (USNMENT01231831) 11Diplolepisbicolor, dorsal view (USNMENT01231831) 12Diplolepisrosae, fore wing (USNMENT00655959) 13Dryocosmuskuriphilus, lateral view (USNMENT01231861) 14Andricusquercuscalifornicus, lateral view (USNMENT01231839) 15Dryocosmuskuriphilus, dorsolateral view (USNMENT01231861) 16Andricuscornigerus, fore wing (USNMENT00655954). Abbreviations: hyp = hypopygium, mci = mesopleural crenulate impression, scf = scutellar foveae.
Figures 17–20.
17Synergus sp., metasoma, dorsolateral view (USNMENT01231858) 18Ceroptres sp., metasoma, dorsolateral view (USNMENT00917016) 19Aulacideacf.hieracii, metasoma, lateral view (PSUC_FEM 000253105) 20Antistrophuspisum, metasoma, lateral view (PSUC_FEM 000247264). Arrows indicate length of longest metasomal tergite.
Figures 21–26.
21Synergusatripennis, dorsolateral view (USNMENT01231845) 22Synergus sp., metasoma, lateral view (USNMENT01231858) 23Synergus sp., lateral view (PSUC_FEM 000079457) 24Synophromorpha sp., dorsolateral view (USNMENT01448499) 25Ceroptres sp., metasoma, dorsolateral view (USNMENT00917016) 26Diastrophuskincaidii, lateral view (PSUC_FEM 000251280). Abbreviations: ppt = pronotal plate, T2 = second metasomal tergite, T2+3 = completely fused second and third metasomal tergites, T3 = third metasomal tergite.
Figures 27–29.
27Ceroptres sp., metasoma, dorsolateral view (USNMENT00917016) 28Diastrophuskincaidii, metasoma, lateral view (PSUC_FEM 000251280) 29Periclistus sp., lateral view (PSUC_FEM 000250920). Abbreviations: T2 = second metasomal tergite, T2+3 = completely fused second and third metasomal tergites.
Figures 30–33.
30Ceroptres sp., head, anterior view (USNMENT00917016) 31Ceroptres sp., metasoma, dorsolateral view (USNMENT00917016) 32Buffingtonellapolita, head, anterior view (USNMENT00892509) 33Buffingtonellapolita, lateral view (USNMENT00892509). Abbreviations: dep = depressed intratorular area, fac = facial carinae, T1 = first metasomal tergite.
Figures 34–37.
34Synergus sp., fore wing (PSUC_FEM 000079457) 35Periclistus sp., dorsal view (PSUC_FEM 000250920) 36Synophromorpha sp., fore wing (PSUC_FEM 000250918 37Synophromorpha sp., dorsal view (PSUC_FEM 000250918). Abbreviations: mcl = marginal cell.
Figures 38–41.
38Synophromorpha sp., dorsolateral view (USNMENT01448499) 39Diastrophuskincaidii, tarsal claw (PSUC_FEM 000251280) 40Antistrophuslaciniatus, anterodorsal view (USNMENT01448496) 41Antistrophussilphii, tarsal claw (CYNANT0048). Abbreviations: mtl = metatarsal claw lobe, ppt = pronotal plate.
Figures 42–45.
42Synergus sp., fore wing (PSUC_FEM 000079457) 43Periclistus sp., dorsal view (PSUC_FEM 000250920) 44Synophromorpha sp., fore wing (PSUC_FEM 000250918) 45Synophromorpha sp., dorsal view (PSUC_FEM 000250918). Abbreviations: mcl = marginal cell, not = notauli.
Figures 46, 47.
46Synophromorpha sp., dorsal view (PSUC_FEM 000250918) 47Diastrophuskincaidii, dorsal view (PSUC_FEM 000251280).
Figures 48–51.
48Phanacis sp., anterodorsal view (USNMENT01448498) 49Phanacis sp., wings (USNMENT01231855) 50Antistrophuslaciniatus, anterodorsal view (USNMENT01448496) 51Antistrophuslaciniatus, wings (USNMENT01448496); dotted line indicates margin of fore wing. Abbreviations: mep = pronotal submedial pits.
Figures 52–57.
52Antistrophuspisum, lateral view (PSUC_FEM 000247286) 53Antistrophusmeganae, lateral view (PSUC_FEM 000248165) 54Antistrophuslaciniatus, wings (USNMENT01448496) 55Aulacidea sp., lateral view (PSUC_FEM 000247286) 56Liposthenesglechomae, lateral view (PSUC_FEM 000248152) 57Aulacidea sp., wings (PSUC_FEM 000247286). Abbreviations: mcl = marginal cell, msp = mesopleuron, T2p = setose patch on second metasomal tergite.
Figures 58–61.
58Aulacidea sp., wings (PSUC_FEM 000247286) 59Aulacidea sp., dorsal view (PSUC_FEM 000247286) 60Liposthenesglechomae, wings (PSUC_FEM 000248152) 61Liposthenesglechomae, dorsal view (PSUC_FEM 000248152). Abbreviations: aro = areolet, mcl = marginal cell.
Systematic overview
. Aulacideini
981653C3-7B17-5876-95D9-8081EAF7484C
Figures 62–67.
62Antistrophuspisum, lateral view (PSUC_FEM 000247286) 63Antistrophusmeganae, lateral view (PSUC_FEM 000248165) 64Antistrophussilphii, lateral view (CYNANT0048) 65Liposthenesglechomae, lateral view (PSUC_FEM 000248152) 66Aulacidea sp., lateral view (PSUC_FEM 000247286) 67Aulacideahieracii, lateral view (PSUC_FEM 000253105).
Figures 87–95.
87 galls of Antistrophuspisum on stem of Lygodesmiajuncea (Asteraceae: Cichorieae), photographed by Chris Friesen (https://www.inaturalist.org/observations/95588437) 88 galls of Antistrophusrufus in dissected stem of Silphiumlaciniatum (Asteraceae: Heliantheae), photographed by Andy Deans (https://www.inaturalist.org/observations/64708490) 89 gall of Antistrophussilphii on apical stem of Silphiumintegrifolium (Asteraceae: Heliantheae), photographed by Andy Deans (https://www.inaturalist.org/observations/64708191) 90 galls of Diplolepispolita on leaves of Rosa sp. (Rosaceae: Roseae), photographed by Garth Harwood (https://www.inaturalist.org/observations/165442438) 91 gall of Diplolepiscalifornica on Rosa sp. (Rosaceae: Roseae), photographed by Mary K. Hanson (https://www.inaturalist.org/observations/115655737) 92 gall of Diastrophuspotentillae on Potentillasimplex (Rosaceae: Potentilleae), photographed by Tom Murray (https://www.inaturalist.org/observations/134669544) 93 gall of Diastrophusnebulosus on stem of Rubus sp. (Rosaceae: Rubeae), photographed by Pam Curtin (https://www.inaturalist.org/observations/174007397) 94 galls of Diastrophuskincaidii on stems of Rubusparviflorus (Rosaceae: Rubeae), photographed by Adam Heikkila (https://www.inaturalist.org/observations/173314109) 95 galls of Phanacistaraxaci on petiole of Taraxacumofficinale (Asteraceae: Cichorieae), photographed by Nathan Earley (https://www.inaturalist.org/observations/174118397).
Diagnosis.
Pronotum tall and broad dorsomedially. Pronotal submedial pits distinct and well-impressed. Pronotal plate present, usually only distinct in anterior half of pronotum. Mesopleuron sculpture striate, reticulate, or striate-reticulate. Mesoscutellar foveae distinct. Fore wing with marginal cell entirely open or entirely closed, never partially open. Wings always hyaline, never tinted or with darkened areas. Metatarsal claws without basal lobe. Metasomal tergites 2 and 3 free and articulate, never with a syntergite.
Note.
The tribe Aulacideini is represented by approximately 90 species in ten genera worldwide (Nieves-Aldrey 2022), three of which are known from North America (Nastasi and Deans 2021): Antistrophus Walsh, 1869, Aulacidea Ashmead, 1897, and Liposthenes Förster, 1869. Monophyly of the tribe is rather well-established (e.g., Ronquist et al. 2015; Blaimer et al. 2020), but the generic taxonomy is somewhat unsettled (Nieves-Aldrey 2022), and many North American species await description (Nastasi, pers. comm.). The number of introduced described species established in North America is uncertain (see the treatment of Aulacidea Ashmead below), but Nastasi and Deans (2021) reported 21 described species.
Globally, members of this tribe induce galls on five plant families (Azmaz and Katılmış 2020; Buffington et al. 2020; Nieves-Aldrey 2022), but the described North American taxa are restricted to host plants in the Asteraceae (tribes Astereae, Chichorieae, and Heliantheae) and Lamiaceae (Glechomahederacea L.) (Nastasi and Deans 2021). Galls induced by wasps of this tribe (Figs 87–89) are most likely to yield adults when collected after host plants have senesced; adult wasps emerge in mid spring through late summer depending on the gall wasp species and collecting locality (Nastasi et al., in lit.). Many species induce cryptic galls that produce no externally discernable modification to the plant tissue; this phenomenon suggests that aulacideine herb gall wasps inducing cryptic galls are probably more diverse than currently known and have evaded detection due to their hidden galls.
. Antistrophus
Walsh, 1869
1D233E5A-47C7-5546-8EB1-15DE735D13A2
Type species.
Antistrophuslygodesmiaepisum Walsh, 1869 (= Antistrophuspisum Ashmead, 1885)
Diagnosis.
Mesoscutum sparsely pubescent, at most with scattered setae throughout and never appearing silky. Notauli typically incomplete but complete in several species. Mesopleuron reticulate or striate-reticulate, never entirely transversely striate. Fore wing with marginal cell open, with R1 never reaching anterior wing margin, always without areolet, and with or without marginal setae. Second metasomal tergite without patch of setae.
Note.
Antistrophus contains ten described species, all of which are known from America north of Mexico (Nastasi and Deans 2021). Antistrophus wasps are most commonly encountered in the Eastern and Midwestern United States, although two species, A.chrysothamni (Beutenmüller) and A.microseris (McCracken & Egbert), are apparently restricted to Arizona and California respectively (Nastasi and Deans 2021). Unpublished records indicate that the genus is far more widely distributed than currently known and is likely common throughout the United States and adjacent parts of Canada (Nastasi, pers. obs.).
Species of Antistrophus induce galls on several genera of asteraceous plants: Chrysothamnus Nutt.; Lygodesmia D.Don; Microseris D.Don; and Silphium L. Additional plant genera are known to host undescribed species. Antistrophus associated with Silphium are especially diverse and primarily comprise undescribed species; each Silphium species appears to be galled by one or more host-specific or narrowly oligophagous gall wasp species, and some Antistrophus are emerging as pests of cultivated Silphium.
Antistrophus, as currently circumscribed, is a heterogeneous assemblage. The genus contains all North American herb gall wasps that did not fit well within Aulacidea Ashmead, 1897 or Diastrophus Hartig, 1840, of which the latter is now placed in Diastrophini. Many undescribed species of this genus are known to us, and morphological and molecular data demonstrate that Antistrophus as currently defined is poorly circumscribed (unpublished data); the limits of Antistrophus will be revised by an ongoing study. Nevertheless, all described species currently placed in this genus as well as all undescribed species currently known to us correctly key to Antistrophus here.
North American species (Nastasi and Deans 2021):
1. Antistrophusbicolor Gillette, 1891
2. Antistrophuschrysothamni (Beutenmüller, 1908)
3. Antistrophusjeanae Tooker & Hanks, 2004
4. Antistrophuslaciniatus Gillette, 1891
5. Antistrophusmeganae Tooker & Hanks, 2004
6. Antistrophusmicroseris (McCracken & Egbert, 1922)
7. Antistrophusminor Gillette, 1891
8. Antistrophuspisum Ashmead, 1885 (replacement name for A.lygodesmiaepisum Walsh as given by Nieves-Aldrey [1994] but omitted from Nastasi and Deans [2021])
9. Antistrophusrufus Gillette, 1891
10. Antistrophussilphii Gillette, 1891
. Aulacidea
Ashmead, 1897
919C2F42-413C-52CF-9DCB-CA86EB361BF3
Type species.
Aulaxmulgediicola Ashmead, 1896 (= Aulacideaharringtoni [Ashmead, 1897])
Diagnosis
(based on North American taxa): Mesoscutum densely pubescent, often appearing silky but at least with rather abundant closely-set setae. Notauli almost always complete (incomplete only in an undescribed species from California). Mesopleuron transversely striate; with a small ventral patch of reticulate sculpture in Aulacideaacroptilonica Tyurebaev, 1972. Fore wing with marginal cell entirely closed, with R1 meeting Rs along anterior wing margin, always with areolet, and always with distinct marginal setae. Second metasomal tergite with a distinct patch of setae (absent in Aulacideaacroptilonica Tyurebaev, 1972 and sometimes appearing reduced in males of various species).
Note.
Aulacidea contains some 40 described species (Azmaz and Katılmış 2020; Nieves-Aldrey 2022), 11 of which are known or suspected from North America (Nastasi and Deans 2021). Native species known from North America induce galls primarily on species of Lactuca L., although one species (A.nabali [Brodie, 1892]) induces galls on Nabalus Cass, and one species (A.ambrosiaecola [Ashmead, 1896]) is doubtfully associated with Ambrosia L. Introduced or suspected species induce galls on Hieracium L., Pilosella Hill, and Rhaponticum Vaill. (Nastasi and Deans 2021).
The number of established exotic Aulacidea is problematic as several species have apparently been introduced (e.g., Moffat and Smith 2015), but few records indicate whether they have successfully established. Aulacideaacroptilonica Tyurebaev is definitively established in the Pacific Northwest, but it is unclear whether A.subterminalis Niblett, 1946 or A.pilosellae (Kieffer, 1901) are truly established (Nastasi and Deans 2021). A single A.pilosellae was collected via Malaise trap in Canada (Moffat and Smith 2015), but there appear to be no subsequent records indicating establishment of this species in North America. The only accessible evidence of establishment of A.subterminalis in North America is a government report detailing introduction attempts in Canada (Government of British Columbia 2018). Records appearing to represent A.hieracii (Linnaeus, 1758) on Hieraciumumbellatum L. in North America have been confirmed since publication of the recent catalogue, although there are some disputes over whether the population present in the Nearctic is conspecific with those found in the Palearctic (unpublished data). Overall, more research is needed to substantiate the identity and establishment of the introduced taxa.
More generally, Aulacidea was erected by Ashmead for herb gall wasps (then, the tribe Aylacini) with a closed marginal cell; this conception of Aulacidea remains virtually unchanged at present. As with Antistrophus, Aulacidea is poorly circumscribed, and the limits of this genus require adjustment (Ronquist et al. 2015; Nieves-Aldrey 2022).
North American species (Nastasi and Deans 2021):
1. Aulacideaabdita Kinsey, 1920
2. Aulacideaacroptilonica Tyurebaev, 1972
3. Aulacideaambrosiaecola (Ashmead, 1896)
4. Aulacideaannulata Kinsey, 1920
5. Aulacideaharringtoni (Ashmead, 1887)
6. Aulacideahieracii (Linnaeus, 1758)
7. Aulacideanabali (Brodie, 1892)
8. Aulacideapilosellae (Kieffer, 1901)
9. Aulacideapodagrae (Bassett, 1890)
10. Aulacideasubterminalis Niblett, 1946
11. Aulacideatumida (Bassett, 1890)
. Liposthenes
Förster, 1869
CC4AB371-E9A2-55A5-B2CC-FF02834F6022
Type species:
Aulaxglechomae Hartig, 1841 (= Cynipsglechomae Linnaeus, 1758).
Diagnosis.
Mesoscutum sparsely pubescent, at most with a few scattered setae. Notauli complete. Mesopleuron mostly transversely striate, at most with slight indication of reticulate sculpture. Fore wing with marginal cell open, never with areolet distinct, and always with distinct marginal setae. Second metasomal tergite always with a distinct patch of setae.
Note.
Liposthenes is known in North America from a single introduced species: L.glechomae (Linnaeus, 1758). This species was apparently introduced from Europe along with its host plant, Glechomahederacea L., and has since become widespread in the United States (Nastasi and Deans 2021). Liposthenesglechomae is the only known gall wasp associated with Lamiaceae in the Nearctic; all other known Nearctic Aulacideini, both described and known undescribed species, are associated with Asteraceae.
North American species (Nastasi and Deans 2021):
1. Liposthenesglechomae (Linnaeus, 1758)
. Ceroptresini
B51D64F3-96AF-51E3-BB0E-CA7DD06E166E
Figures 68, 69.
68Buffingtonellapolita, lateral view (USNMENT00892509) 69Ceroptres sp., lateral view (USNMENT00917016).
Diagnosis.
Pronotum tall and broad dorsomedially. Pronotal submedial pits distinct and well-impressed. Pronotal plate present and complete. Mesoscutellar foveae distinct. Fore wing with marginal cell closed. Metatarsal claws with basal lobe. Metasoma with syntergite, with third tergite greatly enlarged and occupying most of metasoma and with second tergite reduced but free and articulating. First metasomal tergite usually more or less concealed between mesosoma and metasoma and without conspicuous sculpture (more visible and conspicuously striate in some taxa easily confused with Ceroptres). Body generally weakly sculptured.
Note.
Ceroptresini includes 19 North American species: 18 species of Ceroptres Hartig and Buffingtonellapolita (Ashmead, 1896) (Nastasi and Deans 2021).
. Buffingtonella
Lobato-Vila & Pujade-Villar, 2019
267542F4-9CC3-57AD-9176-075CA7EAC182
Type species.
Ceroptrespolitus Ashmead, 1896
Diagnosis.
Area between toruli not depressed and without dense pubescence. Metasomal tergite 1 relatively large and ring-like, not concealed, and longitudinally striate. Frons entirely without facial carinae ventral to toruli.
Note.
Buffingtonella is known only from Virginia from eight specimens collected in 1884 and 1885 (Lobato-Vila and Pujade-Villar 2019). These specimens were apparently ovipositing into the midribs of leaves of Quercusrubra L. at the time of collection, and as such, B.polita has been assumed to be an inquiline of an unidentified oak gall wasp (Lobato-Vila and Pujade-Villar 2019). However, the placement of this genus in Ceroptresini, its recognition as distinct from other related taxa, and its biology remain to be substantiated (Lobato-Vila and Pujade-Villar 2019). Upon examining the aforementioned material of this species in the National Museum of Natural History, we confirm the diagnostic characters for the genus as described by Lobato-Vila and Pujade-Villar (2019) and have included it in the above key.
North American species (Nastasi and Deans 2021):
1. Buffingtonellapolita (Ashmead, 1896)
. Ceroptres
Hartig, 1840
A1D832E4-30C7-5443-936E-BC9B124439C6
Type species.
Ceroptresclavicornis Hartig, 1840.
Diagnosis.
Area between toruli distinctly depressed and with abundant pubescence. Metasomal tergite 1 small, mostly concealed between mesosoma and following tergites, and dorsally smooth. Frons with distinct facial carinae ventral to toruli, apparent at least as short ridges (we strongly recommend careful positioning and light diffusion when assessing this character).
Note.
Ceroptres are occasionally reared from galls induced on oaks by members of the tribe Cynipini (Lobato-Vila and Pujade-Villar 2019; Nastasi and Deans 2021), but are otherwise infrequently encountered. Ceroptres are presumed to be inquilines of Cynipini (Ronquist et al. 2015), although some theorize that they may actually be parasitoids due to observation of female Ceroptres ovipositing into mature galls rather than developing galls as is typical for gall inquilines (Z. Liu, in lit.). While 18 described species of Ceroptres are known from North America, the diversity of this genus has been sparsely surveyed, and many undescribed species are known in association with oak galls (S. Rollins and C. Tribull, pers. comm. 2023). Ceroptres have also been reared by several North American research groups in association with galls of cecidomyiid midges, although the exact nature of this association is unknown.
North American species (Nastasi and Deans 2021):
1. Ceroptrescatesbaei Ashmead, 1885
2. Ceroptresconfertus (McCracken & Egbert, 1922)
3. Ceroptrescornigera Melika & Buss, 2002
4. Ceroptresensiger (Walsh, 1864)
5. Ceroptresfrondosae Ashmead, 1896
6. Ceroptresjunquerasi Lobato-Vila & Pujade-Villar, 2019
7. Ceroptreslanigerae Ashmead, 1885
8. Ceroptreslenis Lobato-Vila & Pujade-Villar, 2019
9. Ceroptresmexicanus Lobato-Vila & Pujade-Villar, 2019
10. Ceroptresminutissimi Ashmead, 1885
11. Ceroptresmontensis Weld, 1957
12. Ceroptresnigricus Lobato-Vila & Pujade-Villar, 2019
13. Ceroptrespetiolicola (Osten Sacken, 1861)
14. Ceroptrespisum (Osten Sacken, 1861)
15. Ceroptresquadratifacies Lobato-Vila & Pujade-Villar, 2019
16. Ceroptresrufiventris Ashmead, 1896
17. Ceroptressnellingi Lyon, 1996
. Cynipini
30539C33-374A-572D-8699-018B414DE164
Figures 70–72.
70Dryocosmuskuriphilus, lateral view (USNMENT01231861) 71Andricusquercuscalifornicus, lateral view (USNMENT01231839) 72Phylloteras sp., lateral view (USNMENT01231835).
Diagnosis.
Pronotum distinctly short and narrow dorsomedially, without distinct plate or pits. Scutellar foveae usually distinct. Mesopleuron usually without broad crenulate impression. Female hypopygium only very rarely plowshare-shaped; only so in Protobalandricus Melika, Nicholls & Stone, 2018, in which the mesopleuron is entirely smooth and therein readily separable from Diplolepis Geoffroy, 1762 (Cuesta Porta, pers. comm. 13 Feb 2024).
Note.
Cynipini is represented by an estimated 680 North American species that induce galls primarily on Quercus (Fagaceae) (Melika et al. 2021). Additional host genera known are Castanea Mill., Chrysolepis Hjelmq., and Notholithocarpus Manos, Cannon, & S.H. Oh (Buffington and Morita 2009). Genera belonging to Cynipini are not keyed in the present work due to the presence of several highly unstable genera that prohibit clear morphological recognition, although recent studies (e.g., Melika et al. 2021) have made taxonomic changes that greatly ease this burden. Further revisionary studies will continue to stabilize genera in the Cynipini, and a key to Cynipini will be published when possible. Relevant keys for Cynipini include Weld (1952), Zimmerman (2018), and Melika et al. (2021), but these works are partial in their taxon coverage or do not align well with current taxonomic hypotheses.
. Diastrophini
2D1172A4-CEE2-5D68-9936-93A993A40C34
Figures 73–75.
73Diastrophuskincaidii, lateral view (PSUC_FEM 000251280) 74Periclistus sp., lateral view (PSUC_FEM 000250920) 75Synophromorpha sp., lateral view (PSUC_FEM 000250918).
Diagnosis.
Pronotum tall and broad dorsomedially. Pronotal submedial pits distinct and well-impressed. Pronotal plate present and complete, distinct both dorsally and ventrally. Mesopleuron sculpture striate or smooth and shining. Mesoscutellar foveae distinct. Fore wing with marginal cell entirely open or entirely closed, never partially open. Wings often with darkened areas, especially around the marginal cell. Metatarsal claws always with basal lobe. Metasomal tergites 2 and 3 either free and articulate, or fused into a syntergite in some females.
Note.
Diastrophini includes 25 described North American species in three genera: Diastrophus Hartig, 1840, Periclistus Förster, 1869, and Synophromorpha Ashmead, 1903 (Nastasi and Deans 2021). The North American members of this tribe are gall inducers on various Rosaceae or inquilines in the galls of Diastrophus Hartig, 1840 or Diplolepis Geoffroy, 1762 (Nastasi and Deans 2021).
. Diastrophus
Hartig, 1840
C9FBDBE8-B9F8-5ECC-8F79-1F7A80FC9960
Type species.
Cynipsrubi Bouché, 1834.
Diagnosis.
Mesoscutum generally weakly sculptured and without abundant strong setigenous punctures. Notauli complete and strong throughout. Mesopleuron sculpture smooth to striate. Fore wing with marginal cell open. Metasoma never with syntergite.
Note.
Diastrophus contains 14 North American species (Nastasi and Deans 2021). Many species induce galls on Rubus L., although the herbaceous genera Fragaria L. and Potentilla L. are also used. Diastrophussmilacis Ashmead, 1896 and its supposed inquiline, Periclistussmilacis Ashmead, 1896, were previously believed to be associated with Smilax L., making D.smilacis the only cynipid known to induce galls on a monocot plant (Gates et al. 2020). However, Gates et al. conclude that this association was erroneous, and the true gall inducer on Smilax is in fact a eulophid wasp (Chalcidoidea: Aprostocetussmilax Gates & Zhang). The biological associations of Diastrophini therein are still atypical as Periclistus inquilines are generally associated with the tribe Diplolepidini. Our own examination of the type material of D.smilacis and P.smilacis (deposited in the USNM) confirm that they are indeed placed in the appropriate genera, although the status of either species and their biological relationships remain suspect and require further investigation.
Galls of Diastrophini (Figs 92–94) can be collected for rearing in the fall, winter, or spring. As in Aulacideini, galls on herbaceous hosts are best collected after host plants have senesced, and adults of all Diastrophus emerge in spring and summer.
North American species (Nastasi and Deans 2021):
1. Diastrophusaustrior Kinsey, 1922
2. Diastrophusbassettii Beutenmüller, 1892
3. Diastrophuscuscutaeformis Osten Sacken, 1863
4. Diastrophusfragariae Beutenmüller, 1915
5. Diastrophusfusiformans Ashmead, 1890
6. Diastrophuskincaidii Gillette, 1893
7. Diastrophusnebulosus (Osten Sacken, 1861)
8. Diastrophusniger Bassett, 1900
9. Diastrophuspiceus Provancher, 1886
10. Diastrophuspotentillae Bassett, 1864
11. Diastrophusradicum Bassett, 1870
12. Diastrophussmilacis Ashmead, 1896
13. Diastrophustumefactus Kinsey, 1920
14. Diastrophusturgidus Bassett, 1870
. Periclistus
Förster, 1869
EA834995-DD1E-5E18-8785-CC99D93EB1D7
Type species.
Aylaxcaninae Hartig, 1840.
Diagnosis.
Mesoscutum generally coarsely sculptured, usually densely pubescent, and with abundant strong setigenous punctures. Notauli incomplete, indistinct at least in anterior third, and weaker throughout. Fore wing with marginal cell closed. Metasoma with syntergite in females but with all tergites free and articulating in males.
Note.
Periclistus contains seven North American species, all of which are inquilines of Diplolepis Geoffroy inducing galls on species of Rosa L., except for P.smilacis Ashmead (see treatment of Diastrophus Hartig). The diversity of this genus is not well understood; Ritchie (1984) treated ten Nearctic species in his unpublished thesis including six new species, but a recent DNA barcoding study (Zhang et al. 2019) revealed the presence of two undescribed Nearctic species. More broadly, future study is needed to investigate host associations, especially given the presence of undescribed species.
North American species (Nastasi and Deans 2021):
1. Periclistusarefactus McCracken & Egbert, 1922
2. Periclistuscalifornicus Ashmead, 1896
3. Periclistusobliquus Provancher, 1888
4. Periclistuspiceus Fullaway, 1911
5. Periclistuspirata (Osten Sacken, 1863)
6. Periclistussemipiceus (Harris, 1841)
7. Periclistussmilacis Ashmead, 1896
. Synophromorpha
Ashmead, 1903
FB4B49D3-90DB-52A4-B693-5E88504E1CEE
Type species.
Synophrussylvestris Osten Sacken, 1861.
Diagnosis.
Mesoscutum generally less coarsely sculptured, appearing mostly or entirely coriaceous, less pubescent, and with some strong setigenous punctures. Notauli complete, strong throughout. Fore wing with marginal cell open. Metasoma with syntergite in females but with all tergites free and articulating in males.
Note.
Synophromorpha is represented by four species in North America, all of which are inquilines of Diastrophus species associated with Rubus L. Ritchie and Shorthouse (1987) described the species S.kaulbarsi Shorthouse & Ritchie, 1987 from a single specimen collected in Mexico; they speculated that this species was evidence of undiscovered Mexican Diastrophus or represented the use of an alternative host such as an oak gall wasp.
North American species (Nastasi and Deans 2021):
1. Synophromorphakaulbarsi Ritchie & Shorthouse, 1987
2. Synophromorpharubi Weld, 1952
3. Synophromorphasylvestris (Osten Sacken, 1861)
4. Synophromorphaterricola Weld, 1952
. Diplolepis
Geoffroy, 1762 (Diplolepididae: Diplolepidinae)
1B6BF731-560C-53EB-883F-D7ADBB6E8E1E
Figures 76–79.
76Diplolepisbicolor, lateral view (USNMENT01231831) 77Diplolepisbicolor, lateral view (USNMENT01231831) 78Diplolepisbicolor, dorsal view (USNMENT01231831) 79Diplolepisrosae, fore wing (USNMENT00655959).
Type species.
Cynipsrosae Linnaeus, 1758.
Diagnosis.
Pronotum distinctly short and narrow dorsomedially, without distinct plate or pits. Scutellar foveae faint or absent, never distinct and well impressed. Mesopleuron with broad crenulate medial impression. Female hypopygium plowshare-shaped.
Note.
Diplolepidinae includes 34 described North American species in Diplolepis Geoffroy which induce structurally diverse galls (Figs 90, 91) on Rosa (Rosaceae) and are widely distributed in the US and Canada (Nastasi and Deans 2021). Recent phylogenomic studies (Blaimer et al. 2020; Hearn et al. 2023) showed that the tribe Diplolepidini clustered together with Pediaspidini outside of the core Cynipidae, causing Cynipidae to form a paraphyletic grade at the base of Cynipoidea. Hearn et al. (2023) raised the former tribe Diplolepidini to subfamily rank (Diplolepidinae) within the family Diplolepididae. All other taxa treated here remain in the Cynipidae.
North American species (Nastasi and Deans 2021):
1. Diplolepisarefacta (Gillette, 1894)
2. Diplolepisashmeadi (Beutenmüller, 1918)
3. Diplolepisbassetti (Beutenmüller, 1918)
4. Diplolepisbicolor (Harris, 1841)
5. Diplolepiscalifornica (Beutenmüller, 1914)
6. Diplolepisdichlocera (Harris, 1841)
7. Diplolepisfulgens (Gillette, 1894)
8. Diplolepisfusiformans (Ashmead, 1890)
9. Diplolepisgracilis (Ashmead, 1897)
10. Diplolepisignota (Osten Sacken, 1863)
11. Diplolepisinconspicuis Dailey & Campbell, 1973
12. Diplolepislens Weld, 1952
13. Diplolepismayri (Schlechtendal, 1877)
14. Diplolepisnebulosa (Bassett, 1890)
15. Diplolepisneglecta (Gillette, 1894)
16. Diplolepisnervosa (Curtis, 1838)
17. Diplolepisnodulosa (Beutenmüller, 1909)
18. Diplolepisoregonensis (Beutenmüller, 1918)
19. Diplolepisostensackeni (Beutenmüller, 1918)
20. Diplolepispolita (Ashmead, 1890)
21. Diplolepispustulatoides (Beutenmüller, 1914)
22. Diplolepisradicum (Osten Sacken, 1863)
23. Diplolepisrosae (Linnaeus, 1758)
24. Diplolepisrosaefolii (Cockerell, 1889)
25. Diplolepissimilis (Ashmead, 1896)
26. Diplolepisspinosa (Ashmead, 1887)
27. Diplolepisterrigena Weld, 1952
28. Diplolepistriforma Shorthouse & Ritchie, 1984
29. Diplolepistuberculator (Cockerell, 1888)
30. Diplolepistuberculosa (Osten Sacken, 1861)
31. Diplolepistumida (Bassett, 1890)
32. Diplolepisvariabilis (Bassett, 1890)
33. Diplolepisverna (Osten Sacken, 1863)
34. Diplolepisweldi (Beutenmüller, 1913)
. Phanacis
Förster, 1860 (Phanacidini)
EBC146B8-4F12-5ED5-B850-57169C26BD71
Figures 80–82.
80Phanacis sp., anterodorsal view (USNMENT01448498) 81Phanacis sp., wings (USNMENT01231855) 82Phanacis sp., lateral view (USNMENT01231855).
Type species.
Parapanteliellaeugeniae Diakontschuk, 1981.
Diagnosis.
Pronotum tall and broad dorsomedially. Pronotal submedial pits rather indistinct and poorly impressed, appearing as a narrow linear impression rather than distinct ovular pits. Pronotal plate present, usually only distinct in anterior half of pronotum. Mesopleuron sculpture reticulate. Mesoscutellar foveae distinct. Fore wing with marginal cell partially open, with vein R1 reaching anterior margin of fore wing and continuing along wing margin but not meeting vein Rs. Wings always hyaline, never tinted or with darkened areas. Metatarsal claws without basal lobe. Metasomal tergites 2 and 3 free and articulate, never with a syntergite.
Note.
Phanacidini includes two North American species, both in Phanacis Förster, which have been introduced along with their host plants (Nastasi and Deans 2021). Phanacishypochoeridis (Kieffer, 1887) induces galls on Hypochaerisradicata L. and is apparently restricted to the western United States (Nastasi and Deans 2021). The other species, P.taraxaci (Ashmead, 1897), induces galls on Taraxacumofficinale F. H. Wigg. (Fig. 95) and is widespread in eastern North America (Nastasi and Deans 2021).
North American species (Nastasi and Deans 2021):
1. Phanacishypochoeridis (Kieffer, 1887)
2. Phanacistaraxaci (Ashmead, 1897)
. Synergus
Hartig, 1840 (Synergini)
F3875393-5486-52E8-A5E0-41E7FD45E6D4
Figures 83–86.
83Synergus sp., lateral view (PSUC_FEM 000079457) 84Synergusincisus, dorsal view (USNMENT01231859) 85Synerguslignicola, anterior view (USNMENT01448497) 86Synergus sp., metasoma, lateral view (USNMENT01231858).
Type species.
Synergusvulgaris Hartig, 1840.
Diagnosis.
Pronotum tall and broad dorsomedially. Pronotal submedial pits distinct and well-impressed. Pronotal plate present but mostly indistinct. Mesoscutellar foveae usually distinct. Fore wing always with marginal cell closed (apparently only partly closed in Synergusmexicanus Gillette, 1896; see Pujade-Villar et al. 2015). Metatarsal claws with or without basal lobe. Metasoma with syntergite, with second and third tergites entirely fused, greatly enlarged, and occupying most of metasoma. Body generally strongly sculptured.
Note.
Sixty-one species of Synergus are known from North America (Nastasi and Deans 2021). Members of Synergus Hartig are inquilines of galls induced by Cynipini on oaks (Buffington et al. 2020). Synergus are extremely commonly reared and are known in association with hundreds of oak gall wasps (Nastasi and Deans 2021; Ward et al. 2022). Synergus is demonstrably polyphyletic, with North American taxa forming as many as three independent clades and many undescribed species exist (Pénzes et al. 2012; Lobato-Vila and Pujade-Villar 2021; Lobato-Vila et al. 2022), meaning a great deal of revisionary work will be needed to resolve major questions within the genus and better understand its diversity.
The genus Saphonecrus Dalla Torre & Kieffer (Tribe Synergini) has long been considered present in North America, but recent taxonomic work refutes this idea. Nastasi and Deans (2021) reported two species: S.favanus Weld and S.gemmariae (Ashmead). Saphonecrusgemmariae was reported in error as the species was considered incertae sedis by Lobato-Vila et al. (2022) due to missing type material which was supposedly deposited in the National Museum of Natural History (USA, D.C.). Upon our own examination of the USNM collection, we were unable to locate the relevant type material. Similarly, the status of S.favanus is also questionable (Pénzes et al. 2009; Pénzes et al. 2012; Lobato-Vila and Pujade-Villar 2021); this species may represent a new genus distinct from other Synergini (Lobato-Vila et al. 2022). As such, we consider the presence of Saphonecrus in North America doubtful and have omitted Saphonecrus from the above key. We have examined type material of S.favanus deposited in USNM (specimen # USNMENT960420 and three additional individuals) and found that in the key to genera, the specimens key to Synergus, bearing no strong distinction from this genus. The taxonomy of the tribe Synergini as a whole is currently uncertain, and ongoing efforts to revise it will likely result in a stronger understanding of the North American fauna (Lobato-Vila et al. 2022).
North American species (Nastasi and Deans 2021):
1. Synergusagrifoliae Ashmead, 1896
2. Synergusashmeadi Lobato-Vila & Pujade-Villar, 2021
3. Synergusaurofacies Lobato-Vila & Pujade-Villar, 2020
4. Synergusatra Gillette, 1896
5. Synergusatripennis Ashmead, 1896
6. Synergusatripes Gillette, 1896
7. Synergusbatatoides Ashmead, 1885
8. Synergusbellus McCracken & Egbert, 1922
9. Synergusbeutenmulleri Lobato-Vila & Pujade-Villar, 2021
10. Synergusbrevicornis Ashmead, 1896
11. Synergusbicolor Ashmead, 1885
12. Synerguscampanula Osten Sacken, 1865
13. Synerguscastanopsidis (Beutenmüller, 1918)
14. Synerguscibriani Lobato-Vila & Pujade-Villar, 2017
15. Synerguscitriformis (Ashmead, 1885)
16. Synerguscompressus Lobato-Vila & Pujade-Villar, 2021
17. Synergusconfertus McCracken & Egbert, 1922
18. Synergusconiferae Ashmead, 1885
19. Synergusdigressus McCracken & Egbert, 1922
20. Synergusdimorphus Osten Sacken, 1865
21. Synergusdistinctus McCracken & Egbert, 1922
22. Synergusdiversicolor Lobato-Vila & Pujade-Villar, 2021
23. Synergusdorsalis (Provancher, 1888)
24. Synergusduricorius Gillette, 1896
25. Synergusebenus Lobato-Vila & Pujade-Villar, 2021
26. Synergusequihuai Pujade-Villar & Lobato-Vila, 2016
27. Synerguserinacei Gillette, 1896
28. Synergusestradae Pujade-Villar & Lobato-Vila, 2016
29. Synergusficigerae Ashmead, 1885
30. Synergusfilicornis Cameron, 1883
31. Synergusflavens McCracken & Egbert, 1922
32. Synergusforcadellae Lobato-Vila & Pujade-Villar, 2020
33. Synergusgilletti Pujade-Villar & Lobato-Vila, 2017
34. Synergusgrahami Lobato-Vila & Pujade-Villar, 2019
35. Synergusincisus Gillette, 1896
36. Synerguslaeviventris (Osten Sacken, 1861)
37. Synerguslignicola (Osten Sacken, 1862)
38. Synerguslinnei Lobato-Vila & Pujade-Villar, 2021
39. Synerguslongimalaris Pujade-Villar & Lobato-Vila, 2017
40. Synerguslongiscapus Pujade-Villar & Lobato-Vila, 2017
41. Synergusmacrackenae Lobato-Vila & Pujade-Villar, 2021
42. Synergusmedullae Ashmead, 1885
43. Synergusmendax Walsh, 1864
44. Synergusmexicanus Gillette, 1896
45. Synergusnigroornatus McCracken & Egbert, 1922
46. Synergusoaxaquensis Lobato-Vila & Pujade-Villar, 2021
47. Synergusobtusilobae (Ashmead, 1885)
48. Synergusochreus Fullaway, 1911
49. Synergusoneratus (Harris, 1841)
50. Synerguspacificus McCracken & Egbert, 1922
51. Synerguspersonatus Lobato-Vila & Pujade-Villar, 2021
52. Synerguspomiformis Ashmead, 1885
53. Synerguspseudofilicornis Lobato-Vila & Pujade-Villar, 2018
54. Synerguspunctatus Gillette, 1896
55. Synergusquercuslana (Fitch, 1859)
56. Synergusreniformis McCracken & Egbert, 1922
57. Synergusruficephalus Lobato-Vila & Pujade-Villar, 2021
58. Synergusrutulus McCracken & Egbert, 1922
59. Synergusshorthousei Lobato-Vila & Pujade-Villar, 2019
60. Synergusstelluli Burnett, 1976
61. Synergusstratifrons Pujade-Villar & Lobato-Vila, 2017
62. Synergussuccinipedis (Ashmead, 1885)
63. Synergustenebrosus Lobato-Vila & Pujade-Villar, 2019
64. Synergusvillosus Gillette, 1891
65. Synergusvirentis (Ashmead, 1885)
66. Synerguswalshii Gillette, 1896
67. Synergusweldi Lobato-Vila & Pujade-Villar, 2021
Supplementary Material
Acknowledgments
We are indebted to Laura Porturas, Michael Skvarla, Codey Mathis, Anne Johnson, Cecil Smith, Jelani Alcorn, Sarah Kaniah, Abby Noel, and Michael Belt for assisting us in testing the key and providing valuable comments. We also thank Y. Miles Zhang for providing commentary on Diplolepis. Lastly, Victor Cuesta Porta and Stephanie Eskew reviewed the manuscript and provided valuable feedback.
Mention of trade names or commercial products in this publication is solely for the purpose of providing specific information and does not imply recommendation or endorsement by the USDA. USDA is an equal opportunity provider and employer.
Citation
Nastasi LF, Buffington ML, Davis CK, Deans AR (2024) Key to the North American tribes and genera of herb, rose, bramble, and inquiline gall wasps (Hymenoptera, Cynipoidea, Cynipidae sensu lato). ZooKeys 1196: 177–207. https://doi.org/10.3897/zookeys.1196.118460
Additional information
Conflict of interest
The authors have declared that no competing interests exist.
Ethical statement
No ethical statement was reported.
Funding
This material is based upon work supported by the National Science Foundation under Grant No. DEB-1856626. Any opinions, findings, and conclusions or recommendations expressed in this material are those of the authors and do not necessarily reflect the views of the National Science Foundation. The first author was generously supported by two awards from the Society of Systematic Biologists: Mini-ARTS and the Graduate Student Research Award.
Author contributions
Conceptualization: LFFN. Funding acquisition: ARRD. Investigation: LFFN, MLLB, CKD. Methodology: MLLB, LFFN. Project administration: LFFN. Resources: MLLB, ARRD. Supervision: MLLB, ARRD. Validation: MLLB. Visualization: CKD, LFFN. Writing - original draft: LFFN. Writing - review and editing: MLLB, CKD, ARRD.
Author ORCIDs
Louis F. Nastasi https://orcid.org/0000-0001-7825-480X
Matthew L. Buffington https://orcid.org/0000-0003-1900-3861
Charles K. Davis https://orcid.org/0000-0001-6056-3903
Andrew R. Deans https://orcid.org/0000-0002-2119-4663
Data availability
All of the data that support the findings of this study are available in the main text.
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Associated Data
This section collects any data citations, data availability statements, or supplementary materials included in this article.
Supplementary Materials
Data Availability Statement
All of the data that support the findings of this study are available in the main text.