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Silphium G a ll Wa sp s: L i t t l e- K now n P r a irie Sp eci a lis t s Richard Henderson, Wisconsin Department of Natural Resources, Science Operation Center, 2801 Progress Road, Madison, WI 53716-3339, [email protected] scott b. sauer, 4302 Clover Ct., Madison, Wisconsin 53711 Abstract: The original prairies of the Midwest have nearly vanished, and thus so have many of the insects linked to prairie vegetation. In 1891, five species of gall-forming wasps, Antistrophus spp. (Hymenoptera: Cynipidae), were described from various plants in the genus Silphium (compassplant, prairie dock, rosinweed, and cup-plant) growing in Illinois prairies. These wasps are thought to live only in Silphium spp., which are characteristic plants of our Midwest prairies. Silphium spp. once dominated the landscape, but now they are mostly limited to scattered remnants of original prairie and prairie plantings. For one hundred years following the description of these wasps, the scientific community paid them very little attention. Then, starting in the early 1990s, researchers began to take interest in the group, describing additional species and investigating the wasps’ ecology and response to fire. However, the distribution and conservation status of Silphium gall wasps are still very much a mystery. Recently, two species have been documented for the first time in Wisconsin, and more species are suspected of being present. Efforts to document the distribution and status of these uncommon prairie specialists in Wisconsin and adjoining states are being made. Key Words / Search Terms: insects, tallgrass prairie, Antistrophus, Hymenoptera, Cynipidae, compassplant, prairie dock, rosinweed, cup-plant, conservation Discovery Working in central Illinois in the late 1880s, as the last of the tallgrass prairies were succumbing to the plow and cow, Dr. Clarence P. Gillette, along with collaborators Mr. C.A. Hart and Mr. J. Marten, discovered several species of small (2-5 mm) gall-forming wasps associated with four plants of the genus Silphium: S. laciniatum (compassplant), S. terebinthinaceum (prairie dock), S. integrifolium (rosinweed), and S. perfoliatum (cup-plant). These were among the most dominant plants of the original eastern tallgrass prairies. Gillette and company made observations in the field and reared adult wasps from plant tissue. From this work, Gillette published descriptions of five Cynipid (Hymenoptera) wasps of the genus Antistrophus (Gillette 1891). Antistrophus silphii Gillette described this species as forming abrupt, large (2.54.5 cm) subglobular swellings (galls) at the tips of the stems of rosinweed and cup-plant (Figure 1). Each gall supported 116 Figure 1. Terminal stem gall on rosinweed (Silphium integrifolium). Photo by R. Henderson. many wasp larvae. Gillette concluded that adult specimens (Figure 2) reared from both species of plants “were in every way identical with those from galls of the other species.” He found that the wasps overwintered as pupae in individual cells within the pith of the galls, emerging as adults in May or June (Figure 3). Figure 2. Adult Antistrophus silphii gall wasp reared from a rosinweed (Silphium integrifolium) terminal stem gall in Wisconsin. Photo by S. Sauer. 2 2 n d N o r t h A m e r i c a n p r a i r i e c o n f e r e n c e | PR A IRIE F L OR A A ND F A U N A wasp larvae chambers numerous than A. rufus. Dr. Gillette, along with Mr. Hart, visited “fields” of compassplant and “found that the majority of the stems were more or less infested with cynipidous larvae, hundreds of which could, in some cases, be found in a single stem.” They went on to investigate other Silphium species in the area and “found similar larval cells abundant in S. perfoliatum, S. terebinthinaceum, and S. integrifolium.” However, they did not rear specimens from these stems to see what species of Antistrophus wasps were present. Figure 3. Cross-section of rosinweed terminal stem gall showing Antistrophus silphii larvae chambers. Photo by S. Sauer. Antistrophus laciniatus Gillette described this species as forming individual, small (4-5 mm), egg-shaped galls occurring in clusters in the flower disks of compassplant (Figure 4). Each gall supports one wasp. The galls occupy the center of the flower disk among the male (sterile) florets. The flowers appear unaffected by the wasps, with the gall cluster becoming evident only as the flower head ripens and falls apart, revealing the galls. Figure 5. Cross-section of compassplant (Silphium laciniatum) stem inhabited by Antistrophus wasps and Mordellid beetle larvae. Photo by S. Sauer. Antistrophus bicolor Gillette did not offer much information about this species. He described it from a single specimen from Normal, Illinois. Both the host plant and gall of the wasp were unknown to him. Seventy years later, Weld (1959) reports the collection date of Gillette’s type specimen as being July 6, 1884, and the accompanying accession catalogue as stating “from Silphium integrifolium.” Figure 4. Antistrophus laciniatus galls from the flower disks of compassplant (Silphium laciniatum) in WI. Photo by R. Henderson. Antistrophus rufus and A. minor Gillette reared both of these species from flower stalk stems of compassplant, but unlike the previous two species, there was no evidence of gall formation. Instead, he found that the wasps pupated in little cells within the pith just under the outer wall of the stem (Figure 5). A. minor was smaller and less Forgotten and Rediscovered After Gillette’s work, there appears to have been nothing published about these Antistrophus species for the next 35 years, except for some confusing name-changing and occasional misidentifications by taxonomists, and the passing along (sometimes with errors) of Gillette’s original observations (Bassett 1900, Kieffer 1902, Beutenmuller 1910). For example, Beutenmuller (1910) listed all four species of Silphium as hosts for A. rufus. This is likely an error, since his only reference, Gillette (1891), confirmed A. rufus from only compassplant. The Antitrophus wasp larvae Gillette found in the stems of the other species were not reared out and identified. In 1912, Lewis H. Weld began to collect specimens and make field observations of Silphium gall wasps in northeast Illinois (Weld 1926). He reaffirmed compass plant as the host for A. laciniatus, A. rufus, and A. minor, and docu- 2 2 n d N o r t h A m e r i c a n p r a i r i e c o n f e r e n c e | PR A IRIE F L OR A A ND F A U N A 117 mented A. minor as also using prairie dock. In 1915 and 1917, Weld documented A. silphii forming terminal stem galls on cup-plant in eastern Nebraska. This was the first published record of any Silphium gall wasp being found outside of Illinois. Weld also presented information indicating that Gillette’s A. bicolor should be considered a synonym of an earlier described species (Aulacidea harringtoni). Weld found the plant genius Lactuca to be a host for this gall wasp. However, 30 years later, Weld (1959) treats A. bicolor as a distinct species. In the Catalog of Hymenoptera in America North of Mexico (Burks 1979), Antistrophus bicolor is listed as both a good species in its own right and as a synonym of Aulacidea harringtoni (same author citation for both listings!), with the host listed as Lactuca spp. Burks (1979) listed Illinois as the only location for A. bicolor, and, he states, “Said to produce galls on Silphium integrifolium,” but he gave no reference for this. Gillette (1891), the only Illinois source, provided no information as to hosts or galls for A. bicolor. Weld (1959) reported the type specimen as coming from S. integrifolium. A. bicolor appears to be a poorly known species in need of both taxonomic and ecological work. Burks’s 1979 comments on A. rufus listed Kansas, in addition to Illinois, as a location for the species. This was the first reported record outside of Illinois for this species, and is presumably based on a museum specimen, but he provided no reference. He listed compassplant as the only host for A. rufus. As far as we have been able to determine, it was not until 1991 that any new work on the ecology and habits of Silphium gall wasps was published since the works of Gillette and Weld, 100 and 80 years earlier, respectively. Then the activity of work on Silphium gall wasps picked up significantly and remains steady to the present. The “rediscovery” of these wasps started in 1988, with work at the Konza Prairie Research Natural Area in eastern Kansas, where Philip Fay and others began to investigate the ecology of A. silphii on rosinweed and its affect on that host plant (Fay and Hartnett 1991, Fay and Samenus 1993, Fay et al. 1996). Their research appears to constitute the first and only published reports of this gall wasp in Kansas. The authors reported its being very common in the area, with over a third of rosinweed shoots galled, and up to 30 larvae per gall (Fay and Hartnett 1991). The authors also reported an unknown gall in the disk florets of rosinweed at Konza. They speculated that it might be A. laciniatus (Fay et al. 1996), but did not rear out adult specimens to confirm. It appears that A. laciniatus has yet to be confirmed outside of Illinois. In 1999, John Tooker and others began to investigate the ecology and habits of internal stem Antistrophus wasps in central Illinois, where the wasps were first discovered. They looked at the endophytic insect communities inhabiting the stems of compassplant and prairie dock (Tooker and Hanks 2004a). They found both A. rufus and A. minor to be common at all eight sites they surveyed, and present in both spe118 cies of Silphium (compassplant and prairie dock). However, A. rufus was three times more abundant than A. minor. The average density of internal galls per stem was 80 for compassplants and 62 for prairie dock. This appears to be the first published documentation of A. rufus using prairie dock. Tooker and Hanks also confirmed that A. rufus and A. minor behave just as Gillette (1891) described for A. silphii, in that the wasps overwinter as pupae in individual cells within the pith of the galls, in this case within the pith of the stems, and emerge as adults in May or June. Tooker et al. (2004b) went on to study the genetic, morphological, and ecological differences of A. rufus populations using compassplant, prairie dock, and cup-plant. They concluded that each species of plant has its own species of wasp within what is now considered the A. rufus complex of species (an apparent example of co-evolution). The recognized species are now A. rufus (restricted to compassplant), A. meganae (restricted to prairie dock), and A. jeanea (restricted to cup-plant). This now makes six Antistrophus species confirmed as being restricted to prairie Silphium spp. But the story is still unfolding. Recent work, yet to be published, by Zhiwei Liu and colleagues at Eastern Illinois University is demonstrating that the terminal stem gall wasps found on rosinweed and cupplant (A. silphii) may actually consist of two different, but morphologically very similar, species, as was the case with the A. rufus complex. This is based on host selection data (Ginder and Liu 2010), and an ongoing project by Liu and colleagues looking at genetic markers (Z. Liu, personnel communication, 2010). If these putative species prove valid, that will make seven species of Antistrophus tied to prairie Silphium spp. But this still may not be the end of the story. Questions still remain about the host, ecology, and taxonomic status of A. bicolor, and no one has documented what Antistrophus species are in the stems of rosinweed, as first noted by Gillette (1891). Might this be yet another new species or simply A. bicolor? We have been unable to find published documentation of internal stem galls using rosinweed since Gillette’s original observations. A complete list of species along with listings of published host associations and the states they have been reported in is provided in Table 1. Associated Insects The recent work on Silphium gall wasps has revealed a whole community of endophytic (within a plant) insects associated with prairie Silphium spp., in some cases possibly dependent upon them. Fay et al. (1996) observed an undescribed species of Eurytoma wasp regularly parasitizing A. silphii wasps in rosinweed galls. Tooker and Hanks (2004b), during a detailed study of endopyhtic insects of compassplant and prairie dock in Illinois, found eight species of parasitoid wasps attacking A. rufus and A. minor gall wasps, or in some cases possibly attacking the parasitoid wasps attacking the Antistrophus wasps. They presented evidence that one of 2 2 n d N o r t h A m e r i c a n p r a i r i e c o n f e r e n c e | PR A IRIE F L OR A A ND F A U N A Table 1. Antistrophus spp. (gall wasps) associated with prairie Silphium spp., along with documented host plant and location records. SOURCE WASP SPECIES HOST PLANT Gillette 1891 Weld 1926 w& 1959 ??2 A. bicolor rosinweed? IL (Normal)1 A. jeanae cup-plant IL A. laciniatus compass plant IL (Champaign) A. meganae prairie dock IL A. minor compass plant IL A. minor prairie dock Winterringer 1961 Burks 1979 Fay et Tooker et al. 1990 al. 2000 Liu 2010 IL in rosinweed3 IL IL (Glenview) IL IL (Evanston) IL IL IL (Evanston) A. rufus compass plant IL IL (Evanston) A. silphii rosinweed IL (Champaign) IA4 A. silphii cup-plant IL (Normal) NE (Valley & Omaha) & IA4 Antistrophus sp. rosinweed IL IL IL & KS3 IL KS IL IL & NE KS, MO, & IL IL No rearing from stems or galls reported. Taxonomy unclear; reared from Lactuca (1926); reports the accession catalogue of the type specimen as being from rosinweed (1959). 3 No source given, assumed to be from specimen labels or accession catalogues. 4 Unclear as to whether the reported IA collection was from cup-plant or rosinweed. 1 2 the parasitoids, Eurytoma lutea, may be a specialist on Antistrophus wasps. They also consistently found the larvae of a mordellid (tumbling flower) beetle, Mordellistena aethiops, burrowing through the stems of compassplant and prairie dock (Figures 5 and 6), along with three species of parasitoid wasps that appear to attack this beetle. They demonstrated that M. aethiops larvae are omnivores, consistently eating both plant tissue and wasp larvae (Tooker and Hanks 2004c), which is unusual for the Mordellistena genus. Their larvae are normally reported as stem-boring herbivores (Ford and Jackman 1996). Figure 6. Tumbling flower beetle, presumably Mordellistena aethiops, emerging from a Silphium stem. Photo by S. Sauer. Distribution, Status, and Future Work Since 1996 we have had a collaborative project looking into which insects species are associated with and dependent upon remnant prairies in Wisconsin and the Upper Midwest. We have also focused on the status, distribution, and response to management of these remnant-dependent species. However, since up to 2,000 species likely fall into this category, we have not been able to address all taxonomic groups, and thus we had paid relatively little attention to gall wasps. We were aware from the literature that there were gall wasps associated with Silphium spp., but they had been reported only from Illinois, Nebraska, and Kansas. There were no specimens or records from Wisconsin. So we did not spend time looking for them here until the fall of 2005, when the lead author (Henderson) noticed a large terminal stem gall on rosinweed in the Madison area and began to wonder if this could be the work of A. silphii. He had seen galls on rosinweed on rare occasions in the past, but had dismissed them as the likely product of generalist gall-formers. This time, however, he collected the gall and waited to see what emerged. Wasps emerged, and a year later we learned that they were indeed A. silphii. So, in 2007, we began to look informally for terminal stem galls on rosinweed. We found them in a few more locations, but they were not at all common, except at a site called Underwood Prairie, west of Madison. Galls were common there, but still far below the densities observed at Konza Prairie in Kansas, where 35% of the rosinweed stems had galls (Fay and Harnett 1991). In comparison, only 2% of the stems at Underwood Prairie had galls. In 2007, we also collected a few stems of compassplant to see what they might hold. They produced what has tentatively been identified as A. bicolor. If this proves true, this will be not only the first documentation of this species in the state, but the first documentation of its using a Silphium species other than rosinweed. Now knowing that at least some Silphium gall wasp species are in the state, we conducted an investigation to learn more about their distribution and status here. In early April of 2009, we visited some 40 sites in southern Wisconsin and collected stems of compassplant, prairie dock, rosinweed, and cup-plant, and looked for and collected terminal stem galls on rosinweed and cup-plant. We also solicited people 2 2 n d N o r t h A m e r i c a n p r a i r i e c o n f e r e n c e | PR A IRIE F L OR A A ND F A U N A 119 to be on the lookout for, and to send us, terminal stem galls on Silphium spp. We also collected flower disk galls from compassplant at a few sites. Anyone collecting compassplant seed in Wisconsin knows that gall clusters in the center of their flower disks are a common occurrence. But apparently no one has tried to find out what is inside those galls. So we collected them in anticipation of finding A. laciniatum. We also made a few collections from a variety of Silphium spp. in Iowa, since there does not appear to be any published documentation of Silphium gall wasps in Iowa either. Identifications of the emerged materials have yet to be confirmed, but there appear to be many Antistophus specimens, a variety of parasitoid wasps (Figures 7 and 8), and many mordellid beetles, possibly Mordellistena aethiops (Figure 6). If the identification of M. aethiops is confirmed, this would be the first record of that beetle in Wisconsin. We found terminal stem galls on rosinweed at six sites in Figure 7. Parasitoid wasp (Eurytomid sp.) emerging from rosinweed terminal stem gall. Photo by S. Sauer. Wisconsin and two in Iowa, and on cup-plant at four sites in Wisconsin and two in Iowa. We found Antistrophus gall wasps in the stems of compassplant at 14 of 18 sites in Wisconsin and 5 of 7 in Iowa; in prairie dock at 18 of 20 sites in Wisconsin; in cup-plant at 3 of 4 sites in Wisconsin and 2 of 2 in Iowa; and in rosinweed at 9 of 11 sites in Wisconsin and possibly 4 of 4 sites in Iowa. Lastly, we found what appear to be A. laciniatum wasps at four sites in Wisconsin. From what we have observed so far, A. silphii appears to be the rarest of the Silphium gall wasps in the state of Wisconsin, and may be worth consideration as a species of greatest conservation need (SGCN). In the case of the cup-plant gall, listing as state endangered or threatened may be warranted. Only a third of the rosinweed populations we checked had terminal stem galls, and, with the exception of the Underwood Prairie site, the gall numbers were very low. Adding to this relative rarity is the fact that, today, rosinweed is very limited in its occurrence on the landscape compared to its great prevalence 200 years 120 Parasitoid wasps reared from compassplant stems Clalcidoidea sp. (reared from rosinweed gall) Figure 8. Parasitoid wasps reared from Silphium galls and stems in WI. Photos by S. Sauer. ago, when prairie and savanna dominated the landscape of southern and western Wisconsin. Galls on cup-plant were extremely hard to find. After visiting 50 or more cupplant populations, and getting word out to people to send us galls, we had only six galls from four sites to show for it. We estimate that only 1% or 2% of cup-plant populations in Wisconsin support this wasp. The cup-plant gall appears to be uncommon in Illinois as well. Winterringer (1961) described it as rather uncommon in Illinois in the 1950s. Dr. Liu of Eastern Illinois University considers the cup-plant gall to be much less common than the rosinweed gall, and it should probably be considered endangered (Z. Liu, personal communication, 2010). We are currently working to get our material identified by specialists, and are seeking funding to (1) conduct a more thorough survey of Silphium gall wasps in the state, (2) conduct research on the effects of fire on these wasps and their associated endophytic insect communities, and (3) investigate the distribution and status of these wasps throughout their range. This community of specialist insects shows that there is still much to learn, and re-learn, about the tallgrass prairie ecosystem, and that a great diversity of species is a part of, and dependent upon, that ecosystem. Lastly, it is amazing to us that such great diversity still exists, given that only a small fraction of 1% of the original acreage of tallgrass prairie has survived, and most in small isolated patches. It gives one hope that recovery and restoration of the system are still possible. Literature Cited Bassett, H. F. 1900. American Hymenoptera. American Entomological Society Transactions 26:310. Beutenmuller, W. 1910. The North American species of Aylax and their galls. Bulletin of the American Museum of Natural History 28:137-144. 2 2 n d N o r t h A m e r i c a n p r a i r i e c o n f e r e n c e | PR A IRIE F L OR A A ND F A U N A Burks, B. D. 1979. Superfamily Cynipoidea. Pages 10451107. In K. V. Krombein, P. D. Hurd, D. R. Smith, and B. D. Burks (eds.), Catalog of Hymenoptera in America north of Mexico. Volume 1. Smithsonian Institution Press, Washington, DC. Fay, P. A. and D. C. Hartnett. 1991. Constraints on growth and allocation patterns of Silphium integrifolium (Asteraceae) caused by a cynipid gall wasp. Oecologia 88:243250. Fay, P. A., D. C. Hartnett, and A. K. Knapp. 1996. Plant tolerance of gall-insect attack and gall-insect performance. Ecology 77:521-534. Fay, P. A. and R. J. Samenus. 1993. Gall wasp (Hymenoptera: Cynipidae) mortality in a spring tallgrass prairie fire. Environmental Entomology 22:1333-1337. Ford, E. J. and J. A. Jackman. 1996. New larval host plant associations of tumbling flower beetles (Coleoptera: Mordellidae) in North America. Coleopterists Bulletin 50:361-368. Gillette, C. P. 1891. Descriptions of new Cynipidae in the collection of the Illinois State Laboratory of Natural History. Bulletin of the Illinois State Laboratory of Natural History 3:191-197. Ginder, D. J. and Z. Liu. 2010. Unpublished data. Eastern Illinois University, Charleston. Kieffer, J. J. 1902. Revision du genre Aulax. Bulletin de la Société d’histoire naturelle de Metz 10(2):93-95. Tooker, J. T., A. R. Deans, and L. M. Hanks. 2004. Description of the Antistrophus rufus (Hyhmenoptera: Cynipidae) species complex, including two new species. Journal of Hymenoptera Research 13:125-133. Tooker, J. T., and L. M. Hanks. 2004a. Impact of prescribed burning on endophytic insect communities of prairie perennials (Asteraceae: Silphium spp.). Biodiversity and Conservation 13:1875-1888. Tooker, J. T., and L. M. Hanks. 2004b. Endophytic insect communities of two prairie perennials (Asteraceae: Silphium spp.). Biodiversity and Conservation 13:2551-2566. Tooker, J. T., and L. M. Hanks. 2004c. Trophic position of the endophytic beetle Mordellistena aethiops Smith (Coleopteara: Mordellidae). Environmental Entomology 33:291-296. Weld, L. H. 1926. Field notes on the gall-inhabiting Cynipid wasps with descriptions of new species. Proceedings of the U.S. National Museum, vol. 68, article 10, 1-131. Weld, L. H.. 1959. Cynipid galls of the eastern United States. Privately printed, Ann Arbor, MI. Winterringer, G. S. 1961. Some plant galls of Illinois. Story of Illinois Series no. 12, Illinois State Museum, Springfield. 2 2 n d N o r t h A m e r i c a n p r a i r i e c o n f e r e n c e | PR A IRIE F L OR A A ND F A U N A 121