Use of tree species by three species of Magicicada (Hemiptera: Cicadidae) in an Appalachian forest

doi:10.1007/s11676-023-01617-2

摘要/Abstract

Abstract:

Periodical cicadas (Magicicada spp.) are endemic to deciduous forests in the eastern United States. In successional forests, they must partition resources such as host trees to coexist. We measured tree size, emergence holes, oviposition scar bundles, and chorusing center abundances of Magicicada species on 12 common tree species in a deciduous forest to understand host-tree use. We predicted that the abundance of periodical cicadas and use of specific host-tree species would change depending on the Magicicada species and tree life stage. We considered the size of the tree (diameter at breast height) as a covariate to control for tree size and collected eggs for a greenhouse experiment to assess whether nymphs prefer to feed on Quercus rubra or Acer saccharum. More emergence holes were found below Quercus species than any other tree species. The abundance of periodical cicadas on host trees used for chorusing centers varied depending on the Magicicada species, but were most abundant on Quercus species. Oviposition scar bundles were also more frequent on Quercus. More nymphs were found on Quercus than Acer in the nymph preference study. Though periodical cicadas used Quercus hosts more than other tree species, their abundances on different host tree sizes and species differed significantly. Periodical cicada species may use specific host species and life stages as a way to partition resources and minimize competition among the Magicicada species during emergence years.

Key words: Ecological succession, Habitat partitioning, Periodical cicadas, Successional forests

Cindy Perkovich, David Ward. [J]. 林业研究(英文版), 2023, 34(6): 2051-2063.

Cindy Perkovich, David Ward. Use of tree species by three species of Magicicada (Hemiptera: Cicadidae) in an Appalachian forest[J]. JOURNAL OF FORESTRY RESEARCH, 2023, 34(6): 2051-2063.

参考文献 82

1	Abdelhady DH, Amer YM. On the inverse power Gompertz distribution. Ann Data Sci, 2021, 8: 451-473, DOI
2	Alexander RD, Moore TE. The evolutionary relationships of 17-year and 13-year cicadas, and three new species (Homoptera, Cicadidae, Magicicada). Ohio J Sci, 1958, 58: 107-127
3	Alexander R, Moore TE. The evolutionary relationships of 17-year and 13-year cicadas, and three new species (Homoptera, Cicadidae, Magicicada), 1962 Ann Arbor University of Michigan
4	Allen D, Dick CW, Strayer E, Perfecto I, Vandermeer J. Scale and strength of oak-mesophyte interactions in a transitional oak-hickory forest. Can J Forest Res, 2018, 48: 1366-1372, DOI
5	Andrews EA. Some work of the periodical cicada. J Wash Acad Sci, 1955, 45: 20-29
6	Angel P, Davis V, Burger J, Graves D, Zipper C. Adams MB. The Appalachian regional reforestation initiative. The forestry reclamation approach: guide to successful reforestation of mined lands, 2017 Newton Square USDA, Forest Service 1-4
7	Barton KE, Boege K. Future directions in the ontogeny of plant defence: understanding the evolutionary causes and consequences. Ecol Lett, 2017, 20: 403-411, DOI
8	Beasley DE, Penick CA, Boateng NS, Menninger HL, Dunn RR. Urbanization disrupts latitude-size rile in 17-year cicadas. Ecol Evol, 2017, 8: 2534-2541, DOI
9	Boeckler GA, Gershenzon J, Unsicker SB. Phenolic glycosides of the Salicaceae and their role as anti-herbivore defenses. Phytochemistry, 2011, 72: 1497-1509, DOI
10	Brown WP, Zuefle ME. Does the periodical cicada, Magicicada septendecim, prefer to oviposit on native or exotic plant species?. Ecol Entomol, 2009, 34: 346-355, DOI
11	Cassin J. Notes on the above species of cicada (M. cassini), and on the Cicada septendecim Linn. Proc Acad Nat Sci Phila, 1851, 5: 273-275
12	Chapman JI, McEwan RW. Thirty years of compositional change in an old-growth temperate forest: the role of topographic gradients in oak-maple dynamics. PLoS ONE, 2016, 11, DOI
13	Clay K, Shelton AL, Winkle C. Differential susceptibility of tree species to oviposition by periodical cicadas. Ecol Entomol, 2009, 34: 277-286, DOI
14	Cooley JR. The distribution of periodical cicada (Magicicada) Brood I in 2012 with previously unreported disjunct populations (Hemiptera: Cicadidae, Magicicada). Am Entomol, 2015, 61: 51-56, DOI
15	Cooley JR, Marshall DC. Sexual signaling in periodical cicadas, Magicicada spp. Behav, 2001, 138: 827-855, DOI
16	Cooley JR, Marshall DC, Simon C, Neckermann ML, Bunker G. At the limits: habitat suitability modeling of the northern 17-year periodical cicada extinctions (Hemiptera: Magicicada spp.). Glob Ecol Biogeogr, 2013, 22: 410-421, DOI
17	Cooley JR, Kritsky G, Edwards MJ, Zyla JD, Marshall DC, Hill KB, Bunker G, Neckermann M, Troutman R, Yoshimura J. Periodical cicadas ( Magicicada spp.): A GIS-based map of Broods XIV in 2008 and “XV” in 2009. Am Entomol, 2011, 57: 144-151, DOI
18	Cooley JR, Arguedas N, Bonaros E, Bunker G, Chiswell SM, DeGiovine A, Edwards M, Hassanieh D, Haji D, Know J, Kritsky G. The periodical cicada four-year hypothesis revisited and the polyphyletic nature of Brood V, including and updated crowd-source enhanced map (Hemiptera: Cicadidae: Magicicada). Peer J, 2018, 6, DOI
19	Donaldson JR, Stevens MT, Barnhill HR, Lindroth RL. Age-related shifts in leaf chemistry of clonal aspen (Populus tremuloides). J Chem Ecol, 2006, 32: 1415-1429, DOI
20	Dybas HS, Davis DD. A population census of seventeen-year periodical cicadas (Homoptera: Cicadidae: Magicicada). Ecology, 1962, 43: 432-444, DOI
21	Dybas HS, Lloyd M. Isolation by habitat in two synchronized species of periodical cicadas (Homoptera: Cicadidae: Magicicada). Ecology, 1962, 43: 444-459, DOI
22	Dybas HS, Lloyd M. The habitats of 17-year periodical cicadas (Homoptera: Cicadidae: Magiciada spp.). Ecol Monogr, 1974, 44: 79-324, DOI
23	Erbilgin N, Colgan LJ. Differential effects of plant ontogeny and damage type on phloem and foliage monoterpenes in jack pine (Pinus banksiana). Tree Physiol, 2012, 32: 946-957, DOI
24	Feeny P. Plant apparency and chemical defense. Rec Adv Phytochemistry, 1976, 10: 1-42
25	Fischer JC. On a new species of cicada. Proc Acad Nat Sci Phila, 1851, 5: 272-273
26	Flinn KM, Mahany TP, Hausman CE. From forest to city: plant community change in northeast Ohio from 1800 to 2014. J Veg Sci, 2018, 29: 297-306, DOI
27	Fulton MR. Patterns in height-diameter relationships for selected tree species and sites in eastern Texas. Can J Forest Res, 1999, 29: 1445-1448, DOI
28	Gossard HA. Distribution of the Ohio broods of periodical cicada with reference to soil. Ohio Agric Exp Sta Bull, 1917, 311: 551-577
29	Hartigan JA, Hartigan PM. The dip test of unimodality. Ann Stat, 1985, 13: 70-84, DOI
30	Hao ZQ, Zhang J, Song B, Ye J, Li BH. Vertical structure and spatial associations of dominant tree species in an old-growth temperate forest. Forest Ecol Manag, 2007, 252: 1-11, DOI
31	Hofmeister J, Mihaljevic M, Hosek J. The spread of ash (Fraxinus excelsior) in some European oak forests: an effect of nitrogen deposition or successional change?. Forest Ecol Manag, 2004, 203: 35-47, DOI
32	Holeski LL, Hillstrom ML, Whitham TG, Lindroth RL. Relative importance of genetic, ontogenetic, induction and seasonal variation in producing a multivariate defense phenotype in a foundation tree species. Oecologia, 2012, 170: 695-707, DOI
33	Howard LO. The seventeen-year locust or periodical cicada. Sci Am, 1911, 104: 524-525, DOI
34	Johnson PS. Oak overstory/reproduction relations in two xeric ecosystems in Michigan. Forest Ecol Manag, 1992, 48: 233-248, DOI
35	Karban R. Effects of local density on fecundity and mating speed of periodical cicadas. Oecologia, 1981, 51: 260-264, DOI
36	Karban R. Experimental removal of 17-year cicada nymphs and growth of host apple trees. J NY Entomol Soc, 1982, 90: 74-82
37	Karban R. Opposite density effects of nymphal and adult mortality for periodical cicadas. Ecology, 1984, 65: 1656-1661, DOI
38	Karban R. Transient habitats limit developmental time for periodical cicadas. Ecology, 2014, 95: 3-8, DOI
39	Koenig WD, Leibhold AM. Regional impacts of periodical cicadas on oak radial increment. Can J Forest Res, 2003, 33: 1084-1089, DOI
40	Kritsky G. Periodical cicadas: the plague and the puzzle, 2004 Indianapolis Indiana Academy of Science
41	Lines ER, Coomes DA, Purves DW. Influence of forest structure, climate and species composition on tree mortality across the eastern US. PLoS ONE, 2010, 5, DOI
42	Liu GJ, Wang JL, Dong PL, Chen Y, Liu ZY. Estimating individual tree height and diameter at breast height (DBH) from terrestrial laser scanning (TLS) data at plot level. Forests, 2018, 9: 398, DOI
43	Lloyd M. Periodical cicadas. Antenna, 1984, 8: 79-91
44	Lloyd M, White J. On the oviposition habits of 13-year vs 17-year periodical cicadas of the same species. J NY Entomol Soc, 1976, 84: 148-155
45	Lloyd M, White J. On reconciling patch microspatial distributions with competition models. Am Nat, 1980, 115: 29-44, DOI
46	Lloyd M, White J. Why is one of the periodical cicadas (Magicicada septendecula) a comparatively rare species?. Ecol Entomol, 1983, 8: 293-303, DOI
47	Maechler M (2015) Package ‘diptest’. http://cran.r-project.org/web/package/diptest/index.html
48	Marlatt CL. The periodical cicada. USDA Bureau Entomol Bull, 1907, 71: 1-181
49	Marshall DC, Cooley JR. Reproductive character displacement and speciation in periodical cicadas, with description of a new species, 13-year Magicicada neotredecim. Evolution, 2000, 54: 1313-1325
50	McCarthy BC, Small CJ, Rubino DI. Composition, structure, and dynamics of Dysart Woods, and old-growth mixed mesophytic forest of southeastern Ohio. Forest Ecol Manag, 2001, 140: 193-213, DOI
51	McEwan R, Muller RN. Spatial and temporal dynamics in canopy dominance of an old-growth central Appalachian forest. Can J Forest Res, 2006, 36: 1536-1550, DOI
52	Moriyama M, Numata H. Urban soil compaction reduces cicada diversity. Zool Lett, 2015, 1: 19, DOI
53	Moriyama M, Numata H. Ecophysiological responses to climate change in cicadas. Physiol Entomol, 2019, 44: 65-76, DOI
54	Moser WK, Butler-Leopold P, Hausman C, Iverson L, Ontl T, Brand L, Matthews S, Peters M, Prasad A. Stanturf JA. The impact of climate change on forest systems in the northern United States: Projections and implications for forest management. Achieving sustainable management of boreal and temperate forests, 2020 Cambridge Burleigh and Dodds Science Publishing 239-290
55	Oberdörster U, Grant PR. Predator foolhardiness and morphological evolution in 17-year cicadas (Magicicada spp.). Biol J Linn Soc, 2007, 90: 1-13, DOI
56	Ochoa-Lopez S, Damian X, Rebollo R, Fornoni J, Dominguez CA, Boege K (2020) Ontogenetic changes in the targets of natural selection in three plant defenses. New Phytol 226:1480–1491.
57	Oladi J. Developing diameter at breast height (DBH) and a height estimation model from remotely sensed data. J Agric Sci Technol, 2005, 7: 95-102
58	Perkovich C, Ward D. Aboveground herbivory causes belowground changes in twelve oak Quercus species: a phylogenetic analysis of root biomass and non-structural carbohydrate storage. Oikos, 2021, 130: 1797-1812, DOI
59	Perkovich C, Ward D. Herbivore-induced defenses are not under phylogenetic constraints in the genus Quercus (oak): phylogenetic patterns of growth, defense, and storage. Ecol Evol, 2021, 11: 5187-5203, DOI
60	Perkovich C, Ward D. Changes in white oak (Quercus alba) phytochemistry in response to periodical cicadas: before, during, and after an emergence. Ecol Evol, 2022, 12, DOI
61	Radcliffe DC, Hix DM, Matthews SN. Predispoing factors’ effects on mortality of oak (Quercus) and hickory (Carya) species in mature forests undergoing mesophication in Appalachian Ohio. For Ecosyst, 2021, 8: 1-14, DOI
62	R Core Team (2019) R: a language and environment for statistical computing, version 3.6.0. Foundation for Statistical Computing, Vienna, Austria
63	Robinson GR Jr, Sibrell PL, Boughton CJ, Yang LH. Influence of soil chemistry on metal and bioessential element concentrations in nymphal and adult periodical cicadas (Magicicada spp.). Sci Tot Environ, 2007, 374: 367-378, DOI
64	Sadaka N, Ponge JF. Climatic effects on soil trophic networks and the resulting humus profiles in holm oak (Quercus rotundifolia) forests in the high Atlas of Morocco as revealed by correspondence analysis. Eur J Soil Biol, 2003, 54: 767-777
65	Salas C, LeMay V, Nunez P, Pacheco P, Espinosa A. Spatial patterns in an old-growth Nothofagus obliqua forest in south-central Chile. Forest Ecol Manag, 2006, 231: 38-46, DOI
66	Sanborn AF, Heath JE, Heath MS, Phillips PK. Temperature responses and habitat selection by mangrove cicadas in Florida and Queensland (Hemiptera: Cicadidae). Trop Zool, 2004, 17: 65-72, DOI
67	Setälä H, Szlavecz K, Pullen JD, Parker JD, Huang Y, Chang CH. Acute resource pulses from periodical cicadas propagate belowground food webs but do not affect tree performance. Ecology, 2022, 103, DOI
68	Shi PJ, Ratkowsky DA, Wang N, Li Y, Zhao L, Reddy GVP, Li BL. Comparison of five methods for parameter estimation under Taylor’s power law. Ecol Complex, 2017, 32: 121-130, DOI
69	Simon C, Cooley JR, Karban R, Sota T. Advances in the evolution and ecology of 13- and 17-year periodical cicadas. Annu Rev Entomol, 2022, 67: 457-482, DOI
70	Toji T, Ishmoto I, Itino T. Seasonal change of flower sex ratio and pollinator dynamics in three reproductive ecotypes of protandrous plant. Ecosphere, 2020, 11, DOI
71	Tuttle JP (2019) Disturbance, fine-scale environment, and forest change in Great Smokey Mountains National Park. Ph.D. dissertation, Department of Biology, University of North Carolina, Chapel Hill
72	Voitsekhovskaja OV, Tyutereva EV. Chlorophyll b in angiosperms: functions in photosynthesis, signaling and ontogenetic regulation. J Plant Physiol, 2015, 189: 51-64, DOI
73	Walsh BD, Riley CV. The periodical cicada. Am Entomol, 1868, 1: 63-72
74	Weiner J. Allocation, plasticity and allometry in plants. Perspect Plant Ecol Evol, 2004, 6: 207-215, DOI
76	White J. Resource partitioning by ovipositing cicadas. Am Nat, 1980, 115: 1-28, DOI
75	White JA. Flagging: hosts defences versus oviposition strategies in perdiocal cicadas (Magicicada spp. Cicadidae, Homoptera). Can Entomol, 1981, 113: 727-738, DOI
77	White PS, Strehl CE. Xylem feeding by periodical cicada nymphs on tree roots. Ecol Entomol, 1978, 3: 323-327, DOI
78	White PS, Tuttle JP, Collins BS. Barton AM, Keeton WS. Old-growth forests in southern Appalachians: dynamics and conservation framework. Ecology and recovery of eastern old-growth forests, 2018 Washington, DC Island Press 63-82, DOI
79	Williams KS, Simon C. The ecology, behavior, and evolution of periodical cicadas. Annu Rev Entomol, 1995, 40: 269-295, DOI
80	Yang LH. Periodical cicadas use light for oviposition site selection. Proc Roy Soc Biol Sci B, 2006, 273: 2993-3000
81	Yang LH, Karban R. The effects of pulsed fertilization and chronic herbivory by periodical cicadas on tree growth. Ecology, 2019, 100, DOI
82	Zwet TVD, Brown EW, Estabrook P. Effect of periodical cicada injury and degree of fire severity on Asian pear cultivars. Fruit Var J, 1997, 51: 35-39