Magicicada is the genus of the 13-year and 17-year periodical cicadas of eastern North America. Although they are sometimes called "locusts", this is a misnomer as cicadas belong to the taxonomic order Hemiptera, suborder Homoptera, while locusts belong to Orthoptera.
Magicicada spp. spend most of their 13- and 17-year lives underground feeding on xylem fluids from the roots of deciduous forest trees in the eastern United States. After 13 or 17 years, mature cicada nymphs emerge at any given locality, synchronously and in tremendous numbers. After such a prolonged developmental phase, the adults are active for about 4 to 6 weeks. The males aggregate into chorus centers and attract mates. Within two months of the original emergence, the life cycle is complete, the eggs have been laid and the adult cicadas are gone for another 13 or 17 years.
Description[edit source | edit]
The familiar winged imago (adult) periodical cicada has red eyes and a black dorsal thorax. The wings are translucent and have orange veins. The underside of the abdomen may be black, orange, or striped with orange and black, depending on the species.
Adults are typically 2.4 to 3.3 cm (0.9 to 1.3 in), depending on species, slightly smaller than the annual cicada species found in the same regions of the United States. Mature females are slightly larger than males.
Magicicada males typically form large aggregations that sing in chorus to attract receptive females. Different species have different characteristic calling songs. The call of decim periodical cicadas is said to resemble someone calling "weeeee-whoa" or "Pharaoh." The cassini and decula periodic cicadas have songs that intersperse buzzing and ticking sounds.
Cicadas do not bite or sting. Like other Homoptera, they have mouthparts used in piercing plants and sucking their sap. A cicada's proboscis can also pierce human skin when it is handled, which is painful but in no other way harmful. These cicadas are not venomous, and there is no evidence that they transmit diseases. They pose little threat to mature vegetation, although planting new trees or shrubs is best postponed until after an expected emergence of the periodical cicadas. Mature plants rarely suffer lasting damage, although twig die-off or flagging can result from egg-laying.
Life cycle[edit source | edit]
Nearly all cicadas spend years underground as juveniles, before emerging above ground for a short adult stage of several weeks to a few months. The seven periodical cicada species are so named because, in any one location, all of the members of the population are developmentally synchronized—they emerge as adults all at once in the same year. This periodicity is especially remarkable because their life cycles are so long—13 or 17 years. Cicadas of all other species (perhaps 3000 worldwide) are not synchronized, so some adults mature each summer and emerge while the rest of the population continues to develop underground. Many people refer to these non-periodical species as annual cicadas since some are seen every summer. The life cycles of most annual species range from two to ten years, although some could be longer.
The nymphs of the periodical cicadas live underground, often at depths of 30 cm (1 ft) or more, feeding on the juices of plant roots. The nymphs of the periodical cicada undergo 5 instar stages in their development underground. The difference in the 13 and 17 year life cycle is the time it takes for the second instar to mature. While underground, the nymphs move deeper below ground feeding on larger roots.
The nymphs emerge on a spring evening when the soil temperature at about 20 cm (8 in) depth is above 17 °C (63 °F). In most years, this works out to late April or early May in far southern states, and late May to early June in the far northern states. Emerging nymphs climb to a suitable place on the nearby vegetation to complete their transformation into an adult cicada. They molt one last time and then spend about six days in the leaves waiting for their exoskeleton to harden completely. Just after this final molt, the teneral adults are white, but darken within an hour.
Adult periodical cicadas live only for a few weeks—by mid-July, all have disappeared. Their short adult life has one purpose: reproduction. The males "sing" a species-specific mating song; like other cicadas, they produce loud sounds using their tymbals. Singing males of a single Magicicada species form aggregations (choruses) that are sexually attractive to females. Males in these choruses alternate bouts of singing with short flights from tree to tree in search of receptive females. Most matings occur in "chorus" trees.
Receptive females respond to the calls of conspecific males with timed wing-flicks, which attract the males for mating. The sounds of a "chorus"—a group of males—can be deafening and reach 100 dB. In addition to their "calling" or "congregating" song, males produce a distinctive courtship song when approaching an individual female.
Both males and females can mate multiple times, although most females seem to mate just once. After mating, the female cuts V-shaped slits in the bark of young twigs and lays approximately 20 eggs in each, for a total of 600 or more eggs. After about six to ten weeks, the eggs hatch and the newborn nymphs drop to the ground, where they burrow and begin another 13 or 17-year cycle.
Predator satiation survival strategy[edit source | edit]
The nymphs emerge in large numbers at about the same time, sometimes more than 1.5 million individuals per acre (>370/m²). Their mass-emergence is a survival trait called predator satiation: for the first week after emergence, the periodic cicadas are an easy prey for reptiles, birds, squirrels, cats, and other small and large mammals. Early ideas maintained that the cicadas' overall survival mechanism was simply to overwhelm predators by their sheer numbers, ensuring the survival of most of the individuals. It was hypothesized that the emergence period of large prime numbers (13 and 17 years) was a predatory avoidance strategy adopted to eliminate the possibility of potential predators receiving periodic population boosts by synchronizing their own generations to divisors of the cicada emergence period. A more parsimonious viewpoint holds that the prime numbered developmental times represent an adaptation to prevent hybridization between broods with different cycles during a period of heavy selection pressure brought on by isolated and lowered populations during Pleistocene glacial stadia, and that predator satiation is a short term maintenance strategy. This hypothesis was subsequently supported through a series of mathematical models, and stands as the most widely accepted explanation of the unusually lengthy and mathematically precise immature period of these insects. The length of the cycle appears to be controlled by a single gene locus, with the 13-year cycle dominant to the 17-year one.
Impact on other populations[edit source | edit]
Cycles in cicada populations are significant enough to affect other animal and plant populations. For example, tree growth has been observed to decline the year before the emergence of a brood, because of the increased feeding on roots by nymphs. Moles, which feed on nymphs, have been observed to do well during the year before an emergence, but suffer population declines the following year, because of the reduced food source. Wild turkey populations respond favorably to increased nutrition in their food supply from gorging on cicada adults on the ground at the end of their life cycle. Uneaten carcasses of periodic cicadas decompose on the ground, providing a resource pulse of nutrients to the forest community.
Broods[edit source | edit]
Periodical cicadas are grouped into broods based on the calendar year when they emerge.
In 1907, entomologist C. L. Marlatt assigned Roman numerals to 30 different broods of periodical cicadas: 17 distinct broods with a 17-year life cycle, to which he assigned brood numbers I through XVII (with emerging years 1893 through 1909); plus 13 broods with a 13-year cycle, to which he assigned brood numbers XVIII through XXX (1893 through 1905).
Many of these hypothetical 30 broods, however, have not been observed. Furthermore, two of the brood numbers assigned by Marlatt (Broods XI and XXI) existed at one time, but have become extinct. The Marlatt numbering scheme has been retained for convenience, although today only 15 broods survive.
|Name||Nickname||Cycle (yrs)||Last emergence||Next emergence||Extent|
|Brood I||Blue Ridge Brood||17||2012||2029||Western VA, WV|
|Brood II||East Coast Brood||17||2013||2030||CT, MD, NC, NJ, NY, PA, DE, VA, DC|
|Brood III||Iowan Brood||17||1997||2014||IA|
|Brood IV||Kansan Brood||17||1998||2015||KS, MO, OK|
|Brood V||17||1999||2016||Northeast OH, MD, PA, VA, WV|
|Brood VI||17||2000||2017||GA, NC, SC|
|Brood VII||Onondaga Brood||17||2001||2018||Upstate NY[Note 1]|
|Brood VIII||17||2002||2019||OH, PA, WV|
|Brood IX||17||2003||2020||Western VA, WV, NC|
|Brood X||Great Eastern Brood||17||2004||2021||From NY to NC along the East Coast, inland to IL and MI[Note 2]|
|Brood XI||17||Extinct||Last seen in 1954 in Ashford, CT along Fenton River|
|Brood XIII||Northern Illinois Brood||17||2007||2024||Northern IL and in parts of IA, WI, and IN[Note 3]|
|Brood XIV||17||2008||2025||Southern OH, KY, TN, MA, MD, NC, PA, northern GA, Western VA and WV, and parts of NY and NJ[Note 3]|
|Brood XIX||Great Southern Brood||13||2011||2024||AL, AR, GA, IN, IL, KY, LA, MD, MO, MS, NC, OK, SC, TN, and VA[Note 4]|
|Brood XXI||Floridian Brood||13||(2000)||Extinct||Last recorded in 1870. Historical range included the FL panhandle|
|Brood XXII||Baton Rouge Brood||13||2001||2014||LA, MS[Note 5]|
|Brood XXIII||Lower Mississippi River Valley Brood||13||2002||2015||IA, IL, IN, WI|
Taxonomy[edit source | edit]
There are seven recognized species within Magicicada. Three of them follow a 17-year cycle:
- M. septendecim (Linnaeus, 1758)
- M. septencassini (Fisher, 1851) (also called M. cassini)
- M. septendecula Alexander & Moore, 1962
Four more species follow a 13-year cycle:
- M. neotredecim Marshall & Cooley, 2000
- M. tredecim (Walsh & Riley, 1868)
- M. tredecassini Alexander & Moore, 1962
- M. tredecula Alexander & Moore, 1962
These seven species are also sometimes grouped differently into three subgroups, the so-called "-decim species," "-cassini species," and "-decula species," reflecting strong similarities of each 17-year species with one or more species with a 13-year cycle.
Generally, the 17-year cicadas are distributed more in the northern states of the eastern United States, while the 13-year cicadas occur in the southern states, but some may overlap, for example, brood IV (17 year cycle) and XIX (13 year cycle) in western Missouri. If this distribution holds, their emergence will coincide in—2219, 2440, 2661, etc., as it did in 1998 (although distributions change slightly from year to year and distribution maps can be unreliable, especially older maps.).
Evolution[edit source | edit]
Not only are the periodical cicada life cycles curious for their prime numbers—13 or 17—their evolution is intricately tied to one- and four-year changes in their life cycle. One-year changes are less common than four-year changes and are probably tied to variation in local climatic conditions. Four-year early and late emergences are common and involve a much larger proportion of the population than one-year changes.
Recent research suggest that different species with identical life cycles developed their overlapping geographic distribution by synchronization of life cycle to existing dominant populations.
Uses to humans[edit source | edit]
As food[edit source | edit]
An entomologist wrote in 1898 that "The use of the newly emerged and succulent cicadas as an article of human diet has merely a theoretical interest, because, if for no other reason, they occur too rarely to have any real value. There is also the much stronger objection in the instinctive repugnance which all insects seem to inspire as an article of food to most civilized nations. Theoretically, the Cicada, collected at the proper time and suitably dressed and served, should be a rather attractive food. The larvae have lived solely on vegetable matter of the cleanest and most whole-some sort, and supposedly, therefore, would be much more palatable and suitable for food than the oyster, with its scavenger habit of living in the muddy ooze of river bottoms, or many other animals which are highly prized and which have not half so clean a record as the periodical Cicada." Eating insects globally is quite common. Over 1400 species are consumed regularly and is known as entomophagy.
Medical uses[edit source | edit]
Cicadas are used in alternative medicine and traditional Chinese medicine (TCM). Though the insect itself is not of much importance in traditional Chinese medicine the molted skins of the Cicadas are of greater value, and have been used to treat rheumatoid arthritis as well as other diseases. Traditionally, the skin is mixed with herbs and boiled into a tea which the patient consumes or applies to affected area.
References[edit source | edit]
- Maxine Shoemaker Heath (1978). Genera of American cicadas north of Mexico (Ph.D. thesis). University of Florida. doi:10.5962/bhl.title.42291.
- "Periodical Cicada". University of Michigan.
- Lloyd, M., and H.S. Dybas (1966). "The periodical cicada problem. I. Population ecology". Evolution 20 (2): 133–149. doi:10.2307/2406568. JSTOR 2406568.
- Williams, K.S., and C. Simon (1995). "The ecology, behavior, and evolution of periodical cicadas" (PDF). Annual Review of Entomology 40: 269–295. doi:10.1146/annurev.en.40.010195.001413.
- Alexander, Richard D; Thomas E. Moore (1962). "The Evolutionary Relationships of 17-Year and 13-Year Cicadas, and Three New Species (Homoptera, Cicadidae, Magicicada)". U Michigan Museum of Zoology. Retrieved 9 June 2011.
- Capinera, John L. (2008). Encyclopedia of Entomology. Springer. pp. 2785–2794. ISBN 1-4020-6242-7.
- Stranahan, Nancy. "Nature Notes from the Eastern Forest". Arc of Appalachia. Retrieved 10 June 2011.
- Cook, William M.; Robert D. Holt (2002). "Periodical cicada (Magicicada cassini) oviposition damage: visually impressive yet dynamically irrelevant". American Midland Naturalist 147 (2): 214–224. doi:10.1674/0003-0031(2002)147[0214:PCMCOD]2.0.CO;2.
- Marlatt, C. F. (1907). "The periodical cicada". Bulletin of the USDA Bureau of Entomology 71 (1): 1–181.
- White, J, and M. Lloyd. 1979. Seventeen year cicadas emerging after eighteen years-a new brood? Evolution 33:1193-1199.
- "Magicicada Brood XIX is emerging now". National Geographic Society. Retrieved 13 June 2011.
- Dybas, H. S.; Davis, D. D. (1962). "A populations census of seventeen-year periodical cicadas (Homoptera: Cicadidae: Magicicada)". Ecology 43 (3): 432–444. doi:10.2307/1933372. JSTOR 1933372.
- Williams, K. S.; Smith, K. G.; Stephen, F. M. (1993). "Emergence of 13-year periodical cicadas (Cicadidae, Magicicada): phenology, mortality, and predator satiation". Ecology 74 (4): 1143–1152. doi:10.2307/1940484. JSTOR 1940484.
- Goles, E.; Schulz, O.; Markus, M. (2001). "Prime number selection of cycles in a predator-prey model". Complexity 6 (4): 33–38. doi:10.1002/cplx.1040.
- Cox, R. T., and C. E. Carlton (1988). "Paleoclimatic influences in the evolution of periodical cicadas (Homoptera: Cicadidae: Magicicada spp.)". American Midland Naturalist 120 (1): 183–193. doi:10.2307/2425898. JSTOR 2425898.
- Tanaka, Y, J. Yoshimura, C. Simon, J. Cooley, and K. Tainaka (2009). "Allee effect in the selection for prime-numbered cycles in periodical cicadas". Proceedings of the National Academy of Sciences 106 (22): 8975–8979. Bibcode:2009PNAS..106.8975T. doi:10.1073/pnas.0900215106. PMC 2690011. PMID 19451640.
- Cox, R. T., and C. E. Carlton (1991). "Evidence of genetic dominance of the 13-year life cycle in periodical cicadas (Homoptera: Cicadidae: Magicicada spp.)". American Midland Naturalist 125 (1): 63–74. doi:10.2307/2426370. JSTOR 2426370.
- Yang, Louie H. (2004). "Periodical cicadas as resource pulses in North American forests". Science 306 (5701): 1565–1567. Bibcode:2004Sci...306.1565Y. doi:10.1126/science.1103114. PMID 15567865.
- National Geographic: Cicada Outbreaks Linked to Other Animals' Booms, Busts.
- Marlatt, C. L. (1907). The Periodical Cicada. USDA. p. 28.
- Post, Susan L. (2004). "A Trill of a Lifetime". The Illinois Steward. Retrieved 9 June 2011.
- "Swarms of cicadas emerging in Midwest". Associated Press. 20 May 2007.
- "Brood XXII (13-year) The Baton Rouge Brood". National Geographic Society. Retrieved 28 August 2011.
- "Magicicada species". National Geographic Society. Retrieved 12 June 2011.
- Compare brood IV distribution with [ brood XIX distribution]. From University of Michigan, Zoology, Insect division 
- See figure 1, p. 107, Cooley et al. The distribution of periodical cicadas. American Entymologist, 55:2, 106-112.
- Lifecycles Of Cicada Species Are Focus Of Biologist's Research, The UConn Advance, 4/26/2004, Elizabeth Omara-Otunnu
- Teiji Sota, Satoshi Yamamoto, John R. Cooley, Kathy B. R. Hill, Chris Simon, Jin Yoshimura (2013). "Independent divergence of 13- and 17-y life cycles among three periodical cicada lineages". Proceedings of the National Academy of Sciences of the United States of America 110 (2). Bibcode:2013PNAS..110.6919S. doi:10.1073/pnas.1220060110. Retrieved 22 March 2013.