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	{{Histmerge\|Draft:Chrysochus auratus (Dogbane Beetle)\|reason=draft duplicative of this article and due to be G13'd; plenty of good material in there which I have now integrated here.}}
	{{short description\|Species of beetle}}		{{short description\|Species of beetle}}
	{{Speciesbox		{{Speciesbox
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	\| synonyms = ''Chrysomela aurata'' <small>], 1775</small>		\| synonyms = ''Chrysomela aurata'' <small>], 1775</small>
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			'''''Chrysochus auratus''''', more commonly known as the '''dogbane beetle''', is a ] primarily found in the ]. The beetle is approximately 8 to 11 mm in length, and possesses an oblong and convex shape. This beetle has two pairs of wings, one of which is a pair of copper colored ]. The beetle is typically found to have a blue-green hue, and its color is often used to ward away potential ].

			A major aspect of this beetles' day to day life is ], as the beetles typically live a highly ] lifestyle.<ref name=":3">Peterson, Merrill; Honchak, Barbara; Locke, Steranie; Beeman, Timothy; Mendoza, Jessica; Green, Jabin; Buckingham, Kati (May 2007). "Relative Abundance and the Species-Specific Reinforcement of Male Mating in the Chrysochus (Coleoptera: Chrysomelidae) Hybrid Zone". Evolution. 59 (12). doi:10.1111/j.0014-3820.2005.tb00976.x. S2CID 25481151.</ref> This beetle has also been found to participate in ] with '']'' in certain geographic regions, resulting in hybrid offspring. Its diet consists primarily of ] (''Apocynum),'' specifically '']'' and ''].''<ref name=":1">{{cite journal \|last1=Peterson \|first1=M. A. \|last2=Dobler \|first2=S. \|last3=Holland \|first3=J. \|last4=T. \|first4=L. \|last5=Locke \|first5=S. \|year=2001 \|title=Behavioral, Molecular, and Morphological Evidence for a Hybrid Zone Between ''Chrysochus auratus'' and ''C. cobaltinus'' (Coleoptera: Chrysomelidae) \|url=https://academic.oup.com/aesa/article-pdf/94/1/1/26912651/aesa94-0001.pdf \|journal=] \|volume=94 \|issue=1 \|pages=1–10 \|doi=10.1603/0013-8746(2001)0942.0.CO;2 \|doi-access=free}}</ref> ''C. auratus'' has developed several different adaptations that allow it to eat dogbane, such as its ability to process the toxins in dogbane leaves. Due to its diet of exclusively dogbane, ''C. auratus'' has been considered as a potential mechanism of biological control for agricultural purposes.
	'''''Chrysochus auratus''''', the '''dogbane beetle''',<ref>{{cite web\|last=Bartlett\|first=Troy\|website=BugGuide\|title=Species ''Chrysochus auratus'' - Dogbane Beetle\|url=https://bugguide.net/node/view/461\|date=13 May 2017\|access-date=3 December 2019}}</ref> of eastern ], is a member of the ] subfamily ]. It is primarily found east of the ]. Its diet mainly consists of dogbane ('']''), specifically '']'' and '']'', and occasionally it eats ]. It measures between 8 and 11 mm and has a convex, ] shape.

	== ~~Description~~ ==		== Geographic range ==
			''Chrysochus auratus'' is generally found in eastern North America, spanning the entire eastern United States and into adjacent ] west of the ]. At the western edge of its range, it extends west of the ] into ] and ]. The related species ''Chrysochus cobaltinus'', in contrast, is found exclusively in ]<nowiki/>he two species were historically considered to have ] distributions. Recently, at least two narrow regions in western North America have been documented where both ''C. auratus'' and ''C. cobaltinus'' occur and apparently interbreed.<ref name=":1" />
	The species is an iridescent blue-green with a metallic copper, golden or crimson shine. Dogbane beetles range from 8 to 11 mm in size, and they are oblong and convex shaped. The head contains two antennae that are widely set apart and located between the beetle's eyes. They are twelve-jointed with eleven segments, and the basal segment is shorter than that of the second segment.<ref name=":5">{{Cite journal\|last=Wilson\|first=Sloan Jacob\|date=1934\|title=The Anatomy of Chrysochus auratus, Fab., Coleoptera: (Chrysomelidae) with an Extended Discussion of the Wing Venation\|journal=Journal of the New York Entomological Society\|volume=42\|issue=1\|pages=65–85\|jstor=25004541\|issn=0028-7199}}</ref>

	== ~~Distribution~~ ~~and habitat~~ ==		== Food resources ==
			Beetles of the ''Chrysochus'' genus typically feed on dogbane plants (Apocynaceae) and ] (Asclepiadaceae). It has been found that ''C. auratus'' exclusively feeds on dogbane plants. More specifically, ''C. auratus'' feeds on the ''Apocynum cannabinum'' and ''Apocynum androsaemifolium'' dogbane varieties. ] of the dogbane beetle will typically feed on the roots of the plants while adults will feed on the leaves of the plants.<ref>MacEachern-Balodis, M.C., Boyd, N.S., White, S.N. et al. Examination of dogbane beetle (Chrysochus auratus) feeding and phenology on spreading dogbane, and considerations for biological control. Arthropod-Plant Interactions 11, 807–814 (2017). https://doi.org/10.1007/s11829-017-9535-3</ref> Plants in the ''Apocynum'' genus release toxins, called ]s, as a defense mechanism to predators. When ingested, it can be fatal for numerous organisms, including humans as consumption can result in ]. Because ''C. auratus'' feed exclusively on ''Apocynum cannabinum'' and ''Apocynum androsaemifolium''; they have developed behavioral and physiological adaptations to overcome these plant's defenses.
	]
	Because the Dogbane's main source of food is ] leaves, they live in areas where this plant is abundant. This includes fields, forests, railroads etc. In turn, Dogbane beetles are also in these areas. However, the beetle cannot withstand all of the varied habitats like that of the Dogbane plant, so instead they are in places that are temperate and terrestrial while also containing the Dogbane plant. Dogbane beetles will live on the plant that they are eating. If the beetle depletes that resource, it may also move to another plant for both food and shelter.<ref name=":2">{{Cite web\|url=https://animaldiversity.org/accounts/Chrysochus_auratus/\|title=Chrysochus auratus\|last=Tolchin\|first=Jaclyn\|website=Animal Diversity Web\|language=en\|access-date=2020-03-03}}</ref>

			Cardenolides have the ability to bind to and block the function of ], which is a transmembrane carrier present in almost all animals and tissues. It controls the balance of cell potentials and is vital to the ]. When poisoned, these systems are detrimentally affected. Therefore, this type of beetle has adapted mechanisms to reduce the effects cardenolides has on Na<sup>+</sup>/K<sup>+</sup> - ATPase in ''C. auratus''. More specifically, ''Chrysochus auratus'' has a single amino acid substitution in its Na<sup>+</sup>/K<sup>+</sup> - ATPase that allows it to achieve this. The beetle is not only adapted to processing toxic cardenolide, but can also able to accumulate this compound in its own body to deter future predators. Cardenolide is shuttled through the beetle's body into cuticular glands, some of which are located in the elytra or wings. When the beetle senses some form of disturbance that requires a ], the beetle will secrete the cardenolides, poisoning its enemies.<ref>Estelle Labeyrie, Susanne Dobler, Molecular Adaptation of Chrysochus Leaf Beetles to Toxic Compounds in Their Food Plants, Molecular Biology and Evolution, Volume 21, Issue 2, February 2004, Pages 218–221, https://doi.org/10.1093/molbev/msg240
	At least two regions of ] between ''C. auratus'' and '']'' have been documented in western North America.<ref>{{cite journal\|first1=M. A.\|last1=Peterson\|first2=S.\|last2=Dobler\|first3=J.\|last3=Holland\|first4=L.\|last4=T.\|first5=S.\|last5=Locke\|year=2001\|title=Behavioral, Molecular, and Morphological Evidence for a Hybrid Zone Between ''Chrysochus auratus'' and ''C. cobaltinus'' (Coleoptera: Chrysomelidae)\|url=https://academic.oup.com/aesa/article-pdf/94/1/1/26912651/aesa94-0001.pdf\|journal=]\|volume=94\|issue=1\|pages=1–10\|doi=10.1603/0013-8746(2001)0942.0.CO;2\|doi-access=free}}</ref>
			</ref> This mutation may explain the dogbane beetle's insensitivity to the poisonous compounds, especially because this same mutation has been shown in the cardenolide-insensitive ].<ref>{{Cite journal \|last1=Karageorgi \|first1=Marianthi \|last2=Groen \|first2=Simon C. \|last3=Sumbul \|first3=Fidan \|last4=Pelaez \|first4=Julianne N. \|last5=Verster \|first5=Kirsten I. \|last6=Aguilar \|first6=Jessica M. \|last7=Hastings \|first7=Amy P. \|last8=Bernstein \|first8=Susan L. \|last9=Matsunaga \|first9=Teruyuki \|last10=Astourian \|first10=Michael \|last11=Guerra \|first11=Geno \|date=2019-10-17 \|title=Genome editing retraces the evolution of toxin resistance in the monarch butterfly \|journal=Nature \|language=en \|volume=574 \|issue=7778 \|pages=409–412 \|doi=10.1038/s41586-019-1610-8 \|issn=0028-0836 \|pmc=7039281 \|pmid=31578524}}</ref>

			These beetles have also evolved to develop a behavioral mechanism that allows for feeding on the ''Apocynum'' genus. As a defense mechanism to predators, ''Apocynum cannabinum'' and ''Apocynum androsaemifolium'' (dogbane) produce a toxic sticky white ] when its stems and leaves are broken. When feeding, ''C. auratus'' beetles feed on the margins of ''A. cannabinum'' and ''A. androsaemifolium'' leaves. The beetle will chew a five-to-seven-millimeter channel that sits diagonal from the leaf margin and points in the direction of the ]. Because this channel transects the major veins of the leaf, these initial cuts will exude a large amount of latex the leaf releases as its defensive mechanism. Distal to this initial cut location is the presence of low-latex tissue, which the beetle exclusively feeds on, biting on it in a downward motion. The feeding process typically lasts around one minute, and the beetle will straddle the leaf margins while feeding. As the beetles feed, latex accumulates on the ] segments of their mouth due to the repetitive downward motion made by their head. Therefore, after feeding has ceased, the beetles will move from the margins of the leaf to the interior portion of the leaf. The beetle will then press its mouth to the surface of the leaf and drag its mouth on the leaf while walking backwards. This method removes the latex buildup from the beetle's mouth region. Evidence of this behavior can be seen on leaves that have been fed on by ''C. auratus'', demonstrated by the rings of dried latex that can be found near the site of feeding.<ref>Williams, Charles. (1991). Host plant latex and the feeding behavior of Chrysochus auratus (Coleoptera: Chrysomelidae). The Coleopterists Bulletin. 45. 195-196.
⚫	== ~~Diet~~ ==
			</ref>
	Dogbane beetles feed on plants in the '']'' genus. Plants in this genus contain toxins (]) that, when ingested, are fatal to many organisms, including humans, causing cardiac arrest.<ref name=":8">{{Cite journal\|last=Labeyrie\|first=Estelle\|last2=Dobler\|first2=Susanne\|date=February 2004\|title=Molecular Adaptation of Chrysochus Leaf Beetles to Toxic Compounds in Their Food Plants\|url=https://academic.oup.com/mbe/article/21/2/218/1187788\|journal=Molecular Biology and Evolution\|volume=21\|issue=2\|pages=218–221\|doi=10.1093/molbev/msg240\|pmid=12949136\|via=Oxford Academic}}</ref> However, the Dogbane beetle is able to consume the plant and compartmentalize the cardenolides into glands. If threatened, the beetle can secrete the cardenolides as a defense mechanism.<ref name=":7">{{Cite web\|url=http://bugoftheweek.com/blog/2016/7/18/one-gorgeous-beetle-dogbane-leaf-beetle-ichrysochus-auratusi\|title=One gorgeous beetle: Dogbane leaf beetle, Chrysochus auratus\|website=Bug of the Week\|language=en-US\|access-date=2020-03-03}}</ref> It is believed that they are able to consume this plant without being poisoned because of their amino acid sequence. At position 122 of their amino acid sequence, ''Chrysochus auratus'' have a histidine, whereas their counterpart species who have an asparagine in this position are poisoned by it.<ref name=":8" />

	==~~Reproduction~~==		== Parental care ==
			No ] has been reported, except the ] that the mother surrounds her ]s with when attaching them to the underside of the dogbane leaf.
	Reproduction between adult male and female dogbane beetles usually occurs everyday, about once each day. In this species, males are the picky of the two, and they will search for the most fit females to mate with. The way in which a male chooses which female is the most fit is via chemical signaling systems.<ref>{{Cite journal\|last=Peterson\|first=Merrill\|last2=Honchak\|first2=Barbara\|last3=Locke\|first3=Steranie\|last4=Beeman\|first4=Timothy\|last5=Mendoza\|first5=Jessica\|last6=Green\|first6=Jabin\|last7=Buckingham\|first7=Kati\|date=May 2007\|title=Relative Abundance and the Species-Specific Reinforcement of Male Mating in the Chrysochus (Coleoptera: Chrysomelidae) Hybrid Zone\|journal=Evolution\|volume=59\|issue=12\|doi=10.1111/j.0014-3820.2005.tb00976.x}}</ref> Dogbane beetles have notoriously low overall fitness, so the males have evolutionarily become more careful when choosing mates. Dogbane beetles use sex pheromones known as Cuticular Hydrocarbon signals to decipher between which females are the most fit and which are not going to increase their own direct fitness through procreation. <ref>{{Cite journal\|last=Kerins\|first=Hallie\|date=2000\|title=Reproductive Character Displacement and X-linkage of Cuticular Hydrocarbons in Chrysochus beetles\|url=https://cedar.wwu.edu/wwu_honors/227/\|journal=WWU Honors Program Senior Projects\|volume=227\|pages=\|via=CEDAR}}</ref> They are also known to be polygamous, and procreating often increases fecundity, and in turn fitness<ref>{{Cite journal\|last=Larson\|first=Erica\|last2=Brassil\|first2=Margaret\|last3=Maslan\|first3=Jonathan\|last4=Juárez\|first4=Danielle\|last5=Lilagan\|first5=Flordeliza\|date=September 2019\|title=The Effects of Heterospecific Mating Frequency Strength of Cryptic Reproductive Barriers\|url=https://search.proquest.com/docview/2235068440\|journal=Journal of Evolutionary Biology\|volume=32\|issue=9\|pages=900–912\|doi=10.1111/jeb.13495\|pmid=31162735\|via=ProQuest}}</ref>. Once the male finds a suitable mate, copulation begins. The copulation process tends to occur earlier in the day and usually takes from an hour to and hour and a half. This is on account of the male perching himself onto the female's back following insemination in order to make sure that she utilizes his sperm in the fertilization of her eggs and to keep other males away from the female. No parental care from either males or females has been reported. The most parental care bestowed upon the female's eggs seems to be the fecal sac that she surrounds them in upon attaching them to the underside of the Dogbane leaf.

			=== Oviposition ===
	Females will lay two or three eggs on the underside of dogbane leaves in the summer months.<ref name=":3">{{Cite web\|url=https://bugguide.net/node/view/461\|title=Species Chrysochus auratus - Dogbane Beetle\|last=Bartlett\|first=Troy\|date=2004\|website=Bug Guide\|url-status=live\|archive-url=\|archive-date=\|access-date=}}</ref> The eggs will be kept in an adhesive, cylindrical sac of the female's feces that allows them to stay attached to the underside of the leaves. This will also serve as protection to the eggs.<ref name=":6">{{Cite web\|url=https://ed.fnal.gov/entry_exhibits/insect/dogbane.html\|title=Golden Beetle and Dogbane\|website=ed.fnal.gov\|access-date=2020-03-03}}</ref> Once an egg hatches, a larva will begin to eat through the fecal sac until it makes a hole that is large enough to exit from. Once there is a large enough hole, the larva will fall from the sac to the ground where it will begin to burrow until it finds Dogbane roots, which will serve as its food until ].<ref name=":0">{{Cite web\|url=https://www.geochembio.com/guides/order-coleoptera-beetles/Chrysochus-auratus.html\|title=Chrysochus auratus, dogbane leaf beetle: taxonomy, facts, life cycle, references at GeoChemBio\|website=www.geochembio.com\|access-date=2020-03-03}}</ref> In Dogbane beetles, pupation usually occurs in the spring. The larva will pupate in a cavity underneath the soil until its body is matured and strong enough to dig back up to the surface. After pupation is complete, the organism is an adult. The lifespan of this organism ranges from 40 to 60 days.<ref name=":0" />
			Copulation typically occurs on the ''Apocynum'' plant, and after mating, females lay eggs on the underside of the leaves of the host plant and surrounding vegetation.

			== Life history ==

			=== Life cycle ===
			After hatching from the egg in midsummer, the first ] larvae will drop to the ground and burrow into the soil. There, it will feed on ] ]s of the ''Apcoynum'' plants. Since ''Apocynum'' contains cardenolides that are very toxic to most animals, the ability of larvae to eat the plant prevents it from being preyed on by ]. Soon after, the larvae will then pupate in a chamber in the same soil, and virgin adults remain in these chambers until they are ready to emerge. Adults will choose to come out of the chamber when their bodies have sufficiently hardened. This usually takes place in the early summer, and the adult beetle will stay in the host plant patch for the next six to eight weeks. Dogbane beetles typically produce one generation per year.<ref>Peterson, M., K. Monsen, H. Pedersen, T. McFarland, J. Bearden. 2005. Direct and indirect analysis of the fitness of Chrysochus (Coleoptera: Chrysomelidae) hybrids.. ''Biological Journal of the Linnean Society'', 84: 273-286.</ref>

			== Genetics ==
			Both ''Chrysochus auratus'' and ''Chrysochus coblatinus'' are considered to have ] distributions. ''C. auratus'' has an eastern North American distribution, occupying eastern North America to the west of the Rocky Mountains. ''C. cobaltinus'' is exclusively found in western North America. In western North America, there are two regions where the distribution of these two species is ], and there are four additional regions in which the two species are less than 100 km apart. In some of these areas of sympatry, there are areas, coined as "hybrid zones" where the two species participate in ]. One such hybrid zone is located in the low-lying area of the ] valley in ] state where there is a 75 km wide region where ''C. auratus'' and ''C. cobaltinus'' interact. Evidence has indicated that this hybrid zone is of post-] origin. During the late Pleitocene, central Washington and the Yakima River Valley faced flooding from ]. The current geographical distribution of the ''C. auratus'' suggests that after the Pleistocene ] receded, the population began to expand into south central Washington, resulting in this hybrid zone. In these areas, hybridization is frequent, but hybrid offspring of the two species have low fitness. Therefore, while hybridization is relatively common, positive ] also has been found to occur.<ref name=":3" />

			In many cases, the hybrid offspring will be more genetically similar to one parent compared to the other. It has been found that when this is the case, the hybrid is often more similar to ''C. auratus''. Hybrid males are also more likely to cluster with ''C. auratus'' beetles over ''C. cobaltinus'' beetles, and the same applies for hybrid females. If a hybrid female clusters with ''C. cobaltnius'', the cluster likely also contains ''C. Cobaltinus'' males, ''C. auratus'' males, and hybrid males. Because the hybrids have lowered fitness and are usually ], ''C. auratus'' and ''C. cobaltinus'' ideally want to mate with beetles within their own respective species. However, in hybrid zones where there is a mix of purebred and hybrid beetles, it can be difficult to make distinctions when a male is trying to choose a female mate. Studies have shown that ''C. cobaltinus'' males are able to make distinctions between ''C. cobaltinus'' and ''C. auratus'' females, even in hybrid zones.<ref>Estelle Labeyrie, Susanne Dobler, Molecular Adaptation of Chrysochus Leaf Beetles to Toxic Compounds in Their Food Plants, Molecular Biology and Evolution, Volume 21, Issue 2, February 2004, Pages 218–221, https://doi.org/10.1093/molbev/msg240
			Kerins, Hallie (2000). "Reproductive Character Displacement and X-linkage of Cuticular Hydrocarbons in Chrysochus beetles". WWU Honors Program Senior Projects. 227 – via CEDAR.</ref>

		⚫	== Mating ==
			]
			=== Mate searching behavior ===
			In this species, males will select the evolutionarily fittest females to mate with. The way in which a male chooses a female to mate with is via chemical signaling systems.<ref name=":3" /> Dogbane beetles use sex ]s known as cuticular hydrocarbon signals to find which females are the fittest and which are not going to increase their direct fitness through procreation.<ref>{{Cite journal \|last=Kerins \|first=Hallie \|date=2000 \|title=Reproductive Character Displacement and X-linkage of Cuticular Hydrocarbons in Chrysochus beetles \|url=https://cedar.wwu.edu/wwu_honors/227/ \|journal=WWU Honors Program Senior Projects \|volume=227 \|via=CEDAR}}</ref>

			=== Female/male interactions ===

			==== Copulation ====

			Adult male and female dogbane beetles usually copulate every day, about once each day. They are also known to be polygamous, and procreating often increases ], and in turn fitness.<ref>{{Cite journal \|last1=Larson \|first1=Erica \|last2=Brassil \|first2=Margaret \|last3=Maslan \|first3=Jonathan \|last4=Juárez \|first4=Danielle \|last5=Lilagan \|first5=Flordeliza \|date=September 2019 \|title=The Effects of Heterospecific Mating Frequency Strength of Cryptic Reproductive Barriers \|journal=Journal of Evolutionary Biology \|volume=32 \|issue=9 \|pages=900–912 \|doi=10.1111/jeb.13495 \|pmid=31162735 \|id={{ProQuest\|2235068440}} \|doi-access=free}}</ref> When the male has found a suitable mate, copulation begins. ] tends to occur earlier in the day and usually takes from an hour to an hour and a half, because the male perches himself on the female's back after ] to make sure his sperm fertilizes her eggs and to keep other males away from the female.
			== Physiology ==
			]
			Adult dogbane beetles are typically an iridescent blue-green color, an appearance that plays to their advantage as it wards off predators. The beetle is typically eight to eleven millimeters in length with an oblong and convex shape. It has a bluish black undersurface. The beetle possesses a pair of ] that are long and twelve joined. They are located between the eye and frontal ridge of the head and are widely separated at their base.

			The ''Chrysochus auratus'' is divided into three large divisions: head, ], and abdomen. It shares this external anatomy with most other ]. Its hind two pairs of legs are attached to the thorax, and it has a highly chitinized body. The head and thorax have deep punctures intermingled with smaller punctures all throughout. This beetle also has a blunt ], characteristics of its herbivorous diet. It has a longer left mandible than the right side which fits into an indentation in the left mandible. This species of beetle has also adapted to have a large ], which allows it to lap up juices from the plants on which it preys.<ref>Wilson, Sloan Jacob (1934). "The Anatomy of Chrysochus auratus, Fab., Coleoptera: (Chrysomelidae) with an Extended Discussion of the Wing Venation". Journal of the New York Entomological Society. 42 (1): 65–85. ISSN 0028-7199. JSTOR 25004541.</ref>

			=== Flight ===
			Attached to its thorax, ''C. auratus'' beetles possess two pairs of wings. The first pair of wings or elytra are heavily ] and are not used for flight. Their main purpose is to protect the more fragile hind wings. The elytra also form the hard case of the beetle, covering its entire dorsal surface and giving it its coppery tinge. The elytra, similar to the head and thorax, contains punctures, but they are smaller and more irregular compared to other parts of the body. The second pair of wings is primarily used for flight and is ] in texture. While ''C. auratus'' do not migrate, they do use their wings to fly between plants in their host patch. The wings have complex venation that vary between beetles. When the wings are folded, certain portions of the wing will reverse.

			==Interactions with humans and livestock==

			=== Agricultural use ===
			''Apocynum'' is a native perennial weed that affects ]. The sprouting portion of the plant interferes with blueberry growth and ] by casting shadows on the blueberry plants. Additionally, dogbane leaves contain latex sap that can potentially poison blueberries. Controlling the spread of this dogbane is difficult, as there are only few effective ]s, many of which harm the blueberry plant as well. Due to ''C. auratus''{{'}} use of ''Apocynum'' (dogbane) as a food source, the beetle has been considered as a potential mechanism of ] for ''Apocynum''. Research on this topic has consistently shown that while an inundation of ''C. auratus'' could significantly deter dogbane growth and spreading, natural population densities of the beetle would not cause enough of an effect to single handedly control the ''Apocynum'' populations. Therefore, many integrated management programs for dogbane proliferation are working on strategies to conserve and augment the ''C. auratus'' population for agricultural use.<ref>
			MacEachern-Balodis, M.C., Boyd, N.S., White, S.N. et al. Examination of dogbane beetle (Chrysochus auratus) feeding and phenology on spreading dogbane, and considerations for biological control. Arthropod-Plant Interactions 11, 807–814 (2017). https://doi.org/10.1007/s11829-017-9535-3</ref>

			''C. auratus'' has also been considered as a potential mechanism of biological control for a non-native ] vine called '']'', which also falls in the ''Apocynaceae family.'' However, experiments have shown that while ''C. auratus'' is very reproductively successful on '']'' and '']'' leaves, this success does not apply to ''Vincetoxicum rossicum''. This beetle lays its eggs on the underside of leaves, and experiments have shown that ''Vincetoxicum rossicum'' leaves are an ] sink for ''C. auratus'' eggs, meaning that depositing eggs on the underside of these leaves can result in a lower probability of successful development and survival for their larvae. Therefore, ''C. auratus'' may not necessarily be as successful an avenue for ''Vincetoxicum rossicum'' control as for other ''Apocynaceae plants''.<ref>R. B. deJonge, R. S. Bourchier, S. M. Smith, Initial Response by a Native Beetle, Chrysochus auratus (Coleoptera: Chrysomelidae), to a Novel Introduced Host-Plant, Vincetoxicum rossicum (Gentianales: Apocynaceae), Environmental Entomology, Volume 46, Issue 3, June 2017, Pages 617–625, https://doi.org/10.1093/ee/nvx072
			</ref>

	==References==		==References==
			{{Wikicommons}}
	{{Reflist}}		{{Reflist}}

Latest revision as of 21:05, 19 May 2024

Species of beetle

Dogbane beetle

Scientific classification
Domain:	Eukaryota
Kingdom:	Animalia
Phylum:	Arthropoda
Class:	Insecta
Order:	Coleoptera
Family:	Chrysomelidae
Subfamily:	Eumolpinae
Tribe:	Eumolpini
Genus:	Chrysochus
Species:	C. auratus
Binomial name
*Chrysochus auratus* (Fabricius, 1775)
Synonyms
Chrysomela aurata Fabricius, 1775

Chrysochus auratus, more commonly known as the dogbane beetle, is a leaf beetle primarily found in the eastern United States. The beetle is approximately 8 to 11 mm in length, and possesses an oblong and convex shape. This beetle has two pairs of wings, one of which is a pair of copper colored elytra. The beetle is typically found to have a blue-green hue, and its color is often used to ward away potential predators.

A major aspect of this beetles' day to day life is sexual reproduction, as the beetles typically live a highly polygamous lifestyle. This beetle has also been found to participate in interbreeding with Chrysochus cobaltinus in certain geographic regions, resulting in hybrid offspring. Its diet consists primarily of dogbane (Apocynum), specifically Apocynum cannabinum and Apocynum androsaemifolium. C. auratus has developed several different adaptations that allow it to eat dogbane, such as its ability to process the toxins in dogbane leaves. Due to its diet of exclusively dogbane, C. auratus has been considered as a potential mechanism of biological control for agricultural purposes.

Geographic range

Chrysochus auratus is generally found in eastern North America, spanning the entire eastern United States and into adjacent southern Canada west of the Rocky Mountains. At the western edge of its range, it extends west of the Rocky Mountains into Arizona and Utah. The related species Chrysochus cobaltinus, in contrast, is found exclusively in western North America. The two species were historically considered to have allopatric distributions. Recently, at least two narrow regions in western North America have been documented where both C. auratus and C. cobaltinus occur and apparently interbreed.

Food resources

Beetles of the Chrysochus genus typically feed on dogbane plants (Apocynaceae) and milkweeds (Asclepiadaceae). It has been found that C. auratus exclusively feeds on dogbane plants. More specifically, C. auratus feeds on the Apocynum cannabinum and Apocynum androsaemifolium dogbane varieties. Larvae of the dogbane beetle will typically feed on the roots of the plants while adults will feed on the leaves of the plants. Plants in the Apocynum genus release toxins, called cardenolides, as a defense mechanism to predators. When ingested, it can be fatal for numerous organisms, including humans as consumption can result in cardiac arrest. Because C. auratus feed exclusively on Apocynum cannabinum and Apocynum androsaemifolium; they have developed behavioral and physiological adaptations to overcome these plant's defenses.

Cardenolides have the ability to bind to and block the function of Na/K - ATPase, which is a transmembrane carrier present in almost all animals and tissues. It controls the balance of cell potentials and is vital to the nervous system. When poisoned, these systems are detrimentally affected. Therefore, this type of beetle has adapted mechanisms to reduce the effects cardenolides has on Na/K - ATPase in C. auratus. More specifically, Chrysochus auratus has a single amino acid substitution in its Na/K - ATPase that allows it to achieve this. The beetle is not only adapted to processing toxic cardenolide, but can also able to accumulate this compound in its own body to deter future predators. Cardenolide is shuttled through the beetle's body into cuticular glands, some of which are located in the elytra or wings. When the beetle senses some form of disturbance that requires a defensive mechanism, the beetle will secrete the cardenolides, poisoning its enemies. This mutation may explain the dogbane beetle's insensitivity to the poisonous compounds, especially because this same mutation has been shown in the cardenolide-insensitive monarch butterfly.

These beetles have also evolved to develop a behavioral mechanism that allows for feeding on the Apocynum genus. As a defense mechanism to predators, Apocynum cannabinum and Apocynum androsaemifolium (dogbane) produce a toxic sticky white latex when its stems and leaves are broken. When feeding, C. auratus beetles feed on the margins of A. cannabinum and A. androsaemifolium leaves. The beetle will chew a five-to-seven-millimeter channel that sits diagonal from the leaf margin and points in the direction of the leaf's apex. Because this channel transects the major veins of the leaf, these initial cuts will exude a large amount of latex the leaf releases as its defensive mechanism. Distal to this initial cut location is the presence of low-latex tissue, which the beetle exclusively feeds on, biting on it in a downward motion. The feeding process typically lasts around one minute, and the beetle will straddle the leaf margins while feeding. As the beetles feed, latex accumulates on the ventral segments of their mouth due to the repetitive downward motion made by their head. Therefore, after feeding has ceased, the beetles will move from the margins of the leaf to the interior portion of the leaf. The beetle will then press its mouth to the surface of the leaf and drag its mouth on the leaf while walking backwards. This method removes the latex buildup from the beetle's mouth region. Evidence of this behavior can be seen on leaves that have been fed on by C. auratus, demonstrated by the rings of dried latex that can be found near the site of feeding.

Parental care

No parental care has been reported, except the fecal sac that the mother surrounds her eggs with when attaching them to the underside of the dogbane leaf.

Oviposition

Copulation typically occurs on the Apocynum plant, and after mating, females lay eggs on the underside of the leaves of the host plant and surrounding vegetation.

Life history

Life cycle

After hatching from the egg in midsummer, the first instar larvae will drop to the ground and burrow into the soil. There, it will feed on tuberous rhizomes of the Apcoynum plants. Since Apocynum contains cardenolides that are very toxic to most animals, the ability of larvae to eat the plant prevents it from being preyed on by parasitic wasps. Soon after, the larvae will then pupate in a chamber in the same soil, and virgin adults remain in these chambers until they are ready to emerge. Adults will choose to come out of the chamber when their bodies have sufficiently hardened. This usually takes place in the early summer, and the adult beetle will stay in the host plant patch for the next six to eight weeks. Dogbane beetles typically produce one generation per year.

Genetics

Both Chrysochus auratus and Chrysochus coblatinus are considered to have allopatric distributions. C. auratus has an eastern North American distribution, occupying eastern North America to the west of the Rocky Mountains. C. cobaltinus is exclusively found in western North America. In western North America, there are two regions where the distribution of these two species is sympatric, and there are four additional regions in which the two species are less than 100 km apart. In some of these areas of sympatry, there are areas, coined as "hybrid zones" where the two species participate in interbreeding. One such hybrid zone is located in the low-lying area of the Yakima River valley in Washington state where there is a 75 km wide region where C. auratus and C. cobaltinus interact. Evidence has indicated that this hybrid zone is of post-Pleistocene origin. During the late Pleitocene, central Washington and the Yakima River Valley faced flooding from Glacial Lake Missoula. The current geographical distribution of the C. auratus suggests that after the Pleistocene glaciers receded, the population began to expand into south central Washington, resulting in this hybrid zone. In these areas, hybridization is frequent, but hybrid offspring of the two species have low fitness. Therefore, while hybridization is relatively common, positive assortative mating also has been found to occur.

In many cases, the hybrid offspring will be more genetically similar to one parent compared to the other. It has been found that when this is the case, the hybrid is often more similar to C. auratus. Hybrid males are also more likely to cluster with C. auratus beetles over C. cobaltinus beetles, and the same applies for hybrid females. If a hybrid female clusters with C. cobaltnius, the cluster likely also contains C. Cobaltinus males, C. auratus males, and hybrid males. Because the hybrids have lowered fitness and are usually sterile, C. auratus and C. cobaltinus ideally want to mate with beetles within their own respective species. However, in hybrid zones where there is a mix of purebred and hybrid beetles, it can be difficult to make distinctions when a male is trying to choose a female mate. Studies have shown that C. cobaltinus males are able to make distinctions between C. cobaltinus and C. auratus females, even in hybrid zones.

Mating

Mate searching behavior

In this species, males will select the evolutionarily fittest females to mate with. The way in which a male chooses a female to mate with is via chemical signaling systems. Dogbane beetles use sex pheromones known as cuticular hydrocarbon signals to find which females are the fittest and which are not going to increase their direct fitness through procreation.

Female/male interactions

Copulation

Adult male and female dogbane beetles usually copulate every day, about once each day. They are also known to be polygamous, and procreating often increases fecundity, and in turn fitness. When the male has found a suitable mate, copulation begins. Copulation tends to occur earlier in the day and usually takes from an hour to an hour and a half, because the male perches himself on the female's back after insemination to make sure his sperm fertilizes her eggs and to keep other males away from the female.

Physiology

Adult dogbane beetles are typically an iridescent blue-green color, an appearance that plays to their advantage as it wards off predators. The beetle is typically eight to eleven millimeters in length with an oblong and convex shape. It has a bluish black undersurface. The beetle possesses a pair of antennae that are long and twelve joined. They are located between the eye and frontal ridge of the head and are widely separated at their base.

The Chrysochus auratus is divided into three large divisions: head, thorax, and abdomen. It shares this external anatomy with most other insects. Its hind two pairs of legs are attached to the thorax, and it has a highly chitinized body. The head and thorax have deep punctures intermingled with smaller punctures all throughout. This beetle also has a blunt mandible, characteristics of its herbivorous diet. It has a longer left mandible than the right side which fits into an indentation in the left mandible. This species of beetle has also adapted to have a large hypopharynx, which allows it to lap up juices from the plants on which it preys.

Flight

Attached to its thorax, C. auratus beetles possess two pairs of wings. The first pair of wings or elytra are heavily chitinized and are not used for flight. Their main purpose is to protect the more fragile hind wings. The elytra also form the hard case of the beetle, covering its entire dorsal surface and giving it its coppery tinge. The elytra, similar to the head and thorax, contains punctures, but they are smaller and more irregular compared to other parts of the body. The second pair of wings is primarily used for flight and is membranous in texture. While C. auratus do not migrate, they do use their wings to fly between plants in their host patch. The wings have complex venation that vary between beetles. When the wings are folded, certain portions of the wing will reverse.

Interactions with humans and livestock

Agricultural use

Apocynum is a native perennial weed that affects lowbush blueberries. The sprouting portion of the plant interferes with blueberry growth and harvest by casting shadows on the blueberry plants. Additionally, dogbane leaves contain latex sap that can potentially poison blueberries. Controlling the spread of this dogbane is difficult, as there are only few effective herbicides, many of which harm the blueberry plant as well. Due to C. auratus' use of Apocynum (dogbane) as a food source, the beetle has been considered as a potential mechanism of biological control for Apocynum. Research on this topic has consistently shown that while an inundation of C. auratus could significantly deter dogbane growth and spreading, natural population densities of the beetle would not cause enough of an effect to single handedly control the Apocynum populations. Therefore, many integrated management programs for dogbane proliferation are working on strategies to conserve and augment the C. auratus population for agricultural use.

C. auratus has also been considered as a potential mechanism of biological control for a non-native European vine called Vincetoxicum rossicum, which also falls in the Apocynaceae family. However, experiments have shown that while C. auratus is very reproductively successful on Apocynum cannabinum and Apocynum androsaemifolium leaves, this success does not apply to Vincetoxicum rossicum. This beetle lays its eggs on the underside of leaves, and experiments have shown that Vincetoxicum rossicum leaves are an oviposition sink for C. auratus eggs, meaning that depositing eggs on the underside of these leaves can result in a lower probability of successful development and survival for their larvae. Therefore, C. auratus may not necessarily be as successful an avenue for Vincetoxicum rossicum control as for other Apocynaceae plants.

References

^ Peterson, Merrill; Honchak, Barbara; Locke, Steranie; Beeman, Timothy; Mendoza, Jessica; Green, Jabin; Buckingham, Kati (May 2007). "Relative Abundance and the Species-Specific Reinforcement of Male Mating in the Chrysochus (Coleoptera: Chrysomelidae) Hybrid Zone". Evolution. 59 (12). doi:10.1111/j.0014-3820.2005.tb00976.x. S2CID 25481151.
^ Peterson, M. A.; Dobler, S.; Holland, J.; T., L.; Locke, S. (2001). "Behavioral, Molecular, and Morphological Evidence for a Hybrid Zone Between Chrysochus auratus and C. cobaltinus (Coleoptera: Chrysomelidae)" (PDF). Annals of the Entomological Society of America. 94 (1): 1–10. doi:10.1603/0013-8746(2001)094[0001:BMAMEF]2.0.CO;2.
MacEachern-Balodis, M.C., Boyd, N.S., White, S.N. et al. Examination of dogbane beetle (Chrysochus auratus) feeding and phenology on spreading dogbane, and considerations for biological control. Arthropod-Plant Interactions 11, 807–814 (2017). https://doi.org/10.1007/s11829-017-9535-3
Estelle Labeyrie, Susanne Dobler, Molecular Adaptation of Chrysochus Leaf Beetles to Toxic Compounds in Their Food Plants, Molecular Biology and Evolution, Volume 21, Issue 2, February 2004, Pages 218–221, https://doi.org/10.1093/molbev/msg240
Karageorgi, Marianthi; Groen, Simon C.; Sumbul, Fidan; Pelaez, Julianne N.; Verster, Kirsten I.; Aguilar, Jessica M.; Hastings, Amy P.; Bernstein, Susan L.; Matsunaga, Teruyuki; Astourian, Michael; Guerra, Geno (2019-10-17). "Genome editing retraces the evolution of toxin resistance in the monarch butterfly". Nature. 574 (7778): 409–412. doi:10.1038/s41586-019-1610-8. ISSN 0028-0836. PMC 7039281. PMID 31578524.
Williams, Charles. (1991). Host plant latex and the feeding behavior of Chrysochus auratus (Coleoptera: Chrysomelidae). The Coleopterists Bulletin. 45. 195-196.
Peterson, M., K. Monsen, H. Pedersen, T. McFarland, J. Bearden. 2005. Direct and indirect analysis of the fitness of Chrysochus (Coleoptera: Chrysomelidae) hybrids.. Biological Journal of the Linnean Society, 84: 273-286.
Estelle Labeyrie, Susanne Dobler, Molecular Adaptation of Chrysochus Leaf Beetles to Toxic Compounds in Their Food Plants, Molecular Biology and Evolution, Volume 21, Issue 2, February 2004, Pages 218–221, https://doi.org/10.1093/molbev/msg240 Kerins, Hallie (2000). "Reproductive Character Displacement and X-linkage of Cuticular Hydrocarbons in Chrysochus beetles". WWU Honors Program Senior Projects. 227 – via CEDAR.
Kerins, Hallie (2000). "Reproductive Character Displacement and X-linkage of Cuticular Hydrocarbons in Chrysochus beetles". WWU Honors Program Senior Projects. 227 – via CEDAR.
Larson, Erica; Brassil, Margaret; Maslan, Jonathan; Juárez, Danielle; Lilagan, Flordeliza (September 2019). "The Effects of Heterospecific Mating Frequency Strength of Cryptic Reproductive Barriers". Journal of Evolutionary Biology. 32 (9): 900–912. doi:10.1111/jeb.13495. PMID 31162735. ProQuest 2235068440.
Wilson, Sloan Jacob (1934). "The Anatomy of Chrysochus auratus, Fab., Coleoptera: (Chrysomelidae) with an Extended Discussion of the Wing Venation". Journal of the New York Entomological Society. 42 (1): 65–85. ISSN 0028-7199. JSTOR 25004541.
MacEachern-Balodis, M.C., Boyd, N.S., White, S.N. et al. Examination of dogbane beetle (Chrysochus auratus) feeding and phenology on spreading dogbane, and considerations for biological control. Arthropod-Plant Interactions 11, 807–814 (2017). https://doi.org/10.1007/s11829-017-9535-3
R. B. deJonge, R. S. Bourchier, S. M. Smith, Initial Response by a Native Beetle, Chrysochus auratus (Coleoptera: Chrysomelidae), to a Novel Introduced Host-Plant, Vincetoxicum rossicum (Gentianales: Apocynaceae), Environmental Entomology, Volume 46, Issue 3, June 2017, Pages 617–625, https://doi.org/10.1093/ee/nvx072

External links

One gorgeous beetle: Dogbane leaf beetle, Chrysochus auratus Bug of the Week

Taxon identifiers
Chrysochus auratus	Wikidata: Q5114766 Wikispecies: Chrysochus auratus ADW: Chrysochus_auratus BioLib: 924106 BOLD: 15210 BugGuide: 461 EoL: 1173273 GBIF: 1048357 iNaturalist: 84162 ITIS: 720993 NatureServe: 2.112898 NCBI: 131619 Open Tree of Life: 981601

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