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Utetheisa ornatrix

January 01, 1970

Utetheisa ornatrix, also called the ornate bella moth, ornate moth, bella moth or rattlebox moth, is a moth of the subfamily Arctiinae. It is aposematically colored ranging from pink, red, orange and yellow to white coloration with black markings arranged in varying patterns on its wings. It has a wingspan of 33–46 mm. Moths reside in temperate midwestern and eastern North America as well as throughout Mexico and other parts of Central America. Unlike most moths, the bella moth is diurnal. Formerly, the bella moth or beautiful utetheisa of temperate eastern North America was separated as Utetheisa bella. Now it is united with the bella moth in Utetheisa ornatrix.

Utetheisa ornatrix
Scientific classification
Domain: Eukaryota
Kingdom: Animalia
Phylum: Arthropoda
Class: Insecta
Order: Lepidoptera
Superfamily: Noctuoidea
Family: Erebidae
Subfamily: Arctiinae
Tribe: Arctiini
Subtribe: Callimorphina
Genus: Utetheisa
Species:
U. ornatrix
Binomial name
Utetheisa ornatrix
Synonyms
  • Phalaena ornatrix Linnaeus, 1758
  • Utetheisa bella (Linnaeus, 1758)
  • Deiopeia ornatrix var. stretchii Butler, 1877
  • Deiopeia pura Butler, 1877
  • Deiopeia ornatrix var. daphoena Dyar, 1914
  • Deiopeia ornatrix var. butleri Dyar, 1914
  • Phalaena Tinea bella Linnaeus, 1758
  • Euprepia venusta Dalman, 1823
  • Deiopeia speciosa Walker, 1854
  • Deiopeia ornatrix var. hybrida Butler, 1877
  • Deiopeia bella var. intermedia Butler, 1877
  • Utetheisa bella var. terminalis Neumoegen & Dyar, 1893
  • Utetheisa nova J.B.Smith, 1910

The larvae usually feed on Crotalaria species, which contain poisonous alkaloid compounds that render them unpalatable to most predators. Larvae may prey on other bella moth larvae in order to compensate for any alkaloid deficiency.

The bella moth also demonstrates complex mating strategies and is thus an excellent model to study sexual selection. Females mate multiply and receive spermatophores containing sperm, nutrients and alkaloid compounds from numerous males as nuptial gifts. Females choose males according to the intensity of a courtship pheromone, hydroxydanaidal, and carry out a sperm selection process after copulation with various males.

Distribution edit

Utetheisa ornatrix is found from southeastern United States to South America (southeast Brazil). In the southeastern United States, its distribution ranges from Connecticut westward to southeastern Nebraska and southward to southern New Mexico and Florida.[1] This species is found to be more common in more tropical parts of this range, in accordance to the availability of its host plant in more southern regions.[1] It is also found throughout Mexico, South America, and Central America.[2]

Taxonomy edit

In 1758, Carl Linnaeus first characterized two species of the genus Phalaena. Phalaena ornatrix was used to describe the paler moth specimens, and Utetheisa bella, described the bright pink moth specimens.[3] In 1819, Hübner moved these species to a new genus, Utetheisa.[4] For nearly a century, it was difficult to determine this moth's evolutionary history as researchers focused on external similarities (color, shape, patterns, size), rather than determining features specific to the species. This led to great confusion when trying to categorize the different subspecies.[4] In 1960, Forbes combined both species, Utetheisa ornatrix and Utetheisa bella, into the species now known as Utetheisa ornatrix.[4] His conclusion was also supported by Pease Jr. who, in 1966, used genetic testing and determined that any phenotypic differences were based on interspecific variation due to geographic differences (rather than intraspecific variation).[4]

Subspecies edit

  • Utetheisa ornatrix ornatrix
  • Utetheisa ornatrix bella (Linnaeus, 1758)
  • Utetheisa ornatrix saintcroixensis Pease, 1973

Description edit

 
On rattlebox blossom (Crotalaria sp.)

Eggs edit

The eggs of the Utetheisa ornatrix are spherical in shape and range in colour from white to yellow to sometimes brown.[1]

Larvae edit

The larvae are orange and brown with irregular black bands on each segment of the body. The anterior and posterior portions of the black binds are also marked with distinct white spots. Full grown larvae reach 30-35mm in length. Although most arctiid larvae have verrucae, Utetheisa ornatrix larvae lack these.[1]

Pupae edit

The pupae are mostly black marked with irregular orange and brown bands. Usually, the pupae are covered with a loose layer of silk.[1]

Adult edit

These moths are aposematic and use their bright coloration to warn predators of their unpalatability. Their wings range in color from yellow, red, pink, and orange to white.[2] Wings contain white bands containing six bands of irregularly spaced black spots.[5] The hind wings can be bright pink with a marginal black band. The adult Utetheisa ornatrix has a wingspan of 33 to 46 millimetres (1.3 to 1.8 in).[2]

Predation edit

 
Mature pods of the rattlepod, Crotalaria retusa

During the larval stages, caterpillars feed on leguminous plants of the genus Crotalaria.[6] These plants contain large amounts of toxins, particularly pyrrolizidine alkaloids (PAs), which are found in high concentrations in the seeds.[6] Bella moth caterpillars sequester these toxins and use them as a deterrent for predators.[6] When the adult is disturbed, they secrete a foam containing the toxins from their head, which makes them unpalatable to predators. Since PAs are an extremely valuable resource, individual larvae compete with one another to colonize an entire pod, an elongated seed-containing pouch from the food plant.[7] Larvae that are unable to take ownership of a pod must obtain the chemicals from leaves, where they are found at much lower densities. These caterpillars sequester smaller amounts of PAs and are more susceptible to predation.[7]

Although it is beneficial to feed on seeds, larvae do not enter the pods immediately after they hatch.[8] During the first larval instars, caterpillars feed on leaves and it is not until the second or third instar that they enter the pods.[8] The evolutionary benefits of this strategy are not understood.[8] When caterpillars metamorphose into adult moths, they carry the alkaloids with them, which continue to protect them during the adult stage.[6]

PAs render the bella moth unpalatable to many of its natural enemies like spiders and insectivorous bats.[9][10] Spiders that capture bella moth larvae or adults release them soon after, leaving them unharmed.[10] In contrast, bella moth individuals grown on a PA-free diet are readily preyed on by spiders.[10] Similarly, bats that catch bella moth individuals quickly release these unpalatable moths without harming them.[9] Unlike other moths of the Arctiidae, the bella moth does not possess an acoustic aposematism system that would enable it to avoid bats altogether.[9] Bella moth larvae and some predators like loggerhead shrikes are not negatively affected by PAs.[6]

The bella moth is able to detoxify PAs due to the possession of the gene pyrrolizidine-alkaloid-N-oxygenase.[11] It has been experimentally shown that bella moth larvae upregulate the expression of this gene when the amount of PAs in their diet increases.[11] In addition, it has been shown that PA rich diets do not have a negative effect on the fitness of these moths,[11] but only affect time of development, which increases with increasing PA concentration in diet.[11] However, caterpillars with longer development times reach similar pupal sizes compared to those with shorter developmental times due to diets containing smaller amounts of PAs.[11]

Cannibalism edit

On occasion, bella moth caterpillars cannibalize other eggs, pupae or larvae from the same species.[12] Since PAs are a limited resource, some caterpillars do not reach optimal levels and resort to cannibalism.[13] This behavior is a consequence of PA deficiency rather than hunger, since deficits in alkaloids are the main cause of mortality.[12] Pupae cannibalism is rare because larvae normally pupate far away from the plant where they feed.[12] Egg cannibalism is also rare because eggs provide larvae with very small quantities of PAs[13] and because eggs from the same cluster hatch synchronously.[14] Larvae may also feed on other bella moth larvae that are laden with alkaloids.[12] This is more common since feeding on one single larva is sufficient to compensate for the cannibalistic caterpillar's alkaloid deficiency.[12]

Kin recognition edit

Bella moth caterpillars may have the ability to recognize other larvae as kin, as larvae are less likely to intrude upon siblings than non-siblings established in seedpods.[15]

Mating edit

Bella moths of both sexes use very complex reproductive strategies, making this species an excellent model system for studying sexual selection.[7] Females mate multiply over their three- to four-week lifespan as adults.[7] They mate with an average of three to four males, each of whom provides her with a nuptial gift, a spermatophore containing sperm, nutrients, and alkaloids.[7] Adult males invest up to 11% of their body mass to create a spermatophore they provide to a female during mating.[7] The nutrients given in the spermatophore allow the female to produce, on average, an additional 32 eggs.[16]

Mating system edit

The bella moth presents a polyandrous mating system, where females mate with multiple males.[17] On average, females mate with four to five males over their lifespan of three to four weeks but can mate with and receive up to thirteen spermatophores.[17] Since spermatophores contain nuptial gifts of pyrrolizidine alkaloid (PA) and nutrients, multiple mating helps the female increase the fitness of her offspring.[17] In addition, multiple mating also benefits the female directly. Since the spermatophores are sizeable and can be digested within the female, multiple mating allows females to accrue the resources necessary to build additional eggs.[17] This is equivalent to a 15% increase in egg production.[18] In addition, multiple mating results in increased transmission of alkaloidal gifts to eggs.[19] However, this does not mean that there is segregated allocation of these gifts. Instead, the PA obtained from numerous males is allocated in admixture so that eggs tend to receive from more than one male source.[19] In contrast, normally most of the sperm used to fertilize the eggs comes from a single male.[16]

Courtship edit

Courtship begins at dusk.[20] Stationary females release a sexual pheromone that lures males.[20] They emit these chemicals in short pulses to provide close-range orientation cues to male moths as they seek out the females.[21] When a male reaches a female, he flutters around her and thrusts two peculiar tufts of scales from his coremata, two yellow spherical structures by the male's genital organs.[6][22] By doing so, the male emits a specific scent from his coremata that is attributed to a pheromone, hydroxydanaidal.[20] After receiving the scent, the female proceeds to mating.[22]

Copulation lasts for up to 12 hours.[23] It takes the male about two hours to transfer the spermatophore containing all of the sperm and nutrients he is going to offer to the female.[24] The remaining hours of copulation are exclusively used for alkaloid transfer.[24] These alkaloids distribute themselves evenly around the female body, even the wings, and offer her great protection as they render her unpalatable to most predators.[24] Eventually, the female allocates about one third of the alkaloids she receives to her ovaries, where they will be used to confer protection to the eggs.[24]

Female pheromonal chorusing edit

Bella moth mating behavior is exceptional in that females compete with other females to obtain more males, as opposed to males competing with males.[25] As in many other moth species, females release sexual pheromones that males can detect over long distances.[25] However, in most species, females do not interact with one another during pheromone release.[25] Female bella moths are unique in that females from the same family often engage in collective pheromone release termed “female pheromonal chorusing”.[25]

This phenomenon is a consequence of a female-biased operational sex ratio. This means that at any given time, there are more females than males seeking to copulate.[25] This occurs because males lose up to 11% of their body mass during mating and once they are done mating, they need time to sequester resources that will allow them to deliver a spermatophore to the next female they mate with.[25] On the contrary, females do not need time to prepare for their next copulation.[25] Due to the unequal mating rates, males become valuable to females and female-to-female competition rises dramatically as a consequence.[25]

Engaging in pheromonal chorusing allows females to increase the attractiveness of genetic relatives and increase their indirect fitness.[25] Females may also, but less frequently, engage in female chorusing with unrelated females.[25] It has been suggested that chorusing is still beneficial under these circumstances, because cooperation for pheromone release may increase the attractiveness of the entire group and increase each moth's individual fitness.[25] It has been experimentally shown that when females detect other female pheromones they increase the rate of pheromone release and call for longer periods of time.[26] Such observations support the hypothesis that females cooperate with one another to increase mating success.[26]

Sexual selection edit

Precopulatory edit

Although most female moths mate multiply, very low instances of mixed paternities occur.[16] In fact, most progeny in a single clutch is sired exclusively by one male.[16] Females of this species do not select based on age, mating order, between-mating interval, or duration of copulation.[16] Instead, female Utetheisa ornatix demonstrate female choice in mate selection that depends on body size, systemic content of defensive pyrrolizidine alkaloid, and glandular content of the courtship pheromone hydroxydanaidal.[27] Selecting for these males provides the females with multiple benefits such as obtaining sperm packages with more defensive pyrrolizidine alkaloids which results in larger offspring.[18] Offspring fathered by larger males are generally less vulnerable to predation because of their higher alkaloid content, allowing the offspring to have higher viability and fitness.[18]

Larger males with the highest alkaloid content can be distinguished by a specific pheromonal scent that predicts the content of the alkaloidal gifts: hydroxydanaidal (HD).[20] There is a relationship between the size of the male, the type of food the males fed on as larvae, and the composition of its spermatophores.[20] For example, males that fed inside a seed pod rather than on leaves produce higher levels of HD.[20] In addition, these males have higher adult weights and have higher systemic loads of PA, the metabolic precursor of HD.[20] By selecting for HD-rich males, the female moth ensures the receipt of a large alkaloid gift (phenotypic benefit) and genes that encode for large size (genetic benefit).[27]

The female's mating preference is inherited paternally since the preference gene or genes lie mostly or exclusively on the Z sex chromosome.[28] The preferred male trait and the female preference for the trait are strongly correlated; females with larger fathers have a stronger preference for larger males.[28]

Postcopulatory edit

After copulating with several males, rival sperm carried by a female do not compete directly for access to the eggs.[16] Females direct a postcopulatory selective process where they choose male sperm based on the intensity of the courtship pheromone that was released prior to copulation, hydroxydanaidal (HD).[7] The intensity of this signal is directly proportional to the amount of alkaloids sequestered by the moth during the larval stages.[7] As a consequence, this pheromone is an indirect indicator of success during larval development and will ultimately determine which sperm will be passed on to the offspring.[7] Once they have selected a male, females use their musculature to channel the selected sperm through the chambers and constructs of their reproductive systems to their eggs.[16]

Parental investment edit

The eggs of the bella moth contain pyrrolizidine alkaloids (PAs) that the mother delivers.[29] The alkaloid is stored during the larval stages and retained through metamorphosis, protecting both larvae and adults from predators.[29] Female moths receive alkaloids from the males at the time of mating as part of the spermatophore.[29] Although the male's contribution of PAs is less than that of the female, it still contributes significantly to egg protection.[29]

Spermatophore edit

The spermatophore that males give to the females when mating contains sperm, nutrients, and pyrrolizidine alkaloids (PA), and accounts for up to 11% of the male's body mass.[18] PA plays an important role in preventing predation in Utetheisa ornatrix because it is poisonous to most organisms. Males transmit PA to the females via a sperm package; the females then give this mating gift to the eggs,[30] along with their own alkaloidal supplement and is utilized to protect the offspring from predation.[18] In addition, females also personally benefit from the gift through protection and nutrition. After mating with a PA-rich male, the received PA is quickly allocated to all body parts.[30] As a result, females become and remain unacceptable as prey to numerous organisms such as spiders.[30] Another problem that females face is the risk of incurring a PA deficit due to the large amount of eggs they lay. Spermatophores is one way for females to compensate for this loss in PA.[19]

Host plants edit

 
Crotalaria pallida

Plants of the genus Crotalaria are the major hosts for the Utetheisa ornatrix, although a variety of plants in the family Fabaceae have also been cited in literature.[1] The word Crotalaria originates from the Greek root “crotal,” which means “a rattle” and is characteristic of the pods found on these plants.[1] The Crotalaria host plants contain pyrrolizidine alkaloids, which are used by the Utetheisa ornatrix to repel predators.[1] Specific host plants used include:

  • Crotalaria avonensis (Avon Park rattlebox)
  • Crotalaria rotundifolia (rabbitbells)
  • Crotalaria lanceolata
  • Crotalaria pallida (smooth rattlebox)
  • Crotalaria spectabilis (showy rattlebox)
  • Crotalaria retusa[1]

Pyrrolizidine alkaloids and humans edit

Pyrrolizidine alkaloids (PAs) are the toxins the bella moth is able to ingest and use for protection from predators.[1] They are known to be the principal toxins found in plants that can cause disease in humans and other animals.[31] Reported pathways for human exposure include crop contamination, milk and honey contamination and some traditional herbal medicines.[31] Once ingested, the alkaloids affect mainly the liver and the lungs. Human poisoning can cause veno-occlusive disease and teratogenicity.[31]

References edit

  1. ^ a b c d e f g h i j "Utetheisa Ornatrix." Entomology and Nemotology. University of Florida, n.d. Web. 14 Nov. 2013.
  2. ^ a b c Sourakov, Andrei; Logan M. Locascio (2013). "Exotic Crotalaria Species (Fabales: Fabaceae) as Host Plants of the Ornate Bella Moth, Utetheisa ornatrix (Lepidoptera: Erebidae), in Florida: Laboratory Biology". Florida Entomologist. 96 (2): 344–350. doi:10.1653/024.096.0254.
  3. ^ Majik, Phil. "Bella Moth". Retrieved 17 November 2013.
  4. ^ a b c d DaCosta, Michelle Antoinette (2007). Phylogenetic Studies of Utetheisa Hubner, the Rattle Box Moth, and Other Arctiines (Lepidoptera: Noctuoidea: Arctiidae). ISBN 978-0-549-11380-5.
  5. ^ "Ornate Bella Moth". Missouri Department of Conservation. Missouri Department of Conservation. Retrieved 15 January 2023.
  6. ^ a b c d e f Conner, W.E. (2009). Tiger Moths and Woolly Bears—behaviour, ecology, and evolution of the Arctiidae. New York: Oxford University Press. pp. 1–10.
  7. ^ a b c d e f g h i Kellya, Caitlin A.; Amanda J. Norbutusb; Anthony F. Lagalanteb; Vikram K. Iyengara (2012). "Male courtship pheromones as indicators of genetic quality in an arctiid moth (Utetheisa ornatrix)". Behavioral Ecology. 23 (5): 1009–1014. doi:10.1093/beheco/ars064.
  8. ^ a b c Gianluppi Ferro, Viviane; Paulo Roberto Guimarães Jr; José Roberto Trigo (2006). "Why do larvae of Utetheisa ornatrix penetrate and feed in pods of Crotalaria species? Larval performance vs. chemical and physical constraints". Entomologia Experimentalis et Applicata. 121 (1): 23–29. doi:10.1111/j.1570-8703.2006.00450.x. S2CID 49541027.
  9. ^ a b c Hristov, Nickolay I.; William E. Conner (2005). "Sound strategy: acoustic aposematism in the bat–tiger moth arms race". Naturwissenschaften. 92 (4): 164–169. doi:10.1007/s00114-005-0611-7. PMID 15772807. S2CID 18306198.
  10. ^ a b c Eisner, Thomas; Maria Eisner (1991). "Unpalatability of the pyrrolizidine alkaloid- containing moth Utetheisa ornatrix, and its larva, to wolf spiders". Psyche: A Journal of Entomology. 98: 111–118. doi:10.1155/1991/95350.
  11. ^ a b c d e Cogni, Rodrigo; Jose R. Trigo; Douglas J. Futuyma (2012). "A free lunch? No cost for acquiring defensive plant pyrrolizidine alkaloids in a specialist arctiid moth (Utetheisa ornatrix)". Molecular Ecology. 21 (24): 6152–6162. doi:10.1111/mec.12086. PMID 23110459. S2CID 25612129.
  12. ^ a b c d e Bogner, Franz X (1996). "Interspecific advantage results in intraspecific disadvantage: chemical protection versus cannibalism in Utetheisa ornatrix". Journal of Chemical Ecology. 22 (8): 1439–1451. doi:10.1007/BF02027723. PMID 24226247. S2CID 26026064.
  13. ^ a b Bogner, Franz; Thomas Eisner (1991). "Chemical basis of egg cannibalism in a caterpillar (Utetheisa ornatrix)". Journal of Chemical Ecology. 17 (11): 2063–2075. doi:10.1007/BF00987992. PMID 24258590. S2CID 23809889.
  14. ^ Hare, James F.; Thomas Eisner (1995). "Cannibalistic caterpillars: (Utetheisa Ornatrix; Lepidoptera: Arctiidae) fail to differentiate between eggs on the basis of kinship". Psyche: A Journal of Entomology. 102 (1–2): 27–33. doi:10.1155/1995/84147.
  15. ^ Walsh, Justin; Vikram Iyengar (2015). "Win,lose, or draw: Effects of size, sex, and kinship on high-stakes larval contests in a moth". Ethology. 121 (8): 733–739. doi:10.1111/eth.12388.
  16. ^ a b c d e f g LaMunyon, Craig; Thomas Eisner (1993). "Postcopulatory sexual selection in an arctiid moth (Utetheisa ornatrix)". Proceedings of the National Academy of Sciences. 90 (10): 4689–4692. doi:10.1073/pnas.90.10.4689. PMC 46578. PMID 8506319.
  17. ^ a b c d Lamunyon, Craig (1997). "Increased Fecundity, as a Function of Multiple Mating, in an Arctiid Moth, Utetheisa Ornatrix". Ecological Entomology. 22 (1): 69–73. doi:10.1046/j.1365-2311.1997.00033.x. S2CID 83564622.
  18. ^ a b c d e Iyengar, Vikram K.; Thomas Eisner (1999). "Female Choice Increases Offspring Fitness in an Arctiid Moth (Utetheisa Ornatrix)". Proceedings of the National Academy of Sciences. 96 (26): 15013–15016. doi:10.1073/pnas.96.26.15013. PMC 24764. PMID 10611329.
  19. ^ a b c Bezzerides, Alexander; Thomas Eisner (2002). "Apportionment of Nuptial Alkaloidal Gifts by a Multiply-mated Female Moth (Utetheisa Ornatrix): Eggs Individually Receive Alkaloid from More than One Male Source". Chemoecology. 12 (4): 213–218. doi:10.1007/pl00012671. ISSN 0937-7409. S2CID 45791334.
  20. ^ a b c d e f g Conner, W. E.; B. Roach; E. Benedict; J. Meinwald; T. Eisner (1990). "Courtship Pheromone Production and Body Size as Correlates of Larval Diet in Males of the Arctiid Moth,Utetheisa Ornatrix". Journal of Chemical Ecology. 16 (2): 543–52. doi:10.1007/BF01021785. PMID 24263510. S2CID 22175859.
  21. ^ Conner, William E.; Thomas Eisner; Robert K. Vander Meer; Angel Guerrero; Dario Ghiringelli; Jerrold Meinwald (1979). "Sex attractant of an arctiid moth (Utetheisa ornatrix): A pulsed chemical signal". Behavioral Ecology and Sociobiology. 7 (1): 55–63. doi:10.1007/BF00302519. S2CID 42239375.
  22. ^ a b Conner, William E.; Thomas Eisner; Robert K. Vander Meer; Angel Guerrero; Jerrold Meinwald (1981). "Precopulatory Sexual Interaction in an Arctiid Moth (Utetheisa ornatrix): Role of a Pheromone Derived from Dietary Alkaloids". Behavioral Ecology and Sociobiology. 9 (3): 227–235. doi:10.1007/BF00302942. JSTOR 4599437. S2CID 22839356.
  23. ^ Iyengar, Vikram K.; Hudson K. Reeve (2010). "Z linkage of female promiscuity genes in the moth Utetheisa ornatrix: support for the sexy-sperm hypothesis?". Evolution. 64 (5): 1267–1272. doi:10.1111/j.1558-5646.2009.00910.x. PMID 20002164. S2CID 43028766.
  24. ^ a b c d Rossini, Carmen; Andres Gonzalez; Thomas Eisner (2001). "Fate of an alkaloidal nuptial gift in the moth Utetheisa ornatrix: systemic allocation for defense of self by the receiving female". Journal of Insect Physiology. 47 (6): 639–647. doi:10.1016/S0022-1910(00)00154-2. PMID 11249953.
  25. ^ a b c d e f g h i j k Lim, Hangkyo; Michael D. Greenfielda (2007). "Female pheromonal chorusing in an arctiidmoth, Utetheisa ornatrix". Behavioral Ecology. 18 (1): 165–173. doi:10.1093/beheco/arl069.
  26. ^ a b Lim, Hangkyo; Kye Chung Park; Thomas C. Baker; Michael D. Greenfield (2007). "Perception of Conspecific Female Pheromone Stimulates Female Calling in an Arctiid Moth, Utetheisa ornatrix". J Chem Ecol. 33 (6): 1257–1271. doi:10.1007/s10886-007-9291-4. PMID 17435986. S2CID 1773649.
  27. ^ a b Iyengar, Vikram K.; Carmen Rossini; Thomas Eisner (2001). "Precopulatory Assessment of Male Quality in an Arctiid Moth ( Utetheisa Ornatrix ): Hydroxydanaidal Is the Only Criterion of Choice". Behavioral Ecology and Sociobiology. 49 (4): 283–288. doi:10.1007/s002650000292. JSTOR 4601888. S2CID 6393340.
  28. ^ a b Iyengar, Vikram K.; H. Kern Reeve; Thomas Eisner (2002). "Paternal Inheritance of a Female Moth's Mating Preference". Nature. 419 (6909): 830–832. doi:10.1038/nature01027. PMID 12397356. S2CID 4417181.
  29. ^ a b c d Dussourd, DE; Ubik K; Harvis C; Resch J; Meinwald J; Eisner T (1988). "Biparental Defensive Endowment of Eggs with Acquired Plant Alkaloid in the Moth Utetheisa Ornatrix". Proceedings of the National Academy of Sciences. 85 (16): 5992–5996. doi:10.1073/pnas.85.16.5992. PMC 281891. PMID 3413071.
  30. ^ a b c Gonzalez, Andres; Carmen Rossini; Maria Eisner; Thomas Eisner (1999). "Sexually Transmitted Chemical Defense in a Moth (Utetheisa Ornatrix)". Proceedings of the National Academy of Sciences. 96 (10): 5570–5574. doi:10.1073/pnas.96.10.5570. PMC 21901. PMID 10318925.
  31. ^ a b c Prakash, Arungundrum; Tamara N Pereira; Paul E.B. Reilly; Alan Seawright (1999). "Pyrrolizidine alkaloids in human diet". Mutation Research/Genetic Toxicology and Environmental Mutagenesis. 445 (1–2): 53–67. doi:10.1016/S1383-5742(99)00010-1. PMID 10415431.

External links edit

  Media related to Utetheisa ornatrix at Wikimedia Commons

  • eNature.com
  • UK Moths

January 01, 1970
utetheisa, ornatrix, also, called, ornate, bella, moth, ornate, moth, bella, moth, rattlebox, moth, moth, subfamily, arctiinae, aposematically, colored, ranging, from, pink, orange, yellow, white, coloration, with, black, markings, arranged, varying, patterns,. Utetheisa ornatrix also called the ornate bella moth ornate moth bella moth or rattlebox moth is a moth of the subfamily Arctiinae It is aposematically colored ranging from pink red orange and yellow to white coloration with black markings arranged in varying patterns on its wings It has a wingspan of 33 46 mm Moths reside in temperate midwestern and eastern North America as well as throughout Mexico and other parts of Central America Unlike most moths the bella moth is diurnal Formerly the bella moth or beautiful utetheisa of temperate eastern North America was separated as Utetheisa bella Now it is united with the bella moth in Utetheisa ornatrix Utetheisa ornatrix Scientific classification Domain Eukaryota Kingdom Animalia Phylum Arthropoda Class Insecta Order Lepidoptera Superfamily Noctuoidea Family Erebidae Subfamily Arctiinae Tribe Arctiini Subtribe Callimorphina Genus Utetheisa Species U ornatrix Binomial name Utetheisa ornatrix Linnaeus 1758 Synonyms Phalaena ornatrix Linnaeus 1758 Utetheisa bella Linnaeus 1758 Deiopeia ornatrix var stretchii Butler 1877 Deiopeia pura Butler 1877 Deiopeia ornatrix var daphoena Dyar 1914 Deiopeia ornatrix var butleri Dyar 1914 Phalaena Tinea bella Linnaeus 1758 Euprepia venusta Dalman 1823 Deiopeia speciosa Walker 1854 Deiopeia ornatrix var hybrida Butler 1877 Deiopeia bella var intermedia Butler 1877 Utetheisa bella var terminalis Neumoegen amp Dyar 1893 Utetheisa nova J B Smith 1910 The larvae usually feed on Crotalaria species which contain poisonous alkaloid compounds that render them unpalatable to most predators Larvae may prey on other bella moth larvae in order to compensate for any alkaloid deficiency The bella moth also demonstrates complex mating strategies and is thus an excellent model to study sexual selection Females mate multiply and receive spermatophores containing sperm nutrients and alkaloid compounds from numerous males as nuptial gifts Females choose males according to the intensity of a courtship pheromone hydroxydanaidal and carry out a sperm selection process after copulation with various males Contents 1 Distribution 2 Taxonomy 2 1 Subspecies 3 Description 3 1 Eggs 3 2 Larvae 3 3 Pupae 3 4 Adult 4 Predation 4 1 Cannibalism 4 2 Kin recognition 5 Mating 5 1 Mating system 5 2 Courtship 5 3 Female pheromonal chorusing 6 Sexual selection 6 1 Precopulatory 6 2 Postcopulatory 7 Parental investment 7 1 Spermatophore 8 Host plants 9 Pyrrolizidine alkaloids and humans 10 References 11 External linksDistribution editUtetheisa ornatrix is found from southeastern United States to South America southeast Brazil In the southeastern United States its distribution ranges from Connecticut westward to southeastern Nebraska and southward to southern New Mexico and Florida 1 This species is found to be more common in more tropical parts of this range in accordance to the availability of its host plant in more southern regions 1 It is also found throughout Mexico South America and Central America 2 Taxonomy editIn 1758 Carl Linnaeus first characterized two species of the genus Phalaena Phalaena ornatrixwas used to describe the paler moth specimens and Utetheisa bella described the bright pink moth specimens 3 In 1819 Hubner moved these species to a new genus Utetheisa 4 For nearly a century it was difficult to determine this moth s evolutionary history as researchers focused on external similarities color shape patterns size rather than determining features specific to the species This led to great confusion when trying to categorize the different subspecies 4 In 1960 Forbes combined both species Utetheisa ornatrix and Utetheisa bella into the species now known as Utetheisa ornatrix 4 His conclusion was also supported by Pease Jr who in 1966 used genetic testing and determined that any phenotypic differences were based on interspecific variation due to geographic differences rather than intraspecific variation 4 Subspecies edit Utetheisa ornatrix ornatrix Utetheisa ornatrix bella Linnaeus 1758 Utetheisa ornatrix saintcroixensis Pease 1973Description edit nbsp On rattlebox blossom Crotalaria sp Eggs edit The eggs of the Utetheisa ornatrix are spherical in shape and range in colour from white to yellow to sometimes brown 1 Larvae edit The larvae are orange and brown with irregular black bands on each segment of the body The anterior and posterior portions of the black binds are also marked with distinct white spots Full grown larvae reach 30 35mm in length Although most arctiid larvae have verrucae Utetheisa ornatrix larvae lack these 1 Pupae edit The pupae are mostly black marked with irregular orange and brown bands Usually the pupae are covered with a loose layer of silk 1 Adult edit These moths are aposematic and use their bright coloration to warn predators of their unpalatability Their wings range in color from yellow red pink and orange to white 2 Wings contain white bands containing six bands of irregularly spaced black spots 5 The hind wings can be bright pink with a marginal black band The adult Utetheisa ornatrix has a wingspan of 33 to 46 millimetres 1 3 to 1 8 in 2 Predation edit nbsp Mature pods of the rattlepod Crotalaria retusa During the larval stages caterpillars feed on leguminous plants of the genus Crotalaria 6 These plants contain large amounts of toxins particularly pyrrolizidine alkaloids PAs which are found in high concentrations in the seeds 6 Bella moth caterpillars sequester these toxins and use them as a deterrent for predators 6 When the adult is disturbed they secrete a foam containing the toxins from their head which makes them unpalatable to predators Since PAs are an extremely valuable resource individual larvae compete with one another to colonize an entire pod an elongated seed containing pouch from the food plant 7 Larvae that are unable to take ownership of a pod must obtain the chemicals from leaves where they are found at much lower densities These caterpillars sequester smaller amounts of PAs and are more susceptible to predation 7 Although it is beneficial to feed on seeds larvae do not enter the pods immediately after they hatch 8 During the first larval instars caterpillars feed on leaves and it is not until the second or third instar that they enter the pods 8 The evolutionary benefits of this strategy are not understood 8 When caterpillars metamorphose into adult moths they carry the alkaloids with them which continue to protect them during the adult stage 6 PAs render the bella moth unpalatable to many of its natural enemies like spiders and insectivorous bats 9 10 Spiders that capture bella moth larvae or adults release them soon after leaving them unharmed 10 In contrast bella moth individuals grown on a PA free diet are readily preyed on by spiders 10 Similarly bats that catch bella moth individuals quickly release these unpalatable moths without harming them 9 Unlike other moths of the Arctiidae the bella moth does not possess an acoustic aposematism system that would enable it to avoid bats altogether 9 Bella moth larvae and some predators like loggerhead shrikes are not negatively affected by PAs 6 The bella moth is able to detoxify PAs due to the possession of the gene pyrrolizidine alkaloid N oxygenase 11 It has been experimentally shown that bella moth larvae upregulate the expression of this gene when the amount of PAs in their diet increases 11 In addition it has been shown that PA rich diets do not have a negative effect on the fitness of these moths 11 but only affect time of development which increases with increasing PA concentration in diet 11 However caterpillars with longer development times reach similar pupal sizes compared to those with shorter developmental times due to diets containing smaller amounts of PAs 11 Cannibalism edit On occasion bella moth caterpillars cannibalize other eggs pupae or larvae from the same species 12 Since PAs are a limited resource some caterpillars do not reach optimal levels and resort to cannibalism 13 This behavior is a consequence of PA deficiency rather than hunger since deficits in alkaloids are the main cause of mortality 12 Pupae cannibalism is rare because larvae normally pupate far away from the plant where they feed 12 Egg cannibalism is also rare because eggs provide larvae with very small quantities of PAs 13 and because eggs from the same cluster hatch synchronously 14 Larvae may also feed on other bella moth larvae that are laden with alkaloids 12 This is more common since feeding on one single larva is sufficient to compensate for the cannibalistic caterpillar s alkaloid deficiency 12 Kin recognition edit Bella moth caterpillars may have the ability to recognize other larvae as kin as larvae are less likely to intrude upon siblings than non siblings established in seedpods 15 Mating editBella moths of both sexes use very complex reproductive strategies making this species an excellent model system for studying sexual selection 7 Females mate multiply over their three to four week lifespan as adults 7 They mate with an average of three to four males each of whom provides her with a nuptial gift a spermatophore containing sperm nutrients and alkaloids 7 Adult males invest up to 11 of their body mass to create a spermatophore they provide to a female during mating 7 The nutrients given in the spermatophore allow the female to produce on average an additional 32 eggs 16 Mating system edit The bella moth presents a polyandrous mating system where females mate with multiple males 17 On average females mate with four to five males over their lifespan of three to four weeks but can mate with and receive up to thirteen spermatophores 17 Since spermatophores contain nuptial gifts of pyrrolizidine alkaloid PA and nutrients multiple mating helps the female increase the fitness of her offspring 17 In addition multiple mating also benefits the female directly Since the spermatophores are sizeable and can be digested within the female multiple mating allows females to accrue the resources necessary to build additional eggs 17 This is equivalent to a 15 increase in egg production 18 In addition multiple mating results in increased transmission of alkaloidal gifts to eggs 19 However this does not mean that there is segregated allocation of these gifts Instead the PA obtained from numerous males is allocated in admixture so that eggs tend to receive from more than one male source 19 In contrast normally most of the sperm used to fertilize the eggs comes from a single male 16 Courtship edit Courtship begins at dusk 20 Stationary females release a sexual pheromone that lures males 20 They emit these chemicals in short pulses to provide close range orientation cues to male moths as they seek out the females 21 When a male reaches a female he flutters around her and thrusts two peculiar tufts of scales from his coremata two yellow spherical structures by the male s genital organs 6 22 By doing so the male emits a specific scent from his coremata that is attributed to a pheromone hydroxydanaidal 20 After receiving the scent the female proceeds to mating 22 Copulation lasts for up to 12 hours 23 It takes the male about two hours to transfer the spermatophore containing all of the sperm and nutrients he is going to offer to the female 24 The remaining hours of copulation are exclusively used for alkaloid transfer 24 These alkaloids distribute themselves evenly around the female body even the wings and offer her great protection as they render her unpalatable to most predators 24 Eventually the female allocates about one third of the alkaloids she receives to her ovaries where they will be used to confer protection to the eggs 24 Female pheromonal chorusing edit Bella moth mating behavior is exceptional in that females compete with other females to obtain more males as opposed to males competing with males 25 As in many other moth species females release sexual pheromones that males can detect over long distances 25 However in most species females do not interact with one another during pheromone release 25 Female bella moths are unique in that females from the same family often engage in collective pheromone release termed female pheromonal chorusing 25 This phenomenon is a consequence of a female biased operational sex ratio This means that at any given time there are more females than males seeking to copulate 25 This occurs because males lose up to 11 of their body mass during mating and once they are done mating they need time to sequester resources that will allow them to deliver a spermatophore to the next female they mate with 25 On the contrary females do not need time to prepare for their next copulation 25 Due to the unequal mating rates males become valuable to females and female to female competition rises dramatically as a consequence 25 Engaging in pheromonal chorusing allows females to increase the attractiveness of genetic relatives and increase their indirect fitness 25 Females may also but less frequently engage in female chorusing with unrelated females 25 It has been suggested that chorusing is still beneficial under these circumstances because cooperation for pheromone release may increase the attractiveness of the entire group and increase each moth s individual fitness 25 It has been experimentally shown that when females detect other female pheromones they increase the rate of pheromone release and call for longer periods of time 26 Such observations support the hypothesis that females cooperate with one another to increase mating success 26 Sexual selection editPrecopulatory edit Although most female moths mate multiply very low instances of mixed paternities occur 16 In fact most progeny in a single clutch is sired exclusively by one male 16 Females of this species do not select based on age mating order between mating interval or duration of copulation 16 Instead female Utetheisa ornatix demonstrate female choice in mate selection that depends on body size systemic content of defensive pyrrolizidine alkaloid and glandular content of the courtship pheromone hydroxydanaidal 27 Selecting for these males provides the females with multiple benefits such as obtaining sperm packages with more defensive pyrrolizidine alkaloids which results in larger offspring 18 Offspring fathered by larger males are generally less vulnerable to predation because of their higher alkaloid content allowing the offspring to have higher viability and fitness 18 Larger males with the highest alkaloid content can be distinguished by a specific pheromonal scent that predicts the content of the alkaloidal gifts hydroxydanaidal HD 20 There is a relationship between the size of the male the type of food the males fed on as larvae and the composition of its spermatophores 20 For example males that fed inside a seed pod rather than on leaves produce higher levels of HD 20 In addition these males have higher adult weights and have higher systemic loads of PA the metabolic precursor of HD 20 By selecting for HD rich males the female moth ensures the receipt of a large alkaloid gift phenotypic benefit and genes that encode for large size genetic benefit 27 The female s mating preference is inherited paternally since the preference gene or genes lie mostly or exclusively on the Z sex chromosome 28 The preferred male trait and the female preference for the trait are strongly correlated females with larger fathers have a stronger preference for larger males 28 Postcopulatory edit After copulating with several males rival sperm carried by a female do not compete directly for access to the eggs 16 Females direct a postcopulatory selective process where they choose male sperm based on the intensity of the courtship pheromone that was released prior to copulation hydroxydanaidal HD 7 The intensity of this signal is directly proportional to the amount of alkaloids sequestered by the moth during the larval stages 7 As a consequence this pheromone is an indirect indicator of success during larval development and will ultimately determine which sperm will be passed on to the offspring 7 Once they have selected a male females use their musculature to channel the selected sperm through the chambers and constructs of their reproductive systems to their eggs 16 Parental investment editThe eggs of the bella moth contain pyrrolizidine alkaloids PAs that the mother delivers 29 The alkaloid is stored during the larval stages and retained through metamorphosis protecting both larvae and adults from predators 29 Female moths receive alkaloids from the males at the time of mating as part of the spermatophore 29 Although the male s contribution of PAs is less than that of the female it still contributes significantly to egg protection 29 Spermatophore edit The spermatophore that males give to the females when mating contains sperm nutrients and pyrrolizidine alkaloids PA and accounts for up to 11 of the male s body mass 18 PA plays an important role in preventing predation in Utetheisa ornatrix because it is poisonous to most organisms Males transmit PA to the females via a sperm package the females then give this mating gift to the eggs 30 along with their own alkaloidal supplement and is utilized to protect the offspring from predation 18 In addition females also personally benefit from the gift through protection and nutrition After mating with a PA rich male the received PA is quickly allocated to all body parts 30 As a result females become and remain unacceptable as prey to numerous organisms such as spiders 30 Another problem that females face is the risk of incurring a PA deficit due to the large amount of eggs they lay Spermatophores is one way for females to compensate for this loss in PA 19 Host plants edit nbsp Crotalaria pallida Plants of the genus Crotalaria are the major hosts for the Utetheisa ornatrix although a variety of plants in the family Fabaceae have also been cited in literature 1 The word Crotalaria originates from the Greek root crotal which means a rattle and is characteristic of the pods found on these plants 1 The Crotalaria host plants contain pyrrolizidine alkaloids which are used by the Utetheisa ornatrix to repel predators 1 Specific host plants used include Crotalaria avonensis Avon Park rattlebox Crotalaria rotundifolia rabbitbells Crotalaria lanceolata Crotalaria pallida smooth rattlebox Crotalaria spectabilis showy rattlebox Crotalaria retusa 1 Pyrrolizidine alkaloids and humans editPyrrolizidine alkaloids PAs are the toxins the bella moth is able to ingest and use for protection from predators 1 They are known to be the principal toxins found in plants that can cause disease in humans and other animals 31 Reported pathways for human exposure include crop contamination milk and honey contamination and some traditional herbal medicines 31 Once ingested the alkaloids affect mainly the liver and the lungs Human poisoning can cause veno occlusive disease and teratogenicity 31 References edit a b c d e f g h i j Utetheisa Ornatrix Entomology and Nemotology University of Florida n d Web 14 Nov 2013 a b c Sourakov Andrei Logan M Locascio 2013 Exotic Crotalaria Species Fabales Fabaceae as Host Plants of the Ornate Bella Moth Utetheisa ornatrix Lepidoptera Erebidae in Florida Laboratory Biology Florida Entomologist 96 2 344 350 doi 10 1653 024 096 0254 Majik Phil Bella Moth Retrieved 17 November 2013 a b c d DaCosta Michelle Antoinette 2007 Phylogenetic Studies of Utetheisa Hubner the Rattle Box Moth and Other Arctiines Lepidoptera Noctuoidea Arctiidae ISBN 978 0 549 11380 5 Ornate Bella Moth Missouri Department of Conservation Missouri Department of Conservation Retrieved 15 January 2023 a b c d e f Conner W E 2009 Tiger Moths and Woolly Bears behaviour ecology and evolution of the Arctiidae New York Oxford University Press pp 1 10 a b c d e f g h i Kellya Caitlin A Amanda J Norbutusb Anthony F Lagalanteb Vikram K Iyengara 2012 Male courtship pheromones as indicators of genetic quality in an arctiid moth Utetheisa ornatrix Behavioral Ecology 23 5 1009 1014 doi 10 1093 beheco ars064 a b c Gianluppi Ferro Viviane Paulo Roberto Guimaraes Jr Jose Roberto Trigo 2006 Why do larvae of Utetheisa ornatrix penetrate and feed in pods of Crotalaria species Larval performance vs chemical and physical constraints Entomologia Experimentalis et Applicata 121 1 23 29 doi 10 1111 j 1570 8703 2006 00450 x S2CID 49541027 a b c Hristov Nickolay I William E Conner 2005 Sound strategy acoustic aposematism in the bat tiger moth arms race Naturwissenschaften 92 4 164 169 doi 10 1007 s00114 005 0611 7 PMID 15772807 S2CID 18306198 a b c Eisner Thomas Maria Eisner 1991 Unpalatability of the pyrrolizidine alkaloid containing moth Utetheisa ornatrix and its larva to wolf spiders Psyche A Journal of Entomology 98 111 118 doi 10 1155 1991 95350 a b c d e Cogni Rodrigo Jose R Trigo Douglas J Futuyma 2012 A free lunch No cost for acquiring defensive plant pyrrolizidine alkaloids in a specialist arctiid moth Utetheisa ornatrix Molecular Ecology 21 24 6152 6162 doi 10 1111 mec 12086 PMID 23110459 S2CID 25612129 a b c d e Bogner Franz X 1996 Interspecific advantage results in intraspecific disadvantage chemical protection versus cannibalism in Utetheisa ornatrix Journal of Chemical Ecology 22 8 1439 1451 doi 10 1007 BF02027723 PMID 24226247 S2CID 26026064 a b Bogner Franz Thomas Eisner 1991 Chemical basis of egg cannibalism in a caterpillar Utetheisa ornatrix Journal of Chemical Ecology 17 11 2063 2075 doi 10 1007 BF00987992 PMID 24258590 S2CID 23809889 Hare James F Thomas Eisner 1995 Cannibalistic caterpillars Utetheisa Ornatrix Lepidoptera Arctiidae fail to differentiate between eggs on the basis of kinship Psyche A Journal of Entomology 102 1 2 27 33 doi 10 1155 1995 84147 Walsh Justin Vikram Iyengar 2015 Win lose or draw Effects of size sex and kinship on high stakes larval contests in a moth Ethology 121 8 733 739 doi 10 1111 eth 12388 a b c d e f g LaMunyon Craig Thomas Eisner 1993 Postcopulatory sexual selection in an arctiid moth Utetheisa ornatrix Proceedings of the National Academy of Sciences 90 10 4689 4692 doi 10 1073 pnas 90 10 4689 PMC 46578 PMID 8506319 a b c d Lamunyon Craig 1997 Increased Fecundity as a Function of Multiple Mating in an Arctiid Moth Utetheisa Ornatrix Ecological Entomology 22 1 69 73 doi 10 1046 j 1365 2311 1997 00033 x S2CID 83564622 a b c d e Iyengar Vikram K Thomas Eisner 1999 Female Choice Increases Offspring Fitness in an Arctiid Moth Utetheisa Ornatrix Proceedings of the National Academy of Sciences 96 26 15013 15016 doi 10 1073 pnas 96 26 15013 PMC 24764 PMID 10611329 a b c Bezzerides Alexander Thomas Eisner 2002 Apportionment of Nuptial Alkaloidal Gifts by a Multiply mated Female Moth Utetheisa Ornatrix Eggs Individually Receive Alkaloid from More than One Male Source Chemoecology 12 4 213 218 doi 10 1007 pl00012671 ISSN 0937 7409 S2CID 45791334 a b c d e f g Conner W E B Roach E Benedict J Meinwald T Eisner 1990 Courtship Pheromone Production and Body Size as Correlates of Larval Diet in Males of the Arctiid Moth Utetheisa Ornatrix Journal of Chemical Ecology 16 2 543 52 doi 10 1007 BF01021785 PMID 24263510 S2CID 22175859 Conner William E Thomas Eisner Robert K Vander Meer Angel Guerrero Dario Ghiringelli Jerrold Meinwald 1979 Sex attractant of an arctiid moth Utetheisa ornatrix A pulsed chemical signal Behavioral Ecology and Sociobiology 7 1 55 63 doi 10 1007 BF00302519 S2CID 42239375 a b Conner William E Thomas Eisner Robert K Vander Meer Angel Guerrero Jerrold Meinwald 1981 Precopulatory Sexual Interaction in an Arctiid Moth Utetheisa ornatrix Role of a Pheromone Derived from Dietary Alkaloids Behavioral Ecology and Sociobiology 9 3 227 235 doi 10 1007 BF00302942 JSTOR 4599437 S2CID 22839356 Iyengar Vikram K Hudson K Reeve 2010 Z linkage of female promiscuity genes in the moth Utetheisa ornatrix support for the sexy sperm hypothesis Evolution 64 5 1267 1272 doi 10 1111 j 1558 5646 2009 00910 x PMID 20002164 S2CID 43028766 a b c d Rossini Carmen Andres Gonzalez Thomas Eisner 2001 Fate of an alkaloidal nuptial gift in the moth Utetheisa ornatrix systemic allocation for defense of self by the receiving female Journal of Insect Physiology 47 6 639 647 doi 10 1016 S0022 1910 00 00154 2 PMID 11249953 a b c d e f g h i j k Lim Hangkyo Michael D Greenfielda 2007 Female pheromonal chorusing in an arctiidmoth Utetheisa ornatrix Behavioral Ecology 18 1 165 173 doi 10 1093 beheco arl069 a b Lim Hangkyo Kye Chung Park Thomas C Baker Michael D Greenfield 2007 Perception of Conspecific Female Pheromone Stimulates Female Calling in an Arctiid Moth Utetheisa ornatrix J Chem Ecol 33 6 1257 1271 doi 10 1007 s10886 007 9291 4 PMID 17435986 S2CID 1773649 a b Iyengar Vikram K Carmen Rossini Thomas Eisner 2001 Precopulatory Assessment of Male Quality in an Arctiid Moth Utetheisa Ornatrix Hydroxydanaidal Is the Only Criterion of Choice Behavioral Ecology and Sociobiology 49 4 283 288 doi 10 1007 s002650000292 JSTOR 4601888 S2CID 6393340 a b Iyengar Vikram K H Kern Reeve Thomas Eisner 2002 Paternal Inheritance of a Female Moth s Mating Preference Nature 419 6909 830 832 doi 10 1038 nature01027 PMID 12397356 S2CID 4417181 a b c d Dussourd DE Ubik K Harvis C Resch J Meinwald J Eisner T 1988 Biparental Defensive Endowment of Eggs with Acquired Plant Alkaloid in the Moth Utetheisa Ornatrix Proceedings of the National Academy of Sciences 85 16 5992 5996 doi 10 1073 pnas 85 16 5992 PMC 281891 PMID 3413071 a b c Gonzalez Andres Carmen Rossini Maria Eisner Thomas Eisner 1999 Sexually Transmitted Chemical Defense in a Moth Utetheisa Ornatrix Proceedings of the National Academy of Sciences 96 10 5570 5574 doi 10 1073 pnas 96 10 5570 PMC 21901 PMID 10318925 a b c Prakash Arungundrum Tamara N Pereira Paul E B Reilly Alan Seawright 1999 Pyrrolizidine alkaloids in human diet Mutation Research Genetic Toxicology and Environmental Mutagenesis 445 1 2 53 67 doi 10 1016 S1383 5742 99 00010 1 PMID 10415431 External links edit nbsp Media related to Utetheisa ornatrix at Wikimedia Commons eNature com UK Moths Retrieved from https en wikipedia org w index php title Utetheisa ornatrix amp oldid 1213052881, wikipedia, wiki, book, books, library,

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