Heloderma Explained

Heloderma is a genus of toxicoferan lizards that contains five species, all of which are venomous.[1] It is the only extant genus of the family Helodermatidae.

Description

The genus Heloderma contains the Gila monster (H. suspectum) and four species of beaded lizards. Their eyes are immobile and fixed in their head.[2] [3] The Gila monster is a large, stocky, most of the time slow-moving reptile that prefers arid deserts. Beaded lizards are seen to be more agile and seem to prefer more humid surroundings.[4] [5] The tails of all species of Heloderma are used as fat storage organs. The scales of the head, back and tail are bead-like, containing osteoderms for better protection. The scales of the belly are free from osteoderms. Most species are dark in color, with yellowish or pinkish markings.[6] [7]

Venom

The venom glands of Heloderma are located at the end of the lower jaws, unlike snakes' venom glands, which are located behind the eyes. Also, unlike snakes, the Gila monster and beaded lizards lack the musculature to inject venom immediately. They have to chew the venom into the flesh of a victim. Heloderma venom is used only in defense. Venom glands are believed to have evolved early in the lineage leading to the modern helodermatids, as their presence is indicated even in the 65-million-year-old fossil genus Paraderma.[7] [8] In general, one adult helodermatid has approximately 15 to 20 mg of venom, while the estimated lethal dose for humans is 5 to 8 mg.[9]

Diet

Helodermatids are carnivorous, preying on rodents and other small mammals, and eating the eggs of birds and reptiles.

Reproduction

All species of Heloderma are oviparous. The Gila monster typically lays 6 eggs, the beaded lizards up to about 18 eggs . Comparing the different species, all eggs have a similar size, and the same holds true for their hatchlings.

Taxonomy

Family Helodermatidae

The four subspecies of beaded lizards, elevated to full species in 2013, are:[10]

ImageSpeciesTaxon authorCommon nameGeographic range
H. alvareziBogert and Martin del Campo, 1956Chiapan beaded lizardMexico

northern Chiapas to extreme northwestern Guatemala

H. charlesbogertiTCampbell and Vannini, 1988Guatemalan beaded lizardGuatemala

the Motagua Valley

H. exasperatumBogert and Martin del Campo, 1956Rio Fuerte beaded lizardMexico

Rio Fuerte, Rio Mayo, southern Sonora, northern Sinaloa, western Chihuahua and the Sierra Madre Occidental

H. horridumT(Wiegmann, 1829)Mexican beaded lizardMexico

southern Sinaloa to Oaxaca

Members of the genus Heloderma have many extinct relatives in the Helodermatidae whose evolutionary history may be traced back to the Cretaceous period, such as Estesia. The genus Heloderma has existed since the Miocene, when H. texana lived, and fragments of osteoderms from the Gila monster have been found in late Pleistocene (8,000-10,000 years ago) deposits near Las Vegas, Nevada. Because the helodermatids have remained relatively unchanged morphologically, they are occasionally regarded as living fossils.[11] Although the beaded lizards and the Gila monster appear closely related to the monitor lizards (varanids) of Africa, Asia, and Australia, the wide geographical separation and unique features not found in the varanids indicates they are better placed in a separate family.[12] The type species is Heloderma horridum, which was first described in 1829 by Arend Wiegmann. Although he originally assigned it the generic name Trachyderma, he changed it to Heloderma six months later, which means "studded skin", from the Ancient Greek words hêlos (ηλος) - the head of a nail or stud - and derma (δερμα), meaning skin.[13]

Conrad, 2008 and Estes et al., 1988 (using morphological data) places Helodermatidae within Varanoidea along with Lanthanotus borneensis and Varanus.[14] [15] However, Estes et al., 1988 understood Helodermatidae as having split earlier from Lanthanotus and Varanus, whereas Conrad, 2008 groups them at the same branch point.

In contrast, molecular studies have identified Heloderma as being within Anguioidea along with Anguidae and Xenosauridae, but specifically sister to Anguidae.[16] [17]

Venom

Venom production among lizards was long thought to be unique to this genus, but researchers studying venom production have proposed many others also produce some venom, all placed in the clade Toxicofera, which includes all snakes and 13 other families of lizards.[18] However, except for snakes, helodermatids, and possibly varanids, envenomation is not considered medically significant for humans

In captivity

H. horridum, H. exasperatum, and H. suspectum are frequently found in captivity and are well represented in zoos throughout much of the world. The other two species of Heloderma, H. alvarezi and H. charlesbogerti, are extremely rare, and only a few captive specimens are known.

Notes

External links

Schwandt, Hans- Joachim www.heloderma.net 2006 in 6 languages

Further reading

Wikispecies has information related to Heloderma suspectum

Notes and References

  1. Web site: POISINDEX(R) TOXICOLOGIC MANAGEMENTS Topic: GILA MONSTER (HELODERMA SUSPECTUM).
  2. Book: Wild and Exotic Animal Ophthalmology: Volume 1: Invertebrates, Fishes, Amphibians, Reptiles, and Birds. Fabiano. Montiani-Ferreira. Bret A.. Moore. Gil. Ben-Shlomo. April 27, 2022. Springer Nature. 978-3-030-71302-7 . Google Books.
  3. Book: Fischbarg, Jorge. The Biology of the Eye. December 9, 2005. Elsevier. 978-0-08-047609-4 . Google Books.
  4. C. M. Bogert, R. M. Del Campo. 1956. The Gila Monster and its Allies. The relationships, habits, and behavior of the lizards of the family Helodermatidae. Bulletin of the American Museum of Natural History. 109. 1–238.
  5. Book: Beck, D. D.. Biology of Gila Monsters and Beaded Lizards. University Press of California. 2005.
  6. Book: Schwandt, Hans-Joachim. The Gila Monster Heloderma suspectum. Edition Chimaira. 2019. 978-3-89973-441-6. Frankfurt/Main.
  7. Book: Cogger, H.G. . Zweifel, R.G. . Bauer, Aaron M.. 1998. Encyclopedia of Reptiles and Amphibians. Academic Press. San Diego. 156. 0-12-178560-2.
  8. Richard L. Cifelli, Randall L. Nydam. 1995. Primitive, helodermatid-like platynotans from the Early cretaceous of Utah. Herpetologica. 51(3):286-291.
  9. Book: Dart, Richard C.. Medical Toxicology. 2004. Lippincott Williams & Wilkins. 978-0-7817-2845-4. en.
  10. http://www.redlist-arc.org/Article-PDFs/Special%20Mexico%20Issue_ARC_7(1)_74-96_low_res.pdf Reiserer & al., 2013, Taxonomic reassessment and conservation status of the beaded lizard, Heloderma horridum (Squamata: Helodermatidae)
  11. Book: King, Ruth Allen . Pianka, Eric R. . King, Dennis . Varanoid Lizards of the World . Indiana University Press . Bloomington . 2004 . 0-253-34366-6 .
  12. Book: Mattison, Chris . Lizards of the World . Blandford . London . 1998 . 0-7137-2357-2 . registration .
  13. Wiegmann. A.F.A.. Arend Friedrich August Wiegmann. Über die Gesetzlichkeit in der geographischen Verbreitung der Saurier. Isis. 22 . 3–4 . 418 - 428. Oken . 1829 .
  14. Conrad. Jack L.. Ast. Jennifer C.. Montanari. Shaena. Norell. Mark A.. 2011. A combined evidence phylogenetic analysis of Anguimorpha (Reptilia: Squamata). Cladistics. en. 27. 3. 230–277. 10.1111/j.1096-0031.2010.00330.x. 34875778. 84301257. 1096-0031. free.
  15. Estes. Richard. 1988. Phylogenetic relationships within squamata. Phylogenetic Relationships of the Lizard Families: Essays Commemorating Charles L. Camp. 119–281. 10088/6457. 9780804714358.
  16. Vidal. Nicolas. Marin. Julie. Sassi. Julia. Battistuzzi. Fabia U.. Donnellan. Steve. Fitch. Alison J.. Fry. Bryan G.. Vonk. Freek J.. Rodriguez de la Vega. Ricardo C.. Couloux. Arnaud. Hedges. S. Blair. 2012-10-23. Molecular evidence for an Asian origin of monitor lizards followed by Tertiary dispersals to Africa and Australasia. Biology Letters. 8. 5. 853–855. 10.1098/rsbl.2012.0460. 3441001. 22809723.
  17. Townsend. Ted M.. Larson. Allan. Louis. Edward. Macey. J. Robert. 2004-10-01. Molecular Phylogenetics of Squamata: The Position of Snakes, Amphisbaenians, and Dibamids, and the Root of the Squamate Tree. Systematic Biology. en. 53. 5. 735–757. 10.1080/10635150490522340. 15545252. 1063-5157. free.
  18. .Fry, B.. etal. February 2006. Early evolution of the venom system in lizards and snakes. Nature. 439. 7076. 584–588. 10.1038/nature04328. 16292255. 2006Natur.439..584F. 4386245.