Sunday, September 9, 2018

Venom resistance in kingsnakes

A kingsnake eating a rattlesnake
Kingsnakes get their name because they eat other snakes, including venomous snakes like copperheads, cottonmouths, and rattlesnakes. They also eat lots of other kinds of prey, including non-venomous snakes, lizards, turtle eggs, and small mammals.

You often hear people say that kingsnakes are resistant or immune to the venom of copperheads, cottonmouths, and rattlesnakes. There is a subtle difference between the meaning of these two words.

Resistance is any physiological ability to tolerate or counteract the effects of a toxin or disease. Like many things in biology, resistance is not an all-or-nothing status, but a gradient. High enough resistance can result in immunity, where the toxin or disease has negligible or no effects.

A kingsnake eating a cottonmouth
Individuals can acquire resistance through repeated exposure to low doses of a toxin. The immune system recognizes the toxin as foreign and attacks it. It forms a memory of each attack and stores the pattern for later, which makes later responses to the same toxin quicker and more effective. If the toxin dose is later increased, the memory is reinforced & may become stronger. This is how antivenom is made, how people become resistant to snake venom, and also how vaccines against infectious diseases work.1

It is not how kingsnake resistance to viper venom works. Kingsnake resistance is evolved rather than acquired. This means that kingsnakes are born resistant to venom. As far as we know, their resistance levels are fixed for life & don’t change with age or exposure. This has happened over a long time through natural selection, over many generations of kingsnakes. We don't actually have a very exact  understanding of the physiological and molecular mechanisms behind how kingsnakes resist the toxic effects of viper venom. At least some of their resistance comes from antibodies—chemicals in their blood that interfere with the venom—because mice injected with kingsnake blood survive viper venom better than those that aren't, and the chemical composition of kingsnake blood changes after exposure to viper venom.

A kingsnake eating a western hognose snake
Any time a weapon appears, there is potential for counter-weapons (i.e. resistance and immunity) to appear in response. This happens through a process called a co-evolutionary arms race2. Just as the United States and the Soviet Union were involved in an arms race centered around nuclear weapons during the Cold War, so are venomous snakes and their prey & predators involved in arms races centered around their primary weapon—venom.

A major difference is that, unlike nations or humans, animals cannot plan for the future and decide to invest more energy in research & development of novel or better weapons technology for future generations. Instead, co-evolutionary arms races happen through natural selection. What start out as tiny variations in toxin resistance can be magnified over many generations. 

A kingsnake and a copperhead biting one another
When vipers were first evolving their front fangs, defensive bites became a new option for them. At first, their predators were probably not very good at resisting the effects of the venom, especially if the predator’s physiology was similar to that of their prey, and venom would have made a very good defense mechanism. Vipers would sometimes be killed and eaten, but many predators later died from their bites. Kingsnake predators that were slightly better able to tolerate the effects of the venom were more likely to survive. Eventually, all the kingsnakes without these venom resistance traits had been killed by vipers that they tried to eat, and only the resistant ones remained. On the other side, vipers that had venom with toxins that were, for example, slightly more painful or fast-acting, might have been more likely to survive a predatory attack. Thus, the arms race escalates. Vipers also exhibit flipping, jerking, “body bridging” and other escape behaviors as a defense against kingsnakes—suggesting, since they do not try to bite kingsnakes in defense, that their venom is essentially useless as an anti-kingsnake defense mechanism by now and that kingsnakes have “won” this arms race.

A mongoose eating a boomslang
This is why kingsnakes are immune to the venom of copperheads, cottonmouths, and North American rattlesnakes, but not to the venom of, for example, king cobras or black mambas. Because they live on different continents, there has never been an opportunity for kingsnakes and black mambas to enter into a co-evolutionary arms race (although both prey and predators of black mambas in Africa, such as honey badgers, and of king cobras in India, such as mongeese, have probably accomplished much the same thing).

Kingsnakes also eat coralsnakes, but amazingly they are not immune to the venom of Eastern Coralsnakes (Micrurus fulvius)—kingsnakes injected with coralsnake venom die quickly, and kingsnake blood is 0% effective at neutralizing venom proteins from coralsnakes. Presumably they are able to catch and consume coralsnakes without getting bitten. This could be because coralsnakes often eat other snakes, so perhaps their venom is more difficult for kingsnakes to evolve resistance against. Or, perhaps coralsnakes are rare or dangerous prey for kingsnakes, and it’s possible but not worth it for them to evolve resistance.

A milksnake constricting a Dekay's brownsnake
Not every kingsnake species has been tested against every venom, but we do know that there is variation in which species are immune to which venoms. The only study to compare species in depth injected mice with mixtures of venom & snake blood and measured mouse symptoms and survival. They found that blood from Eastern Kingsnakes (Lampropeltis getula) had the widest spectrum of protection against the venoms tested and was the most effective at neutralizing many rattlesnake venoms, but the least effective against copperhead venom. Blood from kingsnakes from Florida & the Gulf Coast was the most effective at neutralizing the venom of copperheads & cottonmouths. Mole Kingsnake (Lampropeltis calligaster) blood is about 75% as effective at neutralizing Mojave Rattlesnake (Crotalus scutulatus) venom as the blood of Eastern Kingsnakes. Gray-banded Kingsnakes (L. alterna) have moderate neutralization potential against Western Diamondback (C. atrox) venom, but none against Eastern Diamondback (C. adamanteus) venom. Blood from milksnakes (formerly all called L. triangulum) from various locations had intermediate neutralization capacity, with blood from North American milksnakes being about 70% more effective against rattlesnake venom than blood from Central American milksnakes. Another study found that an eastern milksnake injected with copperhead venom died, and one injected with pigmy rattlesnake venom had "no noticeable ill effects", but a lack of replication prevents these results from being particularly meaningful. Somewhat surprisingly, blood from Long-nosed Snakes (Rhinocheilus lecontei), Cornsnakes (Pantherophis guttatus), Mussuranas (Clelia clelia), and Japanese Four-lined Ratsnakes (Elaphe quadrivirgata) was also effective at protecting mice from viper venoms, but blood from pinesnakes (Pituophis) and gartersnakes (Thamnophis) was not. Both vipers and elapids appear to have at least some level of resistance to their own venom, although detailed studies are lacking for most species.

Fight of the Mongoose and the Serpent Armies
An 1850 folio from the Mahabharata
Kingsnakes are just one of many species that have partial immunity or resistance to venom. Hedgehogs, skunks, opossums, and possibly snake-eagles also have resistance to viper venoms, and eels are resistant to sea krait venom. Unlike kingsnakes, we have actually figured out exactly which proteins in opossum blood are responsible for its snake venom neutralization capacity. We also know that mongeese have followed a different route, changing the shape of the toxin targets in their cells rather than putting molecules into their blood to combat the toxins (which means that their immunity cannot be transferred). Other predators of venomous snakes, such as indigo snakes (genus Drymarchon), appear to have gotten away with not evolving immunity, although I was unable to find any actual data on physiological responses of indigo snakes to venom, just statements saying they were not resistant, so it's possible that actual tests have not been carried out.

A mountain kingsnake constricting a skink
Opossum resistance to copperhead venom probably evolved in a similar way to kingsnake resistance, but vipers are also involved in co-evolutionary arms races with their prey. Many rodent prey of North American vipers are resistant, including wood rats, prairie voles, and ground squirrels. Think of how the U.S. during the Cold War had to balance foreign policy not just with the Soviet Union, but also with other nations. The emerging foreign policy is a compromise, just as the venom that evolves is a compromise of selection pressures from predators and prey. Resistant prey may select for venoms that are better at quickly incapacitating, whereas resistant predators may select for venoms that are less deadly and more painful; it’s difficult to predict exactly what will happen without knowing the exact mechanism of resistance. Sometimes selection from predators and prey may act in the same direction, other times in opposite directions. The details of these processes are what evolutionary biologists study on a day-to-day basis.



1 Creating a vaccine against snake venom is harder than creating one against an infectious disease that is caused by a virus or a bacterium. There are pit viper venom vaccines available for dogs and horses, made from the venom of Western Diamondback Rattlesnakes, but none are available for humans. Additionally, the canine vaccines must be given twice per year, immediate veterinary care is still required, & protection against other species of venomous snakes is poor, so the technology has a long way to go.



2 The most famous co-evolutionary arms race is between toxin-resistant gartersnakes & tetrodotoxin-defended newts in the Pacific Northwest of the US & Canada, although there are many others, such as that between most pathogens & the immune systems of their hosts, between brood parasites such as cuckoos & their hosts, and between bad-tasting plants and herbivores.


ACKNOWLEDGMENTS

If you want to know more, I'd suggest chapter 3 of Christie Wilcox's book Venomous, from which I drew while researching & writing this article. Thanks to Connie Wade, Pierson Hill, Alan Cressler, Joe McDonald, Elana Erasmus, and the Los Angeles County Museum of Art [public domain] via Wikimedia Commons for providing their images for this article. Thanks to Laura Connelly for reading a draft of this article.

REFERENCES

A kingsnake eating a ringneck snake
Barchan, D., S. Kachalsky, D. Neumann, Z. Vogel, M. Ovadia, E. Kochva, and S. Fuchs. 1992. How the mongoose can fight the snake: the binding site of the mongoose acetylcholine receptor. Proceedings of the National Academy of Sciences 89:7717-7721 <full-text>

Bdolah, A., E. Kochva, M. Ovadia, S. Kinamon and Z. Wollberg. 1997. Resistance of the egyptian mongoose to sarafotoxins. Toxicon 35:1251-1261 <abstract>

Bonnett, D. E. and S. I. Guttman. 1971. Inhibition of moccasin (Agkistrodon piscivoris) venom proteolytic activity by the serum of the Florida king snake (Lampropeltis getulus floridana). Toxicon 9:417-425 <abstract>

Carpenter, C. C. and J. C. Gillingham. 1975. Postural responses to kingsnakes by crotaline snakes. Herpetologica 31:293-302 <PDF>

Cates, C. C., E. V. Valore, M. A. Couto, G. W. Lawson, and J. G. McCabe. 2015. Comparison of the protective effect of a commercially available western diamondback rattlesnake toxoid vaccine for dogs against envenomation of mice with western diamondback rattlesnake (Crotalus atrox), northern Pacific rattlesnake (Crotalus oreganus oreganus), and southern Pacific rattlesnake (Crotalus oreganus helleri) venom. American Journal of Veterinary Research 76:272-279 <PDF>

Darawshi, S., U. Motro, and Y. Leshem. 2006. The ecology of the Short-toed Eagle (Circaetus gallicus) in the Judean Slopes Israel. The Rufford Foundation, RSG project, detailed final report <project>

de Wit, C. A. 1982. Resistance of the prairie vole (Microtus ochrogaster) and the woodrat (Neotoma floridana), in Kansas, to venom of the Osage copperhead (Agkistrodon contortrix phaeogaster). Toxicon 20:709-714 <abstract>

de Wit, C. A. and B. R. Weström. 1987. Venom resistance in the hedgehog, Erinaceus europaeus: purification and identification of macroglobulin inhibitors as plasma antihemorrhagic factors. Toxicon 25:315-323 <abstract>

Drabeck, D. H., A. M. Dean, and S. A. Jansa. 2015. Why the honey badger don't care: Convergent evolution of venom-targeted nicotinic acetylcholine receptors in mammals that survive venomous snake bites. Toxicon 99:68-72 <academia.edu>

Heatwole, H. and J. Powell. 1998. Resistance of eels (Gymnothorax) to the venom of sea kraits (Laticauda colubrina): a test of coevolution. Toxicon 36:619-625 <PDF>

Holding, M. L., D. H. Drabeck, S. A. Jansa, and H. L. Gibbs. 2016. Venom Resistance as a Model for Understanding the Molecular Basis of Complex Coevolutionary Adaptations. Integrative and Comparative Biology 10.1093/icb/icw082 <full-text>

Jansa, S. A. and R. S. Voss. 2011. Adaptive evolution of the venom-targeted vWF protein in opossums that eat pitvipers. PLoS ONE 6:e20997 <full-text>

Keegan, H. L. and T. F. Andrews. 1942. Effects of crotalid venom on North American snakes. Copeia 1942:251-254 <PDF>

Keegan, H. L. 1944. Indigo snakes feeding upon poisonous snakes. Copeia 1944:59 <PDF>

Lee, C.-Y., editor. 1979. Snake Venoms. Springer-Verlag, Berlin. <full-text>

Liu, Y.-B. and K. Xu. 1990. Lack of the blocking effect of cobrotoxin from Naja naja atra venom on neuromuscular transmission in isolated nerve muscle preparations from poisonous and non-poisonous snakes. Toxicon 28:1071-1076 <abstract>

Lomonte, B., L. Cerdas, J. Gené, and J. Gutierrez. 1982. Neutralization of local effects of the terciopelo (Bothrops asper) venom by blood serum of the colubrid snake Clelia clelia. Toxicon 20:571-579 <abstract>

Moussatché, H. and J. Perales. 1989. Factors underlying the natural resistance of animals against snake venoms. Memorias do Instituto Oswaldo Cruz 84:391-394 <PDF>

Neves-Ferreira, A. G., N. Cardinale, S. L. Rocha, J. Perales, and G. B. Domont. 2000. Isolation and characterization of DM40 and DM43, two snake venom metalloproteinase inhibitors from Didelphis marsupialis serum. Biochimica et Biophysica Acta (BBA)-General Subjects 1474:309-320 <abstract>

Nichol, A. A., V. Douglas, and L. Peck. 1933. On the immunity of rattlesnakes to their venom. Copeia 1933:211-213 <PDF>

Ovadia, M. and E. Kochva. 1977. Neutralization of Viperidae and Elapidae snake venoms by sera of different animals. Toxicon 15:541-547 <abstract>

Perez, J. C., W. C. Haws, V. E. Garcia, and B. M. Jennings III. 1978. Resistance of warm-blooded animals to snake venoms. Toxicon 16:375-383 <abstract>

Perez, J. C., W. C. Haws, and C. H. Hatch. 1978. Resistance of woodrats (Neotoma micropus) to Crotalus atrox venom. Toxicon 16:198-200 <abstract>

Perez, J. C., S. Pichyangkul, and V. E. Garcia. 1979. The resistance of three species of warm-blooded animals to western diamondback rattlesnake (Crotalus atrox) venom. Toxicon 17:601-607 <abstract>

Philpot, V. 1954. Neutralization of snake venom in vitro by serum from the nonvenomous Japanese snake Elaphe quadrivirgata. Herpetologica 10:158-160 <PDF>

Philpot, V. and R. G. Smith. 1950. Neutralization of pit viper venom by king snake serum. Experimental Biology and Medicine 74:521-523 <abstract>

Philpot, V. B., E. Ezekiel, Y. Laseter, R. G. Yaeger, and R. L. Stjernholm. 1978. Neutralization of crotalid venoms by fractions from snake sera. Toxicon 16:603-609 <abstract>

Poran, N. S., R. G. Coss, and E. Benjamini. 1987. Resistance of California ground squirrels (Spermophilus beecheyi) to the venom of the northern Pacific rattlesnake (Crotalus viridis oreganus): a study of adaptive variation. Toxicon 25:767-777 <abstract>

Swanson, P. L. 1946. Effects of snake venoms on snakes. Copeia 1946:242-249 <full-text>

Voss, R. S. and S. A. Jansa. 2012. Snake-venom resistance as a mammalian trophic adaptation: lessons from didelphid marsupials. Biological Reviews 87:822-837 <PDF>

Weinstein, S. A., C. F. DeWitt, and L. A. Smith. 1992. Variability of venom-neutralizing properties of serum from snakes of the colubrid genus Lampropeltis. Journal of Herpetology 26:452-461 <PDF>

Weldon, P. J. 1982. Responses to ophiophagous snakes by snakes of the genus Thamnophis. Copeia 1982:788-794 <PDF>

Weldon, P. J. and G. M. Burghardt. 1979. The ophiophage defensive response in crotaline snakes: extension to new taxa. Journal of Chemical Ecology 5:141-151 <PDF>

Weldon, P. J. and F. M. Schell. 1984. Responses by king snakes (Lampropeltis getulus) to chemicals from colubrid and crotaline snakes. Journal of Chemical Ecology 10:1509-1520 <ResearchGate>

Werner, R. M. and J. A. Vick. 1977. Resistance of the opossum (Didelphis virginiana) to envenomation by snakes of the family Crotalidae. Toxicon 15:29-32 <PDF>

Wilcox, C. 2016. Venomous: How Earth's Deadliest Creatures Mastered Biochemistry. Scientific American. <official page>

Witsil, A. J., R. J. Wells, C. Woods, and S. Rao. 2015. 272 cases of rattlesnake envenomation in dogs: Demographics and treatment including safety of F(ab')2 antivenom use in 236 patients. Toxicon 105:19-26 <abstract>

Creative Commons License

Life is Short, but Snakes are Long by Andrew M. Durso is licensed under a Creative Commons Attribution-NonCommercial-NoDerivs 3.0 Unported License.

Wednesday, March 7, 2018

The House Snake Mess for Dummies

This article will soon be available in Spanish

Inspired by Mike Van Valen's "The Ratsnake Mess for Dummies"
Please note that the information in this article is current as of March 2018 (no later)
Please contact me or leave a comment if you spot an error

Arguably House Snakes are much more of a mess than ratsnakes, which makes sense when you consider that they are they distributed over an area almost 7 times larger, including areas as diverse as the Sahara Desert, Congo Rainforest, Great Rift Valley, East African Savannah, Ethiopian Highlands, Okavango Delta, and Southern African Great Escarpment, and occur in a total of 46 countries, many of which have perennially turbulent political climates. It's no surprise that the number of herpetologists working in Africa is dwarfed by the number working in North America, and the vast majority of these people have not been of African descent (although that is beginning to slowly change).

African House Snake (Boaedon fuliginosus) from the
northernmost part of the range in Morocco.
Like everywhere in Africa, there are probably multiple
undescribed cryptic species within this lineage
What is surprising is that African House Snakes are popular in the pet trade and are important model organisms for studies of development, behavior, hormones and reproductive biology, yet we still know almost nothing about them in the wild, even though they are common and tolerant of anthropogenically-disturbed environments.

When most people think of African House Snakes, the scientific name that probably comes to mind is Lamprophis fuliginosus. In this article, I'll try to explain why this well-known species had to be moved into the genus Boaedon in 2011, and why it will probably be split up into multiple species sometime in the (hopefully-not-too-distant) future. The correct scientific name of many African House Snakes in captive breeding colonies may be difficult or impossible to determine, especially because most people don't know which part of Africa their House Snakes originally came from (and they may have since been bred with House Snakes from other parts of Africa).

Simplified phylogenetic tree of Lamprophiinae, with
focus on "house snakes" (genera Boaedon & Lamprophis).
There's enough uncertainty about the structure within Boaedon
that I didn't try to represent much of what's known.
For more detailed trees, see the KellyGreenbaum, & Trape papers.
Green are species lacking genetic data that can't be placed yet.
Red stars are multiple cryptic species (there could be more).

Click here for a larger version
To start, let's get a little taxonomic perspective. Pyron et al.'s 2011 article firmly established the family Lamprophiidae for a large group of mostly African snakes (321 species) formerly classified as colubrids but actually more closely-related to elapids (more detail here and here). They also found support for seven subfamilies of lamprophiids, of which only one, Lamprophiinae, concerns us today. There are currently 78 species placed in Lamprophiinae1, of which 25 are or have been at some point commonly called "House Snakes" and/or placed in the genus Lamprophis. Only one of these is Boaedon (formerly Lamprophis) fuliginosus, but in order to understand it, we'll need to take a closer look at the others.

A great deal of clarity was gained from the taxonomic actions of Chris Kelly & co-authors in 2011, who split the species in the genus Lamprophis up into several genera, depending on their relationships to other genera of lamprophiines. Even this study was only able to include data on ~40% of the species of lamprophiine snakes, so it's probable that surprises and new discoveries still await us.

Swazi Rock Snakes, Inyoka swazicus, are endemic to rocky
outcrops in Swaziland and adjacent provinces of South Africa
There are currently 12 genera of lamprophiines. Two of these, Chamaelycus (4 species) and Dendrolycus (1 species), have not been included in any molecular phylogenetic trees, so we're going to ignore them for now. The general relationships of the other 10 genera have been sketched out, and they're divided into two groups of roughly equal diversity. The first includes the African Wolf Snakes (Lycophidion; 20 species) and the African File Snakes (Gonionotophis, including the former genus Mehelya; 15 species), as well as two monotypic genera: Hormonotus modestus (Uganda House Snake or Yellow Forest Snake) and Inyoka swazicus (Swaziland House Snake or Swazi Rock Snake). Both of these were originally described as species of LamprophisHormonotus left the genus in the 19th century, and Inyoka was created for swazicus by Kelly et al. 2011 (it means ‘snake’ in the Nguni language group, the main language group in Swaziland). When it was originally described in 1970, swazicus was thought to be intermediate between Lamprophis and Boaedon, both of which were in use at the time, but it turns out that the resemblance is superficial and it's closely related to neither. That takes care of the first two of our 25 House Snake species, which aren't really House Snakes at all.

The Olive Water Snake, Lycodonomorphus inornatus,
was formerly thought to be a Lamprophis
The second group of lamprophiines contains six genera. Three of these are rather small and pretty straightforward, if obscure: Ethiopian Mountain Snakes (Pseudoboodon; 4 species), Günther's Black Snake (Bothrolycus ater), and Red-Black Striped Snakes (Bothrophthalmus; 2 species). None of these have ever been called House Snakes or placed in Lamprophis2, and they are clearly morphologically distinct. A fourth genus, African Water Snakes (Lycodonomorphus; 9 species), includes two species that were formerly thought of as House Snakes: Ly. inornatus and Ly. rufulus (the second only briefly). Ly. inornatus is interesting because it's terrestrial, unlike the other species of Lycodonomorphus, which is part of why it was classified in Lamprophis for so long.

Fisk's House Snake, Lamprophis fiskii, is found in
rocky & sandy areas in the western part of South Africa
The really important finding of Kelly et al. 2011 was that Lycodonomorphus split up the remaining members of Lamprophis into two groups. The southern African group containing Lamprophis aurora got to keep the name Lamprophis, because L. aurora was the first species to be placed in Lamprophis (it is the "type species" of the genus). It got to bring along its close relatives L. fiskii, L. fuscus, and L. guttatus, all of which are small house snakes with attractive patterns, sometimes referred to as "dwarf house snakes", that are popular in the pet trade despite being relatively poorly known in the wild.

Olive House Snakes, Boaedon olivaceus
are found in forests rather than savannah
& grassland habitats
The other group needed a new name. Fortunately, Boaedon had already been used to refer to this group for a long time, from the 1850s to the 1980s. Four species in Kelly's study got "new" names: B. olivaceus, B. virgatusB. lineatus, and B. fuliginosus. Additionally, Kelly included B. maculatus in this group, because its morphology is similar to the other four species, but since we have no DNA evidence yet, this could change. These are sometimes informally called the "brown house snakes", in reference to their generally drabber patterns compared with the "dwarf house snakes". Morphological differences between these two genera include that Boaedon have enlarged anterior teeth on both the upper & lower jaw, and that the dorsal scales of Boaedon have apical pits, whereas those of Lamprophis do not.

Three other species get to stick around in Lamprophis for now: "L." abyssinicus and "L." erlangeri from the Ethiopian highlands, and "L." geometricus from the Seychelles. Probably once we get genetic data from these they will be moved into another genus, possibly Boaedon.

Most of the tree from Greenbaum et al. 2015, showing
the paraphyly of B. fuliginosus with respect to other
Boaedon species, and the geographic diversity of the samples.
Now, the problems aren't over. The thing is that, in Kelly's study, Boaedon "fuliginosus" was split up by B. olivaceus, which is clearly a good species and it makes no sense to sink it into fuliginosus, as well as by B. lineatus, which has a more complex relationship with B. "fuliginosus"3. There are at least seven lineages of Boaedon "fuliginosus" (probably more than 10), thus we can expect that at least 7-10 cryptic species are waiting to be described within this species complex. To quote Kelly et al.: "There have been several attempts to make sense of the intricate patterns of morphological variation in this complex, generally with only limited success."4. A handful of subspecies have been named based on morphology (e.g. mentalis in Namibia, angolensis from southeastern Angola to the southern DRC, arabicus in Yemen, bedriagae on the islands of São Tomé and Príncipe), some of which will probably eventually turn out to be used for full species.

Which, if any, of these future species will get to keep the name fuliginosus is not clear, because these decisions are made based on the location of the original specimen, called the "type locality". The type locality for L. fuliginosus was originally and incorrectly reported in 1827 as "Java". People were more careless back then. There is also no clear type specimen; at one point, one was designated, but it was lost by 1965. The type locality was subsequently corrected to the more accurate but still completely unhelpful "Africa" in 1962, and further restricted to either South Africa or Ghana, but which one isn't clear.

Map of the species currently in Boaedon Lamprophis
Question marks indicate areas where the species range
is uncertain (pink=lineatus complex, green=olivaceus,
brown="fuliginosus"/"capensis" complex)
Click here for larger version
Finally, there is the issue of Boaedon "capensis", a putative species described in 1997 by Hughes and occurring east of a hazy and ill-defined zone angling northeast-southwest from the Gulf of Aden along the Great Rift Valley, then turning east and extending to the Atlantic Ocean possibly near the Angola-Namibia border, but potentially as far north as the mouth of the Congo River and thus also including three of the largest and most poorly-surveyed countries in Africa: Angola, the Democratic Republic of the Congo, and Sudan (including the still relatively new country of South Sudan). This name effectively replaces fuliginosus in eastern and southern Africa, but the exact boundaries are not remotely known, and it will probably turn out that both species are non-mutually-exclusive complexes of cryptic species. Because of the type locality confusion of fuliginosus, it could even turn out that both names (fuliginosus and capensis) are the same southern African species5, and that the western and central African species will need new names.

Boaedon radfordi, a new species from the Uganda-DRC
border region. From Greenbaum et al. 2015
Recent discoveries have begun the process of adding to the number of species of Boaedon: in 2015, Eli Greenbaum and colleagues named a new species, B. radfordi, from the Albertine Rift in the eastern DRC and Uganda (which was formerly confused with B. olivaceus), and also unexpectedly found that a subspecies of Lycodonomorphus subtaeniatus was actually an undescribed species of Boaedon from a lake in south-central DRC, named B. upembae, that is most closely related to B. virgatus. They wisely refrained from making premature splits to the fuliginosus/capensis complex, stating that "Given the complicated taxonomic history and nebulous type locality for B. fuliginosus, substantial additional sampling and morphometric analyses are needed to assign...B. fuliginosus lineages to available names and to describe new species." They did, however, show that divergence among the various lineages currently referred to as B. fuliginosus could have happened as long as 21 million years ago.

Boaedon longilineatus, a new species from Chad
From Trape & Mediannikov 2016
In 2016, Trape & Mediannikov examined 1,370 specimens from eight countries and described 5 new species of Boaedon from central Africa, bringing the total number of species to 13 (including capensis and the certainly paraphyletic "fuliginosus"). Together, two of these, B. perisilvestris and B. subflavus, seem to effectively separate fuliginosus (western Cameroon and west) and capensis (Angola-DRC-S.Sudan and east), having been split from the middle of the species complex's geographic range; but many sources still use fuliginosus for populations east of the distribution of perisilvestris and subflavus. Trape & Mediannikov seem comfortable with the idea of restricting B. fuliginosus to West Africa, and suggest that a blackish color without clear lines on the head could distinguish the species there, despite the absence of any consistent scale characteristics6. Right now, it's impossible to say how the 5 species described by Trape & Mediannikov fit with those described by Greenbaum or with the clades outlines in Kelly, because they used the 16S RNA gene, whereas the other two studies used three different genes (cyt-b, ND4, and c-mos).

Boaedon capensis from South Africa
So, we seem to be approaching stability, but the most problematic one remaining is the one everybody's heard of, knows and loves. Trape's latest definition notwithstanding, between fuliginosus and capensis, African House Snakes in the strictest sense occur in every country in Africa except for Algeria, Tunisia, Libya, Egypt, Sudan, and offshore countries like Madagascar, the Comoros, and the Seychelles7. At the moment, the L. "fuliginosus" complex is still one of the most widespread snake species in the world.

In case you lost count, a quick recap of species that are or have been in Lamprophis:
  1. Hormonotus modestus (Yellow Forest Snake or "Uganda House Snake"; moved in 1850s)
  2. Inyoka swazicus (Swazi Rock Snake or "Swaziland House Snake"; moved in 2011)
  3. Pseudoboodon lemniscatus (briefly in Lamprophis in 1904, barely counts, see footnote2)
  4. Lycodonomorphus inornatus (originally described as a Lamprophis because it was terrestrial, but always a little weird; moved in 2011)
  5. Lycodonomorphus rufulus (briefly in Lamprophis 1840s-1860s, barely counts)
  6. Lamprophis aurora (type species for the genus, will always be a Lamprophis by definition)
  7. Lamprophis fiskii (gets to stick with aurora)
  8. Lamprophis fuscus (gets to stick with aurora)
  9. Lamprophis guttatus (gets to stick with aurora)
  10. "Lamprophis" abyssinicus (awaiting DNA data; Ethioipian highlands)
  11. "Lamprophis" erlangeri (awaiting DNA data; Ethioipian highlands)
  12. "Lamprophis" geometricus (awaiting DNA data; Seychelles)
  13. Boaedon lineatus (type species for the genus, will always be a Boaedon by definition, although as defined it too is likely a cryptic species complex)
  14. Boaedon virgatus (gets to stick with lineatus)
  15. Boaedon olivaceus (gets to stick with lineatus)
  16. Boaedon maculatus (awaiting DNA data; got to stick with the above 3 because of morphology; Horn of Africa)
  17. Boaedon radfordi (described by Greenbaum et al. 2015, split from olivaceus)
  18. Boaedon upembae (formerly Lycodonomorphus subtaeniatus upembae; moved by Greenbaum et al. 2015; in the B. virgatus group)
  19. Boaedon littoralis (split from B. lineatus by Trape & Mediannikov 2016, but lacks DNA data)
  20. Boaedon longilineatus (split from B. lineatus by Trape & Mediannikov 2016)
  21. Boaedon paralineatus (split from B. lineatus by Trape & Mediannikov 2016)
  22. Boaedon perisilvestris (the first of many cryptic species to be split from B. fuliginosus; by Trape & Mediannikov 2016)
  23. Boaedon subflavus (the 2nd split from B. fuliginosus by Trape & Mediannikov 2016)
  24. Boaedon capensis (replaces fuliginosus in east Africa, could be multiple cryptic species)
  25. Boaedon fuliginosus (definitely at least 7 cryptic species, probably many more, no guarantee that any will be called fuliginosus)
The Aurora House Snake, Lamprophis aurora, is the
type species of the genus Lamprophis, meaning it will always
be in Lamprophis unless that genus goes away completely
Whether fuliginosus goes away completely or remains, it won't be going back to Lamprophis unless Lycodonomorphus does too, or unless new genomic data overwhelm the signals found in the genes used by Kelly's, Greenbaum's, & Trape's studies. There's a recurring debate in taxonomy about whether we should attempt to preserve widely-used and well-known names like fuliginosus, since people are probably going to continue using them anyway, or do away with "the burden of heritage" and adhere strictly to a system that discards 150-year-old names if they prove inconvenient or impossible to keep, at the risk of creating confusion & resentment. Proponents of the second argue that eventually people won't remember the old names, and I think they're right: I was born in the 1980s and didn't realize that Lamprophis fuliginosus was called Boaedon for 130 years beforehand; when I learned its name in ~1999, it was as Lamprophis fuliginosus and that was that. These changes might seem radical, but whenever possible they reinstate older names, like Boaedon, the disuse of which might seem radical to an older generation.

There's further debate about the utility of splitting up cryptic species complexes, especially if it makes it almost impossible to identify which species you're looking at by morphology alone. These same issues are recapitulated in the North American ratsnake taxonomic "mess", North American slimy salamanders, egg-eating snakes, and in countless other species groups around the world. When I was writing this article, I thought more than once that I should just wait for a better time when it's all stabilized, but actually there's never a good time; we're always learning more. Ultimately, fleshing out and revising phylogenies and taxonomies will teach us a lot about biodiversity, evolution, and human nature. My advice is to try to be open-minded rather than bitter and ugly when discussing them. There is no "right" or "wrong", there are just rules we've (mostly) agreed to follow. It's an exciting time.

If this group of snakes interests you, watch the labs of Christopher Kelly, Jakob Hallermann, Aaron Bauer, and Jean-François Trape for future research that should make much of this article obsolete.

Edit: In July 2020, writing in the in the African Journal of Herpetology, Hallermann et al. provide the first DNA data for geometricus, proving as suspected that it belongs in Boaedon. They also revalidate mentalis and angolensis and describe three new species of the fuliginosus complex from Angola (named bocagei, branchi, and fradei). Their analysis continues to suggest numerous undescribed species elsewhere in Africa. They restrict fuliginosus to western Africa from Morocco to northern Angola, although it seems likely that it could be restricted further. They also provide a morphological key to the now nine species of Boaedon in Angola.

Edit: In January 2021, again in the African Journal of Herpetology, Ceríaco and colleagues describe two new species from the islands of São Tomé (Boaedon bedriagae) and Príncipe (Boaedon mendesi) in the Gulf of Guinea off Africa's west coast, which were previously mostly considered a subspecies or synonym of either fuliginosus or lineatus. They also state that "Given the considerable number of names coined as subspecies of either fuliginosus or lineatus, the number of names currently considered as synonyms of these two species and the imprecise data about the type locality of the nominotypical forms, this revision may prove to be one of the most challenging taxonomic works of present-day African herpetology."

Edit: A new paper published in the journal Salamandra on 30 October 2022 led by Arthur Tiutenko re-evaluated the two Ethiopian highland endemics, abyssinicus and erlangeri. Both are removed from Lamprophis but neither belongs to Boaedon. Instead, abyssinicus is assigned to Pseudoboodon on the basis of morphology (still no DNA data are available). The first DNA data for erlangeri are published, from a specimen collected in 2016. Because it is more closely related to Bothrophthalmus and Bothrolycus than it is to other lamprophiines, erlangeri is assigned to a brand new genus, Bofa (an Oromo word for "snake"). Color photos in life, CT scans of the skull, and detailed morphological comparisons with the other genera are graciously provided. They suggest "bofa(s)" or "Ethiopian forest snakes" as common names. In addition, guttatus is removed from Lamprophis and assigned to Alopecion, an "empty" genus originally used in the 1850s for guttatus and various other species, all of which have since ended up in other genera. I didn't see this last one coming, but it makes sense because guttatus shares a common ancestor with the other three Lamprophis (aurora, fiskii, and fuscus) less recently than those three share an ancestor with one another, and guttatus is a rocky habitat specialist that has morphological adaptations that allow it to flatten the head to a great degree, in contrast to other Lamprophis that have relatively rounded heads. Admittedly, this is rather subjective, but the authors note that there might be cryptic species within guttatus that would perhaps benefit from being part of a genus that is morphologically, ecologically, and genetically distinct, however arbitrarily the lines between genera are often drawn.

Edit: A new paper published 30 November 2022 in the bulletin of the French herpetological society described a new species of Boaedon from mountainous areas in Rwanda, Burundi, Uganda, Tanzania, and the DRC as Boaedon montanus, effectively splitting it from fuliginosus/lineatus in that area.



1 Note the difference between the endings of the family ("-idae") and subfamily ("-inae") names.



2 Except for Pseudoboodon lemniscatus, but that was only once, in 1904. It counts, but only in the same way as stuff you did once in college. This is complicated enough already.



3 Sources differ on whether B. lineatus is distinct from B. fuliginosis, but it seems to be in western Africa (though both could be multiple cryptic species). Some resources use B. lineatus for house snakes with head stripes in e.g. Uganda, Ethiopia, and Sudan, but increasingly these are referred to as B. capensis. Characteristics used to distinguish B. virgatus & B. olivaceus from B. fuliginosus/capensis/lineatus include undivided subcaudal scales in B. olivaceus and only 23 dorsal scale rows in B. virgatus, as well as the fact that B. virgatus B. olivaceus are found in forests whereas the others are savannah species.



4 The presence or absence of head stripes has been used as a highly visible character, but ultimately this probably won't prove to be closely correlated with genetic variation (and it's complicated by the fact that some Boaedon populations have head stripes as juveniles but lose them as adults). This is also the case in North American ratsnakes, where former subspecies with radically different adult color patterns, like E. o. rossalleni and E. o. quadrivittata turned out to be so genetically similar to the more widespread black phenotype that they are now not recognized. This is part of a move away from the subspecies concept in general, wherein many authors either synonymize subspecies with existing species as "mere variants" or elevate them to full species status using genetic data. I think we can expect this trend to continue with House Snakes.



5 This could happen if South Africa is chosen as the type locality of fuliginosus, because the type locality of capensis is also in South Africa—if South Africa ultimately contains just one species from the fuliginosus complex, then it will get to keep the older name (fuliginosus), and other former members elsewhere should not use the name capensis in order to avoid further confusion. If the type locality of fuliginosus is chosen to be in Ghana instead, then the name will probably continue to be used in western Africa. Let us hope for the 2nd option.



6 This isn't an identification guide, but if you want to see the scale characters for the different species, you can refer to the tables and descriptions in the Kelly, Greenbaum, and Trape papers.



7 "B. fuliginosus" are also found on the Arabian peninsula in Yemen; this could be the most obvious future split if these are shown to be their own lineage, and several sources have already used the name arabicus for them, although just a few individuals are known and additional biological specimens from Yemen are hard to come by. A recent paper used bedriagae as the name of a full species on the islands of São Tomé, with a new species being described from the neighboring island of Príncipe.


ACKNOWLEDGMENTS

Thanks to Peter Uetz for his advice on literature, and to Konrad Mebert, Cliff & Suretha Dorse, and Dan Rosenberg for the use of their photos.

REFERENCES

For map references, see map inset

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Life is Short, but Snakes are Long by Andrew M. Durso is licensed under a Creative Commons Attribution-NonCommercial-NoDerivs 3.0 Unported License.