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Tim Pearce

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Snail Extinction – Bad Situation Getting Worse

By Timothy Pearce

Move Aside Rosy Wolf Snail, the New Guinea Flatworm Wreaks Greater Devastation

Another species of land snail went extinct on January 1, 2019. George, the last member of his species, Achatinella apexfulva, died in a captive breeding facility at the University of Hawaii. The loss of this snail, and this species, is sad from many perspectives, I’ll mention two: first, George’s species is the first land snail ever described from Hawaii; second, this loss contributes to the largely overlooked extinction crisis of land snails around the world.

Achatinella apexfulva shell
Achatinella apexfulva from the Carnegie Museum of Natural History collection.

George was named after Lonesome George, the last Galapagos tortoise of the subspecies Geochelone nigra abingdoni, who died in 2012. Like most land snails, George the snail was hermaphroditic (having both male and female parts), so either male, female, or androgynous names would have been appropriate.

News outlets including New York Times, National Geographic, and National Public Radio, as well as various blogs (e.g., https://www.shellmuseum.org/curators-corner) have well-covered the story of George’s passing, so look there for more details that I won’t repeat. Those outlets mentioned threats leading to the demise of tree snails, including the introduced rosy wolf snail, a snail-eating snail credited with causing snail extinctions on some Pacific Islands. However, none of those news outlets mentioned the New Guinea flatworm, which is already showing itself to be a much greater threat to snail-kind than the rosy wolf snail.

New Guinea flatworm
The New Guinea flatworm (Platydemus manokwari) eats land snails so efficiently that it is causing snail extinctions. Photo from Wikimedia Commons.

The New Guinea flatworm (Platydemus manokwari), which eats mostly snails, has been categorized as one of the 100 worst invasive species. Originally found in New Guinea, human activity has introduced it to many tropical and temperate regions of the world where it has had significant negative impacts on the rare endemic land snail fauna of some Pacific islands. Evidence indicates that predation by the New Guinea flatworm is the greatest cause of the extinction or drastically reduced numbers of several native snails. Up to 65 mm (2.5 inches) long, it can follow snail mucus trails to catch prey, sometimes even into trees, so its presence in Hawaii seriously threatens the remaining Hawaiian tree snails.

In 2015, the New Guinea flatworm was found in Florida, from which it poses a threat to land snails on the mainland of the USA. A colleague told me that in some of the Everglade hammocks where the flatworm has reached, all you can find now are dead, empty shells of the colorful tree snails that were gobbled by the flatworm. The flatworm does not survive in colder climates, so for the time being, the northern United States might be spared from this scourge. The flatworm survives best at 18 to 28 C (64-82F) and nearly ¼ of them survived in an experiment down to 10°C (50F) for 2 weeks.

Timothy A. Pearce is Curator of Collections, Section of Mollusks at Carnegie Museum of Natural History. Museum employees are encouraged to blog about their unique experiences and knowledge gained from working at the museum.

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Warm Those Heart Cockles

By Timothy A. Pearce

The phrase “cockles of your heart” refers to the cockle-like ventricles of the heart. But the cockles that Mary quite contrary had in her garden, and the cockles being sold by Molly Malone, are bivalve mollusks that have heart-shaped shells. Of the cockles, one of the most heart-shaped is Corculum cardissa, also known as the heart cockle.

heart cockle specimens
Corculum cardissa (heart cockles) have tiny windows in their shells that let in light for their internal algae to photosynthesize. Photo by Tim Pearce.

Corculum cardissa and the related giant clams (genus Tridacna) have microscopic dinoflagellate algae living inside their bodies (in the mantle, gills, and the liver).

Remarkably, the shells of Corculum cardissa have tiny translucent windows that allow light to penetrate so the algae can photosynthesize. The cockle gets food from the algae, and the algae get a safe place to live. They live together in symbiosis (as happy as an alga).

The windows appear to direct and focus light onto the parts of the clam body containing algae, rather than simply dispersing light (Carter & Schneider 1997).

Both Corculum cardissa and the giant clams live in the Indo-Pacific region. They inhabit shallow water because there is not enough light below about 20 m depth for their algae.

The giant clams and heart cockles (Corculum) are perhaps the only bivalves having a symbiotic relationship with dinoflagellates (Farmer et al., 2001).

Second to the corals, these clams are the best-studied systems of photosynthetic symbionts in animals.

Now there is a story to warm the cockles of your heart on these cold winter days!

Timothy A. Pearce is Curator of Collections, Section of Mollusks at Carnegie Museum of Natural History. Museum employees are encouraged to blog about their unique experiences and knowledge gained from working at the museum.

Literature

Carter, J.G. & Schneider, J.A. 1997. Condensing lenses and shell microstructure in Corculum, (Mollusca: Bivalvia). Journal of Paleontology, 71(1): 56-61.

Farmer, M.A., Fitt, W.K. & Trench, R.K. 2001. Morphology of the symbiosys between Corculum cardissa (Mollusca: Bivalvia) and Symbiodinium corculorum (Dinophyceae). Biological Bulletin, 200: 336-343.

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The Tell-Snail Heart

by Timothy A. Pearce

gif of a snail's heart beating

Edgar Allen Poe is well-known as an American writer of poems and short stories, including some spooky works that are often repeated around Halloween. Many people are surprised to learn that Poe once edited a book on shells, “The Conchologist’s First Book”, published in 1839. Poe’s shell book is a condensed version of a book by Thomas Wyatt. Poe wrote the preface and introduction initially; then he made more substantial changes.

Poe’s short story, “The Tell-Tale Heart,” is about someone who kills a man, then hides the body under the floorboards. The murderer, while talking with the police, is initially calm, but goes mad from the perceived sound of a heartbeat, and thinking the sound is the dead man’s beating heart, confesses to the crime.

In honor of Halloween and in recognition of Poe’s contributions to the study of mollusks, I made this gif movie of a snail’s heart beating, visible through the shell. The snail is Neohelix dentifera (the big-tooth whitelip snail), a land snail commonly found in Pennsylvania and elsewhere in northeastern North America. First you see the face with the four tentacles (the upper two tentacles have eyes on the tips; the lower tentacles are for smelling and tasting). Then as I turn the snail you get a quick peek at the breathing pore above the head, then you can look through the translucent shell to see the heart beat 3 times. It is the Tell-Snail Heart!

Timothy A. Pearce is Curator of Collections, Section of Mollusks at Carnegie Museum of Natural History. Museum employees are encouraged to blog about their unique experiences and knowledge gained from working at the museum.

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Carnegie Museum of Natural History Blog Citation Information

Blog author: Pearce, Timothy A.
Publication date: October 31, 2018

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Chasing Snails in the Great Smoky Mountains

by Tim Pearce

Looking for snails in Tennessee is rewarding because that state is third in number of species of land snails in the USA (after Hawaii and California). That large number of snail species likely results from (a) lack of glaciers for a long time, (b) lots of limestone, in which snails thrive, and (c) numerous isolated valleys that provide opportunities for speciation.

We were on the trail of the tiger snails, genus Anguispira, so that we could study their DNA in order to unravel the tangled branches of their family tree. During more than two hundred years, a couple dozen species have been named. Many of the species have distinct shells, but some species look so much alike that we suspect they are actually the same species.

Tim Pearce looking for snails
Finding Anguispira snails near Norris Dam, Tennessee. Photo by Tim Pearce [selfie].

As we checked into our motel at the edge of the Great Smoky Mountains National Park, we navigated around two bears (rummaging in the dumpster) to get to our rooms. Our team included Reham Fathey Ali from Cairo University in Egypt, John Slapcinsky from Florida Museum, and yours truly from Carnegie Museum of Natural History. You might call us a multi-institutional collaboration.

The next day, two people from the Great Smoky Mountains National Park joined our expedition: retired ranger Keith Langdon and intern Miranda Zwingelberg. They led us to the snail research collection in a back room of the office building and we helped them out by identifying some of their snail specimens.

Researchers working on snail identification
Identifying snails in the research collection at the Great Smoky Mountains National Park. Photo by Miranda Zwingelberg.

Keith had previously found empty shells of Anguispira knoxensis, one of the species we needed. He took us to the very tree where he had found them. That day, we five searched for 18-person-hours and found snails of many species, but only 3 empty shells of that target species. However, we did find living snails of another form of Anguispira, which has been called Anguispira lawae.(Intriguingly, that form was named for Annie Law, a shell collector and Civil War spy in the 1800s.) We also need that form for our study, so we considered the day to be a success.

Living specimens of Anguispira rugoderma - tiger snails
Living specimens of Anguispira rugoderma. Photo by Reham Fathey Ali.

Several days later our team found living specimens of both Anguispira knoxensis and Anguispira rugoderma.We suspect they might actually be the same species. An examination of the DNA will help us decide whether those two are separate or the same species. DNA evidence plus scrutiny of existing specimens in our museums will also provide evidence for us to use in revising the Anguispira family tree.

Timothy A. Pearce, PhD, is the head of the mollusks section at Carnegie Museum of Natural History. Museum employees are encouraged to blog about their unique experiences and knowledge gained from working at the museum.

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Extremely Rapid Evolution of Cone Snail Toxins

By Tim Pearce

Cone snails live in the sea and inject venom to paralyze their prey. Most cone snails eat worms, some eat other snails, and some catch and eat fish. They use a hypodermic dart (a modified radular tooth) to inject venom. The venom contains about 100 different peptides (short proteins) that act as neurotoxins. Each of the 600 or so species of cone snail has its own unique cocktail of peptides, with very little overlap of peptides among species, yielding >50,000 peptides among the cone snails of the world.

Cone snail venom peptides are among the most rapidly evolving protein-coding genes in animals. They evolve twice as fast as most other known proteins. The rapid evolution appears to result from extensive gene duplications that provide abundant opportunities for natural selection during predator-prey interactions [1,2].

Furthermore, cone venom peptides are one of the most highly post-translationally modified classes of gene products known. That means the peptides undergo extensive modifications after being translated from DNA, including bromination, glycosylation, and amino acid epimerization (changing from L to D, like becoming their own mirror image) [3].

The venom cocktail targets particular kinds of prey; worm-eaters have a different suite of peptides than fish eaters. At different stages of development, they can express different genes. When very young, the fish eaters are too small to eat fish, so they eat worms, then switch to fish later. Their venom cocktail changes from worm toxins to fish toxins when they switch prey.

textile cone snails
Textile cone (Conus textile), a sea snail with venom powerful enough to kill humans. Specimen CM 127704, photo by Tim Pearce.

Conus magus is one of the species whose diet shifts from worms to fish as it grows. In these diet-shifting species, the shape of the radular dart changes as well – those eating worms have unbarbed darts, while those eating fish have backward pointing barbs to help keep hold of the fish [2,4,5].

Animal nerve cells contain many kinds of ion channels, whose function aids in transmitting signals along the nerve. Each cone snail peptide can target a particular kind of ion channel. The complex mixture of peptides in cone snail venom blocks many ion channels and neuron receptors in prey species. Surprisingly, many cone snail peptides act on pain targets, but it is not clear what advantage the snail would derive from numbing the prey’s pain. However, pain-killing properties are one of the reasons that cone snail venoms are of great interest to pharmaceutical companies and at least one cone snail peptide is currently used as a pain-killer in humans.

Researchers can prospect for venom peptides in the DNA of cone snail tissue snips or from museum specimens. By prospecting in DNA, they can find genes for venom peptides that are not being expressed at that particular life stage [6]. Once a useful peptide is discovered and characterized, it can be manufactured (so it doesn’t need to be milked from the snail).

Cone snails can switch rapidly between toxins for predation or toxins for defense. The toxins used by the geography cone, Conus geographus for catching prey are mostly inactive on humans, but the toxins it uses for defense are paralytic peptides that block neuromuscular receptors. Conus geographus and Conus textile are the two cone snail species known to kill humans [7].

To see videos of cone snails catching and swallowing fish, type into your internet browser: “cone snail eating.”

In addition to their beauty and amazing prey capture abilities, cone snails are remarkable for the extremely rapid evolution of their toxins, some of which show promise as useful medicines.

Timothy A. Pearce, PhD, is the head of the mollusks section at Carnegie Museum of Natural History. Museum employees are encouraged to blog about their unique experiences and knowledge gained from working at the museum.

Notes:

[1] Duda, T.F. & Palumbi, S.R. 1999. Molecular genetics of ecological diversification: Duplication and rapid evolution of toxin genes of the venomous gastropod Conus. Proceedings of the National Academy of Sciences, U.S.A., 96(12): 6820–6823.

[2] Chang, D.& Duda, T.F., Jr. 2016. Age-related association of venom gene expression and diet of predatory gastropods. BMC Evolutionary Biology, 16: 27.

[3] Buczek, O., Yoshikami, D., Bulaj, G., Jimenez, E.C. & Olivera, B.M. 2005. Posttranslational amino acid isomerization: a functionally important D-amino acid in an excitatory peptide. Journal of Biological Chemistry, 280: 4247-4253.

[4] Nybakken, J. & Perron, F. 1988. Ontogenetic change in the radula of Conus magus(Gastropoda). Marine Biology, 98(2): 239–242

[5] Nybakken, J. 1990. Ontogenetic change in the Conusradula, its form, distribution among the radula types, and significance in systematics and ecology. Malacologia, 32(1): 35-54.

[6] I suspect that post-translational effects (including introns and exons) would obscure the understanding of the final product of a peptide discovered by DNA prospecting.

[7]Dutertre, S., Jin, A.-H., Vetter, I., Hamilton, B., Sunagar, K., Lavergne, V., Dutertre, V., Fry, B.G., Antunes, A., Venter, D.J., Alewood, P.F. & Lewis, R.J. 2014. Evolution of separate predation- and defence-evoked venoms in carnivorous cone snails. Nature Communications, 5(3521): 1-9.

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Killer Sea Snails: Cure for the Opioid Crisis?

By Tim Pearce

Carnivorous and predatory, killer cone snails (genus Conus) stun their prey by injecting peptide neurotoxins called conotoxins. These peptides are short proteins, mostly 12-30 amino acids long.

Of the approximately 600 species of cone snails, two species have killed humans: the geography cone (Conus geographusand the textile cone (Conus textile). Those species occur in the South Pacific and Indian Oceans.

cone snails
Geography cone (Conus geographus), a sea snail with venom powerful enough to kill humans. Specimen CM 73476, photo by Tim Pearce.

 

Each cone snail species produces more than 100 conotoxins, with an estimated 5% overlap in conotoxins among species [1]. Although only about 0.1% of these >50,000 peptides have been characterized, many have already been recognized to have pharmaceutical uses: six for pain, three for cardiovascular issues, one for epilepsy, and one for mood.

A potentially useful medicine from the venom of fish-eating cone snails is insulin, which acts faster than human insulin [2]. The cone snail insulin is a single molecule that acts within 5 minutes. In contrast, human insulin is stored as a cluster of six insulin molecules that must separate to become active, and separation can take 60 minutes (or 15-30 minutes for modified human insulin). The cone snail uses its insulin to immobilize fish by hypoglycemic shock (caused by extremely low blood sugar), making prey easier to catch. Researchers are studying cone snail insulin for ideas to make better insulin for use in humans.

Another medicine currently used in humans is the pain killer ziconotide (Prialt). It is more powerful than morphine, not addictive, and people don’t build up a tolerance. However, it doesn’t cross the blood-brain barrier so must be injected directly into spinal fluid. The FDA approved it in 2004 for end-of-life cases (pain management). Scattered reports suggest an odd side effect: people who take Prialt hear music in their heads. Researchers continue studying ways to get the peptide across the blood-brain barrier. Success could mean an alternative to opioid drugs, and potentially a powerful tool for solving the opioid crisis.

“Better living through snails!”

Fun Fact: Sunken ships provide habitat for many undersea creatures including cone snails.

Riddle: What lies at the bottom of the ocean and twitches?

Answer: A nervous wreck!

Timothy A. Pearce, PhD, is the head of the mollusks section at Carnegie Museum of Natural History. Museum employees are encouraged to blog about their unique experiences and knowledge gained from working at the museum.

Notes:

[1] Davis, J., Jones, A. & Lewis, R.J. 2009. Remarkable inter- and intra-species complexity of conotoxins revealed by LC/MS. Peptides, 30(7): 1222-1227.

[2] Safavi-Hemamia, H., Gajewiak, J., Karanth, S., Robinson, S.D., Ueberheide, B., Douglass, A.D., Schlegel, A., Imperial, J.S., Watkins, M., Bandyopadhyay, P.K., Yandell, M., Li, Q., Purcell, A.W., Norton, R.S., Ellgaard, L. & Olivera, B.M. 2015. Specialized insulin is used for chemical warfare by fish-hunting cone snails. Proceedings of the National Academy of Sciences, 112(6): 1743-1748.