Non-Container Ships

 

A question often asked about cancer is: “Can you catch it from someone else?” Answer: “No you can’t.” But as so often in cancer the true picture requires a more detailed response — something that may make scientists unpopular but it’s not our fault! As Einstein more or less said “make it as simple as possible but no simpler.”

No … but …

So we have to note that some human cancers arise from infection — most notably by human immunodeficiency viruses (HIV) that can cause acquired immunodeficiency syndrome (AIDS) and lead to cancer and by human papillomavirus infection (HPV) that can give rise to lesions that are the precursors of cervical cancer. But in these human cases it is a causative agent (i.e. virus) that is transmitted, not tumour cells.

However, there are three known examples in mammals of transmissible cancers in which tumour cells are spread between individuals: the facial tumours that afflict Tasmanian devils, a venereal tumour in dogs and a sarcoma in Syrian hamsters.

Not to be outdone, the invertebrates have recently joined this select club and we caught up with this extraordinary story in Cockles and Mussels, Alive, Alive-O! It’s a tale of clams and mussels and various other members of the huge family of bivalve molluscs — (over 15,000 species) — that began 50 years ago when some, living along the east and west coasts of North America and the west coast of Ireland, started to die in large numbers. It turned out that the cause was a type of cancer in which some blood cells reproduce in an uncontrolled way. It’s a form of leukemia: the blood turns milky and the animals die, in effect, from asphyxiation. In soft-shell clams the disease had spread over 1,500 km from Chesapeake Bay to Prince Edward Island but the really staggering fact came from applying the power of DNA sequencing to these little beach dwellers. Like all cancers the cause was genetic damage — in this case the insertion of a chunk of extra DNA into the clam genome. But amazingly this event had only happened once: the cancer had spread from a single ‘founder’ clam throughout the population. The resemblance to the way the cancer spreads in Tasmanian devils is striking.

Join the club

In 2016 four more examples of transmissible cancer in bivalves were discovered — in mussels from British Columbia, in golden carpet shell clams from the Spanish coast and in two forms in cockles. As with the soft-shell clams, DNA analysis showed that the disease had been transmitted by living cancer cells, descended from a single common ancestor, passing directly from one animal to another. In a truly remarkable twist it emerged that cancer cells in golden carpet shell clams come from a different species — the pullet shell clam — a species that, by and large, doesn’t get cancer. So they seem to have come up with a way of resisting a cancer that arose in them, whilst at the same time being able to pass live tumour cells on to another species!!

Map of the spread of cancer in mussels. This afflicts the Mytilus group of bivalve molluscs (i.e. they have a shell of two, hinged parts). BTN = bivalve transmissible neoplasias (i.e. cancers). BTN 1 & BTN2 indicates that two separate genetics events have occurred, each causing a similar leukemia. The species involved are Mytilus trossulus (the bay mussel), Mytilus chilensis (the Chilean blue mussel) and Mytilus edulis (the edible blue mussel). The map shows how cancer cells have spread from Northern to Southern Hemispheres and across the Atlantic Ocean. From Yonemitsu et al. (2019).

Going global

In the latest instalment Marisa Yonemitsu, Michael Metzger and colleagues have looked at two other species of mussel, one found in South America, the other in Europe. DNA analysis showed that the cancers in the South American and European mussels were almost genetically identical and that they came from a single, Northern hemisphere trossulus mussel. However, this cancer lineage is different from the one previously identified in mussels on the southern coast of British Columbia.

Unhappy holidays

It seems very likely that some of these gastronomic delights have hitched a ride on vessels plying the high seas so that carriers of the cancer have travelled the oceans. Whilst one would not wish to deny them the chance of a holiday, this is serious news because of the commercial value of seafood.

It’s another example of how mankind’s advances, in this case being able to build things like container ships with attractive bottoms, for molluscs at least, can lead to unforeseen problems.

This really bizarre story has only come light because of the depletion of populations of clams and mussels in certain areas but it certainly carries the implication that transmissible cancers may be relatively common in marine invertebrates.

Reference

Yonemitsu, M.A. et al. (2019). A single clonal lineage of transmissible cancer identified in two marine mussel species in South America and Europe. eLife 2019;8:e47788 DOI: 10.7554/eLife.47788.

Invisible Army Rouses Home Guard

Writing this blog – perhaps any blog – is an odd pastime because you never really know who, if anyone, reads it or what they get out of it. Regardless of that, one person that it certainly helps is me. That is, trying to make sense of the latest cancer news is one of the best possible exercises for making you think clearly – well, as clearly as I can manage!

But over the years one other rather comforting thing has emerged: more and more often I sit down to write a story about a recent bit of science only to remember that it picks up a thread from a piece I wrote months or sometimes years ago. And that’s really cheering because it’s a kind of marker for progression – another small step forward.

Thus it was with this week’s headline news that a ‘cancer vaccine’ might be on the way. In fact this development takes up more than one strand because it’s about immunotherapy – the latest craze – that we’ve broadly explained in Self Help Part-1Gosh! Wonderful GOSH and Blowing-up Cancer and it uses artificial nanoparticles that we met in Taking a Swiss Army Knife to Cancer.

Arming the troops

What Lena Kranz and her friends from various centres in Germany described is yet another twist on the idea of giving our inbuilt defence – i.e. the immune system – a helping hand to tackle tumours. They made small sacs of lipid called nanoparticles (they’re so small you could get 300 in the width of a human hair), loaded them with bits of RNA and injected them into mice. This invisible army of fatty blobs was swept around the circulatory system whereupon two very surprising things happened. The first was that, with a little bit of fiddling (trying different proportions of lipid and RNA), the nanoparticles were taken up by two types of immune cells, with very little appearing in any other cells. This rather fortuitous result is really important because it means that the therapeutic agent (nanoparticles) don’t need to be directly targetted to a tumour cell – thus avoiding one of the perpetual problems of therapy.

The second event that was not at all a ‘gimme’ was that the immune cells (dendritic cells and macrophages) were stimulated to make interferon and they also used the RNA from the nanoparticles as if it was their own to make the encoded proteins – a set of tumour antigens (tumour antigens are proteins made by tumour cells that can be useful in identifying the cells. A large number of have now been found: one group of tumour antigens includes HER2 that we met as a drug target in Where’s That Tumour?)

The interferon was released into the tumour environment in two waves, bringing about the ‘priming’ of T lymphocytes so that, interacting via tumour antigens, they can kill target cells. By contrast with taking cells from the host and carrying out genetic engineering in the lab (Gosh! Wonderful GOSH), this approach is a sort of internal re-wiring achieved by giving a sub-set of immune system cells a bit of genetic code (in the form of RNA).

TAgs RNA Nano picNanoparticle cancer vaccine. Tiny particles (made of lipids) carry RNA into cells of the immune system (dendritic cells and macrophages) in mice. A sub-set of these cells releases a chemical signal (interferon) that promotes the activation of T lymphocytes. The imported RNA is translated into proteins (tumour antigens) – that are presented to T cells. A second wave of interferon (released from macrophages) completes T cell priming so that they are able to attack tumour cells by recognizing antigens on their surface (Kranz et al. 2016; De Vries and Figdor, 2016).

So far Kranz et al. have only tried this method in three patients with melanoma. All three made interferon and developed strong T-cell responses. As with all other immunotherapies, therefore, it is early days but the fact that widely differing strategies give a strong boost to the immune system is hugely encouraging.

Other ‘cancer vaccines’

As a footnote we might add that there are several ‘cancer vaccines’ approved by the US Food and Drug Administration (FDA). These include vaccines against hepatitis B virus and human papillomavirus, along with sipuleucel-T (for the treatment of prostate cancer), and the first oncolytic virus therapy, talimogene laherparepvec (T-VEC, or Imlygic®) for the treatment of some patients with metastatic melanoma.

How was it for you?

As we began by pointing out how good writing these pieces to clarify science is for me, the question for those dear readers who’ve made it to the end is: ‘How did I do?’

References

Kranz, L.M. et al. (2016). Systemic RNA delivery to dendritic cells exploits antiviral defence for cancer immunotherapy. Nature (2016) doi:10.1038/nature18300.

De Vries, J. and Figdor, C. (2016). Immunotherapy: Cancer vaccine triggers antiviral-type defences.Nature (2016) doi:10.1038/nature18443.