Outsourcing the Immune Response

We’re very trendy in these pages, for no other reason than that the idea is to keep up to date with exciting events in cancer biology. Accordingly, we have recently talked quite a lot about the emerging field of cancer immunotherapy – the notion that our in-built immune system will try to kill cancer cells as they emerge, because it ‘sees’ them as being to some extent ‘foreign’, but that when tumours make their presence known it has not been able to do the job completely. The idea of immunotherapy is to give our in-house system a helping hand and we’ve seen some of the approaches in Self Help – Part 2 and Gosh! Wonderful GOSH.

The immune see-saw

Our immune system walks a tight-rope: on the one hand it should attack and eliminate any ‘foreign’ cells it sees (so that we aren’t killed by infections) but, on the other, if it’s too efficient it will start destroying out own cells (which is what happens in auto-immune diseases such as Graves disease (overactive thyroid gland) and rheumatoid arthritis.

Like much of our biology, then, it’s a tug-of-war: to kill or to ignore? And, like the cell cycle that determines whether a cell should grow and divide to make two cells, it’s controlled by the balance between ‘accelerators’ and ‘brakes’. The main targets for anti-tumour immune activity are mutated proteins that appear on the surface of cancer cells – called neo-antigens (see The Shape of Things to Come?)

The aim of immunotherapy then is to boost tumour responses by disabling the ‘brakes’. And it’s had some startling successes with patients going into long-term remission. So the basic idea works but there’s a problem: generally immunotherapy doesn’t work and, so far, in only about one in ten of patients have there been significant effects.

Sub-contracting to soup-up detection

Until now it’s seemed that only a very small fraction of expressed neo-antigens (less than 1%) can turn on an immune response in cancer patients. In an exciting new take on this problem, a team of researchers from the universities of Oslo and Copenhagen have asked: “if someone’s immune cells aren’t up to recognizing and fighting their tumours (i.e. ‘seeing’ neo-antigens), could someone else’s help?” It turns out that many more than 1 in 100 neo-antigens are able to cause an immune response. Even more exciting (and surprising), immune cells (T cells) from healthy donors can react to these neo-antigens and, in vitro at least (i.e. in cells grown in the laboratory), can kill tumour cells.

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Genetic modification of blood lymphocytes

T cells are isolated from a blood sample and novel genes inserted into their DNA. The engineered T cells are expanded and then infused into the patient. In the latest development T cells from healthy donors are screened for reactivity against neo-antigens expressed in a patient’s melanoma. T cell receptors that  recognise neo-antigens are sequenced and then transferred to the patient’s T cells.

How does that work?

T cells (lymphocytes) circulating in the blood act, in effect, as scouts, scanning the surface of all cells, including cancer cells, for the presence of any protein fragments on their surface that should not be there. The first contact with such foreign protein fragments switches on a process called priming that ultimately enables T cells to kill the aberrant cells (see Invisible Army Rouses Home Guard).

What the Scandinavian group did was to screen healthy individuals for tissue compatibility with a group of cancer patients. They then identified a set of 57 neo-antigens from three melanoma patients and showed that 11 of the 57 could stimulate responses in T cells from the healthy donors (T cells from the patients only reacted to two neo-antigens). Indeed the neo-antigen-specific T cells from healthy donors could kill melanoma cells carrying the corresponding mutated protein.

What can possibly go wrong?

The obvious question is, of course, how come cells from healthy folk have a broader reactivity to neo-antigens than do the cells of melanoma patients? The answer isn’t clear but presumably either cancers can make T cell priming inefficient or T cells become tolerant to tumours (i.e. they see them as ‘self’ rather than ‘non-self’).

And the future?

The more critical question is whether the problem can be short-circuited and Erlend Strønen and friends set about this by showing that T cell receptors in donor cells that recognize neo-antigens can be sequenced and expressed in the T cells of patients. This offers the possibility of a further type of adoptive cell transfer immunotherapy to the one we described in Gosh! Wonderful GOSH.

https://cancerforall.wordpress.com/2015/11/19/gosh-wonderful-gosh/

As one of the authors, Ton Schumacher, put it “Our findings show that the immune response in cancer patients can be strengthened; there is more on the cancer cells that makes them foreign that we can exploit. One way we consider doing this is finding the right donor T cells to match these neo-antigens. The receptor that is used by these donor T-cells can then be used to genetically modify the patient’s own T cells so these will be able to detect the cancer cells.”

And Johanna Olweus commented that “Our study shows that the principle of outsourcing cancer immunity to a donor is sound. However, more work needs to be done before patients can benefit from this discovery. Thus, we need to find ways to enhance the throughput. We are currently exploring high-throughput methods to identify the neo-antigens that the T cells can “see” on the cancer and isolate the responding cells. But the results showing that we can obtain cancer-specific immunity from the blood of healthy individuals are already very promising.”

References

Strønen, M. Toebes, S. Kelderman, M. M. van Buuren, W. Yang, N. van Rooij, M. Donia, M.-L. Boschen, F. Lund-Johansen, J. Olweus, T. N. Schumacher. Targeting of cancer neoantigens with donor-derived T cell receptor repertoires. Science, 2016.

“Fighting cancer with the help of someone else’s immune cells.” ScienceDaily. ScienceDaily, 19 May 2016.

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Holiday Reading (3) – Stopping the Juggernaut

The mutations that drive cancers fall into two major groups: those that reduce or eliminate the activity of affected proteins and those that have the opposite effect and render the protein abnormally active. It’s intuitively easy to see how the latter work: if a protein (or more than one) in a pathway that tells cells to proliferate becomes more efficient the process is accelerated. Less obvious is how losing an activity might have a similar effect but this comes about because the process by which one cell becomes two (called the cell cycle) is controlled by both positive and negative factors (accelerators and brakes if you will). This concept of a balancing act – signals pulling in opposite directions – is a common theme in biology. In the complex and ever changing environment of a cell the pressure to reproduce is balanced by cues that ask crucial questions. Are there sufficient nutrients available to support growth? Is the DNA undamaged, i.e. in a fit state to be replicated? If the answer to any of these questions is ‘no’ the cell cycle machinery applies the brakes, so that operations are suspended until circumstances change. The loss of negative regulators releases a critical restraint so that cells have a green light to divide even when they should not – a recipe for cancer.

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The cell cycle.

Cells are stimulated by growth factors to leave a quiescent state (G0) and enter the cell cycle – two growth phases (G1 & G2), S phase where DNA is duplicated and mitosis (M) in which the cells divide to give to identical daughter cells. Checkpoints can arrest progression if, for example, DNA is damaged. 

We’re all familiar with this kind of message tug-of-war at the level of the whole animal. We’ve eaten a cream cake and the schoolboy within is saying ‘go on, have another’ whilst the voice of wisdom is whispering ‘if you go on for long enough you’ll end up spherical.’

Because loss of key negative regulators occurs in almost all cancers it is a high priority to find ways of replacing inactivated or lost genes. Thus far, however, successful ‘gene therapy’ approaches have not been forthcoming with perhaps the exception of the emerging field of immunotherapy. The aim here is to boost the activity of the immune system of an individual – in other words to give an innate anti-cancer defense a helping hand. The immune system can affect solid cancers through what’s become known as the tumour microenvironment – the variety of cells and messengers that flock to the site of the abnormal growth. We’ve referred to these as ‘groupies’ and they include white blood cells. They’re drawn to the scene of the crime by chemical signals released by the tumour – the initial aim being to liquidate the intruder (i.e. tumour cells). However, if this fails, a two-way communication sees would-be killers converted to avid supporters that are essential for cancer development and spread.

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The tumour microenvironment. Tumour cells release chemical messengers that attract other types of cell, in particular those that mediate the immune response. If the cancer cells are not eliminated a two-way signaling system is established that helps tumour development.

There is much optimism that this will evolve into a really effective therapy but it is too early for unreserved confidence.

The obstacle of reversing mutations that eliminate the function of a gene has led to the current position in which practically all anti-cancer agents in use are inhibitors, that is, they block the activity of a protein (or proteins) resulting in the arrest of cell proliferation – which may ultimately lead to cell death. Almost all these drugs are not specific for tumour cells: they hit some component of the cell replication machinery and will block division in any cell they reach – which is why so many give rise to the side-effects notoriously associated with cancer chemotherapy. For example, the taxanes – widely used in this context – stick to protein cables to prevent them from pulling duplicated DNA strands apart so that cells, in effect, become frozen in final stages of division. Other classes of agent target different aspects of the cell cycle.

It is somewhat surprising that non-tumour specific agents work as well as they do but their obvious shortcomings have provided a major incentive for the development of ‘specific’ drugs – meaning ones that hit only tumour cells and leave normal tissue alone. Several of these have come into use over the past 15 years and more are in various stages of clinical trials. They’re specific because they knock out the activity of mutant proteins that are made only in tumour cells. Notable examples are Zelboraf® manufactured by Roche (hits the mutated form of a cell messenger – called BRAF – that drives a high proportion of malignant melanomas) and Gleevec® (Novartis AG: blocks a hybrid protein – BCR-ABL – that is usually formed in a type of leukemia).

These ‘targeted therapies’ are designed to not so much to poke the blancmange as to zap it by knocking out the activity of critical mutant proteins that are the product of cancer evolution. And they have produced spectacular remissions. However, in common with all other anti-cancer drugs, they suffer from the shortcoming that, almost inevitably, tumours develop resistance to their effects and the disease re-surfaces. The most remarkable and distressing aspect of drug resistance is that it commonly occurs on a timescale of months.

And being outwitted

Tumour cells use two tactics to neutralize anything thrown at them before it can neutralize them. One is to treat the agent as garbage and activate proteins in the cell membrane that pump it out. That’s pretty smart but what’s really staggering is the flexibility cells show in adapting their signal pathways to counter the effect of a drug blocking a specific target. Just about any feat of molecular gymnastics that you can imagine has been shown to occur, ranging from switching to other pathways in the signalling network to short-circuit the block, to evolving secondary mutations in the target mutant protein so that the drug can no longer stick to it. Launching specific drugs at cells may give them a mighty poke in a particularly tender spot, and indeed many cells may die as a result, but almost inevitably some survive. The blancmange shakes itself, comes up with a counter and gets down to business again. This quite extraordinary resilience of tumour cells derives from the infinite adaptability of the genome and we might do well to reflect that in trying to come up with anti-cancer drugs we are taking on an adversary that has overcome the challenges involved in generating the umpteen million species to have emerged during the earth’s lifetime.

Not the least disheartening aspect of this scenario is that when tumours recur after an initial drug treatment they are often more efficient at propagating themselves, i.e. more aggressive, than their precursors.