For those with a fondness for happy endings we should note that, despite the shortcomings of available drugs, the prospects for patients with a range of cancers have increased significantly over the latter part of the twentieth century. The overall 5-year survival rate for white Americans diagnosed between 1996 and 2004 with breast cancer was 91%; for prostate cancer and non-Hodgkin’s lymphoma the figures were 99% and 66%, respectively. These figures are part of a long-term trend of increasingly effective cancer treatment and there is no doubt that the advances in chemotherapy summarised in the earlier Holiday Readings are contributory factor. Nonetheless, the precise contribution of drug treatments remains controversial and impossible to disentangle quantitatively from other significant factors, notably earlier detection and improved surgical and radiotherapeutic methods.
Peering into the future there is no question that the gradual introduction of new anti-cancer drugs will continue and that those coming into use will be more specific and therefore less unpleasant to use. By developing combinations of drugs that can simultaneously poke the blancmange at several points it may be possible to confront tumor cells with a multiple challenge that even their nimbleness can’t evade, thereby eliminating the problem of drug resistance. Perhaps, therefore, in 20 years time we will have a drug cabinet sufficiently well stocked with cocktails that the major cancers can be tackled at key stages in their evolution, as defined by their genetic signature.
However, on the cautionary side we should note that in the limited number of studies thus far the effect of drug combinations on remission times has not been startling, being measured in months rather than years or decades. Having noted the durability of cancer cells we should not be surprised by this and the concern, of course, is that, however ingenious our efforts to develop drug cocktails, we may always come second to the adaptability of nature.
Equally perturbing is the fact that over 90% of cancer deaths arise from primary tumors spreading to other sites around the body. For this phenomenon, called metastasis, there are currently very few treatment options available and the magnitude of this problem is reflected in the fact that for metastatic breast cancer there has been little change in the survival rates over the past forty years.
Metastasis therefore remains one of the key cancer challenges. It’s over 125 years since the London physician Stepen Paget asked the critical question: ‘What is it that allows tumour cells to spread around the body?’ and it’s a daunting fact that only very recently have we made much progress towards an answer – and thus perhaps a way of controlling it. To the fore in this pursuit has been David Lyden and his colleagues at Weill Cornell Medical College in New York. Their most astonishing finding is that cells in the primary tumour release messengers into the circulation and these, in effect, tag what will become landing points for wandering cells. Astonishing because it means that these sites are determined before any tumour cells actually set foot outside the confines of the primary tumour. Lyden has christened this ‘bookmarking’ cancer. That is a quite remarkable finding – but, as ever in science, it merely shifts the question to ‘OK but what’s the messenger?’
A ray of sunshine
It might appear somewhat churlish, especially after all that funding, to end on a note of defeatist gloom so let’s finish with my ray of sunshine that represents a radical approach to the problem. It relies on the fact that small numbers of cells break away from tumors and pass into the circulation. In addition, tumours can release both DNA and small sacs – like little cells – that contain DNA, proteins and RNAs (nucleic acids closely related to DNA). These small, secreted vesicles are called exosomes – a special form of messengers, communicating with other cells by fusing to them. By transferring molecules between cells, exosomes may play a role in mediating the immune response and they are now recognized as key regulators of tumour growth and metastasis.
Step forward Lyden and friends once more who have just shown in a mouse model of pancreatic cancer that exosomes found their way to the liver during the tumour’s earliest stages. Exosomes are taken up by some of the liver cells and this sets off a chain of cell-to-cell signals that eventually cause the accumulation of a kind of molecular glue (fibronectin). This is the critical ingredient in a microenvironment that attracts tumour cells and promotes their growth as a metastasis (secondary growth). So you can think of exosomes as a kind of environmental educator.
Exosomes released from primary tumours can mark a niche for metastasis.
The small sacs of goodies called exosomes are carried to the liver where they fuse with some cells, setting off a chain reaction that produces a sticky protein – fibronectin – a kind of glue for immune cells and tumour cells. (from Costa-Silva, B., Lyden, D. et al., Nature Cell Biology 17, 816–826, 2015).
The recent, remarkable technical advances that permit the isolation of exosomes also make it possible to fish out circulating tumour cells and tumour DNA from a mere teaspoonful of blood.
Circulating tumour cells have already been used to monitor patient responses to chemotherapy – when a treatment works the numbers drop: a gradual rise is the earliest indicator of the treatment failing. Even more exciting, this approach offers the possibility of detecting the presence of cancers years, perhaps decades, earlier than can presently be achieved. Coupling this to the capacity to sequence the DNA of the isolated cells to yield a genetic signature of the individual tumor can provide the basis for drug treatment. There are still considerable reservations attached to this approach but if it does drastically shift the stage at which we can detect tumors it may also transpire that their more naïve forms, in which fewer mutations have accumulated, are more susceptible to inhibitory drugs. If that were to be the case then even our currently rather bare, though slowly expanding, drug cabinet may turn out to be quite powerful.