A conversation with a son who is in high tech brought up what a blister on the body politic patent trolling is https://en.wikipedia.org/wiki/Patent_troll. I told him that I’m having trouble simply trying to give an idea away. The idea is basically that some cases of chronic fatigue syndrome are due to senescent cells. There is a simple way to look for this — measure a master transcription factor for cellular senescence (p16INK^4a) in blood cells. If correct, a rational therapy for CFS (senolytics) is immediately at hand. I’ve shopped this around, and someone at Stanford involved with CFS claims that he will test it. I’ve heard nothing so far. The idea is free for the taking. Therapy for CFS essentially helps patients live their symptoms rather than diminishing them or attacking the underlying problem.
Since I”m going to Venice for 2 weeks to celebrate my wife’s birthday, there won’t be any new posts for a while — so here is the idea as presented in two posts from my blog — take it and run with it. The patients are waiting.
Not a great way to end 2017
Not a great way to end 2017
2017 ended with a rejection of the following letter to PNAS.
As a clinical neurologist with a long standing interest in muscular dystrophy(1), I was referred many patients who turned out to have chronic fatigue syndrome (CFS) . Medicine, then and now, has no effective treatment for CFS.
A paper (2) cited In an excellent review of cellular senescence (3) was able to correlate an intracellular marker of senescence (p16^INK4a) with the degree of fatigue experienced by patients undergoing chemotherapy for breast cancer. Chemotherapy induces cellular senescence, and the fatigue was thought to come from the various cytokines secreted by senescent cells (Senescence Associated Secretory Phenotype—SASP) It seems logical to me to test CFS patients for p16^INK4a (4).
I suggested this to the senior author; however, he was nominated as head of the National Cancer Institute just 9 days later. There the matter rested until the paper of Montoya et al. (5) appeared in July. I looked up the 74 individual elements of the SASP and found that 9 were among the 17 cytokines whose levels correlated with the degree of fatigue in CFS. However, this is not statistically significant as Montoya looked at 51 cytokines altogether.
In October, an article(6) on the possibility of killing senescent cells to prevent aging contained a statement that Judith Campisi’s group (which has done much of the work on SASP) had identified “hundreds of proteins involved in SASPs”. (These results have not yet been published.) It is certainly possible that many more of Montoya’s 17 cytokines are among them.
If this is the case, a rational therapy for CFS is immediately apparent; namely, the senolytics, a class of drugs which kills senescent cells. A few senolytics are currently available clinically and many more are under development as a way to attack the aging process (6).
If Montoya still has cells from the patients in the study, measuring p16^INK4a could prove or disprove the idea. However, any oncology service could do the test. If the idea proves correct, then there would be a way to treat the debilitating fatigue of both chemotherapy and CFS—not to mention the many more medical conditions in which severe fatigue is found.
Chemotherapy is a systemic process, producing senescent cells everywhere, which is why DeMaria (2) was able to use circulating blood cells to measure p16^INK4a. It is possible that the senescent cells producing SASP in CFS are confined to one tissue; in which case testing blood for p16^INK4a would fail. (That would be similar to pheochromocytoma cells, in which a few localized cells produce major systemic effects.)
Although senolytics might provide symptomatic treatment (something worthwhile having since medicine presently has nothing for the CFS patient), we’d still be in the dark about what initially caused the cells to become senescent. But this would be research well worth pursuing.
Anyone intrigued by the idea should feel free to go ahead and test it. I am a retired neurologist with no academic affiliation, lacking the means to test it.
References
1 Robinson, L (1979) Split genes and musclar dystrophy. Muscle Nerve 2: 458 – 464
2. He S, Sharpless N (2017) Senescence in Health and Disease. Cell 170: 1000 – 1011
3. Demaria M, et al. (2014) Cellular senescence promotes adverse effects of chemotherapy and cancer relapse. Cancer Discov. 7: 165 – 176
5. Montoya JG, et al., (2017) Cytokine signature associated with disease severity in chronic fatigue syndrome patients, Proc Natl Acad Sci USA 114: E7150-E7158
6. Scudellari M, (2017) To stay young, kill zombie cells Nature 551: 448 – 450
Is a rational treatment for chronic fatigue syndrome at hand?
If an idea of mine is correct, it is possible that some patients with chronic fatigue syndrome (CFS) can be treated with specific medications based on the results of a few blood tests. This is precision medicine at its finest. The data to test this idea has already been acquired, and nothing further needs to be done except to analyze it.
Athough the initial impetus for the idea happened only 3 months ago, there have been enough twists and turns that the best way explanation is by a timeline.
First some background:
As a neurologist I saw a lot of people who were chronically tired and fatigued, because neurologists deal with muscle weakness and diseases like myasthenia gravis which are associated with fatigue. Once I ruled out neuromuscular disease as a cause, I had nothing to offer then (nor did medicine). Some of these patients were undoubtedly neurotic, but there was little question in my mind that many others had something wrong that medicine just hadn’t figured out yet — not that it hasn’t been trying.
Infections of almost any sort are associated with fatigue, most probably caused by components of the inflammatory response. Anyone who’s gone through mononucleosis knows this. The long search for an infectious cause of chronic fatigue syndrome (CFS) has had its ups and downs — particularly downs — see https://luysii.wordpress.com/2011/03/25/evil-scientists-create-virus-causing-chronic-fatigue-syndrome-in-lab/
At worst many people with these symptoms are written off as crazy; at best, diagnosed as depressed and given antidepressants. The fact that many of those given antidepressants feel better is far from conclusive, since most patients with chronic illnesses are somewhat depressed.
The 1 June 2017 Cell had a long and interesting review of cellular senescence by Norman Sharpless [ vol. 169 pp. 1000 – 1011 ]. Here is some background about the entity. If you are familiar with senescent cell biology skip to the paragraph marked **** below
Cells die in a variety of ways. Some are killed (by infections, heat, toxins). This is called necrosis. Others voluntarily commit suicide (this is called apoptosis). Sometimes a cell under stress undergoes cellular senescence, a state in which it doesn’t die, but doesn’t reproduce either. Such cells have a variety of biochemical characteristics — they are resistant to apoptosis, they express molecules which prevent them from proliferating and — most importantly — they secrete a variety of proinflammatory molecules collectively called the Senescence Associated Secretory Phenotype — SASP).
At first the very existence of the senescent state was questioned, but exist it does. What is it good for? Theories abound, one being that mutation is one cause of stress, and stopping mutated cells from proliferating prevents cancer. However, senescent cells are found during fetal life; and they are almost certainly important in wound healing. They are known to accumulate the older you get and some think they cause aging.
Many stresses induce cellular senescence of which mutation is but one. The one of interest to us is chemotherapy for cancer, something obviously good as a cancer cell turned senescent has stopped proliferating. If you know anyone who has undergone chemotherapy, you know that fatigue is almost invariable.
****
One biochemical characteristic of the senescent cell is increased levels of a protein called p16^INK4a, which helps stop cellular proliferation. While p16^INK4a can easily be measured in tissue biopsies, tissue biopsies are inherently invasive. Fortunately, p16^INK4a can also be measured in circulating blood cells.
What caught my eye in the Cell paper was a reference to a paper about cancer [ Cancer Discov. vol. 7 pp. 165 – 176 ’17 ] by M. Demaria, in which the levels of p16^INK4a correlated with the degree of fatigue after chemotherapy. The more p16^INK4a in the blood cells the greater the fatigue.
I may have been the only reader of both papers with clinical experience wth chronic fatigue syndrome. It is extremely difficult to objectively measure a subjective complaint such as fatigue.
As an example of the difficulty in correlating subjective complaints with objective findings, consider the nearly uniform complaint of difficulty thinking in depression, with how such patients actually perform on cognitive tests — e. g. there is little if any correlation between complaints and actual performance — here’s a current reference — Scientific Reports 7, Article number: 3901(2017) — doi:10.1038/s41598-017-04353.
If the results of the Cancer paper could be replicated, p16^INK4 would be the first objective measure of a patient’s individual sense of fatigue.
So I wrote both authors, suggesting that the p16^INK4a test be run on a collection of chronic fatigue syndrome (CFS) patients. Both authors replied quickly, but thought the problem would be acquiring patients. Demaria said that Sharpless had a lab all set up to do the test.
Then fate (in the form of Donald Trump) supervened. A mere 9 days after the Cell issue appeared, Sharpless was nominated to be the head of the National Cancer Institute by President Trump. This meant Dr. Sharpless had far bigger fish to fry, and he would have to sever all connection with his lab because of conflict of interest considerations.
I also contacted a patient organization for chronic fatigue syndrome without much success. Their science advisor never responded.
There matters stood until 22 August when a paper and an editorial about it came out [ Proc. Natl. Acad. Sci. vol. 114 pp. 8914 – 8916, E7150 – E7158 ’17 ]. The paper represented a tremendous amount of data (and work). The blood levels of 51 cytokines (measures of inflammation) and adipokines (hormones released by fat) were measured in both 192 patients with CFS (which can only be defined by symptoms) and 293 healthy controls matched for age and gender.
In this paper, levels of 17 of the 51 cytokines correlated with severity of CFS. This is a striking similarity with the way the p16^INK4 levels correlated with the degree of fatigue after chemotherapy). So I looked up the individual elements of the SASP (which can be found in Annu Rev Pathol. 21010; 5: 99–118.) There are 74 of them. I wondered how many of the 51 cytokines measured in the PNAS paper were in the SASP. This is trickier than it sounds as many cytokines have far more than one name. The bottom line is that 20 SASPs are in the 51 cytokines measured in the paper.
If the fatigue of CFS is due to senescent cells and the SASPs they release, then they should be over-represented in the 17 of the 51 cytokines correlating with symptom severity. Well they are; 9 out of the 17 are SASP. However although suggestive, this increase is not statistically significant (according to my consultants on Math Stack Exchange).
After wrote I him about the new work, Dr. Sharpless noted that CFS is almost certainly a heterogeneous condition. As a clinician with decades of experience, I’ve certainly did see some of the more larcenous members of our society who used any subjective diagnosis to be compensated, as well as a variety of individuals who just wanted to withdraw from society, for whatever reason. They are undoubtedly contaminating the sample in the paper. Dr. Sharpless thought the idea, while interesting, would be very difficult to test.
But it wouldn’t at all. Not with the immense amount of data in the PNAS paper.
Here’s how. Take each of the 9 SASPs and see how their levels correlate with the other 16 (in each of the 192 CSF patients). If they correlate better with SASPs than with nonSASPs, than this would be evidence for senescent cells being the cause some cases of CFS. In particular, patients with a high level of any of the 9 SASPs should be studied for such correlations. Doing so should weed out some of the heterogeneity of the 192 patients in the sample.
This is why the idea is testable and, even better, falsifiable, making it a scientific hypothesis (a la Karl Popper). The data to refute it is in the possession of the authors of the paper.
Suppose the idea turns out to be correct and that some patients with CFS are in fact that way because, for whatever reason, they have a lot of senescent cells releasing SASPs.
This would mean that it would be time to start trials of senolyic drugs which destroy senescent cells on the group with elevated SASPs. Fortunately, a few senolytics are currently inc linical use. This would be precision medicine at its finest.
Being able to alleviate the symptoms of CFS would be worthwhile in itself, but SASP levels could also be run on all sorts of conditions associated with fatigue, most notably infection. This might lead to symptomatic treatment at least. Having gone through mono in med school, I would have loved to have been able to take something to keep me from falling asleep all the time.
