On the other hand, there are cancer types that may not respond to a ketogenic diet. Prostate cancers seemed a likely candidate, because there is an inverse correlation with type 2 diabetes, but in animal models a ketogenic diet improves survival.
But recently some U.S. researchers have provided evidence that acetoacetate accelerates the growth of an important type of malignant melanoma, cells with a BRAF V600E mutation.
We recently reported that the ketone body acetoacetate selectively enhances BRAF V600E mutant-dependent MEK1 activation in human cancers. Here we show that a high-fat ketogenic diet increased serum levels of acetoacetate, leading to enhanced tumor growth potential of BRAF V600E-expressing human melanoma cells in xenograft mice. Treatment with hypolipidemic agents to lower circulating acetoacetate levels or an inhibitory homolog of acetoacetate, dehydroacetic acid, to antagonize acetoacetate-BRAF V600E binding attenuated BRAF V600E tumor growth. These findings reveal a signaling basis underlying a pathogenic role of dietary fat in BRAF V600E-expressing melanoma, providing insights into the design of conceptualized “precision diets” that may prevent or delay tumor progression based on an individual’s specific oncogenic mutation profile.
I have some issues with this - firstly, that "Dietary fat promotes ketogenesis to enhance BRAF V600E tumor growth." Dietary fat will only do this in a ketogenic diet. It doesn't take much carbohydrate and/or extra protein to stop it. Fasting or a very low calorie diet will promote ketogenesis too; the rate of oxidation of fat when you skip carbohydrate and restrict protein is exactly the same as when you don't eat, except that ketone levels stay lower over the longer term. So if ketone bodies from fat oxidation promote melanoma, fasting should be worse than a ketogenic diet.
Obesity and type 2 diabetes are conditions that suppress ketogenesis and make it hard to get into ketosis. They are the opposite of fasting. They should be protective against malignant melanoma; they're not. However, the relationship is weak and inconsistent, which might show some effect, countering the usual pro-cancer mechanisms in these conditions.
Type 1 diabetes is a condition that frequently exposes people to high ketone levels. Type 1 diabetes seems to be inversely, but non-significantly correlated with melanoma in Sweden, standardized incidence rate of 0.8 (0.5 to 1.1).
This evidence doesn't refute the ketone-melanoma link in humans, and it doesn't relate to ketogenic diets, but it does show that there are many influences on melanoma (deficient vitamin D3 and hyperleptinaemia, and glutamine as a fuel, appeared in a cursory search) that might swamp the ketone effect.
One of the findings in the latest study was that cholesterol increased in the mice on the ketogenic diet. This is presumed to deliver more lipid to cells. Prostate cancer cells upregulate the LDL-receptor to take in more lipid. and the function of this is to take in more omega-6 fatty acids to make prostaglandins which promote tumour growth. This is relevant to the present case because polyunsaturated fatty acids are especially ketogenic; however, the fat used in this experiment was a mixture of 1 part corn oil to 6.5 parts Primex, which is "pure vegetable shortening, a mixture of partially hydrogenated soybean and palm oil". None of these are fats that anyone on a ketogenic diet would use, and all, it turns out, are contaminated with carcinogens. However this would have had little effect in the context of this experiment.
This dodgy version of a ketogenic diet did not increase tumour size in the mice with the alternative malignant melanoma mutation.
It may be that polyunsaturated fatty acids can promote ketogenesis more easily than other fats in cells that don't normally produce ketones:
This paper summarizes the emerging literature indicating that at least two polyunsaturated fatty acids (PUFA; linoleate, alpha-linolenate) are moderately ketogenic and that via ketone bodies significant amounts of carbon are recycled from these fatty acids into de novo synthesis of lipids including cholesterol, palmitate, stearate and oleate. This pathway (PUFA carbon recycling) is particularly active in several tissues during the suckling period when, depending on the tissue, >200 fold more carbon from alpha-linolenate can be recycled into newly synthesized lipids than is used to make docosahexaenoate. At least in rats, PUFA carbon recycling also occurs in adults and even during extreme linoleate deficiency.
We have many thousands of people around the world using various types of ketogenic diets or fasting, some for a very long time (lifetimes in the case of some people with pediatric epilepsy), and a large proportion of them nowadays are relatively sceptical about sunscreen. There are no case studies of melanoma in such people that I could find, and I have come across no reports in many years on social media.
This is not to say that a ketogenic diet or fasting is a treatment option for BRAF V600E melanoma, this is I think good enough evidence to decide that it's probably not. However, it's likely that other benefits of keto diets and fasting, viz. improved insulin and leptin status, decreased inflammation, lower glutamine, improved vitamin D status, hormetic antioxidants, avoidance of refined oils and a good omega 3:6 ratio, etc. decrease all the other changes that lead to a tumour's appearance in the first place.
The research I cited here has received ample funding from an impressive array of sources, but not all ketone-and-cancer research receives public funding. Thus E.J. Fine and R.D. Feinman are now crowd-sourcing funding for a simple experiment, certainly much less expensive than the one above, which is testing the effect of acetoacetate on a variety of different cancer cell types and looking at the metabolic pathways associated with response and non-response, specifically those that control ROS generation and cytotoxicity.
Our 28 day pilot human trial of 10 subjects with advanced cancers on a very low carbohydrate ketogenic diet (KD) was publilshed in Nutrition (Elsevier) in 2012. Patients with the greatest extent of ketosis had stable cancers or partial remission, while those with the least ketosis showed continued progressive cancer.
In cell culture studies we published that ketone bodies (KB) inhibited growth of 7 different cancers from 20-50%, leaving normal cells unaffected.
Despite a favorable editorial & the Metabolism Award, our proposal to scale up to 65 patients & extend our cell culture work was rejected by the NIH/NCI, as they are committed to drug therapy. We appeal now to people who are interested in supporting promising dietary cancer research.
 Masko EM, Thomas JA, Antonelli JA, et al. Low-Carbohydrate Diets and Prostate Cancer: How Low Is “Low Enough”? Cancer prevention research (Philadelphia, Pa). 2010;3(9):1124-1131. doi:10.1158/1940-6207.CAPR-10-0071
 Siyuan Xia, Ruiting Lin, Lingtao Jin, et al. Prevention of Dietary-Fat-Fueled Ketogenesis Attenuates BRAF V600E Tumor Growth. Cell Metabolism (2016), http://dx.doi.org/10.1016/j.cmet.2016.12.010