I love the flavor that develops from lacto fermenting mushrooms. I’m a little bit suspicious of white button mushrooms (Agaricus species) since they contain agaritine. Agaritine is broken down by heat, making it safe. If you eat raw Agaricus, the agaritine is made into phenylhydrazines in the gut, which causes liver damage and can eventually make you anemic. Under no circumstances should you eat raw Agaricus.
So what about lacto-fermenting them? We know agaritine is heat sensitive. Is it also sensitive to microbial activity, so that it breaks down?
It is true. I am not sure, the articles do not address this specific question. It would depend on the process and the amount of time that you let it ferment. Over a period of weeks, it is likely that the mushrooms will have died, the cell membranes will have broken down, and the chemistry of degradation described in those papers will have taken place.
Fresh mushrooms are still alive at the beginning of the process. Until they die, the mushroom’s cells may continue to produce agaritine, and the chemistry inside of the cells is not necessarily going to be the same as in tap water. The amount of time that it will take for the cells to die depends on the process. If you are submerging the mushrooms into a brine, I don’t think that they will survive for long because of the osmotic pressure.
OK, I’m trying to follow your logic. My understanding is that you assume: (1) When the mushrooms are alive, they will continue to produce agaritine, (2) When the mushrooms are dead, they will stop producing agaritine, (3) When they are dead, they will release the agaritine to the brine so that the compound will be affected in a similar way to the papers above. Both (1) and (2) seem very plausible. I’m less sure about (3), but am I following you well?
Yes, this is what I mean.
As for (3), this is how I am reasoning about this. The mushroom cells are surrounded by a soft cell membrane made out of lipids, and a hard cell wall made out of a network of sugar filaments (primarily chitin). The cell membrane serves as a chemical barrier that separates the chemistry outside of the cell from the chemistry inside of the cell, and it has many mechanisms to allow specific chemicals to flow from one side to the other. This cell membrane is very dynamic and it needs continuous maintenance to remain functioning as intended. When a cell dies, the cell membrane is no longer kept under maintenance, and it basically dissolves.
After the cell membrane disintegrates, the cell wall remains. This cell wall is much tougher and does not require constant maintenance. The wall also has its own filtering capacity as well the ability to absorb and retain chemicals, but it is a lot more porous and this porosity allows water, nutrients, and other water-soluble chemicals to move more freely.
So, my reasoning is: The mushroom dies. The cell wall disintegrates. The more permeable cell wall remains. Agaritine is soluble in water, and water and small water-soluble molecules can usually move freely through the cell wall. So, within a short period of time the water outside of the mushrooms will mix with the water inside of the mushrooms, and the agaritine will distribute throughout the whole volume. At this point, even if the mushroom’s environment had provided some form of protection, the now-mixed agaritine will experience an environment similar to the environments discussed in the papers I from the previous comments.
It is not as simple as I describe here, because the specific properties of the cell wall can be complex, and they can change due to chemical modifications. For example, some molecules can be absorbed into the sugar matrix such that they are protected from degradation - but I could not find any data to suggest that this likely a significant factor for agaritine. There are some recent articles that review the fungal cell wall, I will paste the citations below, in case you want to look at some of this in more detail.
Gow, N. A., & Lenardon, M. D. (2023). Architecture of the dynamic fungal cell wall. Nature Reviews Microbiology, 21(4), 248-259.
Latgé, J. P., & Wang, T. (2022). Modern biophysics redefines our understanding of fungal cell wall structure, complexity, and dynamics. Mbio, 13(3), e01145-22.
Interesting. We’re getting close to actual research territory here and it seems your hypothesis is something that could be worth testing. Until then, I find it plausible and I’ll probably continue using moderate amounts of lacto-fermented Agaricus on the assumption that the agaritine is released into the brine and then subsequently degraded.
I think it would be an interesting hypothesis to test.
I looked a bit more and extended my search into brines, and was able to find another set of data in the following paper:
Roupas, P., Keogh, J., Noakes, M., Margetts, C., & Taylor, P. (2010). Mushrooms and agaritine: A mini-review. Journal of Functional Foods, 2(2), 91-98.
This one is not freely available, but it is found in SciHub and I can also share the PDF if needed.
This relevant section discusses that mushrooms canned in liquid and in brine were measured to have less agaritine, which makes sense. I think that lactofermentation helps degrade even more due to the acid, additional metabolic activity, and possibly a bit more oxygen.
I agree that it would be nice to research. I am surprised that it hasn’t been (or at least it is not easy to find). I did find research on other methods such as heating and drying, but I could not find lacto fermentation…