Wednesday, 5 June 2013

E-I-E-I-O


It is an undeniable fact that as a species we are the dominant animal on the planet. We compliment ourselves on the fact that this dominance is due to our intelligence and ingenuity, the occurrence of which is thought to have arisen from the increased nutrition and resource availability and release from foraging time brought about by the agricultural revolution. The revolution has fuelled the quest for knowledge that makes our species unique; particularly knowledge of other life - be it terrestrial or beyond. Most people would agree that there are other animals on the planet that show forms of intelligence close to our own, but in my experience perceptions tend to be restricted to analogous mammalian groups. It is interesting, then, to discover that this agricultural behaviour has actually evolved nine other times in the animal kingdom, in each case among the insects. Having begun so grandiose in my introduction, it is to the ants, termites and ambrosia beetles we now look.

With 220 species of ants from the tribe Attini ('Attine' ants), 3400 species of ambrosia beetles (a subfamily of weevil, Scolytinae) and 330 termite species from the Macrotermitinae subfamily, our species gets few innovation points for our farming behaviour. However as with all convergent evolution, the same behaviour is achieved in slightly different ways. Where we are above-ground plant growers, all these species are growers of fungus away from light, and where we maintain other culinary prospects, these all these species rely on their cultivated fungi for their only source of sustenance. 

Ant fungiculturalists (for which you can also visit this blog) use a variety of fresh organic substrates on which to grow fungi, from leaves and flowers to seeds and wood. The specific fungus used by each colony is passed on to daughter queen ants before they leave the nest. They transport a sample of the cultivar in pouches present in their mouth-parts and use it to establish their own gardens. Similarly, termite fungiculturalists are specialised to a single genus of fungi, that of Termitomyces, and their life cycle is synchronised with the fruiting of the fungus. Special chambers are allocated inside termite mounds for fungal growth, and they grow their gardens on dead or partially decomposing plant material. Ambrosia beetles tunnel into the wood of trees and maintain the fungal growth that occurs on the excavated walls. Like the ants, these beetles also transport their fungus from old to colonising areas, but instead of mouth pouches, the beetle uses specialised pouches along their body. However, unlike the Attini and termites, an ambrosia beetle's fungal garden is cared for only by the colonising female, which means that if she dies, the fungi will overrun her brood. All three types of insect gardens are also a diverse culture of bacteria and yeasts.


For 50 million years of agricultural success to our 10 thousand years, you might expect these farmers to be experts on agricultural sustainability. So, to maintain our intelligence, we must ask: what can we learn from these insects?

Plant mono-cultures are often identified as one of the weaker aspects of our own husbandry of the land, as minimal diversity opens systems to more effective removal by a single pathogen. Yet all farming insects use mono-cultures. They minimise the problems of such systems using a combination of strategies: isolating and sealing gardens underground to reduce potential for infection, continuously monitoring crops using a myriad of workers, maintaining genetic diversity of the crops by trading cultivars amongst populations, and managing microbes that suppress crop diseases. 

Of these techniques, microbial management of plants seems the most practical and likely option for improving our own agricultural systems. Microbes are known to increase pathogen resistance in some of our own crops, but the microbial composition of the soil is difficult to control. Prior to planting, insects farmers will partially or completely sterilise the substrate into which they plant their fungi. Designing our own agricultural systems to more effectively take advantage of beneficial microbes is a step in the same direction as these green tarsal-clawed gardeners.

It seems that, while our search for intelligent life continues, intelligent lifestyles are right under our toes. 

I cannot recommend 
The Evolution of Agriculture in Insects by Mueller, Gerardo, Aanen, Six and Schultz enough. And thanks to xkcd for the cartoon catalyst.

2 comments:

  1. How extraordinarily fascinating! These little guys never cease to amaze me. Such incredibly complex behaviour carried out by our pinhead brethren. what an incredible co-evolution between animal and fungus, I wonder if they ever show any signs of fungal breeding. I suppose they would pair up with other wood-destroying organisms. This may be an obvious question, but What to the ants and termite do with their fungal gardens? Eat it? Make mushroom soup?

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  2. Yes, they do breed their fungi to select for and maximise desirable traits such as pathogen resistance, which is why every fungus culture tends to be unique within a colony. In ants it is the desirable genetics that have been selectively bred by a colony that is preserved when the daughter ants take their own sample to found a new colony, just like our own selective breeding and seed-sharing. They pair up with the yeasts and bacteria I mentioned in order to maximise their production.
    Haha, yes, unlike ourselves they rely fully on their cultivated fungi as a food substance. The fungi are used primarily to feed their larvae. Ants are able to feed on plant juices but because the fungi are so nutritional, they rarely do so. In most cases, all parts of the fungus is consumed directly and indiscriminately, though the termites preferentially consume the nodules of their specialised mushrooms when available because these have the highest nutritional value. There is so much to be amazed about in these systems. They are really amazingly complex.

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