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The numerate honey bee


The remarkable honey bee can tell the difference between different numbers at a glance. A fresh, astonishing revelation about the 'numeracy' of insects has emerged from new research by an international team of scientists from The Vision Centre, in Australia, published January 28 in the online, open-access, peer-reviewed journal PLoS ONE.

In an exquisitely designed experiment, researchers led by Dr. Shaowu Zhang, Chief Investigator of The Vision Centre and Australian National University and Professor Hans Gross and Professor Juergen Tautz of Wurzburg University in Germany, have shown that bees can discriminate between patterns containing two and three dots - without having to count the dots.

And, with a bit of schooling, they can learn to tell the difference between three and four dots.

However at four, bee maths seems to run out: the team found their honeybees couldn't reliably tell the difference between four dots and five or six.

In the study, the bees flew though an entry of a Y-maze marked with a pattern of either two or three dots, which were signposts to the reward. They then had to choose between two patterns by correctly matching the number of dots, to find where the reward was - a feat they then managed to repeat reliably once they had learned that two dots at the first entry meant they had to look for two dots at one of the second pair of patterns, where the reward was hidden.

Careful control over the experimental environment showed the bees were not using colour, smell or other clues to find their way to the hidden sugar-water reward, says Dr. Zhang.

"My colleague Professor Srinivasan has demonstrated that bees can count up to four landmarks on their way from their hive to a food source. This new research shows they can tell the difference between different numbers - even when we change the pattern, shape or the colour of the dots!"

Presenting blue and yellow dots, stars and lemons, or random patterns didn't fool the clever insects, which continued to reliably navigate their way to the reward once they had figured out and memorised what the signs meant, based on number.

To begin with, the bees spent quite a bit of time scanning the dots. On later visits they zipped straight past them, once they knew what they meant.

"Bees can definitely recognise the difference between two, three and four - although four a little less reliably. This is a process known as 'subitizing' - which means responding rapidly to a small number of items.

"We think the bees are using two memory systems," Dr. Zhang says. "First is working memory, which they use to recall the number of dots that point to the reward. The second system is to use memory rules. We found this out by changing the pattern of the dots - but the bees still managed to locate the reward."

The experiment also demonstrates the remarkable learning power of social insects, which have to go out foraging over long distances - the Vision Centre team has tracked bees over distances as great as 11 kilometres - and then find their back to the hive, and out to the food source again reliably.

Dr. Zhang says the ability to discriminate between different numbers is part of this navigation, perhaps as bees pass clumps of two trees or three trees on their way to the food source, or use similar patterns among flowers or other landmarks as they draw close to it.

"There has been a lot of evidence that vertebrates, such as pigeons, dolphins or monkeys, have some numerical competence - but we never expected to find such abilities in insects. Our feeling now is that - so far as these very basic skills go - there is probably no boundary between insects, animals and us."

The tantalising question is whether bees can actually perform elementary arithmetic - and Shaowu and his colleagues are already planning an experiment to explore it.

The team's paper "Number-based visual generalization in the honeybee" appears in the international scientific journal PLoS ONE January 28.



Dr. Shaowu Zhang
The Vision Centre and ANU
Tel: +61 (0)2 6125 5094

Professor Hans Gross
University of Wurzburg
Tel: +49 931 888 4027

Professor Juergen Tautz
University of Wurzburg
Tel: +49 931 888 4319

Professor Trevor Lamb
The Vision Centre
Tel: +61 2 61258929 or 0434022375

Professor Julian Cribb
The Vision Centre media contact, 0418 639 245

Citation: Gross HJ, Pahl M, Si A, Zhu H, Tautz J, et al. (2009) Number-Based Visual Generalisation in the Honeybee. PLoS ONE 4(1): e4263. doi:10.1371/journal.pone.0004263




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