A new study shows that each spider constructs a net of silk in vegetation beneath the surface and fills it with air carried down on its abdomen - and the spiders can use the diving bell like a gill to extract oxygen from water to remain hidden beneath the surface.
Having already used an oxygen-measuring device called an optode to discover how aquatic insects extract oxygen from water through thin bubbles of air stretched across their abdomens, Roger Seymour from the University of Adelaide was looking for other small bubbles to test his optode.
He got together with Stefan Hetz from Humboldt University, Germany to collect some of the arachnids to find out how they use their diving bells. Diving bell spiders are becoming increasingly rare in Europe but after obtaining a permit to collect the elusive animals, they gathered some in the Eider River. Returning to the lab, they reproduced the conditions in a warm stagnant weedy pond on a hot summer's day to find out how the spiders fare in the most challenging of conditions.
After watching the spiders build their diving bells, the duo gingerly poked an oxygen sensing optode into the bubble to see how the animal reacted. Miraculously, the spider was unperturbed, so they continued recording the oxygen level. "Then it occurred to me that we could use the bubble as a respirometer," says Seymour, to find out how much oxygen the spiders consume.
Taking a series of oxygen measurements in the bubble and surrounding water, the team calculated the amount of oxygen flowing into the bubble before calculating the spider's oxygen consumption rate and found that the diving bell could extract oxygen from the most stagnant water even on a hot day. Also, the metabolic rate of the aquatic spider was low and similar to the low metabolic rates of other spiders that sit waiting for prey to pass.
However, despite satisfying the spider's oxygen demands, the bubble continually shrinks because nitrogen diffuses back into the water, eventually forcing the occupant to venture to the surface to resupply the diving bell. So how long could the bubble survive before the spider had to dash up for air? Calculating the diffusion rate of nitrogen out of the bubble, Seymour and Hetz were surprised to find that the spiders could sit tight for more than a day. "The previous literature suggested they had to come to the surface as often as every 20 minutes throughout the day," comments Seymour, who adds, "It is advantageous for the spiders to stay still for so long without having to go to the surface to renew the bubble, not only to protect themselves from predation but also so they don't alert potential prey that come near."
Citation: Roger S. Seymour and Stefan K. Hetz, 'The diving bell and the spider: the physical gill of Argyroneta aquatica', The Journal of Experimental Biology, doi: 10.1242/jeb.056093