Image: Wasp in amber
A parasitic wasp (Hymenopteran evaniidae) is trapped among spider webbing in 136 million-year-old amber.
updated 6/22/2006 2:39:35 PM ET 2006-06-22T18:39:35

A spider's orb web is one of the most impressive architectural feats in nature, capturing morning dew and insect meals with equal grace.

But webbing rarely stands the test of time, especially over millions of years, and researchers have few samples of ancient web to study.

Now, scientists have found a 136 million-year-old piece of amber encasing pieces of web and trapped insects. The finding helps fill in the gaps of the origin of orb webs, and also indicates predatory spiders likely played a role in the evolution of flying insects. The study is detailed in Friday's issue of the journal Science.

The hunk of amber, which was collected in Spain, contains 26 web strands with a mite, a wasp leg, and a beetle stuck to some of the thread by visible droplets of web "glue." Although these insects are extinct, their size and diversity match the type of prey caught in modern webs.

"The advanced structure of this fossilized web, along with the type of prey that the web caught, indicates that spiders have been fishing insects from the air for a very long time," said study co-author David Grimaldi of the American Museum of Natural History in New York.

The amber is the oldest known example of a web with trapped insects. Although only few pieces of the web remain, the arrangement of the preserved bits strongly suggests an orb web design.

Driving diversity
The orientation of the web indicates that it was strung between objects and hung in the air. The emergence of hanging spider webs might have influenced the evolution of flying insects.

For example, Grimaldi said, members of the family Lepidoptera, which includes moths and butterflies, are covered in scales that allow them to tumble out of sticky webs.

"And it happens that Lepidoptera evolved around the same time that spiders produced these webs," Grimaldi told LiveScience.

The types of insects caught in the fossilized web are important pollinators today, and may have been darting from flowering plant to flowering plant when they were captured by the web. Agile, powerful fliers with good vision, such as bees, would also stand a better chance of avoiding webs, much as they do today. Small, weak flies or less nimble fliers would have been, and still are, more commonly ensnared.

Image: Two spider orb webs
Brent Opell (left) and Mark Chappell (right)
These two images show two examples of orb-web types. The image on the left shows the orb web of a deinopoid spider, Waitkera waitakerensis (Chamberlain) from Piha, New Zealand. The image on the right shows the orb web of an araneoid spider, Argiope trifasciata, from Palo Alto, Calif. Genetic analysis of the spiders indicates that they had a common origin.

How webs work
The finding sets the minimum age for the common ancestor of the two groups of spiders that weave orb webs, Araneoidea and Deinopoidea.

Because the two groups use different tricks to snag prey — Deinopoids create a Velcro-like surface to catch insects, while Araneoids cover their webbing with a sticky "glue" substance—scientists had long believed the orb web design was an example of convergent evolution, a process in which two organisms develop remarkably similar traits.

Along with the age of the amber fossil, genetic analysis of the two spider families, detailed in another paper in the same issue of Science, indicates a common origin for orb web design.

The protein building blocks that make up spider silk are of interest to other scientists and industry because of their remarkable strength, stretchiness, and toughness. Potential applications include better bandages, bulletproof fibers, aerospace tethers, and nets.

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