A team of European scientists has found several specimens of thrips with pollen grains captured in amber, providing the oldest known evidence of insect pollination.
This synchrotron tomography image shows the specimen of Gymnospollisthrips minor studied at the ESRF. The pollen grains are highlighted in yellow (ESRF)
Today, more than 80% of plant species rely on insects to transport pollen from male to female flower parts. Pollination is best known in flowering plants but also exists in so-called gymnosperms, seed-producing plants like conifers. Although the most popular group of pollinator insects are bees and butterflies, a myriad of lesser-known species of flies, beetles or thrips have co-evolved with plants, transporting pollen and in return for this effort being rewarded with food.
During the last two decades, amber specimens from the Lower Cretaceous (about 110-105 million years ago) found in the Basque country in northern Spain have revealed many new plant and animal species, mainly insects.
Two amber pieces from the collection of the Museo de Ciencias Naturales de Álava in Spain revealed six fossilized specimens of thysanopterans, so-called thrips – a group of minute insects of less than 2 mm in length that feed on pollen and other plant tissues – with hundreds of pollen grains attached to their bodies. These insects exhibit highly specialized hairs with a ringed structure to increase their ability to collect pollen grains, very similar to the ones of well known pollinators like domestic bees. The scientists describe these specimens in a new genus comprising two new species: Gymnopollisthrips minor and G. major.
The most representative specimen was also studied with synchrotron X-ray tomography at the European Synchrotron Radiation Facility (ESRF) in Grenoble, France, to reveal in three dimensions and at very high resolution the pollen grain distribution over the insect’s body. The findings appear in the Proceedings of the National Academy of Sciences.
The pollen grains are very small and exhibit the adherent features needed so that insects can transport them. The scientists conclude that this pollen is from a kind of cycad or ginkgo tree, a kind of living fossil of which only a few species are known to science. Ginkgos trees are either male or female, and male trees produce small pollen cones whereas female trees bear ovules at the end of stalks which develop into seeds after pollination.
For which evolutionary reason did these tiny insects, 100 million years ago, collect and transport Gingko pollen? Their ringed hairs cannot have grown due to an evolutionary selection benefiting the trees. The benefit for the thrips can only be explained by the possibility to feed their larvae with pollen. This suggests that this species formed colonies with larvae living in the ovules of some kind of gingko for shelter and protection, and female insects transporting pollen from the male Gingko cones to the female ovules to feed the larvae and at the same time pollinate the trees.
Only amber can preserve behavioral features like pollination in such rich detail over millions of years. 100 million years ago, flowering plants started to diversify enormously, eventually replacing conifers as the dominant species.
“This is the oldest direct evidence for pollination, and the only one from the age of the dinosaurs,” said Dr. Carmen Soriano, who led the investigation of the amber pieces with X-ray tomography at the ESRF. “The co-evolution of flowering plants and insects, thanks to pollination, is a great evolutionary success story. It began about 100 million years ago, when this piece of amber fossil was produced by resin dropping from a tree, which today is the oldest fossil record of pollinating insects. Thrips might indeed turn out to be one of the first pollinator groups in geological history, long before evolution turned some of them into flower pollinators.”
