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Germany: Polymerase Chain Reaction Could Jurassic Park Become Real? DNA Extraction from Insects Trapped in Resin

Editor: MA Alexander Stark

For the first time, scientists successfully extracted genetic material from insects that were embedded in six- and two-year-old resin samples. DNA – in particular, DNA from extinct animals – is an important tool in the identification of species.

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Senckenberg researcher Mónica Solórzano-Kraemer with one of the examined resin samples.
Senckenberg researcher Mónica Solórzano-Kraemer with one of the examined resin samples.
(Source: Xavier Delclòs)

Frankfurt am Main/Germany — Insects embedded in resin whose genetic material will be extracted for research purposes – this idea inevitably invokes memories in many readers of the blockbuster “Jurassic Park.” “However, we have no intention of raising dinosaurs,” laughs Dr. Mónica Solórzano-Kraemer of the Senckenberg Research Institute and Natural History Museum. Rather, their current study is a structured attempt to determine how long the DNA of insects enclosed in resinous materials can be preserved.

To this end, lead author Dr. David Peris of the University of Bonn, the amber researcher from Frankfurt, and researchers from the Universities of Barcelona and Bergen and the Geominero Museum (IGME) in Valencia examined the genetic material of so-called ambrosia beetles that were trapped in the resin of amber trees (Hymenaea) in Madagascar. “Our study fundamentally aimed to clarify whether the DNA of insects embedded in resin continues to be preserved. Using the polymerase chain reaction (PCR) method, we were able to document that this is indeed the case in the six- and two-year-old resin samples we examined,” explains Solórzano-Kraemer.


To date, similar tests of inclusions in several million-year-old amber and several thousand-year-old copals had failed, since more recent environmental impacts had caused significant changes to the DNA of the embedded insects or even destroyed it. Therefore, resin-embedded samples were deemed unsuitable for genetic examinations. Solórzano-Kraemer adds, “We were now able to show for the first time that, although it is very fragile, the DNA was still preserved in our samples. This leads to the conclusion that it is possible to study the genomics of organisms embedded in resin.”

It is still not clear just how long the DNA can survive inside the resin. To address this question, the researchers plan to apply the method in a stepwise fashion from the most recent to the oldest samples to determine the “shelf life” of the resin-embedded DNA.

The scientists' experiments show that water in the inclusions is preserved much longer than previously assumed. This could also affect the genetic material’s stability. “The extraction of functional DNA from several million-year-old amber is therefore rather unlikely,” adds Solórzano-Kraemer in conclusion.

Publication: David Peris, Kathrin Janssen, H. Jonas Barthel, Gabriele Bierbaum, Xavier Delclòs, Enrique Peñalver, Mónica M. Solórzano-Kraemer, Bjarte H. Jordal & Jes Rust (2020): DNA from resin-embedded organisms: past, present and future. PLOS ONE. DOI:

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