FOCUS TOPIC: Using BESSY II to combat plastic waste

At the MX-Beamlines at BESSY II, Gottfried Palm, Gert Weber and Manfred Weiss could solve the 3D structure of MHETase.

At the MX-Beamlines at BESSY II, Gottfried Palm, Gert Weber and Manfred Weiss could solve the 3D structure of MHETase. © F. Krawatzek/HZB

MHET-molecules from PET plastic dock at the active site inside the MHETase and are broken down into their basic building blocks.

MHET-molecules from PET plastic dock at the active site inside the MHETase and are broken down into their basic building blocks. © M. Künsting/HZB

MHETase at work: a MHET-molecule (which is a building block of PET) is broken down into the basic building blocks terephthalic acid and ethylene glycol.

MHETase at work: a MHET-molecule (which is a building block of PET) is broken down into the basic building blocks terephthalic acid and ethylene glycol. © Gert Weber/HZB

Plastics are excellent materials: extremely versatile and almost eternally durable. But this is also exactly the problem, because after only about 100 years of producing plastics, plastic particles are now found everywhere – in groundwater, in the oceans, in the air, and in the food chain.

Just a tiny fraction of plastics is currently recycled at all by expensive and energy-consuming processes which yield either downgraded products or depend in turn on adding 'fresh' crude oil.

An important plastic is PET, which is used, among other things, for the production of plastic bottles. Approximately 50 million tons of PET are newly produced every year. Now there could be a new process to break PET down into its basic materials and recycle it without sacrificing quality.

Japanese researchers discovered bacteria that degrade PET

In 2016, a group of Japanese researchers has discovered a bacterium that grows on PET and partially feeds on it. They found out that his bacterium possesses two special enzymes, PETase and MHETase, which are able to digest PET plastic polymers. PETase breaks down the plastic into smaller PET building blocks, primarily MHET, and MHETase splits this into the two basic precursor building blocks of PET, terephthalic acid and ethylene glycol. Both components are very valuable for synthesising new PET without the addition of crude oil - for a closed sustainable production and recovery cycle.

Structure of PETase was solved in 2018

In April 2018, the structure of PETase was finally solved independently by several research groups, the Diamond Light Source was also involved in the experiments. However, PETase is only part of the solution. It is equally important to characterize the structure of the second enzyme, MHETase.

Decoding the complex structure of MHETase at BESSY II

“MHETase is considerably larger than PETase and even more complex. A single MHETase molecule consists of 600 amino acids, or about 4000 atoms. MHETase has a surface that is about twice as large as the surface of PETase and has therefore considerably more potential to optimise it for decomposition of PET“, explains biochemist and structural biologist Dr. Gert Weber from the joint Protein Crystallography research group at the Helmholtz-Zentrum Berlin and Freie Universität Berlin.

During an interim professorship at the University of Greifswald, Weber there contacted the biotechnologist Prof. Uwe Bornscheuer at the Institute of Biochemistry, who was already involved with plastic-degrading enzymes. Together, they developed the idea of solving the structure of MHETase and then using this insight to optimise the enzyme for applications in PET recycling. To do this, they first had to extract the enzyme from bacterial cells and purify it.

Within this collaboration, the teams have now succeeded in obtaining the complex three-dimensional architecture of MHETase at BESSY II, the synchrotron source at HZB in Berlin.

MHETase observed "in action"

“In order to see how MHETase binds to PET and decomposes it, you need a fragment of plastic that binds to MHETase but is not cleaved by it”, explains Weber. A member of Weber's prior research team in Greifswald, Dr. Gottfried Palm, cut up a PET bottle, chemically decomposed the PET polymer and synthesised a small chemical fragment from it that binds to MHETase but can no longer be cleaved by it. From this 'blocked' MHETase, tiny crystals were grown for structural investigations at the HZB. “The structural investigations enabled us to watch MHETase virtually ‘at work’ and develop strategies for how to optimise this enzyme”, explains Weber.

“Thanks to the joint research group format, we have the means to offer beamtime access on the highly demanded BESSY II MX beamlines for measurements very quickly at any time”, says Dr. Manfred Weiss, who is responsible for the BESSY II MX beamlines. The three-dimensional architecture of MHETase actually displays some special features: enzymes such as MHETase bind to their target molecule first before a chemical reaction occurs. For breakdown of a molecule you need a tailor-made enzyme: “We can now exactly localise where the MHET molecule docks to MHETase and how MHET is then split into its two building blocks terephthalic acid and ethylene glycol”, says Weber.

Next steps: Increasing the efficiency

However, neither PETase nor MHETase are particularly efficient yet. ”Plastics have only been around on this scale for a few decades – even bacteria with their rapid successions of generations and rapid adaptability have not managed to develop a perfect solution through the evolutionary process of trial and error over such a short time”, explains Weber. "Thanks to the clarification of the structure of this very important enzyme, we have now also been able to plan, produce and biochemically characterise variants that show significantly higher activity than natural MHETase and are even active against another intermediate product of PET degradation, BHET," adds Uwe Bornscheuer.

In future, Uwe Bornscheuer will work on systematically optimising the enzymes PETase and MHETase for their task - the decomposition of PET. Gert Weber plans to supplement these studies with further work on biological structures in order to systematically develop plastic-digesting enzymes for environmental applications. Access to the measuring stations and the IT infrastructure of HZB is indispensable for this.

The goal is a genuine recycling process for PET materials. Access to BESSY II light is important for this.

Producing these kinds of enzymes in closed biotechnological cycles, for example, could be a way to really break down PET plastics and other polymers into their basic building blocks. This would also be the key to ideal recycling and a long-term solution to the plastic waste problem: production of plastic would be a closed cycle and no longer dependent on crude oil.

The focus topic is based on the news published on 12.04.2019.

Published in Nature Communications (2019): "Structure of the plastic-degrading Ideonella sakaiensis MHETase bound to a substrate"; G.J. Palm, L. Reisky, D. Böttcher, H. Müller, E.A.P. Michels, C. Walczak, L. Berndt, M.S. Weiss, U.T. Bornscheuer and G. Weber

DOI: 10.1038/s41467-019-09326-3

arö (bearb. sz)

  • Copy link

You might also be interested in

  • Battery research with the HZB X-ray microscope
    Science Highlight
    18.11.2024
    Battery research with the HZB X-ray microscope
    New cathode materials are being developed to further increase the capacity of lithium batteries. Multilayer lithium-rich transition metal oxides (LRTMOs) offer particularly high energy density. However, their capacity decreases with each charging cycle due to structural and chemical changes. Using X-ray methods at BESSY II, teams from several Chinese research institutions have now investigated these changes for the first time with highest precision: at the unique X-ray microscope, they were able to observe morphological and structural developments on the nanometre scale and also clarify chemical changes.
  • BESSY II: New procedure for better thermoplastics
    Science Highlight
    04.11.2024
    BESSY II: New procedure for better thermoplastics
    Bio-based thermoplastics are produced from renewable organic materials and can be recycled after use. Their resilience can be improved by blending bio-based thermoplastics with other thermoplastics. However, the interface between the materials in these blends sometimes requires enhancement to achieve optimal properties. A team from the Eindhoven University of Technology in the Netherlands has now investigated at BESSY II how a new process enables thermoplastic blends with a high interfacial strength to be made from two base materials: Images taken at the new nano station of the IRIS beamline showed that nanocrystalline layers form during the process, which increase material performance.
  • Hydrogen: Breakthrough in alkaline membrane electrolysers
    Science Highlight
    28.10.2024
    Hydrogen: Breakthrough in alkaline membrane electrolysers
    A team from the Technical University of Berlin, HZB, IMTEK (University of Freiburg) and Siemens Energy has developed a highly efficient alkaline membrane electrolyser that approaches the performance of established PEM electrolysers. What makes this achievement remarkable is the use of inexpensive nickel compounds for the anode catalyst, replacing costly and rare iridium. At BESSY II, the team was able to elucidate the catalytic processes in detail using operando measurements, and a theory team (USA, Singapore) provided a consistent molecular description. In Freiburg, prototype cells were built using a new coating process and tested in operation. The results have been published in the prestigious journal Nature Catalysis.