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27 May 2024 | Story Leonie Bolleurs | Photo Supplied
Inaugural
At the inaugural lecture of Prof Dirk Opperman were, from the left: Prof Opperman, Prof Vasu Reddy, Prof Koos Albertyn, Head of the Department of Microbiology and Biochemistry, and Prof Paul Oberholster, Dean of the Faculty of Natural and Agricultural Sciences.

Prof Dirk Opperman, a distinguished biochemist in the Department of Microbiology and Biochemistry, recently (21 May 2024) delivered his inaugural lecture on the Bloemfontein Campus of the University of the Free State (UFS).

The title of his lecture was: Exploring, Exploiting, and Evolving Life at the Atomic Level.

Prof Vasu Reddy, Deputy Vice-Chancellor: Research and Internationalisation at the UFS, welcomed guests, stating, "An inaugural lecture is a major milestone, celebrating a life’s work that culminates in the title of professor. It marks an important chapter in an academic career, with much more to be achieved in the journey of producing important knowledge.”

He believes that an event such as this highlights the university’s pride in the achievements of its academic staff and aligns with Vision 130. “The UFS is proud to host such lectures, as they are significant moments to reveal and showcase the value of excellence in our knowledge pool in research, teaching, and innovation. As a university, we strive to make a difference through groundbreaking work, particularly in addressing society's challenges,” said Prof Reddy, emphasising that this topic truly speaks to the university’s commitment to impactful work in the hard sciences.

Deciphering the unknown

The topic of the lecture captures the essence of Prof Opperman’s research. He explains that ‘exploring’ refers to the determination of the three-dimensional structures of proteins and enzymes. ‘Exploiting’ involves the use of these enzymes to convert substrates into products of value, and ‘evolving’ pertains to mutating the DNA to change the protein, giving it different functions, activities, selectivity, or specificities.

In his lecture, he remarked that if we know the structures of these proteins and enzymes, we can explore what to do with them and how to change them. According to him, there are the unknown knowns, the unknown unknowns, and the known unknowns. “We may know of specific activities and reactions by microorganisms, but we don’t know which enzyme is responsible; similarly, we can know the reactivity of an enzyme, but not necessarily their true physiological functions. I am trying to figure out all these unknowns,” he said.

In his lecture, he also raised the question of whether AI could replace experimental determination of protein structures. "No, not yet; it is only predictions," he believes, commenting that navigating the unknown unknowns is a dangerous place in science.

Establishing the field of structural biology

Prof Opperman, born and raised in the Free State, completed his undergraduate studies at the UFS. Later, in 2008, he obtained his PhD in Biochemistry from the same university. Following his doctoral studies, he conducted postdoctoral research on directed evolution under the guidance of Prof Manfred T Reetz at the Max Planck Institute for Coal Research in Germany, one of the world’s top institutions.

In 2010, he was appointed to the Department of Microbiology and Biochemistry at the UFS, where he has since established the field of structural biology, setting up the infrastructure essential for the advancement thereof. This includes equipment, techniques, and methods for determining the three-dimensional structure of proteins. “It is done using protein crystallisation and then X-ray diffraction,” he explains. Most of these X-ray diffraction experiments are then performed at particle accelerators called synchrotrons, such as Diamond Light Source (UK), which can produce intense X-rays.

His current research explores the interface of evolutionary and structure-function relationships of biocatalysts, with a particular focus on their application in green chemistry. Prof Opperman says that understanding both the structure and the function of an enzyme allows one to manipulate it to perform other functions.

Contributing to the broader goals of sustainable development

One of the projects he is working on highlights the potential for sustainable practices in waste management. Prof Opperman is currently part of a European Research Area Network Cofund partnership on Food Systems and Climate (FOSC), which focuses on developing biocatalysts for upcycling waste. An aspect of this work involves studying enzymes that degrade feathers, thereby converting feather waste into useful products such as fertiliser.

Regarding the contribution of his research to the broader goals of sustainable development and environmental protection, he says that enzymes are the base for biotechnology and the bioeconomy. “They can be sustainably produced, the reactions are environmentally friendly, and the resulting products can be classified as natural. There’s no need to use sources that are not sustainable to extract some of these molecules from,” he explains.

His significant contributions to the field are reflected in more than 50 authored and co-authored papers, some of which are published in prestigious journals such as Science, Nature Communications, and Angewandte Chemie. As an NRF B-rated researcher, his work has received funding from various local and international organisations, including industries such as Sasol and the Global Challenges Research Fund.

News Archive

Link between champagne bubbles and the UFS?
2012-11-16

Prof. Lodewyk Kock with an example of a front page of the publication FEMS Yeast Research, as adapted by F. Belliard, FEMS Central Office.
Photo: Leatitia Pienaar
15 November 2012

What is the link between the bubbles in champagne and breakthrough research being done at the Mayo Clinic in America? Nano research being done at our university.

Prof. Lodewyk Kock of Biotechnology says a human being consists of millions of minute cells that are invisible to the eye. The nano technology team at the UFS have developed a technique that allows researchers to look into such a cell, as well as other microorganisms. In this way, they can get an idea of what the cell’s “insides” look like.

The UFS team – consisting of Profs. Kock, Hendrik Swart (Physics), Pieter van Wyk (Centre for Microscopy), as well as Dr Chantel Swart (Biotechnology), Dr Carlien Pohl (Biotechnology) and Liza Coetsee (Physics) – were amazed to see that the inside of cells consist of a maze of small tunnels or blisters. Each tunnel is about 100 and more nanometres in diameter – about one ten thousandth of a millimetre – that weaves through the cells in a maze.

It was also found that these tunnels are the “lungs” of the cells. Academics doing research on yeast have had to sit up and take notice of the research being done at the UFS – to the extent that these “lungs” will appear on the front page of the highly acclaimed FEMS Yeast Research for all of 2013.

The Mayo Clinic, in particular, now wants to work with the UFS to study cancer cells in more detail in order to fight this disease, says Prof. Kock. The National Cancer Institute of America has also shown interest. This new nano technology for biology can assist in the study and development of nano medicine that can be used in the treatment of cancer and other life threatening diseases. Nano medicine uses nano metal participles that are up to one billionth of a metre in size.

Prof. Kock says laboratory tests indicate that nano medicine can improve the efficacy of anti-cancer medicine, which makes the treatment less toxic. “According to the Mayo Clinic team, nano particles are considered as a gold cartridge which is being fired directly at a cancer tumour. This is compared to fine shot that spreads through the body and also attacks healthy cells.”

“This accuracy implies that the chemotherapy dose can be lowered with fewer side effects. The Mayo Clinic found that one-tenth of the normal dosage is more effective against pancreas cancer in this way than the full dosage with a linkage to nano particles. According to the clinic, this nano medicine could also delay the spread of cancer,” says Prof. Kock.

The nano particles are used as messengers that convey anti-cancer treatment to cancer cells, where it then selectively kills the cancer cells. The transport and transfer of these medicines with regard to gold nano particles can be traced with the UFS’s nano technology to collect more information, especially where it works on the cell.

“With the new nano technology of the UFS, it is possible to do nano surgery on the cells by slicing the cells in nanometre thin slices while the working of the nano medicine is studied. In this way, it can be established if the nano medicine penetrates the cells or if it is only associated with the tiny tunnels,” says Prof. Kock.

And in champagne the small “lungs” are responsible for the bubbles. The same applies to beer and with this discovery a whole new reach field opens for scientists.

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