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UFS researchers investigate deadly fungi affecting millions in South Africa

12 June 2023 | Story André Damons | Photo Sonia Small

Prof Carolina Pohl-Albertyn — Prof Carlien Pohl-Albertyn, National Research Forum (NRF) SARChI Research Chair in Pathogenic Yeasts, leads the research team that is working on various research projects relating to fungi casing yeast.

Fungal infections affect more than one billion people each year, of which more than 150 million cases are severe and life-threatening, causing 1.7 million deaths a year. In South Africa it is estimated that diseases caused by fungal infections total more than three million cases a year. These figures are especially shocking given that prior to 1980, fungal infections were not a major health problem. The WHO has recently published a list of priority pathogens in which fungi are classified in critical, high- and medium- priority groups. Candida species are found in all three levels and Cryptococcus species in critical and medium groups,” says Prof Pohl-Albertyn.

It is for these reasons that researchers in the Department of Microbiology and Biochemistry at the University of the Free State (UFS) are working on various research projects investigating new treatment options beyond the established antifungals. Prof Carlien Pohl-Albertyn, National Research Forum (NRF) SARChI Research Chair in Pathogenic Yeasts, leads the team that is working on various research projects relating to fungi casing yeast.

Multidrug-resistant yeast

One of the yeasts being researched is Candida auris – a multidrug-resistant yeast that can cause severe infections in humans, particularly in people who are hospitalised or have weakened immune systems. C. auris was first identified in 2009 in Japan and has since been reported in over 49 countries.

According to Prof Pohl-Albertyn, C. auris is of concern because it is often resistant to multiple antifungal drugs, making it difficult to treat. In addition, it can survive on surfaces in healthcare settings, which can contribute to its spread between patients, causing outbreaks in hospitals. “Due to its multidrug resistance and potential for transmission, C. auris has been designated by the Centers for Disease Control and Prevention (CDC) as a serious global health threat and listed as the second most critical fungal pathogen in the World Health Organisation (WHO) fungal critical priority group.

“C. auris possesses virulence factors such as increased thermotolerance, high salinity tolerance, biofilm formation, and extra cellular enzyme secretion, which are the major contributing factors to its multidrug resistance profile and virulence. Even though C. auris has a variety of virulence factors that it employs against its human host to develop an infection, its virulence mechanisms remain unclear,” says Prof Pohl-Albertyn.

Therefore, several research projects investigate this pathogenic yeast. All of them started with the development of CRISP-Cas9 gene editing tools for this yeast, in order to be able to delete specific genes in this yeast to study their roles. These tools are also constantly being improved for greater efficiency by students under the supervision of Prof Koos Albertyn. Two current projects deal with the function of specific secreted enzymes in the virulence of C. auris.

Environmental yeast

Another yeast being researched, under the supervision of Prof Olihile Sebolai, is Cryptococcus neoformans, an environmental yeast found in trees and soil contaminated with bird droppings. Moreover, it can be airborne and when inhaled it lodges in the lungs (in alveoli) and can cause primary lung infection, explains Prof Pohl-Albertyn.

Cryptococcus neoformans causes AIDS-defining illnesses in people living with HIV/AIDS. To the point, it was not surprising when the WHO declared it as the first critical fungal pathogen of concern. Dissemination to other organs has been reported where it crosses the epithelium barrier by secreting proteases (a class of enzymes that break down proteins in the host) that compromise the tight junctions between the epithelial cells.

The current projects investigate the interaction between the proteases secreted by C. neoformans and co-infecting viruses, such as SARS-CoV-2 and influenza. The SARS-CoV-2 virus is activated by proteases in the host and proteases also help the influenza virus to enter and infect the host cells. Since the host proteases are similar to those secreted by C. neoformans, these projects are focused on determining if the yeast proteases can also help the viruses to cause infection. This project is also extended to study Candida albicans proteases as this is also a common co-infecting yeast in COVID-19 patients (for more detail on C. albicans).

Another project looks at the application of plants as sources for novel drugs against C. neoformans. This is important since 75-80% of African and Asian populations still rely on traditional or complementary/alternative medicines for their primary health-care needs. Coupled to this, modern medicines have become increasingly expensive and thus inaccessible to many in developing countries. Moreover, there is a shift to more “organic” and “vegan” lifestyles as well as the use of herbal medicines to prevent or manage the development of certain diseases.

Yeast contaminated water

“Considering the severity of invasive fungal infection, it is important to study the dissemination and proliferation of various pathogenic or potentially pathogenic fungal species in our surrounding environments. It is crucial to identify major vectors that aid in the spread of pathogenic yeast to prevent infections in susceptible individuals, which mainly include immunocompromised or immunosuppressed individuals.

“Candida, Cryptococcus and Rhodotorula species are commonly found in a variety of water sources with which humans are in frequent contact through daily activities like bathing, washing of clothes and cooking. This recent information further warrants the investigation into the possibility that fungal infections may occur through contact with yeast contaminated water,” concludes Prof Pohl-Albertyn.

She says it is thus important to investigate the presence and antifungal susceptibility of yeast found in water as well as to identify ways to monitor potential fungal outbreaks, possibly through wastewater surveillance. The research aims to identify potentially pathogenic yeast species as well as to quantify levels of azole, specifically fluconazole, in wastewater. In addition, the fluconazole susceptibility of these isolates will be assessed in an attempt to link azole pollution of the environment to antifungal drug resistance development.

News Archive

New world-class Chemistry facilities at UFS

2011-11-22

A world-class research centre was introduced on Friday 18 November 2011 when the new Chemistry building on the Bloemfontein Campus of the University of the Free State (UFS) was officially opened.
The upgrading of the building, which has taken place over a period of five years, is the UFS’s largest single financial investment in a long time. The building itself has been renovated at a cost of R60 million and, together with the new equipment acquired, the total investment exceeds R110 million. The university has provided the major part of this, with valuable contributions from Sasol and the South African Research Foundation (NRF), which each contributed more than R20 million for different facets and projects.
The senior management of Sasol, NECSA (The South African Nuclear Energy Corporation), PETLabs Pharmaceuticals, and visitors from Sweden attended the opening.

Prof. Andreas Roodt, Head of the Department of Chemistry, states the department’s specialist research areas includes X-ray crystallography, electrochemistry, synthesis of new molecules, the development of new methods to determine rare elements, water purification, as well as the measurement of energy and temperatures responsible for phase changes in molecules, the development of agents to detect cancer and other defects in the body, and many more.

“We have top expertise in various fields, with some of the best equipment and currently competing with the best laboratories in the world. We have collaborative agreements with more than twenty national and international chemistry research groups of note.

“Currently we are providing inputs about technical aspects of the acid mine water in Johannesburg and vicinity, as well as the fracking in the Karoo in order to release shale gas.”

New equipment installed during the upgrading action comprises:

X-ray diffractometers (R5 million) for crystal research. Crystals with unknown compounds are researched on an X-ray diffractometer, which determines the distances in angstroms (1 angstrom is a ten-billionth of a metre) and corners between atoms, as well as the arrangement of the atoms in the crystal, and the precise composition of the molecules in the crystal.
Differential scanning calorimeter (DSC) for thermographic analyses (R4 million). Heat transfer and the accompanying changes, as in volcanoes, and catalytic reactions for new motor petrol are researched. Temperature changes, coupled with the phase switchover of fluid crystals (liquid crystals -watches, TV screens) of solid matter to fluids, are measured.
Nuclear-magnetic resonance (NMR: Bruker 600 MHz; R12 million, one of the most advanced systems in Africa). A NMR apparatus is closely linked with the apparatus for magnetic resonance imaging, which is commonly used in hospitals. NMR is also used to determine the structure of unknown compounds, as well as the purity of the sample. Important structural characteristics of molecules can also be identified, which is extremely important if this molecule is to be used as medication, as well as to predict any possible side effects of it.
High-performance Computing Centre (HPC, R5 million). The UFS’ HPC consists of approximately 900 computer cores (equal to 900 ordinary personal computers) encapsulated in one compact system handling calculations at a billion-datapoint level It is used to calculate the geometry and spatial arrangements, energy and characteristics of molecules. The bigger the molecule that is worked with, the more powerful the computers must be doing the calculations. Computing chemistry is particularly useful to calculate molecular characteristics in the absence of X-ray crystallographic or other structural information. Some reactions are so quick that the intermediary products cannot be characterised and computing chemistry is of invaluable value in that case.
Catalytic and high-pressure equipment (R6 million; some of the most advanced equipment in the world). The pressures reached (in comparison with those in car tyres) are in gases (100 times bigger) and in fluids (1 500 times) in order to study very special reactions. The research is undertaken, some of which are in collaboration with Sasol, to develop new petrol and petrol additives and add value to local chemicals.
Reaction speed equipment (Kinetics: R5 million; some of the most advanced equipment in the world). The tempo and reactions can be studied in the ultraviolet, visible and infrared area at millisecond level; if combined with the NMR, up to a microsecond level (one millionth of a second.

Typical reactions are, for example, the human respiratory system, the absorption of agents in the brain, decomposition of nanomaterials and protein, acid and basis polymerisation reactions (shaping of water-bottle plastic) and many more.

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