Research by a team led by Dr Elizabeth Fullam, has revealed new findings about an enzyme found in Mycobacterium tuberculosis (Mtb), the bacterium that causes TB.
TB causes more deaths than any other infectious disease, including from HIV and malaria. In 2016 there were 10.4 million new cases of TB and 1.7 million people died. The rise in cases of TB that are resistant to the current therapies that are available means that there is an urgent need to develop new TB therapeutics.
Mtb is a highly unique bacterium and is enclosed within a distinctive cell wall that is comprised of unusual sugars and lipids which protect the bacteria from the host environment. Disruption of essential pathways involved in the assembly of the Mtb cell wall is an attractive approach for new TB drugs.
The team found a key structural motif in the tuberculosis N-acetylglucosamine-6-phosphate deacetylase (NagA) enzyme. Attacking this structural motif through the design and exploitation of new molecules will enable scientists to inhibit this critical pathway and kill TB.
Using the X-ray facilities at the Diamond Light Source, Harwell, they were provided with detailed molecular insights into how the NagA enzyme generates important precursors that are involved in Mtb cell wall biosynthesis and metabolism.
Dr Fullam, who is a Sir Henry Dale Fellow at the University of Warwick's School of Life Sciences, said: "Tuberculosis is a major global health problem and the current drugs that we use today are over 40 years old. It is therefore vital that we discover new therapeutic agents to combat TB. In our studies, we have investigated the role of an enzyme in Mtb called NagA. This enzyme is a promising drug target as it is at a crucial metabolic chokepoint in Mtb. This means that a molecule that stops the enzyme from working would be an effective strategy for a drug and therefore it is critical to understand its function.
"Our group has identified a weak point within this protein that we can target and will now enable us to design specific molecules to block its function."
Using a range of biochemical and biophysical checks to determine the substrate specificity for the Mtb NagA enzyme they found a unique structural feature in the Mtb NagA enzyme.This has revealed a molecular image of the protein and provides a platform to allow scientists to design new drugs that will hopefully inhibit this vital pathway and kill TB.