Dual-acting immuno-antibiotics block an essential pathway in a wide range of bacteria and also activate the adaptive immune response
From: The Wistar Institute
December 23, 2020 -- Wistar Institute
scientists have discovered a new class of compounds that uniquely combine
direct antibiotic killing of pan drug-resistant bacterial pathogens with a
simultaneous rapid immune response for combatting antimicrobial resistance
(AMR). These finding were published today in Nature.
The World Health Organization (WHO) has
declared AMR as one of the top 10 global public health threats against
humanity. It is estimated that by 2050, antibiotic-resistant infections could
claim 10 million lives each year and impose a cumulative $100 trillion burden
on the global economy. The list of bacteria that are becoming resistant to
treatment with all available antibiotic options is growing and few new drugs
are in the pipeline, creating a pressing need for new classes of antibiotics to
prevent public health crises.
"We took a creative, double-pronged
strategy to develop new molecules that can kill difficult-to-treat infections
while enhancing the natural host immune response," said Farokh Dotiwala,
M.B.B.S., Ph.D., assistant professor in the Vaccine & Immunotherapy Center
and lead author of the effort to identify a new generation of antimicrobials
named dual-acting immuno-antibiotics (DAIAs).
Existing antibiotics target essential
bacterial functions, including nucleic acid and protein synthesis, building of
the cell membrane, and metabolic pathways. However, bacteria can acquire drug
resistance by mutating the bacterial target the antibiotic is directed against,
inactivating the drugs or pumping them out.
"We reasoned that harnessing the
immune system to simultaneously attack bacteria on two different fronts makes
it hard for them to develop resistance," said Dotiwala.
He and colleagues focused on a metabolic
pathway that is essential for most bacteria but absent in humans, making it an
ideal target for antibiotic development. This pathway, called
methyl-D-erythritol phosphate (MEP) or non-mevalonate pathway, is responsible
for biosynthesis of isoprenoids -- molecules required for cell survival in most
pathogenic bacteria. The lab targeted the IspH enzyme, an essential enzyme in
isoprenoid biosynthesis, as a way to block this pathway and kill the microbes.
Given the broad presence of IspH in the bacterial world, this approach may
target a wide range of bacteria.
Researchers used computer modeling to
screen several million commercially available compounds for their ability to
bind with the enzyme, and selected the most potent ones that inhibited IspH
function as starting points for drug discovery.
Since previously available IspH
inhibitors could not penetrate the bacterial cell wall, Dotiwala collaborated
with Wistar's medicinal chemist Joseph Salvino, Ph.D., professor in The Wistar
Institute Cancer Center and a co-senior author on the study, to identify and
synthesize novel IspH inhibitor molecules that were able to get inside the
bacteria.
The team demonstrated that the IspH
inhibitors stimulated the immune system with more potent bacterial killing
activity and specificity than current best-in-class antibiotics when tested in
vitro on clinical isolates of antibiotic-resistant bacteria, including a wide
range of pathogenic gram negative and gram positive bacteria. In preclinical
models of gram negative bacterial infection, the bactericidal effects of the
IspH inhibitors outperformed traditional pan antibiotics. All compounds tested
were shown to be nontoxic to human cells.
"Immune activation represents the
second line of attack of the DAIA strategy," said Kumar Singh, Ph.D.,
Dotiwala lab postdoctoral fellow and first author of the study.
"We believe this innovative DAIA
strategy may represent a potential landmark in the world's fight against AMR,
creating a synergy between the direct killing ability of antibiotics and the
natural power of the immune system," echoed Dotiwala.
Co-authors: Rishabh Sharma, Poli Adi
Narayana Reddy, Prashanthi Vonteddu, Madeline Good, Anjana Sundarrajan, Hyeree
Choi, Kar Muthumani, Andrew Kossenkov, Aaron R. Goldman, Hsin-Yao Tang, Joel
Cassel, Maureen E. Murphy, Rajasekharan Somasundaram, and Meenhard Herlyn from
Wistar; and Maxim Totrov from Molsoft LLC.
Work supported by: The G. Harold and
Leila Y. Mathers Foundation, funds from the Commonwealth Universal Research
Enhancement (CURE) Program and the Wistar Science Discovery Fund; The Pew
Charitable Trusts supported Farokh Dotiwala with a Wistar Institute recruitment
grant; Additional support was provided by the Adelson Medical Research
Foundation and the Department of Defense. Support for The Wistar Institute
facilities was provided by Cancer Center Support Grant P30 CA010815 and
National Institutes of Health instrument grant S10 OD023586.
Journal Reference:
- Kumar
Sachin Singh, Rishabh Sharma, Poli Adi Narayana Reddy, Prashanthi
Vonteddu, Madeline Good, Anjana Sundarrajan, Hyeree Choi, Kar Muthumani,
Andrew Kossenkov, Aaron R. Goldman, Hsin-Yao Tang, Maxim Totrov, Joel
Cassel, Maureen E. Murphy, Rajasekharan Somasundaram, Meenhard Herlyn,
Joseph M. Salvino, Farokh Dotiwala. IspH inhibitors kill
Gram-negative bacteria and mobilize immune clearance. Nature,
2020; DOI: 10.1038/s41586-020-03074-x
https://www.sciencedaily.com/releases/2020/12/201223125759.htm
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