A $5.8 million grant led by Adrie Steyn PhD, of the University of Alabama at Birmingham and the Africa Health Research Institute (AHRI) in Durban, South Africa, will provide user-requested infected human lung tissue and analytical services to tuberculosis researchers worldwide.
Tuberculosis is a bacterial infection that causes 1.3 million deaths and 10.6 million new active cases each year, yet experimental animal models of TB do not reproduce the full spectrum of disease as it occurs in humans. A paucity of human lung tissue for study has left a fundamental gap in understanding how the bacterial pathogen Mycobacterium tuberculosis (Mtb) causes disease in people, says Steyn, a professor in the UAB Department of Microbiology.
TB disease has existed since antiquity. Mtb was identified as the pathogen more than 140 years ago, and in 1800s Europe, TB caused nearly one in every four deaths. Human lung samples were highly studied until the disease was greatly diminished by better sanitation, and then the advent of antibiotics in the 1940s and ’50s. Since then, researchers have relied mainly on animal models to study TB.
Today, with the emergence of antibiotic-resistant Mtb, “there are few studies focused on elucidating in humans the fundamental mechanisms of active, subclinical and latent TB,” Steyn said. “We believe the TB field can no longer rely on animal models that yield findings of limited clinical relevance. Thus, there is an urgent need to better understand human pulmonary TB in order to develop clinically relevant therapeutic strategies.”
The five-year R24 grant from the National Institutes of Health will establish The Global Research Resource for Human Tuberculosis, with the goal of transforming the global landscape of TB research by accelerating the study of human TB tissue through two unique user-requested services. First is providing pathological, cellular, structural and genetic analysis of resected human TB or postmortem tissue. Second is disseminating human TB tissue to the global TB research community.
“We have several unique advantages since AHRI has access to a continuously growing collection of active TB/HIV and postmortem samples, including entire lungs and lobes,” Steyn (pictured above) said. “This R24 proposal is built upon substantial published data from our group that clearly demonstrate our capacity to examine resected and postmortem lung tissue from Mtb/HIV-infected human subjects. We consider the lack of human TB lung tissue to represent an unmet need and a critical barrier in the TB field that must be eliminated to develop new hypotheses.”
In the first year of the grant, researchers will create repositories of human TB lung tissue for analysis and dissemination at AHRI, as well as existing pulmonary and extrapulmonary TB specimens at UAB and the University of Texas Health Science Center, Houston. These will come from active, subclinical and latent TB patients and decedents, along with clinical and radiological information. About one-quarter of the world’s population is latently infected with Mtb, a poorly understood problem. In the first year, the multi-centre team will build a dedicated web portal to describe all its services, establish an international committee to rapidly evaluate applications through the web portal and establish a virtual information platform.
Other analysis of human TB tissue will include immunohistochemistry and specialised stains, RNAscope to visualise individual mRNAs, spatial transcriptomics, and multiplex immunofluorescence. As part of their preliminary research, published in eBioMedicine this summer, Steyn and colleagues showed that the emerging technology, RNAscope, was able to identify Mtb mRNA in intact and disintegrating bacilli in tissues. They were able use RNAscope to identify Mtb mRNA in UAB lymph node biopsies taken more than a year before a patient died from disseminated tuberculosis. Those biopsies had been negative for the Ziehl-Neelsen stain, the standard test to identify Mtb. Steyn says this shows the diagnostic potential of RNAscope technology in complex TB cases, since the Ziehl-Neelsen stain is highly variable and can miss Mtb organisms.