Tularemia is a rare but highly infectious disease caused by Francisella tularensis, a bacterium that can evade immune defenses. Symptoms of infection can include fever, swollen lymph nodes, and—in some cases—pneumonia. What makes the pathogen especially concerning is how little it takes to cause infection—fewer than 10 bacterial cells can be enough. Scientists at Arizona State University have taken a key step toward understanding how this bacterium survives inside the human body. For the first time, the team has isolated and studied a set of proteins that play a central role in infection, revealing a potential weakness that could eventually be targeted with new treatments. The study is published in the journal Biochimica et Biophysica Acta (BBA)–Biomembranes.

The proteins sit within the bacterium’s inner membrane and appear to work together, forming small assemblies that help it persist inside host cells. Until now, researchers had been unable to produce and stabilize these proteins in the lab, leaving a critical part of the pathogen’s biology unexplored. By developing a method to extract and analyze them, the team has opened the door to more detailed structural studies and eventually, new ways to disrupt the infection process.

The work builds on earlier studies of individual proteins, but advances the research by capturing a group of proteins that function together as a system—one that is essential for infection but had remained inaccessible.

A randomized clinical trial evaluated if fecal microbiota transplant (FMT) is effective in achieving gut decolonization of multidrug-resistant organisms (MDROs) and reducing antimicrobial resistance (AMR) gene abundance in patients with gastrointestinal (GI) diseases.

Among 114 adults, a single FMT session did not significantly increase rates of MDRO decolonization or reduce antimicrobial resistance gene abundance compared to sham intervention. However, FMT was associated with increased bacterial diversity and enrichment with bacteria capable of producing short-chain fatty acids. No significant safety concerns were observed.

These findings indicate that while a single FMT session does not support routine use for MDRO decolonization in GIDisease, microbiome changes warrant further research.

This randomized clinical trial assesses the efficacy of fecal microbiota transplant in causing multidrug-resistant organism decolonization and decreasing antimicrobial resistance genes in patients with gastrointestinal diseases.

New research indicates that statin use is associated with a significantly lower risk of developing intestinal strictures in patients with Crohn’s disease. The study suggests that the anti-inflammatory and antifibrotic properties of statins may help prevent the structural damage that often leads to surgical intervention.

Use of statins after the diagnosis of Crohn’s disease is associated with a lower risk for intestinal stricture formation than the use of other non-statin drugs.

Scientists at Memorial Sloan Kettering Cancer Center (MSK) and their colleagues are shedding new light on a tumor’s earliest moments—revealing how lung cells with cancer-causing mutations recruit accomplices from healthy surrounding tissue to pave the way for a tumor to develop.

This corruption of the local neighborhood—what scientists call the “tumor microenvironment”—begins surprisingly early, as tumors first emerge, according to a study published April 22 in Nature.

The team’s findings show that when this communication with surrounding cells is disrupted, tumors fail to grow.