Source: © Tatiana Shepeleva/Fotolia
Source: © Tatiana Shepeleva/Fotolia

Scientists lead by a team at the NYU Langone Medical Center say they have found out why a particular strain of Staphylococcus aureus, known as HA-MRSA, becomes more deadly than other variations. These new findings open up possible new pathways to vaccine development against this bacterium, which the Centers for Disease Control and Prevention says accounts for over 10,000 deaths annually, mostly among hospital patients.

In a series of experiments in mice and in human immune cells in the lab, recently published (“Counter inhibition between leukotoxins attenuates Staphylococcus aureus virulence”) in Nature Communications,  the NYU Langone team found that the presence or absence of dueling toxins, or bacterial poisons, appears to explain the major difference between HA-MRSA, and its less virulent and more common, community based-based cousin, CA-MRSA, the two main types of MRSA infection.

Specifically, the researchers say, a key toxin, called LUK-PV, secreted only by community-acquired MRSA, counteracts the effects of another more deadly toxin, LUK-ED, secreted by both forms of the bacterium.

Scientists say both LUK-PV and LUK-ED are leukotoxins that target and poison the white blood cells meant to fight the bacterial infection, but LUK-PV is only secreted by community-acquired MRSA, or methicillin-resistant S. aureus.

According to study senior investigator and NYU Langone microbiologist Victor Torres, Ph.D., the newly discovered competing or “antagonistic” relationship between the two bacterial toxins helps explain how community-acquired MRSA is far more widespread and less deadly than hospital-acquired MRSA.

“Essentially, in community-acquired MRSA, the toxins neutralize each other, while in the hospital superbug form, they do not,” says Dr. Torres, who adds that study results challenge the current mindset for finding a vaccine against Staphylococcal infections, including MRSA.

“No longer can we take an isolated approach of trying to target and block one leukotoxin at a time,” the associate professor at NYU Langone points out. “We have to take a broader view of the pathogen and will likely have to target more than one toxin in order to develop an effective vaccine.”

In a separate set of lab experiments previously described in the journal Cell Host & Microbe online August 27, researchers at Dr. Torres' laboratory and colleagues in the Netherlands, France, and Australia showed how LUK-ED attacked red blood cells to obtain nutrients, most notably iron, essential for its rapid growth and infection. The international team found that the toxin split apart the red blood cells by attaching itself first to their so-called Duffy antigen protein receptor, the same receptor widely known to be targeted by the human Plasmodium malarial parasites.

Dr. Torres says his research is making clearer that multiple bacterial toxins, such as the five known to be contained in community-acquired MRSA, react very differently on their own than when combined because they can counteract each other.

His team next plans to analyze the biological mechanisms by which LUK-PV and LUK-ED target, attach and destroy white and red blood cells, making their host more vulnerable to infection. Other experiments are set to determine how widespread bacteremia from Staphylococcal infections actually shuts down the mammalian body, causing death.

Dr. Torres also has plans to study groups of Africans known to be genetically deficient in Duffy antigens and, hence, more resistant to malaria, to see if they are resistant to Staphylococcal infection, as well.

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