Israel is subjected to sand and dust storms from several directions: northeast from the Sahara, northwest from Saudi Arabia and southwest from the desert regions of Syria. The airborne dust carried in these storms affects the health of people and ecosystems alike. New research at the Weizmann Institute of Science suggests that part of the effect might not be in the particles of dust but rather in bacteria that cling to them, traveling many kilometers in the air with the storms.
Some of these bacteria might be pathogenic – harmful to us or the environment – and a few of them also carry genes for antibiotic resistance. Others may induce ecosystem functions such as nitrogen fixation. Prof. Yinon Rudich and his research group, including postdoctoral fellow Dr. Daniela Gat and former research student Yinon Mazar, in Weizmann’s Earth and Planetary Sciences Department investigated the genetics of the windborne bacteria arriving along with the dust.
“In essence, we investigated the microbiome of windborne dust,” says Rudich. “The microbiome of a dust storm originating in the Sahara is different from one blowing in from the Saudi or Syrian deserts, and we can see the fit between the bacterial population and the environmental conditions existing in each area.”
The researchers found that during a dust storm the concentration of bacteria and the number of bacterial species present in the atmosphere rise sharply, so people walking outdoors in these storms are exposed to many more bacteria than usual.
Rudich and his team then explored the genes in these bacteria, checking for antibiotic resistance – a trait that can arise owing to elevated use of antibiotics but also naturally, especially in soil bacteria. Antibiotic resistance has been defined by the World Health Organization as one of the primary global health challenges of the twenty-first century, and its main driver is the overuse of antibiotics. But bacteria can pass on the genes for antibiotic resistance, so any source of resistance is concerning. How many different genes for antibiotic resistance come to Israel from the various dust storms, and how prevalent are these genes?
Rudich says that the study enabled the researchers to identify a “signature” for each source of bacteria based on the prevalence of antibiotic resistant genes, which revealed whether the genes were local or imported from distant deserts. “We found that as more ‘mixing’ occurs between local dust and that which comes from far off, the lower the contribution of the imported antibiotic resistance genes.” In other words, antibiotic resistance coming from Africa or Saudi Arabia is still a very minor threat compared to that caused and spread by human activity, especially animal husbandry. Also participating in this research were Dr. Eddie Cytryn of the Volcani Center and Prof. Yigal Erel of the Hebrew University of Jerusalem.
Urban air pollution is attributed, to a large extent, to emissions from transportation. Prof. Rudich and Staff Scientist Dr. Michal Pardo-Levin ask how these sources contribute to air pollution. Their findings show that pollution that does not come from the combustion engine but rather is released from the friction of the vehicle’s tires on the road and from braking systems can lead to serious health effects upon inhalation. That means that even if we manage to significantly reduce our cars’ tailpipe emissions, city air will still be polluted, to a large extent, with these other substances. And since the friction of tires and brakes are necessary for driving, reducing their emissions could be much harder.
Prof. Yinon Rudich’s research is supported by the Helen and Martin Kimmel Award for Innovative Investigation; the Dr. Scholl Center for Water and Climate, which he heads; the Sussman Family Center for the Study of Environmental Sciences, which he heads; the de Botton Center for Marine Science; the Adelis Foundation; the Henri Gutwirth Fund for Research; the estate of David Levinson; and the estate of Olga Klein Astrachan.
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