“Microplastic pollution in the ocean contributes to antibiotic resistance”

It is now well known that the wide­spread use of antibi­otics – to treat patients, but espe­cial­ly to treat farm ani­mals – has accel­er­at­ed bac­te­r­i­al resis­tance to these treat­ments, ren­der­ing many inef­fec­tive. Also, no new antibi­otics have been dis­cov­ered in decades, putting us at risk of a future with­out them – leav­ing humans vul­ner­a­ble to micro­bial infec­tions. The grow­ing phe­nom­e­non of antibi­ot­ic resis­tance there­fore rep­re­sents one of the most seri­ous threats to human and ani­mal health today. And a bet­ter under­stand­ing of the dif­fer­ent dri­vers of this resis­tance is becom­ing urgent.

Recent­ly, researchers estab­lished a con­nec­tion between this prob­lem and anoth­er major issue of our time: microplas­tic pol­lu­tion in the sea. These plas­tic par­ti­cles, less than 5mm in size, come from the degra­da­tion of plas­tic waste, or direct­ly from cer­tain prod­ucts them­selves, such as cos­met­ics. Because of their small size, microplas­tics found in water (oceans, lakes, rivers) are often ingest­ed by aquat­ic ani­mals, but also by humans since they can be present in tap water and bot­tles. They are sus­pect­ed of hav­ing harm­ful effects on health, and stud­ies to bet­ter under­stand the risks involved are cur­rent­ly being conducted. 

Over the past decade, when micro­bial sam­ples from microplas­tics float­ing in the seas and oceans were stud­ied, path­o­gen­ic bac­te­ria capa­ble of infect­ing humans of the Vib­rio, Sal­mo­nel­la or Legionel­la fam­i­ly were found. Fur­ther­more, many of these bac­te­ria car­ry the genes for antibi­ot­ic resis­tance. Nor­mal­ly, these bac­te­ria are not present in marine waters because they can­not sur­vive in water pH and salin­i­ty, or due to oth­er envi­ron­men­tal fac­tors, but over time their pres­ence in coastal waters has increased. This is main­ly due to the dis­charge of domes­tic, indus­tri­al or agri­cul­tur­al waste­water in the sea… but also of microplas­tics. The asso­ci­a­tion between microplas­tics and path­o­gen­ic bac­te­ria seems to be respon­si­ble for the longevi­ty of these bac­te­ria in marine envi­ron­ments, their repro­duc­tion, and their trans­port to regions far from the place of dis­charge into the sea. Biol­o­gist Maria Belen Sathicq, post-doc­tor­al fel­low at IRSA (CNR), is study­ing this micro­bial ecol­o­gy through the AENEAS research project.

What are the main dan­gers of the microplastic/antibiotic resis­tant bac­te­ria bino­mi­al for human and envi­ron­men­tal health?

Plas­tic pol­lu­tion has a major impact on com­mer­cial fish­ing and aqua­cul­ture activ­i­ties. When microplas­tics accu­mu­late in the tis­sues of marine ani­mals, they also con­t­a­m­i­nate all lev­els of the food chain, right up to our plates. But plas­tic debris also pro­vides a float­ing sub­strate that acts as a car­ri­er for harm­ful algae, organ­ic pol­lu­tants and poten­tial­ly path­o­gen­ic microor­gan­isms. In addi­tion, microplas­tics can facil­i­tate the trans­fer of genes for antibi­ot­ic resis­tance to aquat­ic ani­mals that ingest or fil­ter them… and then to con­sumers of fish and seafood, espe­cial­ly when ingest­ed raw. 

A 2018 study found that the gut micro­bio­ta of peo­ple who spend a lot of time near pol­lut­ed coast­lines often car­ry antibi­ot­ic-resis­tant bacteria.

A 2018 study found that the gut micro­bio­ta of peo­ple who spend a lot of time near pol­lut­ed coast­lines often car­ry antibi­ot­ic-resis­tant bac­te­ria. As for the envi­ron­ment, microplas­tics also induce resis­tance in aquat­ic micro­bial ecosys­tems to oth­er pol­lu­tants, such as heavy met­als. How­ev­er, while these phe­nom­e­na are con­firmed by sev­er­al exper­i­men­tal stud­ies, the search for evi­dence of the impact of microplas­tics on micro­bial com­mu­ni­ties in the nat­ur­al envi­ron­ment is still in its infancy.

What is the “plas­ti­sphere” and how is this new eco­log­i­cal niche formed in which antibi­ot­ic-resis­tant bac­te­ria pro­lif­er­ate, among others?

Bac­te­ria, algae and fun­gi attach them­selves to the sur­face of var­i­ous hard sub­strates – nat­ur­al or arti­fi­cial. This then gives rise to a biofilm – an adhe­sive and pro­tec­tive matrix pro­duced by the microor­gan­isms them­selves – in which they live. In 2013, Zettler and col­leagues pro­posed the term “plas­ti­sphere” to refer to the micro­bial com­mu­ni­ties dis­cov­ered on microplas­tics col­lect­ed in the North Atlantic. Since then, sev­er­al research stud­ies have shown that plas­tic can allow spe­cif­ic micro­bial com­mu­ni­ties to sur­vive in water. Microplas­tics are thus a new eco­log­i­cal niche offer­ing bac­te­ria greater chances of sur­vival in the nat­ur­al envi­ron­ment, and in which genet­ic exchange between dif­fer­ent indi­vid­u­als or species is favoured by the prox­im­i­ty pro­vid­ed by the biofilm.

Your AENEAS project is com­ing to an end. What meth­ods were used and what results were obtained?

The project, born in 2019 thanks to the sup­port of the AXA Research Fund, aimed to study the impact of microplas­tics on micro­bial com­mu­ni­ties in coastal waters of the north­ern Mediter­ranean region, with a par­tic­u­lar focus on the poten­tial selec­tion of antibi­ot­ic resis­tance with­in com­mu­ni­ties exposed to microplas­tic pol­lu­tion. We first assessed plas­tic com­po­si­tion and micro­bial com­mu­ni­ty diver­si­ty on microplas­tics at six sites along the north­ern Tyrrhen­ian Sea coast. We found that the dom­i­nant poly­mer there was poly­eth­yl­ene, and that its great­est con­cen­tra­tion was not in sites with the great­est anthro­pogenic impact (such as ports), as might have been expect­ed, but in less fre­quent­ed areas, such as nature reserves. 

The bac­te­r­i­al colonies present on microplas­tics and in water are very diverse, but poten­tial­ly path­o­gen­ic Vib­rio bac­te­ria and antibi­ot­ic resis­tance genes (espe­cial­ly against tetra­cy­cline), are the most abun­dant on microplas­tics in water. In a sec­ond step, we analysed the role of dif­fer­ent poly­mers on bac­te­ria, in par­tic­u­lar on pathogens. We main­ly stud­ied tyre rub­ber, a type of plas­tic with a very com­plex chem­i­cal com­po­si­tion. Indeed, this mate­r­i­al exerts selec­tion, and poten­tial­ly path­o­gen­ic bac­te­ria (e.g. Pseudomonas, Aeromonas, Acine­to­bac­ter) are rel­a­tive­ly more abun­dant where it is found. Final­ly, we are plan­ning a sur­vey to under­stand the lev­el of risk per­cep­tion of cit­i­zens liv­ing around these issues who live near the coastal areas we are study­ing, it will involve high school students.

Going for­ward, what are the most press­ing areas to study to curb the spread of antibi­ot­ic resistance?

There is still much to be learned about the role of microplas­tics in the spread of antibi­ot­ic resis­tance, although research has already accu­mu­lat­ed a great deal of evi­dence via lab­o­ra­to­ry stud­ies. How­ev­er, results strong­ly sug­gest that microplas­tics act as a long-term reser­voir for antibi­ot­ic resis­tance due to their dura­bil­i­ty, but the role of each type of poly­mer and addi­tive needs to be stud­ied. It is also impor­tant to eval­u­ate the behav­iour of bio­plas­tics; a promis­ing sub­sti­tute for petro­le­um-based plas­tics, that may be sim­i­lar to oth­er con­ven­tion­al plas­tics in terms of micro­bial com­mu­ni­ty formation. 

The grow­ing threat of antibi­ot­ic resis­tance requires a mul­ti-sec­toral approach, which views human, ani­mal and envi­ron­men­tal health as con­nect­ed and depen­dent on each oth­er (One Health con­cept). There are still many issues to be resolved: human abuse of antibi­otics, exces­sive use of these drugs in ani­mal farm­ing, and the effec­tive­ness of waste­water treat­ment plants in remov­ing pol­lu­tants such as microplastics.

Interview by Annalisa Plaitano