Biofilm formation by biologic nanoparticles may require extracellular RNA and intact ribosomal function

Biologic nanoparticles (NPs) isolated from human arterial calcifications and kidney stones form an adherent film on the bottom of flasks when placed in standard cell culture conditions. Since NPs have certain features consistent with microorganisms, we hypothesized that antibiotics and/or RNAse might inhibit this biofilm formation. NPs isolated from calcified human arterial tissue were cultured onto glass coverslips in 24‐well plates containing DMEM with 10% fetal calf serum, plus either no treatment (control), RNase, tetracycline or gentamicin. At 1, 7 and 14 days after inoculation, coverslips were fixed, mounted, and analyzed using a CytoViva darkfield scope and KS‐400 imaging software. In control wells, the percent coverslip covered by biofilm increased by 120% from day 1 to day 14, compared to 47% and 35% in wells treated with RNase and gentamicin, respectively. Wells treated with tetracycline showed a 3% decrease in biofilm by day 14. Since RNase should not enter intact cells, these results indicate that extracellular RNA may play a role in biofilm formation by NPs. Although tetracycline can chelate calcium, it also inhibits ribosomal function, as does gentamicin. Therefore these results also suggest that intact ribosomal function is required for NP‐associated biofilm growth. These experiments suggest that biofilm formation by NPs consists of biological as well as physicochemical processes.