An oral multispecies biofilm model for high content screening applications.

Peri-implantitis caused by multispecies biofilms is a major complication in dental implant treatment. The bacterial infection surrounding dental implants can lead to bone loss and, in turn, to implant failure. A promising strategy to prevent these common complications is the development of implant surfaces that inhibit biofilm development. A reproducible and easy-to-use biofilm model as a test system for large scale screening of new implant surfaces with putative antibacterial potency is therefore of major importance. In the present study, we developed a highly reproducible in vitro four-species biofilm model consisting of the highly relevant oral bacterial species Streptococcus oralis, Actinomyces naeslundii, Veillonella dispar and Porphyromonas gingivalis. The application of live/dead staining, quantitative real time PCR (qRT-PCR), scanning electron microscopy (SEM) and urea-NaCl fluorescence in situ hybridization (urea-NaCl-FISH) revealed that the four-species biofilm community is robust in terms of biovolume, live/dead distribution and individual species distribution over time. The biofilm community is dominated by S. oralis, followed by V. dispar, A. naeslundii and P. gingivalis. The percentage distribution in this model closely reflects the situation in early native plaques and is therefore well suited as an in vitro model test system. Furthermore, despite its nearly native composition, the multispecies model does not depend on nutrient additives, such as native human saliva or serum, and is an inexpensive, easy to handle and highly reproducible alternative to the available model systems. The 96-well plate format enables high content screening for optimized implant surfaces impeding biofilm formation or the testing of multiple antimicrobial treatment strategies to fight multispecies biofilm infections, both exemplary proven in the manuscript.

Evaluation of FTA ® paper for storage of oral meta-genomic DNA.

AIM: The purpose of the present study was to evaluate the short-term storage of meta-genomic DNA from native oral biofilms on FTA(®) paper. MATERIALS AND METHODS: Thirteen volunteers of both sexes received an acrylic splint for intraoral biofilm formation over a period of 48 hours. The biofilms were collected, resuspended in phosphate-buffered saline, and either stored on FTA(®) paper or directly processed by standard laboratory DNA extraction. The nucleic acid extraction efficiencies were evaluated by 16S rDNA targeted SSCP fingerprinting. The acquired banding pattern of FTA-derived meta-genomic DNA was compared to a standard DNA preparation protocol. Sensitivity and positive predictive values were calculated. RESULTS: The volunteers showed inter-individual differences in their bacterial species composition. A total of 200 bands were found for both methods and 85% of the banding patterns were equal, representing a sensitivity of 0.941 and a false-negative predictive value of 0.059. CONCLUSION: Meta-genomic DNA sampling, extraction, and adhesion using FTA(®) paper is a reliable method for storage of microbial DNA for a short period of time.

Activity-based selection of HIV-1 reverse transcriptase variants with decreased polymerization fidelity.

HIV-1 reverse transcriptase (HIV-1 RT) copies the RNA genome of HIV-1 into DNA, thereby committing errors at an exceptionally high frequency. Viral offspring evolve rapidly and consequently are capable of evading the immune response as well as antiviral treatment. However, error-prone viral replication could drive HIV close to extinction owing to an intolerable load of deleterious mutations. We applied a genetic selection scheme to identify variants of HIV-1 RT with a further increased error rate to study the relationship between error rate and viral replication. Using this approach, we identified 16 mutator candidates, two of which were purified and further studied in vitro. One of these variant enzymes showed a generally increased mutation frequency as compared with the reference enzyme. A single amino acid residue, R448, is probably responsible for the observed effect. Mutation of this residue, which is located within the RNase H domain of HIV-1 RT, seems to perturb the interaction with template RNA and consequently affects polymerase activity and fidelity.