The antibiotics potentiator bicarbonate causes upregulation of tryptophanase and iron acquisition proteins in Escherichia coli.

We have reported that bicarbonate (NaHCO3 ) potentiates the activity of aminoglycosides in Escherichia coli, but the action mechanism was not identified. To eventually understand how NaHCO3 can potentiate antibiotics, we thought that a rational first step was to examine the effect of NaHCO3 separately and to inspect initial gene expression changes triggered by it. In this work, we started by confirming that NaHCO3 can reduce the number of viable E. coli bacteria. We then investigated, via RNAseq, gene expression changes induced by NaHCO3 . There were upregulated and downregulated genes, among the top upregulated genes c. 10-fold increase in expression) was tnaA, the gene encoding tryptophanase, the enzyme that degrades tryptophan to indole. Considering that higher expression of tnaA likely led to increases in indole, we tested the effect of indole and found both growth inhibition and synergy with NaHCO3 . We suggest that indole may participate in growth inhibition of E. coli. The RNAseq analysis also revealed upregulation (≥4-fold) of genes encoding proteins for the acquisition of iron and downregulation (≥16-fold) of genes encoding iron-sulphur-holding proteins; hence NaHCO3 apparently triggered also an iron-deficit response. We suggest that iron deficiency may also be involved in growth inhibition by NaHCO3 . SIGNIFICANCE AND IMPACT OF THE STUDY: Bicarbonate (NaHCO3 ) can enhance the activity of various antibiotics. This work investigated its action mechanism. We carried out a transcriptional analysis in Escherichia coli with the aim of defining initial bacterial changes potentially linked to the enhancing activity of NaHCO3 . Our approach differed from the longer term exposure to NaHCO3 recently used by other researchers, who noticed changes in the bacterial proton motive force. Based on our analysis, we propose two routes possibly linked to the effect of NaHCO3 . Conceivably, those routes are potential targets that could be manipulated by alternative means to augment the effect of antibiotics.

On the function of histamine in the central nervous system of arthropods.

Histamine is localized in the CNS of many invertebrate taxa by various methods. It is described to act as a neurotransmitter, neuromodulator, and neurohormone. Because of its distribution throughout these taxa it is tempting to forward the following hypothesis: Histamine acts as a neuroactive substance in all invertebrates. Its function as a transmitter of photoreceptors is restricted to arthropods. A special system of six large histamine-immunoreactive neurons exists exclusively in arachnids.

Cell proliferation and 3H-proline incorporation in periodontal ligament exposed to mechanical stress.

In order to study the metabolic processes induced in the periodontal ligament by mechanical influences, a tension spring was implanted in rats between the incisor and the first maxillary molar on the right-hand side, while the left maxilla of these animals as well as non-operated rats served as controls. Under such mechanical stress, there occurred at 3, 10 and 21 days after implantation a significant increase in the 3H-thymidine labeling index, which was demonstrable histoautoradiographically. A change in cell density was not discovered. Therefore, the increase in S-phase fraction as equally recorded in both pressure and tension zones is regarded as an expression of an enhanced cell turnover. Cell renewal in the periodontal ligament can be modified by inflammatory processes within the gingival region. There is a slight enlargement of the periodontal space in the tension zone. Under our experimental conditions, no change occurs in the silver grain number per cell after 3H-proline administration. The results indicate that, following the impact of orthodontic forces, the reactivity of periodontal cell proliferation as compared to collagen synthesis is enhanced.