Cooperativity between antibiotics and antiseptics: testing the bactericidal effect.

OBJECTIVE: Treatment with antibiotics together with local application of antiseptics is common in wound care. We investigated the effectiveness of an antiseptic in two variations: octenidine (Oct) and octenidine+ (Oct+ with isotonic glucose addition). METHOD: Using the agar diffusion test with cultures of pathogenic Staphylococcus aureus and the non-pathogenic Bordetella petrii, we compared the effectiveness of octenidine to the classical antiseptics beta-isodona (povidone-iodine; PI), chlorhexidine (Chl) and taurolin (Tau) alone, and in combination with various common antibiotics to uncover cooperativity between antiseptics and antibiotics. RESULTS: We detected strong interactions between antibiotics and antiseptics, that either enhanced or reduced the bactericidal efficiency. Effectiveness was dependent on the type of organism tested. Oct applied together with ineffective antibiotics frequently led to effective growth inhibition of Bordetella petrii. With Staphylococcus aureus we did not find such an effect. To this end, we reason that positively charged Oct may associate with antibiotic compounds via electrostatic interactions and guide it more efficiently to the bacterial cell wall. Interaction with antibiotics sometimes led to sequestration and reduced availability of some antiseptic/antibiotic combinations, but never with Oct. CONCLUSION: These data provide new arguments for decision planning concerning the choice of agent in the treatment of wound infections.

Cell growth and migration under octenidine-antiseptic treatment.

OBJECTIVE: The toxicity of octenidine antiseptics in cultured cells contrasts their good tolerability in tissue. This phenomenon prompted us to examine which cell culture conditions allow survival and proliferation and to investigate a possible modulation of toxicity by the extracellular matrix proteoglycan chondroitin sulfate. METHOD: We tested fibroblasts and MCF7 cells for growth using the MTT test, and assessed wound healing potency with a laceration assay. Expression levels of the genes involved in controlling wound healing were assessed with RT-PCR. RESULTS: A 24 hour exposure to the octenidine-based solution was found incompatible with cell growth. When octenidine solution (0.5-0.5mg/l) was coated on dishes, growth was profoundly reduced after 24 hours, however there was no cytotoxic effect at 0.012 mg/l. Interestingly, when dishes were first coated with chondroitin sulfate the cytotoxicity of octenidine-based solution was modulated. Cell migration was not inhibited by octenidine-based solution treatment (2 minutes; 15 mg/l). No significant changes in gene expression levels in response to the octenidine-based solution treatment were detected. CONCLUSION: In cell culture conditions application of the octenidine-based solution without toxicity can be observed, comparable to the minimal application required to give full bactericidal effect. Alteration of toxicity by interaction with chondroitin sulfate in cell culture suggests a similar function for extraceullar matrix in intact tissue.

Growth response of soda lake bacterial communities to simulated rainfall.

Moderately saline soda lakes harbor extremely abundant and fast growing bacterial communities. An interesting phenomenon of an explosive bacterial growth in shallow soda lakes in Eastern Austria after dilution with rainwater, concomitantly with a significant decrease in temperature was observed in a former study. In the present study, we tried to identify the factors being responsible for this enhanced bacterial growth in laboratory batch cultures. Three experiments were performed with water taken from two different lakes at different seasons. Natural soda lake water was diluted with distilled water, artificial lake water, sterile filtered soda lake water, and grazer-free water to test (1) for the influence of compatible solutes released to the environment and reduced salt stress after osmotic down-shock, (2) for the influence of nutrients, which may be washed in from the dry areas of the lake bottom after rainfall and (3) for the decrease of grazing pressure due to dilution. The potential influence of (4) viruses was indirectly deduced. The response of the bacterial community to the manipulations was measured by changes in bacterial numbers, the incorporation of (3)H-leucine and the concomitant determination of the amount of (3)H-leucine uptaking bacteria by microautoradiography. The influence of the environmental factors enhancing bacterial growth after a simulated rainfall event showed variations between the lakes and over the seasons. The addition of nutrients was, in all experiments, the main factor triggering bacterial growth. The decrease in grazing pressure and viral lysis after dilution was of significant importance in two of three experiments. In the experiment with the highest salinity, we could show that either compatible solutes released after osmotic down-shock and used as a source of nutrients for the soda lake bacterial populations or reduced salt stress were most probably responsible for the observed marked enhancement of bacterial growth.

Benthic bacterial production and protozoan predation in a silty freshwater environment.

The interrelation of heterotrophic bacteria with bacterivorous protists has been widely studied in pelagic environments, but data on benthic habitats, especially in freshwater systems, are still scarce. We present a seasonal study focusing on bacterivory by heterotrophic nanoflagellates (HNF) and ciliates in the silty sediment of a temperate macrophyte-dominated oxbow lake. From January 2001 to February 2002 we monitored the standing stock of bacteria and protozoa, bacterial secondary production (BSP, (3)H-thymidine, and (14)C-leucine incorporation), and grazing rates of HNF and ciliates on bacteria (FLB uptake) in the oxic sediment of the investigated system. BSP ranged from 470 to 4050 micro g C L(-1) wet sediment h(-1). The bacterial compartment turned out to be highly dynamic, indicated by population doubling times (0.6-10.0 d), which were comparable to those in the water column of the investigated system. Yet, the control mechanisms acting upon the bacterial population led to a relative constancy of bacterial standing stock during a year. Ingestion rates of protozoan grazers were 0-20.0 bacteria HNF(-1) h(-1) and 0-97.6 bacteria ciliate(-1) h(-1). HNF and ciliates together cropped 0-14 (mean 4)% of BSP, indicating that they did not significantly contribute to benthic bacterial mortality during any period of the year. The low impact of protozoan grazing was due to the low numbers of HNF and ciliates in relation to bacteria (1.8-3.5 x 10(4) bacteria HNF(-1), 0.9-3.1 x 10(6) bacteria ciliate(-1)). Thus, grazing by HNF and ciliates could be ruled out as a parameter regulating bacterial standing stock or production in the sediment of the investigated system, but the factors responsible for the limitation of benthic protistan densities and the fate of benthic BSP remained unclear.

Factors controlling extremely productive heterotrophic bacterial communities in shallow soda pools.

Dilute soda lakes are among the world's most productive environments and are usually dominated by dense blooms of cyanobacteria. Up to now, there has been little information available on heterotrophic bacterial abundance, production, and their controlling factors in these ecosystems. In the present study the main environmental factors responsible for the control of the heterotrophic bacterial community in five shallow soda pools in Eastern Austria were investigated during an annual cycle. Extremely high cyanobacterial numbers and heterotrophic bacterial numbers up to 307 x 10(9) L(-1) and 268 x 10(9) L(-1) were found, respectively. Bacterial secondary production rates up to 738 micro g C L(-1) h(-1) and specific growth rates up to 1.65 h(-1) were recorded in summer and represent the highest reported values for natural aquatic ecosystems. The combination of dense phytoplankton blooms, high temperature, high turbidity, and nutrient concentration due to evaporation is supposed to enable the development of such extremely productive microbial populations. By principal component analysis containing the data set of all five investigated pools, two factors were extracted which explained 62.5% of the total variation of the systems. The first factor could be interpreted as a turbidity factor; the second was assigned to as concentration factor. From this it was deduced that bacterial and cyanobacterial abundance were mainly controlled by wind-induced sediment resuspension and turbidity stabilized by the high pH and salinity and less by evaporative concentration of salinity and dissolved organic carbon. Bacterial production was clustered with temperature in factor 3, showing that bacterial growth was mainly controlled by temperature. The concept of describing the turbid water columns of the shallow soda pools as "fluid sediment" is discussed.

Extremely productive microbial communities in shallow saline pools respond immediately to changing meteorological conditions.

Diel changes in bacterial and cyanobacterial numbers, as well as heterotrophic bacterial production, were examined in two shallow alkaline pools, harbouring dense populations of cyanobacteria (up to 1100 x 109 cells l-1) and bacteria (up to 500 x 109 cells l-1). Together with the recorded bacterial production rates (925 micro gC l-1x h-1), these values are the highest reported for natural aquatic ecosystems. The investigations were performed during a fair-weather situation, and during a rapid change after a long-term fair-weather situation to thunderstorms and heavy rainfall. During fair weather, bacterial growth was significantly correlated to the diurnal light and temperature cycle. Prokaryotic abundances were fairly constant, and loss by grazing and viral lysis must have been of significant importance. During the invasion of rainy weather, the prokaryotic community showed a strong and immediate response. A significant enhancement of bacterial growth followed after rainfall, suggesting that the high salt concentrations had inhibited bacterial activity. Changes in bacterial and cyanobacterial numbers were consistent with this pattern. From comparison with the available literature, we conclude that diel changes of bacterioplankton are regulated by a complex combination of environmental factors specific for each investigated ecosystem. In the soda pools investigated, external abiotic factors were dominant on a diel scale. In larger ecosystems, such factors are much more buffered and internal biotic interactions may prevail.

Weak Coupling between Heterotrophic Nanoflagellates and Bacteria in a Eutrophic Freshwater Environment.

In a study on the dynamics and trophic role of the heterotrophic nanoflagellate (HNAN) assemblage in the microbial food web of a eutrophic oxbow lake abundances, biomass, and production rates of HNAN and their potential prey organisms, namely heterotrophic bacteria and autotrophic picoplankton, were monitored for a period of 2 years. No coupling between HNAN abundance and biomass and the abundance and biomass of their picoplanktonic prey was observed for the investigation period. The ratio of heterotrophic bacterial to HNAN abundance ranged from 2.2 x 103 to 8.6 x 103 (mean: 4.2 x 103 +/- 1.8 x 103). HNAN carbon consumption could account for only 10% to 40% of bacterial secondary production. The lack of coupling between HNAN and their potential prey and the low HNAN abundance relative to bacterial abundance suggested (a) that HNAN grazing was an insignificant factor in the regulation of bacterial abundance and (b) that HNAN abundance was regulated by predation rather than by prey abundance. This hypothesis was supported by the fact that HNAN growth rates were high (in the range of 0.45 d-1 to 1.00 d-1 during spring and summer, yearly mean: 0.52 d-1), and only weakly correlated with prey abundance and biomass. The results indicated strong top-down control of HNAN and consequently a weak coupling of HNAN and picoplankton in the investigated eutrophic freshwater environment.

Comparative study of the abundance of various bacterial morphotypes in an eutrophic freshwater environment determined by AODC and TEM.

Transmission electron microscopy (TEM) and epifluorescence microscopy were used to obtain comparative measurements of total bacterial counts, and to enumerate abundances of various bacterial morphotypes in an eutrophic freshwater habitat. Although particulate matter would have been expected to interfere with counting by obscuring large areas of the electron microscope grids, estimates of total bacterial abundance made by TEM were on average 1.2 times greater than those obtained using the acridine orange direct counting method (AODC). However, the precision of the AODC method was greater than that for TEM, with a coefficient of variation (C.V.) of 4.0% versus 8.8%, respectively. The total bacterial abundance ranged from 1.1 to 3.2 x 10(6) ml(-1). As was the case for total bacterial density, the numbers of rod- and vibrio-shaped cells were lower when counted in the epifluorescence microscope, indicating the presence of potential starvation forms or ultramicrobacteria. Greatest variations in counts made by TEM and AODC were found for filamentous and coccoid bacteria. Counts of filamentous bacteria made by AODC were only about half of those detected by TEM. In contrast, cocci were on average 1.5 times greater when counted by AODC compared to TEM estimates. Both counting differences were probably caused by the morphology and low density of filamentous and coccoid bacteria (1.7 and 1.4 x 10(5) ml(-1), respectively), which led to an uneven distribution on polycarbonate filters as well as on electron microscope grids. Besides, cocci might easily be mistaken for large viral particles when counted by AODC. Hence, the study supports the use of TEM over AODC for obtaining accurate estimates of total bacterial abundance and especially bacterial morphotypes in natural waters.

Investigation of 0.2 µm filterable bacteria from the Western Mediterranean Sea using a molecular approach: dominance of potential starvation forms.

Although the existence of 0.2 µm filterable bacteria has been known since the early 80's, they are not taken into consideration when modeling microbial food webs, due to an overall lack of information concerning this specific size class. According to physiological studies on starvation forms and investigations on small bacterial cells in marine ecosystems, a 0.2 µm filtrate may consist of different phenotypes: starvation forms of typical marine bacteria, ultramicrobacteria or bacterial cells, even larger than 0.2 µm, but flexible enough to pass the nominal filter pore-size. In this pilot study we examined three filtered seawater fractions from the Western Mediterranean Sea (Bay of Calvi, Corsica/France) - the total bacterial population, the bacterial fraction above 0.2 µm and the 0.2 µm filtrate - to investigate the bacterial community structure of each of those fractions by the molecular approach of denaturing gradient gel electrophoresis (DGGE) of 16S rDNA fragments. The analysis of the resulting DGGE profiles revealed different patterns of dominant bands for the 0.2 µm filterable and the total bacterial populations within the samples. Additionally the 0.2 µm filterable bacterial compartment exhibited obvious differences in band patterns for winter and summer samples, which were not observed for the total bacterial fraction. According to the current knowledge concerning the status of 0.2 µm filterable bacteria, DGGE patterns indicate that most of the fragments representing 0.2 µm filterable bacteria were rather starvation forms of marine bacteria than ultramicrobacteria. The sequencing of excised and cloned DNA bands of the DGGE profiles characterized the phylogenetic affiliation of the corresponding 0.2 µm filterable bacteria, clustering mainly with known, typical marine isolates of both alpha-subclass and gamma-subclass of the Proteobacteria and the Cytophaga-Flavobacterium-Bacteroides branch.

Polyphasic classification of 0.2 microm filterable bacteria from the western Mediterranean Sea

The 0.2 microm filtration of sea water samples from the Mediterranean Sea (Bay of Calvi, Corsica), collected from 10 m and 35 m depth led to the isolation of several gram-negative bacterial strains able to grow on full-strength media as well as on diluted media. The analysis of the 16S rRNA gene sequences and estimation of the phylogenetic relationships of these facultative oligotrophic bacteria indicated that they grouped into two phylogenetic branches. The strains RE10F/2, RE10F/5 (10 m depth samples) and RE35/F12 (35 m depth samples) were assigned to the gamma-subclass, while RE35F/1 (35m depth sample) was assigned to the alpha-4-subclass of the Proteobacteria. The strains RE10/F2 and RE10/F5 were most closely related to species and strains of the Pseudoalteromonas group, whereas the strain RE35F/12 placed adjacent to the family Vibrionaceae. The phylogenetic analysis of strain RE35F/1 revealed that this bacterium clusters with marine strains and species of the aerobic anoxygenic phototrophic bacteria Erythrobacter as well as Erythromicrobium and more distantly to Sphingomonas spp. Supplementary to those genotypic classifications the chemotaxonomic signatures including the major respiratory lipoquinone systems, the cellular fatty acid compositions as well as the polyamine contents of the bacteria were investigated. The isolated organisms displayed differences in their physiological and biochemical properties to already described strains belonging to the same genera or families, as revealed by the comparative 16S rRNA analysis. Despite the fact that these bacteria were isolated from a 0.2 microm filtrate, the cultured organisms which were all rod-shaped, displayed width dimensions ranging from 0.4 up to 0.7 microm, indicating that these bacteria were starvation forms at the time of isolation and not ultramicrobacteria as defined by Torella and Morita (1981) or by Schut et al. (1993). Because our isolated strains represent potentially new taxa, this first investigation on 0.2 pm filterable bacteria from the Western Mediterranean Sea supports the hypothesis that this bacterial fraction contributes to the diversity of marine bacteria.

Seasonal variations of virus abundance and viral control of the bacterial production in a backwater system of the danube river.

The abundance of virus-like particles in a backwater system of the Danube River covered a range of 1.2 x 10(sup7) to 6.1 x 10(sup7) ml(sup-1) from 1992 to 1993. Measurements of head diameters for these particles, all of which were presumed to be viruses, led to four defined size classes, ranging from <60 nm to >150 nm. The 60- to <90-nm size class contained the largest fraction of total particles (41%), followed by the 90- to <150-nm size class (33%). The frequency of size classes was not significantly different between the two years. The frequency of bacteria with mature phages ranged from 1 to 4% over the seasons, with mean burst sizes ranging from 17 to 36 phage per host cell. Among the bacterial morphotypes, rods and vibrios were the major host systems for phages, while coccoid and filamentous cells were considered negligible. Counts from transmission electron microscopy and acridine orange direct counts confirmed that rods and vibrios accounted for 85 to 95% of the bacterial population over the seasons. Virus decay experiments showed lower decay rates for temperatures between 5 and 15(deg)C (52 to 70% of the virus population remained) relative to 18 and 25(deg)C (31 to 51% of the virus remained). Bacterial production measurements, performed at the same time and under the same conditions as decay experiments, allowed us to estimate virus-induced death rates, which ranged from 15.8 to 30.1% over the year, with an average of 20% viral control of the bacterial production. Considering that mature phage particles are visible only in the last phase of the latent period and using a mean conversion factor of 5.4 from the literature, based on descriptions of various phage host systems to relate the percentage of visibly infected cells to the total percentage of the bacterial community that is phage infected, we estimate that some 5.4 to 21.6% of the bacterial population is infected with viruses. This would imply that virus-induced death rates of bacteria range from 10.8 to 43.2%. The data on virus-induced bacterial mortality obtained by both the viral decay method and the determination of the frequency of infected cells are compared and discussed.

Carbon fluxes in the microbial loop: Comments.

The heterotrophic bacterial community of oceanic aggregates which mediates particle solubilization, displays features (low carbon demand and low turnover) that are difficult to reconcile with the observed high enzyme activities and cell numbers. Hypotheses are proposed to explain this discrepancy. Furthermore, production of both free and attached bacteria may have been underestimated by neglecting the ultramicrobacteria (UMB). Production of UMB may represent up to 28% of the total bacterial production.