In the present study the biofilm-forming characteristics of 99 serotyped (DMC strains) and 41 genus levelidentified (IS strains) Salmonella strains originating from Turkey were investigated. The strains were selected based on their ability to show the biofilm morphotype on Congo red agar plates. In addition, all strains were evaluated with regard to properties related to forming pellicle structures, physical differences of pellicles, any changes in the media associated with the formation of pellicles, and the presence of cellulose within the formed biofilm matrix as determined using 366 nm UV light. The Salmonella Typhimurium DMC4 strain was the best producer of biofilm grown on polystyrene microtiter plates (optical density at 595 nm: 3.418). In subsequent experiments industrial process conditions were used to investigate different morphotyped Salmonella strains' biofilm-forming capability on stainless steel, a commonly preferred surface for the food industries, and on polystyrene surfaces. The effect of other important industrial conditions, such as temperature (5, 20, 37• C), pH (4.5, 5.5, 6.5, 7.4) and NaCl concentration (0.5, 1.5, 5.5, 10.5%) on the production of biofilm of the different morphotyped Salmonella strains (DMC4; red, dry and rough morphotyped S. Typhimurium, DMC12; brown, dry and rough morphotyped S. Infantis, DMC13; pink, dry and rough morphotyped S. subsp. Roughform) were also assessed. On the other hand, pH values exhibited variable effects on biofilm-forming features for different Salmonella strains on both polystyrene and stainless steel surfaces.
Phosphorus is a major essential macronutrient for plant growth, and most of the phosphorus in soil remains in insoluble form. Highly efficient phosphate-solubilizing bacteria can be used to increase phosphorus in the plant rhizosphere. In this study, 13 isolates were obtained from waste mushroom residues, which were composed of cotton seed hulls, corn cob, biogas residues, and wood flour. NBRIP solid medium was used for isolation according to the dissolved phosphorus halo. Eight isolates produced indole acetic acid (61.5%), and six isolates produced siderophores (46.2%). Three highest phosphate-dissolving bacterial isolates, namely, M01, M04, and M11, were evaluated for their beneficial effects on the early growth of tomato plants (Solanum lycopersicum L. Wanza 15). Strains M01, M04, and M11 significantly increased the shoot dry weight by 30.5%, 32.6%, and 26.2%, and root dry weight by 27.1%, 33.1%, and 25.6%, respectively. Based on 16S rRNA gene sequence comparisons and phylogenetic positions, strains M01 and M04 belonged to the genus Acinetobacter, and strain M11 belonged to the genus Ochrobactrum. The findings suggest that waste mushroom residues are a potential resource of plant growth-promoting bacteria exhibiting satisfactory phosphate-solubilizing for sustainable agriculture.
Over the last decades, several antimicrobial agents have been made available.
Due to increasing antimicrobial resistance, bacteriophages were rediscovered
for their potential applications against bacterial infections. In the
present study, biofilm inhibition and eradication of Salmonella enterica
subsp. enterica serovar Typhimurium DMC4 strain (S. Typhimurium) was
evaluated with respect to different incubation periods at different P22
phage titrations. The efficacy of P22 phage on biofilm formation and
eradication of S. Typhimurium DMC4 strain was screened in vitro on
polystyrene and stainless steel surfaces. The biofilm forming capacity of S.
Typhimurium was significantly reduced at higher phage titrations (106 pfu/mL
?). All phage titers (104-108 pfu/mL) were found to be effective at the end
of the 24 h-incubation period whereas higher phage titrations were found to
be effective at the end of the 48 h and 72 h of incubation. P22 phage has
less efficacy on already formed, especially mature biofilms (72 h-old
biofilm). Notable results of P22 phage treatment on S. Typhimurium biofilm
suggest that P22 phage has potential uses in food systems.
Biofilm formations of 25 Salmonella strains belonging to 19 serotypes were monitored with respect to time at a constant temperature. Two (DMC8 and DMC73) out of 25 strains had low biofilm formation ability and were not included in the modeling study. One (SL1344) strain had awkward biofilm formation which could not be described by a mathematical model, whereas biofilm formation of three strains (DMC33, DMC85 and DMC93) could be described by an exponential model. The modified Gompertz equation with high adjusted determination coefficient (R 2 adj) and low mean square error values produced reasonable fits for the biofilm formation of 19 Salmonella strains. It was also possible to predict the biofilm formation of these strains at two different time values by use of the modified Gompertz equation. Although more studies should be carried out to evaluate different mathematical models under both iso-and nonisothermal conditions, this study reveals that describing and predicting the biofilm formation could be possible.
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