Charge Transport in Bifidobacterium animalis subsp. lactis BB-12 under the various Atmosphere
K. Bozkurt, C. Denkta\c{s}, O. \"Ozdemir, A. Alt{\i}ndal, Z. Avdan,, and H. S. Bozkurt

TL;DR
This study investigates how relative humidity affects the electrical properties of Bifidobacterium animalis subsp. lactis BB-12, revealing humidity's significant impact on conductivity, hysteresis, and surface charge characteristics.
Contribution
First analysis of humidity effects on the electrical behavior of Bifidobacterium animalis subsp. lactis BB-12, highlighting the role of water molecules in charge transport mechanisms.
Findings
Electrical conductivity increases by six orders of magnitude at 75% RH.
Humidity influences hysteresis in I-V characteristics.
Surface charge is negative, with electrons as charge carriers.
Abstract
The influence of relative humidity (RH) on quasistatic current-voltage characteristics of Bifidobacterium animalis subsp. lactis BB-12 thin layers have been studied for the first time. The value of electrical conductivity in 75 RH was found to be in the order of 10 (ohm cm) which was 10 orders of magnitude higher than that observed in dry atmosphere. Here we also demonstrated that RH played a key role in hysteresis behaviour of the measured characteristics. FTIR measurements showed that under water moisture environment the associated bonds for amine and carboxyl group were greatly strengthened that was the source of number of free charge carries after ionization. The type of surface charge of Bifidobacterium animalis subsp. lactis BB-12 was found to be negative by zeta potential measurements, claiming that electrons were the charge carriers.
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Charge Transport in Bifidobacterium animalis subsp. lactis BB-12 under various atmospheres
K. Bozkurt1
C. Denktaş1
O. Özdemir1
A. Altındal1
Z. Avdan2
H. S. Bozkurt3
1Yildiz Technical University, Davutpasa Campus, Science and Arts Faculty, Physics Department, 34220 Esenler Istanbul, Turkey
2Kocaeli University, Umuttepe Campus, Science and Arts Faculty, Physics Department, 41380 Izmit Kocaeli, Turkey
3Maltepe University, Medical Faculty Internal Medicine, Clinic of Gastroenterology, 34843 Maltepe Istanbul, Turkey
Abstract
The influence of relative humidity (RH) on quasistatic current-voltage characteristics of Bifidobacterium animalis subsp. lactis BB-12 thin layers was studied for the first time. The value of electrical conductivity in 75 RH was found to be in the order of 10*-7* (ohm cm)-1 , which was 106 orders of magnitude higher than that observed in dry atmosphere. It was concluded that RH played a key role in hysteresis behaviour of the measured characteristics. FTIR measurements showed that under water moisture environment the associated bonds between amine and carboxyl group were greatly strengthened that was the source of free charge carries after ionization. The surface charge of Bifidobacterium animalis subsp. lactis BB-12 was found to be negative by zeta potential measurements, claiming that electrons were the charge carriers.
Bifidobacterium animalis subsp. lactis BB-12, Charge transport, Water Humidity, FTIR, Zeta potential
pacs:
87.80.-y, 89.90.+n
I Introduction
I.1 BB-12 and Gut Microbiota
The gut microbiota contains a diverse community of commensal, symbiotic and pathogenic microorganisms 1 ; 2 . The gut microbiota has anti-inflammatory, antioxidant, antioncogenic effects and it contributes to the immunological, hormonal and metabolic homeostasis of the host 3 ; 4 . The genus Bifidobacterium belongs to the phylum Actinobacteria and it comprises Gram-positive, non-motile, often branched anaerobic bacteria 5 . The Bifidobacteria are one of the major species in the human colon microbiota and have been frequently used as probiotic 6 . Bifidobacterium animalis subsp. lactis BB-12 is a catalase-negative, rod-shaped bacterium which was first isolated in 1983 (Figure-1). At the time of isolation, Bifidobacterium animalis subsp. was considered as one of the species of Bifidobacterium bifidum 7 .
In 2010, the complete genome sequence of BB-12 was mapped 7 . The BB-12 genome consists of a single circular chromosome of 1,942,198 base pairs with 1642 predicted protein-encoding genes, 4 rRNA operons, and 52 tRNA genes 8 . A physical mapping of the BB-12 chromosome revealed that the genome sequence was correctly assembled (Figure-2).
BB-12 is technologically well suited, expressing fermentation activity, high aerotolerance, good stability and a high acid and bile tolerance 8 . Because of high redox potential in the colon flora ecosystem, BB-12 is highly resistant against acidic pH, digestive enzymes and toxic effect of bile acids 8 . The BB-12 cell envelope is an electrical and physical barrier that can be overcome by pathways that consist of redox proteins and structural proteins. Some of the main molecular mechanisms and electron transport systems are presented in Figure 3.
I.2 BB-12 and Bacterial Cellular Electron Transport Systems
Bacterial cellular electron transport systems (CET) are defined as microbial bioelectrochemical processes in which electrons are transferred from the cytosol to the membrane of the cell 10 . Shi, L. et al showed molecular mechanisms that underlie the ability of bacterial to exchange electrons, such as c-type cytochromes and microbial nanoparticles between bacterial membrane and gut enterocytes 10 . Samuel, H. Light et al described food borne gut pathogen L. monocytogenes cellular electron transfer systems 11 . They showed that NADH dehydrogenase enzymatic pathway is the responsible mechanism for CET from aerobic respiration by channelling electrons to a discrete membrane-localized quinone pool. Although Lorena et al showed the strength of BB-12 under lower pH, bile acid and digestive enzymes conditions, CET features of BB-12 were still not completely identified. Here we first described the probiotic bacteria Bifidobacterium animalis subsp. lactis BB-12 strain features of CET under various atmospheres. This work was organized as follows. Materials, Zeta-potential studies, ATR-FTIR analysis, SEM and SEM images electrical characterization of BB-12 were presented in Sec.II. Charge transport system of Bifidobacterium animalis subsp. lactis BB-12 was discussed in Sec.III. Conclusions and outlooks were given in Sec. IV.
II Materials and Methods
II.1 Material
Mean gut bifidobacterial count of 5 billions cfu of Bifidobacterium animalis subsp. lactis BB-12 (Chr Hansen) were used in this study. This Bifidobacterium was dissolved in 5 of distilled water and the sample was prepared. Spin coating technique was employed to deposit the films of the Bifidobacterium animalis subsp. lactis BB-12 onto the interdigital micro electrode (IDE) arrays. For the spin coating processes, the coating solutions were prepared by dissolving the BB-12 in double distilled water at concentrations of 1 M. 200 of such solution was added with a glass pipette onto the IDE structure held onto spinner (Speciality Coatings Systems Inc., Model P6700 Series). The substrate was spun at 2500 rpm for 60 s and then the film was transferred to the test chamber.
II.2 Zeta Potential
The Zeta potential (ZP) of BB-12 was measured in water using a Zetasizer Nano ZS (Malvern Instruments Ltd) at room temperature. The voltage applied to the driving electrodes of the capillary electrophoresis cell was . The zeta potential of bacteria was calculated based on the Smoluchowski equation and the values of three different samples were averaged,
[TABLE]
where is the zeta potential, represents the slope of the streaming potential versus pressure, is the viscosity, is the relative permittivity of the electrolyte solution, is the electric permittivity of vacuum and is the electrolyte conductivity.
II.3 FTIR Spectral Method
The change in structure of BB-12 was recorded by an Agilent Technologies Cary 630 FTIR apparatus at room temperature. Spectra of all samples were recorded between 400 and 4000 cm*-1* at a resolution of 4 cm*-1* with 100 scans.
II.4 Electrical Characterization of Bifidobacterium animalis subsp. lactis BB-12
Photolitographically patterned interdigital arrays of tin (Sn) electrodes on plexiglass substrate were used for the electrical characterization of Bifidobacterium animalis subsp. lactis BB-12. The interdigital electrodes consisted of 20 finger pairs of electrodes with a width of 100 m and a space of 100 m between adjacent electrodes. Then, the BB-12 film surface exposed to the various levels of RH between 0 and 100 for 10 min. After each exposure, curret-voltage characteristics of the film was measured using an electrometer (Keithley model 617) which was connected to personal computer by an IEEE 488 data acquisition interface. During the deposition of the BB-12 film, the temperature of the interdigitated substrate was kept at 300 K. A home made stainless steel test chamber with a capacity of liters was used in these experiments. Dry nitrogen was used as carrier gas and the desired relative humidity inside the test chamber was obtained by bubbling dry nitrogen gas through double distilled water. Well defined levels of relative humidity were obtained by mixing dry nitrogen gas and water vapor using a computer driven mass flow controllers (Alicat Scientific, Inc.). Direct current (dc) conductivities of the BB-12 film was calculated from the measured current-voltage characteristics by using following equation;
[TABLE]
where is the measured current, is the bias voltage, is the electrode spacing, is the number of electrode finger pairs, is the overlap length of the electrode fingers and is the thickness of the electrodes.
III Results and Discussion
III.1 Zeta-potential studies
The zeta potential of BB-12 was measured using a Zeta master (Malvern Instruments, Malver, UK) at room temperature. The zeta potential for BB-12 was found to be negative , which indicated that the cell surface was predominantly covered with anionic compounds, such as strong acids, the phosphate based (lipo-) teichoic acids, weak acids, the carboxylate containing acidic polysaccharides and proteins 12 . This negative value is in accordance with the previous studies performed considering that (i) CIDCA 5310, 537 and NCC 189 grown in bile-containing medium 13 and (ii) free L. rhamnosus GG cells as a function of pH 14 . Moreover, similar range of zeta potentials have also been reported for microencapsulation in Alginate and Chitosan Microgels to Enhance Viability of Bifidobacterium 15 . Then, the zeta potential of BB-12 was increased from to as a function of time, which can be an indication that the acidic character of the surface was reduced 12 .
III.2 ATR-FTIR Analysis
The surface structure of the cells of BB-12 were examined by ATR-FTIR spectroscopy. The changes in the structure of all the samples were recorded with the time of water exposure and spectrum is shown in Fig. 4. New bonds and increase in the bond intensity were found in the BB-12 spectra after treatment of distilled water. Powder BB-12, a small broad band at 3301.81 was observed, this band intensity increased after treatment distilled water, which corresponds to the hydroxyl stretching vibration of the polysaccharide 16 ; 17 . The vibrational small peak at 2910.32 is related to the alkyl-hydrocarbons groups, the so called fatty acid region 18 ; 19 . After contacting with the pure water, an increase in the intensity of this peak was observed 18 ; 19 . As shown in Fig.4, the very small peak at 1636.62 is related to the carbonyl stretching of secondary amides (Amide ) 18 ; 20 . But, it was observed that after distilled water treatment the increase for the amide absorption band. The very small peaks at 1407 and 1354 are assigned to the bending of and groups of bacterium 20 . The borad and intensive peaks were observed between 900-1200 refers to polysaccharides and carbohydrates groups and the peak 995 was due to the valence group vibrations in the cyclic structures 17 ; 18 ; 19 . But, after 432 h of distilled water treatment of carbohydrate compounds on the surface decreased. The band located the at 852 is attributed to indicate that configurations exist in the polysaccharides 16 . The change of spectral peaks is in agreement with the zeta-potential results of a BB-12 that has passed into the endogenous phase.
III.3 SEM analysis
The surface morphologies of powder BB-12 before treatment with distilled water were characterized using a scanning electron microscope (SEM) and the results are presented in Figure 5. It is seen in Fig. 5 that the bacterial integrity is maintained and non-spherical structure before purified water.
III.4 Charge transport in Bifidobacterium animalis subsp. lactis BB-12
Charge transport in BB-12 film under direct current condition was investigated by current-voltage measurements. The measurements were carried out at room temperature under various RH conditions. Fig. 6 shows the characteristics of the sample at indicated RH levels. In this measurement the voltage was incremented in steps of from to and back again. The measured curves exhibited considerable hysteresis between increasing and decreasing voltage sweeps. It is important to point out that the area within the loop decreased with an increase in RH level. The interpretation of appearance of the hysteresis behavior in dry nitrogen atmosphere and low RH level requires to take into account many elementary physical processes, such as density of mobile charges, and delay time between two successive measurements separated by a potential step. A considerable increase in film electrical conductivity with the increase in RH level, compared to dry nitrogen atmosphere, was also clearly. Observed the effect of the film conductivity was reversible for all RH levels investigated, which indicated that when the film surface was purged with carrier gas (dry nitrogen) the conductivity of the film returned to the initial value. The relative humidity level was controlled with a commercially available humidity meter and it was found to be less than 2 . Increase in dc conductivity of the film revealed that the interaction between the water molecules and the BB-12 film was based on charge transfer. When the water molecules interacted with the surface of the BB-12 film, BB-12 exhibited n-type character, the zeta potential became more negative due to the formation of functional groups such as and .
IV Conclusions
Charge transport behavior of the BB-12 film and the effect of the RH level on it were investigated by means of measurements. Within the relative humidity, electrical conductivity of the BB-12 increased more than six decades while under environment conductivity returned to the initial current value. This behaviour in conductivity modulation was reversible at least in the three cycles. These experimental findings showed that there was no structural transformation at different relative humidity levels. On the other side, increase in the conductivity was observed with the increase in the population of charge carries, supplied by the interaction of BB-12 with the water moisture, monitored through amine and carboxyl group by FTIR and Zeta potential measurements. Overall, the obtained results n this study indicated that Bifidobacterium animalis subsp. lactis BB-12 has a great potential for humidity detection at room temperature. This type of environment control of the conductivity for the conductivity of BB-12 will pave the way for many working areas such as biomaterials and biosensors.
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