To obtain basic information on the sorption and recycling of gold from aqueous systems the interaction of Au(III) and Au(0) nanoparticles on S-layer proteins were investigated. The sorption of protein polymers was investigated by ICP-MS and that of proteinaceous monolayers by QCM-D. Subsequent AFM enables the imaging of the nanostructures.
In this publication the gold sorption behavior of surface layer (S-layer) proteins (Slp1) of Lysinibacillus sphaericus JG-B53 is described. These biomolecules arrange in paracrystalline two-dimensional arrays on surfaces, bind metals, and are thus interesting for several biotechnical applications, such as biosorptive materials for the removal or recovery of different elements from the environment and industrial processes. The deposition of Au(0) nanoparticles on S-layers, either by S-layer directed synthesis 1 or adsorption of nanoparticles, opens new possibilities for diverse sensory applications. Although numerous studies have described the biosorptive properties of S-layers 2-5, a deeper understanding of protein-protein and protein-metal interaction still remains challenging. In the following study, inductively coupled mass spectrometry (ICP-MS) was used for the detection of metal sorption by suspended S-layers. This was correlated to measurements of quartz crystal microbalance with dissipation monitoring (QCM-D), which allows the online detection of proteinaceous monolayer formation and metal deposition, and thus, a more detailed understanding on metal binding.
The ICP-MS results indicated that the binding of Au(III) to the suspended S-layer polymers is pH dependent. The maximum binding of Au(III) was obtained at pH 4.0. The QCM-D investigations enabled the detection of Au(III) sorption as well as the deposition of Au(0)-NPs in real-time during the in situ experiments. Further, this method allowed studying the influence of metal binding on the protein lattice stability of Slp1. Structural properties and protein layer stability could be visualized directly after QCM-D experiment using atomic force microscopy (AFM). In conclusion, the combination of these different methods provides a deeper understanding of metal binding by bacterial S-layer proteins in suspension or as monolayers on either bacterial cells or recrystallized surfaces.
Due to the increasing use of gold for several applications like electronics, catalysts, biosensors, or medical instruments, the demand of this precious metal has grown over the last few years' time 6-9. Gold as well as many other precious and heavy metals are released into the environment via industrial effluents in dilute concentrations, through mining activities, and waste disposal 7,8,10,although most environmental contamination by heavy or precious metals is an on-going process mainly caused by technological activities. This leads to a significant interference of natural ecosystems and could potentially threaten human health 9. Knowing these negative outcomes promotes the search for new techniques to remove metals from contaminated ecosystems and improvements in recycling metals from industrial wastewater. Well-established physico-chemical methods like precipitation or ion exchange are not so effective, especially in highly diluted solutions 7,8,11. Biosorption, either with living or dead biomass, is an attractive alternative for wastewater treatment 10,12. The use of such biological materials can reduce the consumption of toxic chemicals. Many microorganisms have been described to accumulate or immobilize metals. For instance, cells of Lysinibacillus sphaericus (L. sphaericus) JG-A12 have shown high binding capacities for precious metals, e.g., Pd(II), Pt(II), Au (III), and other toxic metals like Pb(II) or U(VI) 4,13, cells of Bacillus megaterium for Cr(VI) 14, cells of Saccharomyces cerevisiae for Pt(II) and Pd(II) 15, and Chlorella vulgar for Au(III) and U(VI) 16,17. The binding of previous metals like Au(III), Pd(II), and Pt(II) has also been reported for Desulfovibrio desulfuricans18 and for L. sphaericus JG-B53 19,20. Nevertheless, not all microbes bind high amounts of metals and their application as sorptive material is limited 12,21. Furthermore, metal binding capacity depends on different parameters, e.g., cell composition, the used bio-component, or environmental and experimental conditions (pH, ionic strength, temperature etc.). The study of isolated cell wall fragments 22,23, like membrane lipids, peptidoglycan, proteins, or other components, helps to understand the metal binding processes of complex constructed whole cells 8,21.
The cell components focused on in this study are S-layer proteins. S-layer proteins are parts of the outer cell envelope of many bacteria and archaea, and they constitute about 15 – 20% of the total protein mass of these organisms. As the first interface to the environment, these cell compounds strongly influence the bacterial sorption properties 3. S-layer proteins with molecular weights ranging from forty to hundreds of kDa are produced within the cell, but are assembled outside where they are able to form layers on the lipid membranes or polymeric cell wall components. Once isolated, nearly all S-layer proteins have the intrinsic property to spontaneously self-assemble in suspension, at interfaces, or on surfaces forming planar or tube-like structures 3. The thickness of the protein monolayer depends on the bacteria and is within a range of 5 – 25 nm 24. In general, the formed S-layer protein structures can have an oblique (p1 or p2), square (p4), or hexagonal (p3 or p6) symmetry with lattice constants of 2.5 to 35 nm 3,24. The lattice formation seems to be in many cases dependent on divalent cations and mainly on Ca2+ 25,26, Raff, J. et al. S-layer based nanocomposites for industrial applications in Protein-based Engineered Nanostructures. (eds Tijana Z. Grove & Aitziber L. Cortajarena) (Springer, 2016 (submitted)). Nevertheless, the full reaction cascade of monomer folding, monomer-monomer interaction, the formation of a lattice, and the role of different metals, especially of divalent cations such as Ca2+ and Mg2+, are still not fully understood.
The gram-positive strain L. sphaericus JG-B53 (renamed from Bacillus sphaericus after new phylogenetic classification) 27 was isolated from the uranium mining waste pile "Haberland" (Johanngeorgenstadt, Saxony, Germany) 4,28,29. Its functional S-layer protein (Slp1) possesses a square lattice, a molecular weight of 116 kDa 30, and a thickness of ≈ 10 nm on living bacteria cells 31. In previous studies, the in vitro formation of a closed and stable protein layer with a thickness of approximately 10 nm was achieved in less than 10 min 19. The related strain L. sphaericus JG-A12, also an isolate from the "Haberland" pile, possesses high metal binding capacities and its isolated S-layer protein has shown a high chemical and mechanical stability and good sorption rates for precious metals like Au(III), Pt(II), and Pd(II) 4,32,33. This binding of precious metals is more or less specific for some metals and depends on the availability of functional groups on the outer and inner protein surface of the polymer and in its pores, ionic strength, and the pH value. Relevant functional groups for metal interaction by the proteins are COOH-, NH2-, OH-, PO4-, SO4-, and SO-. In principle, metal binding capacities open a wide spectrum of applications,Raff, J. et al. S-layer based nanocomposites for industrial applications in Protein-based Engineered Nanostructures. (eds Tijana Z. Grove & Aitziber L. Cortajarena) (Springer, 2016 (submitted)).e.g., as biosorptive components for removal or recovery of dissolved toxic or valuable metals, templates for synthesis or defined deposition of regularly structured metallic nanoparticles (NPs) for catalysis, and other bio-engineered materials like bio-sensory layers 3,5,18,33. Regularly arranged NP arrays like Au(0)-NPs could be used for major applications ranging from molecular electronics and biosensors, ultrahigh density storage devices, and catalysts for CO-oxidation 34-37. The development of such applications and smart design of these materials necessitates a deeper understanding of the underlying metal binding mechanisms.
A prerequisite for the development of such bio-based materials is the reliable implementation of an interface layer between the biomolecule and the technical surface 38,39. For example, polyelectrolytes assembled with the layer-by-layer (LbL) technique 40,41 have been used as an interface layer for recrystallization of S-layer proteins 39. Such an interface offers a relatively easy way to perform the protein coating in a reproducible and quantitative way. By performing different experiments with and without modification with adhesive promoters, it is possible to make statements regarding coating kinetics, layer stability, and interaction of metals with biomolecules 19,42,Raff, J. et al. S-layer based nanocomposites for industrial applications in Protein-based Engineered Nanostructures. (eds Tijana Z. Grove & Aitziber L. Cortajarena) (Springer, 2016 (submitted)). However, the complex mechanism of the protein adsorption and protein-surface interaction is not completely understood. Especially information on conformation, pattern orientation, and coating densities is still missing.
Quartz crystal microbalance with dissipation monitoring (QCM-D) technique has attracted attention in the recent years as a tool for studying protein adsorption, coating kinetics, and interaction processes on the nanometer scale 19,43-45. This technique allows for the detailed detection of mass adsorption in real-time, and can be used as an indicator for the protein self-assembling process and coupling of functional molecules on protein lattices 19,20,42,46-48. In addition, QCM-D measurements open the possibility to study metal interaction processes with the proteinaceous layer under natural biological conditions. In a recent study, the interaction of the S-layer protein with selected metals like Eu(III), Au(III), Pd(II),and Pt(II) has been studied with QCM-D 19,20. The adsorbed protein layer can serve as a simplified model of a cell wall of gram-positive bacteria. The study of this single component can contribute to a deeper understanding of metal interaction. However, solely QCM-D experiments do not allow statements regarding surface structures and influences of metals to protein. Other techniques are necessary to obtain such information. One possibility for imaging bio-nanostructures and obtaining information on structural properties is the atomic force microscopy (AFM).
The objective of the presented study was to investigate the sorption of gold (Au(III) and Au(0)-NPs) to S-layer proteins, in particular Slp1 of L. sphaericus JG-B53. Experiments were done with suspended proteins on batch scale in a pH range of 2.0 – 5.0 using ICP-MS and with immobilized S-layers using QCM-D. Additionally, the influence of metal salt solution on the lattice stability was investigated with subsequent AFM studies. The combination of these techniques contributes to a better understanding of in vitro metal interaction processes as a tool for learning more about binding events on whole bacterial cells regarding specific metal affinities. This knowledge is not only crucial for the development of applicable filter materials for the recovery of metals for environmental protection and the conservation of resources 49, but also for the development of arrays of highly ordered metallic NPs for various technical applications.
1. Microorganism and Cultivation Conditions
Note: All experiments were done under sterile conditions. L. sphaericus JG-B53 was obtained from a cryo-preserved culture 29,30.
2. S-layer Protein Isolation and Purification
Note: Purify Slp1 polymers according to an adapted method as described previously2,19,30,32,50,51.
3. Characterization and Quantification of Slp1 for Experiments
Note: Slp1 concentration for sorption and coating experiments were quantified by UV-VIS spectrophotometry.
4. Sorption Experiments in Batch-mode and Metal Quantification
5. Synthesis of Au-NP and Determination of Particle Size
Note: Citrate stabilized Au(0)-NP were synthesized according to an adapted method described previously by Mühlpfordt, H. et al. (1982) to obtain spherical particles with a diameter of 10 – 15 nm 56,57.
6. QCM-D Experiments – Slp1 Coating on Surfaces and Au-NP Adsorption onto Slp1 Lattice
Note: Measurements were carried out with a QCM-D equipped with up to four flow modules. All QCM-D experiments were performed with a constant flow rate of 125 µl/min at 25 °C. Slp1 coating and metal/NP incubation were done on SiO2 piezoelectric AT-cut quartz sensors (Ø 14 mm) with a fundamental frequency of ≈ 5 MHz. Rinsing steps and addition of solution are marked in the figures of the representative results part. The QCM-D experiments could be described as a step by step way beginning with cleaning and surface modification of the used sensors followed by Slp1 recrystallization and later on the metal and metal NP interaction.
Figure 1. Schematic Design of PE Surface Modification and Slp1 Monolayer Coating; This figure has been modified from Suhr, M. et al. (2015) 19 with permission from Springer. Please click here to view a larger version of this figure.
Figure 2. Schematic Design of QCM-D Setup using Flow Module QFM 401*66. Please click here to view a larger version of this figure.
7. AFM Measurements
Cultivation of Microorganisms and Slp1 Characterization
The recorded data of bacterial growth indicates the end of the exponential growth phase at around 5 hr. Previous investigations have shown that Slp1 can be isolated from this point of harvest (4.36 g/L wet biomass (≈ 1.45 g/L (BDW)) with a maximum yield 19. Nevertheless, optimization of cultivation by using defined media components or fed-batch cultivation strategies would lead to higher biomass yields. This is inalienable for the use of high amount of biomass for industrial applications. The values from the online and offline recorded cultivation parameters are summarized in Figure 3A. Microscopic control (Figure 3B) at the time of harvest show non-sporulated cells of L. sphaericus JG-B53.
Figure 3: (A) online and offline measured cultivation parameters of L. sphaericus JG-B53 and (B) microscopic image of vital bacteria cells of L. sphaericus JG-B53 at the time of harvest in 400 fold magnification; This figure has been modified from Suhr, M. et al. (2014) 19 with permission from Springer. Please click here to view a larger version of this figure.
Also, an additionally made SDS-PAGE protein profile (Figure 4A) indicates the maximum amount of Slp1 at the time of 5 hr of cultivation. The protein band corresponding to Slp1 (≈ 150 kDa) is thicker, but from here on a loss in intensity was observed accompanied by an increase in proteins with lower molecular weight caused by possible protein fragmentation or segregation of other proteins. The bands of isolated and purified proteins obtained by the method mentioned above (Figure 4B) correspond to a molecular weight of approximately 150 kDa, which is heavier than the calculated weight based on sequencing data of Slp1 (116 kDa) 30. This is probably due to posttranslational modifications. Other reasons for the mismatch between theoretical molecular mass and the observed molecular mass in SDS gels are possibly charge dependent artefacts in the SDS gel 30.
Figure 4. Protein Profiles Made by SDS-PAGE of (A) disintegrated bacteria cells obtained from cultivation samples and (B) purified Slp1 after successful isolation; This figure has been modified from Suhr, M. et al. (2014) 19 with permission from Springer. Please click here to view a larger version of this figure.
Batch-sorption Experiments and Determination of Au with ICP-MS
The maximum metal binding capacities (qmax) of Au(III) by suspended Slp1 are shown in Figure 5. The results show that Au(III) was stably bound by Slp1 during the 24 hr incubation within the investigated pH range. Results indicate qmax in the range of approximately 80 – 100 mg Au(III)/g Slp1. The summarized values (Table 1) were compared with the sorption capacity of around 75 mg Au(III)/g Slp1 reported previously by Suhr, M. et al. (2014) obtained from experiments with self-adjusting pH-values by addition of the metal salt solution (pH ≈ 4.3) 19. To summarize, Slp1 has shown the ability to bind high amounts of initially added Au(III) proving its high binding capacities for this element.
Figure 5. Diagram of Maximum Metal Binding Capacities (qmax) of Au(III) to Slp1 polymers within pH-adjusted experiments compared to sorption results using self-adjusted pH-values (≈ 4.3) reported by Suhr, M. et al. (2014) 19. Please click here to view a larger version of this figure.
The calculated metal removal efficiencies (RE) within the investigated pH range were between 50 – 60% thus confirming the results made by Suhr, M. et al. (2014) where values of around 40% were achieved. In previously made experiments, strong interactions of Au(III) with the functional groups e.g., carboxylic-, hydroxyl-, and amino groups, has been observed for S-layer proteins like Slp1 and for the comparative protein SlfB of L. sphaericus JG-A12 1,78. Jankowski, U. et al. (2010) detected spectroscopically a strong interaction of Au(III) mainly with carboxylic groups of SlfB that could also be deduced for Slp1 of L. sphaericus JG-B53 20,79,80. Also, intrinsic protein properties that would reduce Au(III) to Au(0) in the absence of reducing agents could be a reason for the strong interaction 79. Furthermore, the results of this study show the tendency of a preferred binding of Slp1 at lower pH-values. On the other hand, a binding at lower pH-values could also lead to a denaturation of Slp1. Studies to the Slp1 proved a protein stability down to pH = 3.0 (unpublished results). From desorption experiments under acidic conditions, using e.g., nitric acid or using complexing agents like EDTA or citrate (data not shown), verifies that gold was stably bound and could not be released from Slp1 polymers.
Au(III) on Slp1 of L. sphaericus JG-B53 | ||||||||
cinitial (mg/L) | 196.97 | |||||||
pH | 5 | 4.5 | ≈ 4.3 23 | 4 | 3.5 | 3 | 2.5 | 2 |
value | ||||||||
qmax | 88.3 | 85.3 | 74.7 | 102.5 | 94.1 | 81 | 101.9 | 96.9 |
(mg Au(III) /g Slp1) | ||||||||
RE | 47.1 | 47.8 | 37.9 | 57.1 | 54.1 | 44.8 | 58.7 | 56.5 |
(%) |
Table 1: Maximum Metal Binding Capacities (qmax) and Metal Removal Efficiencies (RE) of Batch-sorption Experiments with Au(III) and Slp1 Polymers in Solution Analyzed by ICP-MS. Data compared to previously published results from Suhr, M. et al. (2014) 19.
Slp1 Monolayer Recrystallization Tracked by QCM-D
The immediate decrease in frequency (Δf5, Δf7, Δf9, Δf11) indicates a rapid adsorption and a high affinity of the proteins to the PE modified surface (Figure 6A). Equal to the fast change in frequency, the dissipation (ΔD5, ΔD7, ΔD9, ΔD11) also increases immediately. This fact indicates an adsorption of viscoelastic molecules to the surface because of fast damping resulting in increasing dissipation values. The maximum frequency shift is achieved after 5 min with a value of ≈ 95 Hz and ΔD of 4.2. At a later stage only rearrangements of recrystallized Slp1 occur. Slp1 adsorption was thusly carried out for over 60 min to ensure the formation of an almost fully covered surface and regularly ordered protein lattice. The experiment shows that the positively charged PE layer is inalienable for achieving stable coatings, negative ending modification leads to a weak adsorption and longer coating kinetics (data not shown) 38. Weakly attached proteins and agglomerates were removed by rinsing with Slp1-free recrystallization buffer. The small changes of Δfn confirm the low protein desorption and stable adsorption of Slp1. Despite this the dissipation drops down to ≈ 2.8 indicating that bigger elastic molecules are removed.
Figure 6. Recrystallization of Slp1 on Modified SiO2 Sensors Analyzed by QCM-D; (A) in Δf/ΔD plot and (B) surface thickness profile; This figure has been modified from Suhr, M. et al. (2014) 19 with permission from Springer and Suhr, M. (2015) 20. Please click here to view a larger version of this figure.
The surface profile calculated by using the previous mentioned models show a Slp1 monolayer thickness of ≈ 11.2 nm (Kelvin-Voigt model for elastic films) and of 10.0 nm (Sauerbrey model for rigid layer) (Figure 6B). These values are lower than those reported by Suhr, M. et al. (2014). The differences can be explained by a different used value of protein layer density within the modelling. The current values should be closer to realities of layer thickness of S-layer proteins on the cell surface of living cells of L. sphaericus JG-B53 31,42. This modelling demonstrates that the Sauerbrey relation is inappropriate for acoustical thin proteinaceous layer, because of a propagation of the shear acoustic wave in viscoelastic liquid films 81,82 that results in an underestimation of the adsorbed Slp1 mass and thickness. This can be explained by the elastic properties of S-layer proteins and its coupling of water molecules during the adsorption process. The interaction of water with proteins can be easily described by formation of hydration shells, viscous drag or entrapment in cavities in the adsorbed layer 83. This effects a higher layer thickness measured by the Kelvin-Voigt model and can also clarify the differences in the layer thickness obtained by the two different models. In previous AFM studies, layer thicknesses of Slp1 lattices of around 8-12 nm were measured. By calculating the mass adsorption of Slp1, instead of layer thickness, a total Δm of 1506.6 ng ∙ cm-2 (Kelvin-Voigt model) was calculated. The data of mass adsorption on surfaces are summed up in Table 2 and show a high mass adsorption by using the values of the Kelvin-Voigt model.
mmax | ∆mmax | thickness | thickness | |
(ng/cm2) | (ng/cm2) | (nm) | (nm) | |
(Kelvin-Voigt) | (Sauerbrey) | (Kelvin-Voigt) | (Sauerbrey) | |
Slp1 after coating and rinsing | 1,505.6 | 1,351.6 | 11.2 | 10 |
Table 2: Adsorbed Mass of Slp1 on Modified Polyelectrolyte SiO2 Crystals Analyzed by QCM-D after Rinsing with Recrystallization Buffer (pH = 8.0) and Calculated Layer Thickness.
QCM-D as Tool for Detection of Metal and Metal NP Interaction with Proteinaceous Slp1 Monolayer
The interaction of recrystallized Slp1 monolayer with 1 mM and 5 mM dissolved Au(III) was investigated. The results of total adsorbed mass obtained from calculations and modeling of the recorded data of changes in frequency and dissipation are summarized in Table 3. The QCM-D studies of Au(III) interaction with the monolayers provide a deeper understanding of the metal-biomolecule interaction. For the first time, the binding capacity, sorption kinetics, and how the metal influences the protein stability were studied in a nano-range. After the addition of the metal salt solution to the Slp1 monolayer the frequency decreased within the first 5 min indicating a fast mass adsorption. Nevertheless, the adsorption of Au was not completed after 60 min as described for other metals like Pd(II) in previous studies 19. The mass increase occurs up to 18 hr. After this time, rinsing steps were performed with metal free buffer showing that the adsorbed metal is almost stably bound to the recrystallized Slp1 layer. Finally, a total metal absorption of 955.0 ± 2.7 ng ∙ cm-2 (Kelvin-Voigt model) was obtained in case of the 1 mM Au(III) solution and 4,534.4 ± 5.5 ng ∙ cm-2 (Kelvin-Voigt model) in case of 5 mM Au(III). The higher values obtained by 5 mM Au(III) solutions can be explained by intrinsic reduction properties of Slp1 where smallest metallic Au(0)-NP were formed from this solution. These reducing properties of Slp1 have been already reported in previous studies for Pd(II) and Au(III) 32,33,79,84. The data also showed that the interaction with the gold solution does not lead to a destabilization of the protein layers. This indicates the specific and stable binding of Au(III) to Slp1, which has been also confirmed by ICP-MS measurements using protein polymers.
The formation of Au(0)-NP during the synthesis could be visualized by color change from the starting yellow solution to a reddish one. This color change is caused by the excitation of the surface plasmon oscillations of metallic nanoparticles and proves the formation of Au(0)-NPs 1,78. Furthermore smaller NPs could be synthesized by the variation of the concentration of the reducing agent (higher tannic acid concentration) 85 visible in a different coloring of solution and verified by results of PCS measurements (data not shown). On the other hand, increasing tannic acid concentration leads to a loss of NP stability and NPs tend to agglomerate 20. As proof of principle, pre-synthesized Au(0)-NPs (size distribution of 10 – 18 nm measured by PCS seen in Figure 7A) were incubated with suspended Slp1 for 48 hr and analyzed by SDS-PAGE. The protein profile shown in Figure 7B verifies the conclusion drawn from QCM-D data, that Au(0)-NPs do not disturb the Slp1 structure. The observed protein bands at 150 kDa prove the presence of intact Slp1.
Figure 7. (A) Number weighted size distribution of pre-synthesized Au(0)-NPs measured by PCS and (B) SDS-PAGE protein profile of Slp1; lane 1: 2 µg Slp1 before Au(0)-NPs interaction and lane 2: 1 µg Slp1 polymers in suspension after 48 hr incubation with pre-synthesized Au(0)-NPs. Please click here to view a larger version of this figure.
After the NP-synthesis and characterization, QCM-D experiments were carried out. The adsorption of pre-synthesized metallic Au(0)-NPs is exemplarily shown for QCM-D experiments in Δf/ΔD plots (Figure 8A) and as thickness and mass profiles (Figure 8B).
Figure 8. Adsorption of Pre-synthesized Au(0)-NPs onto Recrystallized Slp1 Lattice Analyzed by QCM-D, (A) in Δf/ΔD plot and (B) layer surface and mass profile. Please click here to view a larger version of this figure.
It could be confirmed that QCM-D can be used to detect the adsorption of the 10 – 18 nm spherical Au(0)-NPs. After addition of the undiluted Au-NP solution (A520 nm = 1) obtained by the described synthesis, the frequency decreases, which is a direct indicator of mass adsorption described by the prediction of the Sauerbrey equation (Equation 1). The adsorption of Au(0)-NPs was almost completed within less than 60 min. After this time no more NPs were deposited on the top of the Slp1 lattice, so it can be assumed that all reactive sites or pores were occupied by Au(0)-NPs. The shown decrease in dissipation can be affiliated to the stiffening of Slp1 lattice cause by the NP interaction. The values of total mass adsorption are summed up in Table 3. Even intensive rinsing with the NP-free citrate buffer leads neither to a desorption of NPs nor to a detachment of the Slp1 monolayer. Therefore, a stable and strong interaction can be predicted for the Au(0)-NP interaction in the same respect as with Au(III).
Metal | cmetal | ∆mmax | ∆mmax | thickness | thickness |
(ng/cm2) | (ng/cm2) | (nm) | (nm) | ||
(Kelvin-Voigt) | (Sauerbrey) | (Kelvin-Voigt) | (Sauerbrey) | ||
Au(III) | 1 mM | 955 | 932.6 | — | — |
5 mM | 4,534.4 | 4,687.9 | — | — | |
Au(0)- | — | 1,382.9 | 1,382.7 | 10.2 | 10.2 |
NPs |
Table 3: Adsorbed Mass on Recrystallized Slp1 Lattice after Au(III) Interaction (pH = 6.0) and Au-NP Adsorption (pH = 4.7) Analyzed by QCM-D and Calculation of Layer Thickness after Au(0)-NP Coating. Data compared to previously published results from Suhr, M. et al. (2014) 19.
AFM for Visualization of Nanometer Scaled Structures
Subsequent AFM studies after QCM-D experiments were performed to obtain structural information of Slp1 self-assemblies before and after their interaction with metals and NPs. This is necessary to correlate the mass adsorption detected during the QCM-D experiments with the completeness of protein coatings and the protein lattice structures allowing statements about protein layer stability. In Figure 9, the protein lattice of Slp1 recrystallized on PE modified sensors is shown with its typical square lattice (p4) as amplitude images. The lattice constant could be determined as 13 – 14 nm, which is comparable to results of previous experiments 30. The layer thickness of 10 nm ± 2.0 nm measured by AFM verified the predicted layer thickness of the QCM-D measurements of ≈ 11.2 nm (Kelvin-Voigt modelling). The small difference in the surface height can be explained by the fact that the calculated QCM-D fit considers the whole sensor area while the high resolution AFM study only shows a partial area. Given this, protein agglomerates that were attached to the sensor surface were included in the calculation of the adsorbed mass respectively to the layer thickness and led to a higher layer thickness than determined by AFM.
Figure 9. AFM Amplitude Image of Recrystallized Slp1 Lattice of L. sphaericus JG-B53 on QCM-D Crystals Directly after Coating and Rinsing with Buffer and Magnification of Marked Region; This figure has been modified from Suhr, M. et al. (2014) 19 with permission from Springer. Please click here to view a larger version of this figure.
Subsequent to Au(III) and Au(0)-NP interaction with Slp1 and measurements performed with QCM-D, the sensor surfaces were investigated by AFM. Figure 10 shows the intact Slp1 lattice after incubation with Au(III) solution. It can be shown that after the incubation the protein lattice remained completely intact. This confirms the results from the QCM-D experiments that predicted the stability of the coating. In Figure 11A and B the adsorbed pre-synthesized Au(0)-NPs (size varies from 10 – 18 nm determined by PCS) on the Slp1 lattice are shown. Due to the particle size, the Au(0)-NPs are adsorbed in the Slp1 pores and do not follow the p4-symmetry of Slp1. Au(0)-NPs are statistical distributed on protein lattice. By measuring the particle sizes in AFM height images (data not shown) the size of the NPs is in the range of 16 – 23 nm and even smaller, namely in the range of approximately 10 nm 19,20. This verifies the determined NP size measured previously by PCS (seen in Figure 8).
Figure 10. AFM Amplitude Image of Recrystallized and Intact Slp1 Lattice on QCM-D Sensor Crystals after Incubation of 5 mM Au(III) Solution and Magnification of Marked Region; This figure has been modified from Suhr, M. et al. (2014) 19 with permission from Springer and Suhr, M. (2015) 20. Please click here to view a larger version of this figure.
Figure 11. (A) AFM amplitude image of adsorbed Au(0)-NPs on recrystallized Slp1 lattice on QCM-D sensor crystals (left) and (B) 3D reconstructed surface profile (right); This figure has been modified from Suhr, M. (2015) 20 with permission from Springer and Raff, J. et al. (2016) Raff, J. et al. S-layer based nanocomposites for industrial applications in Protein-based Engineered Nanostructures. (eds Tijana Z. Grove & Aitziber L. Cortajarena) (Springer, 2016 (submitted)). Please click here to view a larger version of this figure.
In this work studied the binding of Au to S-layer proteins was investigated using a combination of different analytical methods. In particular, the binding of Au is very attractive not only for the recovery of Au from mining waters or process solutions, but also for the construction of materials, e.g., sensory surfaces. For studies of the Au interaction (Au(III) and Au(0)-NPs) with suspended and recrystallized monolayer of Slp1, the protein had to be isolated. Therefore, this study has shown the successful cultivation of the gram-positive bacterial strain L. sphaericus JG-B53 and the isolation of the surface layer protein Slp1. Nevertheless, the cultivation and protein isolation remain challenging and should be optimized. A large scale production of biomass and S-layer proteins is a precondition for an industrial application of both, e.g., for the production of metal selective filter materials. Their application potential is undoubtedly high for the removal of toxic metals or the recovery of valuable metals dissolved in process water, waste water, or drainage water. Furthermore, the application potential for S-layers is even larger considering their additional potential in other bio-inspired materials, such as biosensors and catalysts.
The batch-sorption experiments of suspended Slp1 polymers indicated a high and stable binding of Au(III) within the investigated pH-range from 2.0 to 5.0. Thereby, metal removal efficiencies of up to 60% could be reached. This remarkable binding behavior can be explained by a strong interaction of Au(III) with Slp1 probably induced through interaction of carboxylic groups and nitrogen bearing groups present on the surface of the protein. This arguments could be strengthen by FTIR and EXAFS investigation of the similar strain L. sphaericus JG-A12 32,79. Also, intrinsic reducing properties of Slp1 can explain the high RE of Au(III) by reducing it to nanoparticular Au(0). It can be assumed that S-layer, as first interface of bacteria to the environment, should be mainly involved in metal binding. Within the investigated pH range, the highest metal binding capacity with 102.5 mg Au(III)/g Slp1 was achieved at pH 4.0. This binding capacity is higher than reported for other bio-components, e.g., for isolated cell wall of Bacillus subtilis (71.5 mg Au(III)/g) 86 or for biomass of Chlorella vulgaris (98.5 mg Au(III)/g) 8.
ICP-MS used for determination of the bound metal by Slp1 polymers is very sensitive method and enables the detection of smallest amounts of gold in this study. ICP-MS offers many benefits for performing trace metal determinations, e.g., easy handling system and low detection limits; in case of gold down to 0.1 – 1 ppt. This makes this method a versatile tool for investigating biosorptive processes in low concentration ranges. However, the results in this investigation were gained with suspended S-layer polymers and cannot be easily transferred to S-layer lattices recrystallized on surfaces, and therefore show the limitation of ICP-MS. For example, no direct relation of isolated protein polymers could be made to those S-layer structures on vital bacteria cells. In addition, the ICP-MS measurements do not allow the determination of the kinetic of metal sorption. Therefore, it is necessary to find methods more suitable for the investigation of the metal binding by thin immobilized protein films.
In the present study, QCM-D analyses were applied to detect the in situ formation of S-layer lattices on surfaces as well as the deposition of Au on the proteins. Therefore, QCM-D is a robust and reproducible method for the recognition of molecule adsorption and interaction processes . Additionally QCM-D is a relatively simple, cost-effective, and nonhazardous method to monitor such processes online. The method has the advantage to detect mass change with a maximum mass sensitivity in liquids of ≈ 0.5 ng ∙ cm-2. This enables the possibility to detect even weak interaction, e.g., of protein with dissolved metals or to measure adsorptions in low concentration ranges. The disadvantage of QCM-D is that this is not a structure imaging method that allows the visualization of e.g., protein lattices. Therefore, other techniques are needed.
The QCM-D analyses in this study were followed by AFM imaging. The combination of these methods allowed the study of the sorption kinetics and consequences of Au sorption for the coating, thus proving that they are versatile tools for investigating metal interaction of thin proteinaceous films. Further, it was shown that a reliable recrystallization of the S-layer proteins on technical supports is essential for subsequent protein interaction studies. Therefore, modifications of the surfaces using adhesion promotors are of interest. The described implementation of polyelectrolytes (ending with positively charged PEs) as intermediate layer between SiO2 surfaces and protein layer lead to an improved method for a fast protein coating. The positive effect of a positively charge polyelectrolyte layer has been described previously for e.g., immobilization of vital bacteria cells of L. sphaericus JG-B53 31. The implementation of the presented PE-layers are the most important and critical step for the later successful and reproducible recrystallization of S-layer proteins.
It could be demonstrated that for the investigation of thin layers of Slp1, QCM-D is a good method to show the mass adsorption respective to the protein recrystallization as monolayer films in real time. This could also be observed previously for the reassembly of the S-layer protein SbpA of L. sphaericus CCM2177 47. By using subsequent high-resolution AFM analyses changes of the lattice structure of the protein self-assemblies can be visualized. AFM measurements revealed the p4 symmetry of Slp1 and confirm the modelled layer thickness of Slp1 of about 10 nm. Also, the direct interaction of dissolved metal ions with the protein layer could be monitored by QCM-D proving good binding of Au(III) by the underlying protein layer. The probable formation of the smallest Au(0)-NPs from Au(III) solution inside protein pores caused by intrinsic reducing properties of the Slp1 lattice within QCM-D measurements could not been detected by subsequent AFM measurements. This could be related to the resolution limit of AFM and the experimental set up in this study. This shows the limitation of this technique and the necessity of high resolution imaging for biomolecules in the sub nanometer scale. However, a high stability of the recrystallized Slp1 layer could be deduced from the obtained QCM-results and was confirmed by AFM investigation.
In conclusion, it could be shown that Slp1 polymers have high metal binding capacities for gold within the investigated pH-range. Furthermore, the investigation reveals that the Slp1 lattice is a good matrix metal ion binding and for the immobilization of metallic nanoparticles. It could be shown that each method used in this article has the possibility to detect even small metal interactions, or in case of AFM can visualize structures in the nanoscale range. Although, it is only by the combination of these shown methods, that has allowed to improve the knowledge and understanding of the investigated proteins on a molecular level.
Mainly, QCM-D and AFM are the preferred methods of choice for future investigation of protein monolayer adsorption and their interaction with metals and functional molecules. By combining these two methods, the detection of S-layer protein adsorption processes and surface imaging provides an insight into molecular processes that may be able to be transferred to enhance the knowledge of living bacteria and the interaction with their environment. This study showed an excerpt of possible methods helpful for understanding protein and metal interaction. Other helpful techniques that could enhance the knowledge of such processes in detail ranging from diverse spectrometric and chromatographic methods to spectroscopic investigation of biomolecules and should be included in future studies.
The authors have nothing to disclose.
The present work was partially funded by the IGF-project "S-Sieve" (490 ZBG/1) funded by the BMWi and the BMBF-project "Aptasens" (BMBF/DLR 01RB0805A). Special thanks to Tobias J. Günther for his valuable help during AFM studies and to Erik V. Johnstone for reading the manuscript as a native English speaker. Further, the author of this paper would like to thank Aline Ritter and Sabrina Gurlit (from Institute for Resource Ecology for assistance in ICP-MS measurements), Manja Vogel, Nancy Unger, Karen E. Viacava and the group biotechnology of the Helmholtz-Institute Freiberg for Resource Technology.
equiment and software | |||
Bioreactor, Steam In Place 70L Pilot System | Applikon Biotechnology, Netherlands | Z6X | Including dO2, pH sensors of Applikon Biotechnology and BioXpert software V2 |
Noninvasive Biomass Monitor BugEye 2100 | BugLab, Concord (CA), USA | Z9X | — |
Spectrometer Ultrospec 1000 | Amersham Pharmacia Biotech, Great Britain | 80-2109-10 | Company now GE Healthcare Life Sciences |
MiniStar micro centrifuge | VWR, Germany | 521-2844 | For centrifugation of cultivation samples |
Research system microscope BX-61 | Olympus Germany LLC, Germany | 037006 | Microscope in combination with imaging software |
Cell^P (version 3.1) | Olympus Soft Imaging Solutions LLC, Münster, Germany | — | together with microscope |
Powerfuge Pilot Separation System Serie 9010-S | Carr Centritech, Florida, USA | 9010PLT | For biomasse harvesting |
T18 basic Ultra Turrax | IKA Labortechnik, Germany | 431-2601 | For flagella removal and sample homogenization |
Sorvall Evolution RC Superspeed Centrifuge | Thermo Fisher Scientific, USA | 728411 | Used within protein isolation |
Mobile high shear fluid processor, M-110EH-30 Pilot | Microfluidics, Massachusetts, USA | M110EH30K | Used for cell rupture |
Alpha 1-4 LSC Freeze dryer | Martin Christ Freeze dryers LLC, Osterode, Germany | 102041 | — |
UV-VIS spectrophotometry (NanoDrop 2000c) | Thermo Fisher Scientific, USA | 91-ND-2000C-L | For determination of protein concentration |
Mini-PROTEAN vertical electrophoresis chamber | Bio-Rad Laboratories GmbH, Munich, Germany | 165-3322 | For SDS-PAGE |
VersaDoc Imaging System 3000 | Bio-Rad Laboratories GmbH, Munich, Germany | 1708030 | Used for imaging of SDS-PAGE gels |
ICP-MS Elan 9000 | PerkinElmer, Waltham (MA), USA | N8120536 | For determination of metal concentration |
Zetasizer Nano ZS | Malvern Instruments, Worcestershire United Kingdom | ZEN3600 | For determination of nanoparticle size |
Q-Sense E4 device | Q-Sense AB, Gothenburg, Sweden | QS-E4 | ordered via LOT quantum design (software included with E4 platform) |
Q-Soft 401 (data recording) | Q-Sense AB, Gothenburg, Sweden | ||
Q-Tools 3 (data evaluation and modelling) | Q-Sense AB, Gothenburg, Sweden | ||
QCM-D flow modules QFM 401 | Q-Sense AB, Gothenburg, Sweden | QS-QFM401 | ordered via LOT quantum design |
QSX 303 SiO2 piezoelectric AT-cut quartz sensors | Q-Sense AB, Gothenburg, Sweden | QS-QSX303 | ordered via LOT quantum design |
Ozone cleaning chamber | Bioforce Nanoscience, Ames (IA), USA | QS-ESA006 | ordered via LOT quantum design |
Atomic Force Microscope MFP-3D Bio AFM | Asylum Research, Santa Barbara (CA), USA | MFP-3DBio | AFM measurements and imaging software |
Asylum Research AFM Software AR Version 120804+1223 | Asylum Research, Santa Barbara (CA), USA | — | imaging software included in Cat. No. MFP-3DBio |
Igor Version Pro 6.3.2.3 Software | WaveMetrics, Inc., USA | — | imaging software included in Cat. No. MFP-3DBio |
BioHeater | Asylum Research, Santa Barbara (CA), USA | Bioheater | Sample heater for AFM measurements |
Biolever mini cantilever, BL-AC40TS-C2 | Olympus Germany LLC, Germany | BL-AC40TS-C2 | Prefered cantilever for AFM measurements |
WSxM 5.0 Develop 6.5 (2013) | Nanotec Electronica S.L. , Spain | freeware | Software for AFM analysis |
Name | Company | Catalog Number | Comments |
Detergents and other equiment | |||
Calcium chloride Dihydrate (CaCl2 ∙ 2H2O) | Merck KGaA | 1.02382 | — |
acidic acid, 100 %, p.A. | CARL ROTH GmbH+CO.KG | 3738.5 | Danger, flammable and corrosive liquid and vapour. Causes severe skin burns and eye damage. |
Antifoam 204 | Sigma-Aldrich Co. LLC. | A6426 | For foam suppression |
bromophenol blue, sodium salt | Sigma-Aldrich Co. LLC. | B5525 | — |
Coomassie Brilliant Blue R (C45H44N3NaO7S2) | CARL ROTH GmbH+CO.KG | 3862.1 | — |
Deoxyribonuclease II from porcine spleen | Sigma-Aldrich Co. LLC. | D4138 | Typ IV , 2,000-6,000 Kunitz units/mg protein |
Ethanol, 95% | VWR, Germany | 20827.467 | Danger, flammable |
glycerine, p.A. | CARL ROTH GmbH+CO.KG | 3783.1 | — |
Gold(III) chloride trihydrate (HAuCl4 ∙ 3H2O) | Sigma-Aldrich Co. LLC. | 520918 | Danger |
Guanidine hydrochloride (GuHCl) | CARL ROTH GmbH+CO.KG | 0037.1 | — |
Hellmanex III | Hellma GmbH & Co. KG | 9-307-011-4-507 | — |
Hydrochloric acid (HCl) (37%) | CARL ROTH GmbH+CO.KG | 4625.2 | Danger; Corrosive, used for pH adjustment |
Lysozyme from chicken egg white | Sigma-Aldrich Co. LLC. | L6876 | Lyophilized powder, protein =90 %, =40,000 units/mg protein (Sigma) |
Magnesium chloride Hexahydrate (MgCl2 ∙ 6H2O) | Merck KGaA | 1.05833 | — |
Magnetic stirrer with heating, MR 3000K | Heidolph Instruments GmbH & Co.KG, Germany | 504.10100.00 | Standard stirrer within experiment |
NB-Media DM180 | Mast Diagnostica GmbH | 121800 | — |
Nitric acid (HNO3) | CARL ROTH GmbH+CO.KG | HN50.1 | Danger; Oxidizing, Corrosing |
PageRuler Unstained Protein Ladder | ThermoScientific-Pierce | 26614 | — |
Poly(sodium 4-styrenesulfonat) (PSS) | Sigma-Aldrich Co. LLC. | 243051 | Average Mw ~70,000 |
Polyethylenimine (PEI), branched | Sigma-Aldrich Co. LLC. | 408727 | Warning; Harmful, Irritant, Dangerous for the environment; average Mw ~25,000 |
Potassium carbonate anhydrous (K2CO3) | Sigma-Aldrich Co. LLC. | 60108 | Warning; Harmful |
Ribonuclease A from bovine pancreas | Sigma-Aldrich Co. LLC. | R5503 | Type I-AS, 50-100 Kunitz units/mg protein |
Sodium azide (NaN3) | Merck KGaA | 106688 | Danger; very toxic and Dangerous for the environment |
Sodium chloride (NaCl) | CARL ROTH GmbH+CO.KG | 3957.2 | — |
Sodium dodecyl sulfate (SDS) | Sigma-Aldrich Co. LLC. | L-5750 | Danger; toxic |
Sodium hydroxide (NaOH) | CARL ROTH GmbH+CO.KG | 6771.1 | Danger; Corrosive, used for pH regulation within cultivation and pH adjustment |
Spectra/Por 6, Dialysis membrane, MWCO 50,000 | CARL ROTH GmbH+CO.KG | 1893.1 | — |
Sulfuric acid (H2SO4) | CARL ROTH GmbH+CO.KG | HN52.2 | Danger; Corrosive, used for pH regulation within cultivation |
Tannic acid (C76H52O46) | Sigma-Aldrich Co. LLC. | 16201 | — |
TRIS HCl (C4H11NO3HCl) | CARL ROTH GmbH+CO.KG | 9090.2 | — |
Tri-sodium citrate dihydrate (C6H5Na3O7 ∙ 2H2O) | CARL ROTH GmbH+CO.KG | 3580.2 | — |
Triton X-100 | CARL ROTH GmbH+CO.KG | 3051.3 | Warning; Harmful, Dangerous for the environment |
VIVASPIN 500, 50.000 MWCO Ultrafiltration tubes | Sartorius AG | VS0132 | — |
β-mercaptoethanol | Sigma-Aldrich Co. LLC. | M6250 | Danger, toxic |