Kinetic Control of Microtubule Morphology ... - ACS Publications

Sep 13, 2016 - Gold Nanoparticles on Living Fungal Biotemplates. Andressa M. Kubo,. † ... Carlos, São Carlos, São Paulo, 13.565-905, Brazil. ‡. Labora...
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Kinetic control of microtubule morphology obtained by assembling gold nanoparticles on living fungal biotemplates Andressa Mayumi Kubo, Luiz Fernando Gorup, Luciana Silva Amaral, Edson Rodrigues-Filho, and Emerson Rodrigues Camargo Bioconjugate Chem., Just Accepted Manuscript • DOI: 10.1021/acs.bioconjchem.6b00340 • Publication Date (Web): 13 Sep 2016 Downloaded from http://pubs.acs.org on September 13, 2016

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Bioconjugate Chemistry is published by the American Chemical Society. 1155 Sixteenth Street N.W., Washington, DC 20036 Published by American Chemical Society. Copyright © American Chemical Society. However, no copyright claim is made to original U.S. Government works, or works produced by employees of any Commonwealth realm Crown government in the course of their duties.

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Second Revision Kinetic control of microtubule morphology obtained by assembling gold nanoparticles on living fungal biotemplates Andressa M. Kubo§, Luiz F. Gorup§, Luciana S. Amaral†, Edson R. Filho†, Emerson R. Camargo§* §

LIEC Interdisciplinary Laboratory of Electrochemistry and Ceramics, Department of Chemistry,

UFSCar Federal University of São Carlos, São Carlos, São Paulo, 13.565-905, Brazil †

Laboratory of Micromolecular Biochemistry of Microorganisms, Department of Chemistry, UFSCar

Federal University of São Carlos, São Carlos, São Paulo, 13.565-905, Brazil

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ABSTRACT

Self-assembly of nanoparticles on living biotemplate surfaces is a promising route to fabricate nano- or microstructured materials with high efficiency and efficacy. We used filamentous fungi to fabricate microtubules of gold nanoparticles through a novel approach that consists of isolating the hyphal growth from the nanoparticle media. This improved methodology resulted in better morphological control and faster adsorption kinetics, which reduced the time needed to form homogeneous microtubules and allowed for control of microtubule thickness through successive additions of nanoparticles. Differences in the adsorption rates due to modifications in the chemical identity of colloidal gold nanoparticles indicated the influence of secondary metabolites and growth media in the fungi metabolism, which demonstrated the need to choose not only the fungus biotemplate but also the correct medium to obtain microtubules with superior properties.

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INTRODUCTION The use of soft templates that combine biological structures and inorganic nanoparticles permits the synthesis and large-scale production of advanced nanostructured hybrid systems with high uniformity and reproducibility.1-3 For instance, DNA,4 viruses,5,6 and microorganisms7,8 including bacteria9,10 or fungi11 present unique structural motifs that are easily and quickly reproduced. In this context, various filamentous fungi have been used as biotemplates to fabricate microwires or microtubules, some of them exhibiting promising optical, electronic,12 and catalytic properties.13,14 Due to their facile handling15-18 and capacity to assembly colloidal nanoparticles,19 these new hybrid materials based on living biotemplates exhibit several potential technological applications. However, there is a lack of information about the best procedures and routing protocols to fabricate such materials. The need to control properties at the nanometer scale resulted in diverse strategies to fabricate and improve the morphology and homogeneity of nanostructured materials. For this reason, it is necessary to understand the system features in and out of equilibrium,20 especially when the objective is to arrange colloidal nanoparticles on templates.21,22 Different adsorption kinetic models can be employed to explain the kinetics in liquid-solid systems,23 but only recently the Lagergren equation (also known as LFO) was used to correlate experimental data from adsorption kinetics of silver nanoparticles.24 In this study, we report an optimized route for the self-organization of colloidal gold nanoparticles on living filamentous fungi to fabricate microtubules of 2–3 micrometers thick and lengths exceeding a few millimeters. The process 3 ACS Paragon Plus Environment

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involves the synthesis of gold nanoparticles using the citrate method and the growth of Penicillium brasilianum, Aspergillus aculeatus and Xylaria sp filamentous fungi biotemplates in different culture media. Gold nanoparticles were added in bottles containing mycelial fungi previously grown in culture medium, and these nanoparticles adhered to the surface of the hyphae, covering it in several layers to form microtubule structures. We evaluated the influence of the three fungal species and culture media on the adsorption time of the particles, tube diameter, tube wall thickness and length of the wires. Unlike previous studies that focused only on the properties of the final hybrid material, we paid special attention to correlate the adsorption kinetics with the morphological characteristics of the microtubules. RESULTS AND DISCUSSION Self-assembly of nanoparticles using living biotemplates is a promising route to fabricate nano or microstructured materials with high efficiency and efficacy.25-29 Many researchers used fungi as templates to build functional hierarchical structures by introducing spores directly into a colloidal suspension of nanoparticles. Although it is the most simple and facile way to promote self-organization of nanoparticles on fungal mycelia,19 such a process entail a slow hyphal growth and frequently results in large heterogeneities and microtubules of variable diameters. On the other hand, we obtained better morphological control isolating the hyphal growth from nanoparticle presence. This improved procedure reduced the time necessary to form gold microtubules to intervals of 10–22 days, which is significantly shorter than the 90 days usually required for other methodologies.19 Obviously, the time requirement depends on the fungi species and culture media. For this reason, we evaluated the influence of three species of fungi in different culture media on the time required to form microtubules, analyzing the tube diameter, wall thickness and tubule length as comparative variables. 4 ACS Paragon Plus Environment

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Spores of Aspergillus aculeatus and Penicillium brasilianum and a slice of Xylaria sp. were inoculated at room temperature in different culture media, i.e. CZAPEK (modified DSMZ 130, without agar), CZAPEK-yeast extract and potato dextrose (PD), which detailed compositions are described in Table 1. Figure 1 compares the growth rates of these different fungi by detailing the time needed in each step to form the hybrid material, including i) hyphal growth, ii) particle deposition and iii) lyophilization. The images show typical macroscopic aspects at these distinct moments. The first image shows germinated spores forming a mycelial mass that became visible after approximately 24 h, the second image shows gold nanoparticles forming microtubules on the fungus template, and the last image shows the microtubules completely formed during lyophilization. The time required to form microtubules was different for each fungi, which is likely related to their specific metabolisms and the presence of different metabolites. The shortest time (5 days) was achieved using Penicillium brasilianum and the longest (15 days) occurred with Aspergillus aculeatus. Exploratory experiments showed nanoparticles forming microtubules only on living fungi, confirming the role played by metabolites in the mechanism of nanoparticle deposition.

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Figure 1. Each living fungus required different times to form microtubules and the images show typical macroscopic aspects of the hybrid material at distinct moments. The first step (green) shows hyphae developing after spore/slice germination; the second step (red) exhibits a modified gold suspension color due to the adsorption of nanoparticles on the surface of the fungal wall; the last step (gray) shows the system dehydrated by lyophilization.

Figure 2(a–e) illustrates the changes in color intensity of gold colloidal suspensions during the formation of microtubules on Penicillium brasilianum. The first image shows the turbidity of growth medium free of nanoparticles due the presence of germinated spores after 3 days of inoculation, while (b–e) show media over a period of 5 days after adding gold nanoparticles. The presence of gold nanoparticles can inhibit partially fungal growth30 and 6 ACS Paragon Plus Environment

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strongly attenuate the formation of fungi biofilms31. For this reason, we separated the hyphal growth from the deposition step (Fig.1).29 Fungal vegetative growth also varies when the medium is modified.32-33 Filamentous fungi exhibit variable responses to fungal strain and growth media composition, which includes the amount of available nutrients. In fact, the addition of different carbon supplements (e.g., glucose, sucrose or xylose) or nitrogen sources (nitrates or ammonium inorganic salts) to the basal growth media significantly affects fungal biomass dry weight (BDW) and can alter the production of metabolites. Evidently, a contrary result is also possible, since the addition of other substances commonly found in nature can suppress glucose uptake in some fungi species, which in consequence reduces their BDW.32 There are evidences of environmental physical-chemical signals that trigger the secretion of hydrophobin proteins capable to modify the surface tension of fungus hyphae.33 Apparently, excess or deprivation of nutrients around the fungus determine the metabolic pathway that actives specific fungi genes, resulting in an amphipathic film of hydrophobins at the hyphal surface, which is probable responsible for the attachment of gold nanoparticles.33-35 Due this intricate mechanism, the influence of growth media on the nanoparticles deposition rate cannot be neglected.

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Figure 2. Images showing the filamentous fungus Penicillium brasilianum in five different stages of recovery: (a) mycelial mass free of any gold nanoparticles after 3 days of inoculation; fungal hyphae immersed in a colloidal suspension of gold nanoparticles after (b) 1 day, (c) 3 days, (d) 4 days and (e) 5 days; (f) UV–Visible spectra of the gold suspensions collected at different times exhibiting an expressive decrease of the plasmon band intensity, suggesting the continuous adsorption of nanoparticles on the hyphae; (g) Lagergren equation plot versus time showing the peculiarity of the system in behaving with pseudo first-order adsorption kinetics.

Colloidal gold nanoparticles exhibit a characteristic plasmon absorption band at 520 nm. Using the Lambert-Beer law (Eq.1, where A is the absorbance, ε is the extinction coefficient, b is the optical path and C is the concentration of nanoparticles), the absorbance intensity of this plasmon band provides some insights about the concentration of nanoparticles in suspension36.    1

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Although the accurate calculation of molar concentration of nanoparticles is not a trivial issue, for the present purpose is enough to consider that the absorbance is linearly proportional to the amount of gold nanoparticles at a given moment and it can be used as a relative value of concentration. For instance, the purple color intensity decreases as long as the nanoparticles leave the colloidal medium to form microtubules, almost disappearing after no more than one week (Fig.2f). Therefore, the relative concentration of gold nanoparticles in suspension could be obtained from the maximum intensity value of absorbance at any moment, from 100 % at the beginning to 0 % after a few days, and the amount of deposited gold on fungus can be estimated from the difference of absorbance values between two distinct moments. On the other hand, fungus growth is much slower than the covering rate and could be neglected, resulting in a covering rate that depends only on the nanoparticle concentration. This pseudo-first order kinetic behavior suggests that wall thickness can be adjusted by the amount of nanoparticles available. The Lagergren equation is commonly used to describe liquid-to-solid adsorption processes that follow pseudo-first order kinetics,36-40 although it has not yet been applied to systems based on biotemplates. In this equation (Eq.2), which result in the well-known integrated rate law (Eq.3), the adsorption rate is proportional to the amount of nanoparticles in suspension and limited by the adsorption capacity of the adsorbent. This condition is expressed by the (qe − qt) parameter, where qe and qt are the amount of nanoparticles adsorbed at equilibrium and at time t, respectively.     − 2

ln  −   3

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Although the complexity in determining the experimental qe value,37 (qe − qt) is proportional to the difference between the absorbance intensity measured immediately after inserting gold nanoparticles in the medium and that collected at different moments during the deposition process. At first approximation, it is possible to plot ln (Ie − It) versus time to obtain a linear fit that describes the pseudo-first order adsorption kinetics (Eq.3) responsible for the formation of microtubules on the surface of fungus templates (Fig.2g). Its linear adjustment showed a good coefficient of determination (R2 = 0.988) which allowed us to estimate a half-live of t1/2 = 1.9 days. Although we did not identified any evidence of segregated gold, it is possible that a few amount of gold nanoparticles deposited directly on the surface of glass flasks within the experimental error. Due the rate law expressed in Eq.1, diluted colloidal suspensions slowly form thin microtubules while concentrated suspensions quickly form thick walls. Moreover, thicker microtubules can be achieved by supplying new nanoparticles at fixed time intervals, as illustrated in Fig.3. Images a–d show microtubules 80–500 nm thick after four cycles over 110 days. This multistep procedure allows controlling the microtubules morphology, including fabricating multilayers of different composition.

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Figure 3. SEM images of hybrid microtubules obtained using biotemplates of Penicillium brasilianum after successive additions of gold nanoparticles, forming microtubules with wall thicknesses of 80–500 nm. These images show microtubules with controlled thickness obtained after adding new colloidal suspensions of gold nanoparticles to the system.

Figure 4a shows the average thickness of microtubules formed on Penicillium brasilianum as a function of time. Instead of a constant coverage rate, the sigmoid curve suggests nanoparticles first forming a thin layer over the hyphae, which is thickened posteriorly. This mechanism is better understood in the context of the pseudo-first order rate law of covering. At the beginning, the deposition rate is fast due the high concentration of colloidal nanoparticles in suspension. At this moment, fungal hyphae are uncovered and, consequently, nanoparticles quickly spread out on the entire fungus forming microtubules of thin walls. In the last stage, on 11 ACS Paragon Plus Environment

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the other hand, the deposition rate is lower than that in the beginning and the reminiscent nanoparticles slowly self-assemble on the microtubules layer-by-layer, homogenizing the microtubules thickness. The key to obtain uniform microtubules is a final step of microtubule exposure to diluted nanoparticle suspensions. However, some inherent variability common in biological materials could be observed over the microtubules. For instance, the crosshatched area in Fig.4b exhibits superior and inferior limits of microtubules thickness growth on Aspergillus aculeatus, which ranged from 60 nm to 140 nm after 10 and 130 days, respectively. This likely occurred because the mycelium continues to grow even in presence of gold nanoparticles, fed by the citrate used to stabilize the colloid. These new surfaces introduced some growth delay that was responsible for the presence of new microtubules thicker than those already present (Fig.4d). Examples of these new fungal uncovered segments are visible in Fig.4b, where they appear darker than the older hyphae.

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Figure 4. (a) wall thickness of microtubules formed on Penicillium brasilianum as a function of exposure time to gold nanoparticles; (b) SEM image of the new hyphae over the oldest hyphae characterized by differences in thickness; (c) wall thickness dispersions of microtubules obtained using Aspergillus aculeatus as a function of gold colloid exposure time; (d) illustration showing the growth of the mycelial mass after the nanoparticles cover the surface of the hyphae. Citrate available in the system is used as a growth macronutrient for the fungus, leading to a subtle heterogeneity caused by this diffusion of nanoparticles.

Scanning electron microscopies (SEM) images of a fractured microtubule (Fig.5a) and of an isolated microtubule border (Fig.5b) confirm its hollow nature, revealing morphological details of the cavity occupied by the fungus and of the multilayered wall constituted of gold 13 ACS Paragon Plus Environment

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nanoparticles. Figure 5c shows a representative small area of the fungus covered with a uniform coating of gold nanoparticles, from which a particle size distribution histogram could be constructed and the average size (13.1 nm) calculated from at least 500 nanoparticles.

Figure 5. SEM images of microtubules formed on Penicillium brasilianum grown in CZAPEK medium; (a) the microtubule structure can be observed by the crack in the hypha and (b) the hollow nature is better understood by the cross section of the microtubule. The average size of the gold nanoparticles was 13.1 nm, localized on the surface of the hyphae.

Representative images of the microtubules obtained with Penicillium brasilianum exposed to gold colloids for sixty days demonstrate how the final material retains the general biotemplate aspect (Fig.6a and b), which makes the fungus species choice a critical decision in 14 ACS Paragon Plus Environment

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designing the correct morphology. At first glance, the hybrid material resembles fibers processed by electrospinning that are typically made of organic polymers41 while the surfaces of the hybrid microtubules are covered with metal nanoparticles, as indicated by the XRD pattern in Fig.6e. In spite of these differences, some applications are common to both systems, such as in biomedical applications, drug delivery, environmental engineering, and affinity membranes or enzyme immobilization.42-46 Higher magnification images (c–f) confirm nanoparticles forming a uniform surface on the hyphae without any visible cracks. Reproducibility and uniformity are fundamental aspects of any technology related to nanostructured materials. The homogeneous density of the gold signal in EDS element mapping (Fig.7c) confirms microtubules of uniform thickness. This effective uniformity at the nanometer scale is essential for fabricating nanodevices for biomedicine, molecular biology, biochemistry, catalysis, and SERS spectroscopy.

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Figure 6. SEM images at different magnifications of microtubules obtained using the fungus Penicillium brasilianum. (a–b) The fungal hyphae form an homogenous network with (c–d) a massive coating of gold nanoparticles as seen in the XRD pattern of gold nanoparticles (e), forming well-structured multilayers on the fungal wall. (f) Even after interacting with the fungal wall, the particles retain their nanospherical shape, without cracks or heterogeneity along the hypha.

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Figure 7. SEM images and EDS mapping in 2D of silicon (green) and gold (red) on the hybrid material formed using Penicillium brasilianum. (a,c) A region containing the microstructures was selected and the EDS mapping in 2D presented a dense quantity of gold distributed throughout the hyphae. (b) In contrast, the substrate is identified under the hyphae with the false color green.

Microtubules with controlled diameters were achieved combining fungi and different growth media (Fig.8). Although growing Penicillium brasilianum in CZAPEK and PD media resulted in microtubules of similar diameters, other fungi exhibited different results, indicating the influence of the growth medium in fungi metabolism. This demonstrates the necessity to choose not only the fungus but also its correct medium to obtain a specific microtubule morphology.

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Figure 8. Diameters of microtubules according to the quantity of gold nanoparticles present, influenced by the culture media in which the fungi were cultivated. Hybrid materials were made using Penicillium brasilianum, Xylaria sp. and Aspergillus aculeatus in culture media CZAPEK, CZAPEK-yeast extract and PD.

Sabah et al.47 proposed that the fungus consumes colloidal stabilizing agents to grow, destabilizing the nanoparticles in suspension and causing them to aggregate on the hyphae surface, forming microtubules through successive layers of nanoparticles.48 However, this does not explain the sigmoidal curve of Fig.4a that implies some active role of the live fungus. Our best hypothesis suggests that the first layer of gold nanoparticles interacts strongly with the fungus surface through covalent bonds between the metal and the functional groups on the cells

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that constitute the fungus mycelia, while subsequent layers are deposited due the self-assembly of nanoparticles driven by primary or secondary metabolites excreted by live fungi. Filamentous fungi produce a wide range of natural products, usually small molecules that mediate the interactions between them and the environment providing nutrients, communication between microorganisms and exerting selective toxicity against other microbes.48-50 Filamentous fungi excrete metabolites in response to environment stress, including metal nanoparticles. In fact, gold and silver nanoparticles adversely affect microorganism growth and mycelium composition,30,

31, 51-54

which can explain the faster fungi growth in nanoparticle-free media.

Therefore, it is plausible that gold nanoparticles trigger some fungal biochemical response to produce secondary metabolites responsible for nanoparticle deposition, which opens a new road to improve nanoparticle self-assembly techniques for the production of superior hybrid materials such as microtubules, surfaces decorated with particles, and nanocomposites. CONCLUSIONS Homogeneous microtubules of controlled diameters and thickness were obtained by depositing gold nanoparticles on the surface of fungi biotemplates using a fast methodology that combines different fungi species and growth media isolated from the presence of colloidal nanoparticles. Differences in adsorption kinetics indicated the influence of secondary metabolites on the deposition process, due to modifications in the chemical identity of the colloidal nanoparticles. The final hybrid material resembled the biotemplate morphology, which makes the fungi and growth media choices critical decisions in producing hybrid materials at large scales with a high degree of reproducibility and efficacy.

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EXPERIMENTAL SECTION Reagents were analytical grade and used as received. All hybrid materials, including the gold colloidal suspensions, were prepared inside a laminar flow chamber strictly sterilized with sodium hypochlorite, ethanol (70%) and UV-Vis light. Gold nanoparticles (AuNP) were synthesized from 100 mL of an aqueous solution of HAuCl4 (1.0 mmol•L-1, 99.9% Sigma-Aldrich) at 95 °C that was prepared with deionized water obtained from a commercial Millipore Elix 3 system and autoclaved at 120 °C for 30 min. Then, 1 mL of a solution of sodium citrate was added (0.30 mol•L-1, Na3C6H5O4) and a stable red colloidal suspension of AuNP was formed after 12 min. Fungal inocula of Penicillium brasilianum, Aspergillus aculeatus and Xylaria sp were prepared in a Petri dish containing the culture medium PDA (potato-dextrose-agar) under aseptic conditions. After 7 days, a suspension of the spores was prepared by adding a small amount of fungus spores in a test tube with deionized water, previously sterilized. Then, three culture media containing CZAPEK (modified DSMZ 130, without agar), CZAPEK-yeast extract and PD (potato dextrose) were distributed in Erlenmeyer flasks and autoclaved at 120 °C for 15 min, resulting in nine vials of each medium. Each bottle received 25 mL of the culture medium, with compositions shown in Table 1. The Erlenmeyer flasks were sealed to avoid any external contamination. After cooled the vials to room temperature, they were placed in a laminar flow hood. Once cooled, 200 µL of a suspension containing fungal spores of Aspergillus aculeatus and Penicillium brasilianum (previously prepared) were inoculated in the three culture media in each Erlenmeyer flask. The Xylaria sp. fungus does not sporulate, and thus the inoculation in culture medium occurred by cutting small pieces of the fungus colony from the agar plate added 20 ACS Paragon Plus Environment

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to the culture medium. This is the initial step of growth and development of the fungus, and the flasks were stored in sterile conditions and protected from light. Table 1. Chemical composition of culture media used in cultivation and growth of Aspergillus aculeatus, Penicillium brasilianum and Xylaria sp fungi.

CZAPEK

CZAPEK- yeast extract

Compound

Mass (g)

Compound

Mass (g)

K2HPO4

0.005

K2HPO4

0.005

NaNO3

1.0

NaNO3

1.0

MgSO4.7H2O 0.25

MgSO4.7H2O 0.25

KCl

0.25

KCl

0.25

FeSO2 .7H2O

0.005

FeSO2 .7H2O

0.005

Dextrose

15.0

Dextrose

15.0

Yeast extract

10.0

PD

100g of chopped potatoes cooked in the microwave for 20 minutes with 200 mL of water, kneaded and filtered. When it was filtered, dextrose is added and the solution is diluted until 500mL.

Volume 500 mL After 2–3 days, parts the mycelial mass grew in the solution and on the surface. In this step, the surface of the mycelial mass was removed and the culture medium was diluted with autoclaved deionized water to a total volume of 100 mL. This step was performed to stabilize the fungus growth and avoid the development of fungus hyphae outside the culture medium. During 4 to 6 days after the spore inoculation in the culture medium and entangled hyphae were formed, the diluted culture medium was removed using a peristaltic pump, leaving only the mycelial mass of fungus in the flask. Into this flask was added 100 mL of gold colloid as previously prepared. Over the next 5 to 20 days, AuNP adhered to the fungal walls in multiple layers to form uniform AuNP microtubules. In a second experiment, the colloidal suspension was refreshed after 5 days several times with a new colloidal suspension, so that the fungus remains 21 ACS Paragon Plus Environment

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exposed to a nearly constant particle concentration. The colloidal suspension was removed, leaving only the fungus in the Erlenmeyer flask. Scanning electron microscopy (SEM) was performed with the fungus in nature, without previous dehydration. Gold nanoparticles and hybrid materials were characterized by X-ray diffraction (Rigaku Dmax 2500PC diffractometer) with Cu Kα radiation in the 2θ range of 20–120° operating at 40 kV and 40 mA. To collect the patterns, nanoparticles were deposited on silicon substrates by dripping the aqueous colloidal suspension onto the substrate at room temperature and waiting for solvent evaporation. Spectra of gold nanoparticle suspensions were obtained from 190–800 nm with a UV-Vis spectrophotometer (Shimadzu Multispec 1501) using a commercial quartz cuvette. Scanning transmission electron microscopy (STEM) images of nanoparticles were recorded at 20 kV (FEG Zeiss Supra 35-VP), where the colloid was pinged on support film Cu grids of 400 mesh (PELCO®) with the aid of a pipette and dried at room temperature. The scanning electron microscopy (SEM images of nanoparticles and hybrid material microtubules were recorded with a (FEI Company – XL30 FEG), where samples were deposited on a silicon metal plate (111) with the contact being the sample and the support was carried out with conductive inks based on silver (Degussa). Histograms were constructed using the public domain Image-J image processing software. AUTHOR INFORMATION Corresponding Author *Email: [email protected] Author Contributions

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