Interactions of hydrophobin proteins in solution studied by small-angle X-ray scattering

Hydrophobins are a group of very surface-active, fungal proteins known to self-assemble on various hydrophobic/hydrophilic interfaces. The self-assembled films coat fungal structures and mediate their attachment to surfaces. Hydrophobins are also soluble in water. Here, the association of hydrophobins HFBI and HFBII from Trichoderma reesei in aqueous solution was studied using small-angle x-ray scattering. Both HFBI and HFBII exist mainly as tetramers in solution in the concentration range 0.5-10 mg/ml. The assemblies of HFBII dissociate more easily than those of HFBI, which can tolerate changes of pH from 3 to 9 and temperatures in the range 5°C-60°C. The self-association of HFBI and HFBII is mainly driven by the hydrophobic effect, and addition of salts along the Hofmeister series promotes the formation of larger assemblies, whereas ethanol breaks the tetramers into monomers. The possibility that the oligomers in solution form the building blocks of the self-assembled film at the air/water interface is discussed.     

Purifying selection and birth-and-death evolution in the class II hydrophobin gene families of the ascomycete <Emphasis Type="Italic">Trichoderma/Hypocrea</Emphasis>

Background  

Hydrophobins are proteins containing eight conserved cysteine residues that occur uniquely in mycelial fungi. Their main function is to confer hydrophobicity to fungal surfaces in contact with air or during attachment of hyphae to hydrophobic surfaces of hosts, symbiotic partners or themselves resulting in morphogenetic signals. Based on their hydropathy patterns and solubility characteristics, hydrophobins are divided into two classes (I and II), the latter being found only in ascomycetes.     

Solution structure and interface‐driven self‐assembly of NC2, a new member of the Class II hydrophobin proteins

Hydrophobins are fungal proteins that self‐assemble spontaneously to form amphipathic monolayers at hydrophobic:hydrophilic interfaces. Hydrophobin assemblies facilitate fungal transitions between wet and dry environments and interactions with plant and animal hosts. NC2 is a previously uncharacterized hydrophobin from Neurospora crassa. It is a highly surface active protein and is able to form protein layers on a water:air interface that stabilize air bubbles. On a hydrophobic substrate, NC2 forms layers consisting of an ordered network of protein molecules, which dramatically decrease the water contact angle. The solution structure and dynamics of NC2 have been determined using nuclear magnetic resonance spectroscopy. The structure of this protein displays the same core fold as observed in other hydrophobin structures determined to date, including the Class II hydrophobins HFBI and HFBII from Trichoderma reesei, but certain features illuminate the structural differences between Classes I and II hydrophobins and also highlight the variations between structures of Class II hydrophobin family members. The unique properties of hydrophobins have attracted much attention for biotechnology applications. The insights obtained through determining the structure, biophysical properties and assembly characteristics of NC2 will facilitate the development of hydrophobin‐based applications. Proteins 2014; 82:990–1003. © 2013 Wiley Periodicals, Inc.     

Hydrophobins: the protein-amphiphiles of filamentous fungi

Hydrophobins are surface active proteins produced by filamentous fungi. They have a role in fungal growth as structural components and in the interaction of fungi with their environment. They have, for example, been found to be important for aerial growth, and for the attachment of fungi to solid supports. Hydrophobins also render fungal structures, such as spores, hydrophobic. The biophysical properties of the isolated proteins are remarkable, such as strong adhesion, high surface activity and the formation of various self-assembled structures. The first high resolution three dimensional structure of a hydrophobin, HFBII from Trichoderma reesei, was recently solved. In this review, the properties of hydrophobins are analyzed in light of these new data. Various application possibilities are also discussed.     

A mutant of hydrophobin HGFI tuning the self-assembly behaviour and biosurfactant activity

Hydrophobins are a series of low molecular weight proteins produced by filamentous fungi that play an important role in fungal growth. They have a globular structure and possess a unique hydrophobic patch on their surface that makes them amphiphilic, making them among the most surface-active proteins. Herein, the surface charge properties of HGFI, a class I hydrophobin from Grifola frondosa, were altered by replacing the negatively charged Glu24 with a positively charged Lys to generate the ME24 mutant. Pichia pastoris GS115 was used for recombinant expression of the ME24 mutant, which was purified by a two-step procedure. The function of the mutated residue in HGFI self-assembly was investigated. Reverse-phase high-performance liquid chromatography analysis revealed that the polarity of ME24 was enhanced compared with HGFI. Circular dichroism, thioflavin T assay, water contact angle and atomic force microscopy indicated that Glu24 participates in rodlet formation. Water solubility detection and dynamic light scattering showed that Glu24 affects the assembled state of HGFI in aqueous solution. The behaviour of the mutant in an emulsion, in the dispersion of insoluble materials and in large-scaled protein production suggests the functions of hydrophobins can be tuned for new applications.

     

Solid-phase handling of hydrophobins: immobilized hydrophobins as a new tool to study lipases

Hydrophobins are fungal proteins that self-assemble spontaneously at hydrophilic-hydrophobic interfaces and change the polar nature of the surfaces to which they attach. This attribute can be used to introduce hydrophobic foci on the surface of hydrophilic supports where hydrophobins are attached by covalent binding. In this paper, we report the binding of Pleurotus ostreatus hydrophobins to a hydrophilic matrix (agarose) to construct a support for noncovalent immobilization and activation of lipases from Candida antarctica, Humicola lanuginosa, and Pseudomonas flourescens. Lipase immobilization on agarose-bound hydrophobins proceeded at very low ionic strength and resulted in increased lipase activity and stability. The enzyme could be desorbed from the support using moderate concentrations of Triton X-100, and its enantioselectivity was similar to that of lipases interfacially immobilized on conventional hydrophobic supports. These results suggest that lipase adsorption on hydrophobins follows an "interfacial activation" mechanism; immobilization on hydrophobins offers new possibilities for lipase study and modulation and reveals a new application for fungal hydrophobins.     

High-yield production of hydrophobins RodA and RodB from <Emphasis Type="Italic">Aspergillus fumigatus</Emphasis> in <Emphasis Type="Italic">Pichia pastoris</Emphasis>

Hydrophobins are small fungal proteins with amphipatic properties and the ability to self-assemble on a hydrophobic/hydrophilic interface; thus, many technical applications for hydrophobins have been suggested. The pathogenic fungus Aspergillus fumigatus expresses the hydrophobins RodA and RodB on the surface of its conidia. RodA is known to be of importance to the pathogenesis of the fungus, while the biological role of RodB is currently unknown. Here, we report the successful expression of both hydrophobins in Pichia pastoris and present fed-batch fermentation yields of 200–300 mg/l fermentation broth. Protein bands of expected sizes were detected by SDS-PAGE and western blotting, and the identity was further confirmed by tandem mass spectrometry. Both proteins were purified using his-affinity chromatography, and the high level of purity was verified by silver-stained SDS-PAGE. Recombinant RodA as well as rRodB were able to convert a glass surface from hydrophilic to hydrophobic similar to native RodA, but only rRodB was able to decrease the hydrophobicity of a Teflon-like surface to the same extent as native RodA, while rRodA showed this ability to a lesser extent. Recombinant RodA and native RodA showed a similar ability to emulsify air in water, while recombinant RodB could also emulsify oil in water better than the control protein bovine serum albumin (BSA). This is to our knowledge the first successful expression of hydrophobins from A. fumigatus in a eukaryote host, which makes it possible to further characterize both hydrophobins. Furthermore, the expression strategy and fed-batch production using P. pastoris may be transferred to hydrophobins from other species.     

Involvement of hydrophobic amino acid residues in C7–C8 loop of Aspergillus oryzae hydrophobin RolA in hydrophobic interaction between RolA and a polyester

Hydrophobins are amphipathic secretory proteins with eight conserved cysteine residues and are ubiquitous among filamentous fungi. The Cys3–Cys4 and Cys7–Cys8 loops of hydrophobins are thought to form hydrophobic segments involved in adsorption of hydrophobins on hydrophobic surfaces. When the fungus Aspergillus oryzae is grown in a liquid medium containing the polyester polybutylene succinate-co-adipate (PBSA), A. oryzae produces hydrophobin RolA, which attaches to PBSA. Here, we analyzed the kinetics of RolA adsorption on PBSA by using a PBSA pull-down assay and a quartz crystal microbalance (QCM) with PBSA-coated electrodes. We constructed RolA mutants in which hydrophobic amino acids in the two loops were replaced with serine, and we examined the kinetics of mutant adsorption on PBSA. QCM analysis revealed that mutants with replacements in the Cys7–Cys8 loop had lower affinity than wild-type RolA for PBSA, suggesting that this loop is involved in RolA adsorption on PBSA.     

Hydrophobins, from molecular structure to multiple functions in fungal development

Mycelial fungi secrete small, cysteine-rich, proteins, called hydrophobins, that self-assemble at hydrophilic-hydrophobic interfaces into amphipathic membranes, highly insoluble in case of Class I hydrophobins. By self-assembly at the culture medium-air interface they greatly lower the surface tension enabling emergent structures to grow into the air. By self-assembly at the interface between the hydrophilic cell wall and the air or any other hydrophobic environment, these emergent structures are coated with a hydrophobin membrane. These properties allow hydrophobins to fulfil a broad spectrum of functions in fungal development. They are involved in formation of aerial (reproductive) structures, in aerial dispersion of spores, and they line air channels within fruiting bodies with a hydrophobic coating, probably serving gas exchange. Hydrophobins also mediate hyphal attachment to hydrophobic surfaces such as those of plants. Moreover, they appear involved in complex interhyphal interactions, and in interactions with algae in lichens. Their resistance towards chemical and enzymatic treatments suggests that assembled hydrophobins also protect fungal emergent structures against adverse environmental conditions.     

Partial characterization of a hydrophobin protein Po.HYD1 purified from the oyster mushroom <Emphasis Type="Italic">Pleurotus ostreatus</Emphasis>

Hydrophobins fulfill various physiological functions in fungal development and growth, based on their mechanism of self-assembly at hydrophilic–hydrophobic interfaces into nano-scale, amphipathic membranes. One hydrophobin with an approximate molecular weight of 15 kDa, designated Po.HYD1, was purified from aerial hyphae of Pleurotus ostreatus strain Pm039. Ultrastructures of self-assembled films formed by Po.HYD1 on hydrophobic and hydrophilic substrates were revealed by atomic force microscopy (AFM). A monomolecular adsorption layer, thickness ranging from 3.2 to 3.8 nm, was observed on the surface of highly oriented pyrolytic graphite (HOPG), while a typical rodlet layer with uniform thickness of 4.2 ± 0.1 nm formed on the mica surface. Comparison of CD spectra showed significant secondary structural changes between monomeric and self-assembled states. The spectrum of monomeric Po.HYD1 had a maximum ellipticity at 190 nm and a minimum at 209 nm, and that of assemblage showed the maximum at 195 nm and the minimum shifted to 215–218 nm. Po.HYD1 showed high surface activity, based on the dramatic drop of surface tension through self-assembly at the water–air interface. Moreover, Po.HYD1 is capable of stabilizing the emulsion consisting of water and hexane.     

Heterogeneous expression and emulsifying activity of class I hydrophobin from <Emphasis Type="Italic">Pholiota nameko</Emphasis>

Hydrophobins secreted by filamentous fungi self-assemble into an amphipathic film at hydrophilic/hydrophobic interfaces. This unique property suggests that the hydrophobins have a high potential for industrial applications. However, the assemblages of class I hydrophobins are highly insoluble, making such commercial applications difficult. To enhance the solubility of class I hydrophobins, we have attempted to express class I hydrophobin PNH1 from Pholiota nameko fused with glutathione S-transferase (GST) in Escherichia coli. The GST–PNH1 was effectively isolated from the soluble fraction of transformed E. coli, and subsequent analysis revealed that the purified GST–PNH1 had almost the same emulsifying activity as PNH1.     

Identification, Characterization, and In Situ Detection of a Fruit-Body-Specific Hydrophobin of Pleurotus ostreatus

Hydrophobins are small (length, about 100 ± 25 amino acids), cysteine-rich, hydrophobic proteins that are present in large amounts in fungal cell walls, where they form part of the outermost layer (rodlet layer); sometimes, they can also be secreted into the medium. Different hydrophobins are associated with different developmental stages of a fungus, and their biological functions include protection of the hyphae against desiccation and attack by either bacterial or fungal parasites, hyphal adherence, and the lowering of surface tension of the culture medium to permit aerial growth of the hyphae. We identified and isolated a hydrophobin (fruit body hydrophobin 1 [Fbh1]) present in fruit bodies but absent in both monokaryotic and dikaryotic mycelia of the edible mushroom Pleurotus ostreatus. In order to study the temporal and spatial expression of the fbh1 gene, we determined the N-terminal amino acid sequence of Fbh1. We also synthesized and cloned the double-stranded cDNA corresponding to the full-length mRNA of Fbh1 to use it as a probe in both Northern blot and in situ hybridization experiments. Fbh1 mRNA is detectable in specific parts of the fruit body, and it is absent in other developmental stages.     

Surface adhesion of fusion proteins containing the hydrophobins HFBI and HFBII from Trichoderma reesei

Hydrophobins are surface-active proteins produced by filamentous fungi, where they seem to be ubiquitous. They have a variety of roles in fungal physiology related to surface phenomena, such as adhesion, formation of surface layers, and lowering of surface tension. Hydrophobins can be divided into two classes based on the hydropathy profile of their primary sequence. We have studied the adhesion behavior of two Trichoderma reesei class II hydrophobins, HFBI and HFBII, as isolated proteins and as fusion proteins. Both hydrophobins were produced as C-terminal fusions to the core of the hydrolytic enzyme endoglucanase I from the same organism. It was shown that as a fusion partner, HFBI causes the fusion protein to efficiently immobilize to hydrophobic surfaces, such as silanized glass and Teflon. The properties of the surface-bound protein were analyzed by the enzymatic activity of the endoglucanase domain, by surface plasmon resonance (Biacore), and by a quartz crystal microbalance. We found that the HFBI fusion forms a tightly bound, rigid surface layer on a hydrophobic support. The HFBI domain also causes the fusion protein to polymerize in solution, possibly to a decamer. Although isolated HFBII binds efficiently to surfaces, it does not cause immobilization as a fusion partner, nor does it cause polymerization of the fusion protein in solution. The findings give new information on how hydrophobins function and how they can be used to immobilize fusion proteins.     

Lack of evidence for a role of hydrophobins in conferring surface hydrophobicity to conidia and hyphae of Botrytis cinerea

Background  

Hydrophobins are small, cysteine rich, surface active proteins secreted by filamentous fungi, forming hydrophobic layers on the walls of aerial mycelia and spores. Hydrophobin mutants in a variety of fungi have been described to show 'easily wettable' phenotypes, indicating that hydrophobins play a general role in conferring surface hydrophobicity to aerial hyphae and spores.     

Atomic resolution structure of the HFBII hydrophobin, a self-assembling amphiphile

Hydrophobins are proteins specific to filamentous fungi. Hydrophobins have several important roles in fungal physiology, for example, adhesion, formation of protective surface coatings, and the reduction of the surface tension of water, which allows growth of aerial structures. Hydrophobins show remarkable biophysical properties, for example, they are the most powerful surface-active proteins known. To this point the molecular basis of the function of this group of proteins has been largely unknown. We have now determined the crystal structure of the hydrophobin HFBII from Trichoderma reesei at 1.0 A resolution. HFBII has a novel, compact single domain structure containing one alpha-helix and four antiparallel beta-strands that completely envelop two disulfide bridges. The protein surface is mainly hydrophilic, but two beta-hairpin loops contain several conserved aliphatic side chains that form a flat hydrophobic patch that makes the molecule amphiphilic. The amphiphilicity of the HFBII molecule is expected to be a source for surface activity, and we suggest that the behavior of this surfactant is greatly enhanced by the self-assembly that is favored by the combination of size and rigidity. This mechanism of function is supported by atomic force micrographs that show highly ordered arrays of HFBII at the air water interface. The data presented show that much of the current views on structure function relations in hydrophobins must be re-evaluated.     

A Hydrophobin of the chestnut blight fungus, Cryphonectria parasitica, is required for stromal pustule eruption

Hydrophobins are abundant small hydrophobic proteins that are present on the surfaces of many filamentous fungi. The chestnut blight pathogen Cryphonectria parasitica was shown to produce a class II hydrophobin, cryparin. Cryparin is the most abundant protein produced by this fungus when grown in liquid culture. When the fungus is growing on chestnut trees, cryparin is found only in the fungal fruiting body walls. Deletion of the gene encoding cryparin resulted in a culture phenotype typical of hydrophobin deletion mutants of other fungi, i.e., easily wettable (nonhydrophobic) hyphae. When grown on the natural substrate of the fungus, however, cryparin-null mutation strains were unable to normally produce its fungal fruiting bodies. Although the stromal pustules showed normal development initially, they were unable to erupt through the bark of the tree. The hydrophobin cryparin thus plays an essential role in the fitness of this important plant pathogen by facilitating the eruption of the fungal fruiting bodies through the bark of its host tree.     

Novel Hydrophobins from <Emphasis Type="Italic">Trichoderma</Emphasis> Define a New Hydrophobin Subclass: Protein Properties,Evolution, Regulation and Processing

Hydrophobins are small proteins, characterised by the presence of eight positionally conserved cysteine residues, and are present in all filamentous asco- and basidiomycetes. They are found on the outer surfaces of cell walls of hyphae and conidia, where they mediate interactions between the fungus and the environment. Hydrophobins are conventionally grouped into two classes (class I and II) according to their solubility in solvents, hydropathy profiles and spacing between the conserved cysteines. Here we describe a novel set of hydrophobins from Trichoderma spp. that deviate from this classification in their hydropathy, cysteine spacing and protein surface pattern. Phylogenetic analysis shows that they form separate clades within ascomycete class I hydrophobins. Using T. atroviride as a model, the novel hydrophobins were found to be expressed under conditions of glucose limitation and to be regulated by differential splicing.     

Self-assembly of proteins into a three-dimensional multilayer system: Investigation of the surface of the human fungal pathogen Aspergillus fumigatus

Hydrophobins are small surface active proteins that fulfil a wide spectrum of functions in fungal growth and development. The human fungal pathogen Aspergillus fumigatus expresses RodA hydrophobins that self-assemble on the outer conidial surface into tightly organized nanorods known as rodlets. AFM investigation of the conidial surface allows us to evidence that RodA hydrophobins self-assemble into rodlets through bilayers. Within bilayers, hydrophilic domains of hydrophobins point inward, thus making a hydrophilic core, while hydrophobic domains point outward. AFM measurements reveal that several rodlet bilayers are present on the conidial surface thus showing that proteins self-assemble into a complex three-dimensional multilayer system. The self-assembly of RodA hydrophobins into rodlets results from attractive interactions between stacked β-sheets, which conduct to a final linear cross-β spine structure. A Monte Carlo simulation shows that anisotropic interactions are the main driving forces leading the hydrophobins to self-assemble into parallel rodlets, which are further structured in nanodomains. Taken together, these findings allow us to propose a mechanism, which conducts RodA hydrophobins to a highly ordered rodlet structure. The mechanism of hydrophobin assembly into rodlets offers new prospects for the development of more efficient strategies leading to disruption of rodlet formation allowing a rapid detection of the fungus by the immune system.     

Expression and purification of a functionally active class I fungal hydrophobin from the entomopathogenic fungus <Emphasis Type="Italic">Beauveria bassiana</Emphasis> in <Emphasis Type="Italic">E. coli</Emphasis>

Hydrophobins represent a class of unique fungal proteins that have low molecular mass, are cysteine rich, and can self-assemble into two-dimensional arrays at water/air interfaces. These highly surface-active proteins are able to decrease the surface tension of water, thus allowing fungal structures to penetrate hydrophobic–hydrophilic barriers. Due to their unusual biophysical properties, hydrophobins have been suggested for use in a wide range of biotechnological applications. Here we describe a simple method for producing a functionally active class I hydrophobin derived from the entomopathogenic fungus, Beauveria bassiana, in an E. coli host. N-terminal modifications were required for proper expression and purification, and the hydrophobin was expressed as a fusion partner to a cleavable N-terminus chitin-binding domain-intein construct. The protein was purified and reconstituted from E. coli inclusion bodies. Self-assembly of the recombinant hydrophobin was followed kinetically using a thioflavin T fluorescence binding assay, and contact angle measurements of purified recombinant hydrophobin protein (mHyd2) films on a variety of substrata demonstrated its surface modification ability, which remained stable for at least 4 months. Filament or fibril-like structures were imaged using atomic force and transmission electron microscopy. These data confirmed the functional properties of the purified protein and indicate amino acid flexibility at the N-terminus, which can be exploited for various applications of these proteins.     

Hydrophobin (HFBI): A potential fusion partner for one-step purification of recombinant proteins from insect cells

Hydrophobins play an important role in binding and assembly of fungal surface structures as well as in medium-air interactions. These, hydrophobic properties provide interesting possibilities when purification of macromolecules is concerned. In aqueous micellar two-phase systems, based on surfactants, the water soluble hydrophobins are concentrated inside micellar structures and, thus, distributed to defined aqueous phases. This, one-step purification is attractive particularly when large-scale production of recombinant proteins is concerned. In the present study the hydrophobin HFBI of Trichoderma reesei was expressed as an N-terminal fusion with chicken avidin in baculovirus infected insect cells. The intracellular distribution of the recombinant fusion construct was analyzed by confocal microscopy and the protein subsequently purified from cytoplasmic extracts in an aqueous micellar two-phase system by using a non-ionic surfactant. The results show that hydrophobin and an avidin fusion thereof were efficiently expressed in insect cells and that these hydrophobic proteins could be efficiently purified from these cells in one-step by adopting an aqueous micellar two-phase system.