Joseph G. H. Wessels

Hydrophobins : Proteins that change the nature of the fungal surface

Publisher Summary Hydrophobins were discovered while searching for genes expressed during emergent growth in Schizophyllum commune, and are a novel class of small secreted cysteine-rich proteins of fungi that assemble into amphipathic films when confronted with hydrophilichydrophobic interfaces. The hydrophobicity of the air-exposed surface of the S. commune (SC3) film was as high as that of the surface of aerial hyphae. This process of interfacial self-assembly of a single hydrophobin into a hydrophobic rodlet layer provides a remarkably simple mechanism, by which hyphae and spores obtain a hydrophobic layer at their surface because it is at this surface that the secreted hydrophobin monomers reach the water–air interface and assemble into an amphipathic film. Some hydrophobins form unstable, others extremely stable, amphipathic films. By assembling at a wall–air interface some have been shown to provide for a hydrophobic surface, which has the ultrastructural appearance of rodlets as on aerial hyphae and spores. Some hydrophobins have been shown to assemble into amphipathic films at interfaces between water and oils, or hydrophobic solids, and may be involved in adherence phenomena. It appears that hydrophobins are among the most abundantly produced proteins of fungi, and individual species may contain several genes producing divergent hydrophobins, possibly tailored for specific purposes. Hydrophobins have now been implicated in various developmental processes, such as formation of aerial hyphae, fruit bodies and conidia, and may play essential roles in fungal ecology— including spore dissemination, pathogenesis, and symbiosis. The surfactive properties of hydrophobins and the ability of some of them to form very stable insoluble amphipathic films, which change the wettability of surfaces, also makes them good candidates for technical applications.

Interfacial self-assembly of a hydrophobin into an amphipathic protein membrane mediates fungal attachment to hydrophobic surfaces.

The SC3p hydrophobin of Schizophyllum commune is a small hydrophobic protein (100‐101 amino acids with eight cysteine residues) that self‐assembles at a water/air interface and coats aerial hyphae with an SDS‐insoluble protein membrane, at the outer side highly hydrophobic and with a typical rodlet pattern. SC3p monomers in water also self‐assemble at the interfaces between water and oils or hydrophobic solids. These materials are then coated with a 10 nm thick SDS‐insoluble assemblage of SC3p making their surfaces hydrophilic. Hyphae of S. commune growing on a Teflon surface became firmly attached and SC3p was shown to be present between the fungal cell wall and the Teflon. Decreased attachment of hyphae to Teflon was observed in strains not expressing SC3, i.e. a strain containing a targeted mutation in this gene and a regulatory mutant thn. These findings indicate that hydrophobins, in addition to forming hydrophobic wall coatings, play a role in adherence of fungal hyphae to hydrophobic surfaces.

How a fungus escapes the water to grow into the air

Fungi are well known to the casual observer for producing water-repelling aerial moulds and elaborate fruiting bodies such as mushrooms and polypores. Filamentous fungi colonize moist substrates (such as wood) and have to breach the water-air interface to grow into the air. Animals and plants breach this interface by mechanical force. Here, we show that a filamentous fungus such as Schizophyllum commune first has to reduce the water surface tension before its hyphae can escape the aqueous phase to form aerial structures such as aerial hyphae or fruiting bodies. The large drop in surface tension (from 72 to 24 mJ m-2) results from self-assembly of a secreted hydrophobin (SC3) into a stable amphipathic protein film at the water-air interface. Other, but not all, surface-active molecules (that is, other class I hydrophobins and streptofactin from Streptomyces tendae) can substitute for SC3 in the medium. This demonstrates that hydrophobins not only have a function at the hyphal surface but also at the medium-air interface, which explains why fungi secrete large amounts of hydrophobin into their aqueous surroundings.

Interfacial Self-Assembly of a Fungal Hydrophobin into a Hydrophobic Rodlet Layer.

The Sc3p hydrophobin of the basidiomycete Schizophyllum commune is a small hydrophobic protein (100 to 101 amino acids) containing eight cysteine residues. Large amounts of the protein are excreted into the culture medium as monomers, but in the walls of aerial hyphae, the protein is present as an SDS-insoluble complex. In this study, we show that the Sc3p hydrophobin spontaneously assembles into an SDS-insoluble protein membrane on the surface of gas bubbles or when dried down on a hydrophilic surface. Electron microscopy of the assembled hydrophobin shows a surface consisting of rodlets spaced 10 nm apart, which is similar to those rodlets seen on the surface of aerial hyphae. When the purified Sc3p hydrophobin assembles on a hydrophilic surface, a surface is exposed with high hydrophobicity, similar to that of aerial hyphae. The rodlet layer, assembled in vivo and in vitro, can be disassembled by dissolution in trifluoroacetic acid and, after removal of the acid, reassembled into a rodlet layer. We propose, therefore, that the hydrophobic rodlet layer on aerial hyphae arises by interfacial self-assembly of Sc3p hydrophobin monomers, involving noncovalent interactions only. Submerged hyphae merely excrete monomers because these hyphae are not exposed to a water-air interface. The generally observed rodlet layers on fungal spores may arise in a similar way.

Localization of growth and secretion of proteins in Aspergillus niger

Hyphal growth and secretion of proteins in Aspergillus niger were studied using a new method of culturing the fungus between perforated membranes which allows visualization of both parameters. At the colony level the sites of occurrence of growth and general protein secretion were correlated. In 4-d-old colonies both growth and secretion were localized at the periphery of the colony, whereas in a 5-d-old colony growth and secretion also occurred in a more central zone of the colony where conidiophore differentiation was observed. However, in both cases glucoamylase secretion was mainly detected at the periphery of the colonies. At the hyphal level immunogold labelling showed glucoamylase secretion at the tips of leading hyphae only. Microautoradiography after labelling with N-acetylglucosamine showed that these hyphae were probably all growing. Glucoamylase secretion could not be demonstrated immediately after a temperature shock which stopped growth. These results indicate that glucoamylase secretion is located at the tips of growing hyphae only.

Hydrophobin Genes Involved in Formation of Aerial Hyphae and Fruit Bodies in Schizophyllum.

Fungi typically grow by apical extension of hyphae that penetrate moist substrates. After establishing a branched feeding mycelium, the hyphae differentiate and grow away from the substrate into the air where they form various structures such as aerial hyphae and mushrooms. In the basidiomycete species Schizophyllum commune, we previously identified a family of homologous genes that code for small cysteine-rich hydrophobic proteins. We now report that the encoded hydrophobins are excreted in abundance into the culture medium by submerged feeding hyphae but form highly insoluble complexes in the walls of emerging hyphae. The Sc3 gene encodes a hydrophobin present in walls of aerial hyphae. The homologous Sc1 and Sc4 genes, which are regulated by the mating-type genes, encode hydrophobins present in walls of fruit body hyphae. The hydrophobins are probably instrumental in the emergence of these aerial structures.

Fungal Cell Walls: A Survey

The cell wall is commonly regarded as an assemblage of polymers, mainly polysaccharides, that occurs outside the plasma membrane of cells of plants, fungi, and bacteria. Because of its rigidity it maintains the shape of the cell and offers resistance to unlimited influx of water into the cell. In addition it offers protection and, being the outermost cover of cells, often contains molecules involved in interaction between cells.

Structural Characterization of the Hydrophobin SC3, as a Monomer and after Self-Assembly at Hydrophobic/Hydrophilic Interfaces

Hydrophobins are small fungal proteins that self-assemble at hydrophilic/hydrophobic interfaces into amphipathic membranes that, in the case of Class I hydrophobins, can be disassembled only by treatment with agents like pure trifluoroacetic acid. Here we characterize, by spectroscopic techniques, the structural changes that occur upon assembly at an air/water interface and upon assembly on a hydrophobic solid surface, and the influence of deglycosylation on these events. We determined that the hydrophobin SC3 from Schizophyllum commune contains 16-22 O-linked mannose residues, probably attached to the N-terminal part of the peptide chain. Scanning force microscopy revealed that SC3 adsorbs specifically to a hydrophobic surface and cannot be removed by heating at 100 degrees C in 2% sodium dodecyl sulfate. Attenuated total reflection Fourier transform infrared spectroscopy and circular dichroism spectroscopy revealed that the monomeric, water-soluble form of the protein is rich in beta-sheet structure and that the amount of beta-sheet is increased after self-assembly on a water-air interface. Alpha-helix is induced specifically upon assembly of the protein on a hydrophobic solid. We propose a model for the formation of rodlets, which may be induced by dehydration and a conformational change of the glycosylated part of the protein, resulting in the formation of an amphipathic alpha-helix that forms an anchor for binding to a substrate. The assembly in the beta-sheet form seems to be involved in lowering of the surface tension, a potential function of hydrophobins.

Two genes specifically expressed in fruiting dikaryons of Schizophyllum commune: homologies with a gene not regulated by mating-type genes

The nucleotide (nt) sequences of the Sc3 and Sc4 genes of the filamentous fungus Schizophyllum commune, and the deduced amino acid (aa) sequences, were determined; moreover, the previously published sequence for the Sc1 gene [Dons et al., EMBO J. 3 (1984) 2101-2106] was corrected. All three independently isolated genes were found to have similar structures and nt sequences of their coding regions. At the aa level the homology is 43-62% (63-69% in the C-terminal parts of the proteins), the hydrophobic aa predominate and the hydrophobicity patterns are similar. All three proteins contain leader sequences and eight cysteines among about 110 aa, conserved at the same positions. Yet these genes are differentially regulated: Sc1 and Sc4 are only expressed at high levels in fruiting dikaryons, whereas Sc3 is highly expressed in both monokaryons and dikaryons, independent from fruiting.

Diversity of abundant mRNA sequences and patterns of protein synthesis in etiolated and greened pea seedlings

The diversity of abundant mRNA sequences in various parts of 4-d etiolated pea seedlings (Pisum sativum L. var. Rondo CB) was compared by a cell-free translation of the mRNAs in the presence of [35S]methionine and by an analysis of the products by two-dimensional electrofocussing/ electrophoresis (2D separation). The various parts of the seedlings were also examined for the pattern of protein synthesis in vivo. Proteins were labeled by injection of [35S]methionine into the cotyledons, followed by 2D separation of the products. Over 95% of the abundant mRNA sequences and newly synthesized abundant polypeptides were shared by all parts of etiolated seedlings, including the cotyledons. However, a few distinct differences were observed when comparing mRNAs of roots and shoots; the most prominent among these were a group of six abundant mRNA sequences found exclusively in shoots. Only about 30% of the polypeptides synthesized on isolated RNA could be traced in equivalent positions on the gels as the polypeptides synthesized in vivo. Analysis of total RNA from light-grown pea seedlings showed the appearance of some twenty-five translation products not found with total RNA from etiolated seedlings, while about nine other translation products disappeared. At least ten of the light-induced RNA sequences were also present after growth in low-intensity red light (λ>600 nm) and are therefore thought to be controlled by the phytochrome system. Comparison of 11-d light-grown pea plants with 4-d light-grown seedlings did not reveal additional translatable RNA sequences, indicating that the major morphogenetic changes that occur after 4 d are not accompanied by significant changes in the pattern of abundant RNA sequences.