Abstract
To clarify the potential use of hydrophobicity-related traits of aerial conidia in formulation design of fungal biocontrol agents, hydrophobicity rates (H r) and surface areas (S a) of aerial conidia were assessed with 48 strains of Beauveria bassiana, Isaria fumosorosea and Metarhizium spp. Inter- or intra-specific variation was large in H r (59.7–92.2%) and S a (7.9–25.3 μm2 conidium−1) measurements, which were significantly correlated (r 2 = 0.55). Six isolates of the three fungi with distinguished H r and S a were further studied. Conidial wall proteins of these isolates were sequentially extracted with sodium dodecyl sulfate (SDS), formic acid (FA) and trifluoroacetic acid (TFA). Their H r values were significantly correlated to the contents (P c) of TFA-soluble, but FA-insoluble, proteins (2.7–44.8 μg per 107 conidia; r 2 = 0.79) and reduced drastically by the FA/TFA treatments, which eliminated the hydrophobin-based rodlet layers of conidial surfaces. However, the SDS treatments had no effect on either H r or rodlet layers. The dispersancy of a tested emulsifier to oil formulations of the six isolates in water was adversely correlated to their H r (r 2 = 0.94). The results indicate that both P c and S a are inherent hydrophobicity-related traits and can be utilized to select fungal biocontrol candidates for improved formulation and application.
Similar content being viewed by others
Explore related subjects
Discover the latest articles, news and stories from top researchers in related subjects.Avoid common mistakes on your manuscript.
Introduction
Beauveria, Metarhizium and Isaria are well-known fungal biocontrol agents against arthropod pests, including a large number of candidate isolates that have been developed into mycoinsecticides and mycoacaricides in the world [1–3]. Such biopesticides are usually in the forms of emulsifiable or wettable formulations. As active ingredients of these formulations, aerial conidia are highly hydrophobic no matter how to be produced on solid substrates such as small grains [4]. This feature is an important concern when a fungal formulation is designed for improved field application.
Conidial hydrophobicity of filamentous fungi stems from rodlet layers of conidial surface that consists of hydrophobins [5–7]. Such proteins are associated not only with hydrophobicity but also with morphogenesis, adhesion, antigenicity and defense against host immune reaction [8–10] and can be dissociated from conidia with agents such as formic acid or trifluoroacetic acid [11–13]. In B. bassiana, several hydrophobin-like proteins extracted with formic acid or hydrophobins identified by gene cloning fall in the sizes of 6.5–14.0 kDa [14–16]. A starvation-stress gene (ssgA) of M. anisopliae was found encoding a hydrophobin [17, 18]. However, no hydrophobin has been identified from Isaria fumosorosea. Neither have the amounts of such proteins that may relate to the degree of conidial hydrophobicity been quantified for comparison among or within the mentioned fungi.
For the fungal biocontrol agents, hydrophobicity favors conidial adhesion to insect cuticle, the first step of fungal infection to kill pests [6, 19, 20], but is a barrier to the field spray of a fungal formulation in the form of aqueous dilution. Conidial hydrophobicity can be assessed with several methods [21], often with the method of aqueous-solvent partitioning [22–24]. Apart from inter- or intra-specific variability in hydrophobin content that may affect the hydrophobicity, surface areas of conidia depending on their ellipsoid sizes vary greatly among different fungal species or isolates. For instance, the sizes of Beauveria, Isaria and Metarhizium conidia fall in the ranges of 2–5 × 1–2.5, 4.5–18 × 2.5–5.5 and 2–10 × 1–3.5 μm, respectively [25]. Such a large variation in conidial size or surface area could be another important source of influence on the dispersivity of formulated conidia in aqueous suspension for field spray but has not been elucidated for potential use in fungal formulation design.
In this study, conidial hydrophobicity rates and surface areas measured from 48 isolates of B. bassiana, I. fumosorosea and Metarhizium spp. were compared and correlated. Based on the distribution of their hydrophobicity and surface parameters, six representative isolates were selected from the three fungal groups for further study. The contents of trifluoroacetic acid-soluble cell wall proteins were correlated to the hydrophobicity rates of their conidia. The conidial dispersivity of each of the selected isolates in the aqueous suspension of oil formulation containing different ratios of a selected emulsifier was evaluated. Our goal was to reveal the potential use of the hydrophobicity-related traits for formulation design of the fungal agents.
Materials and Methods
Fungal Isolates
Forty-five isolates of B. bassiana (Bb), M. anisopliae sensu lato (Ma), M. acridum (Mc), M. majus (Mm), M. robertsii (Mr), M. anisopliae var. acridum (Maac, likely Mc) and I. fumosorosea (If) with different host and geographic origins were obtained from the ARS Collection of Entomopathogenic Fungal Cultures (ARSEF; RW Holley Center for Agriculture and Health, Tower Road, Ithaca, NY, USA). Three other isolates, derived from Asian corn borer Ostrinia furnacalis (Bb0101) and false-eye leafhopper Empoasca vitis (Bb0201 and Ma0201) in China, were also included in the study. All isolates were preserved at −76°C and recovered on the plates of Sabouraud dextrose agar plus 1% yeast extract (SDAY) at 25°C prior to use.
Production of Aerial Conidia
Aerial conidia of all isolates were produced on steamed rice in Petri dishes (15 cm diameter) during a period of one month following a protocol described previously [4, 26, 27]. Rice cultures were grown for 7–9 days at 25°C and then dried under ventilation at 34°C for 1 day. Aerial conidia were harvested through a vibrating sieve and vacuum-dried to ≤5% water content at ambient temperature. The dried conidia were used immediately or stored at 4°C in glass vials for use within 3 months, warranting the viabilities of ≥90%.
Assessment of Conidial Hydrophobicity
Conidial hydrophobicity of each isolate was assessed using the method of aqueous-solvent partitioning [22–24] with some modification. For each isolate, conidia were suspended in PM buffer (per liter: 6.97 g K2HPO4, 2.99 g KH2PO4 and 0.2 g MgSO4·7H2O; final pH 7.12) containing 0.02% (v/v) Tween 80, and the spore suspension was standardized to 2 × 107 conidia ml−1. Liquid paraffin, which has proven a desired oil vector of fungal formulations [28–30] and thus was used as organic phase in this study, was then added to the spore suspension at the ratio of 40 μl over 4 ml. The buffer was used to neutralize charges of spore surface, thus excluding their effect on spore distribution in either phase. The mixture in 20-ml standard separation funnel was vortexed for 2 min. When the organic phase was separated from the aqueous phase after vortex, three aliquots were pipetted from the aqueous phase into Neubauer hemocytometers and the conidia left in the aqueous phase were counted under microscope. The hydrophobicity rate (H r) of the tested conidia was assessed as H r = (1−C/C 0) × 100, where C 0 was the spore concentration of the aqueous suspension before paraffin was added and C the residual spore concentration in the aqueous phase after the partitioning. The assay of each isolate was repeated four times.
Measurements of Conidial Sizes and Superficial Areas
For each of the 48 isolates, 30 conidia were cross-measured for their lengths and widths under microscope at 1,000× magnification. Based on the shapes of spheroid, quasi-spheroid, elongated spheroid and cylindroid, all measured conidia were considered as ellipsoid; surface area per capita (S a) was computed as square micrometer (μm2 conidium−1) sing the formula S a = 2(2b)1/2(a 2 + b 2)1/2, where a and b were the length and width of each conidium.
Extraction of Conidial Wall Proteins
To examine cell wall proteins of aerial conidia, six isolates of B. bassiana (Bb2860 and Bb2864), I. fumosorosea (If4205 and If6032), M. anisopliae (Ma456) and M. majus (Mm978) were selected as representatives based on the distributions of their H r and S a among all the tested isolates. Of those, Bb2860 and Ma456 are excellent candidates against sucking pests such as planthoppers, leafhoppers and spider mites [26–30]. The aerial conidia of each isolate were subjected to sequential treatments with boiling sodium dodecyl sulfate (SDS), iced formic acid (FA) and iced trifluoroacetic acid (TFA) following a basic extraction protocol [15, 31] with some modification below.
For the isolates of B. bassiana and I. fumosorosea, 100 mg aliquots of aerial conidia were separately suspended in 4 ml SDS buffer [2% (w/v) SDS, 5% (v/v) β-mercaptoethanol], and the suspension was boiled for 10 min. Four cycles were run for extracting the SDS-soluble proteins from the conidia, and the resultant supernatant was stored at 4°C for analysis. Subsequently, the SDS-treated conidia were collected by 10-min centrifuge at 5,000×g after washing twice and then suspended in 2 ml FA on ice for 2 h. The supernatant was mixed with 2 ml dd-H2O, followed by neutralization with 4 ml 45% (w/v) NaOH on ice. Maintained overnight at 4°C, the supernatant was centrifuged at 5,000×g for 10 min and the deposits were dissolved in 250 μl 2% SDS. After the FA-extracted, SDS-soluble proteins were washed off with 50 ml 2% SDS, the SDS-insoluble pellets collected by 5-min centrifuge at 10,000×g were lyophilized and suspended in 2 ml TFA on ice for 30 min. The suspension was then dried up by evaporation at ambient temperature for removing the TFA and the deposits were resuspended in 50 μl 2% SDS for analysis. For the two isolates of Metarhizium, the first two extractions were the same as earlier. Additionally, the FA-treated conidia were further suspended in 2 ml TFA on ice for 1 h extraction. After the TFA was evaporated, the deposits were suspended in 50 μl 2% SDS for the following analyses.
Assessment of TFA-Soluble Protein Contents
For all the selected isolates, the contents (P c) of the TFA-soluble, but FA-insoluble, proteins extracted from aerial conidia were measured as μg mg−1 conidia with a folin-phenol method [32] using bovine serum albumin as a standard. The measurements were then transferred to the unit of μg per 107 conidia for standardization due to a wide variation of their conidial sizes.
SDS–PAGE Analysis of Conidial Wall Extracts
The 2% SDS solutions of the SDS-, FA- and TFA-soluble proteins from the sequential extracts of all the selected isolates were boiled for 3 min. Subsequently, 15 μl aliquots of the solutions were loaded on Tris–glycine gels (3% stacking gel and 15% resolving gel) for SDS–PAGE analysis [33]. The stacking gel was run at 12 mA and the resolving gel at 18 mA. After electrophoresis, the gel was stained with 0.12% Coomassie Blue R-250 (0.12 g R-250, 25 ml ethanol, 8 ml acetic acid and 67 ml dd-H2O) and visualized in the reagent consisting of 25% (v/v) ethanol and 8% (v/v) glacial acetic acid.
Hydrophobicity Assessment of Treated Conidia
The conidia of the six selected isolates were washed twice with dd-H2O after each of the treatments with SDS, FA or TFA and suspended again in the PM buffer. All the suspensions were adjusted to the concentration of 2 × 107 conidia ml−1, and conidial hydrophobicity rates were separately measured as described earlier.
Western Blotting of Known Hydrophobins
Two hydrophobins Hyd1 (13.81 kDa) and Hyd2 (11.98 kDa) known in B. bassiana [16] were separately expressed as (His)6-tagged recombinant Hyd1 and Hyd2 (ca. 20 kDa for both) in Escherichia coli BL21 by gene transformation. Each hydrophobin was purified from 500 ml BL21 culture and homogenized to 1 mg protein ml−1 normal saline. The saline was then mixed with Freund’s complete adjuvant at the volume ratio of 1:1 and injected into New Zealand white rabbits (4 months old) three times at 14-day interval (2 ml per injection). Rabbit blood was taken 14 days after the final injection. The serums were separated by centrifuge at 3,000×g at 4°C, generating the polyclonal antibodies anti-Hyd1 and anti-Hyd2.
The TFA-soluble, but FA-insoluble, proteins in the conidial extracts of the selected isolates were electrophoretically transferred from gels onto the PVDF membranes and analyzed by Western blot using the kit of ProtoBlot alkaline phosphatase system (Novagen). All blots were probed with 2,000× dilution of the anti-Hyd1 or anti-Hyd2 and visualized with goat anti-rabbit IgG-alkaline phosphatase conjugate (Novagen).
Scanning Electronic Microscopy of Treated Conidia
Dried samples of the conidia from the sequential treatments and control (not treated) were covered with evaporated platinum. Possible changes of rodlet layers (presence or absence) on the surfaces of the treated conidia were then observed under scanning electronic microscope (SEM; Hitachi S4800, Ibaraki, Hitachi, Japan).
Assessment of Emulsifier Dispersancy to Aerial Conidia
Aerial conidia of the six selected isolates were separately suspended in the mixtures of 94.5–98% paraffin as oil carrier and 2–5.5% (v/v) fatty alcohol polyethylene glycol ether ‘AEO-3’ as emulsifier (Xiaoshan Chemical Additives Co., Hangzhou, China), resulting in different emulsifiable formulations at a standardized concentration of 1 × 1010 conidia ml−1. To examine aqueous dispersancy of different emulsifier ratios toward the formulated conidia, 100-fold aqueous dilutions (1 × 108 conidia ml−1) were prepared with four samples (replicates) of each formulation. Each of the dilutions in 15-ml tubes was shaken by wrist action for 0.5 min; three suspension samples were then pipetted into Neubauer hemocytometers for counts of the dispersed conidia in aqueous phase under a microscope. The ratio of the detected spore concentration over the diluted concentration was an index for the dispersancy (D i) of a given emulsifier ratio to the oil-formulated conidia of each isolate.
Data Analysis
All measurements of H r, D i (both transformed to arcsine-squared roots), S a and P c (both log10-transformed) were subjected to one- or two-way analysis of variance (ANOVA), followed by linear correlation to each other. The D i values of each fungal isolate observed over the emulsifier ratios of 2–5.5% (R e) were fitted to the logistic equation D i = K/[1 + exp(a + r d R e)], where K is a maximal potential of dispersancy to be achieved by the tested emulsifier for a given isolate, a an intercept for the fitted curve and r d the rate of dispersancy increase with R e. The fitted r d was also linearly correlated to the H r values of the six isolates. All analyses were performed using an updated version of DPS software [34].
Results
Variability in Conidial Hydrophobicity and Surface Area
The hydrophobicity rates of aerial conidia (Fig. 1a) ranged from 59.7 (Pf6032) to 92.2% (Mm978) and differed significantly among the tested 48 isolates (F 47,144 = 17.9, P < 0.01) and also varied within each fungal group, i.e., 69.5–87.2% (mean: 78.6%) in B. bassiana (F 13,42 = 12.9, P < 0.01), 77.1–92.2% (83.3%) in Metarhizium spp. (F 23,72 = 10.6, P < 0.01) and 59.7–79.2% (72.5%) in I. fumosorosea (F 9,30 = 9.5, P < 0.01). The three means were significantly different from one to another (Fisher’s LSD, P < 0.05).
Surface areas of aerial conidia (Fig. 1b) computed with measured widths and lengths spanned from 7.9 (If6032) to 25.3 μm2 conidium−1 (Mm978) and differed significantly within each fungal group (P < 0.01 in one-way ANOVA). The S a means (±SD) for the isolates of Metarhizium spp., B. bassiana and I. fumosorosea were 14.4 ± 3.8, 10.1 ± 1.4 and 9.0 ± 0.7 μm2 (F 2,45 = 26.3, P < 0.01), respectively. The latter two means had no significant difference (Fisher’s LSD, P > 0.05).
Interestingly, the arcsin-squared roots of the H r measurements from the 48 isolates were significantly correlated to the log10-transformed S a estimates (Fig. 2a). The fitted coefficient of determination (r 2 = 0.55, F 1,46 = 56.5, P < 0.0001) for the linear correlation indicates that 55% of the variation in conidial hydrophobicity is attributed to the surface areas of the tested isolates based on their conidial sizes. The same correlation was also significant for the isolates of Metarhizium spp. (r 2 = 0.45, F 1,22 = 18.2, P = 0.0003) and B. bassiana (r 2 = 0.37, F 1,12 = 7.0, P = 0.0214) but insignificant for I. fumosorosea (r 2 = 0.15, F 1,8 = 1.5, P = 0.26).
Correlation of Hydrophobicity Rates to TFA-Soluble Protein Contents
The contents of the TFA-soluble proteins (P c) fell in a range of 21.5–91.9 μg mg−1 conidia or 2.7–44.8 μg per 107 conidia (Table 1). The P c measurements differed significantly among the tested isolates (P < 0.01 in one-way ANOVA).
The hydrophobicity rates of the extracted conidia (Table 1) were significantly different among the tested isolates (F 5,54 = 11.9, P < 0.01) or between the sequential treatments (F 2,54 = 360.3, P < 0.01) based on two-way ANOVA. The FA treatment reduced drastically the H r values of all B. bassiana and I. fumosorosea isolates (Fisher’s LSD, P < 0.05), whereas the SDS treatment had no significant effect on H r (Fisher’s LSD, P > 0.05). However, the H r values of the two Metarhizium isolates (Ma456 and Mm978) were substantially reduced only by the TFA treatment.
The arcsin-squared roots of the H r values of the six isolates were linearly correlated to the log10-transformed P c values (μg per 107 conidia) measured from their FA and TFA extracts (Fig. 2b). Up to 79% of the H r variation (r 2 = 0.79, P = 0.018) was related to the P c estimates. However, the correlation was not significant (r 2 = 0.44, F 1,4 = 3.1, P = 0.15) when the protein contents in the unit of μg mg−1 conidia were concerned. This suggests that the hydrophobicity of aerial conidia depend on both their TFA-soluble protein content and conidial size.
Components of Conidial Wall Extracts
The components of conidial wall proteins were diverse in the sequential SDS and FA extracts of the selected isolates, as illustrated by SDS–PAGE profiles (Fig. 3a). After the FA treatment, a very few proteins were retained on conidial walls of the two Metarhizium isolates and then extracted well with TFA. In contrast, the FA extraction resulted in no residual wall proteins from the isolates of B. bassiana and I. fumosorosea. Most of the FA-extracted proteins from these isolates were SDS-soluble, whereas a few were SDS-insoluble until being dissolved with iced TFA.
There were only two TFA-soluble proteins in the FA extracts from each of the two B. bassiana isolates. As a result of the Western blotting with prepared antibodies (Fig. 3b), the two proteins were confirmed as the hydrophobins Hyd1 (13.81 kDa) and Hyd2 (11.98 kDa), which were well characterized from the same fungal species (16). However, the TFA-soluble components (10–14 kDa) of the I. fumosorosea and Metarhizium isolates had no reaction with the antibodies (Fig. 3c, d). No cross-reaction was detected for either anti-Hyd1 with the purified Hyd2 or anti-Hyd2 with the purified Hyd1 of the Bb2860 (Fig. 3e).
SEM Examination of Rodlet Layers on the Surfaces of Treated Conidia
Similar SEM overviews to the conidia sequentially treated with SDS, FA and TFA were attained for the two isolates of each fungus with different H r and S a, and thus half of them were shown in Fig. 4. The rodlet layers on conidial surfaces were well retained after the SDS treatment irrespective of the fungal species or isolates. The subsequent FA treatment removed such hydrophobic structures from the conidia of B. bassiana and I. fumosorosea. However, the same surface structure of M. anisopliae was removed only by further TFA extraction.
Aqueous Dispersancy of Emulsifier to Oil-Formulated Conidia
Listed in Table 2 are the measured dispersancy indices (D i) of 2–5.5% emulsifier toward the oil-formulated conidia of the six isolates with distinguished H r, S a and P c values. In aqueous dilutions, the D i values generally increased with the emulsifier ratio but varied greatly among the isolates even at the same emulsifier ratio (P < 0.01 in one-way ANOVA). As a result, emulsifying the oil-formulated conidia in water was easy for If6032, followed by Bb2860 and If4205. In contrast, the emulsification was most difficult for Mm978, followed by Bb2864 and Ma456.
The D i trends over the tested emulsifier ratios fit well the logistic equation with high coefficients of determination (0.93 ≤ r 2 ≤ 0.98; Table 2). The maximal potential of the emulsifier dispersancy to the oil formulation ranged from 26.8 (Mm978) to 91.7% (If6032). The fitted rates of dispersancy increase over the emulsifier ratios were inversely correlated to the H r values of the six isolates (r 2 = 0.94), as illustrated in Fig. 5.
Discussion
As presented earlier, both TFA-soluble protein content and surface area depending on conidial size are important traits for the conidial hydrophobicity of the tested fungal agents and thus useful for improving fungal formulation and field spray. Several aspects on fungal formulations are discussed later.
First of all, fungal biocontrol candidates are usually selected based on their virulence against target pests [1, 2] and tolerance or resistance to environmental stresses such as high temperatures [35, 36], solar UV irradiations [37–39] and fungicide sprays [40]. Apart from the inherent features associated with their biocontrol potential, our results highlight significant contributions of surface area and TFA-soluble protein content to conidial hydrophobicity (Fig. 2). Both traits are also inherent as is well known for fungal virulence and stress tolerance and thus need be taken into account for formulating a fungal candidate.
The TFA-soluble proteins examined in this study are apparently hydrophobins, although some of them are FA extractable. First, this was fully proven with the two isolates of B. bassiana by the Western blots of the polyclonal antibodies (Fig. 3b), which were prepared based on known Hyd1 and Hyd2 [16]. The fact that a few FA-extracted, SDS-insoluble proteins from the two I. fumosorosea isolates became SDS-soluble after being dissolved with TFA indicates their same hydrophobic feature as observed from B. bassiana. The residue proteins of the Metarhizium isolates after the FA treatment were well extracted with TFA. The TFA-soluble proteins of both M. anisopliae and I. fumosorosea in the sizes of 10–14 kDa, although not examined by Western blot due to unavailable hydrophobin-encoded genes, could be biochemically similar to Hyd1 and Hyd2. This is because those proteins can be dissociated into the SDS–PAGE visible monomers with TFA only [11–13] and their molecules fall within the sizes of known hydrophobins [8]. Moreover, the hydrophobin-based rodlet layers [5, 14] were removed by FA for B. bassiana and I. fumosorosea or TFA for M. anisopliae (Fig. 4), accompanied by drastic H r decreases (Table 1). These provide further support for the deduction. Thus, a source of variation in conidial hydrophobicity comes mainly from the content of the TFA-soluble proteins (hydrophobins) and the surface area per conidium. Thus, fungal candidates with desired hydrophobicity can be readily selected from the strains with high virulence and stress tolerance based on the two measurable traits.
From practical point of view, some degree of conidial hydrophobicity is essential for a fungal formulation because it favors conidial adhesion to insect cuticles [6, 19]. However, oil formulation of aerial conidia with high hydrophobicity cannot be readily emulsified into aqueous dilutions for qualified field sprays. The emulsifier tested in this study is usually added to the oil formulation at about 5% for field spray against sucking pests and proven biologically compatible with the conidia of the tested fungal species [28–30, 41]. This emulsifier ratio resulted in 55% dispersancy to the oil formulation of Bb2860 conidia with lower hydrophobicity, but less than 5% to the same formulation of Mm978 conidia with maximal hydrophobicity (Table 2). For each of the six isolates with different degrees of conidial hydrophobicity, the fitted K value provides a potential dispersancy of the used emulsifier toward the oil formulation. For instance, the aqueous dispersivity of the oil-formulated conidia predicted with the fitted equations can be enhanced to 51.2 and 46.4% by increasing the emulsifier ratio to 7 and 8% for the very hydrophobic isolates Bb2864 and Ma456, respectively, but to only 26.8% by elevating the ratio to 15% for the most hydrophobic isolate Mm978. With our experiences, about 50% dispersancy of the same oil formulation emulsified in water ensures acceptable field sprays by conventional sprayers for pest control [42]. A ratio of the tested emulsifier to achieve this dispersancy is ideally around 5%, not exceeding 8%, at a reasonable cost. The same principle may suit to other types of emulsifiers or wetting agents with different potential of aqueous dispersancy to a fungal formulation. The hydrophobicity-related traits elucidated in this study would help understand dispersancy potential of different emulsifiers or wetting agents to a formulation of selected fungal candidates and thus determine their use in the formulation design.
References
Feng MG, Poprawski TJ, Khachatourians GG. Production, formulation and application of the entomopathogenic fungus Beauveria bassiana for insect control: current status. Biocontrol Sci Technol. 1994;4:3–34.
Roberts DW, St Leger RJ. Metarhizium spp., cosmopolitan insect-pathogenic fungi: mycological aspects. Adv Appl Microbiol. 2004;54:1–70.
de Faria MR, Wraight SP. Mycoinsecticides and Mycoacaricides: a comprehensive list with worldwide coverage and international classification of formulation types. Biol Control. 2007;43:237–56.
Ye SD, Ying SH, Chen C, Feng MG. New solid-state fermentation chamber for bulk production of aerial conidia of fungal biocontrol agents on rice. Biotechnol Lett. 2006;28:799–804.
Beever RE, Dempsey GP. Function of rodlets on the superficial of fungal spores. Nature. 1978;272:608–10.
Boucias DG, Pendland JC, Latge JP. Nonspecific factors involved in attachment of entomopathogenic deuteromycetes to host insect cuticle. Appl Environ Microbiol. 1988;54:1795–805.
Bidochka MJ, St Leger RJ, Joshi L, Roberts DW. An inner cell wall protein (cwp1) from conidia of the entomopathogenic fungus Beauveria bassiana. Microbiol-SGM. 1995;141:1075–80.
Wösten HAB. Hydrophobins: multipurpose proteins. Annu Rev Microbiol. 2001;55:625–46.
Wang C, Leger RJS. A collagenous protective coat enables Metarhizium anisopliae to evade insect immune responses. Proc Natl Acad Sci USA. 2006;103:6647–52.
Pitarch A, Nombela C, Gil C. Collection of proteins secreted from yeast protoplasts in active cell wall regeneration. Methods Mol Biol. 2008;425:241–63.
Wessels JGH, de Vries OMH, Ásgeirsdóttir SA, Schuren FHJ. Hydrophobin genes involved in formation of aerial hyphae and fruit bodies in Schizophyllum. Plant Cell. 1991;3:793–9.
Wessels JGH, de Vries OMH, Ásgeirsdóttir SA, Springer J. The thn mutation of Schizophyllum commune, which suppresses formation of aerial hyphae, affects expression of the Sc3 hydrophobin gene. J Gen Microbiol. 1991;137:2439–45.
de Vries OMH, Fekkes MP, Wösten HAB, Wessels JGH. Insoluble hydrophobin complexes in the walls of Schizophyllum commune and other filamentous fungi. Arch Microbiol. 1993;159:330–5.
Bidochka MJ, St Leger RJ, Joshi L, Roberts DW. The rodlet layer from aerial and submerged conidia of the entomopathogenic fungus Beauveria bassiana contains hydrophobin. Mycol Res. 1995;99:403–6.
Jeffs LB, Xavier IJ, Matai RE, Khachatourians GG. Relationships between fungal spore morphologies and superficial properties for entomopathogenic members of the genera Beauveria, Metarhizium, Paecilomyces, Tolypocladium, and Verticillium. Can J Microbiol. 1999;45:936–48.
Cho EM, Kirkland BH, Holder DJ, Keyhani NO. Phage display cDNA cloning and expression analysis of hydrophobins from the entomopathogenic fungus Beauveria (Cordyceps) bassiana. Microbiol-SGM. 2007;153:3438–47.
St Leger RJ, Staples RC, Roberts DW. Cloning and regulatory analysis of starvation-stress gene, ssgA, encoding a hydrophobin-like protein from the entomopathogenic fungus, Metarhizium anisopliae. Gene. 1992;120:119–24.
Bidochka MJ, Kamp AM, Lavender TM, Dekoning J, de Croos JN. Habitat association in two genetic groups of the insect-pathogenic fungus Metarhizium anisopliae: uncovering cryptic species? Appl Environ Microbiol. 2001;67:1335–42.
Fargues J. Adhesion of the fungal spore to the insect cuticle in relation to pathogenicity. In: Roberts DW, Aist JR, editors. Infection processes of fungi. New York: Rockefeller Foundation; 1984. p. 90–110.
Holder DJ, Keyhani NO. Adhesion of the entomopathogenic fungus Beauveria (Cordyceps) bassiana to substrata. Appl Environ Microbiol. 2005;71:5260–6.
Doyle RJ. Contribution of the hydrophobic effect to microbial infection. Microbes Infect. 2000;2:391–400.
Girardin H, Paris S, Rault J, Bellon-Fontaine MN, Latgé JP. The role of the rodlet structure on the physicochemical properties of Aspergillus conidia. Lett Appl Microbiol. 1999;29:364–9.
Holder DJ, Kirkland BH, Lewis MW, Keyhani NO. Superficial characteristics of the entomopathogenic fungus Beauveria (Cordyceps) bassiana. Microbiol-SGM. 2007;153:3448–57.
Shah FA, Allen N, Wright CJ, Butt TM. Repeated in vitro subculturing alters spore superficial properties and virulence of Metarhizium anisopliae. FEMS Microbiol Lett. 2007;276:60–6.
Pu ZL, Li ZZ. Insect mycology. Anhui, China: Anhui Publishing House of Science and Technology; 1996.
Jin SF, Feng MG, Chen JQ. Selection of global Metarhizium isolates for the control of the rice pest Nilaparvata lugens (Homoptera: Delphacidae). Pest Manag Sci. 2008;64:1008–14.
Shi WB, Zhang L, Feng MG. Time-concentration-mortality responses of carmine spider mite (Acari: Tetranychidae) females to biocontrol agents of three hypocrealean fungi in a standardized bioassay system. Biol Control. 2008;46:495–501.
Feng MG, Pu XY, Ying SH, Wang YG. Field trials of an oil-based emulsifiable formulation of Beauveria bassiana conidia and low application rates of imidacloprid for control of false-eye leafhopper Empoasca vitis on tea in southern China. Crop Prot. 2004;23:489–96.
Shi WB, Feng MG. Field efficacy of application of Beauveria bassiana formulation and low rate pyridaben for sustainable control of citrus red mite Panonychus citri (Acari: Tetranychidae) in orchards. Biol Control. 2006;39:210–7.
Shi WB, Zhang LL, Feng MG. Field trials of four formulations of Beauveria bassiana and Metarhizium anisoplae for control of cotton spider mites (Acari: Tetranychidae) in the Tarim Basin of China. Biol Control. 2008;45:48–55.
Ying SH, Feng MG. Relationship between thermotolerance and hydrophobin-like proteins in aerial conidia of Beauveria bassiana and Paecilomyces fumosoroseus as fungal biocontrol agents. J Appl Microbiol. 2004;97:323–31.
Lowry OH, Rosenbrough NJ, Farr AL, Randall RJ. Protein measurement with the Folin phenol reagent. J Biol Chem. 1951;193:265–75.
Laemmli UK. Cleavage of structural proteins during the assembly of the head of bacteriophage T4. Nature. 1970;227:680–5.
Tang QY, Feng MG. DPS data processing system: experimental design, statistical analysis and data mining. Beijing, China: Science Press; 2007.
Rangel DEN, Braga GUL, Anderson AJ, Roberts DW. Variability in conidial thermotolerance of Metarhizium anisopliae stains from different geographic origins. J Invertebr Pathol. 2005;88:116–25.
Li J, Feng MG. Intraspecific tolerance of Metarhizium anisopliae conidia to the upper thermal limits of summer with a description of a quantitative assay system. Mycol Res. 2009;113:93–9.
Braga GUL, Flint SD, Miller CD, Anderson AJ, Roberts DW. Variability in response to UV-B among species and strains of Metarhizium isolated from sites at latitudes from 61°N to 54°S. J Inverteb Pathol. 2001;78:98–108.
Fernandes ÉKK, Rangel DEN, Moraes ÁML, Bittencourt VREP, Roberts DW. Variability in tolerance to UV-B radiation among Beauveria spp. isolates. J Invertebr Pathol. 2007;96:237–43.
Huang BF, Feng MG. Comparative tolerances of various Beauveria bassiana isolates to UV-B radiation with a description of a modeling method to assess lethal dose. Mycopathologia. 2009;168:145–52.
Zou G, Ying SH, Shen ZC, Feng MG. Multi-sited mutations of beta-tubulin are involved in benzimidazole resistance and thermotolerance of fungal biocontrol agent Beauveria bassiana. Environ Microbiol. 2006;8:2096–105.
Feng MG, Chen B, Ying SH. Trials of Beauveria bassiana, Paecilomyces fumosoroseus and imidacloprid for management of Trialeurodes vaporariorum (Homoptera: Aleyrodidae) on greenhouse grown lettuce. Biocontrol Sci Technol. 2004;14:531–44.
Pu XY, Feng MG, Shi CH. Impact of three application methods on the field efficacy of Beauveria bassiana-based mycoinsecticide against the false-eye leafhopper, Empoasca vitis (Homoptera: Cicadellidae) in the tea canopy. Crop Prot. 2005;24:167–75.
Acknowledgments
We thank Humber RA (RW Holley Center for Agriculture and Health, Ithaca, NY, USA) for providing ARSEF fungal isolates. Funding of this study was provided jointly by the Ministry of Science and Technology of China (2009CB118904 and 2007DFA3100) and the Zhejiang R&D Program (2007C12035, 2008C12057 and 2008C02007-1).
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Shan, LT., Wang, ZL., Ying, SH. et al. Hydrophobicity-Related Protein Contents and Surface Areas of Aerial Conidia are Useful Traits for Formulation Design of Fungal Biocontrol Agents. Mycopathologia 169, 483–494 (2010). https://doi.org/10.1007/s11046-010-9283-8
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s11046-010-9283-8