In Vitro Effects of Leaf Extracts from Brassica rapa on the Growth of Two Entomopathogenic Fungi

This study aimed to determine the inhibitive or stimulatory effects of leaf extracts from two Brassica rapa subspecies on the hyphal growth of two well-known entomopathogenic fungi, Cordyceps fumosorosea and Beauveria bassiana. Extract concentrations of 50, 25, and 10% w/v based on leaf fresh weight were prepared from turnip (B. rapa subspecies rapa) and bok choy (B. rapa subspecies chinensis) leaves. Each concentration was individually incorporated into potato dextrose agar plates for in vitro bioassays. The center of each plate was inoculated with 20 µL of a fungal suspension that was allowed 24 h to soak into the agar before sealing the plates and incubating them at 25 °C under a 14-h photophase. The fungal colony perimeter was marked 5 days after inoculation on two perpendicular lines drawn on the bottom of each plate. Radial colony growth was measured from 4 marks per plate 5, 10, and 15 days later. Radial growth rates for both fungi were 1.3–2.0 and 0.9–1.4 times faster with bok choy and turnip extracts, respectively, at the 25% and 50% concentrations compared to the no-extract control treatment. Therefore, bok choy and turnip leaf extracts can stimulate entomopathogenic fungus growth within 15 days. Biochemical compounds in the extracts include sesquiterpenes, α-copaene, β-selinene, γ-gurjunene, calamenene, cubenene, and α-calacorene.


Introduction
The Brassicaceae, commonly known as crucifers, have been studied extensively for secondary metabolites, known as glucosinolates, found exclusively in their tissues [1]. When the plant is mechanically damaged, such as being fed on by an arthropod or infected by a plant pathogen, cellular breakdown exposes the glucosinolates stored in the leaves to degradative enzymes known as myrosinases [2]. The products of the glucosinolate enzymatic hydrolysis, known as isothiocyanates, are reported to have nematicidal [3,4], fungicidal [5,6], and bactericidal [6][7][8] properties. In addition, the sequestration of these toxic isothiocyanates in the hemocoel of arthropod pests can negatively influence the efficacy of EPF used for biological control [9][10][11]. the in vitro growth of M. anisopliae, but in vivo the pathogenicity of this EPF against the mustard beetle, Phaedon cochleariae (Fabricius), feeding on Chinese cabbage was affected by various crucifer-derived stimulatory and inhibitory compounds. Klingen et al. [36] showed that 100 ppm of 2-phenylethyl isothiocyanate completely inhibited the growth of M. anisopliae and Tolypocladium cylindrosporum Gams in vitro; however, when using an in vivo fungus-plant-soil microcosm system, no fungal inhibition was found. Ujjan and Shahzad [37] observed in vivo that some fungal strains of M. anisopliae, Lecanicillium lecanii (Zimmerman) Zare and Gams, B. bassiana, and Purpureocillium lilacinum (Thom) Luangsa-ard, Hywel-Jones, Houbraken, and Samson, were efficacious against the mustard aphid, Lipaphis erysimi (Kaltenbach), after topical applications in the laboratory and under field conditions. Lastly, Dos Anjos et al. [38] observed in vivo that yellowmargined leaf beetles feeding on crucifer leafy greens were susceptible to infection by B. bassiana under field conditions.
The ingestion and sequestration of allelochemical substances by arthropods that consume the brassicaceous plant tissue could play a role in these specialist herbivores rarely becoming infected by EPF [11,27,28]. Gámez Herrera et al. [17] and Montemayor et al. [18], who investigated the efficacy of commercially formulated C. fumosorosea applied against yellowmargined leaf beetles on bok choy (Brassica rapa subspecies chinensis) plants, observed in vivo, that an application rate 2× the label rate resulted in only 35% and 4% mortality of first instars and adults, respectively. Therefore, it appears that the efficacy of C. fumosorosea may be hindered due to the sequestration of glucosinolates by the beetle from feeding on the bok choy leaves. In addition, considering that the preferred host plant of the yellowmargined leaf beetle is turnip, which has been employed as a trap crop in an integrated management strategy for this pest [11,13,14,16], we decided to investigate the compatibility of C. fumosorosea on turnip as well. Moreover, because Dos Anjos et al. [38] observed that B. bassiana could infect this leaf beetle, the compatibility of commercially available fungal products containing different strains of B. bassiana with both bok choy and turnip leaf extracts was determined.
Therefore, to better understand this plant-insect-entomopathogen interaction, the objective of our study was to first determine in vitro if the leaf extracts from B. rapa subspecies rapa (turnip) and B. rapa subspecies chinensis (bok choy), which may be sequestered from feeding on the leaf tissue, have a stimulatory or an inhibitive effect on the hyphal growth of C. fumosorosea and B. bassiana. Additionally, the biochemicals found in the leaf extracts were identified and compared with a gas chromatography-mass spectrometry (GC-MS) analysis to determine if there are any differences in their composition.

Plant Material
Turnip and bok choy seeds were sown in 72-cell trays containing Fafard ® Super-Fine Germinating Mix (Sun Gro Horticulture, Agawam, MA, USA) for at least 20 days. After this, seedlings were transplanted to 3.8 L black plastic pots containing SunGro ® Professional Growing Mix (Sun Gro Horticulture, Agawam, MA, USA). The plants were watered daily and fertilized with Osmocote ® 15:9:12 controlled-release encapsulated formulation (Scotts Miracle-Gro Co., Marysville, OH, USA) for 3 months (Figure 1a,b).

Plant Material
Turnip and bok choy seeds were sown in 72-cell trays containing Fafard ® Super-Fine Germinating Mix (Sun Gro Horticulture, Agawam, MA, USA) for at least 20 days. After this, seedlings were transplanted to 3.8 L black plastic pots containing SunGro ® Professional Growing Mix (Sun Gro Horticulture, Agawam, MA, USA). The plants were watered daily and fertilized with Osmocote ® 15:9:12 controlled-release encapsulated formulation (Scotts Miracle-Gro Co., Marysville, OH, USA) for 3 months (Figure 1a,b).

Leaf Extract Preparation
Twenty-five grams of leaf material were collected 50 days after planting. Extracts from each plant subspecies were prepared by using a modified protocol from Naidu [39]. For this protocol, individual leaves (wet mass) were placed in a mortar, and liquid nitrogen was added as needed. Leaves were crushed and ground with a pestle into a fine powder. From the resultant leaf powder, 12.5 g were placed into a sterile 50 mL propylene Corning ® CentriStar™ centrifuge tube (Corning Inc., Corning, NY, USA) and used immediately or stored at −80 °C until ready for transport for chemical identification. For immediate usage in fungal growth assays, 25 mL of 80% ethanol was added to the powder, and

Leaf Extract Preparation
Twenty-five grams of leaf material were collected 50 days after planting. Extracts from each plant subspecies were prepared by using a modified protocol from Naidu [39]. For this protocol, individual leaves (wet mass) were placed in a mortar, and liquid nitrogen was added as needed. Leaves were crushed and ground with a pestle into a fine powder. From the resultant leaf powder, 12.5 g were placed into a sterile 50 mL propylene Corning ® CentriStar™ centrifuge tube (Corning Inc., Corning, NY, USA) and used immediately or stored at −80 • C until ready for transport for chemical identification. For immediate usage in fungal growth assays, 25 mL of 80% ethanol was added to the powder, and the mixture was allowed one hour for extraction of the chemicals. After this time, the extract was vortexed for 15 sec, filtered through two layers of sterile gauze, and centrifuged at 4000 rpm for 15 min at 4 • C to remove any cell fragments. The resultant extract supernatant was used to produce 50 mL of a 50% w/v concentration based on the fresh weight of the leaves. From this 50% concentration solution, 25 and 5 mL (30 mL total) of the supernatant were removed and diluted with 25 mL and 45 mL of ethanol, respectively, in separate tubes to produce a 25% and a 10% w/v concentration, respectively ( Figure 1c). All supernatant concentrations were then immediately incorporated into the potato dextrose agar (PDA) (Difco™, Benton, Dickinson and Co., Sparks, MD, USA) plates to be used for in vitro bioassays.

Effect of Leaf Extracts on Fungal Growth
Liquid medium (19.5 g of PDA powder/500 mL of sterile distilled water) was mixed in a 1 L bottle by using a magnetic stirring bar and then autoclaved for 20 min at 120 • C. After the liquid medium cooled to~16 • C, 50 mL of supernatant from one of the ethanolleaf extract concentrations were added and the medium was mixed again with a magnetic stirrer for 1 min. Liquid medium (22 mL) containing a specific leaf extract concentration was poured into each of 128 sterile plastic Petri dishes (100 mm × 15 mm) and allowed to solidify. For the control, 50 mL of 80% ethanol were added to the liquid media prior to pouring. Perpendicular lines traversing the diameter of the agar plate (Figure 1e-g) were drawn on the underside of the bottom plate with colored permanent markers prior to pouring the agar.
Prior to inoculation, C. fumosorosea (PFR 97™ 20% WDG and ARSEF 3581) and B. bassiana (BotaniGard ® ES and BioCeres ® WP) suspensions were made from the formulated products mixed with sterile, distilled water and adjusted to a concentration of 10 6 spores/mL. The PDA plates were inoculated by placing a 20 µL drop of the fungal suspension on the center of the plate (Figure 1d) at the intersection of the two perpendicular lines, and 24 h were given for the suspension to soak into the agar before sealing the Petri dish with Parafilm™ M (Bemis Co., Neenah, WI, USA) and placing it in a growth chamber set at 25 • C with a 14 h photophase. There were five replicates per fungal suspension per leaf extract concentration for both plant subspecies. For each fungal suspension per plant subspecies treatment, there was a control treatment, as described above, with five replicates.
The perimeter of the fungal colony was marked on each perpendicular line on the underside of each plate 5 days after inoculation, and the radius was measured. Fungal colony growth was assessed 5, 10, and 15 days later by measuring the colony's radius from the crossing of the perpendicular lines to the perimeter of the colony in two perpendicular directions. Radial growth (RG) per time period was determined by the following formula where R x = colony radius in mm at 5, 10, or 15 days after the initial fungal colony radial measurement; R 0 = initial fungal colony radius in mm 5 days after inoculation. The purpose of this measurement technique was to avoid bias in radial growth measurements caused by variability in colony establishment during the first 5 days. The experiment was conducted twice on separate occasions. When working with entomopathogens, especially fungi, it is necessary to conduct the experiment at least twice or more times to confirm results. One sample from the same product batch could give different results considering it is a living organism.

Gas Chromatography-Mass Spectrophotometry Analysis of Leaf Extracts
Using a scoop previously dipped in liquid nitrogen, leaf powder (5 g) stored at −80 • C was carefully placed into Corning ® Centistar™ 50 mL sterile centrifuge tubes, capped tightly, and left floating in a container with liquid nitrogen until they could be packed for shipping. Tubes were capped tightly, caps sealed with Parafilm, and immediately packed into a styrofoam container with dry ice and shipped overnight from the University of Florida (UF), Indian River Research and Education Center in Ft. Pierce, FL overnight to the UF North Florida Research and Education Center in Quincy, FL to be analyzed. Upon arrival, the leaf powder samples were stored at −20 • C until ready for chemical identification with gas chromatography-mass spectrometry (GC-MS) analysis. Before analysis, leaf samples were defrosted at 21 • C for 3 h, then, 10 mL of dichloromethane was added to each tube. Tubes were centrifuged at 13,000 rpm for 1 min, and 1 mL of supernatant was diluted in dichloromethane at a ratio of 1:10,000. One µL of the diluted solution was then injected into an ISQ QD Single quadrupole GC-MS spectrophotometer (Thermo Fisher Scientific, Inc. Waltham, MA, USA). The gas chromatograph was equipped with a TG-5MS capillary column (30 mm × 0.250 mm inner Ø; 0.25 µm film thickness, Thermo Fisher Scientific, Inc. Waltham, MA, USA). Data collection, storage, and subsequent analysis were performed on Thermo Fisher Chromatographic data system Chromeleon 7™ Thermo Fisher Scientific, Inc. Waltham, MA, USA). Helium at a linear flow velocity of 1 mL/min was used as the carrier gas. The temperature of the column oven was maintained at 40 • C for 1 min and then increased at a rate of 10 • C/min to a final temperature of 250 • C and maintained at 250 • C for 1 min. The injector temperature was set at 270 • C. Constituents of the plant volatile were identified by comparison of mass spectra with spectra in the National Institute of Standards and Technology database, the Flavors and Fragrances of Natural and Synthetic Compounds (FFNSC 3, Wiley, Hoboken, NJ, USA) and the spectra obtained from authentic reference compounds, when available. Additionally, GC retention times of plant volatiles were compared with those of authentic compounds on the TG-5MS column, when available. For each compound, the relative area was calculated by dividing the area of the compound peak with the sum of all the areas of the selected peaks. There were three replicates for each plant species.

Data Analysis
Mean in vitro radial growth measurements at 15 days were compared statistically with Student's t-test (α = 0.05). A best fit linear regression model analysis (α = 0.05) was used to compare the effect of the extracts on the radial growth slopes of each fungal entomopathogen over time. Differences among treatment means of the in vitro linear growth for each fungal entomopathogen per each concentration of the same plant extract were compared statistically using an ANOVA and post-hoc separation of the mean values by a Tukey's HSD test (α = 0.05). Statistical analyses were conducted using SAS 9.4 for WINDOWS 2012 (Cary, NC, USA) and gpplot2 library from R software version 4 [40].

Effect of Leaf Extracts on Fungal Growth
Significant differences in fungal colony radial growth at 15 days were detected among treatments for all four fungal strains on PDA with bok and turnip leaf extracts. For PFR-97, radial growths with 25% and 50% concentration of bok choy leaf extract were similar but significantly greater (F 3, 67 = 10.50; p < 0.0001) than on the control treatment (Figures 1e and 2). Growth on the 25% extract concentration was significantly greater than growth on the 0% and 10% concentrations. There was no significant difference between the 10% concentration and the control treatment. Radial growth on 50% concentration of turnip leaf extract was significantly greater (F 3, 67 = 9.27; p < 0.0001) compared to the other three concentrations (Figure 2).
For BioCeres WP, radial growth at 15 days on PDA with bok choy leaf extracts was significantly greater (F 3, 67 = 21.15; p < 0.0001) with all concentrations compared to the control (Figures 1f and 2). Radial growth with 50% extract concentration was significantly greater than with 25% but similar to growth at the 10% concentration. Radial growth on the turnip leaf extract at 25% and 50% concentrations was similar and significantly greater (F 3, 67 = 9.75; p < 0.0001) than in the control treatment, but only radial growth on the 50% concentration was significantly different from the growth on the 10% concentration ( Figure 2). For BotaniGard ES, radial growth on all bok choy extract concentrations was significantly greater (F 3, 67 = 16.43; p < 0.0001) compared to the control treatment ( Figure 2). Radial growth on the 50% extract concentration was significantly greater than with the 10% concentration but similar to growth on the 25% concentration treatment. On turnip leaf extracts, radial growth was significantly greater (F 3, 67 = 6.82; p = 0.0004) on the 25% concentration compared to the 0% and 50% concentrations, but it was similar to radial growth with 10% extract concentration (Figures 1g and 2). No difference in radial growth was observed between the 50% concentration and control treatments.
Comparisons between fungal strains are based on the extract concentration at which fungal growth was fastest. On PDA with 50% bok choy extract, mean radial growths of ARSEF, PFR-97, and BioCeres at 15 d were similar among themselves but significantly greater (F 3, 57 = 86.26; p < 0.0001) than BotaniGard (Table 1). On PDA with 50% turnip extract, radial growths of PFR-97 and BioCeres at 15 d were similar yet significantly greater (F 3, 57 = 131.06; p < 0.0001) than those of ARSEF and BotaniGard with 25% turnip extract (Table 1). The slopes of the growth models for PFR-97 with 50% concentration and ARSEF with 25% concentration were similar when grown on PDA with extracts from bok choy (t 118 = 1.80; p = 0.0750; n = 60) and turnip (t 118 = −1.22; p = 0.2665; n = 60) ( Figure 5). The slope of the radial growth model was significantly steeper for BioCeres with 50% concentration than for BotaniGard with 25% concentration when grown on PDA incorporated with extracts from bok choy (t 118 = −5.63; p < 0.0001; n = 60) and turnip (t 118 = −7.72; p < 0.0001; n = 60) ( Figure 5).   . Linear models of fungal radial growth for four entomopathogenic fungal products grown on PDA with 50% (PFR-97 and BioCeres) or 25% (ARSEF and BotaniGard) concentration of turnip leaf extract compared to its control treatment over a 15-day observation period. Models for PFR-97 and BioCeres are based on 50% leaf extract concentration; models for ARSEF and BotaniGard are based on 25% because radial growth was fastest at this concentration. Asterisk (*) above a line endpoint represents significance between treatment and control linear models (Student's t-test, p < 0.05). . Linear models of fungal radial growth for four entomopathogenic fungal products grown on PDA with 50% (PFR-97 and BioCeres) or 25% (ARSEF and BotaniGard) concentration of turnip leaf extract compared to its control treatment over a 15-day observation period. Models for PFR-97 and BioCeres are based on 50% leaf extract concentration; models for ARSEF and BotaniGard are based on 25% because radial growth was fastest at this concentration. Asterisk (*) above a line endpoint represents significance between treatment and control linear models (Student's t-test, p < 0.05). and BioCeres are based on 50% leaf extract concentration; models for ARSEF and BotaniGard are based on 25% because radial growth was fastest at this concentration. Asterisk (*) above a line endpoint represents significance between treatment models (Student's t-test, p < 0.05). BioCeres are based on 50% leaf extract concentration; models for ARSEF and BotaniGard are based on 25% because radial growth was fastest at this concentration. Asterisk (*) above a line endpoint represents significance between treatment models (Student's t-test, p < 0.05).

Gas Chromatography-Mass Spectrophotometry Analysis of Leaf Extracts
We identified 17 volatile compounds from the turnip and bok choy leaf extracts ( Figure 6). Major biochemical compounds were α-copaene, β-selinene, γ-gurjunene, calamenene, cubenene, and α-calacorene. For both source plant subspecies, the major compound was calamenene, a sesquiterpene accounting for 22.9% in bok choy extract and 38.0% in turnip extract of the total profile. Overall, bok choy extracts were very rich in sesquiterpenes as they represented >95% of the compounds identified, while turnip extracts had only 80% of sesquiterpenes. Compounds found in turnip but not (or at very low concentration) in bok choy were cymene, undecane, and dodecane. While statistical analyses were not conducted on these data due to the small number of replicates, the standard errors of the means of cymene, dodecane, undecane 4,7 dimethyl, and α-calacorene did not overlap, thus indicating potential differences for these compounds between turnip and bok choy. than for BotaniGard with 25% concentration when grown on PDA incorporated with extracts from bok choy (t118 = −5.63; p < 0.0001; n = 60) and turnip (t118 = −7.72; p < 0.0001; n = 60) ( Figure 5).

Gas Chromatography-Mass Spectrophotometry Analysis of Leaf Extracts
We identified 17 volatile compounds from the turnip and bok choy leaf extracts (Figure 6). Major biochemical compounds were α-copaene, β-selinene, γ-gurjunene, calamenene, cubenene, and α-calacorene. For both source plant subspecies, the major compound was calamenene, a sesquiterpene accounting for 22.9% in bok choy extract and 38.0% in turnip extract of the total profile. Overall, bok choy extracts were very rich in sesquiterpenes as they represented >95% of the compounds identified, while turnip extracts had only 80% of sesquiterpenes. Compounds found in turnip but not (or at very low concentration) in bok choy were cymene, undecane, and dodecane. While statistical analyses were not conducted on these data due to the small number of replicates, the standard errors of the means of cymene, dodecane, undecane 4,7 dimethyl, and α-calacorene did not overlap, thus indicating potential differences for these compounds between turnip and bok choy.

Discussion
Our study demonstrates that bok choy extracts in vitro are stimulatory to the hyphal growth of C. fumosorosea and B. bassiana strains within 15 d compared to the addition of no extract (Figures 2 and 3). Radial growths at day 15 for all EPF subjected to 50% concentration of bok choy and turnip leaf extracts were greater than radial growth on PDA without leaf extract; however, radial growths of C. fumosorosea Apopka strain and B. bassiana GHA strain exposed to the turnip leaf extract were greater at the 25% concentration level (Figure 3). Although interesting, these findings are contrary to what we expected to observe based on a previous in vivo study where the yellowmargined leaf beetle adult was rarely infected by C. fumosorosea Apopka strain while feeding on bok choy leaves sprayed

Discussion
Our study demonstrates that bok choy extracts in vitro are stimulatory to the hyphal growth of C. fumosorosea and B. bassiana strains within 15 d compared to the addition of no extract (Figures 2 and 3). Radial growths at day 15 for all EPF subjected to 50% concentration of bok choy and turnip leaf extracts were greater than radial growth on PDA without leaf extract; however, radial growths of C. fumosorosea Apopka strain and B. bassiana GHA strain exposed to the turnip leaf extract were greater at the 25% concentration level (Figure 3). Although interesting, these findings are contrary to what we expected to observe based on a previous in vivo study where the yellowmargined leaf beetle adult was rarely infected by C. fumosorosea Apopka strain while feeding on bok choy leaves sprayed with the fungus [17,18]. However, in corroboration with the findings in our study, Lin et al. [41,42] observed that the herbivore-induced plant volatiles (HIPVs) emitted from the crucifer Arabidopsis thaliana (L.) Heynh, while its leaves were fed on by the aphid L. erysimi, were stimulatory to spore germination and appressorial formation of L. lecanii, which are requisites for pathogenicity of the fungal infection.
Our study is novel and the first to assess the hyphal growth of C. fumosorosea and B. bassiana strains exposed to leaf extracts of bok choy and turnip in vitro at different concentration levels. However, similar in vitro research that preceded our study varied greatly in protocol, EPFs tested, or both. For example, Vega et al. [34] used the same ARSEF strain of C. fumosorosea, but their protocol differed from our study: (1) Germination of the blastospores of C. fumosorosea was the focus, not radial growth of the fungal colony; (2) Blastospores were grown on Noble agar, not PDA; (3) Rather than whole leaf extracts, sinigrin, a biochemical found in crucifers, was incorporated into the Noble agar. Vega et al. [34] observed that sinigrin did inhibit blastospore germination. Inyang et al. [35] studied in vitro the effect of volatile isothiocyanates from Chinese cabbage (Brassica campestris var. pekinensis) on the radial growth of M. anisopliae on Sabouraud dextrose agar plates. Instead of incorporating an isothiocyanate into the agar, a drop of the biochemical was placed on the inner surface of the Petri dish lid to simulate an HIPV-effect on the EPF. In their study, the isothiocyanates negatively affected spore germination, hyphal development, and the ability of the EPF to infect adult P. cochleariae. Klingen et al. [36] investigated the potential interactions between rutabaga (Brassica napus L.), the isothiocyanates they produce upon wounding (simulated by grating), and M. anisopliae and T. cylindrosporum. They concluded that isothiocyanates can inhibit the growth of EPF in vitro, but after using a more realistic in vivo tritrophic microcosm, no fungal inhibition was observed. In our study, the use of liquid nitrogen to freeze the leaf tissue during pulverization may have allowed the HIPVs inside the leaf powder to be preserved and may have meant that the isothiocyanates usually activated upon wounding or feeding were not released. Moreover, by using leaf extracts that contain a whole composite of interacting biochemicals rather than an isolated isothiocyanate incorporated into the agar, the in vitro condition simulated in our study may be more reflective of the realistic in vivo conditions affecting the EPF on the leaf surface.
The effect that exudates and HIPVs can have on the growth and pathogenicity of an EPF will be either inhibitive, neutral, or stimulatory. In our in vitro study, with bok choy leaf extract incorporated in the PDA, the stimulatory effect on the EPF increased as the concentration of the extract increased. However, the effect of the turnip leaf extract on the hyphal growth of each EPF was very different and not always stimulatory at the highest concentration level. Hyphal growth of C. fumosorosea Apopka strain in PFR-97 was stimulated to grow faster when exposed to the turnip extract only at the 50% concentration level, but the lower concentrations had a neutral effect. In contrast, hyphal growth of the C. fumosorosea ARSEF strain was stimulated more at the 25% concentration level compared to the 10% concentration, which had a neutral effect, whereas the effect on hyphal growth was inhibitive or slowed at the 50% concentration level. A stimulatory effect on hyphal growth for the B. bassiana ANT-03 strain in BioCeres was also observed when this strain was exposed to the turnip extract. The stimulatory effect from turnip extract on B. bassiana GHA strain resulted in a similar trend to that of the C. fumosorosea ARSEF 3581 strain, except that at the highest concentration level the effect was neutral.
Our observation of a stimulatory effect on the EPF hyphae to grow faster as the bok choy extract concentration increased may reflect a similar HIPV-effect as reported by Lin et al. [41,42], who observed that as the number of aphids feeding on A. thaliana leaf increased, the concentration of HIPVs increased, and, subsequently, the germination and appressorial formation of L. lecanii increased as well. Therefore, from an ecological perspective, the release of the HIPVs from the leaf would stimulate the EPF to grow faster, ultimately infecting and killing the feeding herbivore faster as well. This idea of fungal entomopathogens serving the role of "bodyguards" on the leaf phylloplane was proposed by Elliot et al. [43], Cory and Hoover [44], and Cory and Ericsson [45]. Based on our findings, it is possible that the crucifer leaf "attacked" by herbivores will release HIPVs to stimulate EPF growth to "help" kill the herbivore feeding on it. Although speculative and interesting, this hypothesis requires further study to confirm this specific scenario. However, the yellowmargined leaf beetle was observed to be unaffected by the presence of C. fumosorosea propagules after feeding on bok choy leaf [17,18]. Researchers investigating similar tritrophic interactions have concluded that plant exudates and HIPVs released on the leaf phylloplane can affect: (1) the impact of insect fungal pathogens by enhancing or decreasing persistence on the leaf surface [35,41,46], (2) the encounter rate between the insect and the pathogen [47], (3) insect susceptibility to disease [33,[48][49][50][51][52].
The major biochemical compounds in bok choy and turnip leaf extracts are α-copaene, β-selinene, γ-gurjunene, calamenene, cubenene, and α-calacorene. Sesquiterpenes are known to be major compounds found in Brassica species [53]. Nondestructively collected turnip leaf volatiles are known to include mainly sesquiterpenes but also terpenes and green leaf volatiles [54]. It is possible that the pulverization of the leaves increased the release of sesquiterpenes from the leaf tissues. Interestingly, some sesquiterpenes are known to induce hyphal branching in arbuscular mycorrhizal fungi [55] and the growth of the ascomycete Ophiostoma floccosum Math.-Käärik [56]. Therefore, it is possible that sesquiterpenes found in turnip and bok choy extracts might be implicated in the observed increased hyphal growth of the EPF. However, this hypothesis requires further study to be confirmed. In addition, sesquiterpenes are also known to be produced by some fungi for a possible defensive role [57].

Conclusions
It is important to determine the potential effect of a host plant's secondary allelochemicals on the growth of an EPF contained in a fungal biopesticide product in vitro, prior to it being applied under greenhouse or field conditions, in order to maximize the efficacy of any fungal biopesticide. In our case, the in vivo study was conducted first where we observed that the yellowmargined leaf beetle feeding on the bok choy leaves was difficult to induce mortality with C. fumosorosea applied at 2× the label rate [17,18]. We hypothesized that the growth and subsequent pathogenicity of the fungus may be negatively influenced by the presence of glucosinolates in the hemocoel sequestered per os from the leaves during beetle herbivory. However, contrary to our previous in vivo observations, results from this in vitro study revealed that, in general, the leaf extracts of bok choy and turnip when incorporated in the agar were stimulatory, not inhibitory, to the hyphal growth of the EPF. Based on the design of our in vitro study, the positive hyphal stimulation was due to the increase in the added biochemical nutrients contained in the extract incorporated in the agar, which was absent in the control plates. The GC-MS analysis of the leaf extracts identified many different biochemicals that may have played a role in stimulating the hyphal growth of the EPF tested, including C. fumosorosea, previously applied as a fungal biopesticide in the prior in vivo study [17,18]. This same scenario concerning the influence of the host plant on the performance of the EPF after application on different leaf surfaces has been repeated by other researchers as well where the in vivo study preceded the in vitro study [33,41,42]. For example, Lin et al. [41] first determined in vivo that the HIPVs induced by multiple aphids feeding on the brassica plant leaves were stimulatory to the conidial performance of L. lecanii and enhanced the pathogenicity against the aphids. A later study conducted by Lin et al. [42] determined that of all the HIPVs released during herbivory by the aphids, only the biochemicals methyl salicylate and menthol positively affected the growth and pathogenicity of L. lecanii. Therefore, further analysis using purified compounds, particularly the sesquiterpenes, should be conducted to determine which of the biochemicals contained in the complex extract of B. rapa subspecies has a positive effect on the growth of each EPF tested in this study. Confirmation of the effect of sequestered leaf extracts of both B. rapa subspecies on the efficacy of the fungal biopesticides should be assessed under field in vivo conditions.