Introduction
Filamentous fungal fermentation is widely used to produce valuable primary and secondary metabolites such as organic acids, enzymes, and antibiotics [3, 13]. For example, Aspergillus niger is an important industrial strain for the production of citric acid, which is in heavy demand as a bulk chemical for food and other industries [1]. Trichoderma reesei is the principal source of cellulase, which is widely used in the food, feed, and textile industries [2]. One of the most intriguing and often-problematic characteristics of filamentous fungi is their complex morphology in submerged culture. Fungal morphology not only has a significant impact on mixing and mass transfer, but also determines the overall process productivities and subsequent economics [22]. Thus, fungal morphology is considered as a key bioprocess parameter for submerged culture.
In general, the morphology of filamentous fungi varies between dispersed mycelia, clump, and pellet [21]. Under this condition, broth rheology is significantly affected by the complex morphological changes. The morphology of dispersed mycelia is favorable to ensure high production of some enzymes, because it allows almost all the individual hyphal elements to be in contact with the medium [7]. However, a major drawback of this morphology is that the high viscosity of the broth leads to insufficient mixing, which increases energy consumption for mechanical stress [18]. In comparison, clump formation ensures a lower broth viscosity, but disadvantages related to a decline of nutrient availability in the inner part of the compact pellet can occur [9]. Hence, the advantages and disadvantages of fungal morphology have to be balanced out carefully. Fungal morphology is influenced by the genotypes of strains and environmental conditions. Environmental conditions include chemical conditions like the type and content of carbon, nitrogen, phosphate, and metals, and physical conditions like mechanical stress, temperature, and pH.
The relationship between the morphology of filamentous fungi, viscosity of the cultivation broth, mass transfer, and related production has been reviewed by Wucherpfennig et al. [23] and Krull et al. [9], who proposed a new term called morphology engineering. Various studies have demonstrated that optimal production correlates closely with a specific fungal morphology. Obtaining the optimum morphology may provide a basis for the morphology control to optimize the fermentation process. A. terreus is a well-known producer of i taconic a cid (IA) [20]. Apart from t he e arly w ork of Gyamerah [4], who added four different sources of burnt CaSO4 to the fermentation medium in flasks, and the optimum morphology of A. terreus NRRL1960 for IA production was clumps of 0.1-0.5 mm in diameter, there have been no studies in the literature on the relationship between these two factors. However, the CaSO4 needed to be burnt at 530℃ or 900℃ before addition, and the maximum IA production was dependent on the CaSO4 source. Moreover, knowledge about whether the relationship between fungal morphology and production efficiency developed in flasks could be implemented in a scale-up study is limited. In the present study, IA production by A. terreus was used as a model to analyze not only the effects of the major kinds of medium composition and culture conditions on fungal morphology, but also the quantitative relationship between fungal morphology and IA in flasks. Furthermore, scale up from shake flasks to a 7 L stirred tank bioreactor was successfully achieved based on the quantitative relationship.
Materials and Methods
Microorganism, Media, and Growth Conditions
The fungus A. terreus strain FMME033 was isolated from soil in Jiangsu Province of China, in order to obtain an IA high-yielding strain. A. terreus FMME033 cultured on bromocresol green plate was selected for IA accumulation in shake culture. This strain gave the highest ratio of the diameter of the developed yellow halos to that of the colony after incubation for 48 h. It was maintained on malt extract agar slants comprising the following (g/l): malt extract 26.9, glucose 20.0, soybean peptone 1.0, and agar 20.0, without pH adjustment. The slants were inoculated at 37℃ for 7 days aerobically until sporulation, and then stored at 4℃. Conidiospores were harvested with sterile distilled water and quantified by a hemocytometer using a Zeiss microscope (Carl Zeiss AG, Germany). The inoculum medium for the spore-germination experiment contained the following (g/l): glucose 45.0, (NH4)2SO4 5.0, MgSO4·7H2O 1.0, KH2PO4 1.0, FeSO4·7H2O 0.04, ZnSO4·7H2O 0.05, and corn steep liquor powder 1.0, with pH adjusted to 3.1 using HNO3. The experiments were carried out in 500 ml Erlenmeyer flasks with a working volume of 100 ml. Cultivation was carried out at 37℃ and 200 rpm in rotary shakers for 36 h, with an initial spore concentration of 108 or 109 spores/ml. The acid production medium for the fermentation experiments consisted of the following (g/l): glucose 80, (NH4)2SO4 4, MgSO4·7H2O 1, FeSO4·7H2O 0.04, ZnSO4·7H2O 0.05, corn steep liquor powder 3, and KH2PO4, the quantity varied depending on the experiment, with pH adjusted to 3.1 using HNO3. For the experiments, 5 ml of inoculum culture was inoculated into 500 ml Erlenmeyer flasks with 50 ml of acid production medium, or 7.5 ml of inoculum culture was inoculated into 750 ml baffled flasks with 75 ml of acid production medium. The cultivation was carried out at 200 rpm for 48 h, and the temperature was varied depending on the experiment. In a 7 L stirred tank bioreactor (New Brunswick Scientific, USA) containing 4 L of acid production medium without KH2PO4, 10% (v/v) of the inoculum culture containing 108 spores/ml was added and cultivated at 35℃. The mechanical stress (agitation and aeration) was varied depending on the experiment. The initial pH value was adjusted to 3.1 using HNO3 and not corrected during the cultivation. All the media were sterilized at 121℃ for 20 min. All the experiments were carried out in triplicate, and the results are expressed as the mean ± standard deviation (SD).
Analytical Methods
An Agilent 1200 Series high-performance liquid chromatography (HPLC; Agilent Technologies, USA), equipped with a refractive index detector (RID), was used to detect the glucose concentration, and a UV detector was employed to analyze IA at 210 nm. The injection volume was 10 μl. The mobile phase was 5 mmol/l of H2SO4 at a flow rate of 0.6 ml/min through a Bio-Rad Aminex HPX-87H ion-exclusion column (300 × 7.8 mm) at 35℃. To determine DCW, the broth was centrifuged at 8,228 ×g for 5 min to obtain the biomass. Then, the solid fraction was washed three times with distilled water, and dried at 60℃ to a constant weight.
Imaging and Morphological Analysis
Sample preparation was carried out using the method described by Haack et al. [6]. For image analysis, 2 ml of the samples was taken from the culture broth, and one or two drops of lactophenol blue was added to stop growth and increase the contrast of the images. Image capture was accomplished on a Zeiss light microscope. The pellets were distinguished from clumps and dispersed mycelia by the differences in the greyness levels, an approach that has been used to provide a definition for a pellet [21]. Morphological measurements were carried out using the Image-Pro PLUS software (Media Cybernetics Inc., USA). The average clump diameter was calculated on images obtained using a 4× objective. Data, reported as the mean ± SD, were obtained from a population size of approximately 100 events per sample.
Rheological Measurements
Samples were taken from the culture broth based on the growth kinetics of dispersed mycelia, clump, and pellet. Then the wet cell weight was adjusted to the same value in order to avoid the influence of biomass concentration. Rheological parameters were examined using 25 ml of fermentation broth in a 50 ml glass vessel by a Brookfield viscometer (Brookfield, USA), fitted with a discspindle impeller #1. The consistency index (K) and flow behavior index (n) were determined as previously described [12, 19].
Results
Effect of Culture Conditions on A. terreus Morphology in Shake Flasks
Three different fungal morphologies were achieved at three different culture conditions in shake flasks: 500 ml Erlenmeyer flask, inoculum level 109 spores/ml (dispersed mycelia, Figs. 1A–1B); 500 ml Erlenmeyer flask, inoculum level 108 spores/ml (clump, Figs. 1C–1D); and 750 ml baffled flask, inoculum level 108 spores/ml (pellet, Figs. 1E–1F).
Fig. 1.The morphology of A. terreus under different culture conditions. (A, B) Dispersed mycelia; (C, D) Clump; and (E, F) Pellet. Macromorphology was observed by transferring 5 ml of culture broth (of 48 h culture) to a Petri dish and then taking an image using a CMOS camera (IXUS115; Canon, Japan). Micromorphology was examined using a Zeiss light microscope with a 20× objective. Culture conditions: dispersed mycelia (500 ml Erlenmeyer flask, inoculum level 109 spores/ml); clump (500 ml Erlenmeyer flask, inoculum level 108 spores/ml); pellet (750 ml baffled flask, inoculum level 108 spores/ml). All the media contained 0.05g/l of K2PO4 and were cultured at 37℃.
Effect of Morphologies on Broth Rheology and IA Production of A. terreus
The effects of morphologies on the fermentation broth rheological parameters were investigated at three points: the point of the mid-exponential growth phase, lateexponential growth phase, and end of fermentation, as summarized in Fig. 2. From the figure, the following can be observed: (i) With regard to the clump, K exhibited a 290.4% increase, while n presented 18.8% decrease during the period from the mid-exponential growth phase to lateexponential growth phase. Furthermore, the value of K increased by 29.9%, while that of n maintained constancy during the period from the late-exponential growth phase to the end of fermentation. A similar result was observed for dispersed mycelia. (ii) With regard to the pellet, the value of K increased by 17.2% from the mid-exponential growth phase to late-exponential growth phase and by 22.0% from the late-exponential growth phase to the end of fermentation. (iii) At the end of fermentation, the value of K of the dispersed mycelia was 83.8% and 844.3% higher than that of the clump (0.31 Pa·sn) and pellet (0.06 Pa·sn), respectively. The value of n of the pellet was 95.6% and 28.1% higher than that of the dispersed mycelia (0.36 s-1) and clump (0.56 s-1), respectively.
Fig. 2.Effect of morphologies on consistency index (K) (A) and flow behavior index (n) (B) at different time points. (□) The mid-exponential growth phase; () the late-exponential growth phase; and (■) the end of fermentation. Culture conditions: dispersed mycelia (500 ml Erlenmeyer flask, inoculum level 109 spores/ml); clump (500 ml Erlenmeyer flask, inoculum level 108 spores/ml); pellet (750 ml baffled flask, inoculum level 108 spores/ml). All the media contained 0.05 g/l of K2PO4 and were cultured at 37℃.
The effect of morphologies on IA production is presented in Table 1. The yield of IA on DCW and yield of glucose on DCW of the clump presented the highest values, which were 318.2% and 98.8% higher than those of the dispersed mycelia, and 45.7% and 10.6% higher than those of the pellet, respectively. Thus, it can be concluded that A. terreus growth in clump contributed to IA fermentation.
Table 1.Culture conditions: dispersed mycelia (500 ml Erlenmeyer flask, inoculum level 109 spores/ml); clump (500 ml Erlenmeyer flask, inoculum level 108 spores/ml); pellet (750 ml baffled flask, inoculum level 108 spores/ml). All the media contained 0.05 g/l of K2PO4 and were cultured at 37℃.
Effects of Adding KH2PO4 and the Fermentation Temperature on Clump Size and IA Production
The effect of adding KH2PO4 on the clump diameter and IA production is presented in Table 2. When the concentration of adding KH2PO4 was increased from 0 to 0.2 g/l, the clump diameter increase was from 0.53 to 0.75 mm. However, the yield of IA on DCW and yield of glucose on DCW were decreased by 44.7% and 36.2%, respectively. In order to provide a clear description of the effect of clump diameter on IA production and glucose consumption, the time course of IA fermentation at two nutrition conditions (0 and 0.05 g/l of KH2PO4) is illustrated in Fig. 3. It can be observed that the diameter increased during the period of rapid growth and then remained at a relatively constant value from about 24 h to the end of fermentation. Approximately 60% of IA was produced during the stationary phase. Consequently, the average diameter value during the stationary phase was calculated as being representative of a given fermentation. When 0 g/l KH2PO4 was added to the acid production medium, the clump diameter (0.53 mm) was 15.9% smaller than that of the control (0.05 g/l KH2PO4). Addition of 0.05 g/l of KH2PO4 increased the DCW but decreased the IA production and glucose consumption, resulting in the highest yield of IA on DCW of 3.27 g/g and yield of glucose on DCW of 6.57 g/g, which were 24.0% and 21.7% lower than those obtained with the addition of 0 g/l of KH2PO4, respectively.
The effect of culture temperature on the clump diameter and IA production is presented in Table 3. When the culture temperature was decreased from 37℃ to 30℃, the clump diameter decreased from 0.53 to 0.28 mm. Similarly, the yield of IA on DCW and yield of glucose on DCW decreased along with the decrease in temperature from 35℃ to 30℃.
Table 2.aThe average value of the diameter of the clump at a relatively constant phase (from about 24 h to the end of fermentation). Conditions: 500 ml Erlenmeyer flask, inoculum level 108 spores/ml, 37℃.
By using the above-mentioned experimental data, the correlation among the yield of IA on DCW, yield of glucose on DCW, and clump diameter is summarized in Fig. 4. It can be noted from the figure that the yield of IA on DCW (R2 = 0.9809) and yield of glucose on DCW (R2 = 0.9421) were closely correlated with clump diameter. The optimum clump diameter range for higher yield of IA on DCW and yield of glucose on DCW was 0.40–0.50 mm. The yield of IA on DCW and yield of glucose were 4.42 g/g and 8.38 g/g, which were 35.2% and 27.5% higher than the corresponding value of the control (0.05 g/l KH2PO4, 37℃), respectively.
Fig. 3.Time course of IA production by A. terreus at different KH2PO4 concentrations. (A) Clump diameter; (B) IA production; (C) glucose consumption; and (D) DCW. Symbol (○) represents the control with 0.05g /l of KH2PO4, whereas (■) represents no KH2PO4. Fermentation conditions: 37℃, 500 ml Erlenmeyer flask, inoculum level 108 spores/ml.
Table 3.Conditions: 500 ml Erlenmeyer flask, inoculum level 108 spores/ml, without KH2PO4.
Fig. 4.The relationships between clump diameter and (A) yield of IA on DCW and (B) yield of glucose on DCW, respectively. (A) y = 118.2395x3 - 217.6035x2 + 123.3799x - 17.6514, R2 = 0.9809; (B) y = 158.7866x3 - 219.8184x2 + 163.5855x - 20.3128, R2 = 0.9421. Fermentation conditions: 30-37℃, 500 ml Erlenmeyer flask, inoculum level 108 spores/ml, and with 0-0.2 g/l KH2PO4.
Enhanced IA Production by Controlling Clump Diameter in a 7 L Stirred Tank Bioreactor
Based on the above-mentioned results, we could obtain the highest IA production in a stirred tank bioreactor with A. terreus fermented within the optimum diameter range. The changes in morphology and IA production of A. terreus over a range of mechanical stress (agitation and aeration) were investigated. As shown in Table 4, the conditions of optimum mechanical stress were 300 rpm of agitation speed and 0.8 vvm of aeration rate. The time course of IA fermentation under the optimum condition is illustrated in Fig. 5. The clump diameter (0.45 mm) was within the optimum diameter range (0.40–0.50 mm) under the optimum condition, which led to 25.1% and 16.3% increases in the yield of IA on DCW and yield of glucose on DCW, respectively, when compared with those of the control (200 rpm, 0.4 vvm).
Table 4.Fermentation conditions: 500 ml Erlenmeyer flask, inoculum level 108 spores/ml, 35℃, without KH2PO4, and initial pH of 3.1 (not adjusted).
Fig. 5.Time course of IA production in a 7 L fermentor. Symbol (△) represents clump diameter, whereas (□), (■), and (○) represent IA production, glucose consumption, and DCW, respectively. Fermentation was achieved by incubating in 500 ml Erlenmeyer flasks, with inoculum level 108 spores/ml, 300 rpm, 0.8 vvm, 35℃, and without KH2PO4; the initial pH of 3.1 was not adjusted.
Discussion
The present study demonstrated that the inoculum level and shape of the flask had a significant influence on the formation of the three fungal morphologies. Different morphological growth forms affected the rheology of the fermentation broth and IA production. By altering the KH2PO4 concentration and culture temperature, the quantitative relationships between the yield of IA on DCW (R2 = 0.9809), yield of glucose on DCW (R2 = 0.9421), and clump diameter were developed. Furthermore, higher yield of IA on DCW and yield of glucose on DCW were achieved by controlling A. terreus morphology based on the quantitative relationship in a 7 L fermentor.
Fungal morphology is strongly influenced by medium composition and culture condition [8, 22]. The inoculum level may affect conidial aggregation, and then influence fungal morphology. Experiments with A. terreus FMME033 indicated a clear transition from clump to dispersed mycelia when the inoculum level was increased from 108 to 109 spores/ml in 500 ml Erlenmeyer flasks. The results seem to be comparable with those presented in the literature with respect to A. niger, which demonstrated that when the inoculum level was varied from 104 to 109 spores/ml, the morphology changed from pellet, to clump, to dispersed mycelia [14]. Compact pellets were formed in baffled flasks because they can provide higher shear force and higher dissolved oxygen when compared with Erlenmeyer flasks at the same rotation speed. A similar result was also reported by Teng et al. [19]. Different inoculum levels and shapes of flasks were used to develop distinctive morphologies, and growth of A. terreus in clumps was suggested to achieve high IA production. The reason for this may be the higher value of K and lower value of n induced by the dispersed mycelia (Fig. 2), which may have led to a low nutrient and oxygen supply [9]. Although the compact pellet showed the lowest K and highest n (Fig. 2), nutrient and oxygen transfer might be limited in the central part of the pellet [9]. The results based on the sensitivity of the IAproducing mechanism to the lack of oxygen have been reported by Kuenz et al. [10] and Gyamerah [5], who showed that insufficient oxygen diffusion reduced the production of IA significantly. Moreover, the maximum DCW of dispersed mycelia was 23.0% higher than that of the pellet (Table 1), which may limit mass transfer more severely. This may be the reason why the yield of IA on DCW and yield of glucose on DCW of the dispersed mycelia were lower than that of the pellet.
The clump diameter and DCW of A. terreus increased with the increase of phosphate concentration, but the yield of IA on DCW and yield of glucose on DCW decreased (Table 2). Similar changes were also observed in A. niger [15]. Therefore, it is necessary to restrict the phosphate concentration to obtain a small clump diameter and high IA yield. The results seem to be comparable to literature results with A. terreus NRRL 1960, where limiting phosphorus was very important for IA formation, and most of the IA was produced when phosphorus was depleted from the medium [16]. When 0 g/l KH2PO4 was added to the acid production medium, about 30 mg/l of phosphorus was noted in corn steep liquor powder at the start of the fermentation [25], as well as the residual phosphorus from the inoculum medium, which supported reasonable cell growth. Temperature, which is easy to control, may influence the nutritional and pH requirements for growth [13]. The present study indicated that the clump diameter decreased along with the decrease in temperature from 37℃ to 30℃, similar to that observed in Rhizopus delemar [26]. However, this finding is not in agreement with that of the study by Spohr et al. [17] on the production of α-amylase by A. oryzae, where the pellet size distribution was found to be independent of temperature.
Many studies have only focused on the qualitative relationships between morphology and production of metabolites in submerged cultures of filamentous fungi, including the growth form of A. terreus and IA production [10, 24]. In the present study, the quantitative relationships between detailed morphological forms and the production of IA in flasks were investigated. Based on the quantitative relationship, scale-up of A. terreus fermentation from shake flasks to a 7 L stirred tank bioreactor fermentor was successfully performed by manipulating the mechanical stress, which has been proved to be an effective approach to influence fungal morphology [11]. However, in order to further improve the IA production in the fermentor, a deeper understanding of the clump formation mechanism and a systematic study on the effect of different fermentation conditions on the changes in morphology are necessary.
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