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 CHEMICAL ENGINEERING TRANSACTIONS  
 

VOL. 46, 2015 

A publication of 

 
The Italian Association 

of Chemical Engineering 
Online at www.aidic.it/cet 

Guest Editors: Peiyu Ren, Yancang Li, Huiping Song 
Copyright © 2015, AIDIC Servizi S.r.l., 
ISBN 978-88-95608-37-2; ISSN 2283-9216                                                                               

Two-step Shake-static Fermentation to Enhance Cordycepin 
Production by Cordyceps militaris 

Jiapeng Tang*, Zhenqing Qian, Li Zhu 

Department of Biochemistry and Pharmacy, Institute of Nautical Medicine, Nantong University, Nantong, 226019, PR China. 
felix_elf@163.com 

Production of cordycepin by Cordyceps militaris batch fermentation was investigated under various 
fermentation styles. Two-step shake-static fermentation strategy was proposed to achieve the optimal 
cordycepin production. It can be assumed that cordycepin production is linked to the development of aerial 
hyphae and conidiophores by analyzing the results of kinetics and morphology of C. militaris fermentation. 
Massive aerial hyphae and conidiophores accumulation requires two conditions: adequate C. militaris biomass 
as an essential material foundation and the environmental condition, static fermentation in this case, which 
can induce cellular differentiation to form aerial hyphae and conidiophores. The specific mycelia growth rate 
was higher with sufficient nutrition and dissolved oxygen in shake fermentation, and the specific cordycepin 
production rate was higher in static fermentation. Under two-step shake-static fermentation, a lot of C. militaris 
cells were obtained in shake stage and the development of conidiophore was activated in static stage, 
followed by the accumulation of cordycepin. Therefore, cordycepin production reached 2.62 g/L. 

1. Introduction 

Cordycepin, an adenosine analogue, is a nucleic acid antibiotic extracted from Cordyceps militaris (Yue et al., 
2013). It has the anti-tumor, anti-leukemic, anti-metastatic, anti-bacterial, anti-viral, anti-trypanosomiasis, anti-
restenosis, immunomodulatory, and anti-inflammatory activities (Paterson, 2008). Cordycepin is synthesized 
commercially via solid state fermentation and submerged C. militaris cultivation (Das et al., 2010b). 
Considerable effort is currently focused on three aspects of cordycepin production: strain screening and 
improvement (Das et al., 2008), additives (Fan et al., 2012; Mao & Zhong, 2006; Masuda et al., 2007) and 
optimizing fermentation process (Das et al., 2010a; Mao et al., 2005; Mao & Zhong, 2004; Masuda et al., 
2011; Masuda et al., 2007; Masuda et al., 2006; Shih et al., 2007). 
In general, the secondary metabolites synthesis can be considered a non-growth-associated process. 
Because secondary metabolites are not directly required to ensure the growth of the organisms that produce 
them, these products accumulation are not relevant to cell growth. However, the simple non-growth-
associated process is not applicable in higher fungi, especially C. militaris. C. militaris mating and sexual 
cycles are often complicated, as well as its asexual reproduction and morphological differentiation (Zheng et 
al., 2011). Additionally, the different distribution of cordycepin in fruit bodies demonstrates that the capacity of 
C. militaris to produce cordycepin can be different in various cells types (Dong et al., 2013). At this point, 
cordycepin production of C. militaris was similar with ganoderic acids production of Ganoderma lucidum. 
Therefore, cordycepin production was studied based on the combination of fermentation kinetics and 
morphological change of C. militaris. 
In addition, there is the relationship between secondary metabolism and fungal development. Some 
secondary metabolites stimulate sporulation and therefore influence the development of the producing 
organism. Natural products are often produced late in fungal development, and their biosynthesis is complex. 
A common signal transduction pathway can exist to be partially responsible for tying fungal development to 
natural product biosynthesis (Calvo et al., 2002). Therefore, the relationship between cordycepin production 
and fungal development should be investigated in C. militaris fermentation. 
In this study, the course and cell morphology of various fermentation styles were compared and analyzed to 
achieve a more efficient process for cordycepin production. The specific growth rate and production rate were 

                               
 
 

 

 
   

                                                  
DOI: 10.3303/CET1546004

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Please cite this article as: Tang J.P., Qian Z.Q., Zhu L., 2015, Two-step shake-static fermentation to enhance cordycepin production by 
cordyceps militaris, Chemical Engineering Transactions, 46, 19-24  DOI:10.3303/CET1546004  

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calculated on C. militaris fermentation in order to obtain useful information for large-scale production of 
secondary metabolites by the bioprocess. 

2. Materials and methods 

2.1 Microorganism and media 

C. militaris 14014 purchased from the China Center of Industrial Culture Collection was stored at 4 °C. The 
strain was inoculated on potato–agar–dextrose (PDA) slants or plate containing 20.0 g/L glucose, 3.0 g/L 
KH2PO4, 1.5 g/L MgSO4

.7H2O, and a small amount of Vitamin B1. The slants and plates were then incubated 
at 25 °C for 7 d. The liquid medium was composed of 40 g/L glucose, 10 g/L tryptone, 6 g/L yeast extract, 0.5 
g/L MgSO4·7H2O, 0.5 g/L K2HPO4·3H2O, and 0.5 g/L KH2PO4. Approximately 50 mL of the medium was 
placed in a 250 mL flask and sterilized.  

2.2 Spore suspension preparation 

50 mL of fresh liquid medium was added into an active PDA slant from the stock culture. The spores were 
scraped using a sterilized inoculating loop, and then the medium containing spores was introduced into a 
sterile and dry 250 mL Erlenmeyer flask. The culture was incubated at 25 °C on a rotary shaker at 180 rpm for 
4 d. Liquid culture was filtered through four layers of sterile gauze into a sterile tube and centrifuged to remove 
the supernatant. The precipitate was diluted to1.0×105 cfu/mL of spore suspension with sterile water. The 
spore concentrations were quantified with a hemacytometer. 

2.3 Inoculation and culture 

Spore suspensions as inocula were added into the fresh basal medium in the shake (180 rpm) and static 
cultures. Fermentation temperature was 27 °C. All experiments were conducted in triplicate at least. 

2.4 Analytical methods 

The entire contents of the culture flask were centrifuged. The collected mycelia were then sufficiently washed 
with distilled water and dried at 110 °C in an oven until a constant dry weight was obtained. After centrifuging, 
one part of the supernatant was stored at -20 °C and later thawed for analyses of residual sugar and 
cordycepin. Glucose content of the culture was determined using 3,5-dinitryl-salicylic acid reagent. Cordycepin 
concentrations were measured using a high-performance liquid chromatograph (LC-20AD system, Shimadzu 
Corp., Japan) on a reverse phase column (5 μm Ultimate AQ-C18 column, 250 mm × 4.6 mm) (Tang et al., 
2014). 

2.5 Morphology observation 

The morphology of mycelia was observed by SEM (JSM-6510, JEOL, Japan). The cultured mycelia in the 
fermentation broth were collected using centrifugation and wased with sterile water, followed by lyophilization. 
Samples were sliced into thin sections and then gold sputtered before SEM imaging. 

3. Results and discussion 

3.1 Effect of fermentation styles on cells growth, glucose consumption, pH and cordycepin production 

As shown in Figure 1, the effects of fermentation styles on cells growth, glucose consumption, pH and 
cordycepin production are indifferent. The biomass dry weight increased rapidly at the beginning of shake 
fermentation (SHF). The average cell proliferation rate of C. militaris 14014 reached 6.79 g/L/d during the first 
three days of fermentation and maximum mycelial dry weight was about 23.78 g/L on day 5. Specific cell 
growth rate reaches 4.42-4.77 d-1 in the initial stage of shake condition (Figure 2). However, C. militaris 
mycelia on the medium surface grew very tardily in static fermentaion (STF), when exposed to the atmosphere. 
Specific cell growth rate is about 0.75 d-1, which is much lower than that of SHF. Mycelial dry weight was 
approximately 10.00 g/L on day 29.  
In addition, carbon source consumed much more quickly in SHF than STF. The result suggested that most 
glucose was utilized for cell growth in SHF. Carbon source was nearly depleted before day 5 of SHF. During 
the SHF that followed, intermediate products were completely oxidized to carbon dioxide and water through 
aerobic respiration and were not transformed into cordycepin. Figure 2 shows that specific cordycepin 
production rate reduces to zero after 7 d, indicating that cells stopped to synthetise cordycepin. Therefore, the 
cordycepin production rate was lower in SHF than STF after day 5 of fermentation. The medium pH became 
lower in STF than SHF, which meant that anaerobic respiration dominated in carborn metabolism and cells 
produced more acids (Tabak & Cooke, 1968). Carb on source was gradually used for cordycepin production in 
the later period of STF. The maximum cordycepin production of 0.51 g/L and 1.03 g/L were achieved in SHF 
and STF, respectively. 

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Figure 1: Time profiles of mycelial growth, cordycepin production, pH and glucose consumption during batch 
fermentation of C. militaris 14014 at various fermentation styles in a flask. The inoculum size of C. militaris 
14014 spore suspension was 10% v/v.  

On the basis of the above analysis, a two-step shake-static fermentation strategy was developed. SHF carried 
out for the first 4 days of fermentation, and then it was shifted to STF. When fermentation style transformed to 
STF after shaking for 4 d, cells rapidly swallowed up the dissolved oxygen in fermentation broth so that 
intracellular aerobic respiration was converted to anaerobic respiration. Even though residual sugar was zero, 
intermediates inside cells were transferred to the pathway of anaerobic respiration and then converted into 
organic acids (Tabak & Cooke, 1968), resulting in the pH decrease of fermentation broth, which accumulated 
some precursors for cordycepin synthesis. Whether the early stage of fermentation was shake culture or static 
culture, specific cordycepin synthetic rate maintained in the range of 0.002-0.005 d-1 through a saddle-shaped 
curve in the later period of fermentation (Figure 2). Moreover, the decrease of dissolved oxygen in 
fermentation broth could induce the cells differentiation (Scott & Eaton, 2008). When spores developed to 
substrate mycelia after day 7 of STF, the mass transfer resistance of nutrition and dissolved oxygen would 
occur and lead to the transformation from substrate mycelia to aerial hyphae and advanced cordycepin 
accumulation. But the hypoplasia of substrate mycelia later led to the failure to transport the nutrition to aerial 
hyphae and conidiophores, so the specific production rate decreased again to form a saddle-shaped curve. 
Similarly, lower dissolved oxygen induced substrate mycelia to extend away from air-liquid interface in day 4 of 
two-step shake-static fermentation until aerial mycelium and conidiophore was developed. Subsequently, the 
mass transfer was limit ed to lead to a saddle-shaped curve. Then, conidiophores generated conidia through 
microcycle conidiation (Kepler et al., 2012; Zheng et al., 2011). The combination of aerial hyphae, 
conidiophores and conidia formed colonies and mycelia pad (Figure 3), which was essentially similar to 
colonial morphology in repeated batch culture (Das et al., 2010b; Masuda et al., 2014). 

 

Figure 2: Specific cell growth rate and cordycepin production rate of C. militaris with various fermentation 
styles. Solid represents the specific cell growth rate and hollow represents the specific production rate. Square, 
circular and triangle represent shake, static and two-step shake-static fermentation, respectively 

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Figure 3: Colonies and mycelia pad of C. militaris in two-step shake-static fermentation.  

3.2 Morphology observation 

Due to the difference of cordycepin production in various cell types, the mycelial micromorphology of C. 
militaris was observed by SEM. Figure 4A-C show that the mycelia are thick and smooth, having many 
articulate branches under SHF. Their diameters are in the range of 2-5 μm and the gaps among the mycelia 
are small. They have the typical characteristics of substrate mycelium. However, Figure 4D-F indicates that 
the mycelia are long and thin, owning little branches under STF. Their diameters are about 1-2 μm and the 
gaps are big. They have the rough surface with many wrinkles. The mycelia possess the typical characteristics 
of aerial hyphae and conidiophores. 
Secondary metabolism is associated with fungal developmental processes (Calvo et al., 2002). According to 
the data of fermentation kinetics and mycelial morphological differentiation, the development of aerial hyphae 
and conidiophores is linked to high cordycepin production. Once cells differentiated and entered aerial 
mycelium and conidiophore stage, the cordycepin production rate reached a plateau. The aerial mycelium and 
conidiophore developed from the substrate mycelia of the biomass, so the amount of aerial mycelia and 
conidiophores essentially depended on that of biomass. The results showed that a lot of biomass accumulated 
in SHF, but then no trace of aerial hyphae and conidiophores was found because of lacking the condition, 
while low cordycepin production occurred; When inoculated with spore suspension, the total quantity of spores 
was too little. Despite aerial hyphae and conidiophores were well-developed in STF, a small quantity of 
developed aerial hyphae and conidiophores seriously affected the cordycepin accumulation; During two-step 
shake-static fermentation, a large number of biomass accumulated in the shake stage to lay a good 
foundation of aerial hyphae and conidiophores development in static stage. Aerial hyphae and conidiophores 
developed well under the condition of STF and cordycepin production reached 2.62 g/L. 
C. militaris produce cordycepin efficiently at a time that coincides with the mycelia development and 
differentiation. In C. militaris, these processes can be regulated by a common signaling pathway, like other 
fungi (Calvo et al., 2002). In the previous work, two-stage dissolved oxygen control strategy was developed for 
hyperproduction of cordycepin in submerged cultivation (Mao & Zhong, 2004). The strategy and two-step 
shake-static fermentation strategy can both be based on the hypothetic signaling pathway. The only difference 
is that the cells are hungry due to the mass transfer resistance under STF in this study. The cell starvation 
may help to improve the mycelia development and cordycepin production.  

 

Figure 4: Mycelial morphology of C. militaris on SHF and STF. 

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4. Conclusions 

The results of fermentation kinetics of Cordyceps militaris showed the difference of cell growth, development 
and cordycepin biosynthesis in SHF and STF. The mycelia grew much faster in SHF. However, STF benefitted 
cells development and cordycepin production. According to SEM observation, it was found that the substrate 
mycelia of C. militaris in STF more easily differentiated aerial hyphae and conidiophores, accompanied by the 
synthesis of a large number of cordycepin. The present study clarified the key factors in high cordycepin 
production and the relationship between cellular morphology and cordycepin accumulation. High cordycepin 
yield was linked to the mycelia development at the genetic level. The optimal cordycepin production was 
achieved in two-step shake-static fermentation owing to aerial hyphae and conidiophores development. 

Acknowledgements 

This work was supported by Natural Science Foundation of Jiangsu Province of China (BK2011392), Applied 
Research Program of Nantong City (AS2011021), Natural Science Research Program of Nantong University 
(13ZJ006) and Scientific Research Foundation for introduced talents, Nantong University. 

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