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478 
Original Article 

Biosci. J., Uberlândia, v. 32, n. 2, p. 478-485, Mar./Apr. 2016 

IMPROVEMENT IN AUREOFUSCIN PRODUCTION BY Streptomyces 

aureofuscus WITH THE ADDITION OF ACETATE AND PROPIONATE 

SODIUM 
 

MELHORIA NA PRODUÇÃO AUREOFUSCIN POR Streptomyces aureofaciens COM 
A ADIÇÃO DE ACETATO E PROPIONATO DE SÓDIO 

 

Jie WEI
1
; Guokun ZHANG

1
; Xiao ZHANG

1
; Qiuyu WANG

1 

School of Life Science, Liaoning University, Shenyang 110036, China. weijie@lnu.edu.cn 
 

ABSTRACT: Aureofuscin is an important tetraene macrolides antibiotic produced in submerged culture by 
Streptomyces aureofuscus isolated from the soil in China. In the present work, the effects of the addition of precursor on 
cell growth and the kinetics of aureofuscin production were investigated during submerged cultivation of Str. aureofuscus. 
The sodium acetate and sodium propionate are more suitable precursor than alcohol, sodium butyrate, n-propanol, n-
butanol. The addition of acetate and propionic sodium at a ratio of 5:1 at a total concentration of 1.5mg mL−1 after 24 h 
showed stimulatory effects on aureofuscin production, reaching 3.708 mg mL−1 (approximately 267% increases in 
aureofuscin production, compared with the control culture). Moreover , A further enhancement in aureofuscin production 
was achieved by cultivation in a 5-L stirred-tank bioreactor under controlled pH conditions under the above optimum 
condition. The optimal fermentation conditions were that 4L/min ventilatory capacity, 220r/min rotational speed, dissolves 
oxygen not be lower than 20%, fermentation period 84h and pH should control nearby 5.5, and the maximum yield of 
aureofuscin of 3.99 mg mL−1 was achieved after 84 h When the sodium acetate and sodium propionate were added as a 
mixture of acetate and propionate at a ratio of 5:1 and a final concentration of 1.5 mg mL−1 after 24 h cultivation. 
 

KEYWORDS: Aureofuscin. Precursor. Streptomyces aureofuscus. Antibiotic production. 
 
INTRODUCTION 

 
Aureofuscin is an important antifungal 

antibiotic produced by Streptomyces aureofuscus 
isolated from the soil in China. Its structure is 
similar to natamycin (natamycin = pimaricin). Both 
are tetraene macrolides antibiotic. Figure1 shows 

the Chemic structure of Aureofuscin  and 
Natamycin. However, aureofuscin has more 
antibacterial activity than natamycin against 
Saccharomyces cerevisiae, Aspergillus niger, 
Penicillium chrysogenum, and Fusarium. 
Aureofuscin has the chemical formula C25H37NO10, 
a molecular mass of 511(IPRS 1975). 

         
Figure 1-1. Chemic structure of Aureofuscin      Figure 1-2: Chemic structure of Natamycin 

 
Aureofuscin belongs to the polyene 

antibiotic group and the biosynthesis of the 
aureofuscin basic chain follows the biosynthesis of 
fatty acids, which is composed of the 
decarboxylative condensation of simple carboxylic 
acids (APARICIO et al 2004). Therefore, the 
addition of low-molecular weight precursors such as 
carboxylic acids and amino acids was considered to 
be an inexpensive, scalable and easy approach to 
increase the production of different antibiotics, such 
as in the case of rapamycin(CHENG YR et al 1995), 
tylosin(NGUYEN et al 1995), pneumocandin 

(Petersen et al 2001), rampolanin (BRUNATI et al 
2005), glycopeptide antibioticA40926 (JOVETIC et 
al 2008), bitespiramycin (LI ZL et al 2009), and 
natamycin (ELSAYED et al 2013). To our 
knowledge, natamycin has been extensively used as 
a food preservative. However, aureofuscin has not 
been well researched or industrially developed 
because of its low yields from fermentation since 
1975. Therefore, if the yield of aureofuscin could be 
enhanced, it could be a promising antifungal agent 
to be used industrially as a food preservative. 

Received: 18/05/15 
Accepted: 20/01/16 



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Biosci. J., Uberlândia, v. 32, n. 2, p. 478-485, Mar./Apr. 2016 

In this study, we attempt to increase the production 
of aureofuscin by adding precursors. We 
investigated the effect of concentration and adding 
time of sodium acetate, sodium propionate, sodium 
butyrate, alcohol, n-propanol on aureofuscin 
production. After full optimization of the precursor 
addition strategy, the optimal fermentation condition 
(stir speed, the kinetics of cell growth and 
aureofuscin production) was investigated to increase 
the production of aureofuscin. 
 

MATERIALS AND METHODS 

 

Microorganisms and Cultivation conditions  
Str.aureofuscus was obtained from the strain 

preservation center in Shenyang Agricultural 
University (strain numbers SYAU0709).  

Str.aureofuscus was incubated at 29◦C.  
 2×YT medium, yeast extract/malt extract liquid 
medium (YEME), and agar minimal medium (MM) 
were prepared as described. Yeast extract/amidulin 
(YSA) medium was used for aureofuscin 
fermentation (J. Wei et al 2011).  
 
Sample preparation and dry cell weight 

determination 
Sample was 10 mL fermentation broth in the 

case of bioreactor cultures, it was in the form of 
flask. All samples were taken at 72h during 
cultivation and were centrifuged at 4000 rpm for 20 
min. The supernatant was frozen at −20◦C for 
antibiotic determination, and the remaining 
centrifuged cells were washed twice using distilled 
water, followed by centrifugation. The centrifuge 

tubes were then dried to a constant weight at 80◦C to 
determine the dry cell weight. 

 
Aureofuscin bioassay and HPLC analysis (JIE 
WEI et al 2008) 

For the detection of aureofuscin, the 
maximum absorption wavelength was measured 
from 200nm to 400 nm with an ultraviolet 
spectrophotometer. To analyze aureofuscin, a 1 ml 
portion of the culture broth was extracted by adding 
9 ml of methanol, shaking vigorously, centrifuging 
at high speed (9200g,10000 r/min, 10 min), and 
saving the supernatant.  

High Performance Liquid Chromatography 
(HPLC) analysis was performed using a Waters C18 
column as the stationary phase and methanol-water-
glacial acetic acid (48:32:1, v/v) as the mobile 
phase. The flow rate was 1.0 ml/min, UV 
wavelengh at 302.5 nm. A known, pure sample of 
aureofuscin was used as the internal standard. 
 

RESULTS AND DISCUSSION 

 

Effect of the different addition on aureofuscin 

production 

In this experiment, six parallel cultivations 
were conducted to investigate the effect of the 
different addition on aureofuscin production. The 
sodium acetate, sodium propionate, sodium 
butyrate, alcohol, n-propanol, n-butanol were added 
separately at the beginning of the cultivation time at 
concentrations 0.5mg mL−1. Figure2 indicates that 
aureofuscin production increased upon 
supplementation of the fermentation medium with 
sodium acetate or sodium propionate.  

 
Figure 2. Effect of different addition on aureofuscin production 
 

The maximal aureofuscin production of 
2.133 mg mL−1 was achieved in sodium propionate 
supplemented culture. The addition of acetate to the 
fermentation medium also showed a stimulatory 

effect on aureofuscin production. The maximal 
aureofuscin production of 2.065 mg mL−1was 
obtained. On the other hand, the stimulatory effect 
of butyrate and alcohol on volumetric aureofuscin 



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production was much lower compared with acetate 
and propionate. The specific aureofuscin production 
was lower for n-propanol and n-butanol than the 
control. Based on these results, the addition of 
sodium acetate or sodium propionate to the 
fermentation medium at a low concentration of 
0.5mg mL−1 was chosen as the best precursors for 
aureofuscin production in the subsequent 
experiments. 
 

Effect of the addition concentrations on 

aureofuscin production 
To better understand the stimulatory effect 

of different carboxylic acids on aureofuscin 
production, the antibiotic-specific production yields 
are reported in Figure 3. As shown, the yield of 
aureofuscin production increased gradually by 

increasing either sodium acetate or sodium 
propionate concentrations in the culture from 0.5 to 
3 mg mL−1 and decreased thereafter. The increase in 
aureofuscin production in acetate- and propionate-
supplemented cultures was not related to the change 
in the biomass but to the increased cell productivity. 
The maximal values of aureofuscin prouction of 
3.125 mg mL−1 and 3.247 mg mL−1 in cultures 
supplemented with 1.5 mg mL−1 sodium acetate and 
sodium propionate, respectively, were higher than 
those reported in previously published work using 
the same strain in batch culture under optimal 
cultivation conditions in medium without carboxylic 
acid addition（2.94 mg mL−1 and 2.897 mg mL−1）
(WANG HUA et al 2007; JIE WEI et al 2009).  

 

 
Figure 3. Effect of the addition concentrations of sodium acetate and sodium propionate on aureofuscin 

production 
 
Addition at different sodium acetate: sodium 

propionate ratios 

Experiments were conducted to investigate 
the effect of concomitant addition of acetate and 
propionate at different ratios (sodium acetate: 
sodium propionate ratios ranging from 1:9 to 9:1). 
The concentration of total acetate and propionate 
supplemented for all ratios used was 1.5 mg mL−1. 
As shown in Figure4, cell growth decreased 
gradually when the acetate ratio in the mixture was 
increased from 1:9 to 9:1. On the other hand, the 
effectiveness of acetate and propionate 
supplementation on aureofuscin production was 
more pronounced at all applied ratios when a 
mixture was used compared with single acetate and 
propionate experiments. The maximal aureo fuscin 

production of 3.575 mg mL−1was achieved in 
culture supplemented with sodium acetate: sodium 
propionate at a ratio of 5:1. This value was higher 
than the control culture by approximately 157% and 
was also higher than in cultures individually 
supplemented with acetate or propionate by 
approximately 14% and 9.9%, respectively.  

The observed stimulatory effects of the 
addition of a carboxylic acid mixture of acetic and 
propionic acids at a ratio of 7:1 were also reported 
in the previous study of Elsayed Ahmed et al.,in 
which acetate-propionate increased natamycin 
production in a submerged culture of Str. natalensis 
by approximately 150% (3.98 g L−1)when added to 
the production medium at a concentration of 2 g L−1. 

 



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Figure 4. Effect of different sodium acetate : sodium propionate ratios on cell growth and aureofuscin 

production by Str. aureofuscus in shake-flask cultivation.  
(Both acetate-propionate addition were added simultaneously as a mixture to a final concentration of 1.5 mg 
mL−1at the beginning of the cultivation time before inoculation.) 
 
Effect of the addition time of acetate and 

propionate on aureofuscin production 
In addition to the effect of the ratio of 

acetate: propionate ratios on aureofuscin production, 
the time of addition also played a significant role in 
this enhancement effect. The maximal yield of 
aureofuscin production was achieved when sodium 
acetate and sodium propionate (ratio 5:1) were 
added at the beginning or during the first 24 h of 
cultivation. If sodium acetate and sodium propionate 
were added after 72 h (during the late exponential 
growth phase-early stationary phase), the positive 

effect of the addition of acetate and propionate on 
aureofuscin biosynthesis was almost negligible 
(Figure 5). The maximal aureofuscin production of 
3.708 mg mL−1 was achieved when the acetate-
propionate mixture was added after 12h. However, 
cell growth was slightly influenced by the addition 
of sodium acetate-propionate. It was clearly 
observed that the earlier the addition time, the 
higher the negative effect on biomass production. 
Once cells entered the stationary phase (after 72 h), 
no effect of acetate-propionate mixture on biomass 
was observed.  

 

 
Figure 5. Effect of addition time on cell growth and aureofuscin production by Str. aureofuscus in shake-flask 

cultivation. (The sodium acetate and sodium propionate were added as a mixture of acetate and 
propionate at a ratio of 5:1 and a final concentration of 1.5 mg mL−1.) 

 
The results also showed that to achieve the 

stimulatory effect of acetate-propionate mixture, 
they should be added to the cultivation medium 

during the first 24h of cultivation. This maybe 
because the aureofuscin biosynthesis in this strain 
started during the exponential growth phase parallel 



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to cell growth. This was attributed to the fact that 
propionic acid needs to be converted into propionyl-
CoA to act as a precursor for polyene ring synthesis. 
The enzyme system controlling this step is more 
active during the exponential growth phase (JING K 
et al 2011; BIBB MJ 2005; GIL; CAMPELO DIEZ 
2003; MARTIN JF; MCDANIEL LE 1976). 
 

Aureofuscin production during batch cultivation 

in a 5-Lstirred-tank bioreactor with and without 

sodium acetate-propionate addition 

Based on the above studies, cultivations 
were transferred to bioreactor level to investigate 

the possibility of industrialization of this process. 
Medium composition and cultivation conditions 
were the same as in shake flasks. The pH of the 
culture was controlled at 7.2 at the beginning by the 
addition of NaOH to the culture medium. Figure 6 
shows cell growth, aureofuscin production, pH 
value, dissolved oxygen (DO) and reducing sugar 
(%) in culture medium in a 5-L bioreactor. During 
cultivation without sodium acetate-propionate 
addition, the maximal cell dry weight (CDW) was 
32 mg mL−1. This value was higher than the biomass 
obtained in sodium acetate-propionate supplemented 
culture by approximately 45%.  

 
Figure 6. Kinetics of cell growth and aureofuscin production by Str. aureofuscus in a 5-L bioreactor (working 

volume 3 L, agitation 220 rpm, aeration 1 v v−1min−1, temp.29◦C) with and without sodium acetate-
propionate. (Closed and open symbols correspond to results obtained in cultivations without and with 
sodium acetate-propionate addition, respectively. The sodium acetate and sodium propionate were 
added as a mixture of acetate and propionate at a ratio of 5:1 and a final concentration of 1.5 mg mL−1 

after 24 h cultivation.).  



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The maximal value of aureofuscin in 
acetate-propionate supplemented culture was 3.99 
mg mL−1 after 84 h (approximately 183% higher 
than the control culture). The increase in 
aureofuscin production was directly related to 
higher cell productivity in the sodium acetate-
propionate supplemented culture. However, the 
changes in the pH in both cultures were similar. The 
pH value decreased gradually from 7.2 to 
approximately 5.2 during the first 48h of cultivation 
time and increased again gradually to neutral pH 
after 120 h. During the growth phase, the pH drop as 
a result of excretion of TCA organic acids such as 
pyruvic ,α- ketoglutaric and lactic acids in low 
concentration. The excess carbon in medium could 
be used to produce organic acids if not oxidized 
aerobically to CO2 for energy production (El-
Enshasy et al 2003,2008; Ayar-Kayali H and 
Tarhuan L 2006). In the subsequent incubation 
period, the pH increased gradually as a result of the 
decrease of cell growth and the increase in 
aureofuscin production. 

In both cultures, the reducing sugar 
concentration in the bioreactor decreased at a faster 
rate and the reducing sugar was completely 
consumed after 84 h. This was because bioreactor 
cultivation provides better oxygen availability in the 
cultivation vessel due to the continuous aeration and 
better agitation; this increased oxygen availability is 
positively reflected on the physiological activity of 
aerobic microorganisms. The higher cell metabolic 
activities led to higher cell growth and antibiotic 
production rates. In general, the changes in 
dissolved oxygen DO in both cultures were similar, 
decreasing successively during the exponential 
growth phase (the first 72h of cultivation), 
increasing gradually thereafter and reaching 
approximately 85% saturation by the end of the 
cultivation.  
 

 
 

From the obtained results, we infer that the 
addition of a mixture of acetate and propionate 
sodium at a ratio of 5:1 in a total concentration of 
1.5 mg mL−1 at the beginning 24h of the cultivation 
is an easily applicable and inexpensive strategy to 
increase aureofuscin production in submerged 
culture by Str.aureofuscus. This approach could also 
be scalable for large-scale production of aureofuscin 
as it also showed higher aureofuscin yields in small-
scale bioreactor culture. Production of other polyene 
antibiotics, which share the same pathway of 
polyene ring synthesis via the condensation of short-
chain carboxylic acids, could also be improved 
through the addition of a short-chain carboxylic acid 
mixture as shown in this research. To the best of our 
knowledge, this is the first report using an acetate-
propionate mixture as a precursor to enhance 
aureofuscin production in Str.aureofuscus at both 
the shake-flask and bioreactor levels. 
 

Significance and Impact 
The production of aureofuscin is very low in 

the wild-type strain. We attempt to increase the 
production of aureofuscin with adding precursors. 
To our knowledge, this approach has not been 
attempted in S. aureofuscus before. 
 
ACKNOWLEDGEMENTS 

 
This work was supported by grants from 

Science and Technology Government Department 
Fund in Liaoning province (Grant No.L2011008; 
UPRP20140428 ), the National Natural Science 
Foundation of China, Liaoning planning office of 
philosophy and social science Foundation of 
China(Grant No.L15BJY029) and the Foundation of 
Ocean and fishery hall in Liaoning province (Grant 
No.201407 )of China.  
 

Conflict of Interest 

There is no potential conflict of interest to 
declare. 

 
 

RESUMO: Aureofuscin is an important tetraene macrolides antibiotic produced in submerged culture by 
Streptomyces aureofuscus isolated from the soil in China. In the present work, the effects of the addition of precursor on 
cell growth and the kinetics of aureofuscin production were investigated during submerged cultivation of Str. aureofuscus. 
The sodium acetate and sodium propionate are more suitable precursor than alcohol, sodium butyrate, n-propanol, n-
butanol. The addition of acetate and propionic sodium at a ratio of 5:1 at a total concentration of 1.5mg mL−1 after 24 h 
showed stimulatory effects on aureofuscin production, reaching 3.708 mg mL−1 (approximately 267% increases in 
aureofuscin production, compared with the control culture). Moreover , A further enhancement in aureofuscin production 
was achieved by cultivation in a 5-L stirred-tank bioreactor under controlled pH conditions under the above optimum 
condition. The optimal fermentation conditions were that 4L/min ventilatory capacity, 220r/min rotational speed, dissolves 
oxygen not be lower than 20%, fermentation period 84h and pH should control nearby 5.5, and the maximum yield of 
aureofuscin of 3.99 mg mL−1 was achieved after 84 h When the sodium acetate and sodium propionate were added as a 
mixture of acetate and propionate at a ratio of 5:1 and a final concentration of 1.5 mg mL−1 after 24 h cultivation. 



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Biosci. J., Uberlândia, v. 32, n. 2, p. 478-485, Mar./Apr. 2016 

 
PALAVRAS-CHAVE: Aureofuscin. Precursor. Streptomyces aureofuscus. Antibiotic production. 

 
 
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