Canadian Journal of Applied Sciences


ISSN: 1925-7430
Short Key Title: Can J App Sci
DOI: http://dx.doi.org/10.21065/19257430
Start Year: 2011

GAMMA RAYS MUTAGENESIS OF ASPERGILLUS NIGER FOR HYPERPRODUCTION OF MUTAROTASE
Modasrah Mazhar
1 Department of Chemistry and Biochemistry, Faculty of Sciences, University of Agriculture, Faisalabad- 38040, Pakistan. 2 Department of Food Science and Nutrition, College of Agricultural and Marine Sciences, Sultan Qaboos University, P. O. Box 34, PC 123, Al-Khoud, Muscat, Oman. 3 Department of Pharmacology, Faculty of Pharmacy, University of Sargodha, Sargodha, Pakistan.
Keywords: Aspergillus niger, Gamma rays, Mutagenesis, Hyperproduction of mutarotase
Abstract

Pure culture of wild type of Aspergillus niger was subjected to gamma rays mutagenesis at different dose rates (40 to 120 k.Rads). The mutant strains of Aspergillus niger were isolated and selected by random screening method. The selected mutant derived strains were compared with parent type of Aspergillus niger for enhanced production potential of mutarotase. A mutant strain of Aspergillus niger with maximum production potential of mutarotase was finally selected. The enzyme activity of wild type strain was 4.33 U/mL whereas the mutant derived strain showed significantly higher enzyme activity (22.0 U/mL). It is concluded that gamma irradiation of Aspergillus niger can be used for hyperproduction of mutarotase for its ultimate use in clinical diagnostic kits.

Article Information

Identifiers and Pagination:
Year:2012
Volume:2
First Page:24
Last Page:30
Publisher Id:1925-7430.2:1.2012
Article History:
Received:June 17, 2012
Accepted:August 27, 2012
Collection year:2012
First Published:October 1, 2012

INTRODUCTION

Mutarotase (aldose-1-epimerase) is a key enzyme of carbohydrate metabolism that catalyzes the inter-conversion of a- into b-anomers of hexoses such as glucose and galactose [1]. It allows the rapid conversion of a-D-glucose to ß-D-glucose. The enzyme is a monomer with molecular weight of 40,000 kDa and works at a broad pH range of 4-8 [2]. However, the optimum pH for its maximum activity is 7.4 at 40-43 °C [3]. The specific activity of mutarotase was found to be 1.5 times higher in the nuclei (122 U/g dry weight) than that in the cytoplasm (80 U/g dry weight) when isolated with non-aqueous solvents. It is suggested that mutarotase may be involved in the metabolism of D-glucose in the nuclei [4]. The major sources used for the production of mutarotase are: Penicillinum notatum, Escherichia coli [2] and Aspergillus niger [5].

The capacity of filamentous fungi is one of the key features in considering them as a host for producing higher value recombinant therapeutic proteins [6]. Toyoda et al. (1983) reported the activity and specific activity of crude rat kidney mutarotase as 6.05 U/mg and 0.57 U/mg, respectively [3]. Zia (2002) reported that the activity and specific activity of crude bovine cortex was 0.529 U/mL and 0.227 U/mg, respectively [7]. Varalakshmi et al. (2009) screened five fungal isolates for the production of a-amylase using both solid-state and submerged fermentation [8]. They observed that the best amylase producer among them was Aspergillus niger JGI 24 strain, which yielded the maximum enzyme production by solid-state fermentation (SSF) on wheat bran. Further attempts to enhance the enzyme production by UV induced mutagenesis showed that the survival rate decreased with increase in duration of UV exposure. The partial purification of the enzyme using ammonium sulphate fractionation resulted in 1.49 fold increase in the enzyme activity. Gamma rays have been used for the mutagenesis of Aspergillus niger for hyperproduction of amylase as well as for industrial enzyme fermentation [9, 10]. However little is known about their effects on the hyperproduction of mutarotase.  The present study was conducted to investigate the impact of gamma rays mutagenesis of Aspergillus niger to obtain mutants with hyper-production of mutarotase.

 

MATERIALS AND METHODS

The study was conducted in the Enzyme Research Laboratory, Department of Chemistry and Biochemistry, University of Agriculture, Faisalabad, Pakistan. The test microorganism used in the study was wild type of Aspergillus niger [11]. The stock culture was maintained on potato dextrose agar (PDA) media (containing potato starch 2.0g, glucose 2.0g, agar 2.0g, urea 0.3g, ZnSO4.7H2O 0.001g, KH2PO4 0.008g, KCl 0.015g, MgSO4.7H2O 0.05g, in 100 ml medium). The pH of the media was adjusted at 4.0 with 1M HCl /1M NaOH solution.

Strain improvement technique

Mutagenesis was carried out using gamma rays produced from Cobalt-60 (Co60) as a source of gamma radiation. Vogel’s media (KH2PO4 0.5g, NH4NO3 0.2g, (NH4)2SO4 0.4g, MgSO4 0.02g, peptone 0.1g, trisodium citrate 0.5g, yeast extract 0.2g, glucose 50% (w/v), in 100 ml of media), having pH 5.5, was prepared and spores of Aspergillus niger were transferred with the help of a syringe in the flaks containing Vogel’s media. These flasks were kept on rotary shaker at 150 rpm at 30°C for 72 hours and the growth was confirmed by slide test.

Selection of potential doses for mutation

Five different doses of gamma radiation were selected, which were 40, 60, 80, 100, and 120 k.Rad (0.4 to 1.2 kGy). As the impact of dose depends on time, so 40, 60, 80, 100 and 120 k.Rads treated samples were collected after, 1, 2, 3 and 4 days. After treating spores with mutagen, 10 fold dilutions of spores were spread on PDA plates and kept in an incubator for 72 hours. After the corresponding time period, the colonies were counted and the survival curve was drawn. Colonies were restricted with Triton X-100 (2%), used in PDA media. 2-deoxy-D-glucose was used as a selective marker in PDA media, which is a structural analogue of glucose, for the selection of hyper-producing mutant strains.

Mutarotase Enzyme Assay

Spore suspension was prepared by mixing the plate culture with 5ml water. Two ml of each spore suspension was seeded into 100 ml of fermentation media having pH 6.0 (sucrose 3g, potato starch 5g, yeast extract 0.2g, NaNO3 0.2g, MgSO4.H2O 0.05g, CaCl2 1 g in 100 ml of media). These flasks were incubated on rotary shaker at 30°C for 24 hours. Growth of the fermentation media was homogenized, centrifuged and the supernatant was used as enzyme sample.

At time zero, 0.1 ml of enzyme solution was added into 9.9 ml of EDTA buffer and then exactly 100 mg of a-D-glucose was rapidly dissolved in this mixture. The rotation was determined at 1 minute intervals for 10 minutes and then after 5 minutes interval until 30 minutes and lastly at 15 minutes interval until its rotation became constant [7]. The enzyme activity was calculated and compared with the activity of wild type strain of Aspergillus niger. The activity was calculated from the standard mutarotase curve prepared by adding fixed amounts of alpha-D-glucose (Fig. 1). The data so collected was subjected to statistical analysis and the mean values for native wild type and mutagenized strains were compared [12].

 

RESULTS AND DISCUSSION

The ?-rays induced mutagenesis of pure wild type Aspergillus niger was carried out to obtain the mutant strains for hyperproduction of mutarotase.

Formation of Kill curve

Initially a kill curve was prepared using gamma radiation using Co60 as a source of mutagenesis. An optimum gamma-ray dose was calculated at which 80% killing or alternatively 20% survival was obtained. The results are shown in Table-1.

 

 

 

 

            

                                                                       

 

 

 

Fig.1 Kill curve for Aspergillus niger spores exposed to ?-rays

Mutants of A. awamori were isolated with enhanced production of extra-cellular xylanase and b- xylosidase by using NMT chemical mutagen as reported by Smith and Wood (1991)13 and a 90% kill rate from the spore suspension was obtained [13]. The present study however, reports the effect of gamma rays as physical mutagen on pure wild Aspergillus niger for the hyperproduction of mutarotase. The curve used is shown in Fig.1. Usami et al., (2001)14 carried out an investigation to obtain high citric acid yield from A. niger by Co60 gamma irradiation [14]. The spore suspensions were exposed to various doses ranging from 1.75 x 104 to 21.0 x 104 k.Rad and the survival rate and mutation rate were measured. When each sample was subjected to an irradiation dose of 10 x 104 k.Rad or more, the survival rate was less than 4% and the mutation rate was about 17%. The proportion of repressed sporulation types to all mutation rates increased after nitrogen mustard treatment along with UV irradiations.

Table1: Evaluation of Dose related mutagenic effects of Gamma Rays

Sr. No.

Dose

(k.Rad)

Survival Rate (%age)

Mutagenic Rate (%age)

1.       

1.75 x 104

80

0.5

2.       

3.50 x 104

50

3.0

3.       

7.00 x 104

20

10

4.       

10.50 x 104

4

17

5.       

13.50 x 104

3.8

17.2

6.       

17.00 x 104

3.5

17.5

7.       

20.50 x 104

3.3

18.5

8.       

24.00 x 104

3.0

20

 

 

Table 2 Comparison of relative increase Mutarotase enzyme activity & specific activity in different studies

Enzyme Activity

Zia, (2002)

Toyoda et al., (1983)

Rodrigues et al., (2009)

Xiong et al., (2004)

*Present Study

 

Native

Mutant

Native

Mutant

Native

Mutant

Native

Mutant

Native

Mutant

Activity (IU)

 

.529 (38% rise)

-

6.05

-

5.24

-

4.78

-

4.33

22.02*

Specific Activity

(U/mg)

0.227

-

0.570

-

.260

-

0.42

-

0.391

2.00*

%age increase

40%

-

32%

-

37%

-

43.3

-

19.7*

19.55

*This work has been carried out first time under local conditions

 

Selection of Aspergillus niger mutants

After mutagenesis, the dilutions were made and 0.1mL of that was placed on PDA media and the numbers of colonies were restricted to 30 or less. The use of triton X-100 (2%) was found to be the best for colony restriction and clearance. Triton X-100 at 0.01% has already been used to limit the colony size, to facilitate the screening and isolation of mutants of Trichderma reesei enhanced cellulase production [15]. In the present study 2% triton X-100 proved to be optimum for colony restriction whereas 0.1% sodium taruroglycocholate was used as colony growth restrictor, for hyper xylanolytic mutant of Fusarium oxysporum [16].

Triton X-100 (2%) was used to restrict the colonies to merge with each other and to obtain colonies of A. niger in reasonable sizes which could be isolated easily. Valuable results were obtained by using triton X-100 as colony restrictor although the difference of microorganism was significant yet, it was successful. In the present study, it was found that maximum utilizable dose of mutagenic rays was 7 x 104 k.Rad having 20% survival and 10% mutagenic rate. The results are shown in Table-I. In order to produce the depressed mutants for enzyme production, 2-deoxy D-glucose was used at 1mg/mL concentration. The ?-rays treated spores were spread on PDA plate with 2-deoxy D-glucose. All the selected mutants along with wild type of Aspergillus niger were used for the hyperproduction of enzyme mutarotase. Shaker flasks carrying 3% sucrose as substrate in 100mL of fermentation medium were inoculated with 2mL of spore suspensions from the selected potential mutant strains. These were kept in rotary shaker at a speed of 120 rpm at 30oC for 24 hours.

Mutarotase Activity:

The mutarotase activity of pure wild type of Aspergillus niger was 4.33 U/ml whereas the mutant derived strain obtained in this study showed 22.02 U/ml. The specific rotation of the enzyme was 57° with 225 mM of a-D-glucose concentration. The time related mutarotase activity of Aspergillus niger is shown in Fig. 1. This concentration of a-D-glucose was determined by the standard curve of a-D-glucose that was plotted between specific rotation and a-D-glucose concentration. The activity of the mutant derived strain was greater than that of wild type strain because of mutation.

Toyoda et al., (1983)3 reported the activity and specific activity of crude rat kidney mutarotase as 6.05U/mL and 0.57U/mg, respectively [3]. While another study by Zia (2002)7 reported the activity and specific activity of crude bovine cortex as 0.529U/mL and 0.227U/mg, respectively [7]. Both of these studies reported lesser activities than observed in the present study. The major reason of such a difference may be due to the microbial source and its induced mutagenesis for enhanced production. Xiong et al. (2004)17 developed a very efficient method combined with U.V. irradiation and the nitroso-guanidine method, selection of biochemical mutants resistant to metabolic inhibitors (2-deoxy-D-glucose, antimycin A, sodium ortho-vanadate and sodium azide) for improvement of ribonuclease production by A. niger [17]. The most active strain (A. niger SA- 1320 strain) resistant to sodium azide was obtained, which had 43.3% increase in RNase production in comparison with the parent strain. Rodrigues et al. (2009)18 conducted the production of citric acid (CA) through a careful strain selection process by means of physical and chemical optimization and mutation [18]. The best results (445.4 g of CA/kg of Crude Product (CP)) were obtained with sugarcane molasses and 4% methanol (v/w). The mutagenesis induction of A. niger LPB-BC strain was performed with UV irradiation. Eleven mutant strains were tested in Solid State Ferment (SSF) where two mutants showed a higher CA production when compared to the parental strain. A. niger LPB B3 strain produced 537.6 g of CA/kg of CP on the 6th day of fermentation, while A. niger LPB B6 strain produced 616.5 g of CA/kg of CP on the 4th day of fermentation, representing a 19.5% and 37% gain, respectively.

There was 84% increase in the production of mutarotase from gamma rays induced mutagenesis; the most active mutant strain (A. niger M-4) was isolated on 2-deoxy- D-glucose selective medium). The divergence is due to the difference in the product and mutagen. Moreover, the selective marker is also different. The activity of mutarotase of crude Aspergillus niger mutant resulted 22.0 U/mL. The specific rotation of enzyme was 57° with 225 mM of a-D-glucose concentration. This concentration of a-D-glucose was determined by the standard curve of a-D-glucose that was plotted between specific rotation and a-D-glucose concentration. The activity of mutant strain was greater than the wild type due to mutation. In the present research work, triton X-100 (2%) was used in PDA plates as colony restrictor, which proved to be the best colony restrictor for fungal growth. The comparison between different studies regarding the hyperproduction of mutarotase is shown in Table 2. The hyper-produced mutants of Aspergillus niger for mutarotase were isolated on the selective medium having 2-deoxy D-glucose as a marker and showed a 5.11 fold increase in production as compared to wild type. The difference is only due to change in the product and mutagen used. Gamma rays are strongly mutagenic and cause living cell mutation. So an attempt was made to get the advantage of mutagenesis obtaining mutant isolates with high yield of mutarotase. Overall the results of the present study showed 5.11 fold (84%) increase in mutarotase activity in mutant derived strain of A. niger as compared to pure wild type. This divergence may be attributed to differences in product and change in the radiation source and therefore such results are in line with the previously reported results [3, 8].

 

CONCLUSION:

In conclusion, the mutant derived strain of Aspergillus niger obtained in the present study represents a rich source of mutarotase, so its application in the development of diagnostic kits or biosensors would be of great value in the field of medical sciences.

 

REFERENCES

 

1        Timson and R. J. Reece. 2003. Identification and characterization of human aldose-1-epimerase. FEBS Letters, 543(1-3): 21-24.

2        Bailey, T.M., P.H. Fishman and P.G. Pentcher. 1969. Isolation and characterization of mutarotase from bovine kidney cortex. J. Bio. Chem., 244 (4): 781-788.

3        Toyoda, Y., I. Miwa and J. Okuda. 1983. Multiple forms of mutarotases from the kidney, liver and small intestine of rats. Purification, properties, subcellular localization and developmental changes. J. Biochem. 94 (2): 421-431.

4        Baba, S., Y. Ariomoto, D. Yoshikawa, Y. Toyoda, I. Miwa and J. Okuda. 1979. The localization of mutarotase in rat kidney. Experientia 35: 1094-1097.

5        Kinoshita, S., K. Kadota and H. Taguch. 1981. Purification and properties of Aldose-1-epimerase from Aspergillus niger. Biochem. Biophys. Acta, 662 (2): 285-290.

6        Davies, R.W. 1991. Applied molecular genetic of fungi (Peberdy, J.F; Caten. C.E; Ogden, J.E. and Bennett, J.W. Eds.) Cambridge University Press. Elsevier Applied Science, PP: 103-117.Amsterdam, New York, USA.

7        Zia, M.A. 2002. Standardization of conditions for glucose estimation using indigenously   purified enzymes. M.Phil Thesis, Department of Chemistry, Univ. Agriculture, Faisalabad- Pakistan.

8        Varalakshmi K.N., B.S. Kumudini .,B.N. Nandini ., J. Solomon.,R. Suhas., B.Mahesh and AP Kavitha. 2009. Production and characterization of alpha-amylase from Aspergillus niger JGI 24 isolated in Bangalore. Polish J Microbiol. 58(1): 29-36.

9        Shafique, S, Bajwa, R., Shafique, S. 2010. Mutagenesis and genetic characterization of amylolytic Aspergillus niger. Natural Product Research, 24: 1104–1114

10    Awan, M.S., Tabbasam, N., Ayub, N., Babar, M.E., Rahman, M.U., Rana, S.M., Rajoka, M.I. 2011. Gamma radiation induced mutagenesis in Aspergillus niger to enhance its microbial fermentation activity for industrial enzyme production. Mol Biol Rep., 38: 1367–1374.

11    Hamid, H. M., K. Rehman, M. A. Zia and M. Asghar.2003. Optimizations of various parameters for the production of glucose oxidase from rice polishing using Aspergillus niger. Biotechnol. 2(1): 1-7.

12    Steel RGD, JH Torrie, and DA Dicky. 1996. Principles and procedures of Statistics. A Biometrical Approach. 3rd Edition, McGraw Hill Companies, New York, USA.

13    Smith, D. C. and T. M. Wood. 1991. Isolation of mutant Aspergillus awamori with enhanced production of extracellular xylanase and ß-xylosidase. World J. Microbiol. Biotechnol. 7: 343-354.

14    Usami, S., K. Yoshioni, and N. Taketomi. 2001. Induced mutation of Aspergillus niger by gamma ray irradiation. J. Microbiol. And Biotechnol. 66 : 1335-1338.

15    Gadgil, N. J., H. F. Daginawala, T. Chakrabarti and P. Khana. 1995. Enhanced cellulase production by a mutant of Trichoderma reesei. Enzyme and Microbiol. Technol.17: 942-946.

16    Kumar, W. M., R. C. Kuhad and A. Singh. 1995. Xylanase production by a hyperxylanolytic mutant of Fusarium oxysporum .J. Enzyme Microbiol. Technol. 17(6): 551-553.

17    Xiong, Y.H., J.Z. Liu, H.Y. Song, L.P. Weng and L.N. Ji. 2004. Selection of biochemical mutants of Aspergillus niger with enhanced extracellular ribonuclease production. World J. Microbiol. Biotechnol. 20(2): 203-206.

18    Rodrigues, C., L.P.Vandenberghe., J.Teodoro, A. Pandey and C.R. Soccol. 2009.  Improvement on citric acid production in solid-state fermentation by Aspergillus niger LPB BC mutant using citric pulp. Applied Biochemistry and Biotechnology 158: 72-87.


© 2016 The Author(s). This open access article is distributed under a Creative Commons Attribution (CC-BY) 4.0 license. You are free to: Share — copy and redistribute the material in any medium or format Adapt — remix, transform, and build upon the material for any purpose, even commercially. The licensor cannot revoke these freedoms as long as you follow the license terms. Under the following terms: Attribution — You must give appropriate credit, provide a link to the license, and indicate if changes were made. You may do so in any reasonable manner, but not in any way that suggests the licensor endorses you or your use. No additional restrictions You may not apply legal terms or technological measures that legally restrict others from doing anything the license permits
Editor in Chief
Xianghui Qi (PhD)
Jiangsu University, Zhenjiang, China

Bibliography

Dr. Xianghui Qi is working as Professor in the School of Food & Biological Engineering, Jiangsu University, China. His research interests: Biosynthesis of high value-added chemicals by microbes and engineered strains; Discovery of novel genes, enzymes and new strains; Rational & Irrational design of microbial enzymes; Isolation, identification and evolution of microbes; Metabolic engineering & Pathway engineering of functional microbes, and biotransformation; Metabolic regulation based on the research of microbial omics; Application of high value-added products including functional sugar alcohols by biosynthesis and biotransformation based on microbial engineered strains.

Journal Highlights

Subject & Scope
  • Biochemistry and Biotechnology
  • Bioinformatics and Biometric
  • Chemical Technology
  • Dentistry and Hygiene
  • Environmental Health, Safety and Allied Sciences
  • Food and Nutrition
  • Health Management
  • Medical Sciences
  • Molecular/ Cellular Biology
  • Pharmaceutical Sciences
  • Pharmacotherapy
  • Theoretical Models (health, life and clinical practice)
  • Veterinary, Fishery and Animal Biology

Consortium Publisher is an online publisher that enjoys global presence with International Journals

Follow Us

©2009 - 2019 Consortium Publisher Canada

Contact Info

6252 Lisgar Dr Mississauga Ontario L5N7V2 Canada
+1 (647) 526-0885
office@consortiumpublisher.ca
http://www.consortiumpublisher.ca/