![M. Sunitha, / Journal of Pharmacreations Vol-1(4) 2014 [97-102]
97
Pharmacreations |Vol. 1 | Issue 4 | Oct- Dec -2014
Journal Home page: www.pharmacreations.com
Review article Open Access
Strain improvement studies on L-aspaginase producing bacteria
M. Sunitha*
Department of pharmaceutical sciences, andhra university, visakhapatnam-530003, india.
* Corresponding author: M. Sunitha
E-mail id: suneet-bio@rediffmail.com
ABSTRACT
In the present study, we report the strain improvement studies on L-asparaginase producing a newly isolated
Bacillus cereus MS-6. The UV induced mutant MUV-9 showed highest L-asparaginase activity (24.98 IU/ml). It
was 7.84 fold of the parent strain. Further mutagenesis of this strain by NTG treatment could yield few mutants.
Examination of L-asparaginase activity of the selected mutants showed that the mutant MNTG-7 showed further
improvement in L-asparaginase activity (38.06 IU/ml) (Fig. 4.4). It was12.04 fold more of the wild strain (MS-6,
3.16). The EMS mutants (from parent MNTG-7) have not much difference between parent strain and EMS mutants.
Keywords: L-Asparginase, bacillus cereus, MS-6 and mutants
INTRODUCTION
A major potential therapeutic application of enzymes
is in the treatment of cancer. Asparagianse has
proved to be particularly promising in the treatment
of acute lympho-cytic leukaemia. Tumour cells are
deficient in aspartate-ammonia ligase activity, which
restricts their ability to synthesize the normally non-
essential amino acid, L-asparagine. Therefore they
are forced to extract it from body fluids. The action
of Asparaginase does not affect the functioning of
normal cells, which are able to synthesize enough for
their own requirements, but reduce the free
exogenous concentration, and so induce a state of
fatal starvation in the susceptible tumour cells (Sabu,
A, 2003). A 60% incidence of complete remission
has been reported in a study of almost 6,000 cases of
acute lymphocytic leukaemia. This enzyme is
administered intravenously.
L-asparagine+H2O L-aspartate+NH3
Strain improvement is an essential part of process
development for fermentation products. Developed
strains can reduce the costs with increased
productivity and can possess some specialized
desirable characteristics. Such improved strains can
be achieved by inducing genetic variation in the
natural strain and subsequent screening. Thus a major
effort of industrial research in producing enzymes is
directed towards the screening programs. Mutation is
the primary source of all genetic variation and has
been used extensively in industrial improvement of
enzyme production (Ghisalba et al., 1984; Sidney and
Nathan, 1975). The use of mutation and selection to
improve the productivity of cultures has been
strongly established for over fifty years and is still
recognized as a valuable tool for strain improvement
of many enzyme-producing organisms Paradee, A
B(1973).
The industrial geneticist is rarely able to predict
exactly what type of mutation is required to improve
Journal of Pharmacreations](https://image.slidesharecdn.com/05-191217060155/85/Strain-improvement-studies-on-L-aspaginase-producing-bacteria-1-320.jpg)
![M. Sunitha, / Journal of Pharmacreations Vol-1(4) 2014 [97-102]
98
the given strain. Hence a series of mutagenic
treatments are carried out to develop a better yielding
strain by trial and error. Various mutagenic agents
such as ultraviolet rays (UV), N methyl-N’-nitro-N-
nitrosoguanidine (NTG), X-rays, gamma rays, nitrous
acid, ethyl methyl sulfonate (EMS) etc., are generally
used for yield improvement studies. The ultra violet
irradiation , Meyroth, J (1971) is the most convenient
of all mutagens to use and it is also very easy to take
effective safety precautions against it. The UV light
is the best studied mutagenic agent in prokaryotic
organisms. It gives a high proposition of pyrimidine
dimers and includes all types of base pair
substitutions (Meenu et al., 2000).
N-Methyl-N’-nitro-N-nitrosoguanidine( NTG) has
been widely used to induce mutations in bacteria. It
has proved highly effective, so much so that it has
been suggested to be the most potent chemical
mutagen yet discovered (Adelberg, Mandel & Chen,
1965). Adelberg et al. (1965) found that mutations to
valine resistance and to auxotrophy occurred at high
frequency (up to 42-5 % auxotrophs) after exposure
of Escherichia coli to NTG under conditions such
that about 5 % of the treated bacteria remained
viable. NTG was also proved to be a very effective
mutagen for yeasts, though the results are less
dramatic than with E. coli. Ellaiah P (1986) with
Schizosaccharomyces pombe found that, without
selection, NTG-induced auxotrophs increased to a
maximum frequency of about 8 % at 20 % survival.
On the other hand, Nordstrom (1967) obtained up to
50 % petite mutants among survivors of
Saccharomyces cerevisiae after NTG treatment.
MATERIALS AND METHODS
Chemicals
All chemicals and medium constituents used for the
present study were procured from M/S Hi-media,
Mumbai.
Microorganism
The newly isolated bacterial species i.e. Bacillus
cereus MS-6 strain (wild strain) that produce L-
asparaginase was employed in the present study. The
selected isolate was grown on M-7 agar slants at
37oC for 24 h, subcultured at monthly intervals and
stored in the refrigerator.
Preparation of Inoculum
Inoculum was prepared as per the general procedure.
(M. Sunitha et al, 2010)
Shake flask fermentation
The fermentation was conducted as per the general
procedure. (M. Sunitha et al, 2010)
Analytical method
First step in the analytical method is UV irradiation
of parent strain and selection of mutants (Hopwood et
al., 1985). Figure 1 and 2
The next step is NTG treatment and selection of
mutants (Cerda-Olmedo and Hanawalt, 1968;
Adelberg et al., 1965)., (Cerda-Olmedo and
Hanawalt, 1968). Table 1 and fig 3. then the mutants
are treated with EMS (M. Sunitha et al 2010). Table
2 and fig 4.
a) UV irradiation of parent strain and
selection of mutants
Strain improvement for the selected parent strain was
done by mutation and selection. The wild strain (MS-
6) was subjected to UV irradiation. The dose survival
curve was plotted for selecting the mutants between
10 and 0.1% rate. Mutation frequency was mentioned
to be high when the survival rates were between 10
and 0.1% (Hopwood et al., 1985).
b) NTG treatment and selection of mutants
The best UV-mutant of Bacillus cereus MUV-9 was
selected for NTG treatment. The NTG (150 mg) was
accurately weighed and dissolved in 25 ml of
phosphate buffer (pH 8.5) at a temperature of 4ºC to
minimize decomposition and sterilized by passing
through sterile bacterial filter (0.22 µm).
NTG is considered to be a very effective mutagen
(Cerda-Olmedo and Hanawalt, 1968; Adelberg et al.,
1965). Its action has been attributed to its
decomposition products (Cerda-Olmedo and
Hanawalt, 1968). The treated samples were diluted,
plated and colony counts were made. The percentage
survival or kill was calculated and data is presented
in Table 4.2. The survival curve was plotted (Fig.
4.3). Selected colonies (12) were picked up from 120
and 180 min. exposure and transferred on to M-7
medium agar slants. The slants were incubated at](https://image.slidesharecdn.com/05-191217060155/85/Strain-improvement-studies-on-L-aspaginase-producing-bacteria-2-320.jpg)
![M. Sunitha, / Journal of Pharmacreations Vol-1(4) 2014 [97-102]
99
370
C for 24 h to obtain maximum growth. They were
labeled as MNTG 1 to MNTG 12.
c) EMS treatment and selection of mutants
The highest producing MNTG mutant (MNTG-7)
was selected for EMS treatment. The cell suspension
of MNTG-07 was prepared as described earlier and
the cell pellets obtained after centrifugation were
resuspended in phosphate buffer (pH 8.0).
Five ml of each cell suspension was added to 15 ml
of EMS solution (4 mg/ml) and incubated at 37C
(Akhund and Khvostova, 1966). Two ml of this
solution was taken at intervals of 0, 30, 60, 90, 120,
150, 180, 210, and 270 min. and centrifuged
immediately. The supernatant was decanted and the
cell pellet obtained was resuspended in 5 ml of sterile
distilled water to stop the reaction. The total time
from the first incubation of the cell suspension to re-
suspension into distilled water was recorded.
RESULTS
From the results (Fig. 2), it is evident that UV
induced mutant MUV-9 showed highest L-
asparaginase activity (24.98 IU/ml). It was 3.059 fold
improvements over the parent strain.
Further mutagenesis of this strain by NTG treatment
could yield few mutants. Examination of L-
asparaginase activity of the selected mutants
indicated that the mutant MNTG-7 has further
improvement in L-asparaginase activity (38.06
IU/ml) (Fig. 5). It was 4.66 fold improvement in
yield over the wild strain (MS-6).
DISCUSSION
The strain of Bacillus cereus MS-6 was subjected to
strain improvement program with a view to obtain
increased L-asparaginase production. The most
effective mutagens, Ultra Violet rays (UV) and N
methyl-N’-nitro-Nnitrosoguanidine (NTG) were
chosen for strain improvement. The results indicated
that among UV mutants, MUV-9 showed the highest
L-asparaginsase activity (24.98 IU/mL). it was 3.059
fold of the parent strain. The chemical mutagen
(NTG) yielded a better enzyme producing mutant
MNTG-7 with 38.06 IU/mL. Thus the strain
improvement programme resulted in a mutant that
produced 12.11 fold higher amount of the enzyme
production over the parent wild strain (3.14 IU/mL),
which is a very significant achievement in enzyme
yield.
TABLES AND FIGURES
Fig. 1: Survival curve of isolate MS-06 after UV irradiation
0
20
40
60
80
100
120
0 3 6 9 12 15 18
%survival
Irradiation time (min.)](https://image.slidesharecdn.com/05-191217060155/85/Strain-improvement-studies-on-L-aspaginase-producing-bacteria-3-320.jpg)
![M. Sunitha, / Journal of Pharmacreations Vol-1(4) 2014 [97-102]
100
Fig. 4.2: Production of L-asparaginase by UV mutants
UV mutants
MUV-1 MUV-2 MUV-3 MUV-4 MUV-5 MUV-6 MUV-7 MUV-8 MUV-9 MUV-10 MUV-11
L-asparaginaseactivity(IU/ml)
0
5
10
15
20
25
30
Table 1: Effect of NTG on MUV-9
Exposure time
(min)
Number of cells/ml after treatment Percentage
kill
Survival percent
0 4.4 107
0 100
30 4.1 107
6.82 93.18
60 2.9 107
34.09 65.91
90 6.8 106
84.55 15.45
120 6.1 106
86.14 13.86
150 7.9 105
98.2 1.8
180 4.9 105
98.89 1.11
210 4.43 105
98.99 1.01
270 3.2 105
99.27 0.73
Fig. 3: Survival curve of isolate MUV-9 after NTG treatment
0
20
40
60
80
100
120
0 30 60 90 120 150 180 210 270
%survival
Exposure time (min.)](https://image.slidesharecdn.com/05-191217060155/85/Strain-improvement-studies-on-L-aspaginase-producing-bacteria-4-320.jpg)
![M. Sunitha, / Journal of Pharmacreations Vol-1(4) 2014 [97-102]
101
Table 2. Effect of EMS on MNTG-07
Exposure time (min) Number of cells/ml after experiment Percentage
kill
Survival percent
0 20107
0 100
30 10 107
50 50
60 60 106
70 30
90 23.3 106
88.35 11.65
120 20 106
90 10
150 16 106
92 8
180 14 106
93 7
210 12 106
94 6
270 8 105
99.6 0.4
Fig.4. Survival curve of isolate MNTG-7 after EMS treatment
Fig. 4.4: L-asparaginase production by NTG mutants
NTG mutants
MNTG-1 MNTG-2 MNTG-3 MNTG-4 MNTG-5 MNTG-6 MNTG-7 MNTG-8 MNTG-9 MNTG-10 MNTG-11 MNTG-12
L-asparaginaseactivity(IU/ml)
0
10
20
30
40
50
0
20
40
60
80
100
120
0 30 60 90 120 150 180 210 270
%survival
Exposure time (min.)](https://image.slidesharecdn.com/05-191217060155/85/Strain-improvement-studies-on-L-aspaginase-producing-bacteria-5-320.jpg)
![M. Sunitha, / Journal of Pharmacreations Vol-1(4) 2014 [97-102]
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REFERENCES
[1] Sabu A, Enzymes Ind. J. Biotech, 1993, 2, 334-341.
[2] Ghisalba, O., Auden, J. A. L., Schupp, T. and Nuesch, J .In: Biotechnology of Industrial Antibiotics, 1984,
28.
[3] Sidney, P. C. and Nathan, O. K., Methods In Enzymol., 1975, 3, 26, (ed. Hash John, H.), Antibiotics. .,
1975, 3, 26.
[4] Meenu, M., Santhosh, D., Kamia, C. and Randhir, S. Ind. J. Microbiol., 2000, 40, 25.
[5] Adelberg, E. A., Mandel, M. and Chen, G. C. C., Biochem. Biophys. Res. Commun., 1965, 18, 788.
[6] P. Ellaiah, K.V.R.N.S., 1986, Indian Drugs 24, 316-318.Strain Improvement studies on Glucose isomerise
producing Streptomyces sp. N.
[7] Meyroth, J., Bahn, M. and Han, H. E., Radiation and Radioisotopes for Industrial Microorganisms,
International atomic energy agency, Vienna, 1971.
[8] Paradee, A. B. In :Genetics of Industrial Microorganisms Vanik, Z., Hostalek, Z and Cudlin, J. (Eds)
Elsevier, Amesterdam, 1973.
[9] Hopwood, D. A., Bibb, M. J., Chater, K. F., Kieser, T., Bruton, C. J., Kieser, H. M., Lydiate, D. J., Smith,
C. P., Ward, J. M. and Schrempt, H., Genetic Manipulation of Streptomyces – A Laboratory manual, 1985.
[10]Cerda-Olmedo, E. and Hanawalt, P. C. Mol. Gen. Genetics., 1968, 101-191.
[11]Screening and optimization of nutrients for L-asparginase production by Bacillus cereus MNTG-7 in SmF
by placket-burmann design by M. Sunitha 2010, AJMR Vol. 4 (4), pp. 297-303](https://image.slidesharecdn.com/05-191217060155/85/Strain-improvement-studies-on-L-aspaginase-producing-bacteria-6-320.jpg)
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Strain improvement studies on L-aspaginase producing bacteria
- 1. M. Sunitha, / Journal of Pharmacreations Vol-1(4) 2014 [97-102] 97 Pharmacreations |Vol. 1 | Issue 4 | Oct- Dec -2014 Journal Home page: www.pharmacreations.com Review article Open Access Strain improvement studies on L-aspaginase producing bacteria M. Sunitha* Department of pharmaceutical sciences, andhra university, visakhapatnam-530003, india. * Corresponding author: M. Sunitha E-mail id: [email protected] ABSTRACT In the present study, we report the strain improvement studies on L-asparaginase producing a newly isolated Bacillus cereus MS-6. The UV induced mutant MUV-9 showed highest L-asparaginase activity (24.98 IU/ml). It was 7.84 fold of the parent strain. Further mutagenesis of this strain by NTG treatment could yield few mutants. Examination of L-asparaginase activity of the selected mutants showed that the mutant MNTG-7 showed further improvement in L-asparaginase activity (38.06 IU/ml) (Fig. 4.4). It was12.04 fold more of the wild strain (MS-6, 3.16). The EMS mutants (from parent MNTG-7) have not much difference between parent strain and EMS mutants. Keywords: L-Asparginase, bacillus cereus, MS-6 and mutants INTRODUCTION A major potential therapeutic application of enzymes is in the treatment of cancer. Asparagianse has proved to be particularly promising in the treatment of acute lympho-cytic leukaemia. Tumour cells are deficient in aspartate-ammonia ligase activity, which restricts their ability to synthesize the normally non- essential amino acid, L-asparagine. Therefore they are forced to extract it from body fluids. The action of Asparaginase does not affect the functioning of normal cells, which are able to synthesize enough for their own requirements, but reduce the free exogenous concentration, and so induce a state of fatal starvation in the susceptible tumour cells (Sabu, A, 2003). A 60% incidence of complete remission has been reported in a study of almost 6,000 cases of acute lymphocytic leukaemia. This enzyme is administered intravenously. L-asparagine+H2O L-aspartate+NH3 Strain improvement is an essential part of process development for fermentation products. Developed strains can reduce the costs with increased productivity and can possess some specialized desirable characteristics. Such improved strains can be achieved by inducing genetic variation in the natural strain and subsequent screening. Thus a major effort of industrial research in producing enzymes is directed towards the screening programs. Mutation is the primary source of all genetic variation and has been used extensively in industrial improvement of enzyme production (Ghisalba et al., 1984; Sidney and Nathan, 1975). The use of mutation and selection to improve the productivity of cultures has been strongly established for over fifty years and is still recognized as a valuable tool for strain improvement of many enzyme-producing organisms Paradee, A B(1973). The industrial geneticist is rarely able to predict exactly what type of mutation is required to improve Journal of Pharmacreations
- 2. M. Sunitha, / Journal of Pharmacreations Vol-1(4) 2014 [97-102] 98 the given strain. Hence a series of mutagenic treatments are carried out to develop a better yielding strain by trial and error. Various mutagenic agents such as ultraviolet rays (UV), N methyl-N’-nitro-N- nitrosoguanidine (NTG), X-rays, gamma rays, nitrous acid, ethyl methyl sulfonate (EMS) etc., are generally used for yield improvement studies. The ultra violet irradiation , Meyroth, J (1971) is the most convenient of all mutagens to use and it is also very easy to take effective safety precautions against it. The UV light is the best studied mutagenic agent in prokaryotic organisms. It gives a high proposition of pyrimidine dimers and includes all types of base pair substitutions (Meenu et al., 2000). N-Methyl-N’-nitro-N-nitrosoguanidine( NTG) has been widely used to induce mutations in bacteria. It has proved highly effective, so much so that it has been suggested to be the most potent chemical mutagen yet discovered (Adelberg, Mandel & Chen, 1965). Adelberg et al. (1965) found that mutations to valine resistance and to auxotrophy occurred at high frequency (up to 42-5 % auxotrophs) after exposure of Escherichia coli to NTG under conditions such that about 5 % of the treated bacteria remained viable. NTG was also proved to be a very effective mutagen for yeasts, though the results are less dramatic than with E. coli. Ellaiah P (1986) with Schizosaccharomyces pombe found that, without selection, NTG-induced auxotrophs increased to a maximum frequency of about 8 % at 20 % survival. On the other hand, Nordstrom (1967) obtained up to 50 % petite mutants among survivors of Saccharomyces cerevisiae after NTG treatment. MATERIALS AND METHODS Chemicals All chemicals and medium constituents used for the present study were procured from M/S Hi-media, Mumbai. Microorganism The newly isolated bacterial species i.e. Bacillus cereus MS-6 strain (wild strain) that produce L- asparaginase was employed in the present study. The selected isolate was grown on M-7 agar slants at 37oC for 24 h, subcultured at monthly intervals and stored in the refrigerator. Preparation of Inoculum Inoculum was prepared as per the general procedure. (M. Sunitha et al, 2010) Shake flask fermentation The fermentation was conducted as per the general procedure. (M. Sunitha et al, 2010) Analytical method First step in the analytical method is UV irradiation of parent strain and selection of mutants (Hopwood et al., 1985). Figure 1 and 2 The next step is NTG treatment and selection of mutants (Cerda-Olmedo and Hanawalt, 1968; Adelberg et al., 1965)., (Cerda-Olmedo and Hanawalt, 1968). Table 1 and fig 3. then the mutants are treated with EMS (M. Sunitha et al 2010). Table 2 and fig 4. a) UV irradiation of parent strain and selection of mutants Strain improvement for the selected parent strain was done by mutation and selection. The wild strain (MS- 6) was subjected to UV irradiation. The dose survival curve was plotted for selecting the mutants between 10 and 0.1% rate. Mutation frequency was mentioned to be high when the survival rates were between 10 and 0.1% (Hopwood et al., 1985). b) NTG treatment and selection of mutants The best UV-mutant of Bacillus cereus MUV-9 was selected for NTG treatment. The NTG (150 mg) was accurately weighed and dissolved in 25 ml of phosphate buffer (pH 8.5) at a temperature of 4ºC to minimize decomposition and sterilized by passing through sterile bacterial filter (0.22 µm). NTG is considered to be a very effective mutagen (Cerda-Olmedo and Hanawalt, 1968; Adelberg et al., 1965). Its action has been attributed to its decomposition products (Cerda-Olmedo and Hanawalt, 1968). The treated samples were diluted, plated and colony counts were made. The percentage survival or kill was calculated and data is presented in Table 4.2. The survival curve was plotted (Fig. 4.3). Selected colonies (12) were picked up from 120 and 180 min. exposure and transferred on to M-7 medium agar slants. The slants were incubated at
- 3. M. Sunitha, / Journal of Pharmacreations Vol-1(4) 2014 [97-102] 99 370 C for 24 h to obtain maximum growth. They were labeled as MNTG 1 to MNTG 12. c) EMS treatment and selection of mutants The highest producing MNTG mutant (MNTG-7) was selected for EMS treatment. The cell suspension of MNTG-07 was prepared as described earlier and the cell pellets obtained after centrifugation were resuspended in phosphate buffer (pH 8.0). Five ml of each cell suspension was added to 15 ml of EMS solution (4 mg/ml) and incubated at 37C (Akhund and Khvostova, 1966). Two ml of this solution was taken at intervals of 0, 30, 60, 90, 120, 150, 180, 210, and 270 min. and centrifuged immediately. The supernatant was decanted and the cell pellet obtained was resuspended in 5 ml of sterile distilled water to stop the reaction. The total time from the first incubation of the cell suspension to re- suspension into distilled water was recorded. RESULTS From the results (Fig. 2), it is evident that UV induced mutant MUV-9 showed highest L- asparaginase activity (24.98 IU/ml). It was 3.059 fold improvements over the parent strain. Further mutagenesis of this strain by NTG treatment could yield few mutants. Examination of L- asparaginase activity of the selected mutants indicated that the mutant MNTG-7 has further improvement in L-asparaginase activity (38.06 IU/ml) (Fig. 5). It was 4.66 fold improvement in yield over the wild strain (MS-6). DISCUSSION The strain of Bacillus cereus MS-6 was subjected to strain improvement program with a view to obtain increased L-asparaginase production. The most effective mutagens, Ultra Violet rays (UV) and N methyl-N’-nitro-Nnitrosoguanidine (NTG) were chosen for strain improvement. The results indicated that among UV mutants, MUV-9 showed the highest L-asparaginsase activity (24.98 IU/mL). it was 3.059 fold of the parent strain. The chemical mutagen (NTG) yielded a better enzyme producing mutant MNTG-7 with 38.06 IU/mL. Thus the strain improvement programme resulted in a mutant that produced 12.11 fold higher amount of the enzyme production over the parent wild strain (3.14 IU/mL), which is a very significant achievement in enzyme yield. TABLES AND FIGURES Fig. 1: Survival curve of isolate MS-06 after UV irradiation 0 20 40 60 80 100 120 0 3 6 9 12 15 18 %survival Irradiation time (min.)
- 4. M. Sunitha, / Journal of Pharmacreations Vol-1(4) 2014 [97-102] 100 Fig. 4.2: Production of L-asparaginase by UV mutants UV mutants MUV-1 MUV-2 MUV-3 MUV-4 MUV-5 MUV-6 MUV-7 MUV-8 MUV-9 MUV-10 MUV-11 L-asparaginaseactivity(IU/ml) 0 5 10 15 20 25 30 Table 1: Effect of NTG on MUV-9 Exposure time (min) Number of cells/ml after treatment Percentage kill Survival percent 0 4.4 107 0 100 30 4.1 107 6.82 93.18 60 2.9 107 34.09 65.91 90 6.8 106 84.55 15.45 120 6.1 106 86.14 13.86 150 7.9 105 98.2 1.8 180 4.9 105 98.89 1.11 210 4.43 105 98.99 1.01 270 3.2 105 99.27 0.73 Fig. 3: Survival curve of isolate MUV-9 after NTG treatment 0 20 40 60 80 100 120 0 30 60 90 120 150 180 210 270 %survival Exposure time (min.)
- 5. M. Sunitha, / Journal of Pharmacreations Vol-1(4) 2014 [97-102] 101 Table 2. Effect of EMS on MNTG-07 Exposure time (min) Number of cells/ml after experiment Percentage kill Survival percent 0 20107 0 100 30 10 107 50 50 60 60 106 70 30 90 23.3 106 88.35 11.65 120 20 106 90 10 150 16 106 92 8 180 14 106 93 7 210 12 106 94 6 270 8 105 99.6 0.4 Fig.4. Survival curve of isolate MNTG-7 after EMS treatment Fig. 4.4: L-asparaginase production by NTG mutants NTG mutants MNTG-1 MNTG-2 MNTG-3 MNTG-4 MNTG-5 MNTG-6 MNTG-7 MNTG-8 MNTG-9 MNTG-10 MNTG-11 MNTG-12 L-asparaginaseactivity(IU/ml) 0 10 20 30 40 50 0 20 40 60 80 100 120 0 30 60 90 120 150 180 210 270 %survival Exposure time (min.)
- 6. M. Sunitha, / Journal of Pharmacreations Vol-1(4) 2014 [97-102] 102 REFERENCES [1] Sabu A, Enzymes Ind. J. Biotech, 1993, 2, 334-341. [2] Ghisalba, O., Auden, J. A. L., Schupp, T. and Nuesch, J .In: Biotechnology of Industrial Antibiotics, 1984, 28. [3] Sidney, P. C. and Nathan, O. K., Methods In Enzymol., 1975, 3, 26, (ed. Hash John, H.), Antibiotics. ., 1975, 3, 26. [4] Meenu, M., Santhosh, D., Kamia, C. and Randhir, S. Ind. J. Microbiol., 2000, 40, 25. [5] Adelberg, E. A., Mandel, M. and Chen, G. C. C., Biochem. Biophys. Res. Commun., 1965, 18, 788. [6] P. Ellaiah, K.V.R.N.S., 1986, Indian Drugs 24, 316-318.Strain Improvement studies on Glucose isomerise producing Streptomyces sp. N. [7] Meyroth, J., Bahn, M. and Han, H. E., Radiation and Radioisotopes for Industrial Microorganisms, International atomic energy agency, Vienna, 1971. [8] Paradee, A. B. In :Genetics of Industrial Microorganisms Vanik, Z., Hostalek, Z and Cudlin, J. (Eds) Elsevier, Amesterdam, 1973. [9] Hopwood, D. A., Bibb, M. J., Chater, K. F., Kieser, T., Bruton, C. J., Kieser, H. M., Lydiate, D. J., Smith, C. P., Ward, J. M. and Schrempt, H., Genetic Manipulation of Streptomyces – A Laboratory manual, 1985. [10]Cerda-Olmedo, E. and Hanawalt, P. C. Mol. Gen. Genetics., 1968, 101-191. [11]Screening and optimization of nutrients for L-asparginase production by Bacillus cereus MNTG-7 in SmF by placket-burmann design by M. Sunitha 2010, AJMR Vol. 4 (4), pp. 297-303