Effect of Different Concentrations of Glycerol on survival of Azotobacter chroococcum Local strains isolated from Wild Grasses

Asian Journal of Applied Science and Technology (AJAST)
Volume 5, Issue 4, Pages 16-23, Oct-Dec 2021
ISSN: 2456-883X www.ajast.net
16
Effect of Different Concentrations of Glycerol on survival of Azotobacter chroococcum
Local strains isolated from Wild Grasses
B. D. Takate1
& B. M. Gaykar2
1,2
P.G. Department of Botany, Ahmednagar College, Ahmednagar, Maharashtra, India.
DOI: Under assignment
Copyright: © 2021 B.D.Takate & B.M.Gaykar. This is an open access article distributed under the terms of the Creative Commons Attribution License, which
permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Article Received: 21 August 2021 Article Accepted: 14 October 2021 Article Published: 05 November 2021
Introduction
Azotobacter bio-fertilizer can be used in the form of liquid or solid formulations for crop improvement and growth.
The Indian government and private sectors have been trying to increase the production and application of bio
fertilizers along with modern agrochemicals (Mohd Mazid and Taqi Ahmed Khan 2014). Liquid bio-fertilizers are
special liquid formulations containing not only the desired microorganisms and their nutrients but also special cell
protectants or chemicals that promote formation of resting spores or cysts for longer shelf life and tolerance to
adverse conditions (Ghosh, 2004). A particular efficient strain of the N-fixing/P-solublizing microorganism
selection for bio-fertilizer is a big task (Gandhi and Saravanakumar 2009). It was revealed that Azotobacter could
be one of the bio-fertilizer options for sustainable and environmental ecofriendly for maize production where
chemical fertilizer is limited (Baral and Adhikari, 2013). In India, the bio-fertilizers are mostly lignite, coal, peat
based. The microbial inoculants are prepared with the above carried based. Generally it called solid formulations.
But this has many disadvantages such as shorter shelf life, poor quality, high contamination and poor performance.
In addition to this the carrier based inoculants production is tedious, energy consuming activity. It involves milling,
sieving and correcting pH (Somasengaran and hoben 1994). The liquid inoculants formulation is one solution to the
problem associated within processing of solid carriers. The use of various broths cultures amended with substances
that promote the cell survival in the package and after applications for seed or soil. Additives to liquid inoculants
formulations should have a role in protecting Azotobacter cells on seeds at high temperature and during desiccation.
Many kinds of polymer have been used for inoculants production because of their ability to limit heat transfer, their
good rheological properties and high water activities (Mungier and Jung 1985).
In the present work the survival of Azotobacter in liquid formulations were evaluated by using Glycerol at different
concentration. Azotobacter cells in Jenson’s broth alone were used as control. The glycerol at different
ABSTRACT
The plant growth promoting rhizobacterias inoculants used in various formulations for different purpose. In addition to rhizobacterias, the
formulation may also contain various additives. Furthermore, it is important to understand the interaction between bacteria and formulation materials.
The formulation materials serve as cell protectants which enhance the shelf-life of bacteria. It is proved that the Rhizobium is the effective inoculants
along with specific nutrient media for survival. Many researchers have shown that liquid rhizobial formulations are more beneficial than solid
bio-fertilizer formulations. In the present work the survival of Azotobacter in liquid formulations were evaluated by using Glycerol at different
concentration in Jenson’s broth. It was noted that survival of Azotobacter was concentration correlated. Lowest number of colonies in 5 mM in the
medium containing glycerol (23 colonies at zero days and 5 colonies on 360th
day) and highest number of colonies in 25 mM in the medium
containing glycerol (38.66 colonies on zero day and 22 colonies on 360th
day) (109 CFU/ml).
Keywords: Glycerol, Survival, Azotobacter chroococcum.

17
concentration was tried in formulation to understand the survival life of Azotobacter and interaction between
Azotobacter and formulation materials.
Material and Methods
Jensen’s Basal Medium: The N2 free Jensen’s medium (Jensen 1954) containing 20 gm sucrose, 1.0 gm K2HPO4,
0.5 gm MgSO4.7H2O, 0.5 gm NaCl, 2 gm CaCO3, 0.005 gm Na2MoO4, and 0.1 gm FeSO4 dissolved in 1 lit
Distilled water and pH was adjusted to 7.1
Liquid State Formulation with polymer cell protectants: For the standardization of proper quantity of
amendments and to find out the survival time of Azotobacter chroococcum the polymer cell protectants were added
with Jensen’s basal medium. These various formulation were as follows
(1) Basal medium (Control).
(2) Basal medium + Glycerol with 5, 10, 15, 20, 25 mM.
The slant culture of Azotobacter along with above formulation was incubated for 4 days on shaker at 121 rpm. The
optical densities 0.25 were adjusted at 0.25 with the help of spectrophotometer. This 10 ml culture of Azotobacter
chroococcum was inoculated in each flask of above 5 types of liquid formulation under aseptic condition. The
broths were kept for continuous shaking on rotary shaker for 72 hours at 121 rpm, and then the cultures were
transferred in sterilized glass bottle, plugged with cotton and stored at room temperature. These broth cultures were
tested for total viable count at 30 days interval up to 12 months.
(3) Basal Medium + Glycerol 25 mM only- This formulation was prepared to compare the growth and survival of
Azotobacter chroococcum A1 Azotobacter chroococcum A2, Azotobacter chroococcum NCIM 5576 isolates.
These isolates were inoculated (10 ml of culture) separately in each flask under aseptic condition. The broths were
incubated on rotary shaker for 72 hours at 121 rpm, and then cultures were transferred in sterilized glass bottle,
plugged and stored at 300
C temperature. These broth cultures were tested for total viable count at 30 days interval
up to 12 months.
Table1. Effect of Glycerol (CFU/ml at 109
) in Jensen's broth on survival of Azotobacter chroococcum A1 colonies
Days
Broth Alone
(control)
Glycerol
5 mM
Glycerol
10 mM
Glycerol
15 mM
Glycerol
20 mM
Glycerol
25 mM
CD at 0.05%
0 22.66a±0.51
23.00a±0.58
(1.50)
30.00b±0.58
(32.39)
31.00c ±0.58
(36.80)
34.66d±0.51
(50.04)
38.66e±0.51
(70.61)
0.9 4.20E-10
30 20.33a±0.58
23.00a±0.58
(13.13)
28.00c ±0.58
(37.73)
29.00d±0.58
(42.65)
34.33e±0.69
(68.86)
38.33f±0.69
(88.54)
0.47 8.66E-10
60 16.66a±0.38
21.00b±0.58
(26.05)
26.00c±0.58
(56.06)
28.00d±0.58
(68.07)
32.00c±0.58
(92.08)
37.00f± 0.58
(122.09)
0.42 7.84E-11
90 14.00a±0.58
20.00b±0.58
(42.86)
24.00c±0.58
(71.43)
25.00d±0.58
(78.57)
30.00e±0.58
(114.29)
35.00f±0.32
(150.00)
0.44 1.35E-10
120 10.00a±0.58
17.00b±0.58
(70.00)
22.00c ±0.58
(120.00)
22.00c±0.58
(120.00)
28.00d±0.58
(180.00)
33.66e±0.32
(236.60)
0.42 1.71E-11

18
150 8.00a±0.58
16.00b±0.58
(100.00)
20.00c ±0.58
(150.00)
21.00d±0.58
(162.50)
25.00e±0.58
(212.50)
33.33f±0.51
(316.63)
0.43 2.00E-11
180 5.33a±0.31
14.00b± 0.58
(162.66)
20.00c ±0.58
(275.23)
21.66d±0.50
(306.38)
25.00e±0.58
(369.04)
32.00f±0.58
(500.38)
0.4 3.52E-12
Data presented are means of ten readings; values within the same row with different letters are significantly
different at 0.05% P-level by Single factor ANOVA test followed by CD & Tukey's test. [Figures in parentheses
indicate % increase (+) and % decrease (-) over control; ± standard error of mean; CD:critical difference; P-value/
alpha value at 0.05%; CFU/ml At 109
: Colony forming unit per gram per ml of Glycerol plus Jensen's broth).
Table 2. Effect of Glycerol (CFU/ml at 109
) in Jensen's broth on survival of Azotobacter chroococcum A1 colonies
Data presented are means of ten readings; values within the same row with different letters are significantly
different at 0.05% P-level by Single factor ANOVA test followed by CD & Tukey's test. [Figures in parentheses
indicate % increase (+) and % decrease (-) over control; ± standard error of mean; CD: critical difference; P-value/
alpha value at 0.05%; where CFU/ml AT 109
:Colony forming unit per gram per ml of Glycerol plus Jensen's broth).
Table 3. Effect of Glycerol in Jensen's broth on survival of A1,A2 and NCIM 5576 strains of Azotobacter
chroococcum during Storage, at 109
CFU/ml
Name of the bacterium Survival of colonies
(average number )
Days
Azotobacter chroococcumA1 40.69a±2.90 0 to 360
Azotobacter chroococcum A2 46.85b±2.85 1 to 360
Azotobacterchroococcum NCIM 33.00c±1.18 2 to 360
CD at 0.05% 3.1
P-value at 0.05% 0.001
Days
Broth Alone
(control)
Glycerol
5 mM
Glycerol
10 mM
Glycerol
15 mM
Glycerol
20 mM
Glycerol
25 mM
CD at 0.05%
210 4.00a±0.58
12.00b±0.58
(200.00)
17.00c±0.58
(325.00)
21.33d±0.62
(433.25)
23.66e ±0.61
(491.50)
30.00f±0.58
(650.00)
0.45 1.30E-11
240 3.00a±0.58
10.66b± 0.20
(255.33)
16.00c±0.58
(433.33)
20.00d±0.58
(566.67)
23.33e±0.56
(677.67)
28.00f±0.58
(833.33)
0.84 4.45E-12
270 1.33a±0.07
10.33b± 0.46
(676.69)
15.00c±0.58
(1027.82)
18.00d±0.58
(1253.38)
22.00e±0.58
(1554.14)
27.00f±0.58
(1930.08)
0.39 2.61E-12
300 0.00a±0.00 9.00b±0.58 13.00c±0.58 17.00d±0.58 20.00e±0.58 25.00f±0.58 0.4 5.54E-12
330 0.00a±0.00 7.00b±0.58 10.00c±0.58 15.00d±0.58 18.00e±0.58 23.00f±0.58 0.4 1.24E-11
360 0.00a±0.00 5.00b±0.58 9.00c±0.58 14.00d±0.58 17.00e±0.58 22.00f±0.58 0.4 1.53E-11

19
Fig.1. Effect of different concentrations (5 mM to 25 mM) of Glycerol in Jensen's broth on survival of Azotobacter
chroococcum colonies
Fig.2. Effect of Glycerol in Jensen's broth on survival of A1, A2 and NCIM 5576 strains of Azotobacter
chroococcum during Storage, at 109
CFU/ml
0
5
10
15
20
25
30
35
40
45
0 30 60 90 120 150 180 210 240 270 300 330 360
Number
of
survived
colonies
Days
Effect of different concentrations of Glycerol on survival of
Azotobacter colonies
Broth (control)
5mM
10mM
15mM
20mM
25mM
27
32
26
0
10
20
30
40
50
60
70
0 30 60 90 120 150 180 210 240 270 300 330 360
Number
of
colonies
Days
Effect of Glycerol on survival of bacteria during
storge at 109CFU/ML
A.chroococcumA1
A. chroococcum A2
A. chroococcum NCIM

20
.
Photo plate 1. Effect of Glycerol in Jensen's broth on survival of A1, A2 and NCIM 5576 strains of
Azotobacter chroococcum during Storage, at 109
CFU/ml
Result and Discussion
The experimental work was carried out for the survival of Azotobacter in liquid and solid formulations. Many
researchers have shown that liquid rhizobial formulations are more beneficial. Hynes et al (1995, 2001) revealed
that the results of liquid rhizobial formulations for the growth and yield of crops are more suitable than that of
peat-based products. Maniknandan et al (2010) worked on standardization of liquid formulation of Psudomonas
fluorescens by using , trehalose, polyvinylpyrrolidone and glycerol for development of liquid formulation. Among
these, glycerol amendment maintained the greater population level of P. fluorescens Pf1 up to 6 months of
storage.Cortes-Patino Sandra and Bonilla Ruth Rebeca (2015) worked on Polymers selection for a liquid inoculant
of Azospirillum brasilense based on the Arrhenius thermodynamic modelthey used a method of accelerated
degradation to select a polymer and a concentration to maintain cell stability of a liquid inoculant based on the
strain C16 Azospirillum brasilense. A screening at 45°C was made to compare the protectant effect of five
polymers on the viability of the strain (p/v): carrageenan (1.5%), sodium alginate (1%), trehalose (10 mM),
polyvinylpyrrolidone (2%), glycerol (10 mM) and phosphate saline buffer as control. conclude that these polymers
can be used for a formulation of a liquid inoculant based on the strain C16 Azospirillum brasilense.
It was evaluated by using polymers like polyvinyl pyrollidone (PVP), Glycerol, trehalose, separately and PVP,
Glycerol, trehalose together. Simultaneously the survival was also evaluated by using different carbon sources
along with Jensen’s basal medium. The results are depicted in following tables. Data was tabulated and analyzed

21
statistically, presented in graphical form also. Azotobacter cells in Jenson’s broth alone were used as control for
liquid formulation and lignite was used for solid formulation. The different additives were tried in formulation to
understand the survival life of Azotobacter and interaction between Azotobacter and formulation materials.
(1) Effect of glycerol on survival of Azotobacterchroococcum A1 colonies grown in Jensen’s medium (Table No
15, 16, Figure No 19): Glycerol is a sweet-tasting, non-toxic substance that contain a propane molecule attached to
three –Oh groups. Different concentrations viz. 10 mM to 25 mM were prepared and added to the culture of
Azotobacter chroococcum grown in Jensen’s medium. Jensen’s broth/medium without addition of glycerol was
treated as control. Effect of all concentrations on survival of Azotobacter colonies was significant at 0.05%
probability level. On zero days highest number of colonies was recorded in medium containing 25 mM Trehalose
followed by 20 mM, 15 mM, 10 mM and 5 mM in the medium containing glycerol. Survival of the Azotobacter was
maintained up to 360 days. It was noted that survival of Azotobacter was concentration correlated. Lowest number
of colonies in 5mM in the medium containing glycerol (23 colonies at zero days and 5 colonies on 360th
day) and
highest number of colonies in25mM in the medium containing glycerol (38.66 colonies on zero day and 22 colonies
on 360th
day) (109
CFU/ml). Santhosh (2015) recorded similar results. Colonies (22.66 on zero day, 1.33 colonies
on 270th
day) in pure broth could be maintained. Effect of glycerol on survival of Azotobacterchroococcum
colonies grown in Jensen’s medium has shown better result of colony count (22 colonies on 360th
day) over control
at room temperature.
Stock culture of Azotobacter (SR-4) was maintained by Misbahud Dineet al (2019) on nutrient agar slants and
glycerol cultures in nutrient broth and was stored at -800
C. Rojas-Tapias et al (2013) stated that use of preservation
techniques is usually accompanied with use of protective agents, which can increase effectiveness of the technique
preventing cell damage. For this reason, selection of the protective agent like glycerol depends on the preservation
method and type of bacteria.
As per the previous records, our efforts for survival of Azotobacter are successful and economical by using
Glycerol as preservative. Lorda and Balatti (1996) recorded that glycerol (10 mM) showed better population
survival of Azotobacter next to trehalose may which may be due to high water holding capacity and may protect
cell from the effect if desiccation by reducing rate of drying.
(2) The result indicate that, maximum population of Azotobacter was recorded in, glycerol 25 mM 22x109
cfu/ml,
followed by pvp 3%16x109
cfu/ml, trehalose (25 Mm)14x109
cfu/ml, combine use of trehalose, and glycerol 6x107
cfu/ml where as minimum population was recorded in control( Jensen broth only) 4x104
cfu/ml during storage of 12
months.
Santhosh (2015) formulated Rhizobium, Azotobacter, Azospirillium, and Bacillus megaterium and stored these
formulations in BOD incubator for 180 days and total viable count was analyzed at 30 days interval he recorded
0.5% polyvinylpyrrolidone in addition with 0.5% glycerol recorded maximum cell count in all cultures followed by
polyethelene glycerol, gum Arabic and sodium alginate. And also reported that, the survival of bacteria in liquid
formulation was increased due to the improvement in biological integrity, this was because polyvinyl pyrrolidone
which helps to reduce extra protein coagulation of bacterial cell and macromolecular structure maintenance.

22
Polyvinyl pyrrolidone helps to maintain moisture level in medium (Singleton et al 2002; Deaker et al 2004). Also
Polyvinyl pyrrolidone binds with bacterial toxins released in medium, during stationary phase of bacteria
(Errington et al (2002), Deaker et al (2004), C.F. Dayamani and Brahmaprakash (2014).
Conclusion
It was concluded that survival of Azotobacter along with deferent concentrations of glycerol was concentration
correlated. Lowest number of colonies in 5 mM in the medium containing glycerol (23 colonies at zero days and 5
colonies on 360th
day) and highest number of colonies in 25 mM in the medium containing glycerol (38.66 colonies
on zero day and 22 colonies on 360th
day) at (109
CFU/ml) was recorded.
Declarations
Source of Funding
This research did not receive any grant from funding agencies in the public, commercial, or not-for-profit sectors.
Competing Interests Statement
The authors declare no competing financial, professional and personal interests.
Consent for publication
Authors declare that they consented for the publication of this research work.
References
Baral, B.R., & Adhikari, P., (2013). Effect of azotobacter on growth and yield of maize. SAARC J. Agri., 11(2):
141-147.
Cortes-Patino Sandra & Bonilla Ruth Rebeca, (2015). Polymers selection for a liquid inoculant of azospirillum
brasilense based on the arrhenius thermodynamic model. African Journal of Biotechnology, 14(33): 2547-2553.
Deaker, R., Roughley, R.J., & Kennedy, I.R., (2004). Legume seed inoculation technology–a review. Soil Biol
Biochem., 36: 1275-88.
Dayamani, K.J., & Brahmaprakash, G.P., (2014). Influence of forms and concentrations of the osmolytes in liquid
inoculants formulations of plant growth promoting bacteria. International Journal of Scientific and Research
Publications, 4(7): 2250-3153.
Errington, J.R., Pablo, G.D., & Brian, A.P., (2002). The stability of proteins in a polyvinylpyrrolidone matrix.
Department of Chemical Engineering, Princeton University, USA.
Gandhi, A., & Saravanakumar K., (2009). Studies on shelf-life of Azospirillum lipoferum, Bacillus megaterium and
Pseudomonas fluorescens in Vemicompost Carrier. J. Phytol., 1: 75-85.
Ghosh, N., (2004). Promoting biofertilisers in Indian agriculture., Economic and Political Weekly, 39(52):
5617-5625.

23
Hynes, R.K., Jans, D.C., Bremer, E., Lupwayi, N.Z., Rice, W.A., Clayton, G.W., & Collins, M.M., (2001).
Rhizobium population dynamics in pea rhizosphere of rhizobial inoculant strain applied in different formulations.
Can. J. Microbiol., 47: 595-600.
Hynes, R.K., Kraig, K.A., Covert, D., Smith, R.S., & Rennie, R.J., (1995). Liquid rhizobial inoculants for lentil and
field pea. J. Prod. Agric., 8: 547-552.
Jensen, H., (1954). The Azotobacteriaceae Bacteriol Rev., Dec 14(4): 195-214.
Lorda, G., & Balatti, A., (1996). Designing mediaI and II: Legume inoculants. Selection and characterization of
strains, production, use and management (eds) Balatti and Freise, Editorial Kingraf, Buenos Aires.
Maniknandan, R., Sasravanakumar, D., Rajendaran, L., Raguchander, T., Samiyappan, R., (2010). Standardization
of liquid formulation of Pseudomonas fluorescens PF1 for its Efficacy against Fusarium wilt of tomato. J. Biol.
Control, 54(2): 83-89.
Misbahud Din, Rubina Nelofer, Muhammad Salman, Abdullah, Faisal Hayat Khan, Asad Khan, Munib Ahmad,
Fazal Jalil, Jalal Ud Din, Mudassir Khan, (2019). Production of nitrogen fixing Azotobacter (SR-4) and phosphorus
solubilizing Aspergillus niger and their evaluation on Lagenaria siceraria and Abelmoschus esculentus.
Biotechnology Reports, 20: 1-5. http://creativecommons.org/licenses/by/4.0.
Mohd Mazid, & Taqi Ahmed Khan, (2014). Future of bio-fertilizers in indian agriculture: an overview.
International Journal of Agricultural and Food Research, 3(3): 10-23.
Mungier, J., & Jung, G., (1985). Survival of bacteria and fungi in relation to water activity and the solvent
properties of water in biopolymer. Appl. Environ. Microbiol., 50: 108-14.
Santhosh, G.P., (2015). Formulation and shelf life of liquid bio fertilizer inoculants using cell protectants.
Intentional Journal of Researches in Biosciences Agriculture and Technology, 11(7): 243-247.
Singleton, P., Keyser, H., & Sande, E., (2002). ACIAR proceding loge herridge D. (ed) Australian centre for
international Agricultural research Canberra, Australia Development and evolution of liquid inoculants, In
Inoculants and nitrogen fixation of legumes in veitham, 52-60.
Somasengaran, P., & Hoben, J.H., (1994). Handbook of rhizobia method in legume–rhizobium technology,
Springer-Verlag, New York Inc., New York.

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