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Original Article 

Biosci. J., Uberlândia, v. 33, n. 6, p. 1592-1600, Nov./Dec. 2017 

INDOLEACETIC ACID PRODUCTION AND CHROMIUM REDUCTION BY 

CYANOBACTERIA SYNECHOCYSTIS SP. P2A (CHROOCOCCALES) 

IMMOBILIZED IN ALGINATE BEADS 
 

PRODUÇÃO DE ÁCIDO INDOLACÉTICO E REDUÇÃO DO CROMO POR 
CIANOBACTÉRIAS Synechocystis SP. P2A (CHROOCOCCALES) IMOBILIZADAS 

EM ESFERAS DE ALGINATO 
 

Sana KHURSHID
1, 2; Chand ZAHID1; Shahida HASNAIN1 

1. Department of Microbiology and Molecular genetics, University of the Punjab, Quaid-e-Azam Campus, Lahore 54590, Pakistan;  
2. Institute of Molecular Biology and Biotechnology, University of Lahore, Defense road, Lahore, Pakistan; 

sanakhurshid_7@yahoo.com 
 

ABSTRACT: A simple extrusion method was used to entrap Synechocystis sp.P2A in alginate beads. The 
viability, growth response and Indoleacetic acid (IAA) production at different pH were studied in alginate immobilized 
Synechocystis sp.P2A. 2.6% sodium alginate (w/v) and pH-7 was found to be optimum for growth of Synechocystis sp. 
P2A as well as IAA production (79µ g/ml). To prepare effective formulation for plant inoculation, alginate beads were 
further modified by coating with chitosan or chitosan-polyethylene glycol. Effect of all formulations containing 
Synechocystis sp. P2A in free and immobilized form on growth of Triticumaestivum was evaluated. Soil inoculation of 
entrapped Synechocystis in alginate beads coated with chitosan resulted in 20% increase in root length and 14% increase in 
dry weight as compared to non-inoculated seedlings. Free and immobilized cyanobacteria were allowed to grow in BG11 
medium supplemented with 100µg/ml K2CrO4 and chromium reduction was measured at variable pH. At pH 7 
immobilized showed 5% more reduction than free form. The current study showed that alginate immobilized 
Synechocystis sp. P2A can accomplish viable functions including plant growth promoting hormone production and 
chromium reduction and therefore propose an efficient and convenient method for storage and use of cyanobacteria. 
 

KEYWORDS. Immobilization. Chitosan. Cyanobacteria. Auxin. Synechocystis  
 

INTRODUCTION 

 
Cyanobacteria also known as blue green 

algae are oxygenic phototropic prokaryotes. 
Cyanobacteria require vary simple growth 
requirements, which enables them to live in extreme 
environments, and resist a number of abiotic and 
biotic stresses. In Proterozoic Eon (2500-543 
million years ago) cyanobacteria were principle 
primary producers, capable of oxygen production as 
well as nitrogen fixation (KNOLL, 2008). These are 
capable of producing bioactive compounds, which 
not only promote their survival but also exploit by 
other organisms. Cyanobacteria add organic 
material to soil and excrete plant growth promoting 
substances like auxin (MOLNAR; ORDOG, 2005; 
MANICKAVELU et al., 2006) cytokines 
(HUSSAIN; HASNAIN, 2011). Indoleacetic acid 
(IAA) is the first auxin isolated and known for its 
ability to induce stem elongation and root initiation 
(ARTECA, 1996). Use of photosynthetic bacteria as 
biofertilizer offers other advantages like they do not 
contaminate ground water as compared to bacteria. 
These do not deplete the resources and work in 
harmony with nature (KANNAIYAN et al., 1997). 
Survival of cells in soil after inoculation and 

availability of easy to use formulations are two 
major limitations in expansion of use of 
cyanobacteria in agronomy. One way to overcome 
these problems is the use of alginate based carriers. 
These formulations encapsulate the living cells, 
protect the microorganisms against many 
environmental stresses and release them to the soil 
gradually when soil microorganisms degrade the 
polymers. The main advantages of alginate 
preparations are their non-toxic nature, degradation 
in the soil, their slow release of microorganisms into 
the soil and almost unlimited shelf life.  Inoculation 
of alginate beads containing plant growth promoting 
bacteria have shown to improved plant growth 
(BASHAN et al., 2002; WU et al., 2011). 
Chromium is present in various states in our 
environment, each with different properties. In 
surface water hexavalent chromium is mostly 
emitted from industrial effluents. Chromium VI is 
carcinogenic and genotoxic at high concentrations 
(GODET et al., 1996). Chromium VI may be 
reduced chromium III naturally if a large quantity of 
organic matter is present. ChromiumIII, 
thermodynamically the most stable state, is either 
adsorbed on the particulate matter or form large, 
insoluble polynucleate complexes (SANTONEN, 

Received: 11/11/16 
Accepted: 05/07/17 



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2009). Unfortunately, this process is rather slow and 
depends on the appropriate environment. Numerous 
microorganisms have the special capability to adapt 
and colonize the metal polluted environments by 
evolving mechanisms to combat metal toxicity like 
metal eflux channels, metal resistance plasmids, 
adsorption uptake and metal biotransformation 
(RAMI’REZ-DIAZ et al., 2008). Synechocystis sp. 
P2A, unicellular cyanobacteria isolated from 
industrial wastewater is resistant to 100µg/ml 
K2CrO4 (HAMEED; HASNAIN, 2005). The main 
objective of this study was to evaluate alginate 
beads suitable to allow the growth of the unicellular 
cyanobacteria Synechocystis sp. P2A for reduction 
of chromium and production of IAA, with the 
ultimate goal of transferring capsules to the field. In 
this study viability and IAA production of 
Synechocystis sp. P2A in four different 
formulations, alginate beads, alginate chitosan 
beads, alginate chitosan PEG beads and liquid 
medium at different pH was evaluated. The 
efficiency of immobilized Synechocystis sp. P2A as 
biofertilizer was evaluated through soil inoculation 
using wheat as test plant. On the other hand, Cr (VI) 
reduction capacity of immobilized Synechocystis sp. 
P2A was also accessed at different pH. 
 
MATERIALS AND METHODS 

 

Cyanobcterial strain growth conditions 
Synechocystis sp. [AHZ-HB-P2A] was used 

in all experiments already isolated from a local 
environment in Pakistan (HAMEED; HASNAIN, 
2005). Cyanobacteria culture was maintained in 
BG11 liquid medium (RIPPKA et al., 1979) at 25 oC 
under continuous fluorescent illumination (5.8 to 7.8 
µ E/m2s).  
 

Producing Alginate beads by simple extrusion 

method 
Cyanobacteria entrapment within alginate-

beads was carried out under sterile conditions. 
Sodium alginate solution was prepared by 
dissolving in water with constant stirring, 
autoclaved for 20 min at 121 ºC. Fifteen days old 
Synechocystis sp. P2A culture, grown in BG11 
liquid medium was concentrated using 
centrifugation (5min, 8,000Xg), and then mixed 
homogeneously into the sodium alginate solution. 
The mixture was added drop-wise with the aid of 10 
ml sterile syringe into sterilized 1.4% (w/v) CaCl2 at 
room temperature, and beads immediately formed in 
the CaCl2 solution.  
 
Optimization of entrapment of cyanobacteria 

Six concentrations (w/v) of sodium alginate 
1.2%, 1.6%, 2.2%, 2.6%, 3% and 3.4% were 
prepared separately. Beads containing cells were 
prepared by simple extrusion method. Then beads 
were washed three times in sterile water and 
transferred to BG11 medium supplemented with 1.5 
g/L tryptophan (HUSSAIN; HASNAIN, 2011).  
Entrapped bacteria were allowed to grow at 25 oC 
under continuous fluorescent illumination (5.8 - 7.8 
µ E/m2s).  Mechanical properties like weight and 
size of alginate beads were observed regularly. 
 

Solubility of beads and viable population 
Beads were solubilized for bacterial count 

by immersing one bead per ml of potassium 
phosphate buffer, for 40-60 min. To facilitate the 
solubility, the beads were vigorously shaken on a 
Vortex mixer. After solubilization the suspended 
cells were serially diluted in sterile normal saline 
and suitable dilutions were spreaded on BG11 plates 
in duplicate. Plates were incubated at 25 oC. After 
15 days, number of colonies on each plate was 
counted and CFU/ml was calculated. 
 

Quantification of IAA Production 
At every third day 1.5 ml of medium 

containing beads was removed and centrifuged 
(8,000Xg 10min). IAA was detected in 1 ml of 
supernatant using Salkowski reagent (TANG; 
BORNER, 1979). A standard curve was drawn for 
comparison to determine IAA concentration. 
 

Alginate beads coating 
Two different coats to cover cyanobacteria 

containing alginate beads were designed; Chitosan 
alone and chitosan containing Polyethylene glycol 
(PEG). 2.6% (w/v) alginate beads with 
Synechocystis P2A cells, were immersed in 0.4% 
(w/v) sterilized chitosan solution alone or 0.4% 
chitosan containing 0.1% (v/v) Polyethylene glycol 
and stirred. After 45 min, chitosan solution was 
removed and beads were washed with sterile 
distilled water. Cyanobacterial growth and indole 
aceticacid production in coated beads was 
monitored for two weeks in BG11 medium.     
 
Storage 

Two different approaches were used: drying 
and dark storage. For drying 10% sucrose or 10% 
lactose were used as protective agent. Beads were 
immersed in sterilized solution of protective 
medium and kept for one hour at 250C. Recovered 
were then placed on filter paper in sterilized plate 
and dried at 300C for 48 hours. After two days dried 
beads collected and stored at room temperature in 



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hermetically sealed containers. In second procedure, 
alginate beads were stored in distilled water in dark 
at 40C. The same procedures of measuring the cells 
in fresh beads were performed for the stored beads. 

 
Pot experiment 

Seeds of wheat (Triticum aestivum) were 
surface sterilized with 0.1% HgCl2 then washed with 
distilled water. Experiment consists of following 
treatments: Free cyanobacterial cells inoculated (A); 
Immobilized cyanobacterial cells in alginate beads 
inoculated (B1); Inoculation of cyanobacteria cells 
in chitosan coated alginate beads (B2); Inoculation 
of cyanobacterial cells entrapped in chitosan PEG 
coated beads (B3); each treatment received 1×1012 
free or alginate-entrapped cells per pot. Control: 
seeds with no inoculation(C); Blank alginate beads 
inoculated (F1); Blank chitosan coated alginate 
beads inoculated (F2); Blank chitosan PEG coated 
beads inoculated (F3). Each pot received six surface 
sterilized Wheat seeds. The experiment presented a 
completely random design with four replications per 
treatment. Experiment was performed in pots 
containing 150g garden soil in each pot. Plants were 
kept under control conditions (25 oC, 16 hour ±10 
Klux light). Pots were observed and watered 
regularly. Plants were harvested after 15 days and 
different growth parameters were measured. Plant 
dry weight was recorded after drying at 80 °C to 
constant weight.  
 

Chromium Reduction potential 

Synechocystis sp. P2A in alginate beads and 
free form were allowed to grow in BG11 medium 
supplemented with 100µg/ml K2CrO4. 
Diphenylcarbazide method (DELEO; EHRLICH, 
1994) was used to measure concentration of 
remaining chromium at the end of experiment. 

Chromium reduction potential was estimated as the 
concentration difference Cr (VI) between inoculated 
cultures and sterile controls. The experiment was 
done in BG11 medium with pH 6, 7 and 8. Bacterial 
growth was monitored by optical density of medium 
at 730nm; beads were first solubilized in potassium 
phosphate buffer before taking Optical density. 
 

Statistical analysis 

All experiments are done at least in 
duplicate. Results of all repetitions were analyzed 
together by one-way analysis of variance (ANOVA) 
at P ≤0.05 using SPSS software (SPSS Inc., 
Chicago IL). 

  
RESULTS 

 

Entrapment of Synechocystis in alginate beads 
Cyanobacteria Synechocystis sp. P2A was 

immobilized in form of alginate beads using six 
different concentrations (w/v) of sodium alginate, 
ranging 1.2% to 3.4%.  Successful entrapment of 
cyanobacteria was achieved and cells remained 
viable during encapsulation and multiplied inside 
beads. Color of bead turned dark green after five 
days of incubation due to growth of cyanobacteria. 
To verify presence of unicellular cyanobacteria; a 
single bead after ten days of growth was sliced on 
the glass slide and observe under microscope. Beads 
with less concentration of alginate were smaller in 
size but more fragile. Viability and multiplication of 
cyanobacterial cells were checked by taking 
CFU/bead at every third day (Fig. 1). Bacterial 
growth continued to increase within alginate beads 
for fifteen days in BG11 medium.  It was observed 
that after fifteen days of incubation in medium 
beads became very fragile and even release of cells 
in growth medium from beads if continued to grow.

 

 
Figure 1. Growth response of entrapped Synechocystis cells in beads of different alginate w/v percentage, 

showing a gradual increase in CFU/bead with time 



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Although all cyanobacterial cells remained 
viable and multiplied in beads of all alginate 
concentrations; 2.6% was selected for further 
studies as a compromise between algal growth and 
bead stability.  Alginate beads containing 
Synechocystis P2A can be stored in dry or wet forms 
for more than six months without the loss of 
activity.   

 
Indole acetic acid (IAA) production by alginate 

entrapped cells  
Indole-3-acetic acid is the most important 

naturally occurring auxin and is implicated in many 
aspects of plant growth and development 

(SPAEPAN et al., 2007; ZHAO, 2010).  Release of 
indoleacetic acid (IAA) and related compounds 
from entrapped cyanoacterial cells in surrounding 
medium was successfully detected by colorimetric 
method. Amount of released IAA was measured 
every third day of growth (Table 1). The aim was to 
check any negative effect on production and release 
of IAA by entrapped Synechocystis P2A as well as 
to check stability of bead structure in presence of 
tryptophan. IAA production increased with the 
increase of cyanobacterial growth. There was no 
significant difference of cyanobacterial growth and 
stability of beads between beads grown in BG11 and 
that grown in BG11 supplemented with tryptophan.

 
Table 1. Indoleacetic acid (IAA) release in tryptophan supplemented BG11 medium by Synechocystis sp.  P2A  

Alginate Conc. 
(%)(w/v) 

IAA concentration (µ g/ml)1 

Day 3 Day 6 Day 9 Day 13 

2.2 11±0.4 38±0.0 70±1.0 85±0.0 
2.6 9±0.3 37±1.0 56±1.0 79±0.5 
3 10.5±0.5 36.4±0.2 56±0.3 72±0.2 

3.4 10±0.2 15±0.5 33±0.5 70±1.0 
1 Values are mean of two replicates. 
 

IAA production from coated alginate beads  
Alginate beads were treated with different 

chemicals to prepare capsules. Coating increased the 
mechanical and chemical stability of beads and 
prevented cell release in medium. Fig. 2 shows IAA 
production by alginate beads, chitosan coated and 
chitosan-PEG coated beads at three different pH. In 

all formulations maximum production of IAA was 
at pH-7. IAA release from cells in chitosan coated 
alginate beads only decreased 18% and 23% at pH 6 
and 7 respectively; while in free form and in other 
formulations, there was decrease in IAA production 
from 7% to 70%. 

 

 
Figure 2. Indoleacetic acid (IAA) production by Synechocystis sp. P2A in four different forms in BG11 

medium at pH 6, 7 and 8. Values are mean of two replicates. Free cells (White bars); alginate beads 
cells (dotted bars); alginate chitosan beads with cells (horizontal dashed bars) and alginate chitosan 
polyethylene glycol beads (lined bar). 

 



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Plant growth experiment 
A pot experiment was performed to study 

the effect of phytoharmone producing Synechocystis 
sp. P2A in different formulations on growth of 
wheat (Triticum aestivum) seeds. Growth 
parameters of wheat seedlings grown with 
Synechocystis inoculum in free and in different 
encapsulated forms are given in Table 2.  Empty 
beads were also inoculated as control to check any 
negative effect of polymers on plant growth. But no 
negative effect was noted in any growth parameter. 
Only Chitosan coated beads and free Synechocystis 
inoculated plants showed significant increase in 
shoot length (P≤0.05). Synechocystis sp. P2A has a 

significant impact on growth of roots. Chitosan 
alginate beads with Synechocystis inoculated 
seedlings showed 20% increase in root length as 
compared to non-inoculated plants. Synechocystis in 
free and other entrapment forms also significantly 
(P≤0.05) increased root length of inoculated plants. 
Chitosan alginate and Alginate-chitosan-PEG 
Synechocystis beads inoculated plants showed 
13.9% and 24% increase in dry weight as compared 
to non-inoculated plants. While free Synechocystis 
sp. P2A inoculated plants did not showed significant 
increase in dry weight as compared to control 
(P≤0.05). 

 
Table 2. Effect of Synechocystis sp. P2A in free and immobilized form on shoot length, root length, Number of 

roots and dry weight of Triticum aestivum Treatmenta 
 

 
Shoot length 

(cm) 
Root length 

(cm) 
No. of Roots 

Dry matter 
(mg/plant) 

Control 16.5±0.28 14.0±0.47 4.3±0.47 21.6±0.39 
B1 17.2±0.16 15.8±0.32* 5.0±0.0 22.6±0.39* 
B2 17.7±0.25* 17.5±0.22* 5.1±0.04 24.5±0.45* 
B3 16.5±0.34 15.9±0.30* 5.0±0.0 26.8±0.45 
A 20.3±0.5* 15.6±0.47 5.0±0.0 20.8±0.40 
F1 16.5±0.38 15.0±0.16 5.0±0.0 18.6±0.46 
F2 16.7±0.34 15.8±0.3* 4.8±0.2 21.6±0.41* 
F3 17.0±0.45 15.1±0.35 4.6±0.24 22.1±0.15 

LSD at 0.05 1.043 1.00 NS 1.17 
* indicates significantly different from control at P ≤0.05; NS indicates not significant at P ≤0.05 
a A - free Synechocystis sp. P2A; B1 - alginate beads with Synechocystis sp. P2A; B2 - alginate-chitosan beads with Synechocystis sp. 
P2A; B3 - alginate-chitosan-PEG beads with Synechocystis sp. P2A; F1 - alginate beads without Synechocystis sp. P2A; F2 - alginate-
chitosan beads without Synechocystis sp. P2A; F3 - alginate-chitosan-PEG without Synechocystis sp. P2A 

 

Chromium reduction. 
Chromium (VI) reduction potential of 

Synechocystis sp. P2A in free and immobilized form 
was measured at three different pH. 100µg/ml 
K2CrO4 was added to media and concentration of 
hexavalent chromium was detected by 
diphenylcarbazide method. Diphenylcarbazide 
specifically bind to chromium (VI) and purple 
colors develop. Chromium (VI) concentration in 
medium gradually decreased with time. At pH-6 
free cells and immobilized cells of Synechocystis 

showed same level of reduction. 40.8% reduction by 
immobilized cells and 40.7% by free cells. At pH-7 
immobilized cells showed more reduction (59.5%) 
as compared to free cells (54.2%). At pH-8 
immobilized cells showed 44.6% reduction while 
free cyanobacteria showed 47.7% reduction in 
chromium concentration. Alginate beads without 
cells were used as control at all pH, but there was no 
significance reduction by empty beads. In all pH 
maximum reduction of chromium carried out by 
immobilized bacteria at pH-7 (Figure 3).

 
 



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Figure 3. Percentage reduction of Cr (VI) at pH 6, 7 and 8 after 14 days in free form (Black bars) and alginate 

immobilized form (White bars). 
 

DISCUSSION 

 

Most root-promoting microorganisms 
synthesize indole-3-acetic acid (IAA), and their 
effect on plants mimics that of exogenous IAA.  
Tryptophan is a precursor for bacterial IAA 
biosynthesis (ONA et al., 2005); therefore 
tryptophan was added before inoculation in auxin 
production medium. Increase in tryptophan 
concentration increased the amount of IAA release 
by Synechocystis sp. P2A. Presence of tryptophan 
also increased growth of cyanobacteria. Sergeeva et 
al., (2002) proposed two reasons: First, 
cyanobacteria could directly use exogenous 
tryptophan and convert it into IAA; second, 
tryptophan could be used as a source of nitrogen 
during the initial stages of cultivation to increase 
growth. No adverse effect of tryptophan on 
cyanobacterial growth or bead stability was 
observed. In the rhizosphere tryptophan can 
originate from two sources: either released from 
degrading root and microbial cells or released from 
root exudates (SPAEPEN et al., 2007).   

This study showed, use of two polymers 
alginate and chitosan simultaneously as inoculant 
carriers for unicellular cyanobacteria. In soil, 
inoculated cyanobacteria have competition with 
native bacteria in soil. Therefore they should be 
greater in number and protected. Alginate beads act 
as reservoir of inoculated microorganism, where 
they can multiply and released into the environment.   
Alginate is a polysaccharide composed of L-
guluronic (G) and D-mannuronic acid (M) 
monomers in varying proportions and sequential 
arrangements. The gelation takes place due to the 
interaction of the calcium cations with the alginate 

G-blocks (SMIDSROD; SKJAK-BRAEK, 1990). 
The mechanical properties of gel bead depend 
strongly on the composition and concentration of 
the alginate, and on the cation or polycation used as 
a gel-inducing agent (MOREIRA et al., 2006). But 
calcium ions can be removed in presence of 
chelating agents such as phosphate, which results in 
dissolution of gel beads that is why these are 
suitable for the soil applications. When an anionic 
polymer, such as alginate and a cationic polymer, 
such as chitosan are present simultaneously in an 
aqueous solution, a polyelectrolyte complex is 
formed. Chitosan reduces cell release when applied 
as a membrane coat round a gel coat containing 
cells (ZHOU et al., 1998). Thus alginate beads and 
chitosan coated beads provide two types of systems. 
Alginate beads are easily biodegradable and cells 
are released in soil in short period. While chitosan 
coated beads are mechanically strong therefore cells 
are released slowly in soil, multiplying inside beads 
simultaneously.  

When applied to wheat seeds in pot 
experiment, double-coated Synechocystis sp. P2A 
improved growth. Cyanobacterial suspension 
inoculum improved a number of growth parameters 
in wheat plants by modifying their endogenous 
phytohormones (HUSSAIN; HASNAIN, 2011). The 
production of growth promoting substances by 
cyanobacteria and their direct growth promoting 
effect on a rice crop was shown by Kannaiyan et al., 
(1997). Forvarious plant growth promoting 
rhizobacteria, it has been demonstrated that 
enhanced root proliferation is related to bacterial 
IAA biosynthesis.  Studies with Azospirillum 
mutants altered in IAA production support the view 
that increased rooting is caused by Azospirillum 



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IAA synthesis (DOBBELAERE et al., 1999). This 
increased rooting enhances plant mineral uptake and 
root exudation, which in turn stimulates bacterial 
colonization and thus amplifies the inoculation 
effect (DOBBELAERE et al., 1999).  

Chitosan alginate and Alginate-chitosan-
PEG Synechocystis beads inoculated plants showed 
13.9% and 24% increase in dry weight as compared 
to non-inoculated plants. While free Synechocystis 
sp. P2A inoculated plants did not showed significant 
increase in dry weight as compared to control 
(P≤0.05).  Increased activity of cyanobacteria when 
inoculated in immobilized form to that of free form 
could be attributed to several reasons. There are 
many stresses that bacteria must endure upon 
transfer to the competitive and often harsh soil 
environment. In soil inoculation some of 
cyanobacterial cells may be killed by some other 
pathogenic bacteria and therefore cannot form 
association with germinating seeds.  Entrapment 
increases resistance to stresses and reduce loss of 
bacteria. Cyanobacterial cells also enhanced the 
plant growth by providing protection against 
pathogenic microorganisms.  

Besides showing plant growth promoting 
effects, Immobilized Synechocystis sp. P2A also 

reduced hexavalent chromium. Chromium 
compounds are used in many industries and 
industrial discharges often cause environmental 
pollution. Soluble hexavalent chromium species [Cr 
(VI)] are extremely toxic and exhibit mutagenic and 
carcinogenic effects on biological systems due to 
their strong oxidizing nature. Chromate (CrO4

2−) is 
the dominant Cr (VI) species in aqueous 
environments at pH 6.5 to 9. Trivalent chromium, 
Cr (III), is less soluble and less toxic. Thus, 
reduction of Cr (VI) to Cr (III) represents a 
potentially useful detoxification process 
(ISHIBASHI et al., 1990). Synechocystis sp. P2A 
known to reduce hexavalent chromium retained its 
ability in alginate chitosan beads. Maximum 
reduction (59.5%) was observed at pH-7 by 
immobilized cells. Increase uptake of chromium 
immobilized Aulosirafertilissimain comparison to 
free cells was reported by Banerjee et al., (2004). 

In conclusion, alginate beads containing 
Synechocystissp. P2A coated with chitosan showed 
improved plant growth. Entrapment of 
cyanobacterial cells in alginate chitosan beads could 
provide a unique and easy method of soil 
inoculation during sowing of seeds, to improve plant 
growth.

 
 
RESUMO: Um método de extrusão simples foi utilizado para aprisionar Synechocystis sp.P2A em esferas de 

alginato. A viabilidade, a resposta ao crescimento e a produção de ácido indolacético (IAA) a diferentes pH foram 
estudadas na Synechocystis sp.P2A imobilizada com alginato. Alginato de sódio a 2,6% (p/v) e pH-7 revelou-se ótimo 
para o crescimento de Synechocystis sp. P2A, bem como para a produção de IAA (79 µg/ml). Para preparar uma 
formulação eficaz para inoculação de plantas, as esferas de alginato foram adicionalmente modificadas por revestimento 
com quitosano ou quitosano-polietileno glicol. O efeito de todas as formulações contendo Synechocystis sp. P2A em 
forma livre e imobilizada no crescimento de Triticumaestivum foi avaliado. A inoculação no solo com Synechocystis 
aprisionado em esferas de alginato revestidas com quitosano resultou em um aumento de 20% no comprimento da raiz e 
aumento de 14% no peso seco em comparação com mudas não inoculadas. As cianobactérias livres e imobilizadas foram 
deixadas crescer em meio BG11 suplementado com 100 µg/ml de K2CrO4 e a redução do cromo foi medida a um pH 
variável. A um pH 7 a forma imobilizada apresentou 5% mais de redução do que a forma livre. O presente estudo mostrou 
que o alginato imobilizado de Synechocystis sp. P2A pode realizar funções viáveis, incluindo a produção de hormônio 
promotor do crescimento de plantas e redução de cromo e, portanto, propor um método eficiente e conveniente para 
armazenamento e uso de cianobactérias. 
 

PALAVRAS-CHAVE: Imobilização. Quitosano. Cianobactérias; Auxina; Synechocystis 
 

 
REFERENCES 

 
ARTECA, R. Plant growth substances. New York: Chapman & Hall, 1996. https://doi.org/10.1007/978-1-4757-
2451-6 
 
BANERJEE, M.; MISHRA, S.; CHATTERJEE, J. Scavenging of nickel and chromium toxicity in Aulosira 
fertilissima by immobilization: Effect on nitrogen assimilating enzymes. Electronic Journal Of 
Biotechnology, v. 7, n. 3, 2004. https://doi.org/10.2225/vol7-issue3-fulltext-9 
 



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BASHAN, Y.; HERNANDEZ, J.; LEYVA, L.; BACILIO, M. Alginate microbeads as inoculant carriers for 
plant growth-promoting bacteria. Biology And Fertility Of Soils, v. 35, n. 5, p. 359-368, 2002. 
https://doi.org/10.1007/s00374-002-0481-5 
 
DELEO, P.; EHRLICH, H. Reduction of hexavalent chromium by Pseudomonas fluorescens LB300 in batch 
and continuous cultures. Applied Microbiology And Biotechnology, v. 40, n. 5, p. 756-759, 1994. 
https://doi.org/10.1007/BF00173341 
 
DOBBELAERE, S.; CROONENBORGHS, A.; THYS, A.; BROEK, A. V.; VANDERLEYDEN, J. 
Phytostimulatory effect of Azospirillum brasilense wild type and mutant strains altered in IAA production on 
wheat. Plant and Soil, v. 212, n. 2, p. 153-162, 1999. https://doi.org/10.1023/A:1004658000815 
 
GODET, F.; BABUT, M.; BURNEL, D.; VEBER, A.; VASSEUR, P. The genotoxicity of iron and chromium 
in electroplating effluents. Mutation Research/Genetic Toxicology, v. 370, n. 1, p. 19-28, 1996. 
 
HAMEED, A.; HASNAIN, S. Cultural characteristics of chromium resistant unicellular cyanobacteria isolated 
from local environment in Pakistan. Chinese Journal of Ocean and Limnology, v. 23, n. 4, p. 433-441, 2005. 
https://doi.org/10.1007/BF02842688 
 
HUSSAIN, A.; HASNAIN, S. Phytostimulation and biofertilization in wheat by cyanobacteria. Journal Of 
Industrial Microbiology and Biotechnology, v. 38, n.1, 85-92, 2010. https://doi.org/10.1007/s10295-010-
0833-3 
 
ISHIBASHI, Y.; CERVANTES, C.; SILVER, S. Chromium reduction in Pseudomonas putida. Applied and 
Environmental Microbiology, v. 56 n. 7, p. 2268-2270, 1990. 
 
KANNAIYAN, S.; ARUNA, S. J.; KUMARI, S. M. P.; and HALL, D. O. Immobilized cyanobacteria as a 
biofertilizer for rice crops, Journal of applied phycology, v. 9, n. 2, p. 167-174, 1997. 
https://doi.org/10.1023/A:1007962025662 
 
KNOLL, A. H. Cyanobacterial nitrogen fixation in the ocean.Diversity, regulation and ecology. In: HERRERO, 
A.; FLORES, E. The cyanobacteria. Norfolk: Caister Academic Press, 2008. 
 
MANICKAVELU, A.; NADARAJAN, N.; GANESH, S. K.; RAMALINGAM, R.; RAGURAMAN, S.; 
GNANAMALAR, R. P. Organogenesis induction in rice callus by cyanobacterial extracellular 
product. African Journal of Biotechnology, v. 5, n. 5, p. 437, 2006. 
 
MOLNÁR, Z.; ÖRDÖG, V. Microalgal and cyanobacterial extracts in the tissue cultures of higher plants (pea, 
tobacco, beet). Acta Biologica Szegediensis, v. 49, n. 1-2, p. 39-40, 2005. 
 
MOREIRA, S.; MOREIRA-SANTOS, M.; GUILHERMINO, L.; RIBEIRO, R. Immobilization of the marine 
microalga Phaeodactylum tricornutum in alginate for in situ experiments: Bead stability and suitability. 
Enzyme And Microbial Technology, v. 38, n. 1-2, p. 135-141, 2006. 
https://doi.org/10.1016/j.enzmictec.2005.05.005 
 
ONA, O.; IMPE, J.; PRINSEN, E.; VANDERLEYDEN, J. Growth and indole-3-acetic acid biosynthesis of 
Azospirillum brasilense Sp245 is environmentally controlled. FEMS Microbiology Letters, v. 246 n. 1, p. 
125-132, 2005. https://doi.org/10.1016/j.femsle.2005.03.048 
 
RAMÍREZ-DÍAZ, M.; DÍAZ-PÉREZ, C.; Vargas, E.; Riveros-Rosas, H.; Campos-García, J.; Cervantes, C. 
Mechanisms of bacterial resistance to chromium compounds. Biometals, v. 21, n. 3, p. 321-332, 2007. 
https://doi.org/10.1007/s10534-007-9121-8 

 



1600 
Indoleacetic acid…      KHURSHID, S. ZAHID, C. HASNAIN, S.  

Biosci. J., Uberlândia, v. 33, n. 6, p. 1592-1600, Nov./Dec. 2017 

RIPPKA, R.; DERUELLES, J.; WATERBURY, J.; HERDMAN, M.; STANIER, R. Generic Assignments, 
Strain Histories and Properties of Pure Cultures of Cyanobacteria. Journal Of General Microbiology, v. 111, 
n. 1, p. 1-61, (1979). https://doi.org/10.1099/00221287-111-1-1 
 
SANTONEN, T. Inorganic chromium(III) compounds. Geneva: World Health Organization, 2009. 
 
SERGEEVA, E.; LIAIMER, A.; BERGMAN, B. Evidence for production of the phytohormone indole-3-acetic 
acid by cyanobacteria. Planta, v. 215 n. 2, p. 229-238, 2002. https://doi.org/10.1007/s00425-002-0749-x 
 
SMIDSRØD, O.; SKJA, G. Alginate as immobilization matrix for cells. Trends in biotechnology, v. 8, p. 71-
78, 1990. https://doi.org/10.1016/0167-7799(90)90139-O 
 
SPAEPEN, S.; VANDERLEYDEN, J;  Remans, R. Indole-3-acetic acid in microbial and microorganism-plant 
signaling. FEMS Microbiology Reviews, v. 31, n. 4, p. 425-448, 2007.  https://doi.org/10.1111/j.1574-
6976.2007.00072.x 
 
TANG, W. Y; BORNER, J. Enzymes involved in synthesis and breakdown of indoleacetic acid. In: Modern 
Methods of Plant Analysis, 7 eds;  PAECH, K;  TRACEY, M.V,  Gohingen, Heidelberg: Springer Verlag, 
1979, p. 238–241. 
 
WU, Z.; ZHAO, Y.; KALEEM, I.; LI, C. Preparation of calcium–alginate microcapsuled microbial fertilizer 
coating Klebsiella oxytoca Rs-5 and its performance under salinity stress. European Journal of Soil Biology, 
v. 47 n.2, p. 152-159, 2011. https://doi.org/10.1016/j.ejsobi.2010.11.008 
 
ZHAO, Y. Auxin Biosynthesis and Its Role in Plant Development. Annual Review of Plant Biology, v. 61, v. 
1, 49-64, 2010. 
 
ZHOU, Y., MARTINS, E., GROBOILLOT, A., CHAMPAGNE, C., & NEUFELD, R. Spectrophotometric 
quantification of lactic bacteria in alginate and control of cell release with chitosan coating. Journal of 
Applied Microbiology, v. 84, n. 3, p. 342-348, 1998. https://doi.org/10.1046/j.1365-2672.1998.00348.x