BioRisk ize 83-94 (2022) Apeer-reviewed open-access journal

doi: 10.3897/biorisk.17.77483 RESEARCH ARTICLE & R Ke) RP IS k

https://biorisk.pensoft.net

Heavy metal stress response of microalgal strains
Arthronema africanum and Coelastrella sp. BGV

Zornitsa Karcheva', Zhaneta Georgieva', Alexander Tomov', Detelina Petrova',
Miroslava Zhiponova', Ivanina Vasileva?, Ganka Chaneva'

| Faculty of Biology, Sofia University “St. Kliment Ohridski’, 8 Dragan Tsankov Bul., 1164, Sofia, Bulgaria
2 Laboratory of Experimental Algology, Institute of Plant Physiology and Genetics, Bulgarian Academy of Sci-
ences, Acad. G. Bonchev Str., bl. 21, 1113, Sofia, Bulgaria

Corresponding author: Ganka Chaneva (chaneva@biofac.uni-sofia.bg)

Academic editor: Stephka Chankova | Received 1 November 2021 | Accepted 20 December 2021 | Published 21 April 2022

Citation: Karcheva Z, Georgieva Z, Tomov A, Petrova D, Zhiponova M, Vasileva I, Chaneva G (2022) Heavy
metal stress response of microalgal strains Arthronema africanum and Coelastrella sp. BGV. In: Chankova S, Peneva
V, Metcheva R, Beltcheva M, Vassilev K, Radeva G, Danova K (Eds) Current trends of ecology. BioRisk 17: 83-94.
https://doi.org/10.3897/biorisk. 17.77483

Abstract

The present study compared the stress response of two microalgal strains — Arthronema africanum (Cy-
anoprokaryota) and Coelastrella sp. BGV (Chlorophyta), after heavy metals’ treatment. Changes of algal
growth, pigment and protein content were analyzed after adding Cu, Cd and Pb (50 uM and 100 pM) to
the nutrition medium. It was found that Cd and Pb significantly inhibited growth and protein biosynthe-
sis of microalgae, but the effect of Cu remained less pronounced. In both strains, a decrease of chlorophyll
content was observed, while carotenoid content markedly increased, especially in Coelastrella sp. BGV
biomass. The addition of 100 uM Cd and 100 uM Pb to the medium caused a strong enhancement of
malondialdehyde in both microalgal strains, which corresponded to the significant increase of superoxide
dismutase and catalase activity. The antioxidant enzymes appeared to be differently altered by heavy met-
als’ exposure. The activity of SOD in the Arthronema africanum cells was most strongly affected by Cd, in
contrast to Coelastrella sp. BGV that was highly increased by 100 uM Pb. The application of 100 uM Cd
and 100 uM Pb increased in a similar manner catalase activity in both microalgae. The strains that were
studied showed a high absorption capacity for metal ions, especially for Pb, which was absorbed largely
than Cd and Cu. For that reason, we assumed that both microalga and, in particular, Coelastrella sp. BGV,

could be successfully used for treatment of contaminated water bodies.

Keywords

Arthronema africanum, catalase, Coelastrella sp., Cu, Cd, Pb, pigments, superoxide dismutase

Copyright Zornitsa Karcheva et al. This is an open access article distributed under the terms of the Creative Commons Attribution License (CC
BY 4.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

84 Zornitsa Karcheva et al. / BioRisk 17: 83-94 (2022)

Introduction

Heavy metals are among the most common environmental pollutants nowadays. In
addition to natural sources, heavy metal pollution often comes from anthropogenic
activities — mining, refining, chemical and metallurgical industries, etc. (Sibi 2019). A
large number of microorganisms, including bacteria, algae and fungi, have the ability
to absorb and uptake metals and metalloids (Al-Amin et al. 2021; Spain et al. 2021).
Microalgae (prokaryotic and eukaryotic species) may be used as an efficient and eco-
friendly alternative to the existing physicochemical methods for heavy metal removal
(Bestawi 2019; Cui et al. 2021). Cyanoprokaryotes and green microalgae have been
recently studied, due to their high potential for disposal of various pollutants and their
use in phytoremediation (Kalambate et al. 2019; Pham et al. 2020).

Heavy metals that have been usually tested for uptake were Cu, C, Ni, Pb, Zn, Hg,
Cr (Kumar et al. 2015). Cu, Cd and Pb are known to be among the most common
pollutants in natural ecosystems. Cd and Pb, being highly toxic metals, are nonessen-
tial for the growth and development of plant organisms, but Cu, although a necessary
trace element, in elevated concentrations could be also damaging. High Cd content in
the medium leads to significant inhibition of growth and photosynthesis, expressing
its toxic effect via complexing to SH-groups of proteins and inhibiting cellular respira-
tion. Excess Pb causes reduced growth and chlorosis, suppresses photosynthesis, min-
eral nutrition and water balance (Dao and Beardall 2016). Despite their micronutrient
copper requirement most algae may be damaged by Cu, which decreases rates of pho-
tosynthesis and chlorophyll biosynthesis, imbalances cell division, etc. (Yruela 2005).

Arthronema africanum (Cyanoprokaryota) is a filamentous, nonheterocystous cy-
anoprokaryote manifesting some unique morphological and physiological characteris-
tics (Komarek and Lukavsky 1988). The strain is highly adaptive, typical for extreme
desert habitats, a very promising producer of phycobiliproteins (Chaneva et al. 2007).
It is still unexplored and only a few studies are known examining its antitumor and
antioxidant properties (Iliev et al. 2006; Gardeva et al. 2014).

Coelastrella sp. BGV, a newly isolated, fast growing Bulgarian strain, (Draganova
2018; Toshkova-Yotova et al. 2019; Toshkova-Yotova et al. 2020), has also focused the
attention of researchers due to its high bioactive and antitumor capacity.

The aim of that study was to perform a comparative analysis of the stress response
of two microalgal strains, Arthronema africanum (Cyanoprokaryota) and Coelastrella
sp. BGV (Chlorophyta), after heavy metal treatment. This would contribute these
strains to find effective application in phycoremediation.

Methods

The microalgal strains were maintained as batch cultures at the Algal Culture Col-
lection, Department of Experimental Algology, IFRG, BAS. The cyanoprokaryote
Arthronema africanum, strain Lukavsky, 1981/01 (Komarek and Lukavsky 1988),

Heavy metal stress response of microalgal strains 85

CCALA (Tgebod Collection of Autotrophic Organisms, Czech Republic) was culti-
vated at 28—30 °C, on the nutrition medium based on the Allen and Arnon (1955) and
Zehnder (Staub 1961) media, modified by Chaneva et al. (2007).

The green alga Coelastrella sp. BGV, newly isolated Bulgarian strain (Dimitrova et al.
2017), was grown at 28 °C, on the Setlik nutrition medium (Setlik 1967) modified by
Georgiev et al. (1978). Both strains were intensively cultivated in 200 ml vessels, under
continuous illumination by white light, 150 umol phot m~ s"'. Carbon source was pro-
vided by bubbling sterile 2% (v/v) CO, in air (100 | hr). The algal cultures were centri-
fuged at the end of the exponential phase of growth and the biomass was further re-sus-
pended in a fresh nutrition medium at an inoculum 0.5 mg ml"! DW (dry weight). The
10-day treatment was performed by adding to the medium 50 uM and 100 uM of Cu,
Cd* and Pb* (added as CuSO,,, CdCl, and (CH,COO),Pb). These concentrations were
chosen according to data received in our previous study (Marinova et al. 2018).

Growth and physiological changes of the algal cultures were determined on the
34, 7" and 10" day of the treatment. Algal growth was monitored by the changes
of dry weight and total protein content (measured according to Lowry et al. 1951).
Pigment content was determined spectrophotometrically after methanol extraction
and calculated after McKinney (1941). Malone dialdehyde (MDA) content was de-
termined according to Dhindsa et al. (1981). Superoxide dismutase (SOD) activity
was measured after the method of Beauchamp and Fridovich (1971) and catalase
(CAT) activity — after Aebi (1984). The content of Cu, Cd and Pb in dry algal
biomass was analyzed by atomic absorption spectrophotometer Perkin-Elmer. The
experimental data were averaged of triplicate measurements and only statistically
significant results (as defined by a p-value < 0.05) were discussed.

Results

All heavy metals (Cu, Cd and Pb) that were studied inhibited A. africanum growth. The
application of 100 uM Cu and 100 uM Cd led to a significant decrease in dry biomass,
which was by 55%-57% lower than the control variant. In the initial stages of treat-
ment, on the 3 day, 50 uM Cu stimulated, albeit slightly, the growth of A. africanum
(Fig. 1). The green microalga Coelastrella sp. BGV also suffered the t toxic effect of
heavy metals, however, less pronounced than in the cyanoprokaryote. The most signif-
cant influence was observed at 100 uM Cd and 100 uM Pb when the dry algal biomass
was 30%-33% reduced on the 10" day. 50 uM Cu led to an increase of dry weight on
the 3 and 7" day. However, on the 10° day of the experiment, the accumulation of
biomass slowed and remained 17% lower than the control (Fig. 2). The lowest protein
content in A. africanum biomass was measured on the 10" day after 100 uM Cd and
100 uM Pb treatment. The least inhibition of protein biosynthesis was observed after
Cu treatment — 8%-—22% decrease (Table 1). Both Cd concentrations caused maximal
reduction of protein biosynthesis in Coelastrella sp. (-36%). The effect of copper ions
was the weakest and a decrease of about 5% was observed at 50 uM Cu (Table 1).

Zornitsa Karcheva et al. / BioRisk 17: 83-94 (2022)

86

0 day
3 day
E17 day
10 day

se ae

fe) ts) st N a 09 wo t “ °
dj dj a a o cos) ros) ro)
(JW sw) MG

Cu 50 Cu 100 Cd 50 Cd 100 Pb 50 Pb 100

control

Figure |. Influence of heavy metals (Cu, Cd, Pb) on the Arthronema africanum growth (DW, mg ml"),
measured on the 3", 7% and 10" day after treatment by Cu, Cd and Pb (each metal added in concentra-

tions 50 pM and 100 uM).

0 day
G3 day
E17 day

1.8

@ 10 day

————— |

Cu 100 Cd 50 Cd 100 Pb 50 Pb 100

Cu 50

control

Figure 2. Influence of heavy metals (Cu, Cd, Pb) on the Coelastrella sp. BGV growth (DW, mg ml"),
measured on the 3", 7“ and 10" day after treatment by Cu, Cd and Pb (each metal added in concentra-

tions 50 pM and 100 uM).

Heavy metal stress response of microalgal strains 87

Table |. Effect of heavy metals (Cu, Cd, Pb) on the protein and pigment content of Arthronema africa-
num and Coelastrella sp. BGV, 10" day.

Variant Proteins (% DW) Chlorophyll a (% DW) Carotenoids (% DW)
Arthronema africanum
control 46.8 + 1.8 1.71 + 0.06 0.29 + 0.01
Cu 50 pM 43.5+1.9 1.59 = 0.07 0.30 + 0.01
Cu 100 uM 36.6 + 1.4 0.97 + 0.04 0.22 + 0.01
Cd 50 pM 33.9 + 1.4 0.81 + 0.04 0.17 = 0.01
Cd 100 uM 28.3 + 1.3 0.62 + 0.03 0.18 + 0.01
Pb 50 uM 36.5 + 1.6 1.04 + 0.04 0.34 + 0.01
Pb 100 uM 30.7 + 1.3 0.65 + 0.02 0.33 + 0.01
Coelastrella sp. BGV

Proteins (% DW) Chlorophyll a (% DW) Chlorophyll b (% DW) Carotenoids (% DW)
control 44.8 + 1.6 1.57 + 0.07 0.64 + 0.03 0.28 + 0.01
Cu 50 pM 42.9 + 1.8 1.19 + 0.05 0.49 + 0.02 0.25 + 0.01
Cu 100 uM 33.44 1.3 1.23 + 0.06 0.44 + 0.02 0.35 = 0.01
Cd 50 pM 29.0 + 1.2 0.82 + 0.04 0.34 + 0.01 0.39 = 0.02
Cd 100 pM 28.5 + 1.1 0.63 + 0.03 0.31 + 0.01 0.54 = 0.02
Pb 50 uM 37.1 £ 1.8 0.96 + 0.04 0.38 + 0.01 0.50 + 0.02
Pb 100 nM 32.24 15 0.87 + 0.03 0.36 + 0.01 0.51 + 0.02

It was found a significant decrease of chlorophyll a biosynthesis in the A. afri-
canum cells. The severe inhibitory effect was observed at 100 uM Cd and 100 uM
Pb — a strong decrease by 62%-64%. The negative effect of Cu ions was the least
pronounced (Table 1). Cd also caused a significant decrease in the carotenoid content
of A. africanum — a decrease of about 40% compared to the control. In contrast, Cu
ions enhanced the level of carotenoids — by 24% at 100 uM Cu (Table 1). Coelastrella
sp. reacted by an extreme reduction of the amounts of chlorophyll a and chlorophyll 6
after Cd adding to the medium. Similar, though not so pronounced, was the effect of
Pb. Both metals led to a decrease of about 60% of chlorophyll a content and 50% of
chlorophyll 6. Copper ions caused the least change in the chlorophyll content (Table
1). The addition of Cd and Pb to the nutrition medium led to a strong increase in the
level of carotenoids in Coelastrella sp. After 100 pM Cd and 100 uM Pb treatment, a
93% and 82% increase in carotenoids was registered (Table 1).

Examining changes in the levels of malondialdehyde (MDA), one of the most
commonly used markers for the degree of lipid peroxidation in cells, it was found that
all studied heavy metals led to a sharp increase in MDA in A. africanum, especially Cd
and Pb (Fig. 3A). As for Coelastrella sp., the strain showed a similar trend of MDA
increase, although to a lesser extent — it was about 3 times higher in response to the
addition of Cd and Pb (Fig. 3B).

SOD activity of A. africanum increased more than twice at both Cd concentra-
tions. Less pronounced changes were observed under Cu and Pb treatment (Fig. 4A).
The activity of SOD in Coelastrella sp. has been changed in different ways — the highest
values were registered under Pb treatment (80% — 90% enhancement), as well as at
100 uM Cu. The enzyme activity remained lower than the control variant at 50 uM

88 Zornitsa Karcheva et al. / BioRisk 17: 83-94 (2022)

MDA (uumol mg” DW)
py

control Cu 50 Cu 100 Cd 50 Cd 100 Pb 50 Pb 100

:

MDA (mol mg” DW)

control Cu 50 Cu 100 Cd 50 Cd 100 Pb 50 Pb 100

Figure 3. Changes of malondialdehyde content (MDA, pmol mg DW) in the cells of Arthronema afri-
canum — A, and Coelastrella sp. BGV— B, on the 10" day after treatment by Cu, Cd and Pb (each metal
added in concentrations 50 1M and 100 uM).

Cu (Fig. 4B). It has been observed that the catalase activity varied differently compared
to SOD. In the A. africanum cells, the extreme levels were measured at 100 uM Cd
and 100 uM Pb, two times above the control. Copper ions had a lesser effect on the
enzyme activity (Fig. 5A). Similar values were obtained for CAT activity in Coelastrella
sp., which was most significantly increased at 100 uM Cd and 100 uM Pb, while Cu
did not have such a strong effect (Fig. 5B).

Both experimental strains have been shown to accumulate large amounts of the
heavy metals added to the medium. Algal cells appeared to be most willing to absorb
Pb ions, followed by Cd and Cu. Coelastrella sp. showed a particularly high tendency to
accumulate heavy metals in the biomass. ‘The green microalgal strain expressed a much
higher uptake capacity, compared to the cyanoprokaryote A. africanum (Table 2).

89

[PP Ph Pa a ae
te
teererereteeed
Sees

Heavy metal stress response of microalgal strains

140

i=} j=)
N oO ine) wo vt N
a a

(J01d 3) GOS

oS j=) i=] o °

Cu 50 Cu 100 Cd 50 Cd 100 Pb 50 Pb 100

control

i=)
N
hn

A Ae AA AA AAA AA AAA Ad
Eee ee eae re HH MSM]
Pee oe NO OOOO
Wtetststatatettatehatetstetetatetstetstetststcty

TTT TATA TATA

[ATA ATETETUTETETATETETETETESENTETESATETECETETETENE
EERE
LEER EE RR RTE CE ETO CeCe aT

SA AAASAAAAAAAAAAAAAAAAAAAAAAA

ITOTATSTOATOTATSTSRATOTaTOTe.
ateeteuuemmaeens
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A
CECECeRACATECEC Te Te CE CECE ATEN

i=) i=) i=) i=) j=) oO
o

ive) ite) T+ N

(jo1d -8W 9) GOS

Cu 50 Cu 100 Cd 50 Cd 100 Pb 50 Pb 100

control

Figure 4. Changes of superoxide dismutase activity (SOD, U mg’ prot.) in the cells of Arthronema afri-
canum — A and Coelastrella sp. BGV — B, on the 10" day after treatment by Cu, Cd and Pb (each metal

added in concentrations 50 »M and 100 pM).

iscussion

D

A detailed knowledge of heavy metals pollutants’ action is necessary for the successful

application of microalgae in the process of phytoremediation. Therefore, a screening

growing strains, able to absorb heavy metals with higher afhnity, is

required. In our experiments, it was found that treatment with Cd and Pb strongly in-
hibited the growth of Arthronema africanum and Coelastrella sp. BGV, more essentially

that one of A. africanum. (Figs 1

of promising, fast-

, 2). Cd and Pb, applied at 100 uM concentration,

affected the morphology and worsened the condition of the algal cultures.

It became clear that the effect of Cu was less pronounced and in the initial stages

of the experiment 50 pM Cu had a certain stimulating effect on growth, especially

Zornitsa Karcheva et al. / BioRisk 17: 83-94 (2022)

90

io)

oO o o Oo
(j01d Stu _ulw 4) IVD

(}04d Stu ulw 4V) IVD

Figure 5. Changes of catalase activity (CAT, AE min mg" prot.) in the cells of Arthronema africanum —

A and Coelastrella sp. BGV — B, on the 10® day after treatment by Cu, Cd and Pb (each metal added in

concentrations 50 uM and 100 uM).

Table 2. Accumulation of Cu, Cd and Pb (mg kg’ DW) in the biomass of Arthonema africanum and

Coelastrella sp. BGV, 10" day.

Pb (mg ke! DW)

v

Cu (mg ke? DW)

Variant

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N
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= OC Go = Oo Go
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OOU8 OO8

Heavy metal stress response of microalgal strains Dil

of Coelastrella sp. BGV (Fig. 2). The protein content of both strains was the least
affected by heavy metal treatment compared to the other parameters we investigated
(Table 1). It was reported (Marinova et al. 2018; Pham et al. 2020) that Cd and
Pb strongly inhibited growth of green alga Scenedesmus sp. but the strain could efh-
ciently remove Cd, Pb and Cu at low concentrations. The pigment composition was
strongly influenced by Cd and Pb, which had a pronounced inhibitory effect on the
chlorophyll content of both strains. The decrease of chlorophyll content might be a
result of distortion of its structure or inhibition of pigment biosynthesis (Shen et al.
2021). However, a significant increase of carotenoids was observed, particularly well
manifested in Coelastrella sp. BGV, which indicated their antioxidant role in stress-
ful conditions provoked by adding Cd and Pb into the medium (Table 1). It was
reported (Shen et al. 2021) that Cd ions were highly toxic to the cyanoprokaryote
Synechocystis sp., by inhibiting its growth and pigment biosynthesis. Furthermore,
the authors found a reduced carotenoid content under Cd treatment, in contrast to
our study, in which the strong enhancement of carotenoids could be considered a
protective reaction against oxidative stress caused by Cd and especially by Pb.

Heavy metals can damage membrane molecules, disturbing the homeostasis under
the enhanced generation of reactive oxygen species (ROS) and increased lipid peroxi-
dation (Ajayan and Selvaraju 2012). The level of MDA in the biomass of Coelastrella
sp. increased significantly after application of 100 uM Cu and 100 uM Pb and that
effect was particularly pronounced after Pb treatment. ‘The stress response of A. afri-
canum was much more intense and different — the largest increase in MDA levels was
measured after Cd treatment followed by Pb (Fig. 3A, B).

Microalgae develop various antioxidant mechanisms — enzymatic and non-enzy-
matic, to alleviate oxidative damage caused by heavy metal stress (Zhang et al. 2019).
Heavy metals treatment significantly increased SOD activity in both experimental
strains. The activity of SOD of A. africanum was two times enhanced under Cd stress,
while in Coelastrella sp. a similar increase in SOD was observed after the addition of
Pb (Fig. 4A, B). Cd and Pb also led to a significant increase of CAT activity, but these
changes did not strictly correspond to those of SOD and MDA levels (Fig. 5A, B). In
Coelastrella sp., the most significant increase in CAT was observed after the addition of
Pb in the medium, while in the cells of A. africanum Pb and Cd caused a similar increase
of the activity. It is obvious that the enzymatic antioxidant protection of A. africanum,
as a part of the anti-stress response, was not sufficient to overcome heavy metal toxicity,
which was manifested by the severely inhibited growth of the strain. It is likely that in
both strains the elimination of ROS involved certain additional protective mechanisms
in addition to antioxidant enzymes, which should be studied in more detail.

The results concerning physiological and biochemical changes in A. africanum and
Coelastrella sp. suggested that Cu influences the metabolic processes in the algal cells by
a different mechanism, compared to Pb and Cd. ‘That understanding was confirmed by
the way both strains accumulated heavy metals from the nutrition medium. Both mi-
croalga showed a high absorption capacity for metal ions, especially for Pb, which accu-
mulated in the biomass in much greater concentrations than copper and cadmium. The

92 Zornitsa Karcheva et al. / BioRisk 17: 83-94 (2022)

degree of TM uptake was performed as follows Pb>Cd>Cu. (Table 2). Coelastrella sp., in
particular, had a significantly higher ability for metal ion absorption, which did not affect
her growth so strongly as A. africanum. Similar results were obtained in Sc. incrassatulus
treated by 50 uM and 100 pM Cu, Cd and Pb (Goswami et al. 2014; Marinova et al.
2018). The green microalga manifested a very high absorption capacity, accumulating
predominantly Cd from the environment. For that reason, we assumed that the investi-
gated strains, and especially Coelastrella sp., could find real application in the treatment
of water bodies contaminated with Cu, Pb and Cd.

Conclusion

The obtained results supported the understanding of microalgae as very reliable for the
purposes of phytoremediation. In addition to the differences in their uptake capacity,
it is possible that one definite heavy metal ion can interact specifically with a particular
algal strain. Cd and Pb proved to be the most toxic for growth and pigment biosyn-
thesis and provoked the strongest antioxidant response and enhanced MDA levels and
activity of antioxidant enzymes in both investigated strains. The cyanoprokaryote A.
africanum was much mote sensitive to heavy metal stress, in contrast to Coelastrella sp.
BGV, which showed a significantly higher absorption potential. We believe that after
further research we could suggest Coelastrella sp. BGV as a suitable species for non-
toxic and effective heavy metals’ removal.

In conclusion, this study could contribute to expanding knowledge about the
mechanisms of heavy metal stress in microalgae, as well as their future application for
the needs of phytoremediation.

Acknowledgements

We are grateful to Prof. Plamen Pilarski, Laboratory of Experimental Algology, IPPG-
BAS, for his support in the implementation of this study. We are thankful to Prof.
Jaromir Lukavsky (Institutre of Botany, Trebon, Czech Republic) for kindly providing
Arthronema africanum strain.

‘That study was supported by grant N° 80-10-76/25.03.2021, Sofia University

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