Oktavianus


3

*Health Analyst, Faculty of Nursing
and Health, Muhammadiyah
University, Semarang
**Department of Nutrition,
Dr. Kariadi Hospital/
Diponegoro University, Semarang
***Department of Pathology,
Dr. Kariadi Hospital/
Diponegoro University, Semarang
****Department of Pharmacy,
Dr. Kariadi Hospital/
Diponegoro University, Semarang

Correspondence
Dr. Budi Santosa, S.KM, M.Si.Med
Health Analyst,
Faculty of Nursing and Health,
Muhammadiyah University,
Semarang
Jl. Kedungmundu Raya 18 Semarang
Mobile: +6281805867211
Email:
budisantosa.unimus@gmail.com

Univ Med 2015;34:3-9
DOI: 10.18051/UnivMed.2016.v35.3-9
pISSN: 1907-3062 / eISSN: 2407-2230

This open access article is distributed under
a Creative Commons Attribution-Non
Commercial-Share Alike 4.0 International
License

ABSTRACT

UNIVERSA MEDICINA
January-April, 2015January-April, 2015January-April, 2015January-April, 2015January-April, 2015                         Vol.34 - No.1                        Vol.34 - No.1                        Vol.34 - No.1                        Vol.34 - No.1                        Vol.34 - No.1

BACKGROUND
Lead acetate (Pb) inhibits heme biosynthesis through inhibition of δ-
aminolevulinic acid dehydrogenase (δ-ALAD), copro porphyrinogen
oxidase, and ferro chelatase. Zinc supplementation increases lead-binding
metallothionein proteins. The purpose of this study was to find evidence
that zinc supplementation prior to lead exposure improves heme
biosynthesis in rats.

METHODS
This was a randomized post-test only control-group design study involving
28 rats assigned to 4 groups (1 control and 3 treatment groups). The
treatment groups were supplemented with zinc at doses of 0.2, 0.4, and
0.8 mg daily by gavage for 3 weeks. From week 4 to 13, all groups were
exposed to lead 0.5 g/kg BW/day by gavage. At the end of week 13, δ-
ALAD, erythrocyte protoporphyrin (EPP), and heme concentrations were
determined by means of ELISA. One-way ANOVA, followed by
Bonferroni’s test was used to analyse the data.

RESULTS
Mean δ-ALAD concentrations decreased from the control group down to
treatment group 3 (0.24 ± 0.20; 0.15 ± 0.15; 0.12 ± 0.11; 0.05 ± 0.06 ng/
mean per unit). Mean EPP concentrations decreased from the control
group down to treatment group 3 (1.96 ± 0.50; 1.24 ± 0.24; 1.03 ± 0.05;
0.62 ± 0.16 ng/mL). Mean heme concentrations increased from the control
group up to treatment group 3 (8.07 ± 2.64; 10.11 ± 2.27; 10.04 ± 1.65;
11.41 ± 2.58 µM). ANOVA followed by Bonferroni showed that EPP
concentrations differed significantly between the control group and
treatment group 3 (p=0.00).

CONCLUSION
Zinc supplementation prior to lead exposure improves heme biosynthesis
in rats exposed to lead.

Keywords: Zinc, δ-ALAD, EPP, heme

Zinc supplementation improves heme biosynthesis
in rats exposed to lead

Budi Santosa*, Hertanto Wahyu Subagio**, Lisyani Suromo***,
and Henna Rya Sunoko****

DOI: http://dx.doi.org/10.18051/UnivMed.2015.v34.3-9



4

Santosa, Subagio, Suromo, et al                                                                                                   Zinc improves heme biosynthesis

Suplementasi seng memperbaiki biosintesis heme
pada tikus yang terpajan Pb

LATAR BELAKANG
Plumbum (Pb) asetat menghambat proses biosintesis heme melalui inhibisi enzim δ-ALAD, coproporfirinogen
oksidase, ferrokhelatase. Suplementasi seng meningkatkan protein metallothionein yang mengikat Pb. Tujuan
penelitian ini untuk membuktikan suplementasi seng sebelum pajanan Pb memperbaiki proses biosintesis heme
pada tikus.

METODA
Penelitian eksperimental dengan rancangan pra-pasca dengan menggunakan kontrol dilakukan pada 28 ekor
tikus yang secara acak sederhana dibagi menjadi 4 kelompok yaitu 1 kelompok kontrol dan 3 kelompok perlakuan.
Pada kelompok perlakuan disuplementasi seng 0,2; 0,4; 0,8 mg setiap hari melalui sonde sampai minggu ke-3,
awal minggui ke-4 kelompok kontrol dan perlakuan dipajan Pb 0,5 gr/kg BB/hari melalui sonde sampai minggu
ke-13. Akhir minggu ke-13 diperiksa δ-ALAD, EPP, heme menggunakan ELISA. Analisa data menggunakan Kruskal
Wallis, kadar EPP dan heme dengan uji one way ANOVA, dilanjutkan Bonferroni.

HASIL
Rerata δ-ALAD menurun mulai kelompok kontrol sampai perlakuan ke-3 (0,24 ± 0,20; 0,15 ± 0,15; 0,12 ± 0,11;
0,05 ± 0,06 ng rerata per unit). Rerata EPP menurun dari kelompok kontrol sampai perlakuan ke-3 (1,96 ± 0,50;
1,24 ± 0,24; 1,03 ± 0,05; 0,62 ± 0,16 ng/mL). Rerata heme meningkat dari kelompok kontrol sampai perlakuan ke-
3 (8,07± 2,64; 10,11 ± 2,27; 10,04 ± 1,65; 11,41 ± 2,58 µM). Uji ANOVA diteruskan Bonferroni menunjukkan EPP
berbeda bermakna antara kelompok kontrol dengan ke-3 kelompok perlakuan (p=0,00).

KESIMPULAN
Suplementasi seng sebelum pajanan Pb mampu memperbaiki biosisntesis pada tikus terpajan Pb.

Kata kunci: Seng, δ−ALAD, EPP, dan heme

ABSTRAK

INTRODUCTION

Health problems may have various causes;
one of these are heavy metals such as lead, which
is a hazardous air pollutant. The environment
can be polluted by lead through increased human
acitivities, such as mining, smelting, combustion
of gasoline, and the use of lead for commercial
purposes.(1) Some of the main sources of lead
poisoning are vegetables, batteries, paints,
cosmetics, jewelry, toys, gasoline, and others.
In West and Central Java the increasing use of
phosphate fertilizers, pesticides, and herbicides

have the potential to increase lead exposure. The
study conducted by Shah F et al.(2) showed that
in general anemia occurs in children between 1-
5 years old, who have higher lead levels as
compared with children without anemia. Among
children with blood lead levels of > 10 µg/dL
there are 2.87-fold more anemia cases in
comparison with children with blood lead levels
of <10 µg/dL.(3)

Lead intoxication may occur through
inhalation, ingestion of contaminated foods and
drinks, and transdermally.(4) Lead accumulates
in the mitochondria, resulting in the predominant



5

effects of lead, i.e. abnormal heme biosynthesis
and hematopoiesis.(5) Lead binds and inhibits the
sulfhydryl-rich enzymes involved in heme
b i o s y n t h e s i s ,  i . e .  δ- a m i n o l e v u l i n i c  a c i d
dehydrogenase (δ-ALAD) in the cytosol, and
coproporphyrinogen oxidase and ferrochelatase
in the mitochondria.(6) The inhibition of these
enzymes in heme biosynthesis as a result of lead
exposure occurs at the starting point, at midpoint,
and at the endpoint of heme biosynthesis. Delta-
ALAD is the initial enzyme inhibited by lead.
Inhibition of δ-ALAD prevents the conversion
o f  δ- a m i n o l e v u l i n i c  a c i d  (δ- A L A )  i n t o
porphobilinogen (PBG), causing increased δ-
ALA and δ-ALAD concentrations in the blood.
The enzyme inhibited at midpoint of heme
biosynthesis is coproporphyrinogen oxidase,
resulting in increased coproporphyrinogen
concentrations. The last enzyme inhibited by lead
in heme biosynthesis is ferrochelatase, causing
increased protoporphyrin concentrations in the
erythrocytes (free erythrocyte protoporphyrin/
EPP). (7) T h e s e  a b n o r m a l i t i e s  o f  h e m e
biosynthesis result in a reduction in heme
concentrations, leading to decreased hemoglobin
concentrations and anemia.

Various attempts have been made to treat
lead intoxication, such as the use of EDTA as
chelating agent.(8) A chelating agent binds lead
to form a polar (hydrophilic) complex that is
excreted from the body through the kidneys.
According to studies that have been conducted
on the use of EDTA, this is a therapeutic or
curative agent. However, EDTA treatment is far
f r o m  m a x i m a l ,  a n d  i t  i s  a d m i n i s t e r e d
intravenously. Therefore preventive agents
should be studied to reduce lead toxicity, one of
these being metallothionein proteins, since these
play important roles in poisoning by heavy
metals, including lead.(9) Metallothioneins are
rich in sulfhydryl groups, which form covalent
bonds with heavy metals such as lead. Studies
on metallothioneins have found correlations with
zinc levels in the body.(10) The study by Santosa
et al.(11) showed that zinc supplementation in
stepwise increasing doses, i.e. at 0.2 mg, 0.4 mg,

and 0.8 mg daily to rats (Rattus norvegicus) is
capable of increasing metallothioneins. These
d o s e s  h a v e  b e e n  c a l c u l a t e d  b y  t a k i n g  a
conversion factor from humans to rats into
consideration. Preventive zinc supplementation
has been proven to enhance hematopoesis by
reducing basophilic stippling and hematocrit
values in lead-exposed rats.(12)

The mechanism of the prevention of lead
intoxication by zinc through heme biosynthesis
is by blocking enzyme action, competition
between lead and zinc, and covalent bonding.
The blocking mechanism is due to the binding
of lead to enzyme/protein active groups, thus
inactivating the enzyme. Competition between
l e a d  a n d  z i n c  a t o m s  m a y  o c c u r  f o r  t h e
metallothionein sulfhydryl groups. For each
bond, the higher the cationic charge of the metal,
the stronger the bond. The nearer the metal is to
the noble metals the stronger its affinity. In the
periodic system of elements, lead belongs to
period VII and zinc to period IV. Therefore, the
cationic charge of lead is greater than that of
zinc, favoring lead in the competition for the
metallothionein sulfhydryl groups.(13) The
covalent bonding of Pb2+ with the metallothionein
sulfhydryl groups is stable and irreversible. The
formation of irreversible covalent bonds between
l e a d  a n d  m e t a l l o t h i o n e i n  c a u s e s  h e m e
biosynthesis to be disturbed by lead exposure.
Therefore zinc supplementation should be
studied as a preventive alternative against
inhibition of heme biosynthesis by lead exposure.
The aim of this study was to evaluate the effect
of zinc supplementation on heme biosynthesis
in lead-exposed rats.

METHODS

Study design
The present study was carried out according

to an experimental randomized post- test only
control-group design. The time period from
selection of experimental animals and their
housing up to the interventions was 100 days,
the study being conducted between December

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Santosa, Subagio, Suromo, et al                                                                                                   Zinc improves heme biosynthesis

2012 and March 2013. The study took place in
the Integrated Research and Testing Laboratory
(Laboratorium Penelitian dan Pengujian
Terpadu, LPPT), Gadjah Mada University,
Yogyakarta.

Experimental animals
The experimental animals used were 28 15-

week old male black rats (Rattus norvegicus. The
sampled size was determined by means of the
formula:
         Sample size = (t – 1) (r – 1) > 15
where t = number of groups, r = number of
experimental animals per treatment group. The
study used 3 treatment groups and and 1 control
group, so that t=4, (4-1) (r-1) > 15, r > 6. The
number of rats used was 6 per group (3 treatment
groups and 1 control group) so that total sample
size to be used in this study was 24. To the
number of rats per group, one animal was added
as reserve, in anticipation of deaths, so that the
total sample size comprised 28 rats.

Zinc supplementation
Zinc supplementtion was administered to

the treatment groups in stepwise increasing doses
of 0.2, 0.4, and 0.8 mg/day by gavage, whereas
t h e  c o n t r o l  g r o u p  d i d  n o t  r e c e i v e  z i n c
supplementation. The supplementation period
was from the first week to the third week. The 7
animals per group were assigned by simple
random sampling.(13)

Lead exposure
Lead exposure was by administration of

0.5g/kgBW/day (acute dose) for 10 weeks, from
the third week to the thirteenth week. The amount
of lead exposure was based on a previous study
on the effect of lead acetate administration to
Rattus norvegicus.(14) Lead exposure was given
in the form of a solution of 0.5 g/mL.

Measurement of blood parameters
For determination of heme biosynthesis, the

parameters investigated were serum δ-ALAD,
EPP, and heme concentrations. This was

performed by means of the ELISA assay in the
GAKI laboratory, Diponegoro University,
Semarang, for all experimental animals of the
control and treatment groups on the last day of
the thirteenth week.

Data analysis
Differences in δ-ALAD concentrations

between control and treatment groups were
analyzed by the Kruskal-Wallis test, whereas
differences in EPP and heme concentrations were
tested by one way ANOVA, followed by
Bonferroni’s test.

Ethical clearance
We conducted this study after receiving

ethical clearance from the Ethics Commission,
Faculty of Medicine, Diponegoro University/DR.
Kariadi Hospital, Semarang, under No. 339/EC/
FK/RSDK/2012. The Head of the Integrated
Research and Testing Laboratory, Gadjah Mada
University, Yogyakarta, permitted the study to
b e  c a r r i e d  o u t  a f t e r  h a v i n g  r e c e i v e d
communications regarding the ethical clearance.

RESULTS

Improvement of heme biosynthesis was
determined from δ-ALAD, EPP, and heme
concentrations. The concentrations of δ-ALAD
a n d  E P P  w e r e  d e c r e a s e d  w i t h  z i n c
supplementation, in comparison with the control
group, whereas the heme concentrations were
increased. The details of the mean differences
and statistical test results for δ-ALAD, EPP, and
heme concentrations after the thirteenth week by
treatment group are presented in Tables 1 and 2
below.

There was a difference in mean δ-ALAD
concentrations between control and treatment
groups. The highest mean was in the control
groups (0.24 ± 0.20 ng/mL) and the lowest in
the Zinc III treatment group (0.05 ± 0.06 ng/
mL). The Kruskal-Wallis test did not find any
significant differences between control and
treatment groups (p=0.16).



7

Table 1. Mean δ-ALAD, EPP, and heme concentrations after
the thirteenth week by treatment group

There were differences in mean EPP
concentrations between the control and treatment
groups. The highest mean (1.96 ± 0.50 ng/mL)
w a s  i n  t h e  c o n t r o l  g r o u p  w i t h o u t  z i n c
supplementation, and the lowest mean (0.62 ±
0.16 ng/mL) was in the treatment group receiving
zinc supplementation at a dose of 0.8 mg.
A N O VA t e s t  r e s u l t s  s h o w e d  s i g n i f i c a n t
differences between control and treatment groups
(p=0.00). There was no significant difference in
mean heme concentrations (p=0.13).

The results of Bonferroni’s muliple
comparison test showed significant differences
in mean EPP concentrations between the control
group versus the Zinc I, Zinc II and Zinc II
treatment groups (Table 2).

DISCUSSION

From the results of this study, there was a
reduction in δ-ALAD concentrations in the
treatment groups receiving zinc supplementation.
However, laboratory investigations showed a
downward trend in δ-ALAD concentrations,
starting from the control group to the treatment
groups of the lead-exposed rats. Higher zinc
doses resulted in lower δ-ALAD concentrations

in the lead-exposed rats. Lead can inhibit
precursors of heme biosynthesis, such as δ-
ALAD. The activity of δ-ALAD is disturbed by
lead, causing δ-ALA not to be converted into
porphobilinogen so that there is an increase in
δ-ALAD concentrations. These changes due to
lead exposure are acute or toxic. Further studies
are needed on the possibility of compensatory
mechanisms of the body in the form of increases
in δ-ALAD concentrations to convert δ-ALA into
porphobilinogen. The ELISA assay used in the
present study was capable of measuring all δ-
ALAD concentrations, both those from lead
inhibition as well as those excreted by the body
as a compensatory mechanism, so that δ-ALAD
concentrations increased after lead exposure.
Lead exposure of rats that have previously
received zinc supplementation resulted in
decreased δ-ALAD concentrations. This may be
because the metallothioneins that are formed will
bind the lead, while the metallothionein-bound
zinc is released and activates δ-ALAD. Because
of activation, δ-ALAD again functions normally,
being capable of converting δ-ALA into
porphobilinogen, so that the body does no longer
i n c r e a s e  δ- A L A D  c o n c e n t r a t i o n s  i n
compensation, so decreasing its concentrations.
This δ-ALAD activation improves heme
biosynthesis. Several studies support our results
stating that lead is capable of increasing δ-ALAD
and some of these studies have been conducted
on zinc and δ-ALAD.(14-16)

The EPP concentrations were reduced in the
treatment groups receiving zinc supplementation
in comparison with the control group that were
only exposed to lead. This may be explained by
the fact that the last enzyme to be inhibited by
lead in heme biosynthesis is ferrochelatase. This

Table 2. Results of Bonferroni’s test for EPP
after thirteenth week by treatment group

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Santosa, Subagio, Suromo, et al                                                                                                   Zinc improves heme biosynthesis

enzyme is present in the mitochondria and plays
a  r o l e  i n  t h e  c o m p l e x i n g  o f  F e  t o  t h e
protoporphyrin ring. ( 1 7 ) I n h i b i t i o n  o f
f e r r o c h e l a t a s e  i n c r e a s e s  e r y t h r o c y t e
protoporphyrin/EPP. Several studies have found
evidence for a correlation between lead exposure
and erythrocyte protoporphyrin. Lowry et al.(18)

s t u d i e d  t h e  e ff e c t s  o f  l e a d  e x p o s u r e  o n
cytochrome 450 (CYP) and found that low-
intensity lead exposure had no effects on
cytochrome 450 metabolism, but affected several
pathways in hemoglobin synthesis. The EPP
concentrations increased on exposure to lead of
>10 µg/dl.  EPP concentrations increased
significantly in the exposed group (battery
factory workers) as compared with controls.(15)

Shah F et al.(2) studied blood lead levels and the
prevalence of iron deficiency anemia in children
aged between 1 to 5 years, and found that
children with severe iron deficiency anemia had
higher lead levels in the blood as compared with
children with mild iron deficiency anemia. There
was a significant negative correlation between
blood lead levels and iron deficiency anemia.
These results are similar to those of zinc
supplementation, but are based on different
mechanisms. Iron complexes with porphyrin to
form heme, whereas zinc supplementation
competes with lead for metallothionein sulfhydryl
groups so that there is no accumulation of EPP.

In the present study, heme concentrations
were low after lead exposure without zinc
supplementation, whereas heme concentrations
increased, although not significantly, after lead
exposure with zinc supplementation. This proves
t h a t  z i n c  s u p p l e m e n t a t i o n  i s  c a p a b l e  o f
increasing heme synthesis in lead-exposed rats.
To increase heme concentrations significantly in
lead-exposed rats, the zinc supplementation dose
should be increased. Zinc is an important
micromineral in biological processes in the body.
The role of zinc in heme biosynthesis is with
regard to ALAD, which is a zinc-containing
enzyme that plays a role in catalyzing the
condensation of two molecules of ALA into two
molecules of water and one molecule of

porphobilinogen (PBG). Zinc deficiency inhibits
this reaction and influences heme formation.(3)

In heme synthesis, the second enzyme that plays
a role is δ-ALAD. This enzyme is exceedingly
rich in sulfhydryl groups with a stronger affinity
for lead in comparison with zinc. Full enzyme
activity requires intact or complete sulfhydryl
groups and one zinc atom for each subunit.
Enzyme activity is inhibited if the zinc is replaced
by other metals, such as lead.(3) Addition of zinc
may reverse the inhibition of δ-ALAD, but this
requires higher zinc concentrations.(14) According
to Santosa et al.(12) zinc supplementation may
increase metallothioneins that are rich in
sulfhydryl groups capable of binding lead,
causing no interference with delta ALAD (3) and
no inhibition of heme biosynthesis. Various
studies of the effect of lead exposure on heme
biosynthesis have supported the results of the
present study. Several studies on lead exposure
in battery factory workers showed increases in
the heme biosynthesis parameters δ-ALAD and
EPP, but showed decreases in heme and
hemoglobin concentrations.(18) Lead exposure in
30 automobile workers caused increases in δ-
ALAD, EPP, porphobilinogen and decreases in
heme and hemoglobin concentrations.(19) Heme
is an integral part of proteins involved in several
electron transport chains for energy renewal that
are found in nearly all forms of life. In addition,
heme is a cofactor of enzymes, including
catalase, peroxidase, cytochrome P450, and is a
part of sensor molecules.(20)

One limitation of this study was that the
ELISA assay for assessment of δ-ALAD
concentrations will measure all forms of the
enzyme, and cannot distinguish between lead-
inhibited and noninhibited forms. The clinical
i m p l i c a t i o n  o f  t h i s  s t u d y  i s  t h a t  z i n c
supplementation has been proved to reduce δ-
ALAD and EPP concentrations and to increase
heme concentrations, indicating that zinc is
capable of repairing heme biosynthesis in rats
exposed to lead, so that further studies are
necessary to apply these findings to humans.



9

CONCLUSION

Zinc supplementation at doses of 0.4 mg
and 0.8 mg significantly improves heme
biosynthesis, marked by reduced δ-ALAD and
EPP concentratioins and increased heme
concentrations.

ACKNOWLEDGMENTS

We thank the Directorate-General of the
Department of Higher Education (DIRJEN
DIKTI), Ministry of Education and Culture
(Kemendikbud), for the funding of this study.

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