<i>N</i>–nitrosodiethylamine cytochrome P450 induction and cytotoxicity evaluation in primary cultures of rat hepatocytes

doi:10.4236/ajmb.2011.12009

Paper Menu >>

Journal Menu >>

American Journal of Molecular Biology, 2011, 1, 70-78

doi:10.4236/ajmb.2011.12009 Published Online July 2011 (http://www.SciRP.org/journal/ajmb/

AJMB

Published Online July 2011 in SciRes. http://www.scirp.org/journal/AJMB

N–nitrosodiethylamine cytochrome P450 induction and

cytotoxicity evaluation in primary cultures of rat hepatocytes

Claudia Alessandra Fortes Aiub1,2, Gabriele Gadermaier3, Fátima Ferreira3, Israel Felzenszwalb4,

Peter Eckl1, Luis Felipe Ribeiro Pinto2

1Department of Cell Biology, Division of Genetics, Salzburg University, Salzburg, Austria;

2Department of Biochemistry, Rio de Janeiro State University, Rio de Janeiro, Brazil;

3Department of Molecular Biology, Salzburg University, Salzburg, Austria;

4Department of Biophysics and Biometry, Rio de Janeiro State University, Rio de Janeiro, Brazil.

E-mail: aiub@hotmail.com

Received 28 March 2011; revised 27 May 2011; accepted 18 June 2011.

ABSTRACT

The primary routes of potential human exposure to

N-nitrosodiethylamine (NDEA) are ingestion, inhala-

tion, and dermal contact. Air, diet and smoking con-

tribute to potential huma n exposure at levels of a few

µg of NDEA/day. Potential exposure depends on the

ability of the nitrosamines to migrate from the prod-

uct into the body. The first step in the metabolic deg-

radation of NDEA by cytochrome oxidase (CYPs)

enzymes is the introduction of a hydroxyl group and

in human esophage and liver CYP2A3 and CYP2E1

participate on this metabolism. Measuring cytotoxic-

ity in female rat primary hepatocytes cultures, were

used to understand the CYP induction and metaboli-

zation correlated with low NDEA concentrations. We

observed that NDEA at different concentrations in

the absence of CYPs inducers, was able to induce

CYP2B1, CYP2B2, CYP2E1, CYP3A1 and CYP4A3.

A positive NDEA synergistic effect on the levels of

mRNA, was observed in the presence of pyrazole

(300 µM) for CYP2B1 and CYP2B2 and for pregne-

nolone 16-α carbonitrile (0.15 µM) for CYP2E1.

Negative NDEA synergistic effects were observed for

ethanol (0.3%) for CYP3A1, pyrazol (300 µM) for

CYP2A1 and CYP2E1, and phenobarbital (1 mM)

for CYP2A1. These facts are extremally important

once that these metabolites can be directly related to

the primary DNA lesions. We consider that studies to

elucidate the biological factors that determine the

shape of the dose-response curve are crucial for low-

dose extrapol ations of risk.

Keywords: N-Nitrosodiethylamine; Cytochrome P450;

Cytotoxicity; Primary Culture; Hepatocyte; Real-Time

PCR.

1. INTRODUCTION

Cytochrome oxidase (CYPs) form a superfamily of haem-

thiolate proteins present in prokaryotes and throughout

the eukaryotes. CYPs act as mono-oxygenases, with

functions ranging from the synthesis and degradation of

endogenous steroid hormones, vitamins and fatty acid

derivatives (“endobiotics”) to the metabolism of foreign

compounds such as drugs, environmental pollutants, and

carcinogens (“xenobiotics”) [1]. The majority of the

CYP isoforms are found in the liver, however other ex-

tra-hepatic sites include the center nervous system, gas-

trointestinal tract, kidney, lungs, and adrenal glands [2].

CYP gene expression is regulated by several factors,

as gender, microsomal enzyme inducers, age, diet, and

hormones. Differences in the amounts and intrinsic ca-

pacities of CYP forms to metabolize a particular drug or

chemical may influence profoundly drug-drug interac-

tions, drug or carcinogen activation and detoxification

contributing to the development of cancer, Parkinson’s

disease, and adrenal hyperplasia [3].

N-nitrosodiethylamine (NDEA) is activated by cyto-

chrome P450 enzymes, resulting in ethylation of N and

O atoms of most bases from DNA. The N7, and O6 po-

sitions of guanine are preferable ethylated, and a lower

level of ethylation is also observed at the O4 position of

thymine [4]. O6-ethylguanine and O4-ethylthymine, if

not repaired, will lead to mutation and tumour formation

in superior animals [5]. NDEA is able to produce tu-

mours in many species of animals and in a variety of

organs, requiring metabolic activation through P450-

catalyzed α-hydroxylation, generating unstable metabo-

lites that will alkylate the DNA at the site of activation,

in order to induce tumors [6]. Till the present, there is no

evidence that NDEA is a CYP inducer or if CYP’s in-

C. A. F. Aiub et al. / American Journal of Molecular Biology 1 (2011) 70-78 71

duction can increase or decrease others previously in-

duced CYPs.

The presence of NDEA in foodstuffs has been a sub-

ject of several reviews [7-11]. Druckrey and Preussmann

(1962) postulated that NDEA formation could arise in

tobacco smoke via the interaction of nitrogen oxides and

tobacco amines [12]. Additionaly, mechanisms for the in

vivo formation of NDEA may involve chemical and en-

zymatic nitrosation especially dependent on the presence

of both nitrate and nitroreductases [13-16].

In Wistar rats, a commonly used experimental model

for oesophageal carcinogenesis, NDEA induces tumours

at low doses. When higher doses are given for a shorter

period, tumours originate mainly in the liver [5]. Rea-

sons for such interorgan differences are currently un-

known but it has been hypothesized that this could be

due to different enzymes being responsible for the me-

tabolic activation of NDEA [17,18].

The differences in the amounts and intrinsic capacities

of CYP forms to metabolize a particular chemical may

influence: drug-drug interactions, drug or carcinogen

activation and detoxification. This knowledge has con-

tributed to an increase in the scientific literature on

CYP-dependent drug metabolism. Predicting the ability

of a drug, like NDEA, to modulate CYP expression at an

early stage may permit the identification of alternative

noninducing chemical structures. For the pharmaceutical

industry the potential induction of various CYPs by

drugs candidates, is important once they can lead to tox-

icity or reduce drug-drug interactions efficacy.

During the last few years, there has been a great in-

terest in developing rapid and simple tests to identify the

effects of exposure to environmental agents that can in-

duce DNA damage. Therefore, in the present study using

primary female rat hepatocytes we 1) Analyzed the ef-

fects of six microsomal enzyme inducers on CYPs ex-

pression, and 2) Investigated NDEA participation on

CYPs mRNA regulation. The data will provide essential

information to whether classes of microsomal enzyme

affect rat CYPs mRNA levels at low NDEA doses sug-

gesting potential roles of specific ligand-activated tran-

scription factor pathways.

2. MATERIAL AND METHODS

2.1. Animal Model

This study was conducted in compliance NRC (National

Research Council and the “Guide for the Care and Use

of Laboratory Animals”. Female albine Fischer 344 rats

(F-344/DuCrl) from Charles River Laboratories (Ger-

many) between 6 - 8 weeks old were used for the ex-

periments. Light/dark regime was 12/12 h, and standart

pelleted rat feed and drinking water were supplied ad

libitum.

2.2. Hepatocyte Isolation and Culture

Hepatocytes were prepared according to the two-step

collagenase perfusion method [19] with modifications

[20]. Fischer 344 female rats were anesthetized with

sodium pentobarbital (200 mg/kg) and following hepatic

portal vein cannulation, livers were perfused with 200

mL of solution A (NaCl 142 mM, KCl 6.7 mM, HEPES

10 mM) pH 7.4, during 12 - 15 min at 15 mL/min. Liv-

ers were subsequently perfused with 200 mL of solution

C (9:1 of solution A and CaCl2 5.7mM), pH 7.4, con-

taining 0.5 mg/mL collagenase (Collagenase Sigma IV,

125 CDU/mg, CAS 9001-12-1) for 20 min at 10 mL/min.

Perfused livers were excised and dispersed in 50 mL of

solution A and shaken in a closed, sterile container at

37˚C for 10 min. Hepatocyte preparation was filtered

through 180 µm nylon filter and centrifuged at 500 rpm,

for 10 min, at 4˚C. The wash was repeated and the cells

resuspended in MEM eagle Ca++ 1.8 mM (Gibco), sup-

plemented with NaHCO3 (26.2 mM), pyruvate 1mM,

aspartic acid 0.2 mM and L-serine 0.2 mM. Hepatocytes

were counted by hemacytometry, and (2 - 5) × 105

cells/mL were added to 60 mm, and (2 - 5) × 106

cells/mL were added to 90 mm collagen-coated dishes.

Hepatocytes were allowed to attach for 2 hours. Viability,

measured by Trypan blue staining, was approximately

85% - 90% and only preparations with viabilities greater

than 80% were used in experiments. After attachment,

the medium was removed and replaced with fresh MEM

eagle Ca2+ 1.8 mM (Gibco).

2.3. Incubation of Cells

To investigate the effects of drugs on CYP induction,

primary rat hepatocytes were incubated after the first

medium changed, for 14 - 16 h with the CYP inducers

drug. Ethanol (ETOH), Pyrazole (PYR), and Phenobar-

bital (PB) were prepared in NaCl 0.9% solution and

added directly to cultures to give a final concentration of

0.3%, 300 µM and 1 mM. 3-Methylcholanthrene (3-MC),

Streptozotocin (STR) and Pregnenolone 16-



carboni-

trile (PNC) were dissolved in ethanol 30% and added to

culture medium to give a final concentration of 2 µM, 25

µM and 0.15 µM, respectively.

After 14 - 16 h in the presence or in the absence (W/O

group) of CYP inducers, rat hepatocytes were incubated

during 3 h, at NDEA final concentrations ranging from

0.21 µg/mL to 105 µg/mL. All experiments were per-

formed in triplicate, using five isogenic animals.

2.4. Cytotoxicity

The studies were performed in triplicate as described by

Eckl and Riegler (1987) with some modifications [20].

For determination of the number of apoptotic and ne-

C. A. F. Aiub et al. / American Journal of Molecular Biology 1 (2011) 70-78

crotic cells, MEM Eagle 0.4 mM was replaced by cold

fixative methanol-glacial acetic acid (3:1) for 15 min on

the petri dishes, rinsed with distilled water for 2 min and

air dried. The fixed cells were stained with DAPI (0.2

pg/ml) dissolved in McIlvaine buffer (Citric acid 0.1M,

Na2HPO4 0.2M, pH 7.0) for 40 min, washed with McIl-

vaine buffer for 2 min, briefly rinsed with distilled water

and mounted in glycerol. 1000 cells/petri dish (3000

cells per animal/group concentration) were analyzed

under the fluorescence microscope (Reichert Univar).

The cell death processes are presented as the percentage

of cells in 3000 total cells per animal/group concentra-

tion) analized. Apoptotic cells were characterized by the

occurrence of nuclear condensation, DNA fragmentation,

and perinuclear apoptotic bodies, using a fluorescence

microscopy (×100 or higher). Necroses were character-

ized by clumping, increased vacuolation and swelling on

the cell membrane.

2.5. RNA Isolation

Total RNA was isolated with TRIzol (Invitrogen, Ger-

many) and treated with DNase I (0.5 Units) (Invitrogen),

according to the manufacturer’s instructions, and disol-

ved in DEPC water. The concentration of the isolated

total RNA was spectrophotometricaly determined at

A260nm and diluted in DEPC water at 2 µg/µL. Aliquots

of RNA were analyzed by agarose/formadehyde gel

electrophoresis to check RNA integrity and stored at

–20˚C until further use.

Development of primers for quantitative Real Time

PCR Coding sequences for the genes listed in Tab le 1,

were obtained from GenBank (http://www.ncbi.nml.nih.

gov/GenBank). Target regions within the coding se-

quences were determined through nucleotide sequence

alignment comparisons of target within multiple member

gene families using Vector NTI (Informax, Inc., Be-

thesda, MD). A subfamily-specific region for each CYP

was selected as the site of hybridization for either the 5’

or 3’ CYP PCR primer, and then complementary PCR

oligos were screened on the basis of 1) Similar melting

temperatures, 2) Similar oligo length and, 3) The produ-

tion of a PCR amplicon with greater than 50% GC con-

tent. All primers were submitted to the National Center

for Biotechnological Information for nucleotide com-

parison using the basic logarithmic alignment search tool

(BLASTn) to ensure specificity.

2.6. cDNA Synthesis

First-strand cDNA synthesis was performed on the re-

maining DNase-treated total RNA which was reverse-

transcribed using Oligo primers (0.3 ng/µL) and Super-

scriptTM III bulk mix (Invitrogen), according to the

manufacter’s instructions. In addition, duplicate no tem-

plate control samples were run in identitical conditions.

Table 1. Primer sequences used for Real-Time Quantitative

RT-PCR.

Gene/locationTm ˚CPrimerSequence Amplicon bp

67.5F AGTCCCTGCCCTT

TGTACACACCGC

18S RNA

(V01270) 69.5R

ACCATC-

CAATCGGTAG-

TAGCGACGGG

152

68.1F

TCAATCCTCACTG

GCCAC-

TATGCTGGACA

CYP2A1

(J04187)

69.5R

CAGAGGGACAC-

CAAGAGCAT-

GACGCTC

68 F

CAGCCAGGTGTTT

GAGTTCTTCTCTG

CYP2B1

(AJ320166)

66.4R CCCTGTGCTTCTCC

ACAATATGGCCA

122

66.1F

ACATGTGAACA-

GAGATTTCAT-

GAGTACA-

CATCTCAT CYP2B2

(J00720)

68.3R

TGTAGACATAG-

CACTGAGAC-

CATATACA-

GAGTCCAT

148

66.8F

CTCCTCGTCATATC

CATCTGGAAGAA-

GATCT

CYP2E1

(J02627)

63.7R

TGGTGAAA-

GACTTGGGGA-

TATCCTTCAA

127

CYP3A1

63.9F

GTTTATGGAAATTC

GATGTGGAGTGCC

AT 153

(M10161) 64.4R CCCGCCGGTTTGT

GAAGACAGAAA

2.7. Real Time qRT-PCR Analysis

Quantitative RT-PCR reactions were performed using

the reagent mix and protocol contained in the BioRad

iCycler iQ Real-Time Detection System (BioRad). Re-

actions were run in duplicate, in a volume of 10 µL,

containing 5 µL of the cDNA diluted 1:20 in DEPC wa-

ter, 4.4 µL of the iQ SYBR Green Supermix and 0.6 µL

of the primers mix (forward and reverse primers) at a 3

pmol/µL. The cycle was programmed to 95˚C, 3 min; 40

× (95˚C 1 min, 65˚C 1 min and 72˚C 1 min); 95˚C 1

min; 55˚C 1 min. For the melting curve analysis, it was

used a gradient from 55˚C to 95˚C. Real-time PCR data

were collected and analyzed on a Rotor-Gene 3000

(Corbett Research). The products were checked by aga-

rose gel electrophoresis and by sequencing.

The endpoint used in the real-time PCR quantification,

CT value, is defined as the PCR cycle number that

crosses an arbitrarily placed signal threshold. Average

CT values from duplicate PCR reactions were normal-

ized to average CT values for housekeeping gene from

C. A. F. Aiub et al. / American Journal of Molecular Biology 1 (2011) 70-78 73

Tabl e 2. NDEA cytotoxicity followed administration of classi-

cal CYP inducers ETOH (0.3%), PYR (300 µM) and PB (1

mM).

Inducer Assay condi-

tions % Survival % Necrosis % Apoptosis

NaCl 0.9% 98.7 ± 0.3 1.1 ± 0.4 0.2 ± 0.1

0.21 µg/mL 98.2 ± 0.4 1.6 ± 0.3 0.2 ± 0.1

2.1 µg/mL 97.4 ± 0.5*2.4 ± 0.5* 0.2 ± 0.1

21 µg/mL 97.2 ± 0.7*2.4 ± 0.6* 0.4 ± 0.2

W/O

105 µg/mL 97.2 ± 1.0 2.5 ± 1.0 0.4 ± 0.1*

NaCl 0.9% 98.1 ± 0.6 1.4 ± 0.4 0.6 ±0.2

0.21 µg/mL 97.7 ± 0.6 1.6 ± 0.4 0.7 ± 0.1†

2.1 µg/mL 97.5 ± 0.6 1.5 ± 0.3 1.0 ± 0.3†

21 µg/mL 96.6 ± 1.4 2.5 ± 0.7 1.2 ± 0.4†

ETOH

105 µg/mL 95.7 ± 1.1 2.6 ± 0.8 1.7 ± 0.2*††

NaCl 0.9% 98.7 ± 0.5 0.9 ± 0.1 0.4 ± 0.4

0.21 µg/mL 98.1 ± 0.2 1.2 ± 0.2 0.8 ± 0.0††

2.1 µg/mL 97.0 ± 0.7 2.1 ± 0.4 0.9 ± 0.3†

21 µg/mL 95.1 ± 1.0*3.0 ± 0.2** 2.0 ± 0.8†

PYR

105 µg/mL 95.9 ± 0.4*3.0 ± 0.1** 1.1 ± 0.2†

NaCl 0.9% 98.0 ± 0.2 1.3 ± 0.1 0.8 ± 0.1††

0.21 µg/mL 97.9 ± 0.5 1.5 ± 0.3 0.7 ± 0.2†

PB 2.1 µg/mL 93.8 ± 0.3**†† 4.8 ± 0.5*† 1.4 ± 0.2††

21 µg/mL 93.4 ± 0.4**†† 4.7 ± 0.0**† 2.0 ± 0.4*††

105 µg/mL 92.9 ± 0.4**† 3.6 ± 0.3* 3.6 ± 0.1**††

Mean ± SEM of 3 female Fischer 344 rat livers. Were analysed 3000 cells

per animal/group concentration. Statistical analysis, in order to compare the

NDEA cytotoxic effect related with the control (NaCl 0.9%) shown signifi-

cant differences (*p < 0.05 and **p < 0.01) into the same inducer group.

Comparative statistical analysis were made between W/O group and the

CYP inducers group (†p < 0.05 and ††p < 0.01) at same NDEA concentra-

tion.

the same cDNA preparations (Δ CT). The ratio of ex-

pression of each CYP gene induced vs. expression of

each CYP gene spontaneously induced was calculated as

ΔΔCT. The fold induction of each CYP gene is calcu-

lated as 2–(ΔΔCT) as recommended by Perkin-Elmer. Val-

ues were reported as an average of triplicate analyses.

The amount of each gene target in different groups

was normalized to an endogenous control (18S ribo-

somal mRNA).

3. RESULTS

The incubation of the hepatocytes with either each in-

ducer or with different concentrations of NDEA alone

did not result in cell viability lower than 90%, as shown

in Tables 2 and 3.

However, a discrete cytotoxicity was observed when

PB, STR and PNC were incubated with hepatocytes in

the presence of NDEA at 2.1 - 105 µg/mL, 21 µg/mL,

and 0.21 µg/mL, respectively. Most of the cytotoxicity

was a result of the increase of the necroses rate. ETOH,

PYR and PB increased the rate of apoptoses compared to

the control group either with or without different con-

centrations of NDEA (Tables 2 and 3).

The effect of different classical CYP inducers and of

different concentrations of NDEA, either alone or to-

gether, on the expression of CYP mRNAs in rat hepato-

cytes is shown in Figures 1-5. Figure 1 shows that STR

Table 3. NDEA cytotoxicity followed administration of classi-

cal CYP inducers ETOH (0.3%), 3-MC (2 µM), STR (25 µM)

and PNC (0.15 µM)

Inducer Assay condi-

tions % Survival % Necrosis % Apoptosis

NaCl 0.9%98.1 ± 0.6 1.4 ± 0.4 0.6 ± 0.2

0.21 µg/mL97.7 ± 0.6 1.6 ± 0.4 0.7 ± 0.1

2.1 µg/mL97.5 ± 0.6 1.5 ± 0.3 1.0 ± 0.3

21 µg/mL 96.6 ± 1.4 2.5 ± 0.7 1.2 ± 0.4

ETH

105 µg/mL95.7 ± 1.1 2.6 ± 0.8 1.7 ± 0.2*

NaCl 0.9%95.4 ± 0.5 3.8 ± 0.6† 0.9 ± 0.1†

0.21 µg/mL93.6 ± 0.7 5.7 ± 0.9† 0.7 ± 0.2†

2.1 µg/mL95.6 ± 0.3 3.3 ± 0.2† 1.2 ± 0.0*

21 µg/mL 95.9 ± 0.1 2.8 ± 0.3 1.4 ± 0.1*

3-MC

105 µg/mL95.9 ± 0.6 3.1 ± 0.6 1.1 ± 0.0

NaCl 0.9%98.8 ± 0.4 0.9 ± 0.2 0.3 ± 0.2

0.21 µg/mL98.2 ± 0.0 1.1 ± 0.1 0.8 ± 0.1

2.1 µg/mL97.1 ± 0.6 2.1 ± 0.4 0.8 ± 0.2

21 µg/mL 93.7 ± 0.9*† 3.9 ± 1.0 2.5 ± 0.1**

STR

105 µg/mL96.2 ± 0.0** 2.8 ± 0.1** 1.0 ± 0.1*

NaCl 0.9%95.0 ± 0.1 4.3 ± 0.2† 0.8 ± 0.1†

0.21 µg/mL92.9 ± 0.3* 6.5 ± 0.2*†† 0.6 ± 0.1††

PNC 2.1 µg/mL95.2 ± 0.8 3.7 ± 0.9 1.1 ± 0.1

21 µg/mL 95.8 ± 0.1 3.0 ± 0.1* 1.3 ± 0.0**

105 µg/mL95.7 ± 0.5 3.1 ± 0.7 1.2 ± 0.2

Mean ± SEM of 3 female Fischer 344 rat livers. Were analysed 3000 cells

per animal/group concentration.Statistical analysis, in order to compare the

NDEA cytotoxic effect related with the control (NaCl 0.9%) shown signifi-

cant differences (*p < 0.05 and **p < 0.01) into the same inducer group.

Comparative statistical analysis were made between ETH group and the

CYP inducers group (†p < 0.05 and ††p < 0.01) at same NDEA concentra-

tion.

Figure 1. Data has been reported as fold induction of the

house keeping gene (18S), for mRNA levels of CYP2A1,

under different NDEA concentrations and CYP inducers,

measured by real-time RT-PCR.* represents the significant

difference (p < 0.05) between the NDEA treatment and the

control NaCl 0.9%, with the same inducer treatment. Ψ

represents the significant difference (p < 0.05) at same

NDEA concentration (or solvent) between the inducer con-

trol group (W/0 for ETOH, PYR and PB treatment, and

ETOH for 3-MC, STR and PNC treatment) and the inducer.

and PNC caused an induction (7- and 5-fold, respec-

tively) of CYP2A1 expression, when compared to the

solvent treated hepatocytes (W/o group with NaCl 0.9%).

NDEA produced a statistically significant decrease of

the CYP2A1 induction produced by STR (NDEA con-

C. A. F. Aiub et al. / American Journal of Molecular Biology 1 (2011) 70-78

Figure 2. Data has been reported as fold induction of the

house keeping gene (18S), for mRNA levels of CYP2B1,

under different NDEA concentrations and CYP inducers,

measured by real-time RT-PCR.* represents the signifi-

cant difference (p < 0.05) between the NDEA treatment

and the control NaCl 0.9%, with the same inducer treat-

ment. Ψ represents the significant difference (p < 0.05) at

same NDEA concentration (or solvent) between the in-

ducer control group (W/0 for ETOH, PYR and PB treat-

ment, and ETOH for 3-MC treatment) and the inducer.

STR and PNC were not performed.

centrations of 2.1 and 105 µg/mL) and by PNC (NDEA

concentrations from 2.1 to 105 µg/mL). NDEA also re-

duced CYP2A1 mRNA levels in the presence of ETOH

(NDEA at 105 µg/mL), PYR (NDEA at all doses tested),

and PB (NDEA at 2.1 µg/mL).

Figure 2 shows that PYR and PB caused an induction

of (3.6- and 8.1-fold, respectively), whereas 3-MC re-

duced (3.2-fold) CYP2B1 expression. Surprisingly,

NDEA (0.21 µg/mL) produced a 2.5-fold induction of

CYP2B1. The two highest concentrations of NDEA

tested (21 and 105 µg/mL) increased the induction pro-

duced by PYR on CYP2B1 levels (1.6 and 2-fold, re-

spectively). When NDEA (at 2.1 µg/mL) was present

with 3-MC, it abolished the decrease on CYP2B1 ex-

pression produced by 3-MC. CYP2B2 mRNA expres-

sion was also induced by PYR and PB (10- and 2.3-fold,

respectively), and decreased by 3-MC (3.4-fold), as

shown in Figure 3. NDEA caused an increase of the

CYP2B2 mRNA levels (from 2.8- to 1.5-fold at concen-

trations ranging from 0.21 to 21 µg/mL). NDEA in-

creased the induction produced by PYR on CYP2B2

expression (1.4 to 2.1-fold for NDEA concentrations

ranging from 2.1 to 105 µg/mL), and, at 21 µg/mL, it

partially decreased the reduction produced by 3-MC.

CYP2E1 expression was decreased after PYR (2.0-

fold), STR (1.8-fold) and PNC (1.6-fold) treatments, as

shown in Figure 4. Similarly to CYP2B1 and CYP2B2,

CYP2E1 was also induced by NDEA, with an inverse

relationship between the NDEA dose tested and the fold-

induction observed (from 2.6- to 1.6-fold at NDEA con-

centrations ranging from 0.21 to 21 µg/mL). However,

Figure 3. Data has been reported as fold induction of the house

keeping gene (18S), for mRNA levels of CYP2B2, under dif-

ferent NDEA concentrations and CYP inducers, measured by

real-time RT-PCR. * represents the significant difference (p <

0.05) between the NDEA treatment and the control NaCl 0.9%,

with the same inducer treatment. Ψ represents the significant

difference (p < 0.05) at same NDEA concentration (or solvent)

between the inducer control group (W/0 for ETOH, PYR and

PB treatment, and ETOH for 3-MC treatment) and the inducer.

STR and PNC were not performed.”

Figure 4. Data has been reported as fold induction of the

house keeping gene (18S), for mRNA levels of CYP2E1,

under different NDEA concentrations and CYP inducers,

measured by real-time RT-PCR. *Represents the significant

difference (p < 0.05) between the NDEA treatment and the

control NaCl 0.9%, with the same inducer treatment. Ψ

Represents the significant difference (p < 0.05) at same

NDEA concentration (or solvent) between the inducer con-

trol group (W/0 for ETOH, PYR and PB treatment, and

ETOH for 3-MC, STR and PNC treatment) and the inducer.

different from CYP2B1 and CYP2B2, CYP2E1 expres-

sion was reduced when PB and PYR were incubated

with hepatocytes in the presence of NDEA. NDEA abol-

ished the decrease in CYP2E1 expression produced by

either STR or PNC.

CYP3A1 expression was induced by PNC (47-fold),

and decreased by ETOH (2.6-fold). NDEA (2.1 mg/ml)

also induced CYP3A1 mRNA. However, NDEA de-

creased the induction produced by PNC (4.8- to 2.7-fold,

for NDEA concentrations ranging from 2.1 to 105

µg/mL) and it increased the reduction produced by

ETOH on CYP3A1 expression (1.8-fold at 105 µg/mL).

There was also a reduction of CYP3A1 when STR was

incubated with the three highest doses of NDEA tested

(from 5.5- to 3.1-fold for NDEA concentrations ranging

C. A. F. Aiub et al. / American Journal of Molecular Biology 1 (2011) 70-78 75

Figure 5. Data has been reported as fold induction of the

from 2.1 to 105 µg/mL) (Figure 5)

EA was considered a weak muta-

w that the administration of

ce at very

house keeping gene (18S), for mRNA levels of CYP3A1,

under different NDEA concentrations and CYP inducers,

measured by real-time RT-PCR. *Represents the significant

difference (p < 0.05) between the NDEA treatment and the

control NaCl 0.9%, with the same inducer treatment. Ψ

Represents the significant difference (p < 0.05) at same

NDEA concentration (or solvent) between the inducer con-

trol group (W/0 for ETOH treatment, and ETOH for 3-MC,

STR and PNC treatment) and the inducer. PYR and PB were

not performed.”

4. DISCUSSION

Until last decades, ND

gen in classical genotoxicity assays [21-23]. Aiub, et al.

[4,24-25], standardized some genotoxicity assay (Ames

and SOS chromotest) conditions in order to show the

real genotoxicity potential of NDEA. Using more sensi-

tive strains for the Ames test, positive results were de-

tected for NDEA at doses between 1.01 ng/mL and 50.64

ng/mL, when 4% metabolic activation mixture (S9 mix)

was present [16]. Although short-term in vitro tests for

genotoxicity, play an important role in the initial screen-

ing of drugs in order to check their potential to induce

mutagenic/carcinogenic effects, it is very important to

include assays that use mammalian cells, such as pri-

mary cultures of rat hepatocytes, when these systems

maintain metabolic competence for the bioactivation of

xenobiotics by CYP enzymes. The genes encoding these

enzymes are either expressed constitutively or are in-

duced by various chemicals [26]. Hepatocytes, as the

cells that express higher CYP levels, are the most suit-

able model to investigate CYP induction and their rela-

tion with drug metabolism.

In the present work we sho

rtain chemicals results in an up or down regulation of

the transcription of different forms of CYP genes.

Human and rodent CYP2E1, 2A and 3A play impor-

nt roles in the metabolic activation of carcinogenic N-

nitrosamines [27-29]. From the present data we can

suggest the necessity of CYP2A1, 2B1, 2B2, 2E1 and

3A1 induction in NDEA-treated hepatocyte rats and also

recommend a combined treatment for preparation of the

S9 fraction in short-term genotoxicity assays.

The N-nitroso compound was able to indu

w doses, CYP2A1 (0.21 µg/mL ), CYP2B2 (0.21 - 21

µg/mL ), CYP2E1 (0.21 - 105 µg/mL ) and CYP3A1

(2.1 µg/mL ), in the absence of inducers (W/O group).

Otherwise for some of the tested inducers, in the pres-

ence of NDEA, a dose-dependent inhibition of CYP2A1

mRNA (for PYR, STR and PNC treatment, Figure 1),

CYP2B2 mRNA (for ETOH, Figure 3), CYP2E1 mRNA

(ETOH, PYR, PB, STR and PNC, Figure 4), and

CYP3A1 mRNA (for ETOH and STR treatment, Figure

5) was observed. It is known that CYP enzymes exhibit

liver-specific expression driven by transcriptional factors

[30]. One possibility is that NDEA metabolites or NDEA

by itself, are able to interact negatively on the orphan

receptors (ear-2 and ear-3) or in concert with other tran-

scriptional factors (HNF-4 and ER



). Miyazaki et al.

(2005) [31] and Weymarn, et al. (205) [32] have also

shown that the pre-treatment of female A/J mice with 8-

methoxypsoralen inhibits the CYP2A family.

Although 3-MC and PB are known to induce

CYP2A1

nducer, fold in-

ress hepatic levels of CYP2E1

arkable capacity to activate low

otein [33], the effect of NDEA on CYP2A induction

by PB did not show significant effects.

Concerning NDEA’s effects as CYP i

ction of CYP2B1 and CYP2B2 present similar profile

curves although with different intensities. Both CYPs

were strongly induced by PYR (CYP2B1 at 21 - 105

µg/mL NDEA concentration; CYP2B2 at 2.1 - 105

µg/mL) suggesting a synergistic effect on mRNA CYP

expression signaling (Figures 2 and 3). An increase in

the expression of CYP2B1 and CYP2B2 mRNA levels

in the presence of PYR can lead to an increase in the

NDEA metabolites and consequently on the DNA le-

sions. The data herein, show for the first time, the induc-

tion of a CYP2B1 and CYP2B2 by NDEA and provide

basis for a mechanism by which NDEA could modulate

biological processes.

3-MC and PB supp

otein and metabolic activity in rats [34-36]. We ob-

served a decrease on the CYP2E1 mRNA levels in the

presence of NDEA for ETH, PYR and PB inducer treat-

ments. The cultures CYP pre-induced by 3-MC did not

present significantly changes compared with the control

group (ETOH).

CYP2E1 has a rem

olecular weight N-nitrosamines such as NDEA [28].

Mori, et al. (2001) observed that the inducer 4-methylpy-

razole markedly inhibit DMN activity and showed a

higher induction of CYP2B1/2, rather than CYP2E1 [37].

This is in agreement with our findings for CYP2B1,

CYP2B2 mRNA, while for CYP2E1 mRNA is inhibited,

suggesting that NDEA activates CYP2B gene expression

C. A. F. Aiub et al. / American Journal of Molecular Biology 1 (2011) 70-78

at a pretranslational level.

As described by Honkakoski and Negishi (2000) sev-

the only cul-

CYP2B

e CYPs levels of mRNA in culture, it h

has a multifunction

xchange Service

mans, L., Kamataki, T., Stegeman, J.J.,

al CYPs degrade ligands that activate the NR respon-

sible for the regulation of this specific CYP form, creat-

ing a direct feedback loop [38]. In this way, the observed

induction of CYP2B1 and CYP2B2 by NDEA and PYR,

can act inhibiting CYP2A1 and CYP2E1.

In vitro assays with rodents, generally

red cells in which CYP2B genes respond normally to

PB treatment, are primary hepatocytes [39,40]. The me-

chanism for this is based on the PB response unit, that

confers PB inducibility on heterologous promoters pre-

senting transcriptional enhancer properties [41]. Com-

paring the effects on mRNA levels on Figures 4 and 5,

for PB treatment and concerning the fact that PB en-

hances the mRNA levels of CYP2B1 > CYP2B2, inde-

pendently of NDEA concentrations, we can suggest that

NDEA or it metabolites, can enhance the mRNA levels

of CYP2B1 by others unknown mechanisms.

Comparing the mRNA levels of CYP2B1, 2,

YP2E1 and CYP3A1 from ETOH-treated hepatocytes

with the cells without inducer, we can observe a repres-

sion in their expressions (Figures 2-5). Ethanol has been

known as a substrate of CYP2E1 [42]. The constitutive

level of hepatic CYP2E1 is regulated transcriptionally

by liver-enriched transcription factors, especially by

HNF-1 [43].

Regarding thas

en shown that rat hepatocyte in the presence of 3-MC

(2 µM) and PB (1 mM) after second day in culture need

supplementation [44]. The cells were submitted to in-

ducer drugs after 6 hours platting and kept for 16 - 18

hours until NDEA added. Then, these drugs (inducers

and NDEA) remained for 3 hours in the medium.

5. CONCLUSIONS

We have demonstrated that NDEAal

action with wide spectrum induction of phase I enzymes

and alone or in combination with different inducers

would be a pertinent inducer for metabolic enzymes in in

vitro bioassays. This pattern provides a general outline

of the induction/repression effects of NDEA and the in-

ducers used, leading to further mechanistic studies.

6. ACKNOWLEDGEMENTS

The authors were supported by the Austrian E

(OEAD), Coordenação de Aperfeiçoamento de Pessoal de Nível

Superior (CAPES), Conselho Nacional de Desenvolvimento Científico

e Tecnológico (CNPq), Fundação de Amparo à Pesquisa do Estado do

Rio de Janeiro (FAPERJ) and SR2/UERJ.

REFERENCES

[1] Nelson, D.R., Koy

Feyereisen, R., Waxman, D.J., Waterman, M.R., Gotoh,

O., Coon, M.J. and Estabrook, R.W. (1996) P450 super-

family: Update on new sequences, gene mapping, acce-

ssion numbers, and nomenclature. Pharmacogenetics, 6,

1-42. doi:10.1097/00008571-199602000-00002

[2] Anzenbacher, P. and Anzenbacherova, E. (2001) Cyto-

chromes P450 and metabolism of xenobiotics. Cellular

and Molecular Life Science, 58, 737-747.

doi:10.1007/PL00000897

[3] Chang, G.W.M. and Kam, P.C.A. (1999) The physio-

logical and pharmacological roles of cytochrome P450

isoenzymes. Anaesthesia, 54, 42-50.

doi:10.1046/j.1365-2044.1999.00602.

zwalb, I. (2003) [4] Aiub, C.A.F., Pinto, L.F.R. and Felzens

N-nitrosodiethylamine mutagenicity at low concentra-

tions. Toxicology Letters, 145, 36-45.

doi:10.1016/S0378-4274(03)00263-7

[5] Lijinsky, W. (1992) Chemistry and biology of N-nitroso-

en isoamylal-

compounds. In: Coombs, M.M., Ashby, J. and Ricks, M.

Eds., Chemistry and Biology of N-nitrosocompounds,

Cambridge University Press, Cambridge.

[6] Pinto, L.F.R. (2000) Differences betwe

cohol and ethanol on the metabolism and DNA ethy-

lation of N-nitrosodietylamine in the rat. Toxicology, 151,

73-79. doi:10.1016/S0300-483X(00)00297-3

[7] Forman, D. (1987) Dietary exposure to N-nitroso com-

.(1987) A review of current literature on

s, J.H. (1989) Performed N-nitroso compounds

om-

ogenic

pounds and the risk of human cancer. Cancer Research,

6, 719-738.

[8] Hotchkiss, J.H

N-nitroso compounds. Advances in Food Research, 31,

53-115.

[9] Hotchkis

in foods and beverages. Cancer Surveys, 8, 295-321.

[10] Tricker, A.R. and Preussmann, R. (1988) N-nitrosoc

pounds and their precursors in the human environmental.

In: Hill, M.J., Eds., Nitrosamines–Toxicology and Micro-

biology, Ellis Harwood Ltd., Chichester, 88-116.

[11] Tricker, A.R. and Preussmann, R. (1991) Carcin

N-nitrosamines in the diet: Occurrence, formation, me-

chanisms and carcinogenic potential. Mutation Research,

259, 277-289. doi:10.1016/0165-1218(91)90123-4

[12] Druckrey, H. and Preussmann, R. (1962) Zur entstehung

carcinogene nitrosamine an beispiel des tabakrauchs.

Naturwissenschaften, 49, 498-501.

doi:10.1007/BF00637045

[13] Calmels, S., Ohshiiman, H. and McCoy, E. (1987) Bio-

chemical studies on the catalysis of nitrosation by bacte-

ria. Carcinogenesis, 8, 1085-1088.

doi:10.1093/carcin/8.8.1085

[14] Zou, X., Lu, N. and Liu, B. (1994) Volatile N-nitrosa-

mines and their precursors in Chinese salted fish—a

possible etiological factor for NPC in China. Internatio-

nal Journal of Cancer, 59, 155-158.

doi:10.1002/ijc.2910590202

[15] Mirvish, S.S. (1995) Role of Nitroso compounds (NOC)

and N-nitrosation in etiology of gastric, esophageal,

nasopharyngeal and bladder cancer and contribution to

cancer of known exposure to NOC. Cancer letters, 93,

17-48. doi:10.1016/0304-3835(95)03786-V

[16] Aiub, C.A., Mazzei, J.L., Pinto, L.F.R. and Felzenszwalb,

I. (2006) Evaluation of nitroreductase and acetyltran-

sferase participation in N-nitrosodiethylamine genoto-

xicity. Chemical and Biological Interactions, 161, 146-

C. A. F. Aiub et al. / American Journal of Molecular Biology 1 (2011) 70-78 77

154. doi:10.1016/j.cbi.2006.03.012

[17] Swann, P.F., Coe, A.M. and Mace, R. (1984) Ethanol

and dimethylnitrosamine and dietylnitrosamine metaboli-

sm and disposition in the rat. Possible relevance to the

influence of ethanol on human cancer incidence. Carci-

nogenesis, 5, 1337-1343. doi:10.1093/carcin/5.10.1337

[18] Aiub, C.A., Gadermeier, G., Ferreira, F., Pinto, L.F.R.,

nciulli, D., Novotny, A.R., Kli-

of chromoso-

5413-7

Felzenszwalb, I. and Eckl, P. (2011) N-nitrosodiethy-

lamine genotoxicity evaluation: A cytochrome P450 in-

duction study in rat hepatocytes. Genetics and Molecular

Research, 10, In Press.

[19] Michalopoulos, G., Cia

german, A.D., Strom, S.C. and Jirtle, R.L. (1982) Liver

regeneration studies with rat hepatocyte in primary

culture. Cancer Research, 42, 4673-4682.

[20] Eckl, P.M. and Riegler, D. (1997) Levels

mal damage in hepatocytes of wild rats living within the

area of a waste disposal plant. The Science of the Total

Environment, 196, 141-149.

doi:10.1016/S0048-9697(96)0

. and Ames, B.N. [21] McCann, J., Choi, E., Yamasaki, E

(1975) Detection of carcinogens as mutagens in the

Salmonella/microssome test: Assay of 300 chemicals.

Proceedings of Natural Academic of Science of the

United Sates of America, 72, 5135-5139.

doi:10.1073/pnas.72.12.5135

[22] Maron, M. and Ames, B.N. (1983) Revised methods for

erson, B., Haworth, S., Lawlor, T., Mor-

the Salmonella mutagenicity test, Mutation Research,

113, 173-215.

[23] Zeiger, E., And

telmans, K. and Speck, W. (1987) Salmonella mutageni-

city tests, III. Results from the testing of 255 chemicals.

Environmental Mutagenesis, 9, 1-110.

doi:10.1002/em.2860090602

[24] Aiub, C.A.F., Pinto, L.F.R. and Felzenszwalb, I. (2004)

L.F.R. and Fel-

Standardization of conditions for the metabolic activation

of N-nitrosodiethylamine in mutagenicity test. Genetics

and Molecular Research, 3, 264-272.

[25] Aiub, C.A.F., Mazzei, J.L., Pinto,

zenszwalb, I. (2004) Participation of BER and NER

pathways in the repair of DNA lesions induced at low N-

nitrosodiethylamine concentrations. Toxicology Letters,

154, 133-142. doi:10.1016/j.toxlet.2004.07.012

[26] Guengerich, F.P., Dannan, G.A., Wright S.T., Martin,

M.V., Kaminsky, L.S. (1982) Purification and charac-

terization of liver microsomal cytochromes P450: Elec-

trophoretic, spectral, catalytic, and immunochemical pro-

perties and inducibility of eight isozymes isolated from

rats treated with phenobarbital or B-naphthoflavone.

Biochemistry, 21, 6019-6030.

doi:10.1021/bi00266a045

[27] Garro, A.J., Seitz, H.K. and Lieber, C.S. (1981). Enhan-

engerich, F.P. and

cement of dimethylnitrosamine metabolism and acti-

vation to a mutagen following chronic ethanol consum-

ption. Cancer Research, 41, 120-124.

[28] Yamazaki, H., Inui, Y., Yun, C.H., Gu

Shimada, T. (1992) Cytochrome P450 2E1 and 2A6

enzymes as major catalysts for metabolic activation of N-

nitrosodialkylamines and tobacco-related nitrosamines in

human liver microsomes. Carcinogenesis, 13, 1789-1794.

doi:10.1021/bi00266a045

[29] Burke, D.A., Wedd, D.J.,

Spalding, D.J. and Wilcox, P. (1994). Evaluation of

pyrazole and ethanol induced S9 fraction in bacterial

mutagenicity testing. Mutagenesis, 9, 23-29.

doi:10.1093/mutage/9.1.23

[30] Gonzalez, F.J. and Lee, Y.-H. (1996) Constitutive expre-

azaki, H., Takeuchi, H., Saoo, K.,

ssion of hepatic cytochrome P450 genes. FASEB Journal,

10, 1112-1117.

[31] Miyazaki, M., Yam

Yokohira, M., Masumura, K., Nohmi, T., Funae, Y.,

Imaida, K. and Kamataki, T. (2005) Mechanisms of che-

mopreventive effects of 8-methoxypsoralen against 4-

(methylnitrosamino)-1-(3-pyridyl)-1-butanone-induced

mouse lung adenomas. Carcinogenesis, 26, 1947-1955.

doi:10.1093/carcin/bgi156

[32] Weymarn, L.B., Zhang, Q., Ding, X. and Hollenberg, P.F.

(2005) Effects of 8-methoxypsoralen on cytochrome

P450 2A13. Carcinogenesis, 26, 621-629.

doi:10.1093/carcin/bgh348

[33] Chang, T.K.H. and Waxman, D.J. (1996) The CYP2A

.E., Bandiera, S. Maines, S.L., Ryan, D.E. and

subfamily. In: Ioannides, C. Ed., Cytochrome P450 meta-

bolic and Toxicological Aspects. CRC Press, New York,

99-134.

[34] Thomas, P

Levin, W. (1987) Regulation of cytochrome P450-j, a

high-affinity N-nitrosodimethylamine demethylase, in rat

hepatic microsomes. Biochemistry, 26, 2280-2289.

doi:10.1021/bi00382a031

[35] Papac, D.I. and Franklin, M.R. (1988) N-benzylimida-

., Henderson, C.J., Jenke, H.J.

zole, a high magnitude inducer of rat hepatic cytochrome

P-450 exhibiting both polycyclic aromatic hydrocarbon-

and phenobarbital-type induction of phase I and phase II

drug—metabolizing enzymes. Drug and Metabolism

Disposition, 16, 259-264.

[36] Borlakoglu, J.T., Scott, A

and Wolf, C.R. (1993) Transplacental transfer of poly-

chlorinated biphenyls induces simultaneously the expre-

ssion of P450 isoenzymes and the protooncogenes

c-Ha-ras and c-raf. Biochemistry and Pharmacology, 45,

1373-1386. doi:10.1016/0006-2952(93)90035-U

[37] Mori, Y., Koide, A., Fuwa, K. and Kobayashi, Y. (2001)

N-benzylimidazole for preparation of S9 fraction with

multi-induction of metabolizing enzymes in short-term

genotoxicity assays. Mutagenesis, 16, 479-486.

doi:10.1093/mutage/16.6.479

[38] Honkakoski, P. and Negishi, M. (2000) Regulation of

cytochrome P450 (CYP) genes by nuclear receptors.

Biochemistry Journal, 347, 321-337.

doi:10.1042/0264-6021:3470321

[39] Waxman, D.J., Morrisey, J.J., Naik, S. and Jauregi, H.O.

S.A., Sinclair, J.F.

(1990) Phenobarbital induction of cytochromes P-450.

Biochemistry Journal, 271, 113-119.

[40] Sinclair, P.R., Bement, W.J., Haugen,

and Guzelian, P.S. (1990) Induction of cytochrome

P-450 and 5-aminolevulinate synthase activities in cul-

tured rat hepatocytes. Cancer Research, 50, 5219-5224.

[41] Stoltz, C., Vachon, M.H., Trottier, E., Dubois, S., Paquet

Y. and Anderson, A. (1998) The CYP2B2 phenobarbital

response unit contains an accessory factor element and a

putative glucocorticoid response element essential for

conferring maximal phenobarbital responsiveness. Jour-

nal of Biological and Chemistry, 273, 8528-8536.

doi:10.1042/0264-6021:3470321

Herriott, D., Bayliss, M.K.,

C. A. F. Aiub et al. / American Journal of Molecular Biology 1 (2011) 70-78

i, H. and Yoo, J.S.H.

AJMB

[42] Yang, C.S., Patten, C.J., Ishizak

(1991) Induction, purification and characterisation of

cytochrome P450IIE. Methods in Enzymology, 206, 595-

603. doi:10.1016/0076-6879(91)06129-Q

[43] Ueno, T. and Gonzalez, F.J. (1990) Transcriptional

okuno, Y., Tompkins, R.G.,

53337654control of the rat hepatic CYP2E1 gene. Molecullar and

Cell Biology, 10, 4495-4505.

[44] Washizu, J., Berthiaume, F., M

Toner, M. and Yarmush, M.L. (2001) Long-term mainte-

nance of cytochrome P450 activities by rat hepatocyte/

3T3 cell co-culture in heparinized human plasma. Tissue

Engenhary, 7, 691-703.

doi:10.1089/1076327017