Toxicology, 5 (1975) 69-77

© Elsevicr/Noith Holland, Amsterdam - Printed in The Netherlands

POTENTIATION OF CARBON TETRACHLORIDE 11EPATOTOXICITY
]N RATS BY PRETREATMENT WITH POLYCHLORINATED BIPHENYLS

GARY P. CARLSON
Department of Pharmacology and Toxicology, College of Pharmacy, University of Rhode
Island, Kingston, li.l. 02881 (U.S.A.)
(Received March 3 Gib, 197 5)

(Accepted May 6th, 1975)

SUMMARY

Pretreatment of male rats with Aroclor 1254 at a dose of 25 mg/kg i.p. for
6 days resulted in potentiation of the hepatotoxicity of inhaled carbon
tetrachloride (CC1«) as evidenced by a decrease in liver glucose-6-phosphalase and elevations of serum glutamic oxalacetic transaminase (SGOT), se­
rum glutamic pyruvic transaminase (SGPT), isocitrate dehydrogenase, and
sorbitol dehydrogenase. Aroclor 1254 alone did not demonstrate hepatotox­
icity. Aroclor 1264 administration resulted in large increases in cytochrome
c reductase, cytochrome P-450 (448) and p-nitroanisole demethylation. Sub­
sequent exposure to CC14 vapor resulted in over 70% decreases in the latter
two parameters. The potentiation was dose-dependent with a dose of 5
mg/kg or higher being effective. Aroclor 1260 administration gave results
similar to those of Aroclor 1254, but Aroclor 1221 enhanced CC14 toxicity
to a lesser extent.

INTRODUCTION

Since McLean and McLean [1] first demonstrated that the enzyme-induc­
ing agent DDT was capable of potentiating the toxicity of CC)4> many
investigators have found this to be true of other enzyme-inducing agents
such as phenobarbetal [2—4). In addition to phenobarbital and DDT, other
investigators have looked at the influence of the polycyclic hydrocarbon
type inducers which differ in the microsomal carbon monoxide binding pig­
ment induced, i.e. P-448 rather than P-450, and in the spectrum of enzymes
induced [6] Pitchumoni et al. [6] demonstrated that benzo[a]pyrene was
similar to phenobarbital in enhancing the toxicity of CC14. However, Suarez
Abbreviations1. DDT, 1,1 ,l-trichloro-2,2-bis(pclilorophonyl)ethanc; PCB, polychlorinated
biphenyl; SOOT, serum glutamic oxalacetic transaminase; SGl’T, serum glutamic pyruvic
transaminase.

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et al. [3] demonstrated that 3-methylcholanthrene protected against the
hepalotoxicity of CCI4, It thus appears that enhancement versus protection
is not simply a matter of cytochrome P-450 versus P-448.
Recently Alvaros and coworkers |7) have shown that the polychlorinated
biphenyls are unique as enzyme-inducing agents in that they induce the
formation of cytochrome P-448 as does 3-methylcholanthrene, but they
resemble phenobarbita! in that they bring about a more general type of
induction. In view of this uniqueness, it was of interest to ascertain what
effects these compounds have on CCI4 toxicity.
Although the PCB’s as commercially used both in the past and in the
present are complex mixtures, they are numbered according to the percent
chlorine by weight, i.e., Aroclor 1254 contains 64% chlorine. Since the
chlorine content appears to have an influence on the inducing potential of
the PCB’s [8,9], it was also important to determine if percent chlorine
would be a factor in alteration of CC14 toxicity.
METHODS

Adult male albino rats (Charles River Breeding Laboratories) were used.
They were allowed food and water ad lib. and were housed in temperatureand light-controlled rooms. They were injected i.p. with Aroclor 1254 dis­
solved in com oil at a dose of 25 mg/kg unless otherwise indicated, Controls
received com oil alone. Injections were made daily for 6 days and 24 h after
the last dose the rats were exposed to CC14 vapor in a dynamic inhalation
chamber [10] for a period of 2 h. Chamber concentrations were determined
U6ing a Packard gas chromatograph with a flame ionization detector. 22 h
after exposure the rats were lightly anesthetized with ether, liver and tail
vein blood samples taken and various parameters of hepatotoxicity were
assessed.
Liver and body weights were recorded. Liver glucose-6-phosphatase was
measured using the procedure, of Harper [11] with rnaleate buffer, pH 6.25.
p-Nitroanisole demethylation was determined according to the method of
Netter and Seidel [12] as modified by Kinoshita et al. [13]. SGOT and
SGPT transaminases were measured utilizing the method of Reitman and
Frankel [14]. Isocitrate dehydrogenase was determined ..ccording to the
procedure of Ellis and Goldberg [15] and sorbitol dehydrogenase by the
method of Gerlach [16].
In the microsomal cytochrome experiments, the livers were perfused with
cold isotonic KC1, removed, and homogenized -l cold isotonic KC1. The
homogenate was centrifuged at 90V0 g for 20 min in a Sorvall Model RC2B
refrigerated centrifuge and the supernatant furllxr centrifuged at 105 000 g
for 1 h in an International Model IVGO Ultracentrifuge. Cytochrome c reduc­
tase activity and cytochrome P-450 content in the resulting microsomal
fraction were measured according to the methods of Dallner [17]. Protein
concentrations of the microsomes were determined by the method of Lowry
et al. [18].
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The value expressed is the mean i standard error. Student’s t test was used
to compare means at a chosen level of significance of P- 0.05.
RESULTS

The effects of exposing the rats to 3600 ppm of CC14 for 2 h on 3
parameters are presented in Table 1. Pretreatment with Aroclor 1254 re­
sulted in an increase in the liver to body weight ratio. This increase was still
greater in those animals exposed to CC14, although CC14 exposure by itself
did not alter the ratio. At this level of exposure there was a small decrease in
liver glucose-6-phosphatase activity due to the CC14 alone. However, in those
animals pretreated with Aroclor 1254 there was a large decrease in activity
to one-third of the air-exposed level. As a further indication of damage to
the functioning of the liver, drug metabolism was measured since this is
known to be decreased by CC14 and the effect potentiated by phenobnrbilal
but protected against by 3-methylcholanthrene [4]. As indicated in Table I,
a decrease in activity was seen v/ith CC14 inhalation. Aroclor 1254 adminis­
tration resulted in an 8-fold increase in activity which decreased dramatically
following CC14 inhalation.
To further study the potentiation by Aroclor 1254 on the decrease in
microsomal enzyme activity due to CCI4, animals were exposed to 4200
ppm of CC14 and cytochrome c reductase activity and cytochrome P-450
content were measured. As indicated in Table II, cytochrome c reductase
activity was elevated 2-fold by Aroclor 1254. In neither the controls nor the
Aroclor-pretreated rats was the uctivit.y altered by CC14. In the case of the
P-460 (P-448) content, Aroclor 1254 pretreatment resulted in a 3-fold in­
crease in this cytochrome. CCI4 inhalation resulted in a decrease in both the

TABLE I
EFFECT OF AROCLOR 1264 AND CCI„ ON LIVER WE1GHT/BODY WEIGHT,
GLUCOSE-G-P1IOSPHATASE, AND p-NJTKOANISOLE DEM ETHYL ATI ON
Treatment

N"

Liver wt. y , 00
Body wl.

Glucose-6phosphatase1*

p-Nitroanisole
demi’ihylationc

Corn oil—Air
Corn oll-CCI4<s
Aroclor 1264®—air
Aroclor 1264—CCI4

5
6
6
6

4.26 ±0.07
4.02 * 0.16
4.96 ± 0.25*
6.911 0.1 3f-

12.0 1 0.66
10.2.1 0.58'
10.2 1 0.34
3.G i 0.37'-*

5.1 1 0.39
2.9 10.17'
43.1 1 0.42*
12.01 1.571*

* Number of rata
b amoleB P04/g/min.
e *ig/60 mg/30 min.
a 3600 ppm for 2 h.
* 26 mg/kg i.p. for 6 days.
1 Significantly different (P < 0.06) from group receiving same pretreatment.
* Significantly different (P < 0.05) from group receiving same exposure.

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to

TABLE n
EFFECT OF AROCLOR 1254 AND CC14 ON SERUM TRANSAMINASES AND MICROSOMAL CYTOCHROME c
REDUCTASE AND CYTOCHROME P-450
Treatment

Na

Corn oil—air
Com oil—CCI4*
Aroclor 1254*—air
Aroclor 1254—CCI4

5
5
5

Cytochrome c
reductaseb

Cytochrome
P-450c

SGPr1

SGOT^

76 ± 4.9
7S t 8.1
144 ± H.41
132 ± 7.21

161 ± 13.3
95 ± 18.7h
522 ± 37.3'
63 ± 20.2h

13 ±
2.3*
338 ± 43.1*-h
U±
1.4
2213 ± 193.4*-hJ

40 ±
r,.f*
446 ± 140.2b
33 *
2.3
2316 ± 297.7h-1

a Number of rats.
b nmoles of cytochrome c reduced/mg protein/min.
c Difference in absorbance between 450 and 500 nm/mg protein X 10*.
d Reitman-Frankel units
* 4200 ppm for 2 h.
f 25 mg/kg ’.p. for 6 days.
* 4 animals in this group.
h Significantly different (P < 0.05) from group receiving same pretreatment.
* Significantly different (P < 0.05) from group receiving same exposure.

C
to
*O'

STLCOPCB4010427

O'
O'

controls and in the Aroclor-pretreated groups although the magnitude of the
change in the latter case (88%) was much greater than that seen in the
controls (41%).
Serum enzyme measurements were utilized as additional indicators of
increased CCI4 toxicity. As indicated in Table 11, CC14 exposure increased
SGPT and SCOT 26-fold and 11-fold, respectively. However, in the Aroclorpretreated rats these transaminases were elevated 200-fold and 70-fold, re­
spectively. Aroelor 1264 itself was without effect.
To test the influence of the chlorine content on hepatotoxicity, Aroelor
1264 was compared with Aroelor 1221 and Aroelor 12C0 in separate experi­
ments. Two other serum enzymes, sorbitol dehydrogenase and isocitrate
dehydrogenase were used in hopes of increasing the sensitivity. Preliminary
experiments indicated no alteration of thei;e enzymes due to Aroelor 1254
alone. Therefore, Aroclor-pretreated rats exposed to air were not included in
these studies. As indicated in Table III, exposure to 2900 ppm of CC14 for
2 h did not result in a significant change in glucose-6-phosphatase activity in
the corn oil-pretrealed rats. Activity was decreased by 35% in the Aroelor
1221-prctreatcd animals. In tiro animals preheated with Aroelor 1254 the
decrease in the enzyme activity due to CC14 was 70%. In the case of the
sorbitol dehydrogenase, no activity was seen in the air controls, but, mea-

.•

TABLE III
COMPARISON OF EFFECTS OF AROCLORS 1221, 1254 AND 1260 ON CC14
HEPATOTOXICITY
.
Treatment

N*

Glucosc-6
pliosphatascb

Sorbitol
dehydrogenase0

iRocitrate
dehydrogenase1*

Corn oil—air
Corn oil—CCI^ '
1221,-CC14C
1 264r—CCU'

ft
5
5
6

15.9 i 0.75
13.5 ± 0.90
10.4 ± 0.781-'
4.7 + o.'iO'-tk

0
55 ± 22.3l
62 ± 10.7*
495 + Bft.fthJ.k

0
9 +
0.7h-1
15 1
1.6’-1
1324 i 4G5.11J'k

Corn oil—air
Corn oil—CC14 «
]254,-CC)4*
12G0'-€C14‘

6
5
5
6

19.4 ± 0.91
16.0 i■ 0.831
7.1 ± 0.99‘-l
6.7 1 O.OO1-’

0
40 ± 1.11
309 + 36.3iJ
424 i 66.71-1

0
13 3
3.0‘
670 -i 220.3lli
1110 ± 349.5,J

* Number of rats.
b ^ moles POWfi/min.
103/0.2 ml scrum. •
.
oov um

<* IU/I.

* 2900 ppm for 2 h.
* 26 mg/kg for 6 days.
* 2900 ppm for 2 h.
b 4 rats in this group.
1 Significantly different (P < 0.05) from corn oil—air group.
I Significantly different (P < 0.05) from corn oil—CCI4 group.
k Significantly different (P < 0.05) from other Aroelor prelreated group.

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surcable levels were found alter CCl 4 inhalation. These were not significantly
altered by Aroclor 1221 pretrealment but were elevated 9-fold by Aroclor
1261 pretroatinent. Similar findings were seen with the isocitrate dehydro­
genase. Only slight activity was seen with CCl4 exposure in the corn oil
controls. This was increased to a small degree (G6%) in the Aroclor 1221
pretreated rats but much elevated in the Aroclor 1254-pretreated animals
(147-fold).
Aroclor 1260 pretreatment was very similar to Aroclor 1254 (Table III).
In none of the three parameters was there a statistical difference between the
two Aroclors although they both showed remarkable potentiation of the
changes due to CCl 4,
Because of the impressive potentiating ability of Aroclor 1254 of the
hepatotoxicity of CCl 4, it was of interest to determine if even lower doses of
the Aroclor would enhance CCl 4 toxicity. Therefore, groups of rats were
injected with 5, 10 or 25 mg/kg of Aroclor i.p. for 6 days. The results as
presented in Table IV indicate thHt even at the dose of 5 mg/kg Aroclor
1254 potentiated the toxicity of CCl4 measured in terms of alterations in
liver glucose-6-phosphalase and the serum enzymes sorbitol dehydrogenase
and isocitrate dehydrogenase although in the case of the latter enzyme, the
large standard errors prevented the nearly 8-fold potentiation from being
statistically significant. It should also be noted that the potentiating ability
appeared to be dose-related.
Of further interest in view of the ability of Aroclor 1254 to potentiate
CCl4 hepatotoxicity was determining if it would also potentiate the toxicity
TABLE IV
DOSE RESPONSE OF AROCLOR 1254 ON HEPATOTOXICITY
Treatment

N*

Glucose-*)phosphatascb

Sorbitol
dehydrogenase'

Corn oil-air
Corn oil-CCI*'
Aroclor 1264'—CCI4
5 mg/kg
10 mg/kg
26 mg/kg

8
8

18.6+0.61
13.2 + 0.47*

1 ± 0.7
46 ? 9.6*

8
8
8

9.6 + 0.51*-1,
132 + 27.0*'h
8.3 0.41'-h
246 1 53.7*'h
5.8 i 0.16‘ h'i-‘ 340 i 40.8*'1''1

Isocitrale
debydrogenaaed
0
12+

3.1*

911 37.1*
819±140.0,-h
488 ± 119.7th-1

Number of rots,
b tiniolcs PC^/fj/inin.
•
e
10s/0.2 ml scrum.
III/).
* 4 200 ppm for 2 h.
I i.p. daily for 0 days.
* Significantly different (P < 0.06) from corn oil -air.
II Significantly different (P < 0.05) from corn oil- CCI4.
1 Significantly different (P < 0.05) from Arorlor 1 254—5 mg/kg
' Significantly different (P < 0.05) from Aroclor 1254 — 10 mg/ii

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TABLE V
INFLUENCE OF CONCENTRATION OF CCI* ON POTENTIATION OF HEPATOTOXJCITY BY AROCLOH I 254
Pretrcotmcnl

CCI 4“

Nb

(ppm)
Corn oil
Corn oil
Aroclor 1254 *
Corn oil
Aroclor 1264f

0
590
590
2350
2350

3
3
3
3
3

Olucosr-6*
phosphatase'

Sorbitol

IsocitraU*

dehydrogcnasert

dehydrogenase1

10.7 ± 1.00
17.6 1,0.35
10.4 ± 0.24*-h
16.1 + 0.52K
7.1 1 1.56*-’1

0
0
31 ± 3.8'h
15 1 6.0'-'
148 i 16.0*,h'1

0.7
1 +
2 ±
0.5
42 + ll.l*'h
7.3
8 1
288 t 113.6*

* 2 h exposure.
Number of rats.
0 /imolos PC^/g/min.
<> A E^6”cm X 103/0.2 ml serum.
* IU/l.
1 25 mg/Vg for 6 days.
* Signifienntly different (P < 0.05) from corn oil—air.
** Signifienntly different (P < 0.05) from group with same exposure.
1 Significantly different (/’ < 0,05) from group with same presentment.

of a lower level of CCI 4 exposure. To determine this, animals were exposed
to 690 ppm CCI 4 for 2 h and compared with animals exposed to 2350 ppm.
The data in Table V indicate that at this lower level of exposure, no toxicity
due to CCI4 alone was evidenced by any of the three parameters measured.
However, in all three cases there were significant changes in the case of the
Aroclor pretreated animals exposed to CCI4. As expected, there were
changes due to CCI4 alone when it was inhaled at the higher concentration
and these were further exacerbated in those animals pretreated with Aroclor
1254.
DISCUSSION

Although Bruckner ct ah (19] reported that Aroclor 1242 administration
resulted in liver toxicity as evidenced by dovated SGOT values, the present
experiments indicated little if any hepatotoxicity due to the Aroclor alone.
This discrepancy is probably due to live fact that Bruckner ct al. used larger
doses and/or longer time periods. CCI4 alone produced toxicity similar to
other studies concerned with its inhalation f 14 ].
That Aroclor 1264 potentiates the toxicity of CCJ4 was demonstrated in
all of the studies reported bore \s expected (ID] the administration of the
Aroclor increased the liver to body weight ratio. This was further increased
following CCI4 administration. Liver glucose-G-phosphatfise activity was de­
creased. The rises in the four serum enzymes that were measured were all
greatly increased by the presentment with Aroclor 1254.
The effects of Aroclor 1254 on dreg metabolism were us expected.
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Aroc.lor-induced increases in cytochrome r reductase and cytochrome P-450
have been shown by otiier workers 119] as lias the increase in /.-nitroanisole
demothyinlion [9]. As with phcnobarhital | 4 ], neither the normal level of
cytochrome c reductase nor flic elevated level following induction was al­
tered by CC1 ^ inhalation. However, similar to the case with phenoborbilal,
there was a dramatic decrease in P-450 content, following CC14 exposure in
those animals pretreated with the Aroclor 1254 as compared with the con­
trols. Similar comparisons ran be made with the effect on drug metabolism
as evidenced by the large decrease in /i-nitroanisole demothylation.
The comparison of the Aroclors was important in view of the findings of
Chen and DuBois [9] that the ability of Aroclors 1221, 1254 and 1260 to
induce A'-demelhylation and also EPN detoxification increased in proportion
to the chlorine content of the Aroclor but that the O-demethylation of
p-nitroanisole was induced to a greater extent by Aroclor 1254 than by
Aroclor 1260. The resulk (Table 111) indicate that the two more chlorinated
mixtures increase the hepatotoxicity of CC14 more than the less chlorinated
Aroclor 1221, although no difference was delected between the two more
chlorinated ones.
An indication that Aroclor 1254 is a potent potentiator of CCI4 toxicity
was indicated by the finding that a dose of only 5 mg/kg for 6 days was
enough to demonstrate potentiation. ftecause of the difficulty in showing
statistical significance clue to the large variation in response from animal to
animal following CC14 inhalation, it did not seem worthwhile to give lower
doses of the Aroclor. An°fher indication of its potency was the observation
that even at a lower level of CC14 (590 ppm) than is usually employed in
these studies there were significant elevations of the serum enzymes and
decrease in liver glucose-6-phosphatase in the induced animals.
A general conclusion that can be drawn from the results of these experi­
ments is that the Aroclors which induce P-448 rather than P-450 [7] arc
very potent enhancers of CC14 hepatotoxicity so that care must be taken in
considering the suggestion that 3-methykhoIanlhjene protects against CC14
by virtue of the fact that it induces P-448 [20].
ACKNOWLEDGEMENTS

The author wishes to acknowledge the able technical assistance of Mrs.
Barbara Schultz and Mrs. Nadylis Wood. The Aroclors were n gift of the
Monsanto Company, St. Louis, Missouri. The work was supported by NIEHS
Grant No. 00596.
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