Research Article

Integrated InVivoGenotoxicityAssessment of Procarbazine
HydrochlorideDemonstrates InductionofPig-a andLacZMutations,

andMicronuclei, inMutaMouseHematopoietic Cells

ClotildeMaurice,1StephenD.Dertinger,2 Carole L.Yauk,1and FrancescoMarchetti 1*
1Environmental Health Science and Research Bureau, Health Canada, Ottawa, Ontario, Canada

2Litron Laboratories, Rochester, New York

Procarbazine hydrochloride (PCH) is a DNA-reactive
hematopoietic carcinogen with potent and well-
characterized clastogenic activity. However, there is
a paucity of in vivo mutagenesis data for PCH, and
in vitro assays often fail to detect the genotoxic
effects of PCH due to the complexity of its metabolic
activation. We comprehensively evaluated the
in vivo genotoxicity of PCH on hematopoietic cells
of male MutaMouse transgenic rodents using a
study design that facilitated assessments of micronu-
clei and Pig-a mutation in circulating erythrocytes,
and lacZ mutant frequencies in bone marrow. Mice
were orally exposed to PCH (0, 6.25, 12.5, and
25 mg/kg/day) for 28 consecutive days. Blood
samples collected 2 days after cessation of treat-
ment exhibited significant dose-related induction of
micronuclei in both immature and mature erythro-
cytes. Bone marrow and blood collected 3 and

70 days after cessation of treatment also showed
significantly elevated mutant frequencies in both the
lacZ and Pig-a assays even at the lowest dose
tested. PCH-induced lacZ and Pig-a (immature and
mature erythrocytes) mutant frequencies were highly
correlated, with R2 values ≥0.956, with the excep-
tion of lacZ vs. Pig-a mutants in mature erythrocytes
at the 70-day time point (R2 = 0.902). These results
show that PCH is genotoxic in vivo and demonstrate
that the complex metabolism and resulting genotoxi-
city of PCH is best evaluated in intact animal
models. Our results further support the concept that
multiple biomarkers of genotoxicity, especially
hematopoietic cell genotoxicity, can be readily
combined into one study provided that adequate
attention is given to manifestation times. Environ.
Mol. Mutagen. 60:505–512, 2019. © 2018 Her
Majesty the Queen in Right of Canada

Key words:mutagenicity; bonemarrow; red blood cells;mutation;micronuclei

INTRODUCTION

Procarbazine hydrochloride (PCH) is a hydrazine deriva-
tive that is reemerging as a useful drug that in combination
with other anti-neoplastic agents is effective at treating
several malignancies, especially gliomas and Hodgkin’s
lymphoma (Armand et al. 2007). While clearly efficacious,
concerns about PCH treatment-induced tumors exist
(Levine and Bloomfield 1992). Mouse bioassays indicate
that lung and hematopoietic cells are important target sites
(IARC 1981). Furthermore, cancer patients treated with
PCH in combination with other antineoplastic agents have
an elevated risk of secondary malignancies, especially
hematopoietic cancers (IARC 1981; Kaldor et al. 1988).

PCH appears to be a particularly effective in vivo clasto-
gen inducing both micronuclei in bone marrow (Romagna
and Schneider 1990) and DNA breaks as detected by the
alkaline elution (Holme et al. 1989) and comet (Sasaki
et al. 1998) assays in multiple tissues including stomach
and liver. Furthermore, significant increases in median
percent tail DNA were recently reported in bone marrow,

liver, kidney, and lungs of rats, 1 day after a 28-day expo-
sure to 30 or 60 mg PCH/kg/day (Chen et al. 2019). How-
ever, PCH’s mutagenic activity is less well-characterized.
For instance, using the transgenic MutaMouse model,
Suzuki et al. (1999) showed that a single intraperitoneal
(i.p.) injection of 50 mg PCH/kg was a potent micronucleus

Additional Supporting Information may be found in the online version of
this article.

Reproduced with the permission of the Minister of Environmental Health
Science and Research Bureau

Grant sponsor: Natural Sciences and Engineering Research Council of
Canada.
Grant sponsor: Health Canada.

*Correspondence to: Francesco Marchetti, Environmental Health Science
Research Bureau, Health Canada, 50 Colombine Driveway, Ottawa,
Ontario, K1A 0K9, Canada. E-mail: francesco.marchetti@canada.ca

Received 30 October 2018; provisionally accepted 21 December 2018;
and in final form 26 December 2018

DOI: 10.1002/em.22271

Published online 28 December 2018 in
Wiley Online Library (wileyonlinelibrary.com).

Environmental andMolecularMutagenesis 60:505^512 (2019)

© 2018 TheAuthors.Environmental andMolecularMutagenesis published by Wiley Periodicals, Inc. on behalf of EnvironmentalMutagen Society.
This is an open access article under the terms of the Creative Commons Attribution License, which permits use, distribution and reproduction in any
medium, provided the original work is properly cited.

https://orcid.org/0000-0002-9435-4867
mailto:francesco.marchetti@canada.ca
http://creativecommons.org/licenses/by/4.0/


inducer in blood (mean fold change: 19.6x), while no
change to lacZ mutation frequencies were observed in mul-
tiple tissues. In contrast, PCH mutagenicity was evident in
lung, bone marrow, and spleen after five daily administrations
of 150 mg/kg by i.p. injection (Suzuki et al. 1999). Following
a 3-day exposure regimen by oral gavage Phonethepswath
et al. (2013) confirmed the strong clastogenic activity of PCH
and observed a moderate but variable mutagenic response
using the rodent phosphatidylinositol glycan-class A (Pig-a)
assay. Together with the rodent bioassay data and occurrences
of therapy-related tumors noted above, the weight of evidence
provided by in vivo data implies that PCH is a carcinogen
with a genotoxic mode of action that clearly involves clasto-
genicity, with some evidence of mutagenicity as well. Based
on these findings, the mutagenic potential of PCH deserves
more analysis and consideration, including an assessment of
the impact of longer exposure duration, different sampling
times, and a comparison of different genetic endpoints within
the same experimental system.

PCH undergoes complex metabolic activation and forms
intermediates that have the capacity to react with DNA.
One presumably important intermediate is the methyl dia-
zonium ion that induces O6-methyl-guanine adducts
(Souliotis et al. 1994; Pletsa et al. 1997). The complexity
of PCH metabolism is illustrated by the fact that a free rad-
ical, a reactive aldehyde, and an arylmethyl diazonium ion
have also been implicated as significant contributors to
observed toxic effects (IARC 1981; Prough and Tweedie
1987; Suzuki et al. 1999). Given the reactivity of these var-
ious metabolites, the well-documented in vivo genotoxicity
of the drug is not surprising (IARC 1981). At the same
time, the complex metabolism of PCH coupled with defi-
ciencies with standard exogenous metabolic activation sys-
tems is considered responsible for the high occurrence of
false negative in vitro results (reviewed in Suzuki
et al. 1999). Indeed, bacterial mutagenicity data are gener-
ally negative (McCann et al. 1975; Bronzetti et al. 1979).
Mutagenic effects were observed in V79 cells (Suter 1987),
but the clearest effects required nonstandard metabolic acti-
vation systems. There are some reports of positive mouse
lymphoma assay data with the resultant colonies being
described as small, suggesting a clastogenic mode of action
(Clive et al. 1988). However, Vian et al. (1993) failed to
induce micronuclei in cultures of PCH-treated primary
human lymphocytes, with or without rat liver S9. Thus,
PCH represents an example where the genotoxic potential
is best evaluated in vivo.

There is growing interest in integrating various testing
approaches to significantly improve the manner in which
genotoxicity testing is accomplished and reducing the num-
ber of animals required for testing. These integrated
approaches provide a mechanism to precisely quantify dif-
ferent genotoxic endpoints within the same experimental
design and identify which endpoints are most relevant to
adverse effects in humans. We therefore considered PCH to

be an interesting test case for evaluating the merits of an
integrated study design that would allow us to comprehen-
sively assess hematopoietic cell genotoxicity, both for
chromosomal damage and gene mutation potential. The
treatment period consisted of 28 consecutive days of
exposure, and evaluation of chromosomal damage was
accomplished by measuring micronucleus frequencies in
both immature and mature peripheral blood erythrocytes
(MacGregor et al. 1980). We used the MutaMouse trans-
genic mouse model that harbor ~29 tandem copies of a
recombinant λgt10 phage vector containing a mutation-
reporting Escherichia coli lacZ gene on each copy of chro-
mosome 3 (Shwed et al. 2010) and facilitated assessments
of mutations in both the lacZ transgene (Gingerich
et al. 2014) and the endogenous Pig-a gene (Gollapudi
et al. 2015). We quantified mutations arising in these two
reporter genes at two time points: (1) 3 days from the end
of the last treatment as recommended in the Organisation
of Economic Co-operation and Development (OECD) test
guideline 488 (OECD 2013); and (2) 70 days after cessa-
tion of treatment to evaluate effects in long-lived progenitor
cells. The results are discussed in terms of the high infor-
mation content provided by this multiple endpoint study
design, including comparison of mutation frequencies at
two gene loci, one endogenous and one transgenic, and
chromosomal damage.

MATERIALS ANDMETHODS

Reagents andOther Supplies

PCH (CAS no. 36670-1; purity ≥98%) was purchased from Sigma-
Aldrich, Oakville, ON, Canada. Lympholyte®-Mammal cell separation
reagent was purchased from CedarLane, Burlington, NC. Anti-PE
MicroBeads, LS Columns, and a QuadroMACS™ separator were from
Miltenyi Biotec, Bergisch Gladbach, Germany. CountBright™ absolute
count beads and fetal bovine serum (FBS) were purchased from Invitro-
gen, Carlsbad, CA. Anticoagulant solution, buffered salt solution, nucleic
acid dye solution (contains SYTO® 13), anti-CD24-PE, and anti-CD61-PE
were from Mouse Blood In Vivo MutaFlow® Kits (Litron Laboratories,
Rochester, NY). Hank’s balanced salt solution (HBSS) was purchased
from MediaTech, Herndon, VA. Reagents used for flow cytometric micro-
nucleus scoring (anticoagulant solution, buffered salt solution, stock propi-
dium iodide solution, anti-CD71-FITC, and anti-CD61-PE solutions, stock
RNase solution, and malaria biostandards) were from In Vivo Mouse
MicroFlow® Kits (Litron Laboratories).

For the lacZ assay, phenyl-beta-D-galactopyranoside (P-Gal) was
purchased from G-Biosciences, St Louis, MO; proteinase K was from
Invitrogen, Burlington, ON, Canada; packaging extract kits were from
Agilent Technologies, Mississauga, ON, Canada; all other chemicals were
purchased from Sigma-Aldrich.

Animals,Treatments, BloodHarvests

Experiments were conducted with the oversight of the Health Canada
Ottawa Animal Care Committee, which approved all animal procedures.
Male MutaMouse rodents were obtained from a colony maintained at
Health Canada. Mice were allowed to acclimate for approximately 10 days,
and their age at the start of the treatment was between 10 and 12 weeks.

Environmental and Molecular Mutagenesis. DOI 10.1002/em

506 Maurice et al.



Pretreatment blood samples were not collected prior to study initiation.
Water and food were available ad libitum throughout the acclimation and
experimental periods. PCH was prepared in phosphate buffered saline
(PBS) on each treatment day and was administered via oral gavage in a
volume of 0.003 mL/kg body weight/administration. Dose levels were
0, 6.25, 12.5, or 25 mg/kg/day and exposure occurred on study Days
1 through 28 (n = 4 for controls and 8 per treatment group per time point).
The top dose level used in the main study was based on a pilot dose
range-finding study that demonstrated that a dose of 50 mg/kg/day resulted
in a body weight loss that approached what would be considered excessive
toxicity and grossly affected testis weight (this aspect will be reported sep-
arately, manuscript in progress).

For the micronucleus assay, peripheral blood was collected 2 days after
the end of the exposure period (referred to hereafter as 28 + 2d) from
the same groups of animals euthanized the next day (i.e., 28 + 3d) for the
lacZ and Pig-a assays. Approximately 60 μL of peripheral blood was collec-
ted from the facial vein and immediately combined with 350 μL of antico-
agulant from the MicroFlowBASIC Kit (Rodent Fixed Blood; Litron
Laboratories, Rochester, NY). Following MicroFlowBASIC Kit instructions,
anticoagulated blood samples were fixed with ice-cold methanol and stored
at −80�C. After 5 days, fixed blood samples were centrifuged, rinsed, and
transferred to a long-term storage solution. Coded specimens were shipped
to Litron for analysis of micronucleated cell frequency as described below.

Peripheral blood and bone marrow for the Pig-a and lacZ assays,
respectively, were collected at 28 + 3d and 70 days (28 + 70d) after cessa-
tion of treatment. At each time point, animals were euthanized by cardiac
puncture under isoflurane anesthesia. The femurs were removed and
the bone marrow was flushed out in 1 mL of PBS, pelleted via brief centri-
fugation, resuspended in 100 μL of PBS and flash frozen in liquid
nitrogen, and finally stored at −80�C. Following blood collection via car-
diac puncture, 400 μL of blood was immediately transferred to a
0.5 mL K2-EDTA-coated microtainer obtained from Litron and maintained
at 4�C until being placed in an ExactPak shipping container and shipped
on ice overnight to Litron for analysis of Pig-a mutant cell frequencies as
described below.

Micronucleated Reticulocytes: Sample Preparation,Data
Acquisition

The frequency of reticulocytes (%RET), micronucleated immature, and
mature (normochromatic) erythrocytes (MN-RET and MN-NCE, respec-
tively) were determined for coded blood samples collected at the 28 + 2d
time point. To prepare samples for flow cytometric analysis, blood was
washed out of methanol fixative and incubated with antibodies and other
reagents as specified in the In Vivo Mouse MicroFlow Kit manual. This
methodology has been described in detail elsewhere (Dertinger
et al. 2004). Kit-supplied malaria-infected erythrocytes served as biologi-
cal standards and guided instrument settings on each day of analysis
(Tometsko et al. 1993). Micronucleus frequencies were determined upon
the acquisition of 20,000 CD71-positive reticulocytes (RET) per blood
sample. A BD FACSCalibur flow cytometer running CellQuest Pro v5.2
was used for these analyses.

LacZMutation: Sample Preparation,DataAcquisition

LacZ mutant frequencies were determined on coded bone marrow sam-
ples collected at 28 + 3d and 28 + 70d. Bone marrow total genomic DNA
was extracted according to Gingerich et al. (2014). Briefly, bone marrow
was thawed, then 50 μL was digested in 5 mL lysis buffer (10 mM EDTA,
100 mM NaCl, 10 mM Tris–HCl, pH 7.6, 1% sodium dodecyl sulfate
[w/v] and 1 mg/mL Proteinase K [Invitrogen, Burlington, Canada]), and
incubated at 37�C overnight with gentle shaking. Genomic DNA was
extracted using phenol/chloroform extraction procedure and was then
stored at 4�C in 90 μL TE buffer (10 mM Tris pH 7.6, 0.1 mM EDTA).

The P-Gal positive selection assay was used for determining lacZ
mutant frequency in DNA samples as previously described (Gingerich
et al. 2014). The recombinant λgt10 phage vector was transfected from
genomic DNA using Packaging Extract kits then mixed with the host bac-
terium (Escherichia coli lacZ−/galE−), plated on medium containing 0.3%
(w/v) P-Gal and incubated overnight at 37�C. Mutant frequency was cal-
culated as the ratio of mutant plaque forming units (pfu) to total pfu. The
DNA from two mice (a control and one middle dose at 28 + 3d) did not
pack well and produced no colonies; while two mice (one from the low
dose and one from the middle dose) had to be euthanized before tissue col-
lection at 28 + 70d because of rectal prolapse.

Pig-aMutation: Sample Preparation,DataAcquisition

Pig-a mutant phenotype cell frequencies were determined on coded
blood samples collected at 28 + 3d and 28 + 70d. Methods for processing
mouse blood for Pig-a measurements have been described (Labash
et al. 2016). As with previous reports, the frequency of mutant phenotype
reticulocytes (RETCD24-) as well as the frequency of mutant phenotype
erythrocytes (RBCCD24-) was determined for each sample. An Instrument
Calibration Standard was generated on each day data acquisition occurred.
These samples contained a high prevalence of mutant-mimic cells and pro-
vided a means to define the location of GPI anchor-deficient erythrocytes
(Phonethepswath et al. 2010). A BD FACSCanto II flow cytometer run-
ning FACSDiva v6.1.1 was used for the Pig-a analyses.

Calculations, Statistical Analyses

The incidence of MN-RET, MN-NCE, and RET are expressed as fre-
quency percent. The formulas used to calculate RETCD24- and RBCCD24-

frequencies based on pre- and post-immunomagnetic column data are
described by Dertinger et al. (2012) and the MutaFlow manual (www.
litronlabs.com).

To evaluate the effect that PCH treatment may have had on %MN-
RET, %MN-NCE, %RET, and RBCCD24- and RETCD24- frequencies relative
to concurrent vehicle control mice, Dunnett’s multiple comparison t-tests
were performed using JMP software’s one-way ANOVA platform
(v12.0.1, SAS Institute, Cary, NC). With the exception of the %RET end-
point, each test was performed at the 5% level using a one-tailed test to
identify significant increases relative to vehicle control. In the case of
%RET, the tests were two-tailed in order to determine whether a signifi-
cant treatment-related increase or decrease occurred. Also, note that as
similar frequencies were observed for vehicle control mice across every
endpoint and both time points, we pooled these data to achieve a larger
negative control group size.

Prior to performing the parametric tests described above, Levene’s tests
were used to verify the equality of variances in the samples (P > 0.05;
JMP’s ANOVA platform). The following transformations were applied to
fulfill this requirement: %MN-RET and %MN-NCE values were cube root
transformed; and RBCCD24-, RETCD24-, and lacZ mutation frequencies
were log10 transformed.

Pearson correlation coefficients were calculated for lacZ and Pig-a
mean mutant frequencies at the 28 + 3d and 28 + 70d time points
(Microsoft Excel for Mac 2008, v12.3.6, Microsoft, Redmond, WA). This
was done for both RBCCD24- vs. lacZ mutant frequencies, and RETCD24-

vs. lacZ mutant frequencies.

RESULTS

We evaluated the induction of MN, Pig-a, and lacZ
mutations in the hematopoietic system of MutaMouse
males at different time points after cessation of a 28-day
exposure to PCH. No significant reduction in body weight

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was observed at the end of the 4 weeks of exposure, or at
the later time point (data not shown).

%RET were measured at 28 + 2d in conjunction with
MN-RET analyses. Slightly elevated %RET were observed,
with a statistically significant increase evident for the high
dose group (Fig. 1A). Higher %RET values that occur sev-
eral days after cessation of treatment are generally indica-
tive of treatment-induced bone marrow toxicity, with a

consequent period of enhanced erythropoiesis activity upon
cessation of treatment (Dertinger et al. 2012). Robust,
dose-related MN induction was also observed for PCH-
exposed mice. Both MN-RET and MN-NCE frequencies
exhibited statistically significant increases (P < 0.05), even
at the low and middle dose levels that were not observed to
appreciably affect erythropoiesis (Fig. 1B,C). For the high
dose group, MN-RET, and MN-NCE frequencies exhibited
mean fold increases of 9.1x and 6.8x, respectively.
As shown by Figure 2A, treatment with PCH for 28 con-

secutive days caused dose-related increases in lacZ mutant
frequencies at 28 + 3d with significant fold increases of
2.0-, 3.5-, and 6.8-fold at the low, medium, and high doses
(P < 0.05 for all doses), respectively. These effects were
sustained at 28 + 70d, with fold increases of 1.6-, 2.5-, and
5.0- at the low, medium, and high dose (P < 0.05; Fig. 2B).
Although the latter harvest time exhibited modestly lower
mean PCH-induced mutant frequencies, and within group
variation was more pronounced, these results indicate that
PCH induced mutagenicity in long-lived bone marrow pro-
genitor cells. Mean lacZ frequencies for each treatment

Fig.1. Frequency of Day 28 + 2d blood reticulocytes (A), micronucleated
immature erythrocytes (B), and micronucleated mature erythrocytes (C)
for each of four PCH treatment groups, where Low = 6.25, Mid = 12.5,
and High = 25 mg/kg/day. Data for individual mice are shown, and group
means appear as horizontal green lines. Dunnett’s test results are shown to
the far right of each graph, where statistically significant differences
relative to the concurrent vehicle control group appear as italicized black
text as opposed to red text, and by a gray circle as opposed to a red circle.
Circles’ diameters represent 95% confidence intervals (A) or 90%
confidence intervals (B and C).

Fig. 2. Frequency of Day 28 + 3d lacZ mutations (A) and Day 28 + 70d
lacZ mutations (B) for each of four PCH treatment groups, where
Low = 6.25, Mid = 12.5, and High = 25 mg/kg/day. Data for individual
mice are shown, and group means appear as horizontal green lines.
Dunnett’s test results are shown to the far right of each graph, where
statistically significant differences relative to the concurrent vehicle
control group appear as italicized black text as opposed to red text, and by
a gray circle as opposed to a red circle. Circles’ diameters represent 90%
confidence intervals.

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508 Maurice et al.



condition and time point are provided in Supporting Infor-
mation Table S1.

RETCD24- frequencies were significantly increased in
PCH-treated mice on days 28 + 3d and 28 + 70d (Fig. 3A,
C). RETCD24- responses were more variable at the later time
point. As with the lacZ results, the fact that elevated RETCD24-

frequencies were observed at the late time point suggests
that some portion of the mutated cells arose from long-
lived progenitors with extended self-renewal capacity.
RBCCD24- frequencies also showed responses to PCH
exposure, with statistically significant increases observed in
all PCH treatment groups and at both time points (Fig. 3B,
D). Note that the increase observed in the low dose group
at 28 + 70d must be qualified to some extent because statis-
tical significance is lost when the animal with the highest
mutant frequency is removed. Even so, the result is not
likely a scoring artifact as this animal also had the highest
mutant RET value among the animals in the same group.
The raw Pig-a data and calculated frequencies, on a per
mouse basis, are posted at the Pig-a In Vivo Gene Mutation
Assay Database, http://www.pharmacy.umaryland.
edu/centers/cersi-files.

Pearson correlation coefficients were derived for compar-
isons across the two mutation assays. At 28 + 3d, mean
RETCD24- and RBCCD24- vs. lacZ frequencies showed

particularly high correlations, with R2 values of 0.956 and
0.999, respectively (P < 0.05, Fig. 4A,B). At 28 + 70d, mean
RETCD24- were also in good agreement with lacZ (R2 = 0.996,
P < 0.05, Figure 4C), while the RBCCD24- correlation was
slightly lower (R2 = 0.902, P < 0.05, Figure 4D).

DISCUSSION

There is currently considerable pressure to transition the
practice of toxicology toward computational and in vitro
methodologies (Dix et al. 2007; Collins et al. 2008;
Kavlock et al. 2009). In light of this, and given its predom-
inately negative in vitro DNA-damage profile, PCH made
an interesting case study for evaluating multiple in vivo
endpoints of genotoxicity—lacZ and Pig-a mutation, and
chromosomal damage in the form of MN. By concentrating
on bone marrow and blood-based assays, we focused on
the hemotopoietic compartment and the notable hematolog-
ical secondary cancers that have been described for PCH
exposure (Levine and Bloomfield 1992). Furthermore, by
using an experimental design that facilitated assessment of
all three assays, this PCH study was performed in a manner
that addresses resource and animal-usage concerns that are
in part driving the transition noted above.

Fig. 3. Frequency of 28 + 3d Pig-a mutant reticulocytes (A) and Pig-a
mutant erythrocytes (B), as well as 28 + 70d Pig-a mutant reticulocytes
(C) and Pig-a mutant erythrocytes (D) for each of four PCH treatment
groups, where Low = 6.25, Mid = 12.5, and High = 25 mg/kg/day. Data
for individual mice are shown, and group means appear as horizontal

green lines. Dunnett’s test results are shown to the far right of each graph,
where statistically significant differences relative to the concurrent vehicle
control group appear as italicized black text as opposed to red text, and by
a gray circle as opposed to a red circle. Circles’ diameters represent 90%
confidence intervals.

Environmental and Molecular Mutagenesis. DOI 10.1002/em

509Integrated in vivoGenotoxicity Assessment of PCH

http://www.pharmacy.umaryland.edu/centers/cersi-files
http://www.pharmacy.umaryland.edu/centers/cersi-files


In this study, PCH’s in vivo genotoxic activity was read-
ily apparent, as each of the endpoints investigated showed
statistically significant effects at all of the doses tested. As
also found by Suzuki et al. (1999), we observed potent
clastogenic activity as evidenced by robust MN induction.
Whereas Suzuki and colleagues failed to detect significant
increases in in vivo lacZ mutations in bone marrow, liver,
testis, spleen, kidney, and lung upon single administration
of 50 mg PCH/kg, they did observe significant lacZ muta-
tion induction at 150 mg/kg/day when administered for
five consecutive days (cumulative dose: 750 mg/kg) partic-
ularly in those tissues that are prone to develop tumors fol-
lowing PCH exposure (i.e., lung, bone marrow, and
spleen). In our experiments, we demonstrated that a strong
mutagenic response in the bone marrow is occurring at
much lower doses, as even at the lowest PCH dose studied
(6.25 mg/kg/day, or a cumulative dose of 175 mg/kg)
resulted in significant induction of bone marrow lacZ and

blood Pig-a mutation. These results show that PCH elicits a
robust mutagenic response in the bone marrow even at doses
that do not produce cytotoxicity. While Phonethepswath
et al. (2013) also reported PCH-induced Pig-a mutation in
mice, it is not productive comparing those results with data
reported herein because the previous study utilized an early
mouse blood labeling protocol that is now understood to
systematically underestimate mutant cell frequency (Labash
et al. 2016). Finally, Chen et al. (2019) recently reported
strong induction of Pig-a mutations following a 28-day
exposure regimen in rats using daily doses higher than those
used here. Thus, in addition to its well-known clastogenic
activity, PCH is also an effective in vivo mutagen when
recommended OECD test guideline experimental design
considerations are followed.
One of the objectives of our study was to compare the

mutagenic response observed with two reporter genes that
are routinely used for assessing chemical mutagenesis. We

Fig. 4. The mean frequency of Pig-a mutant cells are graphed against the
mean frequency of lacZ mutation for each of four dose groups and each of
two time points, with Pearson correlation coefficients provided by an R2

value. Error bars represent one standard deviation. A = 28 + 3d results,

where Pig-a mutants are reticulocytes; B = 28 + 3d results, Pig-a mutants
are erythrocytes; C = 28 + 70d results, Pig-a mutants are reticulocytes;
and D = 28 + 70d results, Pig-a mutants are erythrocytes.

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510 Maurice et al.



found a very strong correlation (R2 ≥ 0.956) between lacZ
mutant frequencies in bone marrow and Pig-a mutant RET
and RBC at the early time point (i.e., 28 + 3d). At the later
time point (i.e., 28 + 70d), the correlation between the two
assays was still very strong (R2 = 0.996) when comparing
lacZ mutant frequencies with Pig-a mutant RET. The cor-
relation was slightly lower between mutant lacZ bone mar-
row cells and Pig-a mutant RBC (R2 = 0.902), a result that
reinforces expert recommendations to study both RET and
RBC cohorts for Pig-a mutation (Gollapudi et al. 2015).
Overall, our mutation results are in agreement with those
reported by Lemieux and collaborators (Lemieux
et al. 2011) who observed a significant, and comparable,
dose-related increase in mutant cells with the Pig-a and
lacZ assays following exposure of MutaMouse males to
benzo[a]pyrene, a strong mutagen that acts through a
completely different mode of action compared to PCH.
These results support the notion that both assays have a
broad applicability domain and that they both are effective
methods for evaluating gene mutation events.

The use of both gene mutation assays in an integrated
test design represents a convenient means to address limita-
tions that are generally ascribed to the two assays when
used in isolation. The lacZ mutation assay is a well-
validated and regulatory-accepted assay with an adopted
OECD guideline that can be used for assessing mutagenic-
ity in any tissue. A potential limitation of the assay is that
it uses a bacterial gene that is highly methylated and not
transcribed, and thus may not be fully representative of the
susceptibility of endogenous genes to mutation induction
(Lambert et al. 2005). It is also detecting almost exclusively
point mutations (Beal et al. 2015). On the other hand, the
Pig-a gene is an endogenous gene and its inactivation can
occur through a variety of mutational events including
those that would not be detected by the lacZ assay. How-
ever, the Pig-a assay can currently only be conducted in
erythropoietic cells and it is challenging to sequence pre-
sumed mutant cells to characterize the types of lesions
responsible for the mutant phenotype. It should also be
noted that an OECD test guideline for the Pig-a assay is
currently under development, and the results reported
herein add further support to these validation efforts.

In summary, our data agree with previous studies that
found PCH exerts potent clastogenic activity. Furthermore,
detection of its mutagenic potential is also readily observed
when more careful analysis, particularly in terms of dosing
protocol and harvest times, are followed. The advantage
of combining the lacZ, Pig-a, and MN endpoints is that it
allows for a comprehensive assessment of multiple types
of DNA lesions, a particularly important aspect when study-
ing new chemical classes and/or when complex metabolism
makes choosing a single in vivo genotoxicity endpoint diffi-
cult to choose a priori. By coupling the gene mutation assess-
ments with MN analyses, it becomes possible to efficiently
detect a chemical’s mutagenic and chromosome damaging

potential. Thus, when systemic exposure of a chemical and
its reactive intermediate(s) can be verified, this approach rep-
resents an efficient and cost-effective means of obtaining
valuable safety data that includes mode of action information
that has not traditionally been collected due to technical and
cost considerations.

ACKNOWLEDGMENTS

Excellent benchtop work provided by Dorothea Torous,
Svetlana Avlasevich, and Carson Labash is greatly appreci-
ated. This research was funded through Health Canada’s
Chemicals Management Plan. C.M. was funded through the
Natural Sciences and Engineering Research Council of
Canada’s Visiting Fellowships in a Government Laboratory
Program. We are grateful to Karine Chamberland, Julie Todd,
Kevin Little, Scott Smith, Julie Cox, Drs. Martha Navarro,
Marc Beal, Matthew Meier, Alexandra Long, and Richard
Webster for assistance with animal study and necropsy.

AUTHORCONTRIBUTIONS

F.M., C.Y., S.D. and C.M. designed these studies. F.M.
and C.Y. secured funding for the study. C.M. executed the
lacZ analyses, and prepared coded blood samples for ship-
ment to Litron. C.M. and S.D.D. performed statistical ana-
lyses, and all of the authors contributed to data interpretation
and writing the manuscript.

DISCLOSURE

S.D.D is an employee of Litron Laboratories. Litron
holds patents covering flow cytometric methods for scoring
micronucleated erythrocytes and sells kits based on this
technology (In Vivo MicroFlow®); Litron hold patents for
scoring GPI anchor-deficient erythrocytes and sells kits
based on this technology (In Vivo MutaFlow®).

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Accepted by—
B. Gollapudi

Environmental and Molecular Mutagenesis. DOI 10.1002/em

512 Maurice et al.


	 Integrated In Vivo Genotoxicity Assessment of Procarbazine Hydrochloride Demonstrates Induction of Pig-a and LacZ Mutation...
	INTRODUCTION
	MATERIALS AND METHODS
	Reagents and Other Supplies
	Animals, Treatments, Blood Harvests
	Micronucleated Reticulocytes: Sample Preparation, Data Acquisition
	LacZ Mutation: Sample Preparation, Data Acquisition
	Pig-a Mutation: Sample Preparation, Data Acquisition
	Calculations, Statistical Analyses

	RESULTS
	DISCUSSION
	ACKNOWLEDGMENTS
	AUTHOR CONTRIBUTIONS
	DISCLOSURE
	REFERENCES