Báo cáo khoa học: Development of an HSV-tk transgenic mouse model for study of liver damage pptx

In conclusion, the transgenic mouse model with hepatocyte-speci-fic expressed HSV-tk developed hepatitis with administration of GCV, had morphological and clinical chemical characteristic

for study of liver damage

Yan Zhang, Shu-Zhen Huang, Shu Wang and Yi-Tao Zeng

Shanghai Institute of Medical Genetics, Shanghai Children’s Hospital, Shanghai Jiao Tong University, People’s Republic of China

The morbidity of severe liver disease is usually very

high, seriously threatening the patient’s health

Availab-ility of animal models expressing related hepatic

disor-ders should provide a means of studying the pathogenic

mechanism of such diseases Among these are the

gen-etically engineered animal models Unfortunately,

cur-rently available transgenic models are unsatisfactory for

experimental use, because those transgenic mice

expres-sing toxic protein often die too early due to the

over-expression of toxic protein in such a vital organ Others,

for example the alb-uPA transgenic mouse and FAH–

knockout mouse developed in the 1990s can be

main-tained only with constant medical treatment [1,2]

In 1989, Heyman et al [3] developed a new trans-genic mouse in which ablation of a specific cell type is TK-dependent In such a transgenic mouse, the inser-ted herpes simplex virus thymidine kinase (HSV-tk) gene products can phosphorylate certain nucleoside analogues such as ganciclovir (GCV) that are not metabolized by conventional cellular enzymes Phos-phorylated nucleoside analogues such as GCV triphos-phate are potent toxic metabolites for cells Nevertheless, neither GCV nor the HSV-tk alone is harmful to cells Hence, this conditional cell-depleting effect is achieved by expressing HSV-tk with a cell-specific promoter It has been used for depletion of

Keywords

albumin promoter⁄ enhancer; animal model;

ganciclovir; herpes simplex virus thymidine

kinase; inducible liver-specific disease

Correspondence

Y.-T Zeng, Shanghai Institute of Medical

Genetics, Shanghai Children’s Hospital,

Shanghai Jiao Tong University, Shanghai

200040, People’s Republic of China

Fax: +86 21 6247 5476

Tel: +86 21 6247 2308

E-mail: ytzeng@stn.sh.cn

(Received 13 January 2005, revised 23

February 2005, accepted 7 March 2005)

doi:10.1111/j.1742-4658.2005.04644.x

The herpes simplex virus thymidine kinase⁄ ganciclovir (HSV-tk ⁄ GCV) sys-tem that selectively depletes cells expressing HSV-tk upon treatment with GCV has provided a valuable tool for developing a new animal model expressing the desired tissue damage In this paper, an HSV-tk vector with

an albumin promoter⁄ enhancer was constructed Based on the favourable killing effect on Hep-G2 cells by the recombinant construct, the HSV-tk transgenic mouse strains were developed One strain of the TK transgenic mouse (TK5) was studied intensively Integration of the target gene was confirmed primarily by PCR Fluorescence in situ hybridization following G-banding analysis demonstrated that the insertion site was located at 2F1-G3 The hepatocyte-specific transcription and expression of HSV-tk was verified by reverse transcription (RT)–PCR as well as by immunohisto-chemical staining When two second-generation mice (F1 and TK5-F2) were injected with GCV, the pathogenic alterations in the liver were readily identified, including the appearance of vaculation in the hepatocytes with inflammatory infiltration in the liver, and diffuse proliferation of hepatocytes In addition, the blood test demonstrates a significant increase

of serum alanine aminotransferase, aspartate aminotransferase and total bilirubin In conclusion, the transgenic mouse model with

hepatocyte-speci-fic expressed HSV-tk developed hepatitis with administration of GCV, had morphological and clinical chemical characteristics indicative of hepato-cellular disease and should be useful for the the study of inducible liver-specific diseases

Abbreviations

ALT, alanine aminotransferase; AST, aspartate aminotransferase; FISH, fluorescence in situ hybridization; GCV, ganciclovir; HSV-tk, herpes simplex virus thymidine kinase; RT, reverse transcription.

promoter [4–9] Such a system is used in the transgenic

rats of Kawasaki et al [10], in which the rats develop

experimental hepatitis on administration of GCV The

genome of the mouse is much better characterized than

that of the rat and the cost of producing and

maintain-ing transgenic mice is less than for rats The high

conservation and strong liver-specific regulatory

machinery of the mouse serum albumin cluster makes

it appropriate for use as a promoter for

hepatic-speci-fic expression [11,12]

In this study, HSV-tk transgenic mice were produced,

in which the inserted gene is regulated by an albumin

enhancer⁄ promoter; liver injury is readily induced in this

model Among five founder transgenic mice generated,

only one (TK5$) transmitted the transgene to progeny

through the germ line by mating with male –⁄ – wild-type

KM mice Therefore, the F1 and F2 generations of TK5

were used for the inducible hepatic injury In addition,

the founder TK3# was also used for preliminary

ana-lysis of the relationship between expression level and

histopathological changes

Results

Liver damage in transfected Hep-G2 cells after

treatment with GCV

The pCMV-TK vectors were transfected into Hep-G2

cells, which were then induced with GCV The

trans-fected cells started to detach on third day after a single

exposure to 40 lmolÆL)1GCV Hep-G2 cells transfected

with pLLTK started to detach on day 5, and maximal

expression was achieved on day 7 after GCV treatment

Cell apoptosis was recognized in both of the two groups

mentioned above; sick or damaged cells were seen to

swell and burst By contrast, the control cells transfected

with vector pcDNA 3.1⁄ zeo(+) grew and proliferated

normally The Hep-G2 transfected pLLTK showed

completely different morphology as compared to the

control cells (Fig 1A) Such increased cell death could

also be assessed by

3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyl tetrazolium bromide assay The survival rate

of Hep-G2 cells was reduced significantly after

trans-fection with HSV-tk (Fig 1B)

Detection of inserted transgene and monitoring

of the pedigree of mouse family TK5 by PCR

A total of 182 eggs were microinjected and

subse-quently reimplanted into eight pseudopregnant foster

mothers, of which five became pregnant and gave birth

to 36 mice Among them, six mice showed the inser-tion of the HSV-tk gene as detected by PCR The integration rate was 16.7% (6⁄ 36) One line of trans-genic mice is female; the transgene is transmitted to the offspring at a rate of about 50% according to Mendel’s laws (Fig 2A)

Chromosomal localization of transgene integration as demonstrated by fluorescence

in situ hybridization (FISH) More than 50 metaphases were analysed for each transgenic mouse All of the metaphase cells showed one positive hybrid signal According to the standard idiograms of mouse chromosomes, the integration site

is located at 2F1-G3 in TK5-F1-455 (Fig 2B) The

B

Fig 1 Comparison of different HSV-tk transfected Hep-G2 cells post-treatment with GCV and the negative control group (A) Mor-phology of the Hep-G2 cells transfected with pLLTK after adminis-tration of GCV Left, 40 lmolÆL)1 GCV; right, no GCV (original magnification, · 200) (B) Comparison of cellular survival rates among HSV-tk transfected Hep-G2 cells post-treatment with GCV and the negative control group *P < 0.05 Results are expressed

as mean ± SD of three separate experiments Bar1, cells fected with pCMV-TK (positive control group); Bar2, cells trans-fected with pLLTK (experimental group); Bar3, cells transtrans-fected with pcDNA3.1(+) ⁄ zeo (negative control group) Cellular survival rates are assessed by 3-(4, 5-dimethylthiazol-2-y)-2, 5-diphenyl tetra-zolium bromide staining.

integration site of TK5-F2-327 was similar to that of

TK5-F1-455 (data not shown)

Reverse transcription (RT)–PCR of tissue-specific

expression of HSV-tk in transgenic mice

RT-PCR showed that the 390 bp specific band of

HSV-tk was detectable only in the transfected cells,

liver and testicle It was not detectable in the cells used

as negative control, or in blood, kidney, pancreas,

intestine, brain, skin or heart, even though an internal

control band of 190 bp b-actin was present in all of

the samples (Fig 3)

HSV-tk protein expression in the liver of

transgenic mice

Immunohistochemical staining was performed using a

polyclonal rabbit-(anti-HSV-tk) Ig The

yellowish-brown staining sites were located mainly in the nucleus

of hepatocytes integrated by the HSV-tk gene, and the

HSV-tk-positive cells were distributed scattered or

clustered in liver lobules, located mainly around the central vein, and occasionally in the periportal areas (Fig 4A), while there was no staining in the liver of the wild-type mice (Fig 4B) Simultaneously, the positive signal can be observed in both the nucleus and the cytoplasm after GCV treatment (Fig 4C) The staining cells account for 20–30% of the total hepatocytes of TK5-F1-455 (Fig 4A), whereas in mouse TK3, there were approximately 60–70% HSV-tk staining hepato-cytes, with visible slight yellowish-brown signals in the focal necrosis, but several regenerative foci (regener-ating parenchyma hepatocytes) displayed reduced or no staining (Fig 4D) The percentage of HSV-tk-positive hepatocytes in the F2 mice (TK5-F2-327) of TK5 was similar to those of TK5-F1-455 (data not shown)

Hematoxylin and eosin staining for histological analysis

Microscopic analysis of the livers of GCV-treated HSV-tk mice (F1 and F2) showed that the diseased liv-ers display a number of abnormalities, including the appearance of apoptosis bodies, hepatocyte vaculation, lymphocyte infiltration, hepatocyte megalocytosis, and diffused proliferation of hepatocytes (Fig 5A) In transgenic mouse TK3, mutifocal coagulation necrosis was evident in the liver (Fig 5B) Histological analysis

of the kidney showed no apparent abnormity in the GCV-treated transgenic mice and wild-type mice (data not shown)

Biochemical analysis of the blood Twenty-one days after the injection of GCV, the values

of alanine aminotransferase (ALT), aspartate amino-transferase (AST) and total bilirubin were significantly increased in the TK5-F1 transgenic mice (P < 0.05), whereas there were no significant increase in the wild-type control mice The value of creatinine was not altered significantly in either group (Fig 6) The chan-ges of the four serum values in the F2 generation of the TK5 family and mouse TK3 showed similar results (data not shown)

Fig 3 RT-PCR of HSV-tk expression in the transgenic mouse TK5-F1-455 M, 100-bp marker; 1, positive control (Hep-G2 cells trans-fected with plasmid of pCMV-TK); 2, negative control (Hep-G2 cells); 3, blank control; 4, testis; 5, liver; 6, blood; 7, kidney; 8, pan-creas; 9, intestines; 10, brain; 11, skin; 12, heart.

A

B

Fig 2 Analysis of integration of transgene in mouse family TK5.

(A) PCR analysis of the transgenic mice in TK5-F1 1, Hep-G2 cells

transfected pCMV-TK as a positive control; 2, Hep-G2 cells as a

negative control; 3, blank control; 4, founder mouse; 5,7,9,12,

neg-ative offspring; 6,8,10,11,13, positive offspring; M, 100 bp marker.

(B) FISH and G-banding metaphase of the transgenic mouse

(TK5-F1-455) The arrow indicates the integration site of the transgene

located at 2F1-G3 The right panel shows the mouse chromosome

ideogram.

We have generated a number of transgenic mice for

liver damage, in which the HSV-tk gene was regulated

by an albumin promoter⁄ enhancer The excellence of

this mouse model is that liver damage and its extent in

HSV-tk mice can be induced and controlled by GCV

treatment When the mice are injected with GCV, the

pathologic changes and biochemical abnormalities,

including vaculation of the hepatocytes, inflammatory

infiltration, diffuse proliferation of hepatocytes as well

as a significant increase of serum ALT, AST and total bilirubin, can be easily recognized However, renal function is not affected by GCV treatment This indi-cates that GCV at the dosage used in this study is associated with toxin-mediated hepatocyte damage in our HSV-tk mice

We used FISH and RT-PCR to investigate trans-gene integration and HSV-tk expression in various tissues of the transgenic mice FISH indicated that the

Fig 5 Histology of liver tissue (hematoxylin and eosin stain) (A) GCV-treated TK5-F1 tra-nsgenic mouse showed several apoptotic bodies, variably severe cytoplasmic vacuoli-zation, lymphocyte infiltration, hepatocyte megalocytosis, and proliferation of hepato-cytes (B) GCV-treated TK3 mouse, showed apoptosis bodies, mutifocal coagulation necrosis with lymphocyte infiltration, hepatocyte megalocytosis, and proliferation

of hepatocytes (C) GCV-treated nontrans-genic mouse (D) Untreated transnontrans-genic mouse (Original magnification, · 200.)

Fig 4 Immunohistochemical staining observation of the HSV-tk expression (A) Liver of transgenic mouse TK5-F1-455 HSV-tk-positive cells are clustered around the central vein, scattered in the liver lobule tissue, or clustered in the periportal areas (B) Liver of the wild-type mouse showed no staining (C) Liver of transgenic mouse TK5-F1-452 after 21-days of GCV treatment, the positive signal appeared in the nucleus and the cytoplasm after GCV treatment (D) Liver of TK3 mouse, several regenerative foci (regenerating parenchyma hepatocytes) displayed reduced or no staining (slight yellowish-brown signal in focal necrosis (Original magnification, · 400.)

HSV-tk gene was stably integrated in the genomes of

the mouse family (TK5), and the expression of HSV-tk

was readily detectd in the liver and the testis of TK5

family, but was not detectable in other tissues, such as

blood, kidney, pancreas, intestines, brain, skin and

heart It indicated that the recombinant construct

dri-ven by the albumin⁄ enhancer that we used in this study

was highly tissue specific Immunohistochemical

analy-sis confirmed that the HSV-tk protein was expressed

specifically in the liver In TK3 mice, approximately

60–70% of the total hepatocytes showed HSV-tk

expression, and 20–30% of the liver cells in the TK5

family gave positive results The discrepancies of levels

of HSV-tk expression between these two mouse strains

may be due to differences in HSV-tk gene integration

sites, that may be caused by random integration of the

transgene

Recent studies showed that HSV-tk converts the

nontoxic prodrug GCV into GCV-triphosphate, which

can cause chain termination and single-strand breakage

upon incorporation into DNA Although blocking of

DNA synthesis of GCV is especially toxic for dividing

cells, it can also cause damage of nondividing cells,

such as hepatocytes, and liver toxicity of HSV-tk

[13,14] This provides the basis for selected hepatocyte

killing using a hepatocyte-specific promoter in vivo

Hepatocyte replication was not a prerequisite for

this effect, indicating that interference with DNA

syn-thesis during S phase of the cell cycle is not the only

mechanism of toxicity of phosphorylated GCV

Furthermore, although the exact mechanism by which

suicide genes kill the HSV-tk-expressing cells is not yet

clear, apoptosis has been considered to be a major contributor to GCV killing [15–18] Song et al [19] have shown that GCV induced HSV-tk expressing cells into apoptosis, thus inhibiting the growth of ovarian cancer cells Shibata et al [20] injected the HSV-tk vec-tor into rats with bladder cancer and observed apopto-sis of bladder cancer cells Kawasaki et al [10] created

an AL-HSV-tk transgenic rat that expressed HSV-tk in hepatocytes, in which apoptosis was demonstrated after treatment with GCV The administration of GCV elicited leukocyte infiltration and induced chronic hepatitis [21,22] Although in the hepatitis model the precise role of Kupffer cells is unclear, it is possible that they are involved in inflammation [10] Activated Kupffer cells release cytokines and chemokines that activate and transport T cells [23–25] It seems that hepatitis in the rat is primed by hepatocyte apoptosis [10] To examine the immunological mechanisms involved in cell killing using the HSV-tk⁄ GCV system, HSV-tk-transduced human hepatocellular carcinoma (HCC) cells were implanted subcutaneously into im-munocompetent syngeneic mice After GCV treatment, marked infiltration by lymphocytes including CD4+ and CD8+ T cells, apoptosis of cells was induced, and significant reduction or even complete regression of tumours was achieved Conversely, no significant inhibitory effects on tumour formation were observed

in athymic nude mice The results indicate that T cell-mediated immune responses may be a critical factor for achieving successful cell killing using the

HSV-tk⁄ GCV system [26] Administration of GCV to mice and rats injected with adenovirus encoding HSV-tk

Fig 6 Comparison of serum parameters of

TK5-F1 mice with the wild-type mice (n¼ 3).

Results are expressed as mean ± SD of

three mice After 21 days of GCV treatment

the values of ALT, AST and total bilirubin

were significantly increased in the TK5-F1

transgenic mice group (P < 0.05), whereas

there was no significant increase in the

wild-type control group Creatinine was not

significantly altered in either group.

revealed moderate hepatocyte vacuolation and an

increased number of inflammatory cells In this study,

we found that there was more severe focal necrosis of

the liver tissue in TK3 than in TK5 mice Moreover,

the liver regenerating focus was more evident in TK3,

in which clones of transgene expression-deficient cells

were formed as detected by immunohistochemistry

The reasons for the different pathological changes

between these two mouse strains are not clear We

sug-gest that these differences may be associated with the

quantities of HSV-tk expressing cells In addition, the

patchy focal necrosis and regeneration in the TK3 liver

could be explained by the possibility that this founder

mouse may be a mosaic as approximately 5–10% of

founder mice showed mosaicism of some sort (either

multiple integration sites or patchy cellular

distribu-tion) Boucher et al [27] compared the efficacy of the

HSV-tk⁄ GCV system in two human carcinoma cell

lines after exposure to GCV and found that the killing

effect depended on the concentration of the tk enzyme,

the number of cells expressing HSV-tk, different cell

types and the overall confluence of the HSV-tk

expres-sing-cells These results emphasise the importance of

cell-specific metabolism in HSV-tk⁄ GCV-mediated

cytotoxicity In conclusion, the killing of cells with

HSV-tk⁄ GCV is a complex interactive sequence of

biochemical and cellular events involving incorporation

and accumulation of the monophosphorylate

deriv-ative of GCV into DNA, disruption and inhibition of

the cell cycle, gap junction metabolite transfer, and

apoptosis Thus, we conclude that the exact

mecha-nisms may differ in: (a) different cell types; (b)

differ-ent species; (c) the concdiffer-entration of GCV used; (d) the

quantity of cells expressing HSV-tk; and (e) the

distri-bution of cells expressing HSV-tk

It is of interest that male HSV-tk mice (including

the founder TK3 and male offspring of TK5)

gener-ated in this study were not able to reproduce when

mated with wild-type female mice RT-PCR showed

that HSV-tk was expressed both in the liver tissue and

ectopically in the testis even though a

heptocyte-speci-fic promoter was used in generating HSV-tk transgenic

mouse The results suggest that male infertility may

result from ectopic expression of HSV-tk in the testis

It has been reported that the natural HSV-tk gene

con-tains a cryptic internal testis-specific promoter [28–31],

and pathology has revealed that testicular development

was immature and almost no sperm was produced in

these mice (data not shown) When we treated female

transgenic mice with GCV liver damage was induced

In summary, transgenic mice specifically expressing HSV-tk in the liver were generated When transgenic mice were treated with GCV, morphological, clinical, and biochemical characteristics indicative of hepato-cellular disease developed These HSV-tk mice could

be an alternative model for the study of inducible liver-specific disease, and may be useful in the study

of the pathogenesis of liver diseases and potential therapies

Experimental procedures

Plasmid construction and generation of transgenic mice

Total DNA was extracted from KM mouse blood for PCR amplification of murine albumin promoter ()310 bp to +25 bp) and enhancer ()9192 bp to )11 250 bp) The primers for albumin promoter and enhancer are: pro1, 5¢-CTTAGGTACCTCCATGCCAAGGCCCACA-3¢; pro2, 5¢-CTTGCTCACCATGGTGGCGACCGGTAGTGGGGT TGATAGGAAAGG-3¢; en1, 5¢-ACGAGTCTAGAGTG GAGCTTACTTCTTTGATTTGA-3¢; en2, 5¢-CCGCGTC GACGGAAAAGCGCCTCCCCTAC-3¢; The 1800 bp of the HSV-tk coding sequence were also amplified by PCR from the pTK-neo plasmid and the consensus Kozak sequence GCCACC was introduced in front of the transla-tion start codon ATG by the primers tk1, 5¢-CGTA TACCGGTGCCACCATGGCTTCGTACCCCGGC-3¢ and tk2, 5¢-CCGCGTCGACGGAAAAGCGCCTCCCCTAC-3¢) [32] Recombinant plasmid pLLTK was obtained by insert-ing all three of the amplified fragments into the multiple cloning sites of pcDNA3.1(+)⁄ zeo (Invitrogen, Carlsbad,

CA, USA) by cohesive-blunt end ligation Then pLLTK was digested with HindIII and the 4200 bp fragment of LLTK (Fig 7) was obtained with the QIAquick gel extrac-tion kit (Qiagen, Valencia, CA, USA) After purificaextrac-tion with S & S Elutip minicolumns (Schleicher & Schuell, Keen, NH, USA), the DNA fragment was microinjected into the male pronuclei of the KM mouse fertilized eggs and transgenic mice were generated

Fig 7 Schematic illustration of recombinant construction Ealb and Palb represent mouse albumin enhancer and mouse albumin cDNA, respectively.

GCV-induced cytotoxicity in cultured transfected

cells

Human hepatic cell line Hep-G2 and mouse breast epithelia

cell line HC-11 cells were seeded in 24-well plates and grown

in Dulbecco’s modified Eagle’s medium supplemented with

10% (v⁄ v) fetal bovine serum and penicillium ⁄ streptomycin

The cells were then transfected with pLLTK by using

Lipo-fectamineTM2000 (Invitrogen) In a parallel setting, control

cells were transfected with the positive pCMV-TK and

pcDNA3.1(+)⁄ zeo Hep-G2 cells were treated with

40 lmolÆL)1 GCV (Roche, Indianapolis, IN, USA) 24 h

after transfection The morphology of the cells was

exam-ined by using an Olympus IX 70 inverted microscope

(Hamburg, Germany) each day; cell survival rates were

measured by 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyl

tetra-zolium bromide (Sigma Aldrich, St Louis, MO, USA)

stain-ing at 7 days later The units of absorption were measured

by an Elx800 plate reader (Bio-Tek Instruments, Winooski,

VT, USA) at 570 nm Differences in survival rates among

different transfected Hep-G2 cells post-GCV treatment were

analysed statistically using Student’s t-test (SAS Software)

A P-value < 0.05 was considered significant

PCR analysis for the integration of the transgene

The transgene in the founder animals and their progeny

was identified by PCR analysis of genomic DNA obtained

from tail biopsies PCR analysis was performed in 25 lL

reaction mixtures The primers (stk1, 5¢-GTATACCGG

TATGCCCACGCTACTGCGG-3¢; SH552: 5¢-GCACTC

GAGACCCGTGCGTTTTATTCTGTCT-3¢) for HSV-tk

were designed to amplify a 390 bp region Amplification

was performed on a thermocycler for 30 cycles of: 1 min at

94
C, 1 min at 59
C and 30 s at 72
C PCR products

were then separated electrophoretically on 2% agarose gel

and visualized after ethidium bromide staining

Chromosomal localization of transgene integration

sites by using FISH following G-banding

Chromosome preparation was performed following the

reported methods with modifications [33–35] FISH was

carried out according to the previous study with some

modifications [36,37] The DNA fragment LLTK was used

as probe and labelled with the DIG-Nick translation mix

(Roche) according to the manufacturer’s protocol Finally,

slides were counter-stained with propidium iodide

anti-fading solution (Sigma-Aldrich), and examined on a

fluorescent microscope (Leica DM RXA2, Wetzlar,

Germany) The nuclei were red and the hybridization

sig-nals were yellow-green Previously photographed

G-ban-ded metaphases were relocated, and re-photographed

Chromosomal localization of the transgene integration site

was determined by combining FISH hybridization signals

and G-banding results on the same metaphases The mice examined included TK5-F1-455#, TK5-F2-325$ The standard idiograms of mouse chromosomes were obtained from the web site: http://www.ncbi.nlm.nih.gov/genome/ guide/mouse/

RT-PCR of HSV-tk transcription The 60-day-old transgenic mouse TK5-F1-455 was killed under pentobarbital anaesthesia (60 mgÆkg)1) with all possi-ble measures taken to ensure minimum pain and discomfort Animal experiments were performed according to the National Institute of Health Guidelines for Care and Use of Laboratory Animals The tissues of heart, liver, spleen, kid-ney, brain, intestine, pancreas, skin, testis and blood were powdered over an ice bath, total RNA was extracted using the Trizol reagent (Gibco⁄ BRL) Primers stk1 and SH552 were used to amplify the 390-bp region HSV-tk The 190 bp b-actin fragment amplified using primers MA2 (5¢-CCAC AGGCATTGTGATGGA-3¢) and MA3 (5¢-GCTGTGGT GGTGAAGCTGTA-3¢) was used as an internal control

Immunohistochemical analysis of HSV-tk expression

Immunohistochemical staining was performed to detect HSV-tk expression in hepatocytes Tissues fixed in 4% (v⁄ v) phosphate-buffered formalin were embedded in

paraf-fin and 5 lm-thick sections were stained Briefly, parafparaf-fin- paraffin-embedded tissue sections were dewaxed, rehydrated, and permeated before blotting, the slides were then incubated with the rabbit polyclonal anti-(HSV-tk) Ig diluted 1 : 250

in NaCl⁄ Tris for 1 h at 37
C in a humidified chamber The slides were then washed three times and incubated with biotinylated goat anti-rabbit immunoglobulins (DAKO) at

a dilution of 1 : 300 in NaCl⁄ Tris for 1 h at room tempera-ture with protection against light After washing three times with NaCl⁄ Tris, peroxidase-conjugated streptavidin (DAKO) diluted 1 : 300 was added for 1 h at room tem-perature and washed three times with NaCl⁄ Tris Finally, the signal was visualized by incubating the slides with 3–3¢-diaminobenzidine (DAKO) The examined mice included TK5-F1-455, TK5-F2-325 and TK3

Induction of liver damage For the present study, mice were housed individually at

22
C using a 12 h light ⁄ 12 h dark photoperiod Three trans-genic mice of TK5-F1 (including three #), TK5-F2 (including two # and one $) and TK3 aged 8–14 weeks, received tail vein injections of sodium GCV (10 mgÆkg)1) at 48 h intervals through a 29-gauge needle on 10 occasions, meanwhile three nontransgenic mice served as the control GCV was dissolved

in NaCl⁄ Piand filter-sterilized before administration

4% (v⁄ v) phosphate-buffered formalin and

paraffin-embed-ded sections were stained using hematoxylin and eosin as

described previously [38,39]

Biochemical analysis of blood

The physiological function of the liver was examined by

determining biochemical serum values Before the

experi-ment, physiological function of the liver was determined to

be normal by examination of serum ALT, AST, total

biliru-bin, albumin, globulin creatinine, total protein, lactate

dehydrogenase and others Peripheral blood was extracted

from the tail vein once a week for 3 weeks for analysis of

ALT, AST, total bilirubin and creatinine Student’s t-test

(SAS software) was performed to compare the differences

in serum values in transgenic mice and controls after GCV

administration P < 0.05 was considered significant

Acknowledgements

We thank Drs Yi-Ping Hu (Department of Cell

Bio-logy, Second Military Medical University of PLA,

Shanghai, China), Willams Summers (Yale University,

USA), Zheng-Hong Yuan (Key Laboratory of Medical

Molecular Virology, Fudan University, Shanghai,

China) and Hynes (Friedrich Miescher Institute of

Switzerland, Basel, Switzerland) for pTK-neo plasmid,

polyclonal rabbit anti-(HSV-tk), Hep-G2 and HC-11

cell lines, respectively We would like to thank Drs

Zhao-Rui Ren, Jing-Zhi Zhang (Institute of Medical

Genetics, School of Medicine, Shanghai Jiao Tong

University, China) and Dr Xiao-Kang Li (the National

Institute for Child and Development, Japan) for their

very helpful discussion in this work We also thank

Yi-Wen Zhu, Wen-Ying Huang, Xiu-Li Gong

(Insti-tute of Medical Genetics, School of Medicine,

Shang-hai Jiao Tong University, China) for their performing

the FISH and microinjections The study was supported

by: the Chinese National Program for High Technology

Research and Development (No.2002AA216091)

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