TAFII250, Egr-1, and D-type cyclin expression in mice and neonatal rat cardiomyocytes treated with doxorubicin

HOME

HELP

FEEDBACK

SUBSCRIPTIONS

TAFII250, Egr-1, and D-type cyclin expression in mice and neonatal rat cardiomyocytes treated with doxorubicin

Nacéra Saadane¹, Lesley Alpert², and Lorraine E. Chalifour¹^,³

¹ Lady Davis Institute for Medical Research and ² Department of Pathology, Sir Mortimer B. Davis Jewish General Hospital, Montreal H3T 1E2; and ³ Division of Experimental Medicine, Department of Medicine, McGill University, Montreal, Quebec, Canada H3A 1A3

ABSTRACT

Top
Abstract
Introduction
Materials and methods
Results
Discussion
References

Differential display identified that gene fragment HA220 homologous to the transcriptional activator factor II 250 (TAFII250)gene, or CCG1, was increased in hypertrophied rodent heart. Todetermine whether TAFII250 gene expression is modified after cardiacdamage, we measured TAFII250 expression in vivo in mouse heartsafter injection of the cardiotoxic agent doxorubicin (DXR) andin vitro in DXR-treated isolated rat neonatal cardiomyocytes.In vivo atrial natriuretic factor (ANF), $beta$ -myosin heavy chain( $beta$ -MHC), Egr-1, and TAFII250 expression increased with dose andtime after a single DXR injection, but only ANF and $beta$ -MHC expressionwere increased after multiple injections. After DXR treatmentof neonatal cardiomyocytes we found decreased ANF, $alpha$ -MHC, Egr-1,and TAFII250 expression. Expression of the TAFII250-regulatedgenes, the D-type cyclins, was increased after a single injectionin adult mice and was decreased in DXR-treated cardiomyocytes.Thus expression of Erg-1, TAFII250, and the D-type cyclins ismodulated after cardiotoxic damage in adult and neonatalheart.

cardiac damage; differential gene expression; transcriptional activator factor II 250; early growth response-1; cyclins D1, D2, and D3

	INTRODUCTION

Top Abstract Introduction Materials and methods Results Discussion References

PREVIOUSLY, WE ISOLATED transgenic mice that expressed the polyomavirus large T-antigen gene in cardiomyocytes, testes, andendothelial cells (1, 6-8). The transgenic mice display acardiomyocyte hypertrophy with morphological and molecular featuresfound in rodent hypertrophy (17, 18). We set out to identifyspecific mRNAs overexpressed in the hypertrophied transgenic heartand low or absent in the normal heart. We compared the expressionof a series of known genes in normal and hypertrophied heartsand used differential display to identify genes discordantly expressedin normal vs. hypertrophied rodent hearts. We identified earlygrowth response-1 (Egr-1) as uniquely increased in expressionin every hypertrophied heart and c-fos as increased in most hypertrophiedtransgenic hearts (17). Differential display (30, 35) identifieda set of 10 DNA fragments representing mRNAs overexpressed inhypertrophied hearts from transgenic mice and low or absent innormal hearts. We identified one of the DNA fragments as homologousto the hamster and human transcription activator factor II 250(TAFII250).

TAFII250, the largest protein in the TFIID complex, binds to the TATA-box binding protein (TBP) and participates in the formationof the TFIID complex (42). The TAFII250 protein has NH₂-terminaland COOH-terminal serine kinase domains, a histone acetyltransferase(HAT) domain, two retinoblastoma (Rb) binding domains, an adenovirusearly region 1A (E1A) binding domain, a nuclear localization signal,two bromodomains, and a non-histone chromosomal protein (HMG-1)-likearea (50). TAFII250 was originally named cell cycle gene 1 (CCG1)because it was mutated in the temperature-sensitive (ts) G1 mutanthamster cell lines tsBN462 and ts13 (16). These tsBN462 andts13 cells do not show a global loss of mRNA levels, but levelsof cyclin A, cyclin D1, and cyclin D3 are reduced at the nonpermissivetemperature (47, 53, 58). Because cell death could be suppressedby transfection of wild-type CCG1 into the ts cell lines, it wassuggested that wild-type CCG1/TAFII250 functioned as a repressorof apoptosis (46, 58), linking TAFII250 expression to thecontrol of cyclin expression andapoptosis.

Programmed cell death, apoptosis, occurs in the myocyte after ischemia-reperfusion, myocardial infarction, longstanding heartfailure, normal cardiac development, and aging (20, 22). Cardiotoxicagents include the alkaloid emetine in ipecac syrup, cocaine,ethyl alcohol, and doxorubicin (DXR) (11). The anthracyclineantibiotic is a widely used antineoplastic agent (reviewed inRef. 48). However, the irreversible cardiotoxicity of DXR limitsits therapeutic use. DXR-damaged hearts typically display a dilatedcardiomyopathy characterized by a reduced ejection fraction, ventricularwall thinning, and chamber dilation. DXR-induced cardiac damageis thought to be due to induction of oxidative stress and apoptosis(48). In DXR-treated hearts, damaged cardiomyocytes are replacedby connective tissue, and the remaining cardiomyocytes experiencehypertrophy.

We hypothesized that an increase in TAFII250 expression might be present after cardiotoxic damage. In this paper the mousesequences of the TAFII250 are compared with the relevant humanand hamster sequences. We describe our experiments on the expressionof TAFII250 and Egr-1 after DXR treatments given either acutelyor chronically to mice or to isolated rat cardiomyocytes. We describean association between the increase in TAFII250 expression andthe increase in expression of the TAFII250-regulated genes, cyclinsD1, D2, and D3, in vivo. In contrast, DXR-treatment of isolatedneonatal rat cardiomyocytes decreased both TAFII250 and cyclinexpression. These results suggest a link between TAFII250 expressionand cyclin expression inheart.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and methods Results Discussion References

Materials. Taq DNA polymerase and Superscript II reverse transcriptase polymerase were obtained from GIBCO BRL, a PTC-100 programmabletemperature controller was purchased from MJ Research, and RNaseH was purchased from MBI Fermentas. Klenow DNA polymerase, oligo(dT),and guanidine thiocyanate were purchased from Pharmacia. GeneScreen Plus membrane was obtained from DuPont-New England Nuclear.CD-1 virgin and pregnant mice and Sprague-Dawley rat day 1 neonateswere purchased from Charles River Canada. All oligonucleotidesfor differential display and gene-specific analyses were purchasedfrom the Sheldon Biotechnology Centre at McGill University. Randomprimers, pd(NTP)6, were purchased from Pharmacia. Doxorubicinwas a gift from Dr. Moulay Alaoui-Jamali, Lady Davis Institutefor MedicalResearch.

Primers and cDNAs. The sequences of the anchored primers were 5'-T₁₁CT', 5'-T₁₁AC, 5'-T₁₁AG, and 5'-T₁₁AA. The sequences of three arbitrary 10-merprimers used in this study were 5'-CAAGATAGGC-3' (AP-1), 5'-CTGTAGATGG-3'(AP-2), or 5'-CGTAAGAGTC-3' (AP-3). Unless otherwise noted allprimers were selected using the PC/GENE program(IntelliGenetics).

Mouse TAFII250-specific primers for the NH₂-terminal kinase region were regions P4 (5'-AGGAAGACAGCACAGGCAGAATCTAAGG-3') andM15 (5'-CCACAGCCGAGCAGGTCCATAACG-3') with an annealing temperatureof 59°C, and for the region from RNA polymerase II-associatingprotein 74-kDa subunit (RAP74) to the COOH-terminal kinase wereP14 (5'-GGAGTATGTTCGTTGTGAGACAGTCCG-3') and M5 (5'-TGAGTCAGTGAGTGTTTCGGCCC-3')with an annealing temperature of 57°C. The cyclin D1 primers werecyclin D (5'-CTGGCCATGAACTACCTGGA-3'), cyclin D1 specific (5'-GTCACACTTGATCACTCTGG-3'),cyclin D2 specific (5'-CATGGCAAACTTAAAGTCGG-3'), and cyclin D3specific (5'-CCAGGAAATCATGTGCAATC-3') with an annealing temperatureof 48°C (55). Atrial natriuretic factor (ANF)-specific primerswere P3 (5'-GAGAGACGGCAGTGCTTCTAGGC-3') and M7 (5'-CGTGACACACCACAAGGGCTTAGG-3')with an annealing temperature of 53°C. $alpha$ -Myosin heavy chain ( $alpha$ -MHC)-specificprimers were P5 (5'-CAGAAGTAGAGGAGGCAGTACAGG-3') and M3 (5'-CCTGGCGCTTGTAGGCC-3'),and $beta$ -myosin heavy chain ( $beta$ -MHC)-specific primers were P1 (5'-GACGAGGCAGAGCAGATCGC-3')and M12 (5'-GGGCTTCACAGGCATCCTTAGGG-3') with annealing temperaturesof 59°C. Egr-1-specific primers were P50 (5'-TTTGCCTCCGTTCCACCTGC-3')and M8 (5'-TGCCAACTTGATGGTCTAGCGC-3') with an annealing temperatureof 58°C. Tubulin-specific primers were T16 (5'-TCCATCCACGTCGGCCAGGCT-3')and T500 (5'-GTAGGGCTCAACCACAGCAGT-3') with an annealing temperatureof 61°C.

The cDNA for human TAFII250 was a gift from Dr. Robert Tjian (University of California at Berkeley). ANF cDNA was a gift fromDr. Mona Nemer (Institut National de la Santé et de la RechercheMédicale, Montreal, Canada). Mouse Egr-1 cDNA, GenBank/EuropeanMolecular Biology Laboratories (EMBL) J04089, was purchasedfrom American Type Culture Collection. Cyclin D1 cDNA was a giftfrom Dr. John Th'ng [Lady Davis Institute/Jewish General Hospital(LDI/JGH), Montreal, Canada]. The amplified mouse cDNAs from tubulin,cyclin D2, cyclin D3, $alpha$ -MHC, and $beta$ -MHC were purified, cloned intopBluescript, and sequenced. Before the cDNAs were radioactivelylabeled for use as probes on Southern blots, they were excisedfrom the background plasmid and gelpurified.

Mice. Isolation and characterization of the transgenic mice was reported previously (7, 8). Normal and hypertrophic heartsfrom transgenic mice were obtained from 4- to 8-mo-old adult mice.Mice and rats were housed and bred, and experiments were performedaccording to the regulations of the Canadian Council of AnimalCare and the Animal Care Committee of the Lady Davis Institutefor MedicalResearch.

DXR treatment of adult mice. In the acute study, 6- to 8-wk-old female CD-1 mice (average wt 25 g) were randomly placed into eight groups (n $>=$ 8 mice/group)and injected intraperitoneally with DXR at concentrations of 10,20, or 30 mg/kg, and the mice were killed 1 or 7 days later. Controlanimals were injected withsaline.

In the chronic study 6- to 8-wk-old CD-1 female mice (average wt 25 g) were randomly placed into two groups (n $>=$ 8 mice/group)and injected intraperitoneally three times at 1-wk intervals witheither 10 mg/kg DXR or saline, and mice were killed 1 wk afterthe lastinjection.

Representative midventricle horizontal cross sections of all mouse hearts were fixed in neutral buffered Formalin, routinelyprocessed, and embedded in paraffin. Sections were cut at 4 µmand stained with hematoxylin and eosin or with Masson's trichromestain. Sections were examined in a blindedfashion.

Neonatal rat cardiomyocyte and cardiac fibroblast isolation and DXR treatment. Day 1 rat neonates were killed by decapitation, and the hearts were removed. Hearts were minced in pancreatin-containing media(GIBCO 25720-012), digested at 37°C, and briefly centrifuged,and the supernatant was discarded. Fresh pancreatin solution wasadded and the digestion was repeated five to six times until mostof the heart tissue was digested. Once in growth medium [DMEM/199(4:1), 5% fetal calf serum, 5% horse serum and antibiotics] thecell suspension was preplated onto petri dishes for 1.5-2 h toallow fibroblasts to adhere. The cardiomyocyte-enriched and fibroblast-depletedsuspension was then plated onto gelatin-coated dishes at a densityof 1 × 10⁴ cells/ml. Cardiac fibroblasts did not constitute more than 10%of the cardiomyocyte cultures. Beating cardiomyocytes were foundthe next day. Before DXR treatment, the media were removed andreplaced with treatment media [DMEM/199 (4:1), 1% horse serumand antibiotics] for 24 h. Plates were randomly assigned to salineor treatment regimens, and the media were removed and replacedwith treatment media plus saline or treatment media plus 2 µMDXR. After 24 h, washed cells were scraped from the dishes andRNA wasextracted.

RNA preparation. RNA from normal nontransgenic adult heart and hypertrophied transgenic hearts, as well as from DXR-treated and saline-treatedhearts, was isolated after homogenization in guanidine isothiocyanateand centrifugation through a cesium chloride cushion (2). RNAwas prepared from neonatal rat cardiomyocytes and fibroblastsby the method of Chomczynski and Sacchi (10). All purified RNAswere incubated with RNase-free DNase (Pharmacia) to remove residualgenomicDNA.

Differential display. The differential display technique was performed as described in Mou et al. (35). Briefly, 0.2 µg of DNA-free total RNAfrom nontransgenic and hypertrophied transgenic heart was incubatedseparately with 50 µM of each anchored primer (T₁₁AC, T₁₁AG, T₁₁GT,and T₁₁AA), 200 µM dNTPs, 10 mM DTT, and first-strand reactionbuffer and Superscript reverse transcriptase II according to themanufacturer's (GIBCO BRL) instructions. Each PCR reaction containedTaq DNA polymerase buffer, 25 mM MgCl₂, 20 µM of the same anchoredprimer as in the RT reaction, 20 µM of an arbitrary primer (AP-1,AP-2 or AP-3), 2 µl of the RT reaction mixture, 0.5 µl ³⁵S-labeled dATP (>300 Ci/mM), and 2.5 U Taq DNA polymerase (GIBCO).The PCR parameters were denaturation at 94°C for 4 min, followedby 40 cycles of denaturation at 94°C for 30 s, annealing at 40°Cfor 2 min, and extension at 72°C for 30 s, followed by a final10-min postextension at 72°C. Radiolabeled PCR products were separatedon an 8% polyacrylamide-8 M urea sequencing gel, and the wet gelwas exposed to X-ray film. The anchored primers and arbitraryprimer sequences most informative in this study were T₁₁AG orT₁₁CT, coupled with AP-1, AP-2, or AP-3, respectively. AmplifiedDNA fragments present in some samples, but not in others, wereidentified by inspection; the corresponding piece of gel and Whatmanpaper were identified, cut out, and rehydrated in 150 µl of distilledwater, and the DNA was eluted by boiling. The DNA was precipitatedin ethanol and redissolved in water before reamplification. DenaturedPCR-amplified fragments (~100 ng) were fixed to duplicate nylonmembranes using a slot-blot manifold, and then the membranes werehybridized with double-stranded DNA (dsDNA) probes prepared frommRNA of another set of normal nontransgenic or hypertrophic transgenichearts (6). Autoradiography was carried out at $-$ 80°C for upto 3 days. Positive differentially expressed fragments were clonedinto either pCRII (InVitrogen) or a T-tailed EcoR V linearizedpBluescript vector and transformed into competent DH5 $alpha$ Escherichiacoli.

Both strands from inserts of three independent clones from the differential display or TAFII250 gene fragments were sequencedusing a T7 DNA polymerase sequencing kit (Pharmacia). The genefragment sequences were analyzed for similarity to those depositedin GenBank/EMBL DNA databases. Translation of mouse DNA sequencesinto amino acid sequences was performed with Gene Runner (HastingsSoftware).

RT-PCR. DNA-free total RNA (3 µg) was denatured with 250 ng of random primers at 70°C for 10 min. The first-strand reaction proceededaccording to the Superscript II reverse transcriptase instructionsand included RNase H digestion. The PCR contained Taq DNA polymerasebuffer, 1 mM dNTP, MgCl₂, gene-specific primers (0.6 µg), TaqDNA polymerase (2.5 U), and 2 µl of the first-strand reactionin 100 µl final reaction volume. The amount of MgCl₂ was optimizedfor each primer pair. The amplification parameters were 94°C for4 min, followed by 24 cycles of 94°C for 1 min, annealing for1.5 min, and elongation at 72°C for 2-4 min, followed by a postamplificationof annealing for 2 min and elongation at 72°C for 7 min. ControlPCR reactions with all primer sets showed a linear response upto 30 cycles (data not shown). The annealing temperature for eachprimer pair is described in Primers and cDNAs. Aliquots of eachPCR reaction were electrophoresed through 1.5% agarose, visualizedby ethidium bromide staining, photographed, and transferred toGene Screen Plus membrane using the alkaline downward transfermethod (2). The reaction products were hybridized to radioactivelylabeled gene-specific cDNAs, washed, and exposed to X-ray filmfor 2-10 min. Each series of RT-PCR reactions was repeated atleast three separate times. Suitably exposed X-ray films werescanned using an HP ScanJet 5100C and HP Precision Scan software(Hewlett-Packard). The areas under the peaks were quantitatedusing ScionImage Release Beta 3 software (National Institutesof Health, Bethesda, MD). Means ± SE and P values were calculatedusing StatViewSE+ and ANOVA,respectively.

	RESULTS

Top Abstract Introduction Materials and methods Results Discussion References

Identification of overexpressed genes associated with heart hypertrophy. Differential display was used to identify hypertrophy-associated genes (Fig. 1). Different combinations of anchored primersand arbitrary primers were added to RNA prepared from adult heartsfrom nontransgenic mice and hypertrophied hearts from adult metallothionein-1promoter-polyomavirus large T antigen (MT-PVLT) transgenic mice.Hypertrophied hearts from the MT-PVLT transgenic mice averaged2.3 times heavier than hearts from nontransgenic hearts (7,17, 18). Figure 1A shows results from a differential displayusing T₁₁AG and AP-1, AP-2 or AP-3. Each primer pair amplifieda subpopulation of mRNA expressed in heart.

View larger version (74K):
[in this window]
[in a new window]

Fig. 1. Differential display of mRNA from nontransgenic and hypertrophied transgenic hearts. A: total RNA from nontransgenic and transgenic mice hearts was isolated and incubated with RT, dNTPs, and anchored primer 3. Samples were then incubated with an arbitrary primer and ³⁵S-dATP and amplified with Taq DNA polymerase. Amplified DNA was electrophoresed through an 8% acrylamide-8 M urea sequencing gel. The gel was fixed, dried, and exposed to X-ray film. Differentially expressed fragments are shown: *, fragment present in normal but not in transgenic heart; arrows, fragment present in transgenic but not normal heart. A radioactively end-labeled pBR322-Msp I-digested DNA was used as a molecular marker (M), and sizes of selected DNA fragments (kDa) are indicated at right. Sources of total RNA: nontransgenic heart (lanes 1, 4, and 5) or transgenic heart (lanes 2, 6, and 7). Arbitrary primer: AP-1 (lanes 1-3), AP-2 (lanes 4 and 6), or AP-3 (lanes 5 and 7) (see text for primer sequences). RT was omitted from sample in lane 3. Arrowhead points to HA220 in lane 6. B and C: 100 ng of reamplified PCR product from each isolated fragment was applied to duplicate membranes using a slot-blot manifold. Total RNA from nontransgenic and hypertrophic transgenic heart was reverse transcribed, and radioactive double-stranded DNA was generated by standard random-priming procedures. Membranes were hybridized with the radioactive probe. Sources of RNA: B, nontransgenic heart; C, hypertrophied transgenic heart. *, Fragments discordantly expressed on rescreening; arrow, HA220.

We identified 48 fragments, between 100 and 600 bp long, overexpressed in hypertrophied transgenic hearts but low or absentfrom normal hearts. Of the 48, 38 were successfully reamplified.In some samples, where a major band was accompanied by a few weakbands, the major band was cut out of the minigel andpurified.

A second screening was performed using RNA prepared from hearts of a second set of normal nontransgenic and hypertrophiedtransgenic mice. Aliquots of reamplified DNA fragments were fixedonto duplicate membranes and hybridized to radioactive cDNA probesprepared from either normal or hypertrophied transgenic hearts(Fig. 1, B and C). Fragments that hybridized primarily with theprobes made from the hypertrophied heart samples were selectedfor further analysis. After this second screening, 10 of the 38fragments consistently showed discordant expression. We namedthese 10 gene fragments hypertrophy-associated (HA) genes. Sequenceanalysis revealed HA220 as homologous to the human and hamsterTAFII250 genes (Fig. 2).

View larger version (10K):
[in this window]
[in a new window]

View larger version (82K):
[in this window]
[in a new window]

Fig. 2. Mouse TAFII250 schematic (mTAFII250; A) and comparison of mouse (M), hamster (HA), and human (HU) TAFII250 cDNA sequences (B-D). A: diagram of TAFII250 domains. Schematic representation of TAFII250 (top) identifying locations of PCR primer pairs, amplified regions, and region of HA220 homology. Regions corresponding to the NH₂-terminal kinase (NTK), COOH-terminal kinase (CTK), and RNA polymerase II-associating protein 74-kDa subunit (RAP74) binding area are labeled. Scale, no. of nucleotides in thousands. Bottom: Rb1 and Rb2 binding domains, E1A binding domains, histone acetyltransferase (HAT), and non-histone chromosomal protein (HMG)-like areas. B-D: amino acid homology of mouse HA220 to hamster and human TAFII250. Differences in mouse, hamster, and human DNA amino acid differences are underlined. Hamster and human sequences were obtained from GenBank (accession nos. D26114 and D90359, respectively). B: homology of mouse differential display fragment HA220 (GenBank accession no. AF081115) to hamster and human TAFII250. C: homology of mouse TAFII250-NTK (GenBank accession no. AF081116) amplified DNA sequence to hamster and human TAFII250. D: homology of mouse TAFII250-RC (GenBank accession no. AF081117) amplified DNA sequence to the hamster and human TAFII250.

Mouse TAFII250. TAFII250 is a multidomain protein. The relative locations of the NH₂-terminal and COOH-terminal kinase domains, separate Rband adenovirus E1A binding domains, histone acetyltransferasedomain, and RAP74 binding domain are shown in Fig. 2A (50).The mouse nucleotide HA220 sequence (GenBank accession no. AF081115)matched the hamster TAFII250 (haTAFII250) DNA sequence between2,465 and 2,576 bp and the human TAFII250 (huTAFII250) DNA sequencebetween 2,507 and 2,618 bp, respectively, with 80-100% homology(49, 50). This area was identified as Rb binding area 2 (50).When the deduced amino acid sequence was evaluated (Fig. 2B) andmouse, hamster, and human sequences were compared, we identifieda single mismatch, threonine to glutamine at position 849 of thehamstersequence.

We amplified a 464-bp mouse DNA fragment from the TAFII250 NH₂-terminal kinase (NTK) region. A mouse first-strand cDNA wasused as a source of DNA for amplification. The amplified DNA wasextracted from an agarose gel, cloned into pBluescript, sequenced,and named mTAFII250-NTK. Figure 2C shows the amino acid sequenceof this fragment. The mTAFII250-NTK nucleotide sequence (GenBankaccession no. AF081116) was 92.5% and 90% homologous to haTAFII250and huTAFII250 nucleotide sequences, respectively, with nucleotidechanges located sporadically throughout the sequence. When theamino acid sequence was deduced (Fig. 2C), we identified two clustersof differences among the mouse, hamster, and human sequences centeredaround haTAFII250 amino acids 275 and330.

An 872-bp region spanning the RAP74 and COOH-terminal kinase regions was amplified from mouse first-strand cDNA, extractedfrom an agarose gel, cloned into pBluescript, sequenced, and namedmTAFII250-RC. The mTAFII250 nucleotide sequence (GenBank accessionno. AF081117) was 92.5% and 89% homologous with the haTAFII250and huTAFII250 sequences, respectively. A comparison among themouse, hamster, and human amino acid sequences (Fig. 2D) identifiedfour differences, an alanine-threonine sequence change from theproline-alanine sequence at positions 1,183 and 1,184 presentin both hamster and human TAFII250 and a glutamine-methioninesequence change from the histidine-leucine sequence present inthe hamster and human TAFII250 at positions 1,442 and 1,443. Theconservation of the nucleotide and amino acid sequences in thesethree disparate regions of the gene suggests that the mouse, hamster,and human TAFII250 gene is highly conserved and further suggeststhat the mTAFII250 likely functions in an identical way to itsbetter characterized human and hamsterhomologs.

mTAFII250 in DXR-treated mice: acute study. We first examined the time course of ANF and Egr-1 expression after a single injection of DXR. Animals (n = 4 per time period)were injected with DXR or saline and then killed on day 1, 3,5 or 7. RT-PCR analyses of heart RNA showed that after a 10 mg/kgdose of DXR, female CD-1 mice reproducibly displayed an increasein ANF and Egr-1 expression that was detectable in some mice asearly as day 3 and was present in all mice on days 5 and 7 afterinjection (data not shown). Tubulin expression was similar atall time points, indicating a specific rather than a global effectof DXR on cardiac gene expression. DXR-injured cardiomyocytesgenerally show myofibril loss with vacuolar formation and thinfilament degeneration both in vivo and in vitro (3). Histologicalexamination of hematoxylin and eosin- or trichrome-stained crosssections of DXR-treated midventricle heart did not show evidenceof fibrosis, although vacuolar changes (arrows) were noted onday 7 that were consistent with DXR-induced cardiac damage (Fig.3).

View larger version (128K):
[in this window]
[in a new window]

View larger version (137K):
[in this window]
[in a new window]

Fig. 3. Histology of doxorubicin (DXR)-induced damage. Representative midventricular hemotoxylin and eosin-stained cross sections of hearts from saline-injected (A) or DXR-injected (B) mice. Arrows, regions of vacuole formation in DXR-injected heart; scale bar, 50 µm.

We examined the effect of different doses of DXR on TAFII250, Egr-1, and cyclin D, as well as the expression of the muscle-specificANF, $alpha$ -MHC, and $beta$ -MHC genes. Mice were treated with a single injectionof DXR at doses of 10, 20, or 30 mg/kg and were killed 24 h or7 days after injection. Mice treated with the 10 mg/kg dose hadno discernible change in behavior but showed less than one-halfof the weight gain seen in the saline-injected control mice at7 days. Mice treated with the 20 and 30 mg/kg dose averaged aweight loss approaching 6 g at 7 days, were lethargic, and hada disheveled appearance. Heart-to-body weight ratios were calculated(mean 4.52, range 4.39-4.69) and did not differ significantlybetween control and treatmentgroups.

The effect of increasing doses of DXR on the expression of ANF, $alpha$ -MHC, and $beta$ -MHC 24 h or 7 days after injection is shown inFig. 4. The 10 mg/kg dose of DXR did not result in a rise in ventricularANF initially at 24 h, whereas after 7 days, an increase in ANFmRNA is seen. Doses of 20 and 30 mg/kg induced a significant increasein ANF at both 24 h and 7 days after injection. $beta$ -MHC expressionwas not increased 24 h after injection of the 10 mg/kg dose ofDXR and was significantly increased 7 days postinjection. At thehigher doses of DXR an increase in $beta$ -MHC was also detected both24 h and 7 days after injection. In contrast, expression of $alpha$ -MHCwas unaffected by the DXR injection. The expression of tubulinwas used to standardize the level of expression and did not varybetween saline- and DXR-injected mice. These results demonstratea dose- and time-dependent response of the ventricular heart toDXR treatment. Furthermore, the results indicate that the expressionof some genes, e.g., ANF and $beta$ -MHC genes, increases with timeand dose of DXR, whereas the expression of other genes, e.g.,tubulin and $alpha$ -MHC genes, is unaffected.

View larger version (39K):
[in this window]
[in a new window]

Fig. 4. DXR acute study. RT reactions contained equal amounts (3 µg) of total RNA prepared from ventricles of untreated and treated mice, random primers, and Superscript II reverse transcriptase; 2 µl of each first-strand reaction were then amplified using Taq DNA polymerase and gene-specific primers. Equal aliquots from each reaction were electrophoresed through an agarose gel, and the DNA was transferred to membranes and probed with radioactive gene-specific cDNAs (n = 8 animals per dose and time period). Top: representative Southern blots from RT-PCR of RNA isolated from saline-treated (Sal) and DXR-treated mice; bottom: bar graphs of densitometry of Southern blots from 3 separate experiments. Expression from saline-injected mice was artificially designated as 1. RNA sources: Sal, saline-injected mice; 10, 20, 30, mice injected with 10, 20, or 30 mg/kg DXR and killed on day 1 or 7. ANF, atrial natriuretic factor; MHC, myosin heavy chain. * Significantly different (P < 0.05) from DXR-treated mice. Values are means ± SE.

We examined the expression of Egr-1, an immediate- early gene whose expression increases during hypertrophy, and TAFII250.The results are shown in Fig. 4. Egr-1 expression was similarto control samples after the 10, 20, or 30 mg/kg dose 24 h afterDXR injection. Seven days postinjection the expression of Egr-1was elevated significantly at all doses tested. TAFII250 expressionwas not significantly (P > 0.05) increased 24 h after injectionof the 10 mg/kg dose of DXR, whereas after the increased doseof 20 or 30 mg/kg, TAFII250 expression was similar to the saline-injectedcontrol. Seven days postinjection TAFII250 expression was significantlyincreased at all doses of DXR tested. A similar pattern of TAFII250expression was found when PCR primers homologous to the regionseparating the RAP74 and COOH-terminal kinase were used to amplifymTAFII250 mRNA in the PCR reaction (data not shown). These resultsindicate that Egr-1 and TAFII250 were not increased shortly afterDXR-injection but were elevated after 7days.

mTAFII250 in DXR-treated mice: chronic study. Cardiotoxic damage is more likely if multiple doses and an increased accumulated dose of DXR are received (31, 52). Thereforewe injected female mice three times with 10 mg/kg DXR spaced at1-wk intervals, for an accumulated dose of 30 mg/kg. Mice werekilled 7 days after the last injection. Control animals receivedan equal volume of saline. Saline-injected mice had an averageweight gain of 1.6 g (range 0.7-2.3 g) over the injection period,whereas DXR-injected animals had an average weight loss of 2.7g (range 1.5-3.9 g), suggesting that this schedule of chronicDXR treatment was detrimental to the overall health of the mice.Heart-to-body weight ratios did not differ between control (mean4.47, range 3.95-4.98) and DXR-treated animals (mean 4.4, range4.08-5.06), a result that was similar to the results noted alreadyin the acute study. Histological analysis using hematoxylin andeosin staining as well as trichrome staining of midventricularcross sections indicates that, although vacuolar changes werefound in cardiomyocytes, no evidence of fibrosis wasvisible.

We first examined RNA samples prepared from ventricular heart for tubulin, ANF, $alpha$ -MHC, and $beta$ -MHC expression, with the resultsshown in Fig. 5. Tubulin expression was similar in the saline-injectedand DXR-injected animals, indicating that basal gene expressionwas unaltered by the treatment. ANF expression was significantlyincreased in the DXR-treated animals compared with the saline-injectedanimal. $alpha$ -MHC expression was similar in the saline-injected andDXR-treated animals. In contrast, $beta$ -MHC expression was increasedin the DXR-treated compared with the saline-injected control.These results indicate that, similar to our findings in the acutestudy, chronic treatment with DXR caused a selective increasein ANF and $beta$ -MHC expression, whereas expression of tubulin and $alpha$ -MHC was unaffected.

View larger version (16K):
[in this window]
[in a new window]

Fig. 5. DXR chronic study. Southern blots of RT-PCR reactions were performed as described in Fig. 4 and in MATERIALS AND METHODS using RNA prepared from ventricles of mice injected with either saline or 10 mg/kg DXR for 3 consecutive weeks with mice killed 1 wk after last injection; 6 animals/group were analyzed in triplicate. A: representative Southern blots from RT-PCR of RNA isolated from saline-injected and DXR-treated mice. B: bar graphs of Southern blot data from 3 separate experiments. Expression from saline-injected mice was designated as 1. RNA sources: Sal, saline-injected mice; DXR, mice injected with 10 mg/kg DXR. * Significantly different (P < 0.05) from DXR-treated mice. Values are means ± SE.

We next examined Egr-1 and TAFII250 expression. Neither Egr-1 nor TAFII250 expression was significantly different in the saline-injectedvs. DXR-injected animals. These results are in contrast to theresults found in the acute study described above, in which atthis same dose of DXR (10 mg/kg) an increase in both Egr-1 andTAFII250 was detected 7 days postinjection. The accumulated doseof the animals was 30 mg/kg over the course of the 3-wk experiment.These results suggest that the response to a chronic dose is notequivalent to the response to a single dose of the initiatingamount of DXR, 10 mg/kg, or the accumulated dose, 30 mg/kg.

mTAFII250 in isolated neonatal rat cardiomyocytes and cardiac fibroblasts. Cardiomyocytes and cardiac fibroblasts were isolated from day 1 rat neonates. Preplating of the pancreatin-treated heart cellsuspension greatly reduced the number of fibroblasts in the cardiomyocyteculture and allowed separate treatment of both cardiomyocyte andcardiac fibroblasts cultures with saline or DXR. Inspection ofthe cultures showed the presence of beating cardiomyocytes inthe cardiac fibroblast culture and also a minor number of cardiacfibroblasts present in the cardiomyocyte culture. Plates wererandomly assigned to either saline treatment or the addition of2 µM DXR for 24 h before RNA collection. Cells were treated withmedia containing 1% horse serum for 24 h before the addition ofsaline or DXR to minimize any increase in cell numbers for thecardiac fibroblast relative to the cardiomyocytecultures.

We examined the expression of tubulin, ANF, $alpha$ -MHC, and $beta$ -MHC, and the results are shown in Fig. 6. Tubulin did not vary betweenthe saline-treated or DXR-treated cardiomyocytes or cardiac fibroblasts.ANF and $alpha$ -MHC, but not $beta$ -MHC, were significantly decreased inthe DXR-treated cardiomyocytes compared with the saline-treatedcardiomyocytes. These results suggest that DXR treatment of theneonate cardiomyocytes caused a decrease in expression of ANFand $alpha$ -MHC without a significant decrease in tubulin or $beta$ -MHC expression.

View larger version (27K):
[in this window]
[in a new window]

Fig. 6. DXR study: cardiomyocytes (A) and cardiac fibroblasts (B). Neonatal rat hearts were excised, and cardiomyocytes and cardiac fibroblasts were isolated and cultured separately as described in MATERIALS AND METHODS. Cells were treated with Sal or 2 µM DXR for 24 h before RNA collection. Culture, drug treatment, and RT-PCR reactions were performed at same time for cardiomyocytes and cardiac fibroblasts. Representative Southern blots of RT-PCR reactions were performed using RNA from rat neonatal cardiomyocytes (A, top) or cardiac fibroblasts (B, top). Bar graphs of densitometry show means ± SE of triplicate RT-PCR measurements from 2 separate experiments for cardiomyocytes (A, bottom) and cardiac fibroblasts (B, bottom). Expression from saline-treated cells designated as 1 AU. * Significantly different (P < 0.05) from saline-treated mice.

We then examined the expression of Egr-1 and TAFII250 in the DXR-treated cardiomyocytes (Fig. 6). Egr-1 and TAFII250 expressionwas significantly reduced in the DXR-treated cardiomyocytes andcardiac fibroblasts compared with the saline-treated cardiomyocytesand cardiacfibroblasts.

TAFII250-regulated genes: the D-type cyclins. TAFII250 was shown to positively regulate the expression of the D-type cyclins, D1, D2, and D3 (46, 49). D-type cyclinRNA expression coincides with the level of cyclin protein in cardiomyocytes(43). We therefore examined the expression of cyclins D1, D2,and D3 by using a competitive PCR method (55) in the acute study,in the chronic study, and in isolated rat neonatal cardiomyocytesand cardiac fibroblasts; the results are shown in Fig. 7, A andB. Control experiments (data not shown) analyzing the cyclin D-specificgenes individually gave identical results to those shown here.One day after DXR injection in the acute study (Fig. 7A), theexpression of cyclins D1, D2, and D3 was significantly increasedafter the 10 mg/kg dose compared with the saline-injected control.The 20 and 30 mg/kg doses resulted in an increase in cyclin D1and D2, but not cyclin D3, expression. Seven days postinjectionthe expression of cyclins D1, D2, and D3 was significantly increasedat the 10 mg/kg dose, and cyclins D1 and D2 were significantlyincreased at the 10 and 20 mg/kg doses tested. We found that the10 mg/kg dose elicited larger increases in all D-type cyclin expressionthan the 20 or 30 mg/kg dose of DXR. In the chronic study onlyan increase in cyclin D2 expression was found in the saline-injectedcompared with the DXR-injected samples. Isolated cardiomyocytes(Fig. 7B) treated with saline or DXR showed no change in cyclinD1 expression but significant decreases in expression of D2 andD3 cyclins. In contrast, DXR or saline treatment of cardiac fibroblastsdid not change the pattern or expression of the D cyclins.

View larger version (29K):
[in this window]
[in a new window]

View larger version (33K):
[in this window]
[in a new window]

Fig. 7. DXR study: cyclins in vivo (A) and in vitro (B). A, top: Southern blots of RT-PCR from RNA isolated from mice described in MATERIALS AND METHODS used cyclin D-specific primers and RNA from adult mice injected with a single dose of DXR (acute, left) or after multiple doses of DXR (chronic, right). D1, D2, and D3 are cyclins D1, D2, and D3. A, bottom: bar graphs from duplicate RT-PCR from 3 separate experiments. Values are means ± SE. Expression from saline-treated mice designated as 1 arbitrary unit. * Significantly different (P < 0.05) from saline-treated mice. RNA sources: Sal, saline-injected mice; 10, 20, 30, mice treated with 10, 20, or 30 mg/kg DXR, respectively, and killed on day 1 or 7. B, top: representative Southern blots of triplicate RT-PCR from 2 separate experiments performed using cyclin D-specific primers and RNA from neonatal rat cardiomyocytes or cardiac fibroblasts after treatment for 24 h with Sal or DXR as described in MATERIALS AND METHODS. B, bottom: bar graphs from densitometry of Southern blots. Values are means ± SE; * Significantly different (P < 0.05) from saline-treated cells. Sources of RNA: Sal, saline-treated cells; DXR, DXR-treated cells.

	DISCUSSION

Top Abstract Introduction Materials and methods Results Discussion References

Synthesis of mRNA by RNA polymerase II is controlled by DNA elements in the region upstream of the coding sequence. Cis-actingDNA elements can generally be divided into basal promoter andenhancer regions (reviewed in Refs. 23, 28, 40, 57). Recentevidence suggests that the basal and enhancer regions communicatethrough activators that form part of the TFIID complex. TFIIDincludes the TATA-box binding protein and a set of eight or moretranscription-associated factors (TAFs). These TAFs are not requiredfor basal transcription but mediate regulated transcription (reviewedin Ref. 28). A current model suggests that TAFs form contactswith each other as well as with gene-specific activators and repressors(57). It has been hypothesized that TAFs play an active rolein regulating cell proliferation, development, differentiationand apoptosis and may be involved in oncogenesis and genetic diseases(38). It is likely that properties present in TAFII250 1) helpexpose promoter elements in chromatin, permitting entry of thetranscriptional machinery; 2) aid in the recruitment of RNA polymeraseII; and 3) attract and hold enhancer binding proteins throughprotein-protein binding with other TAFs and transcription factorsand intrinsic enzyme activities. Our results suggest that TAFII250is an important regulator of gene expression inheart.

We have shown that TAFII250 and Egr-1 expression is increased in DXR-induced cardiac injury and that such overexpression isdose- and time dependent. We further show that the increase inTAFII250 is concomitant with an increase in expression of theD-type cyclins, previously shown to be TAFII250. To our knowledgethis is the first time TAFII250 expression has been linked toa physiological process. In contrast, in neonatal cardiomyocytes,TAFII250 and D-type cyclin expression was decreased. These conflictingresults suggest that expression of TAFII250 may be linked to thatof the D-type cyclins in cardiomyocytes and also suggest thatadult and neonatal cardiomyocytes do not respond to DXRsimilarly.

Circumstantial evidence has suggested a role for a protein with the activities present in TAFII250 in cardiac gene expression.A hallmark feature of cardiac hypertrophy and damage is the reexpressionof previously silent muscle-specific genes (reviewed in Ref. 56).Acetylation of histones H3 and H4 has been correlated with chromatintranscriptional activation and release of specific promoters fromrepression (reviewed in Ref. 37). Recently, an H3- and H4-specifichistone acetyltransferase activity was detected in vitro in theamino terminal half of TAFII250 (34). Studies in HeLa cellsshowed that an activating transcription factor/cAMP- responseelement (ATF/CRE) site and a novel DXR-induced kinase were necessaryand sufficient for DXR-mediated gene expression changes (27).ATF/CRE sites (TGACGTCA) are present in many gene promoters, suchas ANF and Egr-1, that are induced in cardiac damage and hypertrophy(41, 54). TAFII250-dependent activation of cyclin D1 is lostwhen the CRE site is absent, suggesting that TAFII250 interacts,directly or indirectly, with CRE binding proteins (53). In DXR-treatedHeLa cells, incubation with the H7 kinase inhibitor abolishedDXR toxicity, suggesting that kinase activity is central to itstoxicity (27). Kurabayashi et al. (27) concluded that DXRactivates a kinase that potentiates the activity of a factor alreadybound to DNA. In the current model of TAF activation TAFII250activates transcription by binding to TATA-box binding proteinspreviously bound to DNA (9, 12). The TBP-bound TAFII250 subsequentlyinteracts with different TAFs, suggesting that TAFII250 and thetranscription factors, including factors such as Sp1, interactdirectly (9, 12). TAFII250 has both an NH₂-terminal and COOH-terminalserine kinase (42). Although phosphorylation was shown to bespecific for RAP74 compared with other TAFs, TAFII250 phosphorylationof other, potentially adjacent and transcriptionally relevanttargets, such as Egr-1, c-jun, or c-fos, has not been reported.It is unclear if the results with HeLa cells can be directly transcribedto cardiomyocytes, but the limited data using cardiomyocytes supportthe idea that regulation via ATF/CRE sites and kinase activationis important in DXR-mediated cardiomyocytedamage.

TAFII250 controls expression of the D-type cyclins in fibroblasts (47, 53, 58). We found that higher amounts of TAFII250expression were associated with higher amounts of the D-type cyclinsin adult hearts and lower amounts of TAFII250 expression wereassociated with lower amounts of D-type cyclins neonatal cardiomyocytesin vitro. These studies suggest that TAFII250 controls the levelof D-type cyclin expression in heart. The role of cyclins andcdk activity in heart is unclear. In transgenic mice overexpressingcyclin D1 in the heart, an increase in cardiomyocyte DNA contentoccurred without an increase in cardiomyocyte number (51). Nochange in muscle-specific contractile proteins or Rb phosphorylationwas detected, and the transgenic mice did not develop a hypertrophyor cardiomyopathy. Similarly to the transgenic experiments, wefound no temporal correlation between ANF and $beta$ -MHC expressionand TAFII250 or cyclin expression in chronically treated DXR-damagedhearts. These data do not preclude control of ANF or $beta$ -MHC expressionby TAFII250 at some time point but indicate that a continued highlevel of TAFII250 is notnecessary.

Cyclin D may play a role, other than in cell cycle regulation, in terminally differentiated cells. We found expression ofall three D-type cyclins in neonatal rat cardiomyocytes, however,and found a significant decrease in cyclin D2 and D3, but notin cyclin D1, with DXR treatment. Also decreased were TAFII250,Egr-1, $alpha$ -MHC, and ANF expression in the DXR-treated cardiomyocytes,whereas there was no change in tubulin or $beta$ -MHC levels. A decreasein expression of the cyclins in our experiments suggests thatTAFII250 may regulate cyclin D expression in neonatal rat cardiomyocytes.However, similar results were not detectable in DXR-treated cardiacfibroblasts, suggesting that TAFII250 may not regulate cyclinexpression in these fibroblasts. The results with the neonatalrat cardiomyocytes are similar to those found in the ts hamsterfibroblast cell lines, in which expression of TAFII250 and cyclinA and D were linked (46, 58). In other studies with neonatalcardiomyocytes, serum and angiotensin II increased cyclin D1 andD3 expression without an increase in D1-associated enzyme activity(43). Studies with myoblast and myeloblastic differentiationindicate nonparallel expression of D1 and D3 cyclins, disassociationof cyclin amounts with cdk activity, and cyclin D associationwith non-cdk proteins (25, 26, 39). In our experiments wefound the largest increase in expression of cyclin D1 in the DXR-treatedanimals at all doses in the acute study, whereas there was nochange in cyclin D1 and a drop in cyclins D2 and D3 in the DXR-treatedin vitro cardiomyocyte cultures. These data suggest that the D-typecyclins have nonredundant functions and that the role of cyclinD proteins in undifferentiated cells may not be equivalent tothat of differentiated cells and may change withdevelopment.

Egr-1 is a nuclear phosphoprotein with three zinc fingers that bind to the GC-rich element CGCCCCCGC, present in, e.g., $alpha$ -MHCgene and the Egr-1 gene itself. Egr-1 modulates transcriptionthrough repressive and activating domains and in competition withSp1 (reviewed in Ref. 13). v-Sis-dependent transformed cellgrowth in vitro and in vivo was suppressed by Egr-1 expression.Egr-1 is increased after ionizing radiation injury and oxidativestress, and cells transfected with a dominant-negative Egr-1 mutantsshow a decreased survival (15, 19, 20). In the heart, Egr-1is increased transiently after endothelin, adrenergic, and ANGII activation and stretch, and also in our transgenic model ofhypertrophy (Refs. 4, 32, 36, and 59; and unpublisheddata). Taken together these data suggest that Egr-1 is inducedwhen cells are under stress and that the induction may play aprotectiverole.

The present data demonstrate an increase in TAFII250 and Egr-1 expression on day 7 rather than immediately after an acuteDXR injection on day 1. These data suggest that the TAFII250 andEgr-1 increase is a delayed response in the whole animal. Histologicaldata indicate that vacuolar changes were seen in cardiomyocyteswithout fibrosis, demonstrating that major heart damage had notyet occurred during our experiments. Because of the demonstratedprotective effect of Egr-1 in cultured fibroblast cells and theantiapoptotic activity of TAFII250 in ts hamster cells, theiracute increase may serve to protect hearts from damage. The returnto basal levels in the chronically treated hearts may indicateeither exhaustion of responsive cells, and thus a limit to anyprotective response, or that expression is transient and unrelatedto a protective function. Preliminary data from ongoing experimentsusing DXR-treatment of Egr-1 knockout mice suggest that a lackof Egr-1 is associated with a worse physiological response toDXRtreatment.

The response to an acute dose of DXR is not equivalent to the same dose given chronically or to the accumulated dose. Chronicdosage of DXR is not associated with increased DXR metabolism,and an increase in glutathione-S-transferase activity does notconfer DXR resistance in mammary carcinoma cells (Ref. 45; Alaoui-Jamali,unpublished data). DXR-induced free radical formation is thoughtto be important in its cardiotoxicity, and transgenic mice overexpressingmoderate increases in catalase activity in heart were more resistantto DXR toxicity (11, 24). The antioxidant enzymes glutathioneperoxidase and glutathione reductase were decreased up to 12%in cardiac tissue after chronic DXR treatment without any changein superoxide dismutase or catalase activity (14). These datasuggest that the chronically treated heart would be more sensitiveto further oxidative challenges, and indeed we detected molecularchanges, higher ANF and $beta$ -MHC levels, suggesting that damage hadoccurred. Despite the histological and molecular changes, thelevels of Egr-1, TAFII250, and D1 and D3 cyclins were unchanged,and only a modest, but significant, increase in D2 cyclin wasfound in the DXR-injected animals in our chronic study. Furtherstudies are required to resolve the mechanism of the differentresponses to acute and chronic exposure toDXR.

In conclusion, we show that Egr-1 and TAFII250 are increased in DXR-mediated damage and that TAFII250 overexpression is associatedwith an increased expression of the D-type cyclins in adult heart;TAFII250 underexpression is found along with decreased expressionof cyclins in DXR-treated rat neonatal cardiomyocytes. Egr-1 expressionfollows a similar expression pattern to that of TAFII250. TAFII250and the D-cyclin expression react similarly in DXR-treated adultheart and in DXR-treated neonatal cardiomyocytes, suggesting thatTAFII250 regulates D-type cyclin expression in heart. The differencesin direction of the gene expression changes in DXR-treated adultvs. neonatal cardiomyocytes suggest that developmental changesmay alter the response of the heart to damage. Given 1) the bipartitekinase activity of TAFII250, 2) its activation of transcriptionvia activating transcription factors, 3) its histone acetyltransferaseactivity (HAT), releasing chromatin repression of promoters, 4)its ability to form protein-protein complexes with other TAFsand enhancer-binding proteins, and 5) its overexpression in DXR-damagedheart shown here, we propose that TAFII250 is an important regulatorof normal and pathological heart geneexpression.

	ACKNOWLEDGEMENTS

We thank Drs. John Th'ng and Moulay Alaoui-Jamali for critical reading of the manuscript. We thank Dr. Hung-The Hyunh foruse of Hewlett-Packard equipment and software in thedensitometry.

	FOOTNOTES

This work was supported by grants from the Medical Research Council of Canada (MT-13111) and the Heart and Stroke Foundationof Quebec (L.Chalifour).

The costs of publication of this article were defrayed in part by the payment of page charges. The article must thereforebe hereby marked "advertisement" in accordance with 18 U.S.C.§1734 solely to indicate thisfact.

Address for reprint requests: L. E. Chalifour, Div. of Experimental Medicine, Dept. of Medicine, McGill University, 3755 Côte Ste. Catherine, Montréal, Québec, Canada H3T 1E2.

Received 27 May 1998; accepted in final form 1 October 1998.

	REFERENCES

Top Abstract Introduction Materials and methods Results Discussion References

1. Al Moustafa, A.-E., and L. E. Chalifour. Immortal cell lines isolated from heart differentiate to an endothelial lineage in the presence of retinoic acid. Cell Growth Differ. 4: 841-887, 1993[Abstract].

2. Ausubel, F. M., R. Brent, R. E. Kingston, D. D. Moore, J. G. Seidman, J. A. Smith, and K. Struhl. Current Protocols in Molecular Biology. Toronto: Greene Publishing, 1997.

3. Billingham, M. E., and M. R. Bristow. Evaluation of anthracycline cardiotoxicity: predictive ability and functional correlation of endomyocardial biopsy. Cancer Treatment Symp. 3: 71-76, 1984.

4. Bruneau, B. G., L. A. Piazza, and A. J. DeBold. Alpha(1)-adrenergic stimulation of isolated rat atria results in discoordinate increases in natriuretic peptide secretion and gene expression and enhances Egr-1 and c-myc expression. Endocrinology 137: 137-143, 1996[Abstract].

5. Burley, S. K., and R. G. Roeder. Biochemistry and structural biology of transcription factor IID (TFIID). Annu. Rev. Biochem. 65: 769-799, 1996[Medline].

6. Chalifour, L. E. Slot blot hybridization screening. In: Fingerprinting Methods Based on Arbitrarily Primed PCR, edited by M. R. Micheli, and R. Bova. New York: Springer Verlag, 1997, p. 315-328.

7. Chalifour, L. E., M. L. Gomes, N.-S. Wang, and A.-M. Mes-Masson. Polyomavirus large T-antigen expression in heart of transgenic mice causes cardiomyopathy. Oncogene 5: 1719-1726, 1990[Medline].

8. Chalifour, L. E., A.-M. Mes-Masson, M. L. Gomes, and N.-S. Wang. Testicular adenoma and seminal vesicle engorgement in polyomavirus large T-antigen transgenic mice. Mol. Carcinog. 5: 178-189, 1992[Medline].

9. Chen, J.-L., L. D. Attardi, C. P. Verrijzer, K. Yokomori, and R. Tjian. Assembly of recombinant TFIID reveals differential coactivator requirements for distinct transcriptional activators. Cell 79: 93-105, 1994[Medline].

10. Chomczynski, P., and N. Sacchi. Single-step method of RNA isolation by acid guanidinium thiocyanate-phenol-chloroform extraction. Anal. Biochem. 162: 156-159, 1987[Medline].

11. Combs, A. B., and D. Acosta. Toxic mechanisms of the heart: a review. Toxicol. Pathol. 18: 583-596, 1990[Medline].

12. Dikstein, R., S. Ruppert, and R. Tjian. TAFII250 is a bipartite protein kinase that phosphorylates the basal transcription factor RAP74. Cell 84: 781-790, 1996[Medline].

13. Gashler, A., and V. P. Sukhatme. Early growth response protein 1 (Egr-1): prototype of a zinc-finger family of transcription factors. Prog. Nucleic Acid Res. Mol. Biol. 50: 191-224, 1995[Medline].

14. Gustafson, D. L., J. D. Swanson, and C. A. Pritsos. Modulation of glutathione and glutathione-dependent antioxidant enzymes in mouse heart following doxorubicin therapy. Free Radic. Res. Commun. 19: 111-120, 1993[Medline].

15. Hallahan, D. E., E. Dunphy, S. Virudachalam, V. P. Sukhatme, D. W. Kufe, and R. R. Weichselbaum. c-Jun and Egr-1 participate in DNA synthesis and cell survival in response to ionizing radiation exposure. J. Biol. Chem. 270: 30303-30309, 1995[Abstract/Free Full Text].

16. Hisatake, K., S. Hasegawa, R. Takada, Y. Nakatani, M. Horikoshi, and R. G. Roeder. The p250 subunit of native TATA box-binding factor TFIID is the cell-cycle regulatory protein CCG1. Nature 362: 179-181, 1993[Medline].

17. Holder, E. L., A.-E. Al Moustafa, and L. E. Chalifour. Molecular remodelling in hypertrophied hearts from polyomavirus large T-antigen transgenic mice. Mol. Cell. Biochem. 152: 131-141, 1995[Medline].

18. Holder, E. L., B. Mitmaker, L. Alpert, and L. Chalifour. Morphometry and muscle gene expression in hypertrophied hearts from polyomavirus large T antigen transgenic mice. Am. J. Physiol. 269 (Heart Circ. Physiol. 38): H86-H95, 1995[Abstract/Free Full Text].

19. Huang, R.-P., and E. D. Adamson. A biological role for Egr-1 in cell survival following ultraviolet irradiation. Oncogene 10: 467-475, 1995[Medline].

20. Huang, R.-P., T. Darland, D. Okamura, D. Mercola, and E. D. Adamson. Suppression of v-sis dependent transformation by the transcription factor, Egr-1. Oncogene 9: 1367-1377, 1994[Medline].

21. Huang, R.-P., Y. Fan, Z. Ni, D. Mercola, and E. D. Adamson. Reciprocal modulation between Sp1 and Egr-1. J. Cell. Biochem. 66: 489-499, 1997[Medline].

22. James, T. N. Normal and abnormal consequences of apoptosis in the human heart. Circulation 90: 556-573, 1994[Abstract/Free Full Text].

23. Kaiser, K., and M. Meisterernst. The human general co-factors. Trends Biol. Sci. 21: 342-345, 1996.

24. Kang, Y. J., Y. Chen, and P. N. Epstein. Suppression of doxorubicin cardiotoxicity by overexpression of catalase in the heart of transgenic mice. J. Biol. Chem. 271: 12610-12616, 1996[Abstract/Free Full Text].

25. Kiess, M., R. M. Gill, and P. A. Hamel. Expression and activity of the retinoblastoma protein (pRB)-family proteins, p107 and p130, during L6 myoblast differentiation. Cell Growth Differ. 6: 1287-1298, 1995[Abstract].

26. Kiess, M., R. M. Gill, and P. A. Hamel. Expression of the positive regulator of cell cycle progression, cyclin D3, is induced during differentiation of myoblasts into quiescent myotubes. Oncogene 10: 159-166, 1995[Medline].

27. Kurabayashi, M., S. Dutta, R. Jeyaseelan, and L. Kedes. Doxorubicin-induced Id2A gene transcription is targeted at an activating transcription factor/cyclic AMP response element motif through novel mechanisms involving protein kinases distinct from protein kinase C and protein kinase A. Mol. Cell. Biol. 15: 6386-6397, 1995[Abstract].

28. Latchman, D. S. Eukaryotic transcription factors. Biochem. J. 270: 281-289, 1990[Medline].

29. Li, Z., R. Hromchak, and A. Bloch. Differential expression of protein regulating cell cycle progression in growth vs. differentiation. Biochim. Biochem. Acta 1356: 149-159, 1997.

30. Liang, P., L. Averboroukh, and A. B. Pardee. Distribution and cloning of eukaryotic mRNAs by means of differential display: refinements and optimization. Nucleic Acids Res. 21: 3269-3275, 1994[Abstract/Free Full Text].

31. Lipshultz, S. E., S. D. Colan, R. D. Gelber, A. R. Perez-Atayde, S. E. Sallan, and S. P. Sanders. Late cardiac effects of doxorubicin therapy for acute lymphoblastic leukemia in childhood. N. Engl. J. Med. 324: 808-815, 1991[Abstract].

32. Maass, A., C. Grohe, C. Kubisch, B. Wollnik, H. Vetter, and L. Neyes. Hormonal induction of an immediate-early gene response in myogenic cell lines $---$ a paradigm for heart growth. Eur. Heart J. 16, Suppl. C: C12-C14, 1995.

33. MacLellan, W. R., and M. D. Schneider. Death by design: programmed cell death in cardiovascular biology and disease. Circ. Res. 81: 137-144, 1997[Abstract/Free Full Text].

34. Mizzen, C. A., X.-J. Yang, T. Kokubo, J. E. Brownell, A. J. Bannister, T. Owen-Hughes, J. Workman, L. Wang, S. L. Berger, T. Kouzarides, Y. Nakatani, and C. D. Allis. The TAFII250 subunit of TFIID has histone acetyltransferase activity. Cell 87: 1261-1270, 1996[Medline].

35. Mou, L., H. Miller, J. Li, E. Wang, and L. Chalifour. Improvements to the differential display method for gene analysis. Biochem. Biophys. Res. Commun. 199: 564-569, 1994[Medline].

36. Neyes, L., J. Nouskas, J. Luyken, S. Fronhoff, S. Oberdorf, U. Pfeifer, R. S. Williams, V. P. Sukhatme, and H. Vetter. Induction of immediate-early genes by angiotensin II and endothelin-1 in adult rat cardiomyocytes. J. Hypertens. 11: 927-934, 1993[Medline].

37. Pazin, M. J., and J. T. Kadonaga. What's up and down with histone deacetylation and transcription? Cell 89: 325-338, 1997[Medline].

38. Purrello, M., C. DiPietro, A. Viola, A. Rapisarda, S. Stevens, M. Guermah, Y. Tao, C. Bonaiuto, A. Arcidiacono, A. Messina, G. Sichel, K.-H. Grzeschik, and R. G. Roeder. Genomics and transcription analysis of human TFIID. Oncogene 16: 1633-1638, 1998[Medline].

39. Rao, S. S., and D. S. Kohtz. Positive and negative regulation of D-type cyclin expression in skeletal myoblasts by basic fibroblast growth factor and transforming growth factor beta. A role for cyclin D1 in control of myoblast differentiation. J. Biol. Chem. 270: 4093-4100, 1995[Abstract/Free Full Text].

40. Roeder, R. G. The role of general initiation factors in transcription by RNA polymerase II. Trends Biol. Sci. 21: 327-335, 1996.

41. Rosenzweig, A., T. D. Halazonetis, and C. E. Seidman. Proximal regulatory domains of atrial natriuretic factor gene. Circulation 84: 1256-1265, 1991[Abstract/Free Full Text].

42. Ruppert, S., E. H. Wang, and R. Tjian. Cloning and expression of human TAFII250: a TBP-associated factor implicated in cell-cycle regulation. Nature 362: 175-179, 1993[Medline].

43. Sadoshima, J., H. Aoki, and S. Izumo. Angiotensin II and serum differentially regulate expression of cyclins, activity of cyclin dependent kinases, and phosphorylation of retinoblastoma gene product in neonatal cardiac myocytes. Circ. Res. 80: 228-241, 1997[Abstract/Free Full Text].

44. Sauer, F., S. K. Hansen, and R. Tjian. Multiple TAFIIs directing synergistic activation of transcription. Science 270: 1783-1788, 1995[Abstract/Free Full Text].

45. Schecter, R. L., M. A. Alaoui-Jamali, A. Woo, W. E. Fahl, and G. Batist. Expression of rat glutathione-S-transferase complementary DNA in rat mammary carcinoma cells: impact upon alkylator-induced toxicity. Cancer Res. 53: 4900-4906, 1993[Abstract/Free Full Text].

46. Sekiguchi, T., T. Nakashima, T. Hayashida, A. Kuraoka, S. Hashimoto, N. Tsuchida, Y. Shibata, T. Hunter, and T. Nishimoto. Apoptosis is induced in BHK cells by the tsBN462/13 mutation in the CCG1/TAFII250 subunit of the TFIID basal transcription factor. Exp. Cell Res. 218: 490-498, 1995[Medline].

47. Sekiguchi, T., E. Noguchi, T. Hayashida, T. Nakashima, H. Toyoshima, T. Nishimoto, and T. Hunter. D-type cyclin expression is decreased and p21 and p27 CDK inhibitor expression is increased when tsBN462 CCG1/TAFII250 mutant cells arrest in G1 at the restrictive temperature. Genes Cells 1: 687-705, 1996[Abstract].

48. Shan, K., A. M. Lincoff, and J. B. Young. Anthracycline-induced cardiotoxicity. Ann. Intern. Med. 125: 47-58, 1996[Abstract/Free Full Text].

49. Shao, Z., and P. D. Robbins. Differential regulation of E2F and Sp1-mediated transcription by G1 cyclins. Oncogene 10: 221-228, 1995[Medline].

50. Shao, Z., J. L. Siegert, S. Ruppert, and P. D. Robbins. Rb interacts with TAFII250/TFIID through multiple domains. Oncogene 15: 385-392, 1997[Medline].

51. Soonpaa, M. H., G. Y. Koh, L. Pajak, S. Jing, M. T. Franklin, K. K. Kim, and L. J. Field. Cyclin D1 overexpression promoted cardiomyocyte DNA synthesis and multinucleation in transgenic mice. J. Clin. Invest. 99: 2644-2654, 1997[Medline].

52. Steinherz, L. G., P. G. Steinherz, and C. Tan. Cardiac failure and dysrhythmias 6-19 years after anthracycline therapy: a series of 15 patients. Med. Pediatr. Oncol. 24: 352-361, 1995[Medline].

53. Suzuki-Yagawa, Y., M. Guermah, and R. G. Roeder. The ts13 mutation in the TAFII250 subunit (CCG1) of TFIID directly affects transcription of D-type cyclin genes in cells arrested in G1 at the nonpermissive temperature. Mol. Cell. Biol. 17: 3284-3294, 1997[Abstract].

54. Tsai-Morris, C.-H., X. Cao, and V. P. Sukhatme. 5'Flanking sequence and genomic structure of Egr-1, a murine mitogen inducible zinc finger encoding gene. Nucleic Acids Res. 16: 8835-8842, 1988[Abstract/Free Full Text].

55. Uchimaru, K., T. Taniguchi, M. Yoshikawa, S. Asano, A. Arnold, T. Fujita, and T. Motokura. Detection of cyclin D1 (bcl-1, PRAD1) overexpression by a simple competitive reverse transcriptase-polymerase chain reaction assay in t(11:14)(q13:q32)-bearing B-cell malignancies and/or mantle cell lymphoma. Blood 89: 965-974, 1997[Abstract/Free Full Text].

56. Van Bilsen, M., and K. R. Chien. Growth and hypertrophy of the heart: towards an understanding of cardiac specific and inducible gene expression. Cardiovasc. Res. 27: 1140-1149, 1993[Medline].

57. Verrijzer, C. P., and R. Tjian. TAFs mediate transcriptional activation and promoter selectivity. Trends Biol. Sci. 21: 338-342, 1996.

58. Wang, E. H., and R. Tjian. Promoter-selective transcriptional defect in cell cycle mutant ts13 rescued by hTAFII250. Science 1263: 811-814, 1994.

59. Yamazaki, T., I. Komuro, and Y. Yazaki. Molecular mechanism of cardiac cellular hypertrophy by mechanical stress. J. Mol. Cell. Cardiol. 27: 133-140, 1995[Medline].

This article has been cited by other articles:

S. Heon, M. Bernier, N. Servant, S. Dostanic, C. Wang, G. M. Kirby, L. Alpert, and L. E. Chalifour
Dexrazoxane does not protect against doxorubicin-induced damage in young rats
Am J Physiol Heart Circ Physiol, July 11, 2003; 285(2): H499 - H506.
[Abstract] [Full Text] [PDF]