RAR{gamma} is critical for maintaining a balance between hematopoietic stem cell self-renewal and differentiation

doi:10.1084/jem.20052105

Published online 8 May 2006 doi:10.1084/jem.20052105
Rockefeller University Press, 0022-1007 $8.00
JEM, Volume 203, Number 5, 1283-1293

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ARTICLE

RAR ${gamma}$ is critical for maintaining a balance between hematopoietic stem cell self-renewal and differentiation

Louise E. Purton¹, Sebastian Dworkin¹, Gemma Haines Olsen¹, Carl R. Walkley¹^,2, Stewart A. Fabb¹, Steven J. Collins³, and Pierre Chambon⁴

¹ Trescowthick Research Laboratories, Peter MacCallum Cancer Centre, East Melbourne, Victoria 3002, Australia
² Department of Medicine, University of Melbourne, Fitzroy, Victoria 3065, Australia
³ Human Biology Division, Fred Hutchinson Cancer Research Center, Seattle, WA 98109
⁴ Institut de Génétique et de Biologie Moléculaire et Cellulaire, Centre National de la Recherche Scientifique/Institut National de la Santé et de la Recherche Médicale/ULP/Collège de France, 67404 Illkirch Cedex, CU de Strasbourg, France

CORRESPONDENCE Louise E. Purton: lpurton{at}partners.org

Top
Abstract
RESULTS
DISCUSSION
MATERIALS AND METHODS
References

Hematopoietic stem cells (HSCs) sustain lifelong productionof all blood cell types through finely balanced divisions leadingto self-renewal and differentiation. Although several genesinfluencing HSC self-renewal have been identified, to date nogene has been described that, when activated, enhances HSC self-renewaland, when activated, promotes HSC differentiation. We observethat the retinoic acid receptor (RAR) ${gamma}$ is selectively expressedin primitive hematopoietic precursors and that the bone marrowof RAR ${gamma}$ knockout mice exhibit markedly reduced numbers of HSCsassociated with increased numbers of more mature progenitorcells compared with wild-type mice. In contrast, RAR ${alpha}$ is widelyexpressed in hematopoietic cells, but RAR ${alpha}$ knockout mice do notexhibit any HSC or progenitor abnormalities. Primitive hematopoieticprecursors overexpressing RAR ${alpha}$ differentiate predominantly togranulocytes in short-term culture, whereas those overexpressingRAR ${gamma}$ exhibit a much more undifferentiated phenotype. Furthermore,loss of RAR ${gamma}$ abrogated the potentiating effects of all-transretinoic acid on the maintenance of HSCs in ex vivo culture.Finally, pharmacological activation of RAR ${gamma}$ ex vivo promotesHSC self-renewal, as demonstrated by serial transplant studies.We conclude that the RARs have distinct roles in hematopoiesisand that RAR ${gamma}$ is a critical physiological and pharmacologicalregulator of the balance between HSC self-renewal and differentiation.

Abbreviations used: ATRA, all-trans retinoic acid; BMT, BM transplant;CFU-GEMM, CFU-granulocyte, erythrocyte, macrophage, megakaryocyte;CFU-S, CFU-spleen; CLP, common lymphoid progenitor; CMP, commonmyeloid progenitor; Hes1, hairy and enhancer of split 1; HSC,hematopoietic stem cell; LKS⁺, lineage-negative, c-kit–positive,Sca-1–positive cells; LKS^–, lineage-negative, c-kit–positive,Sca-1–negative cells; RAR, retinoic acid receptor; RU,repopulating unit.

Louise E. Purton's present address is Center for RegenerativeMedicine, Harvard Medical School, Harvard Stem Cell Institute,Massachusetts General Hospital, Boston, MA 02114.

Carl R. Walkley's present address is Pediatric Oncololgy andDepartment of Hematology-Oncology, Dana-Farber Cancer Instituteand Children's Hospital, Harvard Medical School, Boston, MA02115.

Organogenesis requires a balance between self-renewal and differentiationof the organ's stem cells. This is important not only for producingthe mature cells essential for its normal function but alsoto maintain a pool of multipotent stem cells in organs, especiallythose that undergo continual developmental processes duringan organism's lifespan.

Hematopoiesis requires a continuous production of progenitorsand mature blood cells from hematopoietic stem cells (HSCs)through differentiation processes. Simultaneously, maintenanceof the HSC pool occurs via cell fate decisions of self-renewal,apoptosis/senescence, or differentiation. Studies involvinggenetically modified HSCs such as overexpression of HOXB4 (1,2), Notch1 (3), and ß-catenin (4) in HSCs have providedevidence of genes that increase HSC self-renewal. Although eachof these genes increases HSC potential when artificially induced,their physiological roles in HSC homeostasis are unclear, asmice deficient for Hoxb4, ß-catenin, and Notch1 havebeen reported to have normal HSC content and function (5–7).Furthermore, to date, there has been a lack of studies describinggenes that are physiologically required for maintaining theHSC pool in vivo and that reciprocally regulate HSC fate inan activation state–dependent manner.

We have previously described a novel role for the vitamin Aderivative, all-trans retinoic acid (ATRA), in enhancing themaintenance of HSCs in ex vivo liquid suspension culture (8).ATRA activates the retinoic acid receptors (RARs), of whichthere are three subtypes: RAR ${alpha}$ , RARß, and RAR ${gamma}$ . In thesestudies, we sought to determine whether any of the RARs hada physiological role in the regulation of HSCs.

Here, we show that loss of RAR ${gamma}$ results in reduced numbers ofHSCs and increased numbers of more differentiated progenitorcells in the mutant mice. Furthermore, unlike wild-type HSCs,RAR ${gamma}$ null HSCs did not repopulate recipients after 14 d of exvivo culture with ATRA. In contrast, loss of the other RAR predominantlyexpressed in hematopoietic cells, RAR ${alpha}$ , did not result in anyhematopoietic defects in the mice and ATRA-treated RAR ${alpha}$ nullHSCs had comparable repopulating activity to wild-type HSCscultured with ATRA. Finally, treatment of cultures of highlyenriched populations of hematopoietic precursors/stem cellswith ATRA, the natural ligand for RAR ${gamma}$ , resulted in increasedNotch1 and Hoxb4 expression in these cells accompanied by enhancedHSC self-renewal, as shown by increased potential of ATRA-treatedHSCs to repopulate mice after serial transplantation. Theseresults, therefore, demonstrate that RAR ${gamma}$ is a critical regulatorof the balance between HSC self-renewal and differentiation;loss of RAR ${gamma}$ results in reduced numbers of HSCs as the resultof enhanced HSC differentiation, whereas RAR ${gamma}$ activation resultsin HSC self-renewal.

RESULTS

Top
Abstract
RESULTS
DISCUSSION
MATERIALS AND METHODS
References

RAR ${gamma}$ 1 and RAR ${alpha}$ have different effects on hematopoietic progenitor cells
RAR ${alpha}$ and RAR ${gamma}$ subtypes are most widely expressed in hematopoiesisand loss of both of these RARs results in early postnatal lethalityaccompanied by impaired granulopoiesis in vivo (9). To determinewhich of the RARs may have a role in regulating HSCs, expressionanalysis of the major isoforms of the three RAR subtypes wasperformed in the HSC-containing lineage-negative, c-kit–positive,Sca-1–positive (LKS⁺) cells and the lineage-negative,c-kit–positive, Sca-1–negative (LKS^–) cellpopulation, which does not contain HSCs (10) and differentiatesin response to ATRA treatment (11). RAR ${alpha}$ was expressed in bothLKS⁺ and LKS^– cells. In contrast, RARß2 andRAR ${gamma}$ 1 were expressed preferentially by LKS⁺ (Table S1, availableat http://www.jem.org/cgi/content/full/jem.20052105/DC1). RARßnull mice are essentially normal (12) in contrast with the RAR ${alpha}$ and RAR ${gamma}$ null mice, which have profound defects in multiple organs(13, 14). Therefore, we focused our attention on a role forRAR ${alpha}$ or RAR ${gamma}$ in the regulation of HSCs.

To further define the roles of RAR ${alpha}$ and RAR ${gamma}$ 1 in HSCs, we usedretroviral vector-mediated gene transduction to individuallyoverexpress RAR ${alpha}$ and RAR ${gamma}$ 1 (15) in 5-fluorouracil pretreated BMand monitored the proliferation and differentiation of the transducedcells during 4 wk of culture in cytokine-containing media (seesupplemental Materials and methods, available at http://www.jem.org/cgi/content/full/jem.20052105/DC1).48 h after the infection, the transduction efficiencies (GFP⁺cells) were 8.8% (control), 4.3% (RAR ${alpha}$ ), and 4.5% (RAR ${gamma}$ 1). Duringthe 4 wk of culture, cell viabilities of the GFP⁺ cells withineach culture were similar. Both the control and RAR ${alpha}$ -overexpressingcells proliferated well in culture, comprising >50% of thecells in the cultures at 4 wk (Fig. S1, A–C, availableat http://www.jem.org/cgi/content/full/jem.20052105/DC1). Atthis time point, the RAR ${alpha}$ -overexpressing cells predominantlyexpressed the granulocyte marker, Gr-1 (Fig. S1 D). In contrast,cells overexpressing RAR ${gamma}$ 1 proliferated slowly in culture (comprising<2% of the culture), did not express Gr-1, were negativefor all other lineage markers assessed, and expressed high levelsof Sca-1 (Fig. S1). Thus, there was a marked difference in theproliferation and differentiation of the RAR ${alpha}$ - vs. RAR ${gamma}$ 1-transducedcells, with the RAR ${alpha}$ -transduced cells exhibiting rapid proliferationand differentiation to granulocytes, whereas the RAR ${gamma}$ transducedcells exhibited much slower proliferation associated with amuch more immature phenotype.

RAR ${gamma}$ null BM cells have increased numbers of progenitors
To confirm that RAR ${alpha}$ and RAR ${gamma}$ have distinct roles in hematopoiesis,especially with respect to HSCs, we investigated the multipotentialprogenitor cell compartment of RAR ${alpha}$ and RAR ${gamma}$ +/+, +/–, and–/– single mutant mice. BM obtained from the RAR ${alpha}$ ^–/–and RAR ${alpha}$ ^+/– mice had equivalent numbers of immature mixedcolonies (CFU-granulocyte, erythrocyte, macrophage, megakaryocyte[GEMM]) and CFU-spleen (CFU-S) compared with RAR ${alpha}$ ^+/+ BM (Fig. 1, A and B ).In contrast, BM from RAR ${gamma}$ ^–/– mice had twofold increasedCFU-GEMM and threefold increased CFU-S compared with RAR ${gamma}$ ^+/+BM (Fig. 1, C and D; P < 0.05). Further investigation ofRAR ${gamma}$ ^–/– BM revealed that this was also accompaniedby significantly increased numbers of common myeloid progenitors(CMPs) and common lymphoid progenitors (CLPs) compared withRAR ${gamma}$ ^+/+ BM (Fig. 1, E and F; P < 0.05).

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Figure 1. BM cells derived from 8-wk-old mice deficient for RAR ${gamma}$ have increased numbers of progenitors. (A) Numbers of CFU-GEMM produced per femur from 8-wk-old RAR ${alpha}$ ^+/+, RAR ${alpha}$ ^+/–, and RAR ${alpha}$ ^–/– mice (n = 4). (B) CFU-S content per femur from 8-wk-old RAR ${alpha}$ ^+/+, RAR ${alpha}$ ^+/–, and RAR ${alpha}$ ^–/– mice (n = 4). (C) Numbers of CFU-GEMM produced per femur from 8-wk-old RAR ${gamma}$ ^+/+, RAR ${gamma}$ ^+/–, and RAR ${gamma}$ ^–/– mice (n = 4). *, P < 0.05 compared with RAR ${gamma}$ ^+/+ BM (paired Student's t test). (D) CFU-S content per femur from 8-wk-old RAR ${gamma}$ ^+/+, RAR ${gamma}$ ^+/–, and RAR ${gamma}$ ^–/– mice (n = 4). *, P < 0.05 compared with RAR ${gamma}$ ^+/+ BM; #, P < 0.05 compared with RAR ${gamma}$ ^+/– BM (paired Student's t test). (E) Numbers of CMP per femur from 8-wk-old RAR ${gamma}$ ^+/+ and RAR ${gamma}$ ^–/– mice (n = 3). *, P < 0.05 compared with RAR ${gamma}$ ^+/+ BM (paired Student's t test). (F) Numbers of CLP per femur from 8-wk-old RAR ${gamma}$ ^+/+ and RAR ${gamma}$ ^–/– mice (n = 3). *, P < 0.05 compared with RAR ${gamma}$ ^+/+ BM (paired Student's t test). Data are presented as means ± SEM.

RAR ${gamma}$ null BM cells contain markedly reduced numbers of HSCs
The increased numbers of CFU-GEMM, CFU-S, CMPs, and CLPs inthe RAR ${gamma}$ ^–/– BM may have resulted from increased numbersof HSCs, or alternatively from enhanced proliferation or differentiationof the HSCs into the more mature progenitor pool. Therefore,we performed limiting dilution assays (16) using BM from wild-type,RAR ${gamma}$ ^+/–, RAR ${gamma}$ ^–/–, and RAR ${alpha}$ ^–/– miceto compare the numbers of transplantable HSCs in these mice.Lethally irradiated (10 Gy) recipient mice (8–10 miceper cell dose) were injected with limiting numbers of donorcells together with 2 x 10⁵ competing cells, and the frequencyof HSCs estimated at 6 mo posttransplant using Poisson statistics(Fig. S2, available at http://www.jem.org/cgi/content/full/jem.20052105/DC1).Mice that had $≥$ 1% multilineage repopulating donor cells wereconsidered to be positive for donor cell reconstitution andthose that had <1% donor cells were considered to be negative.

The number of long-term repopulating HSCs per femur of eachgenotype is shown in Fig. 2 , derived from data given in Fig.S2. There was a 3.3-fold reduction in the number of HSCs perfemur in BM from RAR ${gamma}$ ^–/– mice compared with wild-typeBM (Fig. 2; P < 0.05). Furthermore, this profound decreaseoccurred in the very primitive, multilineage repopulating HSCs,as repopulation of the myeloid and lymphoid lineages was equallyaffected by loss of RAR ${gamma}$ (unpublished data). In marked contrast,there were similar numbers of long-term repopulating HSCs perfemur in BM from RAR ${alpha}$ ^–/– mice compared with wild-typeBM (Fig. 2).

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Figure 2. BM cells derived from 8-wk-old mice deficient for RAR ${gamma}$ have reduced numbers of HSCs. Number of HSCs per femur of 8-wk-old wild-type (+/+), RAR ${gamma}$ ^+/–, RAR ${gamma}$ ^–/–, and RAR ${alpha}$ ^–/– mice (n = 8–10). *, P < 0.05 compared with wild-type and RAR ${alpha}$ ^–/– BM; #, P < 0.05 compared with RAR ${gamma}$ ^+/– BM (paired Student's t test). Data are presented as means ± SEM.

The reduction in HSCs together with the increased numbers ofCFU-GEMM, CFU-S, CMPs, and CLPs in RAR ${gamma}$ ^–/– BM (Fig. 1,C–F) suggests that the loss of RAR ${gamma}$ in vivo likely resultsin enhanced differentiation of HSCs into more mature progenitorcompartments. Interestingly, the RAR ${gamma}$ ^+/– mice also showedsigns of haplo-insufficiency with respect to their HSC content,having twofold fewer HSCs per femur than wild-type mice (Fig. 2;P < 0.05) and twofold increased numbers of CFU-S (Fig. 1 D).In marked contrast, we did not detect an altered HSC contentin RAR ${alpha}$ ^–/– mice compared with their wild-type littermates(Fig. 2). Collectively, these data underscore the importanceof RAR ${gamma}$ in the maintenance of the HSC pool.

Enriched populations of RAR ${gamma}$ null HSCs have reduced long-term repopulating potential accompanied by increased production of progenitor cells
To further explore a potential role of RAR ${gamma}$ in regulating HSCs,we assessed the repopulating potential of a more enriched populationof RAR ${gamma}$ -deficient HSCs, the LKS⁺ cell population, which are theHSC-containing population used in our previous studies (8, 11).

The numbers of LKS⁺ cells in RAR ${gamma}$ ^–/– BM were significantlyelevated compared with that of RAR ${gamma}$ ^+/+ BM (Fig. 3 A , P <0.05). Interestingly and similar to the results obtained fromthe whole BM cell studies, the numbers of CFU-S formed per 500LKS⁺ cells were significantly increased from both RAR ${gamma}$ ^+/–and RAR ${gamma}$ ^–/– cells compared with that of RAR ${gamma}$ ^+/+ cells(Fig. 3 B, P < 0.05). It is known that LKS⁺ cells are heterogeneous;therefore, we further investigated the LKS⁺ cell compartmentof RAR ${gamma}$ wild-type and null mice by phenotypic analysis of theCD34 and Flt3 subsets within LKS⁺ cells, which discriminatebetween long-term HSCs (CD34^–Flt3^–), short-termHSCs (CD34⁺Flt3^–), and multipotent progenitors (CD34⁺Flt3⁺)(17). RAR ${gamma}$ ^–/– LKS⁺ cells had significantly reducedpercentages of CD34⁺Flt3⁺ cells, significantly increased contentof CD34⁺Flt3^–, and similar percentages of CD34^–Flt3^–compared with RAR ${gamma}$ ^+/+ LKS⁺ cells (Fig. 3 C).

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Figure 3. Properties of RAR ${gamma}$ mutant LKS⁺ cells. (A) Number of LKS⁺ cells per femur from 8-wk-old RAR ${gamma}$ ^+/+, RAR ${gamma}$ ^+/–, and RAR ${gamma}$ ^–/– mice (n = 7–12). *, P < 0.05 compared with RAR ${gamma}$ ^+/+ and RAR ${gamma}$ ^+/– LKS⁺ cells (paired Student's t test). (B) Number of CFU-S produced per 500 LKS⁺ cells (n = 4). *, P < 0.05 compared with RAR ${gamma}$ ^+/+ LKS⁺ cells; #, P < 0.05 compared with RAR ${gamma}$ ^+/– LKS⁺ cells (paired Student's t test). Data are presented as means ± SEM. (C) Percentages of CD34 and Flt3 populations in LKS⁺ cells obtained from 8-wk-old RAR ${gamma}$ ^+/+ and RAR ${gamma}$ ^–/– mice (n = 5). *, P < 0.05 compared with RAR ${gamma}$ ^+/+ LKS⁺ cells.

We further examined the functional capacity of LKS⁺ cells byperforming competitive repopulating assays with LKS⁺ cells obtainedfrom RAR ${gamma}$ ^+/+, RAR ${gamma}$ ^+/–, and RAR ${gamma}$ ^–/– mutants (8).The numbers of repopulating units (RU) were estimated as previouslydescribed for comparison of HSC potential across the genotypes(18).

All populations had similar RU at 5 wk after BM transplant (BMT)(Fig. 4 A ). Thereafter, there was a progressive decline inRU from RAR ${gamma}$ ^–/– LKS⁺ cells compared with RAR ${gamma}$ ^+/+ LKS⁺cells, resulting in a 2.5-fold reduction by 3 mo and a significant6.6-fold reduction by 6 mo (Fig. 4, B and C; P < 0.05). Hence,RAR ${gamma}$ ^–/– LKS⁺ cells had reduced long-term repopulatingpotential compared with RAR ${gamma}$ ^+/+ LKS⁺ cells, results that areconsistent with those obtained using unfractionated BM. Thefunctional potential of the RAR ${gamma}$ ^–/– LKS⁺ cells thereforedid not correlate with their CD34 phenotype, which is consistentwith reports by other investigators that CD34 subsets do notnecessarily provide an accurate measurement of HSC numbers inmutant mice or mice that are not in homeostatic conditions (19–22).In contrast, RAR ${alpha}$ ^–/– LKS⁺ cells did not have alteredrepopulating potential compared with wild-type LKS⁺ cells (Fig.S3, available at http://www.jem.org/cgi/content/full/jem.20052105/DC1).

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Figure 4. RAR ${gamma}$ ^–/– LKS⁺ cells from 8-wk-old mice have reduced long-term competitive repopulating potential accompanied by increased production of progenitor cells. (A–C) 1,000 LKS⁺ cells isolated from RAR ${gamma}$ ^+/+, RAR ${gamma}$ ^+/–, or RAR ${gamma}$ ^–/– BM were mixed with 10⁵ congenic BM cells and transplanted into each lethally irradiated congenic recipient (n = 8). Peripheral blood was analyzed at (A) 5 wk, (B) 3 mo, and (C) 6 mo after BMT for donor-derived multilineage repopulating cells. The numbers of RU in each population are depicted below their respective graphs. *, P < 0.05 compared with RAR ${gamma}$ ^+/+ LKS⁺ cells (paired Student's t test). Data are presented as means ± SEM. (D) Apoptosis and cell cycle properties of RAR ${gamma}$ mutant LKS⁺ cells (n = 3–5).

We further investigated properties of RAR ${gamma}$ ^+/+ and RAR ${gamma}$ ^–/–LKS⁺ cell populations to determine if altered survival or cellcycle properties could account for the reduced repopulatingactivity of the RAR ${gamma}$ ^–/– LKS⁺ cells. There were nodifferences in apoptosis, the percentages of cells in G₀/G₁or the proportion of G₀/G₁ LKS⁺ cells that were in G₀ in RAR ${gamma}$ ^–/–LKS⁺ cells compared with RAR ${gamma}$ ^+/+ LKS⁺ cells (Fig. 4 D). Hence,it did not appear that altered survival or cell cycle propertieswere contributing to the reduced long-term repopulating potentialof RAR ${gamma}$ ^–/– LKS⁺ cells.

BM obtained from 12-mo-old RAR ${gamma}$ null mice have reduced CFU-GEMM colony-forming cell potential
RAR ${gamma}$ ^–/– mice have been reported to exhibit earlylethality from unknown causes (14). In our care, a small numberof RAR ${gamma}$ ^–/– mice have survived to 12 mo of age, whichappears to be the maximum lifespan of these mutants. In theseolder mice, the PB and BM cellularities were slightly elevatedcompared with their wild-type age-matched littermates (Fig. 5, A and B ).The total CFC content was similar between all genotypes (Fig. 5 C).In contrast and opposite to that of 8-wk-old RAR ${gamma}$ ^–/–mice, the numbers of the immature CFU-GEMM were markedly reducedin RAR ${gamma}$ ^–/– BM compared with their wild-type littermates(Fig. 5 D; P < 0.05). The CFU-GEMM content, the oppositeof that of BM from 8-wk-old RAR ${gamma}$ null mice (Fig. 2 D), is alsoconsistent with enhanced differentiation and reduced self-renewalcapacity of RAR ${gamma}$ HSCs, which, as the HSCs exhaust over time,would likely result in reduced immature colony-forming cellpotential in the BM of ageing mice.

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Figure 5. Altered hematopoiesis in 12-mo-old mice deficient for RAR ${gamma}$ . (A) Peripheral blood cellularity of 12-mo-old mice (n = 3). (B) BM cellularity of 12-mo-old mice (n = 3). (A and B) WBC, white blood cells; RBC, red blood cells; PLT, platelets; HGB, hemoglobin; HCT, hematocrit. (C) Numbers of CFU-GEMM produced per femur from 12-mo-old RAR ${gamma}$ ^+/+, RAR ${gamma}$ ^+/–, and RAR ${gamma}$ ^–/– mice (n = 3). *, P < 0.05 compared with RAR ${gamma}$ ^+/+ BM (paired Student's t test). (D) Numbers of total colonies produced per femur from 12-mo-old RAR ${gamma}$ ^+/+, RAR ${gamma}$ ^+/–, and RAR ${gamma}$ ^–/– mice (n = 3). Data are presented as means ± SEM.

ATRA-induced enhancement/maintenance of HSCs in ex vivo cultures requires RAR ${gamma}$
We have previously shown that ATRA-treated LKS⁺ cells have enhancedlong-term repopulating activity after 14 d of culture comparedwith LKS⁺ cells cultured without ATRA (8). We wished to determineif RAR ${gamma}$ was the major RAR responsible for this maintenance ofHSCs in ATRA-treated ex vivo cultures and thus compared ATRA-treatedcultures of RAR ${gamma}$ ^+/+ and RAR ${gamma}$ ^–/– LKS⁺ cells.

Consistent with our previous studies, neither RAR ${gamma}$ ^+/+ nor RAR ${gamma}$ ^–/–LKS⁺ cells cultured without ATRA for 14 d displayed any competitiverepopulating potential (unpublished data). After 14 d of culture,ATRA-treated RAR ${gamma}$ ^+/+ LKS⁺ cells comprised an average of 14% ofperipheral blood cells in the transplanted mice, and these weremultilineage repopulating HSCs (Fig. 6 ). In contrast, ATRA-treatedRAR ${gamma}$ ^–/– LKS⁺ cells did not show any multilineagerepopulating potential after 14 d of culture (Fig. 6). Furthermore,RAR ${alpha}$ ^–/– LKS⁺ cells cultured for 14 d with ATRA hadsimilar competitive repopulating potential (average 18%) comparedwith ATRA-treated wild-type LKS⁺ cells (Fig. 6). These datashow that RAR ${gamma}$ , but not RAR ${alpha}$ , is essential for the maintenanceof HSCs in ATRA-treated ex vivo cultures.

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Figure 6. ATRA does not enhance the repopulating ability of RAR ${gamma}$ ^–/– LKS⁺ cells. Shown are the competitive repopulation ability of wild-type (+/+), RAR ${alpha}$ ^–/–, and RAR ${gamma}$ ^–/– LKS⁺ cells after 14 d of culture with ATRA. Data are expressed as the mean ± SEM donor cell multilineage reconstitution in the peripheral blood of transplanted recipients (n = 8) analyzed at 6 mo after BMT. *, P < 0.05 compared with wild-type and RAR ${alpha}$ ^–/– LKS⁺ cells (paired Student's t test).

RAR ${gamma}$ signaling impacts on Notch1 expression
The aforementioned observations suggest that loss of RAR ${gamma}$ resultsin an imbalance in HSC self-renewal decisions, resulting inincreased commitment/differentiation of HSCs into more matureprogenitor cells. To determine if loss of RAR ${gamma}$ altered the expressionof genes previously shown to influence HSC self-renewal, weinvestigated the expression of such genes in mRNA from freshlyisolated RAR ${gamma}$ ^+/+ and RAR ${gamma}$ ^–/– LKS⁺ cells. We choseto investigate the possible deregulation of three differentcandidate genes (p21^Cip1/Waf1, Notch1, and Hoxb4) based on boththeir known involvement in HSC self-renewal (3, 23, 24) andalso their previous links with retinoids in other settings (25–27).

Loss of RAR ${gamma}$ did not alter expression of either p21^Cip1/Waf1or Hoxb4 in LKS⁺ cells (Table I A ). In contrast, there wasa significant reduction in the expression of Notch1 in RAR ${gamma}$ ^–/–LKS⁺ cells (Table I A, P < 0.004), accompanied by reducedexpression of hairy and enhancer of split 1 (Hes1), a measureof activated Notch1 (28) in these cells (Table I A).

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Table I. Notch1 expression is altered by RAR ${gamma}$ signaling

To determine if activation of RAR ${gamma}$ altered the expression ofthese genes, we compared the expression of p21^Cip1/Waf1, Hoxb4,Notch1, and Hes1 in 3-d cultures of RAR ${gamma}$ ^+/+ LKS⁺ cells treatedfor 3 d with or without ATRA. There were no changes in the expressionof p21^Cip1/Waf1 in LKS⁺ cells cultured with or without ATRAfor 3 d (Table I B). In contrast, the expression of both Hoxb4and Notch1 were significantly up-regulated in ATRA-treated LKS⁺cells compared with LKS⁺ cells cultured without ATRA (Table I B,P < 0.001). Interestingly, despite the absence of exogenousNotch1 ligands in these cultures, expression of Hes1 was alsosignificantly increased in the 3-d ATRA-treated LKS⁺ cells comparedwith the LKS⁺ cells cultured without ATRA (Table I B, P <0.005).

We also compared the expression of these genes in cultures ofATRA-treated RAR ${gamma}$ ^+/+ and RAR ${gamma}$ ^–/– LKS⁺ cells. The expressionof p21^Cip1/Waf1 and Hoxb4 was similar for both populations.In contrast, both Notch1 and Hes1 were significantly down-regulatedin ATRA-treated RAR ${gamma}$ ^–/– LKS⁺ cells compared withRAR ${gamma}$ ^+/+ LKS⁺ cells (Table I C, P < 0.05). In marked contrast,studies using RAR ${alpha}$ ^–/– LKS⁺ cell populations showedthat Notch1 and Hes1 were not down-regulated in RAR ${alpha}$ ^–/–LKS⁺ cells (Table I C).

Finally, we examined the expression of Notch1 and Hes1 in 2-dcultures of immature BM cells transduced with RAR ${gamma}$ 1. Both Notch1and Hes1 were significantly up-regulated in RAR ${gamma}$ 1-overexpressingBM compared with those expressing the control vector (Table I D,P < 0.02). Interestingly, overexpression of RAR ${alpha}$ did increaseNotch1 expression compared with the control vector, but notto the magnitude of RAR ${gamma}$ 1 (Table I D, P < 0.05). Furthermore,Hes1 was not significantly increased in RAR ${alpha}$ -overexpressing BMcompared with the control vector (Table I D).

ATRA enhances the self-renewal of HSCs
Given that there was no difference in survival or cell cycleproperties of RAR ${gamma}$ ^–/– LKS⁺ cells (Fig. 4), whereasboth RAR ${gamma}$ null LKS⁺ cells and unfractionated BM populations hadincreased numbers of progenitors accompanied by reduced numbersof HSCs (Figs. 1–4 ), our data are consistent with RAR ${gamma}$ null HSCs undergoing reduced self-renewal and more differentiationdecisions. Furthermore, Notch1 and Hes1, a measure of activatedNotch1, which has previously been shown to enhance HSC self-renewal(3), were significantly reduced in RAR ${gamma}$ ^–/– LKS⁺ cellpopulations (Table I), further supporting that possibility.In addition, there was increased expression of two genes previouslyassociated with HSC self-renewal (Hoxb4 and Notch1) after 3d of culture of wild-type LKS⁺ cells with ATRA compared withLKS⁺ cells cultured without ATRA (Table I B). In this study(Fig. 6) and in a previous report, we have also shown that thereis retention of repopulating potential in wild-type LKS⁺ cellscultured with ATRA for 14 d compared with loss of repopulatingability in LKS⁺ cells cultured in the same conditions but withoutATRA (8). We now show that RAR ${gamma}$ is required for these effects(Fig. 6). Therefore, we wished to determine if ATRA was enhancingthe self-renewal of wild-type HSCs.

The HSC compartment has been shown to be heterogeneous, comprisedof a hierarchy of HSCs that can be identified by their functionalcapacity. The most immature HSC in this hierarchy is capableof sustaining hematopoiesis throughout serial transplantation(Fig. 7 A ) (29, 30). Therefore, to determine if ATRA enhancedself-renewal of these highly primitive, serially transplantableHSCs, we investigated the serial BMT potential of LKS⁺ cellscultured with or without ATRA for 3 d compared with nonculturedLKS⁺ cells using competitive repopulation assays.

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Figure 7. ATRA enhances the serial transplantability of cultured HSCs. (A) Experimental protocol for detecting the most primitive HSCs by serial transplantation. (B) The data show the increased serial transplantability of LKS⁺ cells after 3 d of culture with ATRA compared with noncultured LKS⁺ or LKS⁺ cells cultured without ATRA for 3 d. Data are expressed as the mean ± SEM donor cell reconstitution in the peripheral blood of transplanted recipients (six mice per group) analyzed at 6 mo (primary transplant) and 3 mo (subsequent serial transplants) after BMT. *, P < 0.05; #, P < 0.01 compared with noncultured LKS⁺ cells (paired Student's t test).

The long-term, multilineage, competitive repopulating HSC potential(6 mo after BMT) of 1,000 freshly isolated LKS⁺ cells or theircultured equivalents was first measured in primary lethallyirradiated recipients. BM cells from these mice were then pooledwithin treatment groups and injected into secondary lethallyirradiated recipients. The multi-lineage repopulating potentialof HSCs in secondary recipients and each subsequent serial transplantrecipient was measured at 3 mo after BMT, then BM from thesemice were pooled and injected into the next serial transplantrecipients.

The donor cell chimerism of HSCs cultured with or without ATRAfor 3 d increased relative to the control (noncultured) LKS⁺cells (% donor cell chimerism, mean ± SEM control: 59.7± 17, no ATRA: 74.91 ± 10.75, ATRA: 73.98 ±10.95, Fig. 7 B). Interestingly, in the secondary recipientsof the HSCs cultured without ATRA, the donor cell chimerismwas significantly reduced compared with the control, suggestingthat there was enhanced differentiation into more mature HSCswithin the HSC hierarchy. In contrast, the reconstituting abilityof the 3-d ATRA-treated LKS⁺ cells remained significantly higherin the secondary recipients compared with that of recipientsof control (noncultured) LKS⁺ cells, even during subsequenttransplantation (Fig. 7 B). Of note, all quaternary recipientsof the 3-d ATRA-treated LKS⁺ cells had significant multilineagedonor reconstituting ability, with donor repopulating levelsin quaternary BMT recipients of 20.1 ± 8.6% (Fig. 7 B).In marked contrast, no quaternary BMT recipient of nonculturedLKS⁺ cells or LKS⁺ cells cultured without ATRA for 3 d had detectabledonor cell reconstitution (Fig. 7 B). The strikingly increasedserial transplantability of the ATRA-treated LKS⁺ cells overthat of the noncultured LKS⁺ cells, which would have the highestserial transplant potential if self-renewal was not enhanced,indicated that pharmacological stimulation with ATRA enhancedthe self-renewal of HSCs in the 3 d ex vivo cultures.

DISCUSSION

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DISCUSSION
MATERIALS AND METHODS
References

In these studies, we show that the two major RARs expressedin hematopoietic cells, RAR ${alpha}$ and RAR ${gamma}$ , have distinct roles inthe regulation of immature progenitors and HSCs. We demonstratethat RAR ${gamma}$ ^–/– mice have increased numbers of committedhematopoietic progenitors (Fig. 1, C–F) and that thisis accompanied by significantly reduced numbers of long-termrepopulating HSCs (Figs. 2 and 4 C). These abnormalities arenot observed in RAR ${alpha}$ ^–/– mice (Fig. 2 and Fig. S3).The survival and cell cycle properties of enriched populationsof RAR ${gamma}$ ^–/– HSCs were not different to those of RAR ${gamma}$ ^+/+HSCs, suggesting that the impaired repopulating potential ofthe RAR ${gamma}$ ^–/– HSCs were not the result of altered apoptosisor cycling of these HSCs (Fig. 4 D). Furthermore, we show thatATRA enhances HSC self-renewal (Fig. 7 B) and that RAR ${gamma}$ , butnot RAR ${alpha}$ , is required for the potentiating effects of ATRA inextended ex vivo culture systems (Fig. 6).

These data collectively demonstrate that RAR ${gamma}$ is a key physiologicalregulator of HSCs. In RAR ${gamma}$ ^+/+ HSCs, there is a balance betweenHSC self-renewal and differentiation decisions. When treatedwith pharmacological levels of ATRA, the HSCs undergo more self-renewaldivisions (Fig. 7 B). In contrast, our observations that RAR ${gamma}$ ^–/–mice display increased numbers of committed progenitors (Fig. 1, C–F,and Fig. 3 B) and reduced numbers of long-term repopulatingHSCs (Figs. 2 and 4 C) suggests that the HSCs from RAR ${gamma}$ ^–/–mice display an imbalance between self-renewal and differentiation,favoring differentiation divisions. Furthermore, loss of RAR ${gamma}$ signaling results in the inability of the HSCs to maintain repopulatingability in response to ATRA treatment in ex vivo culture (Fig. 6).In addition, the haplo-insufficiency shown by RAR ${gamma}$ ^+/– HSCs,which had an intermediate phenotype between that of RAR ${gamma}$ ^–/–and RAR ${gamma}$ ^+/+ HSCs (Figs. 1–4 ), also underscores the importanceof RAR ${gamma}$ signaling in HSCs. These data demonstrate that RAR ${gamma}$ isa key regulator of HSC homeostasis, influencing the balancebetween self-renewal and differentiation decisions of the HSC.

In a previous investigation, Labrecque et al. reported thatRAR ${gamma}$ null mice do not have altered numbers of progenitor cells(9). The major difference between the previous study and oursis that they used fetal BM (18.5 dpc), whereas we used BM fromadult (8-wk-old) mice. In addition, in contrast with the increasednumbers of progenitors in 8-wk-old mice, we observed significantlyreduced numbers of progenitors in 12-mo-old RAR ${gamma}$ null mice. Thesecontrasting data therefore demonstrate that the age of the micestudied can also be crucial to the results obtained as can thesubsequent interpretation of that data, when investigating hematopoieticdefects such as that observed in RAR ${gamma}$ ^–/– mice.

The effects of RAR ${gamma}$ were specific to this RAR, as RAR ${alpha}$ null micedid not display any HSC defects (Fig. 2), and RAR ${alpha}$ null HSCsretained their ability to self-renew in ex vivo culture in responseto ATRA treatment (Fig. 6). RARß2 was not apparentlyimportant to the HSC defect observed in RAR ${gamma}$ ^–/– miceas it was expressed at equal levels in both RAR ${gamma}$ ^+/+ and RAR ${gamma}$ ^–/–LKS⁺ cells (unpublished data). Collectively, these data highlightthe importance and nonredundant role of RAR ${gamma}$ in mediating theHSC self-renewing effects induced by ATRA treatment.

In hematopoiesis, ATRA is predominantly known as a differentiatingagent, potently inducing the terminal granulocytic maturationof primary leukemia cells from patients with acute promyelocyticleukemia (31–33). We have also shown that, in contrastwith its potentiating effects on HSC self-renewal, ATRA alsohas potent effects in enhancing normal primary granulocyte differentiationin vitro (11). RAR ${alpha}$ appears to be the most potent of the threereceptors in inducing these effects, as shown by its geneticinvolvement in acute promyelocytic leukemia (34), and it hasthe most dramatic effects on neutrophil differentiation fromboth maturing committed granulocyte progenitors and more immatureprogenitors (35, 36).

In the current study, we have confirmed the predominant roleof RAR ${alpha}$ in granulopoiesis, as RAR ${alpha}$ -overexpressing BM cells rapidlydifferentiated down the granulocytic pathway compared with boththe control and RAR ${gamma}$ 1-overexpressing cells (Fig. S1). However,despite these profound effects of RAR ${alpha}$ in enhancing primitivecell differentiation down the granulocyte lineage, RAR ${alpha}$ doesnot appear to have a role in regulating HSCs, as we did notobserve any defects in the numbers of primitive progenitorsor HSCs in RAR ${alpha}$ null mice.

It was of interest to determine whether RAR ${gamma}$ signaling affectedother genes known to induce HSC self-renewal (3, 23, 24). Despitehaving previously been reported to have an retinoic acid responseelement in its promoter region (37), expression of the cyclin-dependentkinase inhibitor p21^Cip1/Waf1 was not altered by ATRA treatment(Table I B), nor was it deregulated in RAR ${gamma}$ ^–/– LKS⁺cells (Table I, A and C). We have also previously shown thatp27^Kip1, which has roles in HSC homeostasis (38, 39), is inpart required for RAR ${alpha}$ -, but not RAR ${gamma}$ -, mediated responses (36);therefore p27^Kip1 is also unlikely to be involved in RAR ${gamma}$ -inducedHSC self-renewal.

The expression of Hoxb4 was markedly up-regulated in ATRA-treatedLKS⁺ cells (Table I B), consistent with previous studies showingthat retinoids regulate Hox gene expression in other organs(40). Despite this increase, however, there were no differencesin Hoxb4 expression between the RAR ${gamma}$ ^–/– and RAR ${gamma}$ ^+/+LKS⁺ cells (Table I, A and C); hence, Hoxb4 is not likely atarget gene of RAR ${gamma}$ .

In contrast with Hoxb4 and p21^Cip1/Waf1, Notch1 expression wasmarkedly increased in both ATRA-treated RAR ${gamma}$ ^+/+ LKS⁺ cells (Table I B)and RAR ${gamma}$ 1-overexpressing BM cells (Table I D) and significantlydecreased in RAR ${gamma}$ ^–/– LKS⁺ cells compared with wild-typeLKS⁺ cells (Table I, A and C). This was accompanied by similarlyaltered levels of expression of Hes1, a measure of Notch-mediatedsignaling, in these populations (Table I). In contrast, Notch1and Hes1 were not significantly down-regulated in RAR ${alpha}$ ^–/–LKS⁺ cells (Table I).

Of interest, it has recently been shown that Notch signalingis down-regulated as HSCs differentiate (41). Given both ourobservations of the reduced self-renewal/enhanced differentiationof RAR ${gamma}$ ^–/– HSCs and the reduced expression of Notch1in RAR ${gamma}$ ^–/– LKS⁺ cells, it is possible that alteredNotch1 signaling was contributing to the HSC defects observedin RAR ${gamma}$ null mice. Likewise, it is possible that increased signalingof Notch1 was contributing to the enhanced HSC self-renewalobserved in ATRA-treated cultures of wild-type HSCs (Fig. 7 B).However, unlike RAR ${gamma}$ null mice, Notch1 knockout mice do not havean HSC defect (7); hence, altered Notch1 is unlikely to be themain contributing factor to the HSC defects observed in RAR ${gamma}$ null mice.

Of therapeutic relevance is that HSCs were induced to self-renewin simple ex vivo cultures using pharmacological levels of ATRA,which is approved for use. Interestingly, a recent report demonstratedthe potential beneficial use of ATRA for the expansion of humanHSCs (42). Our studies demonstrating the different roles ofthe RARs and especially the critical role for RAR ${gamma}$ in regulatingHSCs now suggest that specifically targeting RAR ${gamma}$ could furtherimprove on the ATRA-mediated ex vivo expansion of HSCs. Additionalstudies are therefore warranted to further investigate the effectsof RAR-specific ligands in enhancing the expansion of HSCs fortherapeutic purposes.

MATERIALS AND METHODS

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DISCUSSION
MATERIALS AND METHODS
References

Mice.
For serial transplant studies, donor mice were C57BL/6J (CD45.2⁺)and recipient mice were B6.SJL-Ptprc^aPep3^b/BoyJ (herein referredto as Ptprca; CD45.1⁺), both were obtained from Animal ResourcesCentre, Perth, WA, Australia. RAR ${alpha}$ (13) and RAR ${gamma}$ (14) mutant micewere backcrossed 10 generations onto the C57BL/6J backgroundfor these studies. Except when otherwise described, all micewere used between 8 and 10 wk of age. All experiments performedwere approved by the Peter MacCallum Cancer Centre animal experimentationethics committee and were conducted in strict compliance tothe regulatory standards of the Australian Code of Practicefor the Care and Use of Animals for Scientific Purposes.

Quantitation of progenitor cell content in RAR mutant mice.
The number of CFU-GEMM per 5 x 10⁴ BM cells and CFU-S from 5x 10⁵ BM and 500 LKS⁺ cells were measured as described previously(11). The numbers of BM CMP and CLP were measured as describedpreviously (38, 43, 44).

Limiting dilution assay.
The frequency of HSCs in whole BM obtained from RAR ${gamma}$ +/+, +/–,or –/– mice was determined by Poisson statisticsusing the limiting dilution assay described previously (16).Recipient mice were lethally irradiated with a total dose of10 Gy, given in two equal fractions 3 h apart, and deliveredby two opposing ¹³⁷Cs sources (Gammacell 40, Atomic Energy ofCanada) on the day of transplant. Recipient CD45.1⁺ mice (8–10mice per group) were injected with 10⁴, 5 x 10⁴, 2 x 10⁵ or2 x 10⁶ BM cells obtained from the CD45.2⁺ RAR ${gamma}$ mice togetherwith 2 x 10⁵ Ptprca/C57BL/6J (CD45.2⁺/CD45.1⁺) congenic BM.Mice were assessed for CD45.2⁺/CD45.1^– donor cell peripheralblood reconstitution in lymphoid and myeloid lineages at 6 moposttransplant as described previously (8, 38).

LKS⁺ cell culture and transplantation studies.
LKS⁺ cells and LKS^– cells were isolated and cultured inIscove's modified essential medium containing 20% FBS, 100 ng/mlof each recombinant mouse (rm) SCF, recombinant human (rh) IL-6,rhFlt-3L, and 10 ng/ml rhIL-11 (Peprotech, Inc.) as describedpreviously (11). Cultures were supplemented with or without1 µM ATRA (Sigma-Aldrich).

Primary competitive repopulating potential of RAR ${gamma}$ mutant LKS⁺cells was performed as described previously (8). The numbersof RU were assessed according to the method of Harrison et al.(18). In brief, donor RU = % donor x competitor RU/(100 –% donor), where competitor RU = number of competing BM (x10⁵),in this situation = 1.

Primary competitive repopulating transplants of nonculturedand 3-d cultured LKS⁺ cells were performed as described previously(8). Donor mice were C57BL/6J (CD45.2⁺), and recipient micewere Ptprca (CD45.1⁺), both obtained from Animal Resources Centre.Multilineage peripheral blood cell reconstitution by CD45.2⁺donor cells was monitored at 6 mo posttransplant.

For serial transplant studies, the primary recipient mice werekilled at 7 mo posttransplant and the contents of their femurswere pooled within the respective groups. Irradiated secondaryPtprca recipients received BM cells equivalent to one thirdof the femoral contents of the primary recipients. Donor (CD45.2⁺)cell reconstitution was assessed at 3 mo posttransplant forthe secondary and subsequent recipients, then these recipientswere killed and the contents equivalent to one tenth of a femoralcontent were injected into new lethally irradiated Ptprca recipients.

Additional properties of LKS⁺ cells obtained from RAR ${gamma}$ null mice.
Apoptosis was measured in LKS⁺ cells by the annexin V–FITCapoptosis detection kit (Becton Dickinson), according to themanufacturer's instructions. Cell cycle analysis of LKS⁺ cellpopulations was performed as described previously (38). Theproportions of CD34 and Flt3 populations in LKS⁺ cells weremeasured as described previously (17).

RNA extraction and quantitative RT-PCR.
Extraction of mRNA and synthesis of cDNA were performed as describedpreviously (45). All reactions were conducted using an ABI Prism7000 Sequence Detection System (Applied Biosystems). 8 µlcDNA (1:10 dilution) was combined with 10 µl SyBr greenPCR Master Mix (Applied Biosystems) and 200 nm each of senseand antisense oligonucleotides (Geneworks). PCR conditions wereas follows: 50°C for 2 min and 95°C for 10 min, followedby 45 cycles at 95°C for 15 s and 60°C for 1 min. Expressionof all genes were compared with ß₂-microglobulin todetermine relative levels of mRNA transcripts. All primers usedin these studies are given in Table S2 (available at http://www.jem.org/cgi/content/full/jem.20052105/DC1).

Statistics.
The results are expressed as the mean ± SEM for n givensamples. Data were analyzed using the paired two-tailed Student'st test, with any p-value $≤$ 0.05 being considered significant.

Online supplemental material.
Fig. S1 shows the effects of overexpression of RAR ${alpha}$ or RAR ${gamma}$ 1 onprimitive BM cells; Fig. S2 shows the limiting dilution graphsfor calculation of HSC numbers in RAR ${gamma}$ mutants; and Fig. S3 showsthe repopulating potential of RAR ${alpha}$ ^–/– and RAR ${alpha}$ ^+/+LKS⁺ cell populations. Table S1 shows the expression of RARsin LKS⁺ and LKS^– cell populations. Table S2 provides real-timeprimer sequences used in these studies. Online supplementalmaterial, including supplemental Materials and methods, is availableat http://www.jem.org/cgi/content/full/jem.20052105/DC1.

Acknowledgments

We thank J. Fero for assistance with generating the cDNA-containingretroviral vectors, Peter MacCallum Cancer Centre (PMCC) AnimalFacility Staff for care of experimental mice, and PMCC FACSStaff for assistance with FACS sorting. We also thank G. McArthur,D. Scadden, I. Bertoncello, E. Sitnicka, X. Shen, and K. Orfordfor comments on the manuscript and useful suggestions.

This work was supported by grants from the Cancer Council ofVictoria (to L.E. Purton), the National Health and Medical ResearchCouncil (to L.E. Purton), and the National Institutes of Health(to S.J. Collins). C.R. Walkley was a recipient of an AustralianPostgraduate Award and L.E. Purton was a Special Fellow of theLeukemia and Lymphoma Society.

The authors have no conflicting interests.

Submitted: 19 October 2005
Accepted: 28 March 2006

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