Transient treatment with cytokines appears to improve hematopoietic function in Fanconi anemia; however, the effectiveness or adverse effect of long-term treatment is not known. The mitomycin C–treatedFancc−/− mouse provides a valuable model to address long-term efficacy of such treatment.Fancc−/− mice injected with granulocyte colony-stimulating factor, erythropoietin, or both cytokines showed a delay in mitomycin C (MMC)–induced bone marrow (BM) failure compared to untreated mice. However, long-term cytokine exposure followed by MMC challenges did not protect mice from the reduction of peripheral blood counts or the number of early myeloid progenitors. These results suggest that cytokine treatment may be beneficial only in the short-term, while long-term treatment is not protective for BM aplasia.

Fanconi anemia (FA) is a severe bone marrow (BM) failure syndrome transmitted through autosomal recessive inheritance. Somatic cell fusion studies resulted in the classification of FA patients into 8 complementation groups, each corresponding to a separate gene defect.1 Of these disease genes, six have been cloned, although no molecular function has been definitively attributed to any of the gene products. The clinical manifestation of FA is defined by a progressive BM failure and, in the majority of cases, a multitude of congenital malformations.2 In addition, FA patients are at an increased risk of developing myelodysplasia, acute myeloid leukemia (AML), and solid tumors later in life.3 The long-term curative treatment of the hematologic manifestation of the disease is BM or peripheral blood stem cell transplantation using a sibling HLA-matched donor.4-6Alternatives to BM transplantation include the administration of androgens and hematopoietic growth factors such as granulocyte colony-stimulating factor (G-CSF) and erythropoietin (EPO),7-10 which may transiently improve peripheral blood counts. Because treatment of FA patients with cytokines have been done on small cohorts and measured short-term effects, the long-term efficacy of such treatment and its impact on the progression of FA to myelodysplasia and acute myeloid leukemia have not been determined. The FA group C knockout (Fancc−/−) mouse model provides a unique opportunity to assess the long-term effect of G-CSF and EPO treatment on mitomycin C (MMC)–induced BM failure. Our results show that G-CSF administration, alone or in combination with EPO, results in a delayed onset of MMC-induced BM failure in Fancc−/− mice, but that long-term therapy with both cytokines may increase the sensitivity ofFancc−/− mice to MMC.

Mice, MMC injections, and cytokine treatment

Mice, 5- to 6-month-old wild-type and Fancc knockout previously described,11 from a BALB/c genetic background were injected intraperitoneally with MMC (Roche Diagnostics, Laval, QC, Canada) at 0.3 mg/kg diluted in saline solution, a dose previously shown to induce progressive BM failure inFancc−/− mice.12 Control mice were injected with equivalent volumes of saline. Human recombinant G-CSF (Filgrastim; Amgen, Mississauga, ON, Canada) and EPO (Janssen-Ortho, Toronto, ON, Canada), were diluted in saline and administered subcutaneously 3 times a week at a dose of 5 μg per mouse (160 μg/kg) of G-CSF and 10 U per mouse (300 U/kg) of EPO. The animal experiments were approved by the Animal Care Committee of the Hospital for Sick Children, Toronto, ON, Canada.

Hematological analysis

Peripheral blood counts including erythrocytes (RBC) and leukocytes (WBC) were analyzed from heparinized blood collected from the mouse tail vein using an automated cell counter (Coulter Counter Z1, Coulter Electronics, Mississauga, ON, Canada) as previously described.12 For hematopoietic colony-forming cell (CFC) assay, BM cells were seeded in complete methylcellulose medium as previously described.12 Statistical analysis was performed using either the Student paired t test or a 1-way analysis of variance (ANOVA) statistical program.

Effect of cytokine treatment on MMC-induced BM failure inFancc−/−mice

Although Fancc−/− mice have only subtle defects in their peripheral hematopoietic system without spontaneous BM failure, they have a significant stem cell defect.13,14The mice are exquisitely sensitive to the DNA cross-linking agent MMC, which, when used in low doses, induces severe BM aplasia.12 Thus, the MMC-treatedFancc−/− mice are useful models that reflect the BM aplasia seen in FA patients. To determine if G-CSF therapy protects against BM aplasia in this model, we treatedFancc+/+ and Fancc−/−mice with weekly injections of 0.3 mg/kg MMC, a dose known to induce progressive BM failure in Fancc−/−mice,12 in combination with G-CSF, EPO, or G-CSF plus EPO. The survival, RBC and WBC counts were monitored weekly during the course of the experiment. Treatment with G-CSF, EPO, and the combination of cytokines significantly delayed the reduction of both RBC and WBC counts in MMC-treated Fancc−/−mice (Figure 1). However, cytokine treatment did not reverse BM aplasia, indicating that primitive stem cells were not affected by this treatment. Indeed, neither G-CSF nor EPO act on murine repopulating stem cells. MMC treatment had no effect on survival of Fancc+/+ mice and, as expected, cytokine administration increased both RBC and WBC counts in these control mice. As predicted from the peripheral blood cell counts, G-CSF and EPO increased the survival time ofFancc−/− mice by 1 week when compared with mice receiving MMC without cytokines (survival of 3 weeks). In addition, Fancc−/− mice receiving both cytokines survived twice as long as the controls receiving MMC without cytokines (6 weeks, Figure 1C). Histopathologic analysis showed BM aplasia in all Fancc−/− mice receiving MMC treatment; neither G-CSF and EPO alone nor a combination of both was able to prevent BM failure. Taken together, these results indicate that short-term administration of G-CSF and/or EPO significantly delays the onset of MMC-induced pancytopenia in the peripheral blood ofFancc−/− mice but does not reverse BM aplasia.

Fig. 1.

Red and white blood cell counts in

Fancc−/− andFancc+/+ mice treated with MMC and cytokines. RBC counts (A), WBC counts (B), and survival curves (C) of Fancc−/− and wild-type mice receiving either MMC alone (Fancc+/+, ■;Fancc−/−, ▪) or in combination with G-CSF (Fancc−/−, ♦), erythropoietin (Fancc−/−, *), or G-CSF with erythropoietin (Fancc+/+, ○;Fancc−/−, ●). Each point represents the mean ± SEM of 2 to 4 mice. The absence of SEM bars indicates that values were too low to appear in the graph. Significant differences between Fancc−/− without cytokines compared toFancc−/− treated with cytokines: *,P < .01; †, P < .05. RBC at week 1: EPO,P < .01; G-CSF and G-CSF + EPO,P < .05. RBC at week 2: G-CSF, P < .01; EPO and G-CSF + EPO, P < .05. WBC at week 1:P < .05. WBC at week 2: G-CSF + EPO,P < .01.

Fig. 1.

Red and white blood cell counts in

Fancc−/− andFancc+/+ mice treated with MMC and cytokines. RBC counts (A), WBC counts (B), and survival curves (C) of Fancc−/− and wild-type mice receiving either MMC alone (Fancc+/+, ■;Fancc−/−, ▪) or in combination with G-CSF (Fancc−/−, ♦), erythropoietin (Fancc−/−, *), or G-CSF with erythropoietin (Fancc+/+, ○;Fancc−/−, ●). Each point represents the mean ± SEM of 2 to 4 mice. The absence of SEM bars indicates that values were too low to appear in the graph. Significant differences between Fancc−/− without cytokines compared toFancc−/− treated with cytokines: *,P < .01; †, P < .05. RBC at week 1: EPO,P < .01; G-CSF and G-CSF + EPO,P < .05. RBC at week 2: G-CSF, P < .01; EPO and G-CSF + EPO, P < .05. WBC at week 1:P < .05. WBC at week 2: G-CSF + EPO,P < .01.

Close modal

Effect of long-term exposure to G-CSF and EPO on survival and peripheral blood counts of Fancc−/−mice

We established a long-term cytokine treatment model to determine if increased duration of cytokine treatment could trigger primitive cells into action. Moreover, this experimental design provokes a more subtle neutropenia than the study reported in Figure 1, more closely mimicking FA patients who undergo cytokine treatment in response to neutropenia. Fancc−/− mice were subjected to a single MMC injection to induce neutropenia and decrease BM cellularity, as previously shown.12 We started cytokine injections one week after the MMC treatment and monitored RBC and WBC counts weekly (Figure 2A,B). Mice receiving EPO with or without G-CSF showed an increase of their RBC after 3 weeks of treatment as opposed to mice receiving either G-CSF alone or no cytokines. The WBC count increased after 3 weeks of cytokine treatment above control values. After 18 weeks another dose of MMC was given. If the stem and progenitor cells had expanded or been stimulated by long-term cytokine action, we would expect the mice to survive this challenge. However, all cytokine-treatedFancc−/− mice showed a dramatic decrease in RBC counts following the MMC challenge as compared to untreated mice, whereas all mice, including cytokine-treated and untreated mice, showed a decrease in WBC counts. Mice receiving both G-CSF and EPO did not survive the MMC challenge, with 5 of 6 mice dying from pancytopenia within 1 week and the remaining mouse within 2 weeks of the challenge (Figure 2E). The surviving mice were killed 8 weeks after challenge to establish BM cultures and analyze their BM histopathology. A reduction of granulocyte macrophage colony-forming units (Figure 2D) was observed in all MMC-challenged mice regardless of cytokine administration, when compared to control animals not receiving MMC. The number of erythroid burst-forming units (Figure 2C) remained at subnormal level, in keeping with the RBC count in peripheral blood at that time.

Fig. 2.

Effect of long-term exposure to G-CSF on peripheral blood cell counts and BM colony formation.

(A) RBC and (B) WBC counts in Fancc−/− mice before and after one MMC injection prior to cytokine therapy (■, no cytokines; ⋄, G-CSF; ●, EPO; ▪, EPO + G-CSF). Mice were subjected to a MMC challenge after 18 weeks of cytokine treatment, and blood cell counts were monitored for the following 8 weeks, at which point the experiment was terminated and BFU-E (C) and CFU-GM (D) were analyzed. (E) Survival curves of Fancc−/− mice before (after 18 weeks of cytokine treatment) and following MMC challenge (■, no cytokines; ⋄, G-CSF; ●, EPO; ▪, EPO + G-CSF). Each point represents the mean ± SEM of 2 to 6 mice. The absence of SEM bars indicates that values were too low to appear in the graph. Significant differences compared to untreated controls: *,P < .05 evaluated by 1-way ANOVA.

Fig. 2.

Effect of long-term exposure to G-CSF on peripheral blood cell counts and BM colony formation.

(A) RBC and (B) WBC counts in Fancc−/− mice before and after one MMC injection prior to cytokine therapy (■, no cytokines; ⋄, G-CSF; ●, EPO; ▪, EPO + G-CSF). Mice were subjected to a MMC challenge after 18 weeks of cytokine treatment, and blood cell counts were monitored for the following 8 weeks, at which point the experiment was terminated and BFU-E (C) and CFU-GM (D) were analyzed. (E) Survival curves of Fancc−/− mice before (after 18 weeks of cytokine treatment) and following MMC challenge (■, no cytokines; ⋄, G-CSF; ●, EPO; ▪, EPO + G-CSF). Each point represents the mean ± SEM of 2 to 6 mice. The absence of SEM bars indicates that values were too low to appear in the graph. Significant differences compared to untreated controls: *,P < .05 evaluated by 1-way ANOVA.

Close modal

Throughout the experiment, we did not observe increased numbers of myeloid cells or the presence of leukemic blasts in the peripheral blood of Fancc−/− mice receiving G-CSF and/or EPO. However, it should be noted that Fancc−/−mice treated or not treated with MMC do not appear to have a significant risk of developing myelodysplastic syndrome and/or AML. Our results demonstrate that G-CSF and EPO alone or in combination are efficacious in transiently increasing peripheral blood counts in FA. Long-term administration of either G-CSF or EPO may be partially beneficial, although the administration of both cytokines does not prevent BM failure, suggesting an inability to act on the long-term repopulating stem cells, which are the primary defect inFancc mice. Indeed, there is a possibility that cytokine treatment may even accelerate BM hypoplasia. Conceivably, the long-term administration of these factors may result in a depletion of the stem cell compartment, which, as we have previously shown, contains a reduced number of long-term repopulating stem cells with impaired function and self-renewal capacity.13 14 

The authors thank Ms Lily Morikawa for tissue sectioning and Dr Colin McKerlie for histopathologic analysis of mouse tissues. M.B. holds the Lombard Insurance Chair in Pediatric Research at the Hospital for Sick Children and the University of Toronto.

Prepublished online as Blood First Edition Paper, April 30, 2002; DOI 10.1182/blood-2001-11-0007.

Supported by grants from the National Cancer Institute of Canada (NCIC) with funds from the Canadian Cancer Society (J.E.D., M.B.), the Canadian Institutes of Health Research (M.C., J.E.D., M.B.), the Canadian Genetic Diseases Network of the National Centers of Excellence (J.E.D.), the Blood Gene Therapy Program of the Hospital for Sick Children, a CIHR junior investigator award (M.C.), and a CIHR scientist award (J.E.D.).

The publication costs of this article were defrayed in part by page charge payment. Therefore, and solely to indicate this fact, this article is hereby marked “advertisement” in accordance with 18 U.S.C. section 1734.

1
Joenje
H
Patel
KJ
The emerging genetic and molecular basis of Fanconi anaemia.
Nat Rev Genet.
2
2001
446
457
2
Liu
JM
Fanconi's anemia.
Bone Marrow Failure Syndromes.
Young
NS
2000
47
68
WB Saunders
Philadelphia, PA
3
Alter
BP
Leukemia and preleukemia in Fanconi's anemia.
Cancer Genet Cytogenet.
58
1992
206
208
discussion 209.
4
Gluckman
E
Bone marrow transplantation in Fanconi's anemia.
Stem Cells.
11(suppl 2)
1993
180
183
5
Kohli-Kumar
M
Morris
C
DeLaat
C
et al
Bone marrow transplantation in Fanconi anemia using matched sibling donors.
Blood.
84
1994
2050
2054
6
Guardiola
P
Pasquini
R
Dokal
I
et al
Outcome of 69 allogeneic stem cell transplantations for Fanconi anemia using HLA-matched unrelated donors: a study on behalf of the European Group for Blood and Marrow Transplantation.
Blood.
95
2000
422
429
7
Kemahli
S
Canatan
D
Uysal
Z
Akar
N
Cin
S
Arcasoy
A
GM-CSF in the treatment of Fanconi's anaemia.
Br J Haematol.
87
1994
871
872
8
Guinan
EC
Lopez
KD
Huhn
RD
Felser
JM
Nathan
DG
Evaluation of granulocyte-macrophage colony-stimulating factor for treatment of pancytopenia in children with fanconi anemia.
J Pediatr.
124
1994
144
150
9
Rackoff
WR
Orazi
A
Robinson
CA
et al
Prolonged administration of granulocyte colony-stimulating factor (filgrastim) to patients with Fanconi anemia: a pilot study.
Blood.
88
1996
1588
1593
10
Scagni
P
Saracco
P
Timeus
F
et al
Use of recombinant granulocyte colony-stimulating factor in Fanconi's anemia.
Haematologica.
83
1998
432
437
11
Chen
M
Tomkins
DJ
Auerbach
W
et al
Inactivation of Fac in mice produces inducible chromosomal instability and reduced fertility reminiscent of Fanconi anaemia.
Nat Genet.
12
1996
448
451
12
Carreau
M
Gan
OI
Liu
L
et al
Bone marrow failure in the Fanconi anemia group C mouse model after DNA damage.
Blood.
91
1998
2737
2744
13
Carreau
M
Gan
OI
Liu
L
Doedens
M
Dick
JE
Buchwald
M
Hematopoietic compartment of Fanconi anemia group C null mice contains fewer lineage-negative CD34+ primitive hematopoietic cells and shows reduced reconstruction ability.
Exp Hematol.
27
1999
1667
1674
14
Haneline
LS
Gobbett
TA
Ramani
R
et al
Loss of FancC function results in decreased hematopoietic stem cell repopulating ability.
Blood.
94
1999
1
8

Author notes

Madeleine Carreau, Unité de génétique humaine et moléculaire, CHUQ-Hôpital St-François d'Assise, 10 rue de l'Espinay, Québec, QC, Canada G1L 3L5; e-mail: madeleine.carreau@crsfa.ulaval.ca.

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