Maintenance of hemopoiesis in long-term bone marrow cultures from S1/S1d and W/Wv mice

Although phenotypically similar, the cellular defects in congenitally anemic mice of genotype W/Wv and S1/S1d are quite different. W/Wv mice have defective hemopoietic stem cells; in contrast, S1/S1d mice have normal stem cells, but their hemopoietic microenvironment cannot support normal differentiation of the stem cells. We also observed defective hemopoiesis as measured by granulocyte-macrophage colony-forming units (GM-CFU) in long-term bone marrow cultures (LTBMC) established with marrow from these mutants, but in contrast to an earlier report we obtained long-term maintenance of hemopoiesis (up to 20 weeks) albeit at a lower level than the control (28% of control for S1/S1d and 23% for W/Wv). These levels probably reflect more accurately the in vivo effects of the mutations than the severe defect reported previously. However, this level of hemopoiesis and the high variability observed in replicate flasks in LTBMC make it difficult to study these mutants in tissue culture.     

Failure of W/Wv mouse-derived cultured mast cells to enter S phase upon contact with NIH/3T3 fibroblasts

Although W/Wv mutant mice are profoundly deficient in tissue mast cells, these mice do have cells with similar features of mast cells that develop from their bone marrow cells as efficiently as those from congenic +/+ mice in pokeweed mitogen-stimulated spleen cell- conditioned medium (PWM-SCM). With cultured mast cells (CMCs), we analyzed the mechanism of mast-cell deficiency in tissues of W/Wv mice. CMCs were established from bone marrow cells of W/Wv and congenic +/+ mice with PWM-SCM, and then co-cultured with various mouse fibroblast cell lines without PWM-SCM. All the examined mouse embryo-derived fibroblast cell lines maintained CMCs derived from +/+ mice, but not CMCs from W/Wv mice, for greater than 2 weeks. Mast cells in S phase were observed only in CMCs derived from +/+ mice under these conditions. The poor survival of W/Wv CMCs as compared with +/+ CMCs was not owing to a differential death rate but to the inability of W/Wv CMCs to continue active proliferation on fibroblasts without PWM-SCM. By synchronizing CMCs at the G1 phase of the cell cycle, the defect in W/Wv CMCs was further characterized as a failure to transit G1 and enter the S phase upon contact with fibroblasts. This finding indicates the indispensable function of the W gene product(s) for this response.     

Fetal hemopoiesis in diffusion chamber cultures. III. The effect of neutropenia.

Proliferation and differentiation of granulocytes, macrophages, and both myeloid committed (CFC) and pluripotent (CFU) stem cells in diffusion chamber (DC) cultures of fetal liver were studied in order to evaluate the role of circulating humoral factors in the control of fetal myelopoiesis. When DC with fetal liver cells were implanted into mice rendered neutropenic by pretreatment with cyclophosphamide, more granulocytes and CFC were produced through day 10 as compared to DC implanted into saline pretreated control hosts. A difference in CFU recovery from fetal liver suspensions grown in DC implanted into neutropenic and control hosts was not seen until day 10. Serum CSF concentrations were increased in neutropenic as compared to control host mice 2 and 3 days after implantation of DC. Levels of serum inhibitors of colony growth showed marked variability but, in general, were similar in both groups. These data provide evidence that fetal CFC and fetal myelopoiesis are influenced by a circulating humoral factor present in neutropenic serum. CSF may be the factor, although the data presented in this paper do not establish this with any certainty.     

The Effect of Neutropenia on Myeloid Growth and the Stem Cell in an In Vivo Culture System

An in vivo diffusion chamber (DC)culture technique was used to evaluate the role of circulating humoral factors in the control of myelopoiesis.Normal mouse bone marrow cell suspensions sealed in DC’s were implanted intraperitoneally into mice orrats rendered neutropenic by pretreatment with cyclophosphamide, and thegrowth of cells in the DC’s was evaluated at intervals thereafter. When marrow was cultured in hosts with gradedneutropenia, a dose-related augmentation of myelopoiesis was demonstrated. The growth of macrophagesand of pluripotent stem cells,measured by the spleen colony-forming technique, was also enhanced byculture in neutropenic hosts. Thesedata provide further evidence that therate of myelopoiesis is influenced bya circulating humoral factor. Theyfurther suggest that a humoral or hormonal factor is important in controlof the pluripotent stem cell population.

Submitted on March 30, 1972 Revised on May 27, 1972 Accepted on June 2, 1972     

Effects of recombinant human erythropoietin on anaemic W/Wv and SI/SId mice

The effects of recombinant human erythropoietin (rHuEPO) on anaemic W/Wv and Sl/Sld mice were investigated. rHuEPO was injected every day for a week in doses up to 86,000 iu/kg. Wv/+ and Sld+ mice, which have genetically a weak anaemia, received 17 or 86 iu/kg of rHuEPO and showed dose-dependent increases in haemoglobin, PCV, RBC and reticulocytes to the same extent as that in normal mice. W/Wv mice also showed increases in the haematological parameters in response to 8600 iu/kg of rHuEPO but the dose was much higher than that for normal mice. A reticulocyte increase in W/Wv mice appeared later than in normal mice and was not sustained for 2 weeks even though the rHuEPO treatment was continued. Sl/Sld mice, however, did not show any significant haematological effect from doses up to 86,000 iu/kg. In both W/Wv and Sl/Sld mice receiving 8600 and 86,000 iu/kg of rHuEPO, respectively, an increase in splenic or bone marrow CFU-E was observed regardless of the defect in their haemopoietic systems. The plasma erythropoietin (EPO) level in W/Wv and Sl/Sld mice was inversely correlated with the haemoglobin, indicating that EPO production was not influenced by the haemopoietic defect and was regulated by the hypoxic properties of the anaemia. These results indicate that a large dose of exogenous rHuEPO is effective for the anaemia in W/Wv mice caused by a stem cell defect but not for the anaemia in Sl/Sld mice caused by a defective microenvironment.     

Hematopoietic stem cell function in motheaten mice

Mice homozygous for the autosomal recessive mutation "motheaten" have normal numbers of multipotential hematopoietic stem cells in the bone marrow and spleen as determined by spleen colony assay. Histologic examination shows no qualitative abnormality in morphology of stem cell colonies in recipients of bone marrow or spleen cells from motheaten mice. Despite the apparently normal ontogeny, distribution, and differentiative capacity of CFU stem cells, bone marrow and spleen cells from motheaten mice fail to save congenic +/+ lethally gamma-irradiated hosts. This impaired lifesparing capacity is not due to defective self-renewal but appears to be due in part to pulmonary hemorrhage from alveolar capillaries in the gamma-irradiated hosts. Treatment of motheaten mice with 500 R gamma-irradiation followed by reconstitution with normal bone marrow cells increases the lifespan of this mutant to 10 months of age. The early onset of pneumonitis and subsequent short lifespan of motheaten mice is determined at the level of progenitor cells in the bone marrow.     

Regulation of hematopoiesis: helper and suppressor influences of the thymus

Thymocytes from normal mice strains as well as from genetically determined stem cell defective W/Wv anemic mice were cocultured with syngeneic (or congeneic) bone marrow cells. We assayed these cocultures for the proliferation of erythroid progenitor cell types (BFU-E and CFU- E) using the plasma clot technique. Results indicate that when concentrations of thymocytes were lower than bone marrow cells, significant suppression of erythroid growth was observed. However, when the concentration of thymocytes exceeded that of the bone marrow cells in culture (greater than 1:1), significant enhancement of erythroid growth was demonstrated. The W/Wv anemic bone marrow appears to respond to this interaction by enhancement at all concentrations of added normal thymocytes. The regulatory functions observed can be diminished by treatment of the thymocytes in vitro with anti-theta serum plus complement. Thus, we establish regulatory functions for anti-theta- sensitive regulatory cells (TSRC) with both positive (enhancement) and negative (suppression) components.     

"Stem cell" origin of the hematopoietic defect in dyskeratosis congenita

We have used the long-term bone marrow culture (LTBMC) system to analyze hematopoiesis in three patients with dyskeratosis congenita (DC), two of whom had aplastic anemia, and the third had a normal blood count (apart from mild macrocytosis) and normal BM cellularity. Hematopoiesis was severely defective in all three patients, as measured by a low incidence of colony-forming cells and a low level of hematopoiesis in LTBMC. The function of the marrow stroma was normal in its ability to support the growth of hematopoietic progenitors from normal marrows seeded onto them in all three cases, but the generation of hematopoietic progenitors from patients marrow cells inoculated onto normal stromas was reduced, thus suggesting the defect to be of stem cell origin. The parents and unaffected brother of one of the families have also been studied in LTBMC and all showed normal hematopoietic and stromal cell function. From this study we speculate that there are some similarities between DC and the defect in the W/Wv mouse.     

In vivo expansion of purified hematopoietic stem cells transplanted in nonablated W/Wv mice

We have evaluated the in vivo amplification potential of purified murine hematopoietic stem cells, identified as Wheat Germ Agglutinin+ (WGA+), 15-1.1(-) , Rhodamine 123 Dull (Rho-dull) cells, by serial transplantation into stem cell defective nonmyeloablated W/Wv mice. C57BL Rho-dull cells (250/ 500 cells/mouse) permanently engrafted nonablated W/Wv mice as defined by the presence of > 95% red and > 20% white donor-derived circulating cells for at least 1.5 years following transplantation. At this time, approximately 61% of Rho-dull cells and all the Rho-bright progenitor and colony forming cells of the engrafted mice were found to be donor-derived by c-Kit genotyping and by their response to stem cell factor (SCF). Retransplantation of 250-1000 Rho-dull cells from primary into secondary W/Wv recipients generated C57BL hematopoiesis in 40%-64% of animals revealing the presence of donor derived hematopoietic stem cells (HSC) in the bone marrow of the primary recipients. One and half years after transplantation, the bone marrow of the secondary engrafted animals contained C57BL Rho-dull cells approximately = 51% by genotype), which were capable of reconstituting tertiary W/Wv recipients. In this respect, 25% of tertiary mice expressed C57BL hematopoiesis when transplanted with 250-1000 Rhodull cells purified from secondary W/Wv recipients. On the basis of the number of Rho-dull cells purified from a single mouse, we calculate that approximately 7.3x10(4) Rho-dull cells, which are genotypically and functionally defined as C57BL long-term repopulating stem cells, were generated in the marrow of reconstituted primary W/Wv recipients transplanted 1.5 years earlier with 250-500 C57BL Rho-dull cells. We conclude that murine HSC have extensive amplification capacity in nonmyeloablated animals.     

Megakaryocytopoiesis and granulopoiesis of W/Wv mice studied in long- term bone marrow cultures

Megakaryocytopoiesis and granulopoiesis of marrow cells from W/Wv mice were studied using a continuous liquid marrow culture system. Cells in the suspension phase were assayed weekly over a 16-week period for total nucleated cells, megakaryocytes, granulocytes, megakaryocytes and granulocyte-macrophage progenitor cells (CFU-Ms, CFU-GMs), and spleen colony-forming cells (CFU-Ss). Without hydrocortisone supplementation, proliferation of megakaryocytes, granulocytes, and their progenitor cells was significantly less in W/Wv cultures than in +/+ cultures. These cells became undetectable in both W/Wv and +/+ cultures at seven to 11 weeks in culture, after which only monocytes and macrophages proliferated in the cultures. Treatment of cultures with hydrocortisone improved megakaryocytopoiesis and granulopoiesis in both W/Wv and +/+ cultures. Following an initial lag phase of three to four weeks, proliferation of megakaryocytes, granulocytes, and their progenitor cells in W/Wv cultures equalled that observed in +/+ cultures and was sustained for 16 to 24 weeks. This improvement was associated with a sustained reduction in monocytes and macrophages. Despite improvements in megakaryocytopoiesis and granulopoiesis, production of macroscopic and microscopic spleen colonies by cells from W/Wv cultures remained severely reduced or absent. Studies of DNA synthesis rates of fresh marrow cells indicated that significantly fewer CFU-Ms and CFU-GMs were in cycle in W/Wv mice compared with +/+ mice. However, in hydrocortisone-treated W/Wv cultures, DNA synthesis rates of CFU-Ms and CFU-GMs increased markedly and equalled those observed for +/+ cultures. These results suggest that the improvements in megakaryocytopoiesis and granulopoiesis in hydrocortisone-treated liquid cultures is associated with a reduction in monocytes and macrophages and that progenitor cells of W/Wv mice have a proliferative defect that is correctable by hydrocortisone treatment in vitro.     

Leucopoiesis versus concentration of cytokines in diffusion chamber cultures of mouse bone marrow cells: clues to the physiological roles of growth factors

Physiological mechanisms that regulate formation of neutrophil granulocytes, macrophages and their precursor cells were studied with the diffusion chamber (DC) technique. DC inoculated with mouse bone marrow cells were implanted intraperitoneally into host mice. When these in vivo cultures had been established and their marrow populations were expanding (2-day cultures), the DC were transferred to different environments: new, normal mice, lethally irradiated mice, or incubation flasks with optimal concentrations of growth factors. Culture development during the following final culture period was correlated to the concentration of some select candidate growth regulators in DC. After 3 d the cellularity of DC in irradiated hosts had increased significantly more than in the normal hosts. A difference was detectable already after 1-2 d when preculturing was omitted. The increased growth appeared to take place at several stages of cell maturation and not only at the progenitor cell level. Colony stimulating factor(s) for granulocyte and macrophage progenitors, as well as cytokines stimulating the bone marrow-derived cell line, 14 M.1, were present in DC fluid (DCF) at higher concentrations in irradiated than in normal mice throughout the final culture period. On the other hand, DCF concentrations of tumour necrosis-like factor (that may either induce CSF secretion or directly inhibit myelopoiesis), were not significantly different in irradiated compared with normal DC hosts. The cytokines detected in the DC may at least in part stem from inflammatory cells accumulating around the chambers. This animal model should be useful in further investigation of the highly complex regulatory network governing formation of white blood cells in the intact organism.     

Regulation of hematopoiesis-IV: The role of interleukin-3 and bryostatin 1 in the growth of erythropoietic progenitors from normal and anemic W/Wv mice

We and others have established a role for T lymphocytes and their products in the regulation of erythropoiesis. Interleukin-3 (IL-3) is a multipotential lymphokine with burst-promoting activity that is produced by activated T lymphocytes. In the anemic, stem cell-defective W/Wv mouse we have described the absence of a functionally active thymocyte population that in normal animals enhances erythroid progenitor growth and stem cell self-renewal. In studies reported here we find that W/Wv mouse marrow responds to exogenous IL-3 by increased erythroid progenitor cell growth. The BFU-E and CFU-E from anemic donors are more sensitive to IL-3 than are those in +/+ marrow. We have recently observed a stimulatory effect of bryostatin 1 (a macrocyclic lactone derived from a marine invertebrate) on normal erythropoiesis in human bone marrow progenitor assays. To test the effects of this molecule on murine normal and anemic W/Wv cells we grew these cells in the presence of increasing doses of bryostatin 1. Bryostatin mimics the stimulatory action of IL-3 on W/Wv bone marrow. Polyclonal antibody directed against murine IL-3 blocks the stimulatory effect of bryostatin on erythropoiesis. Otherwise inactive thymocytes from W/Wv mice in coculture with W/Wv bone marrow showed stimulation of erythropoiesis in the presence of bryostatin. We believe that bryostatin may in part act by stimulating T lymphocytes to release physiologic concentrations of lymphokines.     

Defective protective capacity of W/Wv mice against Strongyloides vatti infection and its reconstitution with bone marrow cells

The susceptibility of congenitally anemic, and mast cell deficient W/Wv mice to infection with Strongyloides ratti was examined. After a primary infection, W/Wv mice showed greater and more persistent peak larval counts than did normal littermates. Worm expulsion was also slower in W/Wv mice than in +/+ mice. Furthermore, difference in susceptibility was expressed as early as 24 h after infection, suggesting not only that protective mechanisms of the gut but also of the connective tissue were defective in W/Wv mice. Reconstitution with bone marrow or spleen cells from +/+ mice was effective in restoring the protective response in W/Wv mice, whereas thymocytes or mesenteric lymph nodes had no effect. Both connective tissue and mucosal mast cells were repaired in W/Wv mice after marrow reconstitution and infection. Since relatively long incubation period was required for the expression of such reconstituting activities, bone marrow cells seem to contain precursor cells of the effector and/or regulator cells.     

Interaction of hemolysis and genotype on ionized calcium in bile of mice with hemolysis-induced gallstones

In this study, we used an ion-selective membrane electrode to measure ionized calcium in hepatic bile of control +/+ mice and nb/nb mice with hereditary hemolytic anemia. We found that biliary concentrations of ionized, bound, and total calcium were significantly higher (p less than 0.001) and magnesium was significantly lower (p less than 0.001) in nb/nb mice than in control +/+ mice. To separate the hemolytic process from genotypic influences, we transplanted genetically defective bone marrow from nb/nb mice into histocompatible nonhemolytic recipients (W/Wv). After successful engraftment, transplanted W/Wv mice had significantly higher biliary concentrations of ionized calcium than their untreated W/Wv counterparts (p less than 0.001); but bound and total calcium and magnesium concentrations were not different from untreated W/Wv controls. When compared with nb/nb mice, transplanted W/Wv mice had lower ionized calcium (p less than 0.001) and higher bound calcium concentrations (p less than 0.001) in their biles. These data indicate that ionized calcium in hepatic bile is significantly influenced by genotypic factors and subsequently increased in chronic hemolysis; and further, that increased ionized calcium in bile of mice with hemolysis is a risk factor, but of limited predictive value for hemolysis-induced gallstone formation.     

Effect of rabbit antimouse brain serum on marrow cells capable of curing W/Wv mice

The W/Wv mouse has a recessively inherited defect in hematopoietic stem cells (HSC) but can be cured of its hematopoietic abnormalities by infusion of marrow from a co-isogeneic, +/+ mouse. The "curative" cell for the W/Wv is thought to be a subcompartment of the HSC that is capable of forming hematopoietic spleen colonies (CFU-S) in irradiated mice. The curative HSC must have a very high proliferative potential and it is known that HSC with variable degrees of proliferative potential are found within the CFU-S compartment. Rabbit antimouse brain serum (RAMBS) was used to treat +/+ marrow and its effect upon CFU-S and upon curative cells was compared with the effect of normal rabbit serum (NRS) or of sham treatment. CFU-S were reduced to 70%-79% of control by NRS and to 8%-9% by RAMBS. Curative cells for the W/Wv were not detectably reduced by NRS; they were reduced by RAMBS, but to only approximately 20%-30% of control. Thus, it appeared to a certain degree that RAMBS spared HSC with a high proliferative potential when compared with its effect on the entire CFU-S compartment.     

Neonatal W-mutant mice are favorable hosts for tracking development of marked hematopoietic stem cells

Neonatal unirradiated mice of W-mutant genotypes, with a hematopoietic stem cell defect and anemia, were injected i.v. with normal fetal liver hematopoietic cells. Efficient, long-term engraftment occurred as a result of the competitive advantage to the donor stem cells. The frequency of engraftment and rate of repopulation characteristically diminish in the series W/Wv, Wf/Wf, and Wv/+, in which the severity of the endogenous defect is progressively less. H-2 compatibility is required in the inbred strain combinations examined; other histocompatibility loci play a minor role in some strain combinations. Engraftment is due to self-renewing hematopoietic stem cells ancestral to myeloid and lymphoid lineages. The more mildly defective mutants display much greater variability in the kinetics of repopulation--a result consistent with seeding by single, or very few, stem cells that form developing clones. Engraftment efficiency is reduced by prolonged culture of fetal liver cells during experimental infection by recombinant retroviruses; nevertheless, after 24 h in vitro to achieve retroviral marking, stem cells retain their ability to repopulate and develop in W/Wv neonates.     

Engraftment of bone marrow transplants in W anemic mice measured by electronic determination of the red blood cell size profile.

Defective stem cells of WBB6F1-W/Wv mice produce macrocytic red blood cells (RBCs); stem cells of WBB6F1-+/+ mice produce normocytic RBCs. Utilization of the Coulter counter channelyzer permitted good dissociation between the size distribution of populations of +/+ and W/Wv RBCs. Peaks (mean cell volumes) for +/+ and W/Wv RBCs have been determined to be between the 30th and 40th channel and 50th and 60th channel, respectively. Variability of profiles for individual mice of both genotypes did not exceed the variability of separate determinations of the same cell suspension from a single mouse. Admixture (approximately 15%) of either type of erythrocytes could be quantitatively detected by this method. One week after transplant of 10(7) +/+ marrow cells into W/Wv recipients, 25% of donor type erythrocytes were detected. Eighteen days post-graft, concentration of +/- normocytes exceeded the concentration of macrocytes in the W/Wv recipients' circulation. Approximately 45 days post-transplant, the proportion of macrocytes decreased below the 10% detectable level. Calculation of the daily RBC production rate during repopulation and estimation of the number of RBCs produced by a single hematopoietic colony were determined. The RBC size profile was found to be a convenient method for studying the effect of implantation of W/Wv marrow into lethally irradiated +/+ mice. This method proved suitable for repetitive determination of the size population in individual transplanted mice.     

Analysis of the hematopoietic effects of new dominant spotting (W) mutations of the mouse. II. Effects on mast cell development

In addition to their anemia, sterility and lack of coat pigment (1,2), W/Wv mice are mast cell deficient (3,4). Our analysis of three recently described W alleles (5) confirms reports (3,6) that (a) W mutations alter skin mast cell number in parallel with their influence on red cell number (but not with pigmentation), (b) that mast cells arise from hematopoietic tissue (7) and (c) that injections of normal bone marrow cells, which cure the anemias of W/Wv recipients, also alleviate the deficiency of skin mast cells in these mice. Transplants of bone marrow cells from mice homozygous for two new anemia-causing W alleles, W39 and W41, fail to cure the anemias of W/Wv recipients (companion paper) or increase the number of mast cells in their skin. Marrow cell implants from non-anemic W44/W44 mice cure the anemia, but do not change the number of mast cells in the skin of W/Wv recipients. The fact that the bone marrows of all three new homozygotes have fewer than normal numbers of CFUs hematopoietic stem cells (see companion paper) and have reduced mast cell-regenerating capacities, supports Kitamura's contention (8) that mast cell precursors may be closely related to or identical with the CFUs.     

Latent deficiency of the hematopoietic microenvironment of aged mice as revealed in W/Wv mice given +/+ cells

The macrocytic anemia of W/Wv mice can be cured by injection of +/+ bone marrow cells (BMC) from WBB6F1 mice. However, it has been observed that some W/Wv recipients appear to "lose" their cure with time, an effect that does not appear to be related to the age of the BMC donor. The present study was undertaken to determine the effect of recipient age on W/Wv responses to BMC injection. The effect of aging on erythroid parameters was similar in untreated W/Wv mice and +/+ controls. In both genotypes, hematocrit (HCT) and red blood cell count (RBC) decreased, and the modal red blood cell size (peak) increased between 13 and 150 weeks of age. As anticipated, mean HCT and RBC values were lower and peak values higher in W/Wv mice compared to +/+ controls at every age. However, the rate of decrease in HCT and RBC with age was the same for both genotypes, suggesting that the age effect and W gene effect were independent. Peak values increased slightly more with age for W/Wv than for +/+ controls. When female W/Wv mice in three age groups (23.5, 70, and 91.5 weeks old) were injected with 5 x 10(5) BMC from 20-week-old +/+ female donors and HCT, RBC, and peak were determined monthly, improvement was seen in most W/Wv recipients. However, in the older mice this improvement was slower and often was not sustained; 100% of the youngest recipients, 80% of the middle-aged, and only 30% of the older groups were cured after 3 months. Taken together, these data suggest a latent deficiency of the aging hematopoietic microenvironment that is revealed in W/Wv mice by the stress of continuing erythroid demand on the limited number of normal donor BMC.     

Poor response of Wv/Wx mice to a grafted neutrophilia-inducing, colony-stimulating-factor-producing tumor

Although mice possessing two mutant genes at the W locus have a defect in multipotential hematopoietic stem cells that form macroscopic colonies in the spleen of irradiated mice, the number of neutrophils in the blood of these mutant mice is normal or nearly normal. We investigated neutrophil production using the NFSA fibrosarcoma of C3H mouse origin, which induces neutrophilia accompanied by production of a neutrophil-macrophage colony-stimulating factor by the tumor. When the NFSA tumor was transplanted to (C57BL/6 X C3H/He)F1-Wv/Wx or to congenic +/+ mice, neutrophilia developed in mice of both genotypes. However, there was a significant difference between the degree of neutrophilia that developed in them; there was a 107-fold increase in the +/+ mice, but only a 28-fold increase in the Wv/Wx mice four weeks after tumor transplantation. This result is consistent with the concept that doubly heterozygous W mice have multipotential stem cells with diminished ability to respond to stimulation. The unperturbed condition may not provide a sufficient stimulus to demonstrate the defect in neutrophil production in doubly heterozygous W mutant mice.