Phorbol Ester Enhancement of IL-3-Dependent Proliferation of Primitive Hematopoietic Progenitors of Mice in Culture

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Vol. 280, Issue 1, 225-231, 1997

Phorbol Ester Enhancement of IL-3-Dependent Proliferation of Primitive Hematopoietic Progenitors of Mice in Culture¹

Manabu Musashi, Keisuke Sakurada, Ken-Ichi Kawamura , Hiroshi Iwasaki, Yuzo Tsuda, Masanobu Kobayashi, Makie Sasaki, Keiko Kato, Eiji Tanaka, Tetsuo Sudo, Masahiro Asaka and Tamotsu Miyazaki

Third Department of Internal Medicine, Hokkaido University School of Medicine (M.M., K.S., K.K., H.I., Y.T., M.A., T.M.), Department of Pathology, Cancer Institute (M.K.), Hokkaido University School of Medicine, College of Medical Technology (M.S., K.K., E.T.), Hokkaido University, Sapporo, Japan and Basic Research Laboratories, Toray Industries Inc., Kamakura, Japan

	Abstract

Top Abstract Introduction Materials & Methods Results Discussion References

Protein kinase C (PKC) is a Ca⁺⁺- and phospholipid-dependent protein kinase activated by diacylglycerol that is either releasedfrom cell membranes in response to certain growth factors or mimickedby 12-O-tetradecanoyl phorbol-13-acetate (TPA). We studied theeffects of TPA on interleukin-3 (IL-3)-dependent colony formationof mouse bone marrow cells from mice injected with 5-fluorouracil2 days before examination in order to clarify the significanceof PKC in the proliferation of primitive hematopoietic progenitors.Although TPA alone did not support colony formation, TPA in combinationwith IL-3 increased colony numbers from 1.5 to 2 times that formedwith IL-3 and vehicle. TPA increased not only the granulocyte/macrophagecolonies, but also the multilineage colonies. A sequential colonycount showed that TPA, unlike IL-6, did not hasten the appearanceof colonies. Because TPA enhanced IL-3-dependent colony formationderived from lineage-negative marrow cells obtained from micethat received 5-FU 2 days before, it is possible that it mightact directly on primitive progenitors. Prolonged pretreatmentof marrow cells with TPA prevented TPA-augmented colony growth.Calphostin C, a specific PKC inhibitor, and certain specific tyrosinekinase inhibitors, such as genistein and herbimycin A, abrogatedthe enhancing effects of TPA on IL-3-dependent colony formation.These data suggest that TPA had a direct effect on the primitiveprogenitors and enhanced IL-3-dependent colony formation via activationof PKC and certain tyrosine kinases.

	Introduction

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IL-3 is a multilineage hematopoietic cytokine that can support the survival and proliferation of immature multipotential progenitorsand cells committed to a number of myeloid lineages (Ihle, 1992).IL-3 also supports the proliferation of factor-dependent celllines such as FDCP-1 (Dexter et al., 1980) and B6SUtA1 (Sorensenet al., 1989). The receptor for human IL-3 consists of an $alpha$ -subunitand a $beta$ -subunit, but both lack detectable catalytic domains (Ihle,1992). Recent studies on postreceptor cytokine signaling haverevealed that the binding of IL-3 to its receptor molecules resultsin their dimerization, thus activating two signaling pathways:a ras-mediated (ras-raf-1-MAP kinase) pathway (Satoh et al., 1992;Vojtek et al., 1993; Kyriakis et al., 1992) and a ras-independentJAK (Janus kinase)-STAT (signal transducer and activator of transcription)system (Silvennoinen et al., 1993; Ihle et al., 1994).

PKC (Nishizuka, 1984; 1988; 1992) has been reported to play an important role in the proliferation of IL-3-dependent celllines. IL-3 stimulation of FDCP-1 cells has been reported to inducethe translocation of PKC from cytosole to membrane (Farrar etal., 1985). Although this observation has been confirmed in somestudies (Whetton et al., 1986; Pelech et al., 1990), it has notbeen confirmed in others (Ihle, 1992). Recently, it has been shownthat PKC activates Raf-1 by direct phosphorylation in NIH 3T3fibroblasts (Kolch et al., 1993, Burgering and Bos, 1995). Thesefindings are very important in demonstrating the cross-talk ofPKC activation and ras-mediated IL-3 signal transduction pathways.However, it is not certain that these observations are applicableto normal hematopoiesis.

In the presence of IL-3, certain cytokines, such as IL-6 (Ikebuchi et al., 1987), granulocyte colony-stimulating factor (G-CSF;Ikebuchi et al., 1988), IL-11 (Musashi et al., 1991a), c-kit ligand(Tsuji et al., 1991) and IL-12 (Jacobson et al., 1993; Hirayamaet al., 1994), have been observed to be capable of exerting synergisticeffects on the proliferation of primitive hematopoietic progenitors.These particular cytokines are termed "synergistic factors" (Ogawa,1993). On the basis of these studies, it has been suggested thatIL-3 can support the proliferation of progenitors that have leftthe dormant state of the cell cycle (G0) but that it is unableto trigger the recruitment of primitive progenitors into the cellcycle (Suda et al., 1985; Leary et al., 1989). On the other hand,these synergistic factors augment IL-3-dependent colony growthby shortening the G0 period (Ikebuchi et al., 1987; 1988; Musashiet al., 1991a; Tsuji et al., 1991; Hirayama et al., 1994). Interestingly,in addition to its synergistic effects on IL-3-dependent colonyformation, c-kit ligand stimulates the proliferation of progenitorsthat have left the G0 state, so it is able to exert synergisticeffects on other "synergistic factors" (Tsuji et al., 1991). Thusthe synergistic interaction of these cytokines is somewhat complicated,and it is important that their signal transduction pathways, alongwhich cellular responses will be made, be clarified.

As a first step, we studied the PKC activator TPA (Niedell et al., 1983) in order to determine whether it could enhance theIL-3-dependent proliferation of primitive hematopoietic progenitorsin mice, in an effort to clarify the significance of PKC in theproliferation of primitive hematopoietic progenitors.

	Materials and Methods

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Cell preparation. Ten to 15-week-old male BDF₁ (C57 B1/6 × DBA/2 F1 hybrids) mice were obtained from Charles River Japan (Atsugi, Japan). Asingle-cell suspension was prepared from the pooled femurs ofthe mice, which had been injected with 150 mg/kg b. w. of 5-FU(Kyowa Hakko Kogyo Co., Tokyo, Japan) i.v. through their tailveins 2 days before examination (Day-2 post 5-FU marrow cells)in order to enrich the noncycling hematopoietic primitive progenitors(Hodgson and Bradley, 1979; Suda et al., 1983). Lineage-negative(Lin $-$ ) Day-2 post 5-FU marrow cells were isolated as describedby Shih et al. (1992) with some minor modifications. Briefly,light-density cells were separated by density centrifugation aboveFicoll-Conray (specific gravity, 1077) from the Day-2 post 5-FUmarrow cells. They were then incubated at 4°C for 45 min in acocktail of antibodies: anti-Thy 1.2 (Pharmingen, San Diego, CA),B220 (CD45R, Pharmingen), Gr-1 (Pharmingen), and Mac-1 (CD11b,Boehringer Mannheim Biochemica, Germany). After washing twice,sheep anti-rat IgG (Fc)-conjugated immunomagnetic beads (Dinabeads,Dynal A.S., Oslo, Norway) were added to the cell suspension andincubated at 4°C for 45 min. Lineage-specific-antigen-positive(Lin+) cells were removed by a magnetic particle concentrator(Dynal), and Lin $-$ cells were recovered from the supernatant. Thecell/bead ratio applied was 1:30.

Factors and agents. The source of recombinant murine IL-3 was medium conditioned by Chinese hamster ovary (CHO) cells that had been geneticallyengineered to produce murine IL-3 to high titer (approximately70,000 U/ml). Human recombinant Ep was a generous gift from KirinBrewers Co. (Tokyo Japan). TPA and OAG were purchased from SigmaChemical Co. (St. Louis, MO). Calphostin C, a specific inhibitorof PKC, was purchased from Kyowa Medics Co. (Tokyo, Japan). TheIC₅₀ values of calphostin C against PKC, cyclic AMP-dependentprotein kinase (A-kinase) and tyrosine kinase (p60^v-src) were reported to be 0.05 µM, >50 µM and >50 µM, respectively(Kobayashi et al., 1989 a, b).

Genistein (Akiyama et al., 1987

) and herbimycin A (Uehara et al., 1988

; Uehara et al., 1989

) were used as the tyrosine kinaseinhibitors. Genistein was purchased from Sigma. The IC₅₀ valuesof genistein have been reported to be 8 µg/ml (p60^v-src), 6 µg/ml (epidermal growth factor receptor) and >100 µg/ml (PKC,A-kinase) (Akiyama et al., 1987

). The IC₅₀ values of herbimycinA have been reported to be 5 µM (tyrosine kinase, p210^bcr/abl), 12 µM (tyrosine kinase, p60^v-src), >350 µM (PKC) and >350 µM (A-kinase) (Fukazawa et al., 1991

).All the agents were dissolved in dimethyl sulfoxide (DMSO), andthe final concentration of DMSO in the culture dishes was lessthan 0.1%.

Clonal cell culture. Methylcellulose cell culture was performed in 35-mm Lux suspension culture dishes (No. 5221R, Nunc Inc., Naperville, IL) asdescribed previously (Musashi et al., 1991a, b). One milliliterof culture contained 5 × 10⁴ Day-2 post 5-FU marrow cells or 2000 lineage-negative cells,alpha-medium (Flow Laboratories Inc., Rockville, MD), 1.2% methylcellulose(Wako Junyaku Co., Tokyo, Japan), 30% fetal calf serum (HycloneLaboratories, Logan, UT), 1% fraction V bovine serum albumin (Sigma),2 U/ml of recombinant human Ep, 100 µM 2-mercaptoethanol (2-ME,Eastman Kodak, Rochester, NY), hematopoietic factors and agents.The dishes were incubated in a humidified atmosphere flushed with5% CO₂ at 37°C. Colonies consisting of 50 or more cells were countedon indicated days under an inverted microscope according to colonytypes (Nakahata et al., 1982) as indicated in the tables. Briefly,GM colonies consisted of large, round macrophages and polygonalneutrophils. GEMM colonies were recognized by the red or darkbrown color of hemoglobin in aggregated erythrocytes and by hugemegakaryocytes adding to granulocytes and macrophages. The blastcell colonies consisted of a homogeneous population of up to 1000loosely arranged, frequently clumped, round cells with no signsof terminal differentiation such as granulocytes, macrophages,erythrocytes, and megakaryocytes. The blast cell colonies wouldlater develop into GEMM colonies or large GM colonies.

For OAG supplementation assay, on day 2 of the culture, a supplement of OAG was added by layering 0.1 ml of 10⁶ M OAG over the surface of each 0.9-ml culture containing 5 ×10⁴ Day-2 post 5-FU marrow cells, 100 U of IL-3 and 10⁷ M OAG.

Protein kinase inhibitors were added to the cell suspensions at least 10 min before the addition of TPA or IL-3.

Unless otherwise stated, data represent mean ± S.D. from quadruplicate dishes.

Effects of long-term preincubation of cells with TPA on colony growth. Long-term incubation of cells with TPA resulted in a down-regulation of PKC (Kitajima et al., 1988; Goodnight et al., 1994).To examine whether TPA exerts its effects through the activationof PKC, one million Day-2 post 5-FU marrow cells were incubatedin alpha-medium with 2 × 10⁸ M TPA or vehicle for 48 hr. Neither the FCS nor the cytokineswere supplemented in the cell suspension. After washing, the cellswere incubated in a methylcellulose culture containing IL-3 eitheralone or in combination with TPA.

Preincubation of cells. To infer the signal transduction of TPA by using the protein kinase inhibitors, Day-2 post 5-FU bone marrow cells were preincubatedfor 12 hr with TPA either alone or in combination with the inhibitors.After washing twice, the cells were cultured in methylcellulosecontaining IL-3.

Statistical analysis. Student's t test was used for the statistical analysis. For analysis of variance (ANOVA), an F test was performed on the databefore Student's t test.

	Results

Top Abstract Introduction Materials & Methods Results Discussion References

Colony formation derived from Day-2 post 5-FU marrow cells. We first analyzed the colony formation derived from Day-2 post 5-FU marrow cells supported by IL-3 in combination with TPA.Whereas TPA alone did not stimulate colony growth, it did augmentcolony formation when in combination with IL-3, maximally at 10⁷ M. This particular concentration of TPA, in combination withIL-3, increased colony growth by 175% ± 16% (mean ± S.D.) in nineof the experiments compared with the IL-3 plus vehicle control.Table 1 shows a representative result. A higher concentrationof TPA (10⁶ M) seemed to suppress colony growth. The final concentrationof DMSO that contained 10⁷ M TPA was 0.01%. Because concentrations of DMSO less than 0.1%did not affect IL-3-dependent colony formation (data not shown),this suppressive effect of TPA is not due to DMSO. Another PKCactivator, OAG, at a concentration of 10⁶ M and 10⁷ M also, significantly enhanced IL-3-dependent colony formation.However, the degree of increase was less than that for those augmentedwith TPA. The addition of supplement OAG (final concentration,10⁷ M) on the second day to those cultures containing 10⁷ M OAG resulted in an increase in colony numbers (19 ± 2) comparedwith those supplemented with vehicle (16 ± 2) and those that hadnot been supplemented (15 ± 2). These data suggest that OAG maybe inactivated rapidly in the culture dishes.

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TABLE 1
Effects of TPA on colony formation in Day-2 post 5-FU marrow cells

TPA increased not only the GM colonies but also the GEMM colonies (table 2).

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TABLE 2
Differential counts of colonies

Serial observation of blast cell development in Day-2 post 5-FU marrow cells. To examine the time course of colony development, we observed the culture dishes every third day for a serial observationof blast cell development. As shown in figure 1, although TPAaugmented IL-3-dependent colony growth, unlike IL-6, it did nothasten the appearance of colonies supported by IL-3. The additionof TPA did not affect the synergistic effects of IL-3 + IL-6.

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Fig. 1. Time course of colony formation. Day-2 post 5-FU marrow cells were cultured with 2 U/ml of Ep and designated agents. Colonieswere counted on every third day. Colony numbers show mean numberfor four dishes, each containing 5 × 10⁴ cells.

To analyze further the kinetics of colonies supported by IL-3 + TPA, we examined the culture dishes daily and recorded thedevelopment of new blast cell colonies and their subsequent proliferationin cultures containing IL-3 + vehicle and IL-3 + TPA ("mappingstudies," fig. 2). On the basis of lines connecting the two endpointsof the growth curves, we estimated the doubling time of individualcolonies to be 17.5 ± 4.3 hr and 17.3 ± 2.9 hr in cultures supportedby IL-3 + vehicle and by IL-3 + TPA, respectively. The averagenumber of days required for colonies to reach 100 cells was calculatedto be 10.8 ± 2.9 and 10.2 ± 2.3 in cultures supported by IL-3+ vehicle and by IL-3 + TPA, respectively. Because the differencesbetween the two groups in growth rate and average number of daysrequired for colonies to reach 100 cells were not statisticallysignificant, these data indicated that TPA, unlike synergisticfactors, did not shorten the G0 period where primitive progenitorshad resided.

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Fig. 2. Growth rate of individual blast cell colonies. Solid lines shows blast cell colonies that later developed into GM colonies;dashed lines show those that later revealed GEMM expression. Thedata are from colonies identified in each of the four dishes seededwith 5 × 10⁴ day-2 post 5-FU bone marrow cells in the presence of IL-3 eitheralone or in combination with TPA.

Colony formation in pooled blast cells. It is not clear whether TPA acted on primitive progenitors. To clarify this, we used pooled blast cells instead of Day-2 post5-FU marrow cells. Because the pooled blast cells that constitutedthe blast cell colony did not contain stromal or mature cellsand contained a relatively homogeneous population, as well ashaving a high plating efficiency (Nakahata et al., 1982; Musashiet al., 1991a), we extracted and pooled those blast cell coloniesfound to be smaller than 150 cells per colony as stimulated byIL-3 on day 9 of the culture. After washing, the pooled blastcells were reincubated with IL-3 or IL-3 + TPA in cultures containing30% fetal calf serum, 1% bovine serum albumin, and 2 U/ml of Ep.Both IL-3 + TPA and IL-3 + vehicle stimulated secondary colonyformation in the pooled blast cells, and the plating efficiencieswere 15% to 20% and 8% to 12%, respectively (table 3). Thesedata suggested that TPA had, to some extent at least, acted onthe early progenitors directly.

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TABLE 3
Secondary colony formation of pooled blast cells with IL-3 alone or in combination with TPA

Colony formation in lineage-negative bone marrow cells. To analyze further the direct effects of TPA on primitive progenitors, we purified progenitor cells partially by density cutand immunomagnetic bead selection. TPA increased IL-3-dependentcolony formation derived from Lin $-$ cells about 6-fold, whereasthe mean increment by TPA of IL-3-dependent colonies derived fromDay-2 post 5-FU marrow cells was 175%. Thus TPA-enhanced IL-3-dependentcolony formation was more sensitive to TPA in Lin $-$ bone marrowcells than in Day-2 post 5-FU marrow cells (table 4). Again,TPA increased not only the GM colonies but also the GEMM colonies.Lin+ cells did not give rise to colonies in response to IL-3 eitheralone or in combination with TPA.

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TABLE 4
Effect of TPA on colony formation in Day-2 post 5-FU lineage-negative marrow cells

Effects of long-term preincubation of cells with TPA on colony growth. Next we examined the involvement of PKC in the proliferation of primitive progenitors stimulated by IL-3 alone or in combinationwith TPA. When the cells were preincubated with a vehicle, a differencein colony numbers was observed between those supported by IL-3and those supported by IL-3 + TPA. However, IL-3 and IL-3 + TPAgave rise to almost the same number of colonies (13 vs. 11) afterpreincubation with TPA (table 5). These results suggested that48 hr of incubation with TPA may have down-regulated the PKC inthe progenitor cells, resulting in the loss of the enhancing effectof TPA.

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TABLE 5
Effects of preincubation with TPA for 48 hr on colony formation in Day-2 post 5-FU marrow cells

Effects of preincubation with TPA alone and in combination with protein kinase inhibitors on IL-3-dependent colony formation. To infer a signal transduction pathway of TPA, we preincubated Day-2 post 5-FU marrow cells for 12 hr with TPA alone or incombination with the inhibitors. After washing twice, the cellswere cultured with IL-3. The specific PKC inhibitor calphostinC abrogated the enhancing effects of TPA at a concentration of200 nM; this concentration was 4 times higher than the IC₅₀ valueagainst PKC and much lower than the IC₅₀ value against PTK andA-kinase. Genistein and herbimycin A also abrogated the effectsof TPA at 10 µg/ml and 200 ng/ml, respectively. This concentrationof genistein was almost the same as that of the IC₅₀ against tyrosinekinase, and the concentration of herbimycin A was markedly lowerthan the concentration of IC₅₀ against tyrosine kinase (table6). The incubation of Day-2-post 5-FU marrow cells for 12 hrwith DMSO, calphostin C, genistein or herbimycin A had no effecton the viability of these cells. The viabilities of the Day-2post 5-FU marrow cells incubated with DMSO (0.1%-0.001%), calphostinC (50-200 nM), genistein (1-100 µg/ml) and herbimycin A (50-200ng/ml) were 97.9% to 98.4%, 98.9% to 99.0%, 96.9% to 99.2% and98.1% to 98.7%, respectively. Although these results suggest thatTPA augmented IL-3-dependent colony formation, probably throughactivation not only of PKC but also of certain tyrosine kinases,direct evidence of this activation of PKC and tyrosine kinaseis needed for confirmation.

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TABLE 6
Effects of protein kinase inhibitors on colony formation

	Discussion

Top Abstract Introduction Materials & Methods Results Discussion References

In this study we showed that TPA directly augmented the IL-3-dependent colony formation of primitive hematopoietic progenitorsthrough the activation of PKC and certain tyrosine kinases. TPAdid not augment colony formation at all the doses evaluated; at10⁶ M, there was a reduced number of colonies. Although the suppressiveeffect of TPA at high concentration has already been reported(Kanakura et al., 1991), its mechanism is as yet unclear. Theweaker action of OAG might be due to its rapid metabolism. Repeatedsupplement of OAG is required to produce a cellular response similarto that triggered by a single dose of TPA (Nishizuka, 1992). Ourdata from the addition of supplement OAG also appear to supportthis observation.

TPA is well known to induce the monocytic differentiation of myeloid leukemia cells, such as HL-60 (Rovera et al., 1979; Hubermanand Callaham, 1979) and KG-1 (Ferrero et al., 1983). TPA, alone(Stuart and Hamilton, 1980; Burgess and Nicola, 1983) or in combinationwith IL-6 (Heyworth et al., 1993; Whetton et al., 1994), can alsostimulate the proliferation of GM-CFC. But the extent of thesestimulative effects of TPA is not limited to GM lineage: as wehave shown, TPA in combination with IL-3 increased not only GMcolonies but also multilineage GEMM colonies (table 2).

In terms of the synergistic effects of synergistic factors on IL-3-dependent colony formation, the synergistic factors didnot influence the cell doubling time of blast cells but shortenedthe G0 period of blast cell CFC. Because TPA, unlike other synergisticfactors, did not hasten the appearance of the blast cell coloniesor shorten the G0 period of the blast cell CFC (figs. 1 and 2),it seems possible that TPA acts through some other mechanism thanthe shortening of the G0 period of progenitor cells, such as suppressionof the programmed cell death of progenitor cells. It has beenreported that not only IL-3 (Williams et al., 1990; Collins etal., 1992) but also TPA can rescue bone marrow cells from apoptosisthrough activation of PKC (Lotem et al., 1991). Further studiesare needed to confirm the relationship between the rescue of progenitorcells by TPA from apoptosis and the enhancing effect of TPA onIL-3-dependent colony formation in primitive progenitor cells.

Next we examined whether TPA acted on primitive progenitors directly or indirectly through accessory cells contained in thecultures. To do this, we used blast cells obtained from the blastcell colonies that had developed in the presence of IL-3. Thesepooled blast cells are not primitive progenitor cells in themselves,however, they can give rise to secondary colonies, including GEMMcolonies (Nakahata and Ogawa, 1982; Musashi et al., 1991a). Thelower plating efficiencies than those found in previous experimentsmight be attributable to different culture conditions, such asthe quality of fetal calf serum. TPA also enhanced the IL-3-dependentcolony formation derived from lineage-negative Day-2 post 5-FUmarrow cells. The multiple increase of colonies by TPA from lineage-negativecells was higher than that from Day-2 post 5-FU marrow cells (6-foldvs. 1.8-fold).

Then we focused on the signal transduction of TPA in IL-3-dependent colony formation derived from Day-2 post 5-FU marrow cells.First, we examined the effects on colony formation of prolongedpretreatment of the progenitors with TPA. Although we did notmeasure PKC activity in the bone marrow cells before and afterthe prolonged incubation with TPA, it has been reported that incubationwith 2 × 10⁸ M TPA for 48 hr resulted in a down-regulation of PKC (Nishizuka,1984; Goodnight et al., 1994). TPA did not enhance IL-3-dependentcolony growth further after 48 hr of incubation, which suggeststhe involvement of PKC in the enhancing effect of TPA on IL-3-dependentcolony formation. Second, we used protein kinase inhibitors againstPKC and against tyrosine kinase. In these studies, the specificityof the inhibitors is critical. Calphostin C is a recently developedPKC inhibitor. It works by binding to the regulatory domain ofPKC (Nishizuka, 1988; 1992) and does not share a common homologywith other protein kinases, so it gives specific inhibitory effects.Calphostin C has a 1000 times lower IC₅₀ value against PKC thanagainst tyrosine kinase or A-kinase. Because high concentrationsof calphostin C have been reported to be somewhat cytotoxic tohuman tumor cells (Bruns et al., 1991), we examined the cytotoxiceffects of calphostin C on Day-2 post 5-FU marrow cells. Twelvehours of incubation with calphostin C at a concentration of 50to 200 nM did not influence cell viability. The fact that calphostinC abrogated the augmentation of IL-3-dependent colony formationby TPA suggests that PKC might be involved in the enhancing effectsof TPA. We cannot, however, exclude the possibility that calphostinC blocks the signaling not only of TPA but also of IL-3, becausecalphostin C decreased colony numbers to less than that achievedwith IL-3 stimulation only.

Genistein and herbimycin A, specific tyrosine kinase inhibitors, also inhibited the enhancing effects of TPA. One tyrosinekinase that may be activated by TPA and blocked by these inhibitorsis MAP kinase (Gilmore and Martin, 1983; Vila and Weber, 1988),which is activated by both phosphorylation of threonine and tyrosineresidues. Because genistein and herbimycin A, as well as calphostinC, completely abrogated IL-3-dependent colony formation, we couldnot ignore the possibility that these tyrosine kinase inhibitorsmight block the signaling of both TPA and IL-3, of which the intracellularsignal is transduced via tyrosine kinase JAK 2 (Silvennoinen etal., 1993).

Further studies aimed at providing direct evidence of the involvement of PKC in the enhancing effects of TPA on the IL-3-dependentcolony formation of primitive hematopoietic progenitors are underway.

	Acknowledgments

We would like to thank both Dr. Yoshimasa Uehara (National Institute of Health, Tokyo) for providing herbimycin A, and KirinBrewers Co. for the supply of recombinant human erythropoietin.

	Footnotes

Accepted for publication September 13, 1996.

Received for publication October 23, 1995.

¹ This work was supported in part by a grant-in-aid from the Ministry of Education, Science and Culture of Japan (No. 04671504)and by a special grant-in-aid for the Promotion of Education andScience at Hokkaido University provided by the same.

Send reprint requests to: Manabu Musashi, M.D., Third Department of Internal Medicine, Hokkaido University School of Medicine, Kita-15, Nishi-7, Kita-ku, Sapporo 060, Japan.

	Abbreviations

Day-2 post 5-FU marrow cells, bone marrow cells obtained from mice that received i.v. 5-FU 2 days before; DMSO, dimethyl sulfoxide; Ep, erythropoietin; GM, granulocyte/macrophage; GEMM, granulocyte erythrocyte/macrophage/megakaryocyte; 5-FU, 5-fluorouracil; IC₅₀, 50% inhibition constant; IL-3, interleukin-3; OAG, 1-oleoyl-2-acetyl-glycerol; PKC, protein kinase C; TPA, 12-O-tetradecanoyl phorbol-13-acetate.

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