Keratinocyte Growth Factor Administered Before Conditioning Ameliorates Graft-Versus-Host Disease After Allogeneic Bone Marrow Transplantation in Mice

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Blood, Vol. 92 No. 10 (November 15), 1998: pp. 3960-3967
Keratinocyte Growth Factor Administered Before Conditioning Ameliorates Graft-Versus-Host Disease After Allogeneic Bone Marrow Transplantation in Mice

By Angela Panoskaltsis-Mortari, David L. Lacey, Daniel A. Vallera, and Bruce R. Blazar
From the University of Minnesota Cancer Center and Department of Pediatrics, Division of Bone Marrow Transplantation, and Department of Therapeutic Radiology-Radiation Oncology, University of Minnesota, Minneapolis, MN; and Amgen Inc, Thousand Oaks, CA.

  ABSTRACT

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

Keratinocyte growth factor (KGF) is important in tissue repair and wound healing and its administration can abrogate chemical-and radiation-induced tissue damage in rodents. We investigatedKGF as a therapeutic agent for the prevention of graft-versus-hostdisease (GVHD)-induced tissue damage, morbidity, and mortalityin an established murine allogeneic bone marrow transplantation(BMT) model. B10.BR (H2^k) recipient mice were lethally irradiated and transplanted withC57BL/6 (H2^b) bone marrow (BM) with spleen cells (BMS) as a source of GVHD-causingT cells. KGF-treated mice (5 mg/kg/d subcutaneously days $-$ 6, $-$ 5,and $-$ 4 pre-BMT) receiving BMS exhibited better survival than thosenot receiving KGF (P = .0027). Cyclophosphamide (Cy), a commoncomponent of total body irradiation (TBI)-containing regimens,was administered to other cohorts of mice at a dose of 120 mg/kg/dintraperitoneally on days $-$ 3 and $-$ 2 before BMT. KGF-treated miceagain exhibited a better survival rate than those not receivingKGF (P = .00086). However, KGF-treated recipients receiving TBIor Cy/TBI BMS were not GVHD-free, as shown by lower body weightscompared with BM groups. GVHD target tissues were assessed histologicallyduring a 38-day post-BMT observation period. KGF ameliorated GVHD-inducedtissue damage in the liver, skin, and lung (completely in somerecipients) and moderately so in the spleen, colon, and ileum,even with Cy conditioning. These studies demonstrate that KGFadministration, completed before conditioning, has potential asan anti-GVHD therapeutic agent.
© 1998 by The American Society of Hematology.

  INTRODUCTION

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

GRAFT-VERSUS-HOST disease (GVHD) is caused by a donor antihost alloreactivity that involves both donor and host immuneresponses and is a major cause of morbidity and mortality post-bonemarrow transplantation (BMT). To prevent GVHD, most therapiesrely on the elimination of donor T cells from the graft or immunosuppressingthe host. Unfortunately, these approaches can result in poor engraftment,a loss of graft-versus-leukemia (GVL) activity, and/or higherrisk of leukemic relapse. Measures to hinder tissue damage andthe subsequent adhesion, extravasation, and recruitment of thecells responsible for the initial inflammatory insult in the earlypost-BMT period may provide alternative strategies.

Humans and rodents that receive intense conditioning regimens develop manifestations of an acute-phase reaction, includingcachexia, weight loss, and fever early post-BMT. The acute injuryto endothelial and epithelial cells causes the expulsion of intracellularcontents, acute-phase reactants, and cytokines (eg, interleukin-1[IL-1], IL-6, and tumor necrosis factor $alpha$ [TNF $alpha$ ]) that initiatethe inflammatory response necessary for tissue repair. Not onlydo these cytokines induce the expression of endothelial surfaceproteins (eg, P-selectin, E-selectin, and intercellular adhesionmolecule-1 [ICAM-1]) conducive to the tethering, adhesion, andtransmigration of inflammatory cells, but the damage caused bythe acute injury is also conducive to the prolonged exposure ofalloreactive and/or host cells to normally sequestered antigens.Contributing to this injury cascade is endotoxin released fromthe intestinal bacterial flora now accessible to the circulationthrough the damaged gut epithelium. With endothelial injury tothe liver, clearance of toxins is compromised, further amplifyingmanifestations of GVH disease. In the response of the lung totoxic injury, type I epithelial pneumocytes are most sensitiveto death from injury and type II cells proliferate to replacethem in the repair process. If the extent of damage to type IIcells exceeds the ability for re-epithelialization, the depositionof extracellular matrix (collagen) and fibrosis ensues leadingto respiratory insufficiency and idiopathic pneumonia. These failingtarget organs thus become contributory factors culminating inGVHD-induced morbidity and mortality.

Keratinocyte growth factor (KGF), also called fibroblast growth factor 7 (FGF-7), is a mediator of epithelial cell proliferation¹and a growth factor for hepatocytes² and type II pneumocytes.³^,⁴KGF has been shown to be protective in lethal models of radiation-and bleomycin-induced lung injury in rats,⁵ possibly by facilitatingrepair of DNA damage in alveolar epithelial cells.⁶ Other studieshave shown that KGF is protective against cyclophosphamide (Cy)-inducedulcerative hemorrhagic cystitis of the bladder in rats⁷ andalso against chemotherapy- and radiation-induced gastrointestinalinjury (mucositis) and mortality in mice⁸ (possibly by increasingintestinal stem cell survival⁹). Particularly noteworthy isa recent study that demonstrated that KGF did not cause significantproliferation of various human squamous cell tumor lines, includingthose that were KGF receptor positive.¹⁰ Therefore, by preventingchemotherapy- and radiation-induced side effects such as mucositisand lung injury, KGF has the potential for reducing GVHD complicationsand increasing the therapeutic index of chemoradiotherapy of cancerwithout stimulating the cancer cells. Few studies have focusedon the prevention of the damage to host tissues caused by theconditioning chemoradiation regimen administered pre-BMT. Thecurrent study was performed to determine whether exogenous invivo administration of KGF, completed before conditioning, couldprevent, ameliorate, or delay GVHD after allogeneic BMT in mice.

  MATERIALS AND METHODS

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Mice. B10.BR (H2^k) and C57BL/6 (H2^b) mice were purchased from The Jackson Laboratories (Bar Harbor, ME). Mice were housed in microisolatorcages in the SPF facility of the University of Minnesota and caredfor according to the Research Animal Resources guidelines of ourinstitution. For BMT, donors were 8 to 12 weeks of age and recipientswere used at 8 to 10 weeks of age.

KGF production. Recombinant human KGF produced in Escherichia coli was prepared as previously described³ at Amgen (Thousand Oaks, CA) andfound to be endotoxin-free. It was assayed using the BALB/MK keratinocytecell line.¹¹

Pre-BMT conditioning. B10.BR mice received PBS or KGF (5 mg/kg/d subcutaneously [sc]) on days $-$ 6, $-$ 5 and $-$ 4 pre-BMT (Fig 1). Mice were then segregatedinto those receiving either phosphate-buffered saline (PBS) orCy (Cytoxan; Bristol Myers Squibb, Seattle, WA) at 120 mg/kg/das a conditioning regimen pre-BMT on days $-$ 3 and $-$ 2. All micewere lethally irradiated on the day before BMT (7.5 Gy total bodyirradiation [TBI]) by x-ray at a dose rate of 0.41 cGy/min, asdescribed.¹² In an alternative treatment schedule, some micealso received KGF on days 1, 2, and 3 post-BMT.

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Fig 1. KGF treatment and conditioning schedule for BMT experiments. KGF (5 mg/kg/d) or PBS was administered sc to B10.BR recipients on days $-$ 6, $-$ 5, and $-$ 4. Mice were then further segregated into those receiving Cy (120 mg/kg/d) or PBS intraperitoneally on days $-$ 3 and $-$ 2. All recipients were irradiated (7.5 Gy) on the day before transplant (day $-$ 1). Groups were segregated into those receiving C57BL/6 BM alone or BM with allogeneic spleen cells (BMS) intravenously. In some mice, KGF treatment was also administered on days 1, 2, and 3 posttransplant in the context of Cy/TBI conditioning.

BMT. Our BMT protocol has been described previously.¹³ Briefly, donor C57BL/6 BM was T-cell depleted (TCD) with anti-Thy 1.2monoclonal antibody (clone 30-H-12, rat IgG2_b; kindly providedby Dr David Sachs, Cambridge, MA) + complement (Nieffenegger Co,Woodland, CA). Recipient mice were transplanted via caudal veinwith 20 × 10⁶ TCD C57BL/6 (H-2^b) marrow with or without 15 × 10⁶ NK cell depleted (PK136, anti-NK1.1 + complement) spleen cells(BMS) as a source of GVHD-causing T cells. All mice were monitoredfor survival and clinical evidence of GVHD (ie, weight loss, ruffledfur, cachexia, alopecia, and diarrhea). In other experiments,cohorts of mice were killed on a periodic basis for histologicevaluation of GVHD target tissues (3 mice/group/time point; seebelow).

Frozen tissue preparation. After anesthesia with sodium pentobarbitol, mice were killed by cervical dislocation and the GVHD target organs were removedby dissection. Spleen, liver, colon, small intestine, cecum, skin,and lungs were arranged in aluminum foil cups, snap-frozen inliquid nitrogen, and stored at $-$ 80°C. The lungs were first infusedvia the trachea with a mixture of 0.5 mL Optimal Cutting Temperaturemedium (OCT; Miles Inc, Elkhart, IN):PBS (3:1) before freezing.

Histological assessment. Frozen sections were cut 4-µm thick, mounted onto glass slides, fixed for 5 minutes in acetone, and stained with hematoxylinand eosin (H&E). Tissues were scored on a scale of 0 to 4+ forGVHD based on standard GVHD criteria.^13-19

Statistical analysis. Kaplan-Meier plots of survival data were analyzed by Mantel-Peto-Cox summary of $chi$ ².²⁰ Other data were analyzed using the Student's t-test. Probability(P) values less than or equal to .05 were considered statisticallysignificant. P values greater than .05 and less than .1 were considereda statistical trend.

  RESULTS

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

KGF ameliorates GVHD-induced lethality and weight loss after allogeneic BMT. To determine whether KGF administration would benefit BMT recipients under sublethal GVHD conditions, experiments were begunusing a nonuniformally lethal dose of allogeneic spleen cells(ie, not all recipients die). Figure 2A depicts the survival curvesof PBS- or KGF-pretreated (days $-$ 6, $-$ 5 and $-$ 4 pre-BMT), lethallyirradiated adult B10.BR (H2^k) mice infused with C57BL/6 bone marrow cells alone (BM groups)or with 5 × 10⁶ spleen cells as a source of GVHD-causing T cells (BMS groups),which corresponded to a 50% lethal dose in this experiment. BMSrecipients receiving KGF exhibited a statistical trend towardimproved survival (P = .070). Nonetheless, Fig 2B depicts thevery significant difference in body weights between BMS groupsreceiving KGF or PBS. Beginning on day 19 post-BMT, the weightsof BMS mice receiving KGF diverged from those not receiving KGFto a significant degree (P = .009 on day 19). Furthermore, theserecipients gained weight post-BMT at a rate equal to those micereceiving BM without spleen cells.

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Fig 2. Amelioration of mortality (A) and weight loss (B) by KGF following allogeneic BMT with a nonuniformly lethal dose of allogeneic spleen cells. B10.BR recipient mice (n = 8/group) were lethally irradiated (7.5 Gy) on day $-$ 1 and infused on day 0 with C57BL/6 BM either without (BM) or with 5 × 10⁶ spleen cells (BMS) as indicated. For (A), () BM ± KGF, ( $black-square$ ) BMS + PBS, and ( $black-triangle$ ) BMS + KGF. For (B), () BM + PBS, ( $triangle$ ) BM + KGF, ( $black-square$ ) BMS + PBS, and ( $black-triangle$ ) BMS + KGF. *.0003 < P < .01 from this point.

Next, KGF was studied under a more aggressive, 100% lethal condition induced by administration of 15 × 10⁶ spleen cells. Figure 3A depicts the survival curves of lethallyirradiated adult B10.BR mice infused with C57BL/6 BM or BMS. Asindicated, these groups were further segregated into those receivingpretreatments of PBS or KGF. Mice receiving KGF (BMS+KGF) exhibiteda higher actuarial survival rate that was statistically significant(P = .0027) compared with the GVHD control group (BMS+PBS). Figure3B shows the post-BMT body weights. Although KGF had no significanteffect on the weights of the recipients for the first 4 weekspost-BMT, it did prevent the subsequent weight loss in survivingmice. However, these mice did not regain their pre-BMT body weights,implying that they were not GVHD-free. In the absence of allogeneicT cells, Figs 2 and 3 (open symbols) demonstrate that KGF is notdeleterious to survival or weight gain post-BMT.

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Fig 3. Amelioration of mortality (A) and weight loss (B) by KGF after allogeneic BMT with a uniformly 100% lethal dose of allogeneic spleen cells. B10.BR recipient mice (n = 26/group) were lethally irradiated (7.5 Gy) on day $-$ 1 and infused on day 0 with C57BL/6 BM either without (BM) or with 15 × 10⁶ spleen cells (BMS) as indicated. Groups were further segregated into those receiving PBS or KGF (5 mg/kg/d) on days $-$ 6, $-$ 5, and $-$ 4 pre-BMT. Data compiled from two representative experiments are shown. For (A), () BM ± KGF, ( $black-square$ ) BMS + PBS, and ( $black-triangle$ ) BMS + KGF. For (B), () BM + PBS, ( $triangle$ ) BM + KGF, ( $black-square$ ) BMS + PBS, and ( $black-triangle$ ) BMS + KGF.

KGF delays the Cytoxan-induced acceleration of lethality post-BMT. Because the majority of BMT protocols in humans entail the use of Cy and TBI as a conditioning regimen, experiments were setup to determine the effects of KGF on this combined regimen. Thedose of Cy used (120 mg/kg/d for 2 days) was previously shownby this laboratory²¹ to be well tolerated in the early post-BMTperiod and biologically effective in facilitating the engraftmentof TCD allogeneic BM when combined with 7.5 Gy TBI. We have alsopreviously shown that, in the presence of allogeneic T cells,Cy accelerates GVHD-induced mortality and weight loss and leadsto the most significant pulmonary dysfunction.²² Figure 4A showsthat KGF delays the Cy-induced acceleration of GVHD mortalityto a significant degree (P = .00086). In fact, this actuarialsurvival rate is no different from the BMS + PBS group of Fig3A (from the same pool of experiments) that received TBI alone(P = .5). Therefore, it appears that, as far as GVHD mortalityis concerned, KGF has negated the deleterious effects of the combinedCy/TBI regimen.

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Fig 4. KGF delays the Cytoxan-induced acceleration of mortality (A) and weight loss (B). B10.BR recipient mice (n = 26/group) were lethally irradiated (7.5 Gy) on day $-$ 1 and infused on day 0 with C57BL/6 BM either without (BM) or with 15 × 10⁶ spleen cells (BMS) as indicated. Groups treated with Cy received 120 mg/kg/d on days $-$ 3 and $-$ 2. Groups were further segregated into those receiving PBS or KGF (5 mg/kg/d) on days $-$ 6, $-$ 5, and $-$ 4 pre-BMT. Data compiled from two representative experiments are shown. For (A), ( $open circle$ ) BM + CY + PBS, ( $triangle$ ) BM + CY + KGF, ( $bullet$ ) BMS + CY + PBS, and ( $black-down-triangle$ ) BMS + CY + KGF. For (B), ( $open circle$ ) BM + CY + PBS, ( $triangle$ ) BM + CY + KGF, ( $bullet$ ) BMS + CY + PBS, and ( $black-down-triangle$ ) BMS + CY + KGF. *P < .05 versus no KGF.

Figure 4B shows that KGF had a beneficial effect on weight loss during the second week post-BMT (P < .05) using this Cy/TBIregimen in combination with a uniformally lethal spleen cell dose.This finding was highly reproducible in two separate experiments.However, after the second week, body weights did not differ betweengroups. KGF had no effect on the late Cy-induced death and weightloss in the BM groups not receiving allogeneic spleen cells (Fig4, open symbols). Although the cause of this late mortality²²is still under investigation, we have concluded that these deathsare not GVHD-mediated as assessed histologically and neither arethey due to bone marrow aplasia²² or inflammatory mediatorssuch as those induced by sepsis as assessed by systemic levelsof IL-1 $beta$ , IL-6, TNF $alpha$ , and interferon $gamma$ (IFN $gamma$ ). It is suspectedthat the mortality may be caused by malnutrition due to toothdeformities arising from the toxic side effects of Cy on tootheruption. The time course of the mortality is consistent withthe observations of others²³^,²⁴ concerning this problem, andour inspections of the recipients' teeth at the time of deathsupport this hypothesis.

The dose of KGF used (5 mg/kg/d) before cytoablative therapy was consistent with that used for other studies in the literature.⁵^,⁷^,⁸There is evidence that KGF can be even more effective if administeredboth before and immediately after irradiation or chemotherapy.²⁵^,²⁶To determine whether the beneficial effect of KGF on survivalcould be improved upon, an additional KGF dosing schedule wastested. Mice received KGF on days $-$ 6, $-$ 5 and $-$ 4 pre-BMT only oralso on days +1,+2, and +3 post-BMT. To compare the effect ofKGF schedule on the different pre-BMT conditioning regimens, micewere further segregated into those receiving TBI alone or Cy/TBI.Figure 5A shows that KGF administered pre-BMT and post-BMT didnot further improve the actuarial survival rate over that of micereceiving KGF pre-BMT only (P = .32 and .19 comparing KGF schedulesfor TBI groups and Cy/TBI groups, respectively). In addition,TBI BMS recipients receiving KGF pre-BMT tended to have body weightshigher than their counterparts receiving KGF pre-BMT and post-BMT,with some recipients reaching their pre-BMT body weights (Fig5B). Therefore, it appears that an additional post-BMT dose scheduleof KGF does not add to survival and may be detrimental to bodyweight post-BMT.

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Fig 5. Effect of additional post-BMT KGF administration on mortality (A) and weight loss (B) after allogeneic BMT with a uniformly 100% lethal dose of allogeneic spleen cells. B10.BR recipient mice (n = 8/group) were lethally irradiated (7.5 Gy) on day $-$ 1 and infused on day 0 with C57BL/6 BM with 15 × 10⁶ spleen cells (BMS). Groups treated with Cy received 120 mg/kg/d on days $-$ 3 and $-$ 2. Groups were further segregated into those receiving KGF (5 mg/kg/d) on days $-$ 6, $-$ 5, and $-$ 4 pre-BMT (KGFpre) or those receiving KGF on days $-$ 6, $-$ 5, and $-$ 4 pre-BMT and days 1, 2, and 3 post-BMT (KGFpre&post). In (A), P = .32 and .19 comparing KGF schedules for TBI groups and Cy/TBI groups, respectively. In (B), for BMS + KGFpre versus BMS + KGFpre&post, .05 < P < .1 ( <A><AC> </AC><AC>ˆ</AC></A> ) and .01 < P < .05 (*). ( $black-triangle$ ) BMS + KGFpre, ( $black-lozenge$ ) BMS + KGFpre and post, ( $black-down-triangle$ ) BMS + CY + KGFpre, and () BMS + CY + KGFpre and post.

KGF ameliorates GVHD-induced pathology in the liver, lung, and skin but only delays GVHD in the spleen, colon, and ileum. Because it was evident from the weight curves of Figs 3B and 4B that surviving KGF-treated animals were not GVHD-free, representativerecipients from each group were examined to assess possible effectson GVHD-induced pathology in target organs. Recipients receivingpretreatment with KGF, Cy/TBI, and high-dose (15 × 10⁶) spleen cells had reduced histological signs of GVHD in the targetorgans (liver, colon, and lung) on day 48 post-BMT compared withrecipients not receiving KGF. Representative photomicrographsare shown in Fig 6 that illustrate the dramatic difference thatpretreatment with KGF can effect on GVHD-induced tissue destruction.The infiltrates are predominantly composed of monocytes, CD4⁺ T cells, CD8⁺ T cells, and neutrophils (immunohistochemistry not shown). KGFpretreatment did not affect the composition of the infiltrates,when present. There is minimal perivascular mononuclear cell infiltrationin the liver and lung and only moderate infiltration in the colonicmucosa. The spleen did show evidence of destruction, but thiswas surrounded by normal appearing post-BMT splenic tissue notseen in the GVHD-positive control (moribund at day 28 post-BMT)that did not even receive Cy in the conditioning regimen.

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Fig 6. Histologic assessment of GVHD in BMS (15 × 10⁶ spleen cells) recipients on day 28 (PBS, TBI group) and day 48 (KGF, Cy/TBI group) after allogeneic BMT. H&E-stained cryosections of spleen, liver, colon, and lung of a representative mouse taken from the indicated treatment groups at these time points show that KGF can abrogate GVHD-induced manifestation in the liver and lung and moderately so in the spleen and colon (original magnification × 100; resolution power, 40× objective lens).

To determine whether KGF was preventing, ameliorating, or delaying GVHD-induced pathology, a kinetic histologic analysis wasperformed on cohorts of BMT recipients of BM or BMS comparingKGF pretreatment on both TBI and Cy/TBI conditioning regimenson days 5, 14, 18, and 38 post-BMT. The average GVHD scores (3mice/group) assessed from H&E stains of cryosections of BMS recipientorgans removed on days 5, 14, and 38 post-BMT are depicted inFig 7. At day 5 post-BMT (Fig 7A), KGF-treated mice had averageGVHD scores lower than their PBS-treated counterparts. KGF-pretreatmentof Cy/TBI BMS recipients (thick hatched bars) resulted in loweringGVHD scores to the level of PBS-treated BMS recipients not receivingCy (dotted bars) for most target organs. This is consistent withthe findings of Fig 4A in which KGF negated the Cy-induced acceleratedmortality. In the absence of Cy, KGF treatment (solid bars) againresulted in lower scores. However, on days 14 and 18 post-BMT,KGF-treated recipients had moderate GVHD scores, albeit slightlylower than non-KGF recipients, in the lung and skin, while exhibitingmoderate to severe lesions in the spleen, colon, ileum, and liverequivalent to the PBS control recipients (Fig 7B, day 14 shown).It is obvious that this KGF treatment regimen, although it significantlydelayed mortality, did not prevent GVHD-induced pathology. However,when graphed on a linear time scale, GVHD scoring results showedthat KGF delayed the time it took to reach a moderate GVHD scoreof 2+ by 3 to 7 days for all organs (not shown). On day 38 post-BMT,a time when recipients not treated with KGF had all died of severeGVHD, Fig 7C shows that KGF-treated survivors had severe GVHDlesions in the spleen and gut but little to moderate pathologyin the liver, lung, and skin. In fact, KGF-treated BMS TBI recipientsexhibited no GVHD-induced pathology in the lung and skin (ie,appeared normal) at this time point. Thus, it appears that theseKGF-treated recipients were able to survive despite severe splenicdestruction and colitis, which would account for the inabilityof KGF to prevent weight loss at this high dose of allogeneicT cells. All recipients of allogeneic BM without spleen cellshad GVHD scores of either 0 or 0.5+ in all target organs for alltime points, with few exceptions (highest score was 1+).

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Fig 7. GVHD scores in target organs of B10.BR recipients pretreated with PBS or KGF on days $-$ 6, $-$ 5, and $-$ 4 pre-BMT, conditioned with Cy/TBI (days $-$ 3, $-$ 2, and $-$ 1) or TBI alone (day $-$ 1), and transplanted with C57BL/6 BM with 15 × 10⁶ spleen cells. Scores are averages of 3 mice/group on days 5, 14, and 38 post-BMT. ( $dagger$ ) indicates that all mice in the group had died by this time point. (0) indicates that all mice in the group exhibited normal histological appearance of the target organ. () BMS + PBS, () BMS + CY + PBS, ( $black-square$ ) BMS + KGF, () BMS + CY + KGF.

  DISCUSSION

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

A major contribution of this study is that it shows for the first time that KGF administration, when administered and completedbefore conditioning for murine allogeneic BMT recipients, resultsin a significant anti-GVHD effect, entirely inhibiting GVHD lesionsin the lungs and skin of long-term survivors. When administeredas a preconditioning treatment, KGF ameliorated tissue damageand, consequently, mice exhibited a higher survival rate, reducedweight loss, and reduced cellular infiltration post-BMT. Thisapproach is unique as KGF is administered only as a preconditioningtherapy, in contrast to neutralization with monoclonal antibodiesor cytokine protein administration administered during or afterconditioning, which may also affect antileukemia or engraftmentproperties.^27-29 KGF pretreatment of irradiated recipients of BMwith a 50% lethal dose of allogeneic spleen cells resulted inhigher survival (88% v 50% on day 62 post-BMT) and prevented GVHD-inducedweight loss. Under more aggressive GVHD conditions using a uniformly100% lethal dose of allogeneic spleen cells, KGF significantlyprolonged survival (P = .0027), but recipients never reached theirpre-BMT body weights. However, KGF did prevent lethal weight lossin some mice, ie, KGF-treated long-term survivors maintained sufficientbody weights to prevent morbidity.

Another major observation was that KGF inhibited the morbidity/mortality induced by Cy conditioning. KGF pretreatment of BMTrecipients conditioned with the combined Cy/TBI regimen againresulted in a significant increase in the actuarial survival rate(P = .00086). In fact, KGF negated the Cy-induced accelerationof lethality so that the survival of these recipients became equivalentto BMS recipients conditioned with TBI alone (and no KGF). KGF-treatmentsignificantly ameliorated GVHD-induced weight loss using thisaggressive conditioning regimen, but its effects were not maintainedafter 2 weeks post-BMT.

When KGF was administered post-BMT in addition to the pretreatment regimen, no additional beneficial effect on survival orbody weights were attained. In fact, body weights tended to belower with the additional post-BMT KGF treatment. The reason forthis paradox is unclear. It has been reported³⁰ that cytokinesmitogenic for epithelial cells may actually promote inflammationduring tissue repair when the epithelium is injured and producinginflammatory mediators such as IL-1 $beta$ and IL-8 either directlyor indirectly via fibroblast activation. Hence, the timing ofthe KGF administration may be critical to realizing its benefits,and we are currently investigating the effects of KGF on cytokinerelease in our murine BMT model.

Kinetic histological analysis demonstrated that KGF did not prevent the generation of GVHD-induced inflammatory cell infiltrationsand lesions in the target organs studied (spleen, colon, ileum,liver, lung, and skin), although it appeared that it delayed thegeneration of moderate lesions in affected recipients by 3 to7 days. Surprisingly, KGF-treated survivors (day 38 post-BMT)exhibited no pathology in the lung and skin (and liver in somerecipients, see also Fig 6). Because of the manner in which thisstudy was executed, it could not be determined whether KGF pretreatmenteffected a resolution of the GVHD-induced lesions in the lungsand skin (and liver in many cases) or whether these survivorsnever had GVHD manifestations in these organs. However, on days14 and 18 post-BMT, all KGF recipients had moderate GVHD scoresin the liver, lungs, and skin. Severe splenic lesions and colitiswere manifest in all KGF recipients, even those surviving post38 days, equivalent to those lesions present in moribund BMT recipientsnot pretreated with KGF. This would account for the inabilityof KGF-treated mice to regain their pre-BMT body weights. Nonetheless,surviving KGF-treated recipients were able to tolerate these severelesions. This implies that KGF ameliorated the GVHD-induced manifestationsin the liver, lung, and skin, so that, when combined with themanifestations in the other organs, they were insufficient totip the survival threshold.

It is possible that the route of injection (sc) was not suitable for sufficient KGF to reach the intestinal and colonic epitheliumin the face of severe GVHD-induced destruction. However, thissc route has been used in other studies and shown to be effectivefor KGF-mediated protection of irradiation and chemotherapy-inducedintestinal injury,⁸^,⁹ but in the absence of allogeneic, GVHD-causingcells. The administration of KGF via another route, eg, intraperitoneallyor intravenously, should be investigated.

We have not, to date, investigated the mechanism by which KGF ameliorates GVHD in our mouse model. KGF, a member of the fibroblastgrowth factor family, is produced by mesenchymal cells¹¹ andintraepithelial $gamma$ $delta$ T cells³¹ and acts predominantly on epithelialcells via binding to KGF receptors.³² It is presumed to playan important role as a mediator of mesenchymal-epithelial cellinteractions during embryogenesis.³³^,³⁴ The binding of KGFto its receptor activates a phosphorylation cascade³⁵ entailingphospholipase C- $gamma$ and mitogen-activated protein kinases.³⁶ KGFcan increase repair of irradiation-induced DNA damage via DNApolymerases- $alpha$ , - $delta$ , and - $epsilon$ ⁶ in addition to protecting cellsfrom reactive oxygen-induced apoptosis,⁴ possibly by upregulatingexpression of glutathione peroxidase,³⁷ which detoxifies reactiveoxygen species. It can facilitate wound repair in various injury-inducingmodels through its proliferative effects on epithelial cells inthe skin (keratinocytes),³⁸ hepatocytes in the liver,² alveolartype II cells in the lung,^3-5 gastrointestinal,²^,⁸^,⁹ urothelial,⁷^,³⁹pancreatic,⁴⁰ and mammary epithelium.⁴¹ These effects alsohave the benefit of helping to maintain functional epithelialbarriers, as has been shown in lung⁴² permeability studies.

In the current study, KGF had the greatest effect on those target organs that have been shown to express relatively high levelsof KGF receptor, specifically the lung and skin.³³ We have yetto determine whether KGF is affecting the GVHD properties of allogeneicT cells via direct signaling, but the expression of KGF receptorson lymphocytes has not been directly addressed. KGF is most likelyameliorating GVHD by reducing conditioning-induced injury, hencelowering the release of acute-phase reactants and dampening theensuing inflammatory cascade.

The potential use of recombinant human KGF for minimizing the toxicities of chemotherapy and/or radiation in the clinic holdsgreat promise, especially in view of the results of recent studiesdemonstrating that exogenous KGF does not stimulate the proliferationof tumor cells¹⁰ (even those bearing KGF receptors) or providea selective growth advantage or radioprotection.¹⁰^,⁴³

  ACKNOWLEDGMENT

The expert technical assistance of Sumiko Yonegi, Claudia DeLlano, John Hermanson, Chris Lees, Kelly Coffey, Stacey Hermanson,and Tamra Knutson is greatly appreciated. We also thank Dr PatriciaA. Taylor for critical review of this manuscript.

  FOOTNOTES

   Submitted May 8, 1998; accepted July 8, 1998.
   Supported by National Institutes of Health Grant No. HL 55209 and by the Viking Children's Fund.
   The publication costs of this article were defrayed in part by page charge payment. This article must therefore be herebymarked "advertisement" in accordance with 18 U.S.C. section 1734solely to indicate this fact.

Address reprint requests to Angela Panoskaltsis-Mortari, PhD, University of Minnesota, Department of Pediatrics, Division of Heme/Onc/Bone Marrow Transplantation, Box 484 UMHC, 420 Delaware St SE, Minneapolis, MN 55455; e-mail: panos001{at}maroon.tc.umn.edu.

  REFERENCES

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

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