©1995 by The American Society for Biochemistry and Molecular Biology, Inc.
High Activity Suppression of Myeloid Progenitor Proliferation by Chimeric Mutants of Interleukin 8 and Platelet Factor 4 (*)

(Received for publication, April 20, 1995; and in revised form, July 26, 1995)

Thomas J. Daly (1)(§) Gregory J. LaRosa (1) Sylvia Dolich (1) Theodore E. Maione (1) Scott Cooper (2) Hal E. Broxmeyer (2)

From the  (1)Repligen Corporation, Cambridge Massachusetts 02139 and the (2)Departments of Medicine (Hematology/Oncology), Microbiology/Immunology, and the Walther Oncology Center, Indiana University School of Medicine, Indianapolis, Indiana 46202-5121

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

The proliferation of human myeloid progenitor cells is negatively regulated in the presence of certain members of the chemokine family of molecules. This includes interleukin 8 (IL-8) and platelet factor 4 (PF4), which in combination are able to synergize, resulting in cell suppression at very low concentrations of these molecules. A series of PF4 and IL-8 mutant proteins were analyzed in an in vitro colony formation assay for myeloid progenitor cells to assess domains of these proteins that are required for activity. Mutation of either of the two DLQ motifs within PF4 resulted in an inactive protein. Perturbations within the IL-8 dimer interface region also resulted in mutants that were incapable of suppressing colony formation. A class of chimeric mutants consisting of domains of either PF4 and IL-8, Gro-alpha and PF4, or Gro-beta and PF4 were observed to inhibit myeloid cell proliferation at concentrations which were between 500- and 5000-fold lower than either the IL-8 or PF4 wild-type proteins alone. These chimeric mutants possessed activities that were comparable to or better than the activity observed when IL-8 and PF4 were added together in vitro. One of these highly active chimeric proteins was observed to be 1000-fold more active than either IL-8 or PF4 alone in suppressing not only the proliferation but also the cell cycling of myeloid progenitor cells following intravenous injection of the mutant into mice. Examination of additional IL-8-based mutants in the colony formation assay, which centered on the perturbation of the amino-terminal ``ELR'' motif, resulted in the observation that the highly active IL-8 mutant required both aspartic acid at amino acid residue 4 and either glutamine or asparagine at residue 6. Single mutations at either of these positions resulted in mutants with myelosuppressive activity equivalent to wild-type IL-8. Mutants such as IL-8M1 and IL-8M10 were observed to be significantly reduced in their ability to activate isolated human neutrophils, suggesting that separate mechanisms may exist by which myeloid progenitor cells and neutrophils are affected by chemokines.


INTRODUCTION

Myelopoiesis is a complex, highly regulated process, which is dependent on the action of both positive and negative growth factors to control the proliferation of primitive morphologically indistinct cells from hematopoietic organs to supply functional end-stage blood cells. Factors that stimulate cell growth and differentiation have been well characterized and include the colony-stimulating factors (GM-CSF), (^1)granulocyte colony-stimulating factor, and macrophage colony-stimulating factor), erythropoietin, some of the interleukin family members (e.g. IL-1, IL-3, IL-4, IL-6, IL-9, IL-11) as well as other cytokines including Steel factor 1-3). A number of suppressor molecules have also been identified. These include E-type prostaglandins, H-ferritin, lactoferrin, interferons, tumor necrosis factors, and transforming growth factor-beta (1, 2, 3) . More recently, several members of the chemokine family of proteins including macrophage inflammatory protein-1alpha (MIP-1alpha), MIP-2alpha (Gro-beta), interleukin 8 (IL-8), platelet factor 4 (PF4), monocyte chemotactic and activating peptide (MCAF/MCP-1), and interferon-inducible protein, molecular weight 10,000 (IP10), have been demonstrated to possess inhibitory activity toward the proliferation of immature stem/progenitor cells in vitro and in vivo(4, 5, 6, 7, 8, 9, 10, 11, 12, 13) .

Chemokines are a family of small inducible proteins possessing structural similarities and high amino acid identities(14, 15, 16) . Although activity differences exist between the proteins, all are believed to possess chemoattractant properties for various cell types. The family is subdivided into two groups based on positioning of cysteine residues within the amino-terminal domain. The CXC group (2 cysteines with an intervening amino acid) includes IL-8, Gro-alpha, Gro-beta, NAP-2, PF4, ENA78, and IP10. The three-dimensional structures of IL-8 and PF4 have been solved and show general structural identity(17, 18) . Protein family members that possess the amino acid motif ``ELR'' within the amino terminus have all been observed to elicit potent neutrophil chemoattractant and stimulatory activities. This motif has also been shown to be required for specific interaction with either of the two IL-8 receptor proteins on the surface of neutrophils(19, 20, 21) . The remaining members of the CXC subgroup display a more diverse activity profile, weak or no neutrophil chemoattracting activity, and less sequence homology to the ELR motif containing subgroup. Neither PF4 nor IP10 have demonstrated significant neutrophil-related activities(22, 23, 24, 25) .

The other half of the chemokine family is characterized by the CC motif (two adjacent cysteine residues located within the amino terminus) and displays a much more diverse sequence homology and activity profile. CC chemokines act predominantly on monocytes, although basophils, lymphocytes, and eosinophils have also been reported to be target cells for various CC proteins including RANTES, MIP-1alpha, and MCP-1(26, 27, 28, 29) . Compared to the CXC family, less is understood regarding domains within the proteins which are required for biological activity. However, recent structural information on MIP-1beta should facilitate this understanding(30) .

Activated platelets have been observed to release high concentrations of a high molecular weight proteoglycan complex consisting of chondroitin sulfate and PF4(31) . In addition to high affinity binding and neutralization of heparin, PF4 also has been observed to inhibit angiogenesis, inhibit bone resorption, and reverse the immunosuppressive effect of lymphoma cells(32, 33, 34, 35, 36) . IL-8 has been observed to possess potent chemotactic and stimulating properties toward human neutrophils in vitro and has been shown to bind with high affinity to either of the two cloned human IL-8 receptors in vitro. In addition to these activities, IL-8 and PF4, as well as MIP-1alpha, MCP-1, Gro-beta, and IP10, were all observed to inhibit early myeloid progenitor cell proliferation at equivalent concentrations >25 ng/ml(10, 11) . Several members of the chemokine family, including NAP-2, Gro-alpha, Gro-, RANTES, and MIP-1beta did not possess any inhibitory activities in this assay. A third group of chemokines including Gro-alpha and Gro- (MIP-2beta) blocked the inhibitory activity of IL-8 and PF4(10) . Similarly, MIP-1beta was observed to inhibit the activity of MIP-1alpha(6, 10) . Combinations of any two of the six active chemokines resulted in a synergistic decrease in the amount of each chemokine needed to inhibit proliferation (0.1 ng/ml of each chemokine), suggesting the possibility of a novel mechanism of action on the progenitors(10, 11) . The low concentrations of PF4 and IL-8 required to elicit inhibition suggest the presence of protein-based receptors on the progenitor cells. To address this issue, a series of chimeric IL-8/PF4 mutants were expressed, purified, and tested for inhibitory activity toward immature subsets of myeloid progenitor cells.


MATERIALS AND METHODS

Isolation of Recombinant Proteins

The synthetic genes for human IL-8, PF4, and related mutants were expressed as non-fusion proteins in Escherichia coli (BL21) cells and grown in a 500-ml shaker flask containing 300 µg/ml kanamycin until an absorbance of 0.6 at 600 nm was reached. Cells were induced with isopropyl-1-thio-beta-D-galactopyranoside for 3 h at 37 °C, followed by centrifugation at 14,000 times g for 30 min to pellet the cells. The cell paste was resuspended in 20 ml of 1 times phosphate-buffered saline (Life Technologies, Inc.) and sonicated for 3 min at 4 °C using a Braun-Sonic model 1510 sonicator at 200 watts. Following lysis, the cell suspension was centrifuged for 30 min at 18,000 times g at 4 °C. The precipitate from the centrifugation step was extracted in buffer containing 0.05 M Tris-HCl, pH 8.0, 6 M guanidine HCl, 50 mM dithiothreitol at 25 °C for 1 h. The extracted material was then diluted with a 50-fold excess (v/v) of buffer containing 25 mM sodium acetate, pH 4.0, 8 M urea. This material was centrifuged at 14,000 times g and the supernatant filtered through 0.45-µm nitrocellulose filters. The protein was loaded onto an S-Sepharose column equilibrated in 25 mM sodium acetate, pH 4.0, 8 M urea and the column was washed with 25 mM sodium acetate, pH 4.0, to remove the urea. A second wash was performed using buffer containing 25 mM sodium acetate, pH 4.0, 0.5 M NaCl. The protein was then eluted using buffer containing 50 mM Tris-HCl, pH 8.0, 1 M NaCl. Fractions containing the appropriate chemokine protein were subjected to refolding overnight in the presence of 1 mM oxidized, 2 mM reduced glutathione at 25 °C. Extent of refolding of the proteins was monitored through Poros analytical chromatography. The reduced protein was observed to elute from the Poros column at a different acetonitrile concentration relative to the refolded species. Refolded fractions were pooled and rechromatographed by C4 semi-preparative reverse phase HPLC using a 0-100% acetonitrile gradient in 0.1% trifluoroacetic acid/H(2)O. Peak fractions were pooled and lyophilized for concentration determination. Purity was assessed by Coomassie staining of SDS-polyacrylamide gel electrophoresis, analytical C4 reverse phase HPLC, and amino acid analysis. Small scale purifications typically yielded several milligrams of highly purified (>95% purity) material.

Isolation of Human Neutrophils

For isolation of human neutrophils, typically 22.5 ml of human blood was layered over 10 ml of Ficoll 1119 and 10 ml of Ficoll 1077 in a 50-ml polypropylene conical tube. The blood was centrifuged in a tabletop centrifuge for 20 min at 1800 rpm at 8 °C. Following centrifugation, the neutrophil layer (located just above the pelleted red blood cell layer) was collected, washed in sterile phosphate-buffered saline (without Ca and Mg; Life Technologies, Inc.), and pelleted by centrifugation for 5 min at 1800 rpm at 8 °C. The neutrophil fraction, which contains some contaminating red blood cells, was resuspended in 27 ml of sterile H(2)O, which served to lyse the remaining red blood cells. 3 ml of 10 times phosphate-buffered saline were added to the resuspended cells, which were pelleted by centrifugation at 8 °C for 5 min at 1800 rpm. The pelleted neutrophils were resuspended in 10 ml of PBS and counted. Resuspended cells were kept on ice until needed for chemokine-dependent assays.

Elastase Release Assay

Elastase release from human neutrophils was monitored using the fluorescent substrate MeO-Suc-Ala-Ala-Pro-Val-aminomethylcoumarin as described by Hebert et al.(37) . Isolated human neutrophils were suspended in PBS buffer containing 0.02 M Na(2)HPO(4), pH 7.4, 0.15 M NaCl, 0.2 M Hepes, 1 mg/ml bovine serum albumin, 5 mM glucose, 5 times 10 mg/ml cytochalasin B (5 mg/ml stock in Me(2)SO; Sigma) at a concentration of 2 times 10^6 cells/ml. 0.5 ml aliquots of the suspended neutrophils were added to 0.5 ml of the PBS buffer solution. Following incubation, cells were re-equilibrated at 37 °C for 15 min. Chemokines at varying concentrations were added to the neutrophils while gently mixing. Following addition of the chemokines, the cells were pelleted and 0.75 ml of the resulting supernatant was added to 2.25 ml of PBS in the presence of 5 times 10 mg/ml of the elastase substrate (5 mg/ml stock in Me(2)SO; Peninsula Laboratories, Inc., Belmont, CA). The samples were incubated for 1 h at 37 °C then placed on ice for spectrofluorometric analysis. Samples were excited at 380 nm with emission monitored at 460 nm.

Neutrophil Chemotaxis

The ability of IL-8-derived mutants to elicit chemotaxis of isolated human neutrophils was examined using a 48-well micro chemotaxis chamber with a 5-µm pore size filter (Neuroprobe) as described previously(38) . Typically, 50,000 neutrophils were added per well and chemokine concentration was varied. After a 30-min incubation period at 37 °C, the upper chamber was removed and cells on the filter from the upper chamber were scraped away. The filter was fixed with 100% ethanol, stained with a solution of 0.5% toluidine blue in 3.7% formaldehyde, and counted at 400times magnification.

Binding Studies

IL-8 was iodinated as described previously (39) or purchased from DuPont NEN. A stable transfectant CHO cell line, 4ABCHO33(21) , expressing human neutrophil IL-8 receptor subtype B (huIL8Rb), was used in binding assays to test mutant chemokine binding. Binding was performed as described in (21) .

Colony Formation Assays

As described previously(8, 9) , 1 times 10^5 low density (<1.077 g/cm^3) normal human bone marrow cells were plated in 0.3% agar culture medium with 10% fetal bovine serum (HyClone, Logan, UT) with 100 units/ml recombinant human (rhu) GM-CSF plus 50 ng/ml rhu Steel factor (Immunex Corp., Seattle, WA) in the absence and presence of rhu chemokines for assessment of CFU-GM. For assessment of CFU-GEMM and BFU-E, cells were grown in 0.9% methylcellulose culture medium in the presence of rhu erythropoietin (1-2 units/ml) in combination with 50 ng/ml rhu Steel factor. Three plates were scored per concentration per experiment for CFU-GM, CFU-GEMM, and BFU-E colonies after incubation at 37 °C in lowered (5%) O(2) for 14 days. The combination of GM-CSF and Steel factor or erythropoietin and Steel factor allow detection of large colonies (usually >1000 cells/colony) which come from early, more immature subsets of CFU-GM, CFU-GEMM, and BFU-E. Levels of significance were determined using Student's t distribution (two-tailed test).

In Vivo Testing of Chemokine Proteins

C3H/HeJ and BDF(1) mice were purchased from Jackson Laboratories (Bar Harbor, ME). Mice were injected intravenously with 0.2 ml of saline/mouse or the stated amount of chemokine and sacrificed 24 h later. Femoral bone marrow was removed, treated with or without high specific activity tritiated thymidine, and plated in 0.3% agar cultured medium with 10% fetal bovine serum in the presence of 10% v/v pokeweed mitogen mouse spleen cell cultured medium as described previously(9) . Colonies (>40 cells/aggregate) were scored after 7 days of incubation. The proportion of progenitors in DNA synthesis (S phase of the cell cycle) was estimated using the high specific activity (20 Ci/mM) tritiated thymidine (50 µCi/ml) (DuPont NEN) kill technique and is based on the calculation in vitro of the reduction in the number of colonies formed after pulse exposure of cells for 20 min to ``hot'' tritiated thymidine as compared with control (McCoy's medium or a comparable amount of non-radioactive ``cold'' thymidine).


RESULTS

Generation of IL-8- and PF4-derived Mutants

A series of chemokine mutants, based on either PF4 or IL-8 native sequences were constructed to examine the domains of these proteins, which are involved in suppression of myeloid progenitor cell proliferation. Fig. 1shows the amino acid sequences of the mutant proteins, which were expressed, purified, and tested in the neutrophil-based assays as well as the myeloid progenitor colony formation assays. For IL-8-based mutants, emphasis was placed on regions surrounding the amino-terminal ELR domain. Mutations were also clustered in the region involved in IL-8 dimerization. For the PF4-based mutants, changes within the DLQ motif, located within the amino-terminal domain were examined. A second DLQ motif, located proximal to the putative heparin binding domain at a reverse beta-turn near the carboxyl-terminal domain was also emphasized for mutation. Previously, several groups have reported that peptides containing this motif displayed activity toward suppression of progenitor cell proliferation(13, 40) . Native sequence proteins as well as mutants were expressed as nonfusion proteins in E. coli (Novagen, pET system). Expression was induced using isopropyl-1-thio-beta-D-galactopyranoside, and protein was initially observed as inclusion bodies following lysis of the cells. Proteins were purified from the inclusion bodies by extraction under reducing and denaturing conditions, ion exchange chromatography, a refolding procedure followed by reverse phase HPLC. Correct refolding of the chemokines was monitored by differential retention times using Poros chromatography. Identification of the purified protein was accomplished using amino acid analysis, mass spectrometry, and amino-terminal sequencing. Purity was determined by analytical reverse phase HPLC, mass spectrometry, and SDS-gel electrophoresis.


Figure 1: Amino acid sequences of IL-8, PF4, and related chemokine mutants. Sites of mutation are highlighted for each protein.



Assessment of Neutrophil Activities in Vitro

The ability of each of the chemokine proteins to activate neutrophils was tested using a degranulation assay, which followed chemokine-dependent release of elastase. Fig. 2A shows a summary of the activities of the purified chemokine proteins. IL-8, as well as IL-8M3, M4, M6, M7, and M64 all show significant elastase release activity, although compared to IL-8 wild-type, M4 was less active. The PF4-based mutant, PF4M2, displayed approximately 50% of the activity observed with the native sequence IL-8, demonstrating the requirement of the amino-terminal ELR domain for neutrophil-based activity. Some activity was observed with mutants PF4M1 and IL-8M1 only at concentrations of protein greater than 10M (10 µg/ml). As expected, PF4, PF4-412, PF4-413, PF4-414, and PF4-421 showed no neutrophil elastase release activity at any of the concentrations tested.


Figure 2: A, summary of ability of chemokine mutant proteins to elicit elastase release from human neutrophils in vitro. Chemokines at concentrations of either 10M or 10M (0.1 µg/ml or 1 µg/ml) were added to isolated neutrophils while gently mixing. Extent of elastase release was monitored spectrofluorometrically following cleavage of the fluorogenic substrate as described under ``Materials and Methods.'' Relative potency of each mutant was compared to the amount of cleaved product generated by neutrophil stimulation with equivalent concentrations of IL-8. B, dose-dependent release of elastase from isolated human neutrophils by chemokine mutants. Samples include IL-8 WT, bullet; IL-8M8, circle; IL-8M9, box; IL-8M10, .



Additional IL-8 mutants, designated IL-8M8 (ELQ), IL-8M9 (DLR), and IL-8M10 (DLN), which were developed to examine in greater detail the requirements surrounding the NH(2)-terminal ELR motif, were also tested in the elastase release assay in a concentration-dependent manner (Fig. 2B). As anticipated, all three displayed either significantly reduced activity or no ability to elicit degranulation of the isolated human neutrophils. Neither IL-8M8 or IL-8M10 elicited any release of elastase at concentrations as high as 4 times 10M (40 µg/ml) and 1.25 times 10M (100 µg/ml), respectively. IL-8M9 demonstrated the ability to release elastase, although at concentrations approximately 200-fold greater than for the native sequence IL-8. Perturbation of the ELR motif resulted in profound effects on the ability of these chemokine mutants to function on the neutrophil.

The ability of each of these mutant proteins to elicit chemotaxis of neutrophils was also examined. Each chemokine mutant was tested in a concentration-dependent manner for ability to elicit chemotaxis of isolated human neutrophils in a boyden chamber. Each concentration of each mutant was tested in triplicate in two separate experiments. Each data point was read in triplicate as well, for a total of 18 data points/concentration/chemokine. The results obtained demonstrate a direct correlation between the ability of the chemokine mutants to elicit chemotaxis of neutrophils and the ability to cause neutrophil degranulation as exhibited in the elastase release assay results (Fig. 3, A-D). With the exception of PF4M2, none of the PF4-derived mutants displayed any chemotactic activity toward neutrophils. Similarly, with the exception of IL-8M1, which showed substantially reduced activity, all of the IL-8-derived mutants exhibited potent neutrophil chemotactic activity, although some reduction in activity was also observed for IL-8M4, IL-8M64, and IL-8M7. However, this decrease also correlated with the data obtained in the elastase release assay.


Figure 3: Concentration dependence of chemokine mutants on neutrophil chemotaxis activity in vitro. Experiments were performed as described under ``Materials and Methods.'' A, samples include IL-8 WT, bullet; IL-8M3, circle; PF4 WT, ; IL-8M1, box. B, IL-8 WT, bullet; IL-8M64, circle; PF4M1, ; PF4M2, box. C, IL-8 WT, bullet; IL-8M6, circle; IL-8M4, ; PF4-426, box. D, IL-8 WT, bullet; IL-8M7, circle; PF4-413, ; PF4-421, box.



Binding of the IL-8-derived mutants to CHO cells containing the stably transfected IL-8 receptor subtype B was also performed. The B subtype receptor is able to bind with high affinity to IL-8 as well as other ``ELR''-containing chemokines including Gro-alpha, Gro-beta, and NAP-2. As shown in Table 1, competition binding experiments utilizing I-labeled IL-8 and unlabeled mutant chemokine competitors demonstrated that each of the proteins that was able to activate the neutrophils was also able to bind to the neutrophil receptors. IL-8M1 and PF4M1, which displayed decreased ability to elicit elastase release from the neutrophils, showed a similarly decreased ability to compete with the labeled IL-8 for receptor binding.



In Vitro Chemokine-dependent Suppression of Myeloid Progenitor Proliferation

Chemokines were assessed for the ability of each to suppress the proliferation of progenitor cells derived from the posterior iliac crest of normal healthy volunteers who had given informed consent. Chemokines were tested in a dose-dependent fashion, with concentrations ranging from 100 ng/ml (1 times 10M) down to 0.001 ng/ml (1 times 10M) in the assay. Cells were plated in the presence of rhu GM-CSF (100 units/ml) ± rhu Steel factor (50 ng/ml) for granulocyte-macrophage progenitors (CFU-GM). Chemokines were added at the start of culture and colonies were permitted to develop for 14 days after which they were scored. Each chemokine mutant was tested in at least three separate experiments with three plates being scored per experimental point. The results obtained for the mutant chemokine proteins are summarized in Table 2and demonstrate three distinct categories of mutant activity. Several of the mutants showed little effect of the mutation on activity compared to either wild-type IL-8 or PF4. These include PF4-421 and IL-8M64. Both of these proteins as well as the wild-type PF4 and wild-type IL-8 inhibited progenitor cell proliferation at concentrations beginning between 10 and 25 ng/ml (approximately 1 times 10M). These results are comparable to previously published data(5, 6, 10, 11) .



Several mutants were no longer able to inhibit the proliferation of the myeloid progenitors. Even at concentrations up to 100 ng/ml (1 times 10M), no activity could be detected. These proteins include PF4M1, PF4-412, PF4-413, IL-8M3, IL-8M4, and IL-8M6. Of this group, three distinct types of mutations resulted in loss of activity. IL-8M3, IL-8M4, and IL-8M6 result from changes within the dimer interface region of IL-8. PF4M1 results from a point mutation within the DLQ motif located within the amino-terminal domain. Finally, PF4-412 and PF4-413, result from domain swaps with IL-8 and NAP-2, respectively, at the COOH-terminal DLQ region of PF4.

The third phenotype of chemokine mutant includes proteins possessing enhanced in vitro inhibitory activity toward proliferation of the CFU-GM population. The activities of these proteins, shown in Fig. 4(A and B), are compared to the activities of either IL-8 or PF4 alone. The results are expressed as mean percent change from control ± 1 S.E. These proteins include PF4M2, IL-8M1, IL-8M10, PF4-414, and PF4-426. PF4M2 and PF4-414 were active down to a concentration of 0.01 ng/ml (19 ± 8% and 34 ± 8% inhibition, respectively). The other highly active proteins displayed suppressive activity down to concentrations of 0.001 ng/ml (1 times 10M). Previously, it was observed that combining two individual active chemokines such as PF4 and IL-8 produced inhibitory activity at concentrations of each protein as low as 0.1 ng/ml (1 times 10M)(10) . The results obtained with these proteins suggest that specific mutations produce effects comparable to or better than the synergistic activity previously demonstrated.


Figure 4: Summary of activities of chemokine mutants for in vitro inhibition of CFU-GM. A, comparison of highly active IL-8-derived mutants compared to IL-8 and PF4. Samples include IL-8 WT, ; PF4 WT, box; IL-8M1, circle; IL-8M10, bullet. B, comparison of highly active PF4-derived mutants compared to IL-8 and PF4. Samples include IL-8 WT, ; PF4 WT, box; PF4M2, circle; PF4-426, bullet; PF4-414, up triangle.



In Vivo Activity of Chimeric Chemokine Mutant

One of the highly active chimeric proteins, IL-8M1, was examined for in vivo activity in a murine system using two different strains of mice: C3H/HeJ and BDF(1) (Table 3). Single doses of 10, 1, or 0.01 µg of PF4, IL-8, or IL-8M1 were injected intravenously into mice and progenitor cell proliferation was monitored 24 h later by harvesting of marrow from the femurs as previously reported for MIP-1alpha(9, 41) . Cells were monitored both for total numbers of CFU-GM per femur as well as for the percent of these progenitors that were undergoing cell cycling. PF4, IL-8, and IL-8M1 alone were able to suppress total colony formation at a dose of 10 µg. Similarly, cell cycling was completely inhibited by these proteins at this dose. At a dose of 1 µg, neither IL-8 or PF4 showed any suppressive activity on total colony formation or on the percentage of progenitors in S phase. IL-8M1, however, was active at this dose, with a significant decrease in total colony formation and cell cycling. In vivo activity of IL-8M1 was observed at a dose as low as 0.01 µg/mouse. At this dose of the chimeric mutant, progenitor cell cycling was observed to be inhibited by 69-73% compared to control. The data demonstrate that the chimeric protein is a more potent suppressive agent in vivo on a weight to weight basis for progenitor proliferation than either IL-8 or PF4 by themselves.



Amino-terminal Amino Acid Requirements in IL-8 for Myelosuppression

An additional group of mutant proteins were expressed, purified, and tested in the colony formation assay to determine the role of specific amino acids in the synergistic myelosuppressive activity observed with IL-8M1 (IL-8 ``DLQ''). These proteins include IL-8M8 (IL-8 ``ELQ''), IL-8M9 (IL-8 ``DLR''), and IL-8M10 (IL-8 ``DLN''). These new mutants were tested along with IL-8 wild-type, PF4 wild-type, and IL-8M1 in assays designed to examine the concentration dependence of the inhibition of colony formation in the CFU-GM, CFU-GEMM, and BFU-E lineages. As shown in Table 4, there was no observable differences in activity between cell lineages for any of the chemokine proteins tested, demonstrating a broad chemokine-dependent suppression on multiple progenitor cell populations rather than a lineage specific inhibition. Of the mutants examined, IL-8M8 and IL-8M9 both exhibited suppressive activities comparable to the activities observed with either IL-8 or PF4 wild-type proteins, suggesting that the double mutation within IL-8 is critical toward the enhanced myelosuppressive activity. IL-8M10 was observed to be highly active (comparable to IL-8M1; see Fig. 4A) demonstrating that either glutamine or asparagine are suitable for replacement of arginine at amino acid 6 in IL-8 for the synergistic activity.



Examination of Chemokine Mutant Competitors of Myelosuppression

The mutants that were inactive in the progenitor proliferation assay were also tested for their ability to inhibit the activity of either IL-8 or PF4. Chemokine mutants IL-8M3, IL-8M4, IL-8M6, and PF4-412 were incubated at varying concentrations with either PF4 or IL-8 at a concentration of 50 ng/ml (5 times 10M). Mutants IL-8M4 and PF4-412 had no effect either as suppressors of proliferation of as competitors with either IL-8 or PF4. IL-8M6 was observed to suppress the proliferation of the progenitors at a concentration of 500 ng/ml, demonstrating that it is actually a weak agonist in this system. In the presence of 500, 250, or 50 ng/ml IL-8M3, no suppression of progenitor proliferation was observed. However, at the highest two concentrations, IL-8M3 was able to block the myelosuppressive activity of IL-8. Under identical conditions, this mutant was unable to inhibit the ability of PF4 to suppress progenitor proliferation (Table 4). IL-8M3 is a mutant that contains several amino acids in the dimer interface region from MCP-1. That it inhibits IL-8 and not PF4 suggests that this mutant is able to interact with a cell-based receptor. In addition, the observation suggests that since it only affects IL-8 and not PF4, several different receptors with different specificity are likely to exist on the progenitor cell. Unfortunately, because of the low frequency of progenitor cells in bone marrow (<1/1000), it is not possible to get enough purified progenitors from bone marrow to perform adequate receptor binding studies.


DISCUSSION

A series of chemokine mutants have been cloned, expressed, purified, and evaluated for in vitro myelosuppressive activity. Of the proteins examined, one group of proteins have been identified that are able to inhibit myeloid progenitor cell proliferation at very low concentrations. The activities of these individual mutants appeared comparable to or greater than the activity observed previously when low concentrations of IL-8 and PF4 were added together(10) . These proteins include PF4M2, PF4-414, PF4-426, IL-8M1, and IL-8M10. These synergistic mutants were found to be active at concentrations as low as 0.001 ng/ml (1 times 10M monomer concentration). PF4M2 contains the NH(2)-terminal ELR motif from IL-8 with the remaining COOH-terminal domains from PF4. It has been shown to possess both neutrophil-related activities as well as an ability to bind heparin and inhibit the proliferation of cultured endothelial cells. Conversely, IL-8M1 contains the amino-terminal DLQ motif from PF4 with the remaining COOH-terminal domains from IL-8. This potent mutant displayed significantly reduced neutrophil binding, chemotaxis and activation activities. Comparable to native IL-8, IL-8M1 binds to heparin with an affinity that is significantly reduced relative to PF4. Because this protein is inactive on neutrophils, but highly active on progenitor cells, it is likely that progenitor-related activity occurs via a different mechanism than that which occurs on neutrophils.

IL-8M10 was another highly active mutant in the myeloid progenitor proliferation assay. This mutant contains the sequence DLN as a replacement for ELR in wild-type IL-8. The activity of this mutant is similar to IL-8M1 and demonstrates that either glutamine or asparagine in this position is well tolerated on the progenitor cell. IL-8M9, which contains DLR, displayed an equivalent activity to the wild-type IL-8 and suggests that specific amino acids replacing the arginine residue are likely to result in the highly active phenotype. Similarly, IL-8M8 containing ELQ possessed activity comparable to wild-type IL-8. The results obtained from this mutant would suggest that the aspartic acid at amino acid position 4 is critical for the highly active phenotype. The dramatic difference in activity imposed by the difference of a CH(2) moiety at amino acid 4 between IL-8M1 and IL-8M8, suggests a highly specific interaction must be occurring on the progenitor cell. The conclusion obtained from these mutants suggests that a double mutation of the ELR motif is critical for the highly active phenotype.

PF4-414 contains a sequence from Gro-alpha replacing the second, COOH-terminal DLQ domain from PF4. Unlike similar inactive mutants, that contain domains of IL-8 (PF4-412) or NAP-2 (PF4-413), PF4-414 displayed enhanced activity, comparable to IL-8M1. The region of PF4 encompassing this second DLQ motif is likely to play a role in either maintaining the appropriate protein conformation or in direct interaction with the progenitor cell. The latter hypothesis is currently favored since peptides containing this domain have been previously observed to be active in suppression of progenitor cell proliferation in vitro(13, 40) . Furthermore, analysis of the crystal structure of PF4 predicts that this region of the protein assumes a reverse beta-turn conformation, which is solvent-accessible (17) . It is not currently understood why this mutation would result in a highly active chemokine in the progenitor proliferation assay since Gro-alpha alone was inactive in suppression of progenitor cell proliferation(10) . However, Gro-alpha was observed to block PF4- and IL-8-dependent inhibition of proliferation(10) , suggesting that Gro-alpha is able to bind to the progenitor cell. It is possible that the combination of the DLQ motif from PF4 with the sequence ACLNPASPIVK is sufficient to generate a molecule that possesses an activity analogous to the combination of two of the active chemokine proteins(10) . It is suspected that correct combinations of domains from various chemokine proteins elicit a synergistic activity on myeloid progenitor cells.

This hypothesis is supported by mutant PF4-426. This mutant contains three point mutations, each of which replaces an arginine residue with glutamine. The result is a highly active protein, which on first glance is a simple PF4 mutant. A closer analysis, however, reveals that substitution of the third arginine residue at position 49 with glutamine results in the generation of the sequence IATLKNGQK, which is identical to a sequence within Gro-beta. Gro-beta has been demonstrated previously to be able to synergize with PF4 in the progenitor proliferation assay(10) . The results demonstrate that correctly placed domains that result in chimeric chemokines are able to elicit an enhanced suppressive activity on myeloid progenitor cells.

Another class of mutants appeared either inactive or significantly reduced in inhibitory activity in the assay. All of the IL-8 mutants which contain mutations within the dimerization domain of IL-8 were either inactive or significantly reduced in activity, suggesting that this region and perhaps more specifically the sequence ELRV plays a role in suppression of proliferation of progenitor cells. These three IL-8 mutants all elicited elastase release and were able to chemoattract neutrophils, demonstrating that they are likely to be correctly refolded in a manner analogous to the native sequence IL-8. Although IL-8M3, IL-8M4, and IL-8M6 contain mutations within the dimer interface of IL-8, only IL-8M4 appears to be monomeric in solution at 0.1 mg/ml (1 times 10M) concentration (data not shown). (^2)Another monomeric IL-8 mutant, IL-8M64, possessed equivalent activity as wild-type IL-8 on both neutrophils and progenitor cells, suggesting that oligomeric state may not be a critical factor for activity on myeloid progenitor cells. Furthermore, at concentrations in the range of 10M, wild-type IL-8 is likely to exist predominantly as a monomeric species in solution(42) . The data from this class of mutant suggest that activity may not be oligomeric state-dependent but rather a result of a specific amino acid sequence within the protein or correct protein folding, which is required for myeloid suppression.

Another mutant that lacked the ability to inhibit progenitor proliferation was PF4M1. This protein contains a single point mutation (DLQ to DLR) within the amino-terminal domain. It is unclear whether this amino acid change results in a direct effect on the interaction with the progenitor cells. However, crystal structure data demonstrate that spacially, the DLQ motifs of two PF4 monomers (the A and D subunits) lie adjacent to each other(17) . The glutamine residues in particular are situated side by side in the intact tetramer. Replacement of these glutamine residues with the positively charged arginine groups may result in charge repulsion and an altered oligomeric conformation of the protein. The DLQ motif of PF4 appears to be highly important with regard to activity on the progenitor cells. The region surrounding the COOH-terminal DLQ motif of PF4 also appears important for myeloid cell growth suppression. Two mutants, PF4-412 and PF4-413 were generated, which replace this domain with the analogous regions of either IL-8 or NAP-2, respectively. The resulting loss of activity suggests that this region also is involved either in direct interaction with progenitor cells or is required for proper folding of the protein. Both of these mutants were observed, however, to inhibit endothelial cell proliferation in vitro and to bind heparin at concentrations comparable to wild-type PF4.

Fig. 5is a summary of the domains that have been identified to be involved in this activity. In IL-8, the amino-terminal ELR motif appears to be required for activity, especially if inserted into PF4. The dimer interface region of IL-8 also appears critical for suppressive activity. In PF4 both of the DLQ motifs appear necessary for this protein to inhibit myeloid progenitor proliferation. Loss of either of these domains results in loss of activity of PF4. Combinations of IL-8 and PF4, PF4 and Gro-alpha, as well as PF4 and Gro-beta result in synergistic effects. It is anticipated that other combinations of chemokines may also generate additional synergistic mutants.


Figure 5: Schematic representation of a summary of the chemokine domains necessary for myelosuppression. IL-8-derived domains are depicted in black with PF4-derived domains in gray. Domain 1 is the NH(2)-terminal ELR domain from IL-8. Domain 2 is the dimer interface domain from IL-8. Domain 3 is the amino-terminal DLQ sequence from PF4. Domain 4 is the COOH-terminal domain surrounding the second DLQ domain from PF4.



A number of chemokine receptors have been identified to date, including the two human neutrophil IL-8 receptors and the Duffy antigen on erythrocytes(43, 44, 45) . Recent work by Cacalano et al.(46) has shown that deletion of a murine gene with high homology to the two human IL-8 receptors results in a mouse with a phenotype of elevated levels of B cells, metamyelocytes, band, and mature neutrophils, suggesting that the receptor plays a role in the negative control of development of blood cell components. However, neither of the two identified human IL-8 receptors displays the activity profile with either the mutant chemokines or native sequence chemokine family members that has been observed with the progenitor cells(46) . This would suggest that the neutrophil receptors may not be involved in the regulation of progenitor cell proliferation. Furthermore, no receptor has as yet been identified as being specific for platelet factor 4. Since the activity pattern of the IL-8 and PF4 mutants does not correlate with the activity profile observed on neutrophils, it is possible that a new family of receptors may exist on the progenitors. Furthermore, the observation that IL-8M3 was able to inhibit the suppressive activity of IL-8 but not PF4 suggests that it is not a single receptor, but possibly a family of receptors that are responsible for interaction with each chemokine. One potential model for the mechanism of action of the chemokines on progenitor cells that is supported by our data, in conjunction with work by Broxmeyer et al.(10) , suggests that two or more different occupied receptors, each with a high affinity for a specific chemokine (such as IL-8 or PF4) and a weaker affinity for each of the other active chemokines, interact with each other, leading to signal transduction and suppression of progenitor cell cycling. Since a minimum of two bound receptors with different specificities would be required for this synergistic suppression, it is likely that chimeric chemokines such as IL-8M1 are simultaneously interacting with two distinct receptors with different specificities with high affinity, leading to the synergistic phenotype observed. The apparent weaker activity observed with a single chemokine such as IL-8, may result from specific binding to the high affinity IL-8 receptor and nonspecific binding to a much lower affinity PF4 (or other chemokine) receptor. Further work in this area will provide insight into the mechanism of chemokine-dependent myeloid progenitor cell regulation.


FOOTNOTES

*
These studies were supported in part by United States Public Health Service Grants R37 CA36464 from the National Cancer Institute and Grants RO1 HL46549 and RO1 HL49202 from the National Institutes of Health (to H. E. B.). This publication was also supported in part by Grant 1R43 (A66432-0) from the National Cancer Institute Small Business Innovation Research Program (to T. J. D.). The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore by hereby marked ``advertisement'' in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

§
To whom correspondence should be addressed: Repligen Corp., 1 Kendall Sq., Bldg. 700, Cambridge, MA 02139.

(^1)
The abbreviations used are: GM-CSF, granulocyte/macrophage colony-stimulating factor; IL, interleukin; PF, platelet factor; MIP, macrophage inflammatory protein; MCP, monocyte chemotactic and activating peptide; IP10, interferon-inducible protein (molecular weight 10,000); HPLC, high performance liquid chromatography; PBS, phosphate-buffered saline; CHO, Chinese hamster ovary; CFU, colony-forming unit; BFU-E, burst-forming unit of erythroid progenitor cells; GM, granulocyte/macrophage; GEMM, multipotential cells.

(^2)
T. J. Daly, J. C. Lee, S. Dolich, K. Mayo, J. Barry, L. Zuchowski, and G. L. LaRosa, manuscript in preparation.


REFERENCES

  1. Broxmeyer, H. E. (1992) in Concise Reviews in Clinical and Experimental Hematology (Murphy, M. J., ed) pp. 119-147, Alpha Medical Press, Dayton, OH
  2. Broxmeyer, H. E. (1993) in Clinical Applications of Cytokines: Role in Pathogenesis, Diagnosis, and Therapy (Oppenheim, J. J., Roseo, J. L., and Gearing, A. J. H., eds) pp. 201-230, Oxford University Press, New York
  3. Broxmeyer, H. E. (1995) in Human Cytokines: Their Role in Disease of Therapy (Agarwal, B. B., and Puri, R. K., eds) Blackwell Scientific Publications, Inc., Cambridge, in press
  4. Graham, G. J., Wright, E. G., Hewick, R., Wolpe, S. D., Wilkie, N. M., Donaldson, D., Lorimore, S., and Pragnell, I. B. (1990) Nature 344,442-444 [CrossRef][Medline] [Order article via Infotrieve]
  5. Broxmeyer, H. E., Sherry, B., Lu, L., Cooper, S., Oh, K.-O., Tekamp-Olson, P., Kwon, B. S., and Cerami, A. (1990) Blood 76,1110-1116 [Abstract]
  6. Broxmeyer, H. E., Sherry, B., Cooper, S., Ruscetti, F. W., Williams, D. E., Arosio, P., Kwon, B. S., and Cerami, A. (1991) J. Immunol. 147,2586-2594 [Abstract/Free Full Text]
  7. Dunlop, D. J., Wright, E. G., Lorimore, S., Graham, G. J., Holyoake, T., Kerr, D. J., Wolpe, S. D., and Pragnell, I. B. (1992) Blood 79,2221-2225 [Abstract]
  8. Lord, B. I., Dexter, T. M., Clements, J. M., Hunter, M. A., and Gearing, A. J. H. (1992) Blood 79,2605-2609 [Abstract]
  9. Maze, R., Sherry, B., Kwon, B. S., Cerami, A., and Broxmeyer, H. E. (1992) J. Immunol. 149,1004-1009 [Abstract/Free Full Text]
  10. Broxmeyer, H. E., Sherry, B., Cooper, S., Lu, L., Maze, R., Beckmann, M. P., Cerami, A., and Ralph, P. (1993) J. Immunol. 150,3448-3458 [Abstract/Free Full Text]
  11. Sarris, A. H., Broxmeyer, H. E., Wirthmueller, U., Karasavvas, N., Cooper, S., Lu, L., Krueger, J., and Ravetch, J. V. (1993) J. Exp. Med. 178,1127-1132 [Abstract]
  12. Han, Z. C., Sensebe, L., Abgrall, J. F., and Briere, J. (1990) Blood 75,1234-1239 [Abstract]
  13. Gewirtz, A, M., Calabretta, B., Rucinski, B., Niewiarowski, S., and Xu, W. Y. (1989) J. Clin. Invest. 83,1477-1486 [Medline] [Order article via Infotrieve]
  14. Oppenheim, J. J., Zachariae, C. O., Mukaida, N., and Matsushima, K. (1991) Annu. Rev. Immunol. 9,617-648 [CrossRef][Medline] [Order article via Infotrieve]
  15. Schall, T. (1991) Cytokine 3,165-183 [Medline] [Order article via Infotrieve]
  16. Taub, D. T., and Oppenheim, J. J. (1993) Cytokine 5,175-179 [Medline] [Order article via Infotrieve]
  17. Zhang, X., Chen, L., Bancroft, D. P., Lai, C. K., and Maione, T. E. (1994) Biochemistry 33,8361-8366 [Medline] [Order article via Infotrieve]
  18. Clore, G. M., and Gronenborn, A, M. (1991) J. Mol. Biol. 217,611-620 [Medline] [Order article via Infotrieve]
  19. Moser, B., Dewald, B., Barella, L., Schumacher, C., Baggiolini, M., and Clark-Lewis, I. (1993) J. Biol. Chem. 268,7125-7128 [Abstract/Free Full Text]
  20. Hebert, C. A., Vitangcol, R. V., and Baker, J. B. (1991) J. Biol. Chem. 266,18989-18994 [Abstract/Free Full Text]
  21. LaRosa, G. J., Thomas, K. M., Kaufmann, M. E., Mark, R., White, M., Taylor, L., Gray, G., Witt, D., and Navarro, J. (1992) J. Biol. Chem. 267,25402-25406 [Abstract/Free Full Text]
  22. Walz, A., Dewald, B., von Tscharner, V., and Baggiolini, M. (1989) J. Exp. Med. 170,1745-1750 [Abstract]
  23. Leonard, E. J., Yoshimura, T., Rot, A., Noer, K., Walz, A., Baggiolini, M., Walz, D. A., Goetzl, E. J., and Castor, C. W. (1991) J. Leukocyte Biol. 49,258-261 [Abstract]
  24. Deuel, T. F., Senior, R. M., Chang, D., Griffin, G. L., Heinrikson, R. L., and Kaiser, E. T. (1981) Proc. Natl. Acad. Sci. U. S. A. 78,4584-4587 [Abstract]
  25. Dewald, B., Moser, B., Barella, L., Schumacher, C., Baggiolini, M., and Clark-Lewis, I. (1992) Immunol. Lett. 32,81-83 [CrossRef][Medline] [Order article via Infotrieve]
  26. Leonard, E. J., and Yoshimura, T. (1990) Immunol. Today 11,97-101 [CrossRef][Medline] [Order article via Infotrieve]
  27. Matsushima, K., Larsen, C. G., DuBois, G. C., and Oppenheim, J. J. (1989) J. Exp. Med. 169,1485-1490 [Abstract]
  28. Schall, T. J., Bacon, K., Toy, K. J., and Goeddel, D. V. (1990) Nature 347,669-671 [CrossRef][Medline] [Order article via Infotrieve]
  29. Kuna, P., Reddigari, S. R., Rucinski, D., Oppenheim, J. J., and Kaplan, A. P. (1992) J. Exp. Med. 175,489-493 [Abstract]
  30. Lodi, P. J., Garrett, D. S., Kuszewski, J., Tsang, M. L.-S., Weatherbee, J. A., Leonard, W. J., Gronenborn, A. M., and Clore, G. M. (1994) Science 263,1762-1767 [Medline] [Order article via Infotrieve]
  31. Moore, S., Pepper, D. S., and Cash, J. D. (1975) Biochim. Biophys. Acta 379,370-378 [Medline] [Order article via Infotrieve]
  32. Loscalzo, J., Melnick, B., and Handin, R. I. (1985) Arch. Biochem. Biophys. 240,446-455 [Medline] [Order article via Infotrieve]
  33. Rucinski, D., Niewiarowski, S., James, P., Walz, D. A., and Budzynski, A. Z. (1979) Blood 53,47-62 [Medline] [Order article via Infotrieve]
  34. Maione, T. E., Gray, G. S., Petro, J., Hunt, A. J., Donner, A. L., Bauer, S. I., Carson, H. F., and Sharpe, R. J. (1990) Science 247,77-79 [Medline] [Order article via Infotrieve]
  35. Barone, A. D., Ghrayeb, J., Hammerling, U., Zucker, M. B., and Thorbecke, G. J. (1988) J. Biol. Chem. 263,8710-8715 [Abstract/Free Full Text]
  36. Horton, J. E., Harper, J., and Harper, E. (1980) Biochim. Biophys. Acta 630,459-463 [Medline] [Order article via Infotrieve]
  37. Hebert, C. A., Luscinskas, F. W., Kiely, J.-M., Luis, E. A., Darbonne, W. C., Bennett, G. L., Liu, C. C., Obin, M. S., Gimbrone, M. A., Jr., and Baker, J. B. (1990) J. Immunol. 145,3033-3040 [Abstract/Free Full Text]
  38. Falk, W., Goodwin, R. H., Jr., and Leonard, E. J. (1980) J. Immunol. Methods 33,239-247 [CrossRef][Medline] [Order article via Infotrieve]
  39. Thomas, K. M., Taylor, L., and Navarro, J. (1991) J. Biol. Chem. 266,14839-14841 [Abstract/Free Full Text]
  40. Caen, J. P., Lebeurier, I., Aidoudi, S., Chen, Y. Z., Amiral, J., and Han, Z. C. (1993) Blood 82,162a
  41. Cooper, S., Mantel, C., and Broxmeyer, H. E. (1994) Exp. Hematol. (NY) 22,186-193 [Medline] [Order article via Infotrieve]
  42. Paolini, J. F., Willard, D., Consler, T., Luther, M., and Krangel, M. S. (1994) J. Immunol. 153,2704-2717 [Abstract/Free Full Text]
  43. Horuk, R., Wang, Z., Peiper, S. C., and Hesselgesser, J. (1994) J. Biol. Chem. 269,17730-17733 [Abstract/Free Full Text]
  44. Holmes, W. E., Lee, J., Kuang, W.-J., Rice, G. C., and Wood, W. I. (1991) Science 253,1278-1280 [Medline] [Order article via Infotrieve]
  45. Murphy, P. M., and Tiffany, H. L. (1991) Science 253,1280-1283 [Medline] [Order article via Infotrieve]
  46. Cacalano, G., Lee, J., Kikly, K., Ryan, A. M., Pitts-Meek, S., Hultgren, B., Wood, W. I., and Moore, M. W. (1994) Science 265,682-684 [Medline] [Order article via Infotrieve]

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