The enhanced in vitro hematopoietic activity of leridistim, a chimeric dual G-CSF and IL-3 receptor agonist.

The in vitro activity of leridistim was characterized for cell proliferation, generation of colony-forming units (CFU) and differentiation of CD34+ cells. In AML-193.1.3 cells, leridistim exhibited a significant increase in potency compared to rhG-CSF, SC-65303 (an IL-3 receptor agonist) or an equimolar combination of rhG-CSF and SC-65303. CFU-GM assays demonstrated that at 50% of the maximum response, the relative potency of leridistim was 12-fold greater than the combination of rhG-CSF and rhIL-3 and 44-fold more potent than rhG-CSF alone. In multi-lineage CFU assays, a combination of erythropoietin (rhEPO) and leridistim resulted in greater numbers of BFU-E, CFU-GEMM and CFU-Mk than rhEPO alone. Ex vivo culture of peripheral blood or bone marrow CD34+ cells with leridistim substantially increased total viable cells over cultures stimulated with rhG-CSF, SC-65303, or a combination of rhG-CSF and SC-65303. Culture with leridistim, resulted in a greater increase in myeloid (CD15+/CD11b+), monocytic (CD41-/CD14+) and megakaryocytic (CD41+/CD14-) precursor cells without depleting the progenitor pool (CD34+/CD15-/CD11b-). These results demonstrate that leridistim is a more potent stimulator of hematopoietic proliferation and differentiation than the single receptor agonists (rhG-CSF and SC-65303) either alone or combined. These unique attributes suggest that leridistim may enhance hematopoietic reconstitution following myelosuppressive chemotherapy.

Promegapoietin, a family of chimeric growth factors, supports megakaryocyte development through activation of IL-3 and c-Mpl ligand signaling pathways.

OBJECTIVE: The signaling pathways induced by promegapoietin (PMP), a family of chimeric growth factors that activate the human IL-3 and c-Mpl receptors, were investigated. METHODS: The biological activity of PMP was examined by receptor binding, cell proliferation, ex vivo expansion of hematopoietic progenitor cells, and in vivo production of platelets. The activation of signaling pathways was examined by Western blot and Northern blot analyses. RESULTS: Two PMP molecules, PMP-1 and PMP-1a, induced proliferation of cells expressing the IL-3 receptor, c-Mpl, or both receptors and bound to the IL-3 receptor and c-Mpl with high affinity. Ex vivo expansion assays using human bone marrow CD34(+) cells suggested that PMP-1 induced greater total cellular expansion as well as expansion of CD41(+) megakaryocytic precursor cells than IL-3 or c-Mpl ligand alone. Subcutaneous administration of 50 microg/kg of PMP-1 for 10 days to rhesus monkeys resulted in increased platelet production in vivo from a baseline of 357 +/- 45 x 10(3) cells/mL to 1376 +/- 151 x 10(3) cell/mL. PMP-1 induced phosphorylation of the beta(c) subunit of IL-3 receptor and c-Mpl, JAK2, and STAT5b, but not STAT3. PMP-1 induced greater expression of Pim-1, c-Myc, and cyclin D2 than did either an IL-3 receptor agonist or c-Mpl receptor agonist alone. The magnitude of induction of early response genes was similar for PMP and the coaddition of IL-3 receptor agonist and c-Mpl receptor agonist. CONCLUSION: PMP combines the biological activities of IL-3 and c-Mpl ligand in a single molecule that can simultaneously activate signaling pathways induced by both these ligands.

Multiple conformations of a human interleukin-3 variant.

Interleukin-3 (IL-3) is a cytokine that stimulates the proliferation and differentiation of hematopoietic cells. The hyperactive hIL-3 variant SC-55494 was shown to have at least two major conformations by high-resolution NMR spectroscopy. Mutants of SC-55494 were constructed in which alanine was substituted for proline in order to test the hypothesis that proline cis-trans isomerization is the source of the observed conformational heterogeneity, as well as to evaluate the effect of prolyl peptide bond configuration on biological activity. NMR spectra of four single proline-to-alamine mutants (P30A, P31A, P33A, and P37A) retain doubled resonances, while spectra of the double mutant P30A/P31A and the quadruple mutant P30A/P31A/P33A/ P37A are substantially free of heterogeneity. These observations suggest that the two major conformations in SC-55494 correspond to cis and trans isomers of either or both of the R29-P30 and P30-P31 peptide bonds. All six mutants had somewhat lower cell proliferative activity than SC-55494, with relative activities ranging from 40 to 80%. The P37A mutant has a binding affinity to the low-affinity IL-3 receptor alpha-subunit statistically equivalent to SC-55494, while P30A, P31A, and P33A each had about two-fold decreases, and P30A/P31A and P30A/P31A/P33A/P37A had four-fold decreases. These findings suggest an important role for the cis configuration of either or both of the R29-P30 and P30-P31 peptide bonds in IL-3 for optimal interaction with the receptor alpha-subunit.

Effects of Histoplasma capsulatum on murine macrophage functions: inhibition of macrophage priming, oxidative burst, and antifungal activities.

Histoplasma capsulatum yeast cells fail to trigger an oxidative burst response in normal murine macrophages. The results of this study, in which an in vitro assay of macrophage antifungal effects was used, extend these findings. During 18 h of incubation, unprimed elicited murine macrophages inhibited H. capsulatum growth only when macrophages were present in great excess. Gamma interferon (IFN-gamma)-primed macrophages showed enhanced fungal growth inhibition but a similar requirement for an excess of phagocytes. Macrophages containing heat-killed H. capsulatum exhibited diminished antifungal effects toward viable H. capsulatum and Saccharomyces cerevisiae cells. Parallel experiments showed no comparable effect of ingested latex particles on macrophage antifungal activity. Using chemiluminescence as a measure of the oxidative burst, we found that macrophages primed in vitro with IFN-gamma alone failed to exhibit a significant response to triggering by H. capsulatum yeast cells unless a second priming agent (tumor necrosis factor alpha or bacterial lipopolysaccharide) was added to IFN-gamma. Furthermore, macrophage priming with single agents was blocked by the prior ingestion of heat-killed H. capsulatum. These studies provide evidence that ingestion of H. capsulatum yeast cells can induce a prompt and enduring deactivation of murine macrophages.

Amphotericin B selectively stimulates macrophages from high responder mouse strains.

Lymphoid cells from most inbred mouse strains respond to amphotericin B (AmB)-induced immunostimulation. However, C57BL/6 mice and related strains display low or absent lymphoid cell stimulation by AmB and enhanced susceptibility to AmB toxicity. Experiments reported here show that in vitro incubation with AmB can stimulate AKR (AmB-high responder strain) macrophage proliferation. Intraperitoneal injection of AKR mice with AmB also elicits a population of macrophages primed for enhanced oxidative burst activity after triggering by zymosan particles. Under the same experimental conditions, AmB elicits a population of very weakly responsive macrophages from C57BL/6 mice. The low responsiveness of C57BL/6 macrophages correlates with previous observations that AmB is a potent immunoadjuvant and B cell mitogen in most inbred strains, but it selectively lacks immunoadjuvant effects in C57BL/6 mice and it also fails to induce polyclonal B cell stimulation in their spleen cell suspensions. Similarly, in measurements of protein synthesis in vitro, high concentrations of AmB produce a greater inhibition of protein synthesis in C57BL/6 peritoneal macrophages than in parallel cultures of AKR macrophages. These findings support the hypothesis that the macrophage is an important target cell in the mediation of AmB-induced immunomodulation.

Circular permutation of granulocyte colony-stimulating factor.

The sequence of granulocyte colony-stimulating factor (G-CSF) has been circularly permuted by introducing new chain termini into interhelical loops and by constraining the N- and C-terminal helices, either by direct linkage of the termini (L0) or by substitution of the amino-terminal 10-residue segment with a seven-residue linker composed of glycines and serines (L1). All the circularly permuted G-CSFs (cpG-CSFs) were able to fold into biologically active structures that could recognize the G-CSF receptor. CD and NMR spectroscopy demonstrated that all of the cpG-CSFs adopted a fold similar to that of the native molecule, except for one [cpG-CSF(L1)[142/141]] which has the new termini at the end of loop 34 with the shorter L1 linker. All of the cpG-CSFs underwent cooperative unfolding by urea, and a systematically lower free energy change (DeltaGurea) was observed for molecules with the shorter L1 linker than for those molecules in which the original termini were directly linked (the L0 linker). The thermodynamic stability of the cpG-CSFs toward urea was found to correlate with their relative ability to stimulate proliferation of G-CSF responsive cells. Taken together, these results indicate that the G-CSF sequence is robust in its ability to undergo linear rearrangement and adopt a biologically active conformation. The choice of linker, with its effect on stability, seems to be important for realizing the full biological activity of the three-dimensional structure. The breakpoint and linker together are the ultimate determinants of the structural and biological profiles of these circularly permuted cytokines. In the following paper [McWherter, C. A., et al. (1999) Biochemistry 38, 4564-4571], McWherter and co-workers have used circularly permuted G-CSF sequences to engineer chimeric dual IL-3 and G-CSF receptor agonists in which the relative spatial orientation of the receptor agonist domains is varied. Interpreting the differences in activity for the chimeric molecules in terms of the connectivity between domains depends critically on the results reported here for the isolated cpG-CSF domains.

Circular permutation of the granulocyte colony-stimulating factor receptor agonist domain of myelopoietin.

Myelopoietins (MPOs) are a family of engineered dual interleukin-3 (IL-3) and granulocyte colony-stimulating factor (G-CSF) receptor agonists that are superior in comparison to the single agonists in their ability to promote the growth and maturation of hematopoietic cells of the myeloid lineage. A series of MPO molecules were created which incorporated circularly permuted G-CSF (cpG-CSF) sequences with an IL-3 receptor (IL-3R) agonist moiety attached at locations that correspond to the loops that connect the helices of the G-CSF four-helix bundle structure. The cpG-CSF linkage sites (using the original sequence numbering) were residue 39, which is at the beginning of the first loop connecting helices 1 and 2; residue 97, which is in the turn connecting helices 2 and 3; and residues 126, 133, and 142, which are at the beginning, middle, and end, respectively, of the loop connecting helices 3 and 4. The N- and C-terminal helices of each cpG-CSF domain were constrained, either by direct linkage of the termini (L0) or by replacement of the amino-terminal 10-residue segment with a seven-residue linker composed of SGGSGGS (L1). All of the MPO molecules stimulated the proliferation of both IL-3-dependent (EC50 = 13-95 pM) and G-CSF-dependent (EC50 = 35-710 pM) cell lines. MPOs with the IL-3R agonist domain linked to cpG-CSFs in the first (residue 39) or second (residue 133) long overhand loops were found by CD spectroscopy to have helical contents similar to that expected for a protein comprised of two linked four-helix bundles. The MPOs retained the ability to bind to the IL-3R with affinities similar to that of the parental MPO. Using both a cell surface competitive binding assay and surface plasmon resonance detection of binding kinetics, the MPOs were found to bind to the G-CSF receptor with low nanomolar affinities, similar to that of G-CSF(S17). In a study of isolated cpG-CSF domains [Feng, Y., et al. (1999) Biochemistry 38, 4553-4563], domains with the L1 linker had lower G-CSF receptor-mediated proliferative activities and conformational stabilities than those which had the L0 linker. A similar trend was found for the MPOs in which the G-CSFR agonist activity is mostly a property of the cpG-CSF domain. Important exceptions were found in which the linkage to the IL-3R agonist domain either restored (e.g., attachment at residue 142) or further decreased (linkage at residue 39) the G-CSFR-mediated proliferative activity. MPO in which the IL-3R agonist domain is attached to the cpG-CSF(L1)[133/132] domain was shown to be more potent than the coaddition of the IL-3R agonist and G-CSF in stimulating the production of CFU-GM colonies in a human bone marrow-derived CD34+ colony-forming unit assay. Several MPOs also had decreased proinflammatory activity in a leukotriene C4 release assay using N-formyl-Met-Leu-Phe-primed human monocytes. It was found that circular permutation of the G-CSF domain can alter the ratio of G-CSFR:IL-3R agonist activities, demonstrating that it is a useful tool in engineering chimeric proteins with therapeutic potential.