Finding Order in Chaos: Quantitative Predictors of Chaos Terrain Morphology on Europa.

The mechanisms for chaos terrain formation on Europa have long been a source of debate in the scientific community. There exist numerous theoretical and numerical models for chaos formation, but to date there has been a lack of quantifiable observations that can be used to constrain models and permit comparison to the outputs of these chaos models. Here, we use mapping and statistical analysis to develop a quantitative description of chaos terrain and their observed morphologies. For nine chaos features, we map every block, or region of pre-existing terrain within disrupted matrix. We demonstrate that chaos terrains follow a continuous spectrum of morphologies between two endmembers, platy and knobby. We find that any given chaos terrain's morphology can be quantified by means of the linearized exponential slope of its cumulative block area distribution. This quantitative metric provides a new diagnostic parameter in future studies of chaos terrain formation and comparison.

Oncogenic mutants of RON and MET receptor tyrosine kinases cause activation of the beta-catenin pathway.

beta-Catenin is an oncogenic protein involved in regulation of cell-cell adhesion and gene expression. Accumulation of cellular beta-catenin occurs in many types of human cancers. Four mechanisms are known to cause increases in beta-catenin: mutations of beta-catenin, adenomatous polyposis coli, or axin genes and activation of Wnt signaling. We report a new cause of beta-catenin accumulation involving oncogenic mutants of RON and MET receptor tyrosine kinases (RTKs). Cells transfected with oncogenic RON or MET were characterized by beta-catenin tyrosine phosphorylation and accumulation; constitutive activation of a Tcf transcriptional factor; and increased levels of beta-catenin/Tcf target oncogene proteins c-myc and cyclin D1. Interference with the beta-catenin pathway reduced the transforming potential of mutated RON and MET. Activation of beta-catenin by oncogenic RON and MET constitutes a new pathway, which might lead to cell transformation by these and other mutant growth factor RTKs.

Anti-apoptotic action of macrophage stimulating protein (MSP).

MSP is a serum protein belonging to the plasminogen-related kringle domain protein family. In addition to macrophages, epithelial cells are also MSP targets. MSP is a multifunctional factor regulating cell adhesion and motility, growth and survival. MSP mediates its biological activities by activating a transmembrane receptor tyrosine kinase called RON in humans or SKT in mice. MSP can protect epithelial cells from apoptosis by activating two independent signals in the PI3-K/AKT or the MAPK pathway. The MAPK pathway mediates the MSP antiapoptotic effect only if additional signaling pathways are activated through adhesion. This indicates that MSP receptors and integrins, the receptors mediating cell-matrix-dependent adhesion, can collaborate in promotion of cell survival. This adhesion-dependent pathway, which is essential for the MAPK-mediated anti-apoptotic effect, remains to be identified. A hypothesis that Stat3 might represent a key component of the adhesion-induced anti-apoptotic pathway is presented in this review.

Cross-talk between RON receptor tyrosine kinase and other transmembrane receptors.

RON is a transmembrane receptor tyrosine kinase that mediates biological activities of Macrophage Stimulating Protein (MSP). MSP is a multifunctional factor regulating cell adhesion, motility, growth and survival. MSP binding to RON causes receptor tyrosine phosphorylation leading to up-regulation of RON catalytic activity and subsequent activation of downstream signaling molecules. Recent studies show that RON is spatially and functionally associated with other transmembrane molecules including adhesion receptors integrins and cadherins, and cytokine and growth factor receptors IL-3 betac, EPOR and MET. For example, MSP-induced cell shape change is mediated via RON-activated IL-3 betac receptor. Activation of integrins causes MSP-independent RON phosphorylation, and the integrin/RON collaboration regulates cell survival. Thus, RON can be activated without MSP by ligand stimulation of RON-associated receptors, and MSP-activated RON can cause ligand-independent activation of RON-associated receptors. As a result of the receptor cross-activation RON-specific pathways become a part of a signal transduction network of other receptors, and conversely signaling pathways activated by other receptors can be used by RON. This receptor collaboration extends the spectrum of cellular responses generated by MSP and by putative ligands of RON-associated receptors. However signaling pathways involved in the receptor cross-talk and underlying activation mechanisms remain to be investigated. The purpose of this review is to summarize data and to discuss a role of cross-talk between RON and other transmembrane receptors.

alpha 1-Antichymotrypsin is the human plasma inhibitor of macrophage ectoenzymes that cleave pro-macrophage stimulating protein.

Macrophage stimulating protein (MSP) is secreted as 78-kDa single chain pro-MSP, which is converted to biologically active, disulfide-linked alphabeta chain MSP by cleavage at Arg(483)-Val(484). Murine resident peritoneal macrophages have two cell surface proteolytic activities that cleave pro-MSP. One is a pro-MSP convertase, which cleaves pro-MSP to active MSP; the other degrades pro-MSP. The degrading protease is inhibited by soybean trypsin inhibitor or by low concentrations of blood plasma, which allows the convertase to cleave pro-MSP to MSP. Using pro-MSP cleavage as the assay, we purified the inhibitor from human plasma. The bulk of the plasma protein was removed by salting out and by isoelectric precipitation of albumin. Highly purified inhibitor was then obtained in three steps: dye-ligand binding and elution, ion exchange chromatography, and high performance liquid chromatography gel filtration. After SDS-polyacrylamide gel electrophoresis and transfer to a polyvinylidene membrane, N-terminal sequencing of the product identified it as alpha(1)-antichymotrypsin. The mean concentration of alpha(1)-antichymotrypsin in human plasma is 7 micrometer. At this concentration, alpha(1)-antichymotrypsin inhibits both macrophage enzymes. A concentration of 0.4 micrometer, which is in the expected concentration range in extracellular fluid, preferentially inhibits the degrading enzyme, which allows for cleavage to active MSP by the pro-MSP convertase.

Gene structure of the human receptor tyrosine kinase RON and mutation analysis in lung cancer samples.

The human RON gene (MST1R) maps to 3p21.3, a region frequently altered in lung cancer and other malignancies. It encodes a receptor tyrosine kinase (RTK) closely related to MET, whose mutations are associated with neoplasia. We investigated whether RON might be involved in the development or progression of lung cancer. We first determined the exon-intron structure of the gene by direct sequencing of RON cosmid DNA and PCR products containing intronic sequences, and then developed primers suitable for mutation analysis by the single-strand conformation polymorphism (SSCP) method. Twenty coding exons were characterized, all but the first one small (average size: 170 bp), a feature shared with other RTK genes. We performed SSCP analysis of RON in small and non-small cell lung cancer samples, upon detection of its expression in a sample of lung cancer cell lines. A mutation (T915C: L296P) was found in an adenocarcinoma specimen. Several single nucleotide polymorphisms were also found. The panel of intron-anchored primers developed in this work will be useful for mutation analysis of the RON gene in different types of human tumors.

Integrin-mediated RON growth factor receptor phosphorylation requires tyrosine kinase activity of both the receptor and c-Src.

Cooperation between integrins and growth factor receptors plays an important role in the regulation of cell growth, differentiation, and survival. The function of growth factor receptor tyrosine kinases (RTKs) can be regulated by cell adhesion to extracellular matrix (ECM) even in the absence of ligand. We investigated the pathway involved in integrin-mediated RTK activation, using RON, the receptor for macrophage-stimulating protein. Adhesion of RON-expressing epithelial cells to ECM caused phosphorylation of RON, which depended on the kinase activity of both RON itself and c-Src. This conclusion is based on these observations: 1) ECM-induced RON phosphorylation was inhibited in cells expressing kinase-inactive c-Src; 2) active c-Src could phosphorylate immunoprecipitated RON from ECM-stimulated cells but not from unstimulated cells; and 3) ECM did not cause RON phosphorylation in cells expressing kinase-dead RON, nor could active c-Src phosphorylate RON immunoprecipitated from these cells. The data fit a pathway in which ECM-induced integrin aggregation causes both c-Src activation and RON oligomerization followed by RON kinase-dependent autophosphorylation; this results in RON becoming a target for activated c-Src, which phosphorylates additional tyrosines on RON. Integrin-induced epidermal growth factor receptor (EGFR) phosphorylation also depended on both EGFR and c-Src kinase activities. This sequence appears to be a general pathway for integrin-dependent growth factor RTK activation.

Two independent signaling pathways mediate the antiapoptotic action of macrophage-stimulating protein on epithelial cells.

In addition to its effects on macrophage function, macrophage-stimulating protein (MSP) is a growth and motility factor for epithelial cells. The growth and survival of epithelial cells generally require two signals, one generated by interaction with extracellular matrix via integrins, the other initiated by a growth factor. Therefore we investigated the effect of MSP on epithelial cell survival. Survival of epithelial cells cultured overnight in serum-free medium was promoted by adhesion, which activated both the phosphatidylinositol 3'-kinase (PI3-K)/AKT and mitogen-activated protein kinase (MAPK) pathways, operating independently of one another. The number of apoptotic cells resulting from inhibition of either pathway alone was approximately doubled by simultaneous inhibition of both pathways. This shows that each pathway made a partial contribution to the prevention of apoptosis. In the presence of an inhibitor of either pathway, MSP increased the activity of the other pathway so that the single uninhibited pathway alone was sufficient to prevent apoptosis. In contrast to the results with adherent cells, although MSP also prevented apoptosis of cells in suspension (anoikis), its effect was mediated only by the PI3-K/AKT pathway. Despite activation of MAPK by MSP, anoikis was not prevented in suspended cells with a blocked PI3-K/AKT pathway. Thus, activation of MAPK alone is not sufficient to mediate MSP antiapoptotic effects. Cell adhesion generates an additional signal, which is essential for MSP to use MAPK in an antiapoptotic pathway. This may involve translocation of MSP-activated MAPK from the cytoplasm into the nucleus, which occurs only in adherent cells. Our results suggest that there is cross talk between cell matrix adhesion and growth factors in the regulation of cell survival via the MAPK pathway. Growth factors induce MAPK activation, and adhesion mediates MAPK translocation from the cytoplasm into the nucleus.

Interaction of macrophage-stimulating protein with its receptor. Residues critical for beta chain binding and evidence for independent alpha chain binding.

Macrophage-stimulating protein (MSP) and hepatocyte growth factor/scatter factor (HGF/SF) are plasminogen-related growth and motility factors that interact with cell-surface protein tyrosine kinase receptors. Each one is a heterodimeric protein comprising a disulfide-linked alpha chain and a serine protease-like beta chain. Despite structural similarities between MSP and HGF, the primary receptor binding site is located on the alpha chain of HGF/SF but on the beta chain of MSP. To obtain insight into the structural basis for MSP beta chain binding, beta chain structure was modeled from coordinates of an existing model of the HGF beta chain. The model revealed that the region corresponding to the S1 specificity pocket in trypsin is filled by the Asn(682)/Glu(648) interacting pair, leaving a shallow cavity for possible beta chain interaction with the receptor. Mutants in this region were created, and their binding characteristics were determined. A double mutation of Asn(682)/Glu(648) caused diminished binding of the beta chain to the MSP receptor, and a single mutation of neighboring Arg(683) completely abolished binding. Thus, this region of the molecule is critical for binding. We also found that at equimolar concentrations of free alpha and beta chains, alpha chain binding to receptor was detectable, at levels considerably lower than beta chain binding. The EC(50) values determined by quantitative enzyme-linked immunosorbent assay are 0.25 and 16.9 nM for beta and alpha chain, respectively. The data suggest that MSP has two independent binding sites with high and low affinities located in beta and alpha chain, respectively, and that the two sites together mediate receptor dimerization and subsequent activation.

Macrophage stimulating protein-induced epithelial cell adhesion is mediated by a PI3-K-dependent, but FAK-independent mechanism.

Macrophage stimulating protein (MSP) is a growth and motility factor that mediates its activity via the RON/STK receptor tyrosine kinase. MSP promotes integrin-dependent epithelial cell migration, which suggests that MSP may regulate integrin receptor functions. Integrins are cell surface receptors for extracellular matrix. Epithelial cell adhesion and motility are mediated by integrins. We studied the enhancement by MSP of cell adhesion and the molecular mechanisms mediating this effect. MSP decreased the time required for adhesion of 293 and RE7 epithelial cells to substrates coated with collagen or fibronectin. Prevention of adhesion by an RGD-containing peptide showed that the cell-substrate interaction was mediated by integrins. Wortmannin, an inhibitor of phosphatidylinositol 3-kinase (PI3-K), blocked MSP-dependent adhesion, which shows that PI3-K is in the MSP-induced adhesion pathway. MSP also affected focal adhesion kinase (FAK) which is important for some types of cell adhesion and motility. Although MSP caused PI3-K-independent tyrosine phosphorylation and activation of FAK, experiments with dominant-negative FAK constructs showed that FAK does not mediate the effects of MSP on cell adhesion or motility. Thus PI3-K, but not FAK, mediates MSP-induced integrin-dependent adhesion of epithelial cells. Also, we found ligand-independent association between RON and beta1 integrin, which is additional evidence for a relationship between these two receptor systems.

Characterization of free alpha- and beta-chains of recombinant macrophage-stimulating protein.

Human serum macrophage-stimulating protein (MSP) induces motile activity of murine resident peritoneal macrophages and is a growth and motility factor for epithelial cells. It belongs to the plasminogen-related family of kringle proteins, and is secreted as a single-chain, 78-kDa, biologically inactive pro-MSP. Proteolytic cleavage of pro-MSP at a single site yields active MSP, a disulfide-linked alphabeta-chain heterodimer. However cleavage of recombinant pro-MSP yielded not only the disulfide-linked heterodimer, but also free alpha- and beta-chains, indicating that some of the recombinant molecules lacked an alphabeta-chain disulfide. We purified the free chains for characterization. The beta-chain of MSP has three extra cysteines, Cys527, Cys562, and Cys672, which are not found in the plasminogen beta-chain. Disulfide bond analysis showed a Cys527-Cys562, but also a Cys588-Cys672. Coopting Cys588 by Cys672 prevented the expected formation of a disulfide between alpha-chain Cys468 and beta-chain Cys588. Concomitant studies determined structures of oligosaccharides at the three Asn-linked glycosylation sites of MSP. The oligosaccharides at the three Asn loci are heterogeneous; 11 different sugars were identified, all being sialylated fucosyl biantennary structures. We also located the pro-MSP signal peptide cleavage site at Gly18-Gln19 and the scissile bond for formation of mature MSP at Arg483-Val484.

Kinases involved in MSP/RON signaling.

Macrophage stimulating protein (MSP) belongs to the plasminogen-related kringle domain family. In addition to stimulation of macrophages, MSP acts on other cell types including epithelial and hematopoietic cells. The MSP receptor is a transmembrane tyrosine kinase called RON in humans and STK in mice. MSP/receptor interaction induces activation of signal transduction pathways that mediate MSP biological activities. Cytoplasmic kinases are intracellular messengers occupying an important role in signal transduction. We have identified kinases that participate in RON signaling. In addition to previously identified involvement of phosphatidylinositol 3-kinase (PI3-K), JNK, and MAPK, we found that FAK, c-Src, and AKT are rapidly and transiently activated by MSP. FAK, MAPK, and c-Src are involved in MSP-induced cell proliferation. MAPK and c-Src are components of one signal transduction cascade, and MAPK is downstream of c-Src. FAK also regulates MSP-induced cell growth, but via a path different from c-Src/MAPK. AKT kinase is a component of a separate branch of the RON/PI3-K pathway that mediates the MSP anti-apoptotic effect on epithelial cells. PI3-K regulates MSP-induced adhesion and motility but via downstream components different from AKT. Thus, occupancy of the RON receptor by MSP activates distinct signal transduction pathways that mediate several cellular responses.

Proteolytic cleavage and activation of pro-macrophage-stimulating protein and upregulation of its receptor in tissue injury.

Macrophage stimulating protein (MSP) exists in blood as inactive pro-MSP. Cleavage yields active MSP, the ligand for a membrane receptor (RON) that is expressed on keratinocytes as well as macrophages. Because both cells have roles in tissue injury, we looked for active MSP and expressed RON in wounds. Concentration of pro-MSP + MSP in wound exudates was in the range for optimal activity. Western blot showed that MSP comprised about half the total, in contrast to less than 10% of the total in blood plasma. The presence of MSP was attributed to an exudate pro-MSP convertase that had an inhibitor profile consistent with a trypsin-like serine protease. Exudate evoked morphologic changes in macrophages in vitro like that of MSP. Removal of this activity by an anti-MSP column shows that exudate stimulation of macrophages is due to MSP. RON was infrequently detected in normal skin. RON protein was markedly upregulated in burn wound epidermis and accessory structures, in proliferating cells or differentiated cells, or both. RON was also detected on macrophages and capillaries. Tissue injury leads to cleavage of pro-MSP to MSP, which has potential to act on keratinocytes, macrophages, and capillaries, all components of the wound healing response.

Mode of receptor binding and activation by plasminogen-related growth factors.

Hepatocyte growth factor/scatter factor (HGF/SF) and macrophage stimulating protein (MSP) are plasminogen-related kringle proteins that lost serine protease domain enzymatic activity and became ligands for cell surface tyrosine kinase receptors. They are activated by cleavage to disulfide-linked alphabeta chains. Surprisingly, despite structural similarities, the high affinity receptor binding regions of the two proteins are different: alpha chain for HGF, and beta chain for MSP. We propose that after cleavage exposes a beta chain binding site (high affinity for MSP, low affinity for HGF), monomeric ligand induces receptor dimerization and activation via alpha and beta chain binding sites of different affinity.

Macrophage stimulating protein (MSP) binds to its receptor via the MSP beta chain.

Macrophage stimulating protein (MSP) is a 78-kDa disulfide-linked heterodimer belonging to the plasminogen-related kringle protein family. MSP activates the RON receptor protein-tyrosine kinase, which results in cell migration, shape change, or proliferation. A structure-activity study of MSP was performed using pro-MSP, MSP, MSP alpha and beta chains, and a complex including the first two kringles and IgG Fc (MSP-NK2). Radioiodinated MSP and MSP beta chain both bound specifically to RON. The Kd of 1.4 nM for MSP beta chain is higher than the reported Kd range of 0.6-0.8 nM for MSP. Pro-MSP, MSP alpha chain, and MSP-NK2 did not bind. Only MSP stimulated RON autophosphorylation. Although the beta chain bound to RON and partially inhibited MSP-induced RON phosphorylation in kidney 293 cells, it did not induce RON phosphorylation. Pro-MSP, MSP alpha chain, or MSP-NK2 failed to activate RON, consistent with their inability to bind to the RON receptor. Functional studies showed that only MSP induced cell migration, and shape change in resident macrophages, and growth of murine keratinocytes. Our data indicate that the primary receptor binding domain is located in a region of the MSP beta chain, in contrast to structurally similar hepatocyte growth factor, in which the receptor binding site is in the alpha chain. However, full activation of RON requires binding of the complete MSP disulfide-linked alphabeta chain heterodimer.

Biological aspects of macrophage-stimulating protein (MSP) and its receptor.

Macrophage-stimulating protein (MSP; also known as HGF-like protein [HGFl]) is a 78 kDa plasma protein that is secreted by the liver into the circulation as single-chain, biologically inactive pro-MSP. The presence of conserved triple disulfide loops (kringles) places pro-MSP in a family of coagulation system serine protease zymogens that are activated by proteolytic cleavage. Although pro-MSP has lost enzymic activity, it has retained the activation mechanism, in that proteolytic cleavage at a single site yields biologically active disulfide-linked alpha beta-chain heterodimeric MSP. The MSP receptor is a transmembrane protein tyrosine kinase. MSP causes phosphorylation of the receptor cytoplasmic domain, association of phosphatidylinositol (PI)-3 kinase with the receptor, and phosphorylation of receptor-bound PI-3 kinase. Inhibition of PI-3 kinase by wortmannin prevents MSP action on cells. MSP stimulates motility of murine resident peritoneal macrophages. However, it does not act on exudate macrophages or blood monocytes, since these earlier maturational stages of the lineage do not express the receptor. MSP also stimulates keratinocyte cell lines, causing either chemotactic responses or increased cell numbers in culture. We suggest that pro-MSP diffuses into local tissue sites, where proteolytic cleavage to MSP results in stimulation of keratinocytes and macrophages. It possibly plays a role in tissue injury or wound healing.

Requirement of phosphatidylinositol-3 kinase for epithelial cell migration activated by human macrophage stimulating protein.

Macrophage stimulating protein (MSP) is a ligand for the RON receptor protein tyrosine kinase. Activation of RON in murine resident macrophages results in cell shape change and migration. We studied cell movement induced by MSP in different types of human epithelial cells and the possible role of phosphatidylinositol-3 (PI-3) kinase in RON-mediated signal transduction. We observed specific and saturable binding of 125I-MSP to RON on several epithelial cell lines. In addition to activation and phosphorylation of RON, MSP also induced tyrosine phosphorylation of the PI-3 kinase p85 subunit in a time-dependent manner, with a peak at 15 min. Moreover, phosphorylated RON formed a complex with PI-3 kinase in both HK-NOC keratinocyte and RON cDNA-transfected MDCK cells. An in vitro protein interaction assay confirmed that PI-3 kinase from a lysate of MSP-activated cells bound to pure RON protein. MSP, at a concentration range of 1 to 5 nM, induced migration of three epithelial cell lines. This effect was inhibited by wortmannin, a specific inhibitor for PI-3 kinase, with an IC50 of 10 nM. MSP-induced shape change in murine resident peritoneal macrophages was also abolished by wortmannin. These data suggest that activation of PI-3 kinase is required for MSP-induced epithelial cell migration. The stimulation by MSP of epithelial cell movement may have implications for tissue repair, wound healing, and tumor metastasis.

Hepatic catabolism of intravenously administered pro-macrophage-stimulating protein in mice.

We injected 125I-pro-macrophage-stimulating protein (pro-MSP) intravenously into normal mice to determine its clearance from the circulation and to test for conversion of pro-MSP to the biologically active heterodimer in the absence of inflammation or tissue injury. Pro-MSP was cleared from the circulation with a half-life of approximately 100 min. This rapid clearance was not peculiar to 125I-pro-MSP, since clearance rates of unlabeled pro-MSP and of 125I-bovine serum albumin were comparable. The liver was the major locus of radioactivity 10-20 min after the intravenous injection of 125I-pro-MSP. By 90 min, over 60% of total recovered radioactivity was in the small intestine. Reflecting gastrointestinal transit, counts decreased in the small intestine and appeared in the colon by 180 min. Essentially all counts in urine and feces obtained at later times were soluble in trichloracetic acid. These findings reflected rapid hepatic proteolysis of pro-MSP to fragments undetectable by antibody to pro-MSP; within 20 min after intravenous administration, immunoprecipitable counts were only 22% of the total liver extract radioactivity. Comparison of sodium dodecyl sulfate-polyacrylamide gel electrophoresis and radioautography data for immunoprecipitated plasma and liver extract revealed no evidence for hepatic conversion of pro-MSP to MSP. Thus, the hepatic catabolic pathway of pro-MSP is degradative and does not yield mature MSP. The results support our view that MSP is not released into the circulation but is generated at specific extravascular loci by pro-MSP convertases.

Macrophage-stimulating protein, a ligand for the RON receptor protein tyrosine kinase, suppresses myeloid progenitor cell proliferation and synergizes with vascular endothelial cell growth factor and members of the chemokine family.

Macrophage-stimulating protein (MSP), originally identified as an inducer of murine resident macrophage responsiveness to chemoattractants, is a ligand for human RON/murine STK receptor protein tyrosine kinases. Since STK was cloned from populations enriched for hematopoietic stem cells, we initiated studies on the effects of MSP on colony formation by granulocyte-macrophage (CFU-GM), erythroid (BFU-E), and multipotential (CFU-GEMM) myeloid progenitor cells. MSP alone had no colony stimulating activity. However, MSP caused about a 50% suppression of CFU-GM colony formation induced by synergistic combinations of SLF or Flt-L plus GM-CSF, G-CSF, or IL-3 and of BFU-E and CFU-GEMM colonies induced by SLF or Flt3-L plus Epo or Epo and IL-3. In contrast, MSP had no effect on progenitors stimulated by one growth factor. MSP also suppressed colony formation by stimulated cord blood progenitors, but only after preinduction to a rapidly cycling state. It was previously reported that several members of the chemokine family synergistically suppress myeloid progenitor proliferation. Likewise, synergistic suppression was observed when MSP was paired with VEGF, MIP-1 alpha, IL-8, PF4, MCP-1, IP-10, or ENA-78, or when VEGF was paired with the chemokines; and the required MSP concentration was more than 100-fold less than for MSP alone. Additionally, MSP or VEGF inhibited proliferation of the human myeloid growth factor-dependent cell line, M07e, but a sustained effect required multiple additions over time. At the least, some of the MSP suppressive effects on myeloid progenitors, as assessed on single isolated CD34 marrow cells, appeared to be directly on the progenitors; sustained additions of MSP were required to see this effect. The suppressive action of MSP and its synergism with proteins of the chemokine family may be of relevance to regulation of blood cell production.