Abnormalities of bone marrow mesenchymal cells in multiple myeloma patients

Cells migrating within tissues may encounter multiple chemoattractant signals in complex spatial and temporal patterns. To understand leukocyte navigation in such settings, we have explored the migratory behavior of neutrophils in model scenarios where they are presented with two chemoattractant sources in various configurations. We show that, over a wide range of conditions, neutrophils can migrate “down” a local chemoattractant gradient in response to a distant gradient of a different chemoattractant. Furthermore, cells can chemotax effectively to a secondary distant agonist after migrating up a primary gradient into a saturating, nonorienting concentration of an initial attractant. Together, these observations suggest the potential for cells' step-by-step navigation from one gradient to another in complex chemoattractant fields. The importance of such sequential navigation is confirmed here in a model system in which neutrophil homing to a defined domain (a) requires serial responses to agonists presented in a defined spatial array, and (b) is a function of both the agonist combination and the sequence in which gradients are encountered. We propose a multistep model of chemoattractant-directed migration, which requires that leukocytes display multiple chemoattractant receptors for successful homing and provides for combinatorial determination of microenvironmental localization.

We have identified two RHAMM (receptor for hyaluronan-mediated motility) isoforms that encode an alternatively spliced exon 4 (Hall, C. L., Yang, B., Yang, X., Zhang, S., Turley, M., Samuel, S., Lange, L. A., Wang, C., Curpen, G. D., Savani, R. C., Greenberg, A. H., and Turley, E. A. (1995) Cell 82, 19-26 and Wang, C., Entwistle, J., Hou, G., Li, Q., and Turley, E. A. (1996) Gene 174, 299-306). One of these, RHAMM variant 4 (RHAMMv4), is transforming when overexpressed and regulates Ras signaling (Hall et al.). Here we note using flow cytometry and confocal analysis that RHAMM isoforms encoding exon 4 occur both on the cell surface and in the cytoplasm. Epitope-tagging experiments indicate that RHAMMv4 occurs only in the cytoplasm. Several observations suggest that both cell surface RHAMM isoforms and RHAMMv4 are involved in regulating extracellular-regulated kinase (ERK) activity. Affinity-purified anti-RHAMM exon 4 antibodies block the ability of platelet-derived growth factor to activate ERK, and these reagents modify the protein tyrosine phosphorylation profile of proteins resulting from treatment with platelet-derived growth factor. A dominant negative form of RHAMMv4 inhibits mutant active Ras activation of ERK and coimmunoprecipitates with both mitogen-activated protein kinase kinase and ERK, suggesting that the intracellular RHAMMv4 acts downstream of Ras, possibly at the level of mitogen-activated protein kinase kinase-ERK interactions. Consistent with this, overexpression of RHAMMv4 constitutively activates ERK. These results identify a novel mechanism for the regulation of the Ras-ERK signaling pathway and suggest that RHAMM plays multiple roles in this regulation.

Hyaluronan is a high molecular weight glycosaminoglycan found in the extracellular matrix of many tissues, where it is believed to promote cell migration and proliferation. It was recently shown that hyaluronan-dependent pericellular matrix formation is a rapid process that occurs as cells detach during mitosis. Growing evidence for intracellular hyaluronan in tissues in vivo, together with evidence of intracellular hyaluronan binding molecules, prompted us to examine hyaluronan distribution and uptake as well as hyaluronan binding sites in cells and their relationship to cell proliferation in vitro, using a biotinylated hyaluronan binding protein and fluorescein-labeled hyaluronan. In permeabilized smooth muscle cells and fibroblasts, hyaluronan staining was seen in the cytoplasm in a diffuse, network-like pattern and in vesicles. Nuclear hyaluronan staining was observed and confirmed by confocal microscopy and was often associated with nucleoli and nuclear clefts. After serum stimulation of 3T3 cells, there was a dramatic increase in cytoplasmic hyaluronan staining, especially during late prophase/early prometaphase of mitosis. In contrast, unstimulated cells were negative. There was a pronounced alteration in the amount and distribution of hyaluronan binding sites, from a mostly nucleolar distribution in unstimulated cells to one throughout the cytoplasm and nucleus after stimulation. Exogenous fluorescein-labeled hyaluronan was taken up avidly into vesicles in growing cells but was localized distinctly compared to endogenous hyaluronan, suggesting that hyaluronan in cells may be derived from an intracellular source. These data indicate that intracellular hyaluronan may be involved in nucleolar function, chromosomal rearrangement, or other events in proliferating cells. (J Histochem Cytochem 47:1331-1341, 1999)