Novel chemokine functions in lymphocyte migration through vascular endothelium under shear flow.

The recruitment of circulating leukocytes at vascular sites in target tissue has been linked to activation of Gi-protein signaling in leukocytes by endothelial chemokines. The mechanisms by which apical and subendothelial chemokines regulate leukocyte adhesion to and migration across endothelial barriers have been elusive. We recently found that endothelial chemokines not only stimulate integrin-mediated arrest on vascular endothelial ligands but also trigger earlier very late antigen (VLA)-4 integrin-mediated capture (tethering) of lymphocytes to vascular cell adhesion molecule 1 (VCAM-1)-bearing surfaces by extremely rapid modulation of integrin clustering at adhesive contact zones. This rapid modulation of integrin avidity requires chemokine immobilization in juxtaposition with the VLA-4 ligand VCAM-1. We also observed that endothelial-bound chemokines promote massive lymphocyte transendothelial migration (TEM). It is interesting that chemokine-promoted lymphocyte TEM requires continuous exposure of lymphocytes but not of the endothelial barrier to fluid shear. It is noteworthy that lymphocyte stimulation by soluble chemokines did not promote lymphocyte TEM. Our results suggest new roles for apical endothelial chemokines both in triggering lymphocyte capture to the endothelial surface and in driving post-arrest events that promote lymphocyte transmigration across endothelial barriers under shear flow.

The Src kinase p56(lck) up-regulates VLA-4 integrin affinity. Implications for rapid spontaneous and chemokine-triggered T cell adhesion to VCAM-1 and fibronectin.

In circulating lymphocytes, the VLA-4 integrin preexists in multiple affinity states that mediate spontaneous tethering, rolling, and arrest on its endothelial ligand, vascular cell adhesion molecule-1 (VCAM-1). The regulation and function of VLA-4 affinity in lymphocytes has never been elucidated. We show here that p56(lck), the major Src kinase in T cells, is a key regulator of high affinity VLA-4. This high affinity is essential for the rapid development of firm adhesion of resting T cells to VCAM-1 and to their extracellular matrix ligand, fibronectin. Lck-regulated VLA-4 function does not require intact TCR nor several key components of the TCR signaling pathway, including ZAP-70 and SLP-76. Furthermore, stimulation of p56(lck) by the phosphatase inhibitor, pervanadate, triggers firm VLA-4-dependent adhesion to VCAM-1. Although Lck is not required for chemokine receptor signaling to mitogen-activated protein kinase, the presence of Lck-regulated high affinity VLA-4 also facilitates firm adhesion triggered by the chemokine, SDF-1, at short-lived contacts. Surprisingly, bond formation rates, ability to tether cells to VLA-4 ligand, and VLA-4 tether bond stability under shear flow are not affected by VLA-4 affinity or Lck activity. Thus, the ability of high affinity VLA-4 to arrest cells on VCAM-1 under flow arises from instantaneous post-ligand strengthening rather than from increased kinetic stability of individual VLA-4 bonds. These results suggest that p56(lck) maintains high affinity VLA-4 on circulating lymphocytes, which determines their ability to strengthen VLA-4 adhesion and rapidly respond to proadhesive chemokine signals at endothelial sites.

Subsecond induction of alpha4 integrin clustering by immobilized chemokines stimulates leukocyte tethering and rolling on endothelial vascular cell adhesion molecule 1 under flow conditions.

Leukocyte recruitment to target tissue is initiated by weak rolling attachments to vessel wall ligands followed by firm integrin-dependent arrest triggered by endothelial chemokines. We show here that immobilized chemokines can augment not only arrest but also earlier integrin-mediated capture (tethering) of lymphocytes on inflamed endothelium. Furthermore, when presented in juxtaposition to vascular cell adhesion molecule 1 (VCAM-1), the endothelial ligand for the integrin very late antigen 4 (VLA-4, alpha4beta1), chemokines rapidly augment reversible lymphocyte tethering and rolling adhesions on VCAM-1. Chemokines potentiate VLA-4 tethering within <0.1 s of contact through Gi protein signaling, the fastest inside-out integrin signaling events reported to date. Although VLA-4 affinity is not altered upon chemokine signaling, subsecond VLA-4 clustering at the leukocyte-substrate contact zone results in enhanced leukocyte avidity to VCAM-1. Endothelial chemokines thus regulate all steps in adhesive cascades that control leukocyte recruitment at specific vascular beds.

Modification of PDGFalpha receptor expression or function alters the metastatic phenotype of 3LL cells.

Functional PDGFalpha receptors are selectively expressed on highly lung-metastasizing clones of the 3LL Lewis lung carcinoma, but not on low-mestastatic clones. The highly metastatic clones are also growth induced in vitro by PDGF and lung conditioned medium. To investigate whether modification of PDGFalpha receptor expression or function can affect metastatic capability, we transfected cells of a low-metastatic 3LL clone with a full length PDGFalpha receptor gene and cells of a highly-metastatic clone with a truncated kinase domain PDGFalpha receptor gene. Introduction of the full length PDGFalpha receptor conferred upon low-metastatic cells the ability to grow in vitro in the presence of PDGF-AA and to colonize the lung in experimental and spontaneous metastases assays. Conversely, introduction of a truncated version of the PDGFalpha receptor into highly metastatic cells reduced their metastatic load to control levels. Accordingly, their responses to PDGF-AA, including growth stimulation and receptor autophosphorylation, were reduced. These results demonstrate that PDGFalpha receptor expression and function can control the capacity of tumor cells to generate metastases in the lung. The response of this receptor to lung-derived PDGF-like factors may define a paracrine mode of metastatic cell growth in the target organ.