Integrin-mediated adhesion is a general concept referring to a series of adhesive phenomena including tethering-rolling, affinity, valency, and binding stabilization altogether controlling cell avidity (adhesiveness) for the substrate. Arrest chemokines modulate each aspect of integrin activation, although integrin affinity regulation has been recognized as the prominent event in rapid leukocyte arrest induced by chemokines. A variety of inside-out and outside-in signaling mechanisms have been related to the process of integrin-mediated adhesion in different cellular models, but only few of them have been clearly contextualized to rapid integrin affinity modulation by arrest chemokines in primary leukocytes. Complex signaling processes triggered by arrest chemokines and controlling leukocyte integrin activation have been described for ras-related rap and for rho-related small GTPases. We summarize the role of rap and rho small GTPases in the regulation of rapid integrin affinity in primary leukocytes and provide a modular view of these pro-adhesive signaling events. A potential, albeit still speculative, mechanism of rho-mediated regulation of cytoskeletal proteins controlling the last step of integrin activation is also discussed. We also discuss data suggesting a functional integration between the rho- and rap-modules of integrin activation. Finally we examine the universality of signaling mechanisms regulating integrin triggering by arrest chemokines.

GTP binding proteins known as small GTPases make up one of the largest groups of regulatory proteins and control almost all functions of living cells. Their activity is under, respectively, positive and negative regulation by guanine nucleotide exchange factors (GEFs) and GTPase activating proteins (GAPs), which together with their upstream regulators and the downstream targets of the small GTPases form formidable signalling networks. While genomics has revealed the large size of the GTPase, GEF and GAP repertoires, only a small fraction of their interactions and functions have yet been experimentally explored. Dictyostelid social amoebas have been particularly useful in unravelling the roles of many proteins in the Rac-Rho and Ras-Rap families of GTPases in directional cell migration and regulation of the actin cytoskeleton. Genomes and cell-type specific and developmental transcriptomes are available for Dictyostelium species that span the 0.5 billion years of evolution of the group from their unicellular ancestors. In this work, we identified all GTPases, GEFs and GAPs from genomes representative of the four major taxon groups and investigated their phylogenetic relationships and evolutionary conservation and changes in their functional domain architecture and in their developmental and cell-type specific expression. We performed a hierarchical cluster analysis of the expression profiles of the ~2000 analysed genes to identify putative interacting sets of GTPases, GEFs and GAPs, which highlight sets known to interact experimentally and many novel combinations. This work represents a valuable resource for research into all fields of cellular regulation.

The members of the Ras-like superfamily of small GTP-binding proteins are molecular switches that are in general regulated in time and space by guanine nucleotide exchange factors and GTPase activating proteins. The Ras-like G-proteins Ras, Rap and Ral are regulated by a variety of guanine nucleotide exchange factors that are characterized by a CDC25 homology domain. Here we study the evolution of the Ras pathway by determining the evolutionary history of CDC25 homology domain coding sequences. We identified CDC25 homology domain coding sequences in animals, fungi and a wide range of protists, but not in plants. This suggests that the CDC25 homology domain originated in or before the last eukaryotic ancestor but was subsequently lost in plant. We provide evidence that at least seven different ancestral Ras guanine nucleotide exchange factors were present in the ancestor of fungi and animals. Differences between present day fungi and animals are the result of loss of ancestral Ras guanine nucleotide exchange factors early in fungal and animal evolution combined with lineage specific duplications and domain acquisitions. In addition, we identify Ral guanine exchange factors and Ral in early diverged fungi, dating the origin of Ral signaling back to before the divergence of animals and fungi. We conclude that the Ras signaling pathway evolved by gradual change as well as through differential sampling of the ancestral CDC25 homology domain repertoire by both fungi and animals. Finally, a comparison of the domain composition of the Ras guanine nucleotide exchange factors shows that domain addition and diversification occurred both prior to and after the fungal-animal split.