Foraging behavior of Highland cattle in silvopastoral systems in the Alps.

Trees and shrubs expanded in the last decades in European mountains due to land abandonment and the decrease in grazing pressure, and are expected to further spread also due to climate change. As a consequence of low forage quality and topographic constraints, the management of mountain environments dominated by woody vegetation with livestock is often challenging. Silvopastoral systems based on cattle hardy breeds able to forage on woody plants, such as Highland cattle, could be a suitable option for the management and restoration of such environments. In this study, we used direct observations to explore the foraging behavior of Highland cattle in four study areas across the western Alps. In particular, we assessed: (1) cattle diet composition, (2) the selection for more than 30 tree and shrub species, and (3) the relationships between species consumption and their abundance in the environment. Highland cattle fed on a mixture of both woody and herbaceous species, including between 15 and 46% of woody plants in the diet. Some trees (e.g., Celtis australis, Fraxinus spp., and Populus tremula) and shrubs (e.g., Frangula alnus, Rhamnus spp., and Rubus idaeus) were positively selected by cattle, thus they could be an important forage supplement to their diet. Moreover, the results highlighted that relative species consumption generally increased with increasing species abundance in the environment, suggesting that this cattle breed could be suitable to control shrub expansion in highly encroached areas. The outcomes of this study can support the development of targeted silvopastoral systems in the Alps. Supplementary Information: The online version contains supplementary material available at 10.1007/s10457-023-00926-z.

Geldanamycins trigger a novel Ron degradative pathway, hampering oncogenic signaling.

Ron, the tyrosine kinase receptor for macrophage-stimulating protein is responsible for proliferation and migration of cells from different tissues. Ron can acquire oncogenic potential by single point mutations in the kinase domain, and dysregulated Ron signaling has been involved in the development of different human cancers. We have previously shown that ligand-activated Ron recruits the negative regulator c-Cbl, which mediates its ubiquitylation and degradation. Here we report that Ron is ubiquitylated also by the U-box E3 ligase C-terminal Hsc70-interacting protein (CHIP), recruited via chaperone intermediates Hsp90 and Hsc70. Gene silencing shows that CHIP activity is necessary to mediate Ron degradation upon cell treatment with Hsp90 inhibitors geldanamycins. The oncogenic Ron(M1254T) receptor escapes from c-Cbl negative regulation but retains a strong association with CHIP. This constitutively active mutant of Ron displays increased sensitivity to geldanamycins, enhanced physical interaction with Hsp90, and more rapid degradation rate. Cell growth and migration, as well as the transforming potential evoked by Ron(M1254T), are abrogated upon Hsp90 inhibition. These data highlight a novel mechanism for Ron degradation and propose Hsp90 antagonists like geldanamycins as suitable pharmacological agents for therapy of cancers where altered Ron signaling is involved.

p190 Rho-GTPase activating protein associates with plexins and it is required for semaphorin signalling.

Plexins are transmembrane receptors for semaphorins, guiding cell migration and axon extension. Plexin activation leads to the disassembly of integrin-based focal adhesive structures and to actin cytoskeleton remodelling and inhibition of cell migration; however, the underlying molecular mechanisms are unclear. We consistently observe a transient decrease of cellular RhoA-GTP levels upon plexin activation in adherent cells. One of the main effectors of RhoA downregulation is p190, a ubiquitously expressed GTPase activating protein (GAP). We show that, in p190-deficient fibroblasts, the typical functional activities mediated by plexins (such as cell collapse and inhibition of integrin-based adhesion) are blocked or greatly impaired. Notably, the functional response can be rescued in these cells by re-expressing exogenous p190, but not a mutant form specifically lacking RhoGAP activity. We furthermore demonstrate that semaphorin function is blocked in epithelial cells, primary endothelial cells and neuroblasts upon treatment with small interfering RNAs that knockdown p190 expression. Finally, we show that p190 transiently associates with plexins, and its RhoGAP activity is increased in response to semaphorin stimulation. We conclude that p190-RhoGAP is crucially involved in semaphorin signalling to the actin cytoskeleton, via interaction with plexins.

Plexin-B3 is a functional receptor for semaphorin 5A.

Semaphorins are a large family of molecular cues implicated in neural development and in a variety of functions outside the nervous system. Semaphorin 5A (Sema5A) is a transmembrane semaphorin, containing seven thrombospondin type-1 repeats, which was recently found to control axon guidance. Here we show that plexin-B3 is a high-affinity receptor specific for Sema5A. We further demonstrate that plexin-B3 activation by Sema5A mediates functional responses in plexin-B3-expressing cells (either fibroblasts, epithelial and primary endothelial cells). In addition, Sema5A can trigger the intracellular signalling of the hepatocyte growth factor/scatter factor receptor, Met, associated in a complex with plexin-B3. We thus conclude that Sema5A is able to elicit multiple functional responses through its receptor plexin-B3.

Functional regulation of semaphorin receptors by proprotein convertases.

PLEXIN genes encode receptors for secreted and membrane-bound semaphorins. It was proposed that the extracellular domain of plexins acts as an inhibitory moiety, preventing receptor activation. Here we show that plexin-B1 and plexin-B2 undergo proteolytic processing in their extracellular portion, thereby converting single-chain precursors into non-disulfide-linked, heterodimeric receptors. We demonstrate that plexin processing is mediated by subtilisin-like proprotein convertases, by inhibition with alpha1-antitrypsin Portland, and by mutagenesis of the substrate-cleavage sites. We provide evidence indicating that proprotein convertases cleave plexins in a post-Golgi compartment and, likely, at the cell surface. In addition, we find that both cell surface targeting and proteolytic processing of plexin-B1 depend on protein-protein interaction motifs in the cytoplasmic domain of the receptor. We then show that proteolytic conversion of plexin-B1 into a heterodimeric receptor greatly increases the binding and the functional response to its specific ligand semaphorin 4D/CD100. Thus, we conclude that cleavage by proprotein convertases is a novel regulatory step for semaphorin receptors localized at the cell surface.

The semaphorin 4D receptor controls invasive growth by coupling with Met.

Semaphorins are cell surface and soluble signals that control axonal guidance. Recently, semaphorin receptors (plexins) have been discovered and shown to be widely expressed. Their biological activities outside the nervous system and the signal transduction mechanism(s) they utilize are largely unknown. Here, we show that in epithelial cells, Semaphorin 4D (Sema 4D) triggers invasive growth, a complex programme that includes cell#150;cell dissociation, anchorage-independent growth and branching morphogenesis. Interestingly, the same response is also controlled by scatter factors through their tyrosine kinase receptors, which share striking structural homology with plexins in their extracellular domain. We found that in cells expressing the endogenous proteins, Plexin B1 (the Sema 4D Receptor) and Met (the Scatter Factor 1/ Hepatocyte Growth Factor Receptor) associate in a complex. In addition, binding of Sema 4D to Plexin B1 stimulates the tyrosine kinase activity of Met, resulting in tyrosine phosphorylation of both receptors. Finally, cells lacking Met expression do not respond to Sema 4D unless exogenous Met is expressed. This work identifies a novel biological function of semaphorins and suggests the involvement of an unexpected signalling mechanism, namely, the coupling of a plexin to a tyrosine kinase receptor.