Spatial signal repression as an additional role of Sprouty2 protein variants.

Sprouty2 (Spry2) is a prominent member of a protein family with crucial functions in the modulation of signal transduction. One of its main actions is the repression of mitogen-activated protein kinase (MAPK) pathway in response to growth factor-induced signalling. A common single nucleotide polymorphism within the Spry2 gene creates two protein variants where a proline adjacent to the serine rich domain is converted to an additional serine. Both protein variants perform similar functions although their efficiency in fulfilling these tasks varies. In this report, we used biochemical fractionation methods as well as confocal microscopy to analyse quantitative and qualitative differences in the distribution of Spry2 variants. We found that Spry2 proteins localize not solely to the plasma membrane, but also to other membrane engulfed compartments like for example the Golgi apparatus. In these less dense organelles, predominantly slower migrating forms reside indicating that posttranslational modification contributes to the distribution profile of Spry2. However there is no significant difference in the distribution of the two variants. Additionally, we found that Spry2 could be found exclusively in membrane fractions irrespective of the mitogen availability and the phosphorylation status. Considering the interference of extracellular signal-regulated kinase (ERK) activation in the cytoplasm, both Spry2 variants inhibited the levels of phosphorylated ERK (pERK) significantly to a similar extent. In contrast, the induction profiles of pERK levels were completely different in the nuclei. Again, both Spry2 variants diminished the levels of pERK. While the proline variant lowered the activation throughout the observation period, the serine variant failed to interfere with immediate accumulation of nuclear pERK levels, but the signal duration was shortened. Since the extent of the pERK inhibition in the nuclei was drastically more pronounced than in the cytoplasm, we conclude that Spry2 - in addition to its known functions as a repressor of general ERK phosphorylation - functions as a spatial repressor of nucleic ERK activation. Accordingly, a dominant negative version of Spry2 was only able to enhance the pERK levels of serum-deprived cells in the cytosol, while in the nucleus the intensity of the pERK signal in response to serum addition was significantly increased.

Differential Effects of Variations at Codon 106 on Sprouty2 Functions in Lung Cancer-Derived Cells.

Sprouty2 is a modulator of receptor tyrosine kinase-mediated signalling with an important role during lung carcinogenesis. Here, we characterize a Sprouty2 variant harbouring a substitution of proline 106 with serine. Serine substitution fails to influence expression, but accumulation of slower migrating phosphatase-sensitive forms indicates that its presence facilitates phosphorylation. In normal lung cells the serine variant is slightly more potent in inhibiting proliferation and migration. Additionally non-malignant cells expressing the major Sprouty2 variant attach more effective to fibronectin, while the serine variant only weakly stimulates cell adhesion. Mechanistically, the serine variant interferes less effectively with mitogen-activated protein kinase induction in response to serum. Concerning the positive Sprouty2 effect on epidermal growth factor receptor activation the serine variant is more potent. In all lung cancer-derived cell lines proliferation is more effectively inhibited if the Sprouty2 protein harbours the serine. In contrast, an increased interference of the serine Sprouty2 variant is only observed in cells with unaltered K-Ras. In cells harbouring a K-Ras mutation the serine conversion weakens the reduction of migration velocity indicating that dependent on the status of K-Ras the serine influences Sprouty2 functions differently. Accordingly, cell adhesion in cells with unaffected K-Ras is only stimulated by a Sprouty2 protein harbouring proline, while a serine conversion improves the attachment of the cells with constitutive active Ras. In summary our studies demonstrate that substitution of proline by serine at position 106 has biological significance and that the observed effects of this conversion depend on the activation status of endogenous K-Ras. J. Cell. Biochem. 117: 1822-1832, 2016. © 2016 Wiley Periodicals, Inc.

Sprouty4 interferes with cell proliferation and migration of breast cancer-derived cell lines.

Sprouty proteins are modulators of mitogen-induced signal transduction processes and therefore can influence the process of cancerogenesis. In particular, Sprouty2 has been shown to have an important role in cancer development of many tumor entities including breast cancer. In this report, we investigated the role of Sprouty4 in breast cancer-derived cell lines. We have found that ectopic Sprouty4 expression inhibits cell proliferation of breast cancer cell lines independently of their endogenous expression levels. Corroborating Sprouty4 downregulation causes accelerated growth. Furthermore, we demonstrate that an increase in Sprouty4 content interferes with serum-induced activation of mitogen-activated protein kinase pathway. Additionally, Sprouty4 expression negatively influences cell migration. These data suggest that Sprouty4 is a possible candidate for a tumor suppressor in breast cancer.

In non-small cell lung cancer mitogenic signaling leaves Sprouty1 protein levels unaffected.

Sprouty1 protein belongs to a family of receptor tyrosine kinase-mediated signaling inhibitors, whose members are usually regulated by growth factors to form a negative feedback loop. Correspondingly fluctuations of Sprouty1 mRNA in response to single growth factors have been observed. In this report, we investigate Sprouty1 protein levels and show that in non-small cell lung carcinoma-derived cells, the expression levels are unaffected by the serum content in the cellular environment. Although cells harboring K-Ras mutations express insignificant higher Sprouty1 levels, ectopic expression of constitutive active Ras in normal human lung fibroblasts fails to augment Sprouty1 protein content. Furthermore, serum starvation for three days has no influence on Sprouty1 expression and addition of serum or of singular growth factors leaves Sprouty protein levels unchanged. Cell cycle analysis reveals that Sprouty1 levels remain constant throughout the whole cell cycle. These data demonstrate that Sprouty1 expression is not connected with mitogenic signaling and cell proliferation.

Identification of a lysine-rich region of Fas as a raft nanodomain targeting signal necessary for Fas-mediated cell death.

Fas interaction at the plasma membrane with its lipid and protein environment plays a crucial role in the early steps of Fas signalling induced by Fas ligand binding. Particularly, Fas localisation in the raft nanodomains, ezrin-mediated interaction with the actin cytoskeleton and subsequent internalization are critical steps in Fas-mediated cell death. We identified a lysine-rich region (LRR) in the cytoplasmic, membrane-proximal region of Fas as a key determinant modulating these initial events. Through a genetic approach, we demonstrate that Fas LRR represents another signal additional to palmitoylation targeting Fas to the raft nanodomains, and modulates Fas interaction with the cytoskeleton.

Loss of nucleoplasmic LAP2alpha-lamin A complexes causes erythroid and epidermal progenitor hyperproliferation.

Lamina-associated polypeptide (LAP) 2alpha is a chromatin-associated protein that binds A-type lamins. Mutations in both LAP2alpha and A-type lamins are linked to human diseases called laminopathies, but the molecular mechanisms are poorly understood. The A-type lamin-LAP2alpha complex interacts with and regulates retinoblastoma protein (pRb), but the significance of this interaction in vivo is unknown. Here we address the function of the A-type lamin-LAP2alpha complex with the use of LAP2alpha-deficient mice. We show that LAP2alpha loss causes relocalization of nucleoplasmic A-type lamins to the nuclear envelope and impairs pRb function. This causes inefficient cell-cycle arrest in dense fibroblast cultures and hyperproliferation of epidermal and erythroid progenitor cells in vivo, leading to tissue hyperplasia. Our results support a disease-relevant model in which LAP2alpha defines A-type lamin localization in the nucleoplasm, which in turn affects pRb-mediated regulation of progenitor cell proliferation and differentiation in highly regenerative tissues.