Abp1p and cortactin, new "hand-holds" for actin.

Recently, two new ligands of the Arp2/3 complex have been described that may shed light on the way cells organize complex networks of actin in response to signals. Abp1p, a yeast protein involved in endocytosis, and cortactin, a mammalian src substrate, both enhance the ability of the Arp2/3 complex to assemble branched actin filament networks.

Transgenic mice expressing bovine GH develop arthritic disorder and self-antibodies.

We observed disability of movement in 6-month-old transgenic mice expressing the fusion gene coding for the bovine GH (bGH) under the transcriptional control of phosphoenolpyruvate carboxykinase promoter (PEPCK-bGH). Histological study of the knee joint showed altered synovial and tibial articular cartilage tissues. In the cartilage the following observations were made: (i) generalized loss of the normal zonal structure and presence of clefts, and (ii) profound alterations in chondrocyte growth/differentiation processes consistent with hypertrophy. The synovial tissue showed a reduced number of adipocytes, and a significant thickening of synovial lining tissue and pannus. These findings indicate that transgenic mice suffer damage to diarthritic joints with osteoarthritic appearance. As changes in synovial membrane in osteoarthritis are almost indistinguishable from those seen in inflammatory arthritis, we determined the potential correlation with an immunological disorder. Serological determination of self-antibodies measured as a function of age and sex showed anti-nuclear, anti-single-stranded DNA, anti-double-stranded DNA and anti-70K antibodies, and an altered immunoglobulin typing. These results suggest that transgenic mice expressing bGH develop an arthritic process which is correlated with an immune disorder. The results also indicate that these mice are a suitable animal model to study the specific role of GH-driven processes in immune cells and arthritis.

Prolactin (PRL)-PRL receptor system increases cell proliferation involving JNK (c-Jun amino terminal kinase) and AP-1 activation: inhibition by glucocorticoids.

PRL receptor (PRLR) signal transduction supports PRL-induced growth/differentiation processes. While PRL is known to activate Jak2-Stat5 (signal transducer and activator of transcription 5) signaling pathway, the mechanism by which cell proliferation is stimulated is less known. We show that PRL induces proliferation of bovine mammary gland epithelial cells and AP-1 site activation. Using PRLR mutants and the PRLR short form, we have found that both homodimerization of PRLR wild type and the integrity of box-1 and C-distal tyrosine of PRLR intracellular domain are needed in PRL-induced proliferation and AP-1 activation. The effect of PRL has been assayed in the presence of dexamethasone (Dex), insulin, and alone. We found that Dex negatively regulates PRL-induced proliferation and AP-1 site activation. We demonstrate that PRL exerts activation of AP-1 transcriptional complex, and the mechanism by which this activation is produced is also studied. We show that PRL induces an increase in the c-Jun content of AP-1 transcriptional complexes. The PRL-induced c-Jun of AP-1 transcriptional complex diminishes in the presence of Dex in a dose-dependent manner. Dex inhibition was reversed by the higher concentration of PRL added to cells. Despite the fact that the regulation of the AP-1 site is complex, we found that PRL activates the c-Jun amino terminal kinase (JNK), while glucocorticoid prevents this JNK activation. These data support a regulation of cellular growth by PRL-PRLR system by increasing AP-1 transcriptional complex activity via JNK activation. JNK activation can be repressed by glucocorticoid in a DNA-binding-independent manner.