Project description:Adjusting to a wide range of light intensities is an essential feature of retinal rod bipolar cell (RBC) function, and persuasive evidence suggests this modulation involves phosphorylation by protein kinase C-alpha (PKC-alpha). PKC-alpha is a serine/threonine kinase that is strongly expressed in RBCs, but the targets of PKC-alpha phosphorylation in the retina have not been identified. PKC-alpha activity and phosphorylation in RBCs was examined by immunofluorescence confocal microscopy using a conformation-specific PKC-alpha antibody and antibodies to phosphorylated PKC motifs. PKC-alpha activity was dependent on light and expression of TRPM1, and RBC dendrites were the primary sites of light-dependent phosphorylation. PKC-alpha-dependent retinal phosphoproteins were identified using a multiplexed tandem mass tag-based approach to compare total protein and phosphopeptide abundance between phorbol ester-treated wild type and PKC-alpha knockout (PKC-alpha-KO) mouse retinas. Of the 23 proteins showing significant differential abundance between the two groups, most have roles in cytoskeleton/transport, transcriptional regulation, or metabolism/homeostasis. Phosphopeptide mass spectrometry identified over 1100 phosphopeptides in mouse retina, with 12 displaying significantly greater phosphorylation in WT compared to PKC-alpha-KO samples. The differentially phosphorylated proteins fall into the following functional groups: cytoskeleton/transport (4 proteins), ECM/adhesion (2 proteins), signaling (2 proteins), transcriptional regulation (3 proteins), and homeostasis/metabolism (1 protein). Two strongly differentially expressed phosphoproteins, BORG4 and TPBG, were localized to the synaptic layers of the retina, and may play a role in PKC-alpha-dependent modulation of RBC physiology.

Project description:The pathogenic bacterium Francisella tularensis possesses a non-canonical T6SS encoded on the Francisella pathogenicity island (FPI) that is essential for efficient phagosomal escape and access to the cytosolic compartment of infected host cells. Using a global and site-specific phosphoproteomic analysis of F. novicida, we identified a phosphorylated form of IglB, which constitutes with iglA the outer sheath of the T6SS. We show here that substitution of the unique phosphorylated tyrosine (Y139) of IglB to alanine or to the non-phosphorylatable analogue phenylalanine prevents the formation of the sheath-like structures and impairs normal bacterial phagosomal escape. We propose that IglB phosphorylation is involved in the dynamics of assembly-disassembly of the sheath.

Project description:The high prevalence of sickle cell disease in some human populations likely results from the protection afforded against severe Plasmodium falciparum malaria and death by heterozygous carriage of HbS. P. falciparum remodels the erythrocyte membrane and skeleton, displaying parasite proteins at the erythrocyte surface that interact with key human proteins in the Ankyrin R and 4.1R complexes. Oxidative stress generated by HbS, as well as by parasite invasion, disrupts the kinase/phosphatase balance, potentially interfering with the molecular interactions between human and parasite proteins. HbS is known to be associated with abnormal membrane display of parasite antigens. Studying the proteome and the phosphoproteome of red cell membrane extracts from P. falciparum infected and non-infected erythrocytes, we show here that HbS heterozygous carriage, combined with infection, modulates the phosphorylation of erythrocyte membrane transporters and skeletal proteins as well as of parasite proteins. Our results highlight modifications of Ser- /Thr- and/or Tyr- phosphorylation in key human proteins, such as ankyrin, β-adducin, β-spectrin and Band 3, and key parasite proteins, such as RESA or MESA. Altered phosphorylation patterns could disturb the interactions within membrane protein complexes, affect nutrient uptake and the infected erythrocyte cytoadherence phenomenon, thus lessening the severity of malaria symptoms.

Project description:Phosphorus (P) deficiency is considered as a major constraint on crop production. Although a set of adaptative strategies are extensively suggested in soybean (Glycine max) to phosphate(Pi) deprivation, molecular mechanisms underlying reversible protein phosphorylation in soybean responses to P deficiency remains largely unclear. In this study, isobaric tags for relative and absolute quantitation, combined with liquid chromatography and tandem mass spectrometry analysis was performed to identify differential phosphoproteins in soybean roots under Pi sufficient and deficient conditions. A total of 427 phosphoproteins were found to exhibit differential accumulations, with 213 up-regulated and 214 down-regulated.Taken together, identification of differential phosphoproteins not only reveled complex regulatory pathways in soybean adaptation to Pi starvation through reversible protein phosphorylation.

Project description:Salinity causes osmotic stress to crops and limits their productivity. To understand the mechanism underlying soybean salt tolerance, quantitative phosphoproteomics approach was used to identify phosphoproteins that were altered by NaCl treatment.

Project description:Cancer is considered as a disease of a specific organ, but its effects are felt throughout the body. The systemic effects of cancer can lead to weakness in muscles and heart, which hastens cancer-associated death. miR-486 is a myogenic microRNA and its reduced expression in skeletal muscle is observed in muscular dystrophy. Muscle-specific transgenic expression of miR-486 using muscle creatine kinase promoter (MCK-miR-486) partially rescues skeletal muscle defects in muscular dystrophy animal models. We had previously demonstrated reduced circulating and skeletal muscle levels of miR-486 in several cancer types and lower miR-486 levels correlated with skeletal muscle defects and functional limitations in mammary tumor models. Therefore, skeletal muscle defects induced by cancer could resemble defects observed in various dystrophies, which could be reversed through skeletal muscle expression of miR-486. We performed functional limitations studies and biochemical analysis of skeletal muscles of MMTV-Neu transgenic mice that mimic HER2+ breast cancer and MMTV-PyMT transgenic mice that mimic luminal subtype B breast cancer and these mice crossed to MCK-miR-486 transgenic mice. miR-486 significantly prevented tumor-induced reduction in muscle contraction force, grip strength, and rotarod performance in MMTV-Neu, but not in MMTV-PyMT mice. In MMTV-Neu model, miR-486 reversed several of the cancer-induced changes in skeletal muscle including loss of p53, phospho-AKT, and phospho-laminin alpha 2 (LAMA2) and gain of phosphorylation of the pre-mRNA processing factor hnRNPA0 and the splicing factor SRSF10. LAMA2 is a part of the dystrophin-associated glycoprotein complex, and its loss-of-function mutation is associated with congenital muscular dystrophy. Thus, similar to muscular dystrophy, miR-486 has the potential to reverse skeletal muscle defects and cancer burden in select cancer types.

Project description:Francisella possesses a non-canonical T6SS that is essential for efficient phagosomal escape and access to the cytosol of infected macrophages. Using a global and site-specific phosphoproteomic analysis of Francisella we identified here a unique phosphorylation site on IglB, the TssC homologue and a key component of the T6SS contractile sheath. Phosphorylation of the sheath may constitute a previously unrecognized mechanism contributing to the dynamics of assembly-disassembly of the T6SS.

Project description:Francisella possesses a non-canonical T6SS that is essential for efficient phagosomal escape and access to the cytosol of infected macrophages. Using a global and site-specific phosphoproteomic analysis of Francisella we identified here a unique phosphorylation site on IglB, the TssC homologue and a key component of the T6SS contractile sheath. Phosphorylation of the sheath may constitute a previously unrecognized mechanism contributing to the dynamics of assembly-disassembly of the T6SS.

Project description:The PTEN tumor suppressor controls cell death and survival by regulating functions of various molecular targets. Whilst the role of PTEN lipid-phosphatase activity on PtdIns(3,4,5)P3 and inhibition of PI3K pathway is well characterized, the biological relevance of PTEN protein-phosphatase activity remains undefined. Using knock-in (KI) mice harbouring cancer-associated and functionally relevant missense mutations, we show that although loss of PTEN lipid-phosphatase function cooperates with oncogenic PI3K to promote rapid mammary tumorigenesis, the additional loss of PTEN protein-phosphatase activity triggered an extensive cell death response evident in early and advanced mammary tumors. Omics and drug-targeting studies revealed that PI3Ks act to reduce glucocorticoid receptor (GR) levels, which are rescued by loss of PTEN protein-phosphatase activity to restrain cell survival. The dual regulation of GR by PI3K and PTEN functions as a rheostat that can be exploited for the treatment of PTEN-loss driven cancers.

Project description:Protein kinase inhibitors are amongst the most successful cancer treatments, but targetable kinases activated by gene fusions are rare in T-ALL (e.g., NUP214-ABL1). Nevertheless, leukemic blasts rely on enhanced kinase signaling to sustain dysregulated proliferation. Protein kinases can be hyper-activated in the absence of defects in their genes. Thus, phospho-proteomics can provide information on pathway activation, signaling networks and aberrant kinases activities that offer important opportunities for targeted therapies. Here, we performed mass spectrometry-based global profiling of tyrosine, serine, and threonine phosphorylation in a panel of 11 T-ALL cell lines to identify potential targetable kinases. We report a comprehensive dataset consisting of 21,000 phosphosites on 4896 phosphoproteins, including 217 kinases. We identify several Src-family members (LCK, SRC, FYN, YES1) as well as the cyclin-dependent kinases CDK1 and CDK2 as broadly activated in our panel. We validate highly active kinases as putative target for therapy in vitro and propose potential novel combination treatment strategies, such as the inhibition of the insulin-like growth factor receptor (IGF-1R) signaling pathway to increase the sensitivity to dasatinib treatment in T-ALL.