An optimized platform for hydrophilic interaction chromatography-immobilized metal affinity chromatography enables deep coverage of the rat liver phosphoproteome.

While analysis of the phosphoproteome has become an important component of understanding how cells function, it remains a nontrivial task in terms of the number of sample preparation steps and instrument time needed to achieve sufficient depth of coverage to produce meaningful results. We previously described a multidimensional method that uses hydrophilic interaction chromatography (HILIC) followed by Fe(3+) immobilized metal affinity chromatography (IMAC) to reduce complexity, improve selectivity, and increase phosphopeptide identifications. Here we present refinements to our overall protocol that make it simpler and more efficient, while they provide greater coverage of the phosphoproteome. We introduce filter-aided sample prep (FASP) for cell lysis and trypsin digestion. Following HILIC separation, fractions are IMAC enriched using a 96-well filter plate. Finally, enriched samples are analyzed using an LC-MS strategy optimized for the fractionation scheme. The optimized protocol improves protein recovery, simplifies phosphopeptide enrichment, and optimizes instrument time, while it maintains deep coverage of the phosphoproteome. By using the refined protocol, we identified more than 16,000 unique phosphosites from rat liver in a single experiment, which used approximately 1 day of instrument time. All together, we present evidence for 24,485 rat liver phosphosites that represents the deepest coverage of a tissue phosphoproteome to date.

Quinoline 3-sulfonamides inhibit lactate dehydrogenase A and reverse aerobic glycolysis in cancer cells.

BACKGROUND: Most normal cells in the presence of oxygen utilize glucose for mitochondrial oxidative phosphorylation. In contrast, many cancer cells rapidly convert glucose to lactate in the cytosol, a process termed aerobic glycolysis. This glycolytic phenotype is enabled by lactate dehydrogenase (LDH), which catalyzes the inter-conversion of pyruvate and lactate. The purpose of this study was to identify and characterize potent and selective inhibitors of LDHA. METHODS: High throughput screening and lead optimization were used to generate inhibitors of LDHA enzymatic activity. Effects of these inhibitors on metabolism were evaluated using cell-based lactate production, oxygen consumption, and 13C NMR spectroscopy assays. Changes in comprehensive metabolic profile, cell proliferation, and apoptosis were assessed upon compound treatment. RESULTS: 3-((3-carbamoyl-7-(3,5-dimethylisoxazol-4-yl)-6-methoxyquinolin-4-yl) amino) benzoic acid was identified as an NADH-competitive LDHA inhibitor. Lead optimization yielded molecules with LDHA inhibitory potencies as low as 2 nM and 10 to 80-fold selectivity over LDHB. Molecules in this family rapidly and profoundly inhibited lactate production rates in multiple cancer cell lines including hepatocellular and breast carcinomas. Consistent with selective inhibition of LDHA, the most sensitive breast cancer cell lines to lactate inhibition in hypoxic conditions were cells with low expression of LDHB. Our inhibitors increased rates of oxygen consumption in hepatocellular carcinoma cells at doses up to 3 microM, while higher concentrations directly inhibited mitochondrial function. Analysis of more than 500 metabolites upon LDHA inhibition in Snu398 cells revealed that intracellular concentrations of glycolysis and citric acid cycle intermediates were increased, consistent with enhanced Krebs cycle activity and blockage of cytosolic glycolysis. Treatment with these compounds also potentiated PKM2 activity and promoted apoptosis in Snu398 cells. CONCLUSIONS: Rapid chemical inhibition of LDHA by these quinoline 3-sulfonamids led to profound metabolic alterations and impaired cell survival in carcinoma cells making it a compelling strategy for treating solid tumors that rely on aerobic glycolysis for survival.

Bacterial production of biologically active canine interleukin-1beta by seamless SUMO tagging and removal.

Interleukin 1beta (IL-1beta) is a potent stimulator of extracellular matrix degradation in models of osteoarthritis (OA). In contrast to bovine explant models which effectively respond to recombinant human IL-1beta, canine models are relatively refractory to human IL-1beta stimulation. Canine IL-1beta cDNA was cloned in order to produce a fully potent species matched preparation of IL-1beta for use specifically in canine models of OA. Established methods for the production of various orthologous IL-1beta proteins from different species are problematic due to the exquisite sensitivity of the mature IL-1beta product to N-terminal variations and the intrinsic technical challenges associated with producing an unmodified product. We have applied a seamless method of SUMO tagging and removal in order to produce a homogeneous unmodified preparation of canine IL-1beta from Escherichia coli which was found to be a potent inducer of aggrecanase activity in isolated canine articular chondrocytes. This method combines highly efficient aspects of seamless plasmid engineering, protein purification, and precise tag removal.

Expression, purification, and characterization of an enzymatically active truncated human rho-kinase I (ROCK I) domain expressed in Sf-9 insect cells.

Rho Kinase I (ROCK I) is a serine/threonine kinase that is involved in diverse cellular signaling. To further understand the physiological role of ROCK I and to identify and develop potent and selective inhibitors of ROCK I, we have overexpressed and purified a constitutively active dimeric human ROCK I (3-543) kinase domain using the Sf9-baculovirus expression system. In addition, using a limited proteolysis technique, we have identified a minimal functional subdomain of ROCK I that can be used in crystallization studies. The availability of multimilligram amounts of purified and well characterized functional human ROCK I kinase domains will be useful in screening and structural studies.

Interleukin-1F7B (IL-1H4/IL-1F7) is processed by caspase-1 and mature IL-1F7B binds to the IL-18 receptor but does not induce IFN-gamma production.

We have recently reported the identification of four novel members of the interleukin-1 (IL-1) family which we designated as IL-1 homologue 1-4 (IL-1H1-4). These proteins exhibit significant sequence homology to other members of the IL-1 family. Of these homologues, only IL-1H4 (renamed IL-1F7b) was predicted to contain a propeptide domain and a caspase cleavage site. We now report that caspase-1 cleaves IL-1F7b at the predicted site to generate mature IL-1F7b. Caspase-4 was also able to process IL-1F7b, albeit inefficiently. Other caspases and Granzyme-B did not cleave IL-1F7b. Furthermore, adenovirus-mediated expression of IL-1F7b in HEK 293 cells led to in situ processing and secretion of mature IL-1F7b. In a screen to identify a potential receptor, both pro and mature IL-1F7b bound to the soluble IL-18 receptor alpha-Fc (IL-18Ralpha-Fc) but not to the soluble IL-1R-Fc or ST2R-Fc fusion proteins. Mature IL-1F7b bound to the IL-18Ralpha-Fc protein with higher affinity than the pro form, although the affinities for both proteins were significantly lower than that observed for IL-18. Consistent with this observation, only IL-18 and not IL-1F7b induced IFN-gamma production by KG1a cells. We also report that pro and mature IL-1F7b form homodimers with association constants of 4 microM and 5 nM, respectively, suggesting biological relevance to IL-1F7b processing. Finally, we have localized the expression of IL-1F7b protein in discrete cell populations including plasma cells and tumor cells. These data suggest that IL-1F7b may be involved in immune response, inflammatory diseases and/or cancer.