Structural characterization of recombinant alpha-1-antitrypsin expressed in a human cell line.

Human alpha-1-antitrypsin (A1PI) is a plasma protein with the function of protecting lung tissues from proteolytic destruction by enzymes from inflammatory cells. A1PI deficiency is an inherited disorder associated with pulmonary emphysema and a higher risk of chronic obstructive pulmonary disease (COPD). Here we present the structural characterization of a recombinant form of human A1PI (Hu-recA1PI) expressed in the human PER.C6 cell line using an array of analytical and biochemical techniques. Hu-recA1PI had the same primary structure as plasma-derived A1PI (pd-A1PI) except reduced N-terminal heterogeneity. The secondary and tertiary structures were indistinguishable from pd-A1PI. Like pd-A1PI, Hu-recA1PI was modified by N-linked glycosylation on N46, N83, and N246. Unlike pd-A1PI, most glycans on recA1P1 were core fucosylated via α(1-6) linkage. In addition, significantly higher amounts of tri- and tetraantennary glycans were observed. These differences in glycosylation contributed to the apparent higher molecular weight and lower isoelectric point (pI) of Hu-recA1PI than pd-A1PI. Hu-recA1PI contained both α(2-3)- and α(2-6)-linked sialic acids and had very similar sialylation levels as pd-A1PI. Hu-recA1PI glycans were differentially distributed, with N46 containing mostly biantennary glycans, N83 containing primarily tri- and tetraantennary glycans, and N247 containing exclusively biantennary glycans.

Cerebral cavernous malformation 2 protein promotes smad ubiquitin regulatory factor 1-mediated RhoA degradation in endothelial cells.

Mutation of CCM2 predisposes individuals to cerebral cavernous malformations, vascular abnormalities that cause seizures and hemorrhagic stroke. CCM2 has been proposed to regulate the activity of RhoA for maintenance of vascular integrity. Herein, we define a novel mechanism where the CCM2 phosphotyrosine binding (PTB) domain binds the ubiquitin ligase (E3) Smurf1, controlling RhoA degradation. Brain endothelial cells with knockdown of CCM2 have increased RhoA protein and display impaired directed cell migration. CCM2 binding of Smurf1 increases Smurf1-mediated degradation of RhoA. CCM2 does not significantly alter the catalytic activity of Smurf1, nor is CCM2 a Smurf1 substrate. Rather the CCM2-Smurf1 interaction functions to localize Smurf1 for RhoA degradation. These findings provide a molecular mechanism for the pathogenesis of cerebral cavernous malformations (CCM) resulting from loss of CCM2-mediated localization of Smurf1, which controls RhoA degradation required for maintenance of normal endothelial cell physiology.

Hyperosmotic induction of mitogen-activated protein kinase scaffolding.

Eukaryotic cells respond to hyperosmotic conditions by expunging water from the cell, leading to cell shrinkage. This is counteracted by adaptive responses that restore cell volume and strengthen the cytoskeletal architecture. In the budding yeast Saccharomyces cerevisiae, this response is mediated primarily by the mitogen-activated protein kinase (MAPK) cascade CDC42-STE50-STE11-Pbs2-Hog1. In mammalian cells, MAPK scaffold proteins facilitate the efficiency of signaling within the cascade by placing a kinase near its substrate and also regulate the subcellular localization of the signaling. Our laboratory has discovered a scaffold that coordinates the analogous Hog1 signal in mammalian cells, termed OSM (osmosensing scaffold for MEKK3). OSM organizes a complex consisting of the small GTPase Rac, MEKK3, and MKK3 for the activation of p38 MAPK. Interactions among OSM, Rac, and MEKK3 are augmented in response to sorbitol and are also localized to membrane ruffles, sites of rapid actin turnover. Suppression of the expression of OSM or MEKK3 by RNA interference strongly inhibits the sorbitol-dependent activation of p38. Furthermore, mutations in OSM were concurrently found to cause cerebral cavernous malformations (CCM), a disease of the central nervous system characterized by thin-walled, leaky blood vessels that become hemorrhagic. Our laboratory has also demonstrated that Krit1, another gene harboring mutations that lead to CCM, binds OSM and its interaction is enhanced in response to sorbitol in a similar manner as the MEKK3-OSM interaction. This chapter describes the cell biological and biochemical methods used for assaying protein-protein interactions in live cells using fluorescence resonance energy transfer, in vitro kinase assays for MEKK3-MKK3-p38 pathway members, and gene suppression by RNA interference to study hyperosmotic stress-dependent signaling.

Proteomic identification of the cerebral cavernous malformation signaling complex.

Cerebral cavernous malformations (CCM) are sporadic or inherited vascular lesions of the central nervous system characterized by dilated, thin-walled, leaky vessels. Linkage studies have mapped autosomal dominant mutations to three loci: ccm1 (KRIT1), ccm2 (OSM), and ccm3 (PDCD10). All three proteins appear to be scaffolds or adaptor proteins, as no enzymatic function can be attributed to them. Our previous results demonstrated that OSM is a scaffold for the assembly of the GTPase Rac and the MAPK kinase kinase MEKK3, for the hyperosmotic stress-dependent activation of p38 MAPK. Herein, we show that the three CCM proteins are members of a larger signaling complex. To define this complex, epitope-tagged wild type OSM or OSM harboring the mutation of F217-->A, which renders the OSM phosphotyrosine binding (PTB) domain unable to bind KRIT1, were stably introduced into RAW264.7 mouse macrophages. FLAG-OSM or FLAG-OSMF217A and the associated complex members were purified by immunoprecipitation using anti-FLAG antibody. OSM binding partners were identified by gel-based methods combined with electrospray ionization-MS or by multidimensional protein identification technology (MudPIT). Previously identified proteins that associate with OSM including KRIT1, MEKK3, Rac, and the KRIT1-binding protein ICAP-1 were found in the immunoprecipitates. In addition, we show for the first time that PDCD10 binds to OSM and is found in cellular CCM complexes. Other prominent proteins that bound the CCM complex include EF1A1, RIN2, and tubulin, with each interaction disrupted with the OSMF217A mutant protein. We further show that PDCD10 binds phosphatidylinositol di- and triphosphates and OSM binds phosphatidylinositol monophosphates. The findings define the targeting of the CCM complex to membranes and to proteins regulating trafficking and the cytoskeleton.

Caspase-3 dependent cleavage and activation of skeletal muscle phosphorylase b kinase.

Phosphorylase b kinase (PhK) is a key enzyme involved in the conversion of glycogen to glucose in skeletal muscle and ultimately an increase in intracellular ATP. Since apoptosis is an ATP-dependent event, we investigated the regulation of skeletal muscle PhK during apoptosis. Incubation of PhK with purified caspase-3 in vitro resulted in the highly selective cleavage of the regulatory alpha subunit and resulted in a 2-fold increase in PhK activity. Edman protein sequencing of a stable 72 kD amino-terminal fragment and a 66 kD carboxy-terminal fragment revealed a specific caspase-3 cleavage site within the alpha subunit at residue 646 (DWMD G). Treatment of differentiated C2C12 mouse muscle myoblasts with the inducers of apoptosis staurosporine, TPEN, doxorubicin, or UV irradiation resulted in the disappearance of the alpha subunit of PhK as determined by immunoblotting, as well as a concurrent increase in caspase-3 activity. Moreover, induction of apoptosis by TPEN resulted in increased phosphorylase activity and sustained ATP levels throughout a 7 h time course. However, induction of apoptosis with staurosporine, also a potent PhK inhibitor, led to a rapid loss in phosphorylase activity and intracellular ATP, suggesting that PhK inhibition by staurosporine impairs the ability of apoptotic muscle cells to generate ATP. Thus, these studies indicate that PhK may be a substrate for caspase regulation during apoptosis and suggest that activation of this enzyme may be important for the generation of ATP during programmed cell death.

Insulin-independent pathways mediating glucose uptake in hindlimb-suspended skeletal muscle.

Insulin resistance accompanies atrophy in slow-twitch skeletal muscles such as the soleus. Using a rat hindlimb suspension model of atrophy, we have previously shown that an upregulation of JNK occurs in atrophic muscles and correlates with the degradation of insulin receptor substrate-1 (IRS-1) (Hilder TL, Tou JC, Grindeland RF, Wade CE, and Graves LM. FEBS Lett 553: 63-67, 2003), suggesting that insulin-dependent glucose uptake may be impaired. However, during atrophy, these muscles preferentially use carbohydrates as a fuel source. To investigate this apparent dichotomy, we examined insulin-independent pathways involved in glucose uptake following a 2- to 13-wk hindlimb suspension regimen. JNK activity was elevated throughout the time course, and IRS-1 was degraded as early as 2 wk. AMP-activated protein kinase (AMPK) activity was significantly higher in atrophic soleus muscle, as were the activities of the ERK1/2 and p38 MAPKs. As a comparison, we examined the kinase activity in solei of rats exposed to hypergravity conditions (2 G). IRS-1 phosphorylation, protein, and AMPK activity were not affected by 2 G, demonstrating that these changes were only observed in soleus muscle from hindlimb-suspended animals. To further examine the effect of AMPK activation on glucose uptake, C2C12 myotubes were treated with the AMPK activator metformin and then challenged with the JNK activator anisomycin. While anisomycin reduced insulin-stimulated glucose uptake to control levels, metformin significantly increased glucose uptake in the presence of anisomycin and was independent of insulin. Taken together, these results suggest that AMPK may be an important mediator of insulin-independent glucose uptake in soleus during skeletal muscle atrophy.

Phosphorylation of insulin receptor substrate-1 serine 307 correlates with JNK activity in atrophic skeletal muscle.

c-Jun NH(2)-terminal kinase (JNK) has been shown to negatively regulate insulin signaling through serine phosphorylation of residue 307 within the insulin receptor substrate-1 (IRS-1) in adipose and liver tissue. Using a rat hindlimb suspension model for muscle disuse atrophy, we found that JNK activity was significantly elevated in atrophic soleus muscle and that IRS-1 was phosphorylated on Ser(307) prior to the degradation of the IRS-1 protein. Moreover, we observed a corresponding reduction in Akt activity, providing biochemical evidence for the development of insulin resistance in atrophic skeletal muscle.