Discovery of highly potent small molecule kallikrein inhibitors.

Uncontrolled kallikrein activation is involved in diseases such as hereditary angioedema, bacterial septic shock and procedures such as cardiopulmonary bypass. Here we report a series of small molecule compounds that potently inhibit kallikrein activity in vitro. Kinetic studies indicate that some of these compounds are slow binding inhibitors of kallikrein with Ki final less than a nanomolar. The ability of these compounds to inhibit the activity of kallikrein was further confirmed in a plasma model by quantitating the release of bradykinin, an endogenous cleavage product of plasma kallikrein. To understand the inhibitory mechanism of the selected compounds toward kallikrein, the interactions between the selected compounds and kallikrein was explored using molecular modeling based on the information of crystal structures of TF/FVIIa and kallikrein. The information presented in the current study provides an initial approach to develop more selective and therapeutically useful small molecule inhibitors.

Interaction of the growth hormone receptor cytoplasmic domain with the JAK2 tyrosine kinase.

An early step in GH action involves tyrosine phosphorylation of various cellular proteins. Recently, it has been shown in murine preadipocytes that GH promotes the association of its receptor (the GHR) with and the activation of the JAK2 tyrosine kinase. In this study, we confirmed the human (h) GH-induced association of JAK2 with hGHR in IM-9 cells by coimmunoprecipitation experiments using anti-hGHR serum. We further examined the interaction of JAK2 with the GHR cytoplasmic domain by two lines of investigation. For in vitro studies, we assayed by immunoblotting the ability of cell-derived JAK2 to interact with glutathione S-transferase fusion proteins containing elements of the hGHR cytoplasmic domain. A fusion protein containing the entire hGHR cytoplasmic domain (residues 271-620) specifically associated with JAK2 independent of prior stimulation of cells with hGH. This interaction was not dependent on tyrosine phosphorylation of either partner. Mutational analysis of the hGHR cytoplasmic domain component of the fusions indicated that a membrane-proximal 20-residue region that includes the proline-rich box 1 was necessary for the interaction. This region appeared to cooperate with another region(s), largely in the N-terminal one third of the cytoplasmic domain, to promote full interaction with JAK2. For in vivo reconstitution experiments, wild-type (WT) and mutant rabbit GHRs (rGHRs) along with murine JAK2 were expressed by transient transfection in COS-7 cells. rGHR mutations were confined to the cytoplasmic domain and included C-terminal truncations as well as internal deletions of residues 297-406 and 278-292 (the latter contains box 1). All mutant rGHRs were expressed at the cell surface and bound hGH to a degree similar to the WT rGHR. Receptors were tested for their ability to mediate the hGH-induced immunoprecipitability of JAK2 with phosphotyrosine (APT) antibodies. A rGHR truncated to residue 275 [rGHR-(1-275)], which contains only five cytoplasmic residues, failed to mediate JAK2 APT precipitability in response to hGH. In contrast, WT rGHR; the C-terminal truncations rGHR-(1-542), rGHR-(1-390), and rGHR-(1-317); and the rGHR-(d297-406) deletion mutant maintained this ability. Deletion of the 278-292 box 1-containing region in the context of either rGHR-(d297-406) or WT rGHR eliminated detectable hGH-induced JAK2 APT precipitability. Interestingly, rGHR-(1-292), which includes box 1, was not able to mediate significant hGH-induced JAK2 APT precipitability.(ABSTRACT TRUNCATED AT 400 WORDS)

Urinary bladder transitional cell papilloma in a shorthorn heifer.

A 12-month-old shorthorn heifer was presented for pollakiuria of 4 months' duration. Urinary bladder transitional cell papilloma was diagnosed. The heifer had no exposure to bracken fern and no papillomavirus or bacterium was demonstrated. Laser surgery was used in an attempt to debulk the mass.

The microtubule-associated protein tau is extensively modified with O-linked N-acetylglucosamine.

Tau is a family of phosphoproteins that are important in modulating microtubule stability in neurons. In Alzheimer's disease tau is abnormally hyperphosphorylated, no longer binds microtubules, and self-assembles to form paired helical filaments that likely contribute to neuron death. Here we demonstrate that normal bovine tau is multiply modified by Ser(Thr)-O-linked N-acetylglucosamine, a dynamic and abundant post-translational modification that is often reciprocal to Ser(Thr)-phosphorylation. O-GlcNAcylation of tau was demonstrated by blotting with succinylated wheat germ agglutinin and by probing with bovine milk beta(1,4)galactosyltransferase. Structural analyses confirm the linkage and the saccharide structure. Tau splicing variants are multiply O-GlcNAcylated at similar sites, with an average stoichiometry of greater than 4 mol of O-linked N-acetylglucosamine/mol of tau. However, the number of sites occupied appears to be greater than 12, suggesting substoichiometric occupancy at any given site. A similar relationship between average stoichiometry and site-occupancy has also been described for the phosphorylation of tau. Site-specific or stoichiometric changes in O-GlcNAcylation may not only modulate tau function but may also play a role in the formation of paired helical filaments.

Hepatic metabolism of oxidatively modified apo E-free high-density lipoproteins.

AIMS/BACKGROUND: The metabolism of rat apo E-free high-density lipoproteins (HDL) was contrasted with oxidatively modified apo E-free high-density lipoproteins (OX-HDL) in the rat hepatoma cell, Fu5AH. RESULTS: When 10-100 microg/ml [125I]-HDL or [125I]-OX-HDL were incubated with cells for 4 h at 37 degrees C, cellular uptake of oxidized lipoproteins was twice control. In contrast, protein degradation was equal. [125I]-HDL or [125I]-OX-HDL were incubated with the cells for 4 h followed by a 4 h chase with unlabeled HDL and OX-HDL, respectively. In these experiments, 80% of [125I]-HDL was resecreted from the cell within 30 min while 50% of [125I]-OX-HDL was retained by the cell after 2 h. Electron microscopy was used to determine if the OX-HDL was retained in lysosomes. Cells were incubated with gold-labeled OX-HDL, and lysosomes were stained with acid phosphatase. Gold-labeled OX-HDL was abundant in intracellular vesicles that were not reactive to acid phosphatase. However, vesicles with a high content of OX-HDL frequently stained positively for 3,3'-diaminobenzidine, a stain that reacts with catalase and is used to detect peroxisomes. CONCLUSIONS: The present evidence indicates that the cellular metabolism of OX-HDL is different from that of unmodified HDL.