The RKIP (Raf-1 Kinase Inhibitor Protein) conserved pocket binds to the phosphorylated N-region of Raf-1 and inhibits the Raf-1-mediated activated phosphorylation of MEK.

The Raf-MEK-ERK pathway regulates many fundamental biological processes, and its activity is finely tuned at multiple levels. The Raf kinase inhibitory protein (RKIP) is a widely expressed negative modulator of the Raf-MEK-ERK signaling pathway. We have previously shown that RKIP inhibits the phosphorylation of MEK by Raf-1 through interfering with the formation of a kinase-substrate complex by direct binding to both Raf-1 and MEK. Here, we show that the evolutionarily conserved ligand-binding pocket of RKIP is required for its inhibitory activity towards the Raf-1 kinase mediated activation of MEK. Single amino acid substitutions of two of the conserved residues form the base and the wall of the pocket confers a loss-of-function phenotype on RKIP. Loss-of-function RKIP mutants still appear to bind to Raf-1. However the stability of the complexes formed between mutants and the N-region Raf-1 phosphopeptide were drastically reduced. Our results therefore suggest that the RKIP conserved pocket may constitute a novel phosphoamino-acid binding motif and is absolutely required for RKIP function.

Human platelet 12-lipoxygenase, new findings about its activity, membrane binding and low-resolution structure.

Human platelet 12-lipoxygenase (hp-12LOX, 662 residues+iron nonheme cofactor) and its major metabolite 12S-hydroxyeicosatetraenoic acid have been implicated in cardiovascular and renal diseases, many types of cancer and inflammatory responses. However, drug development is slow due to a lack of structural information. The major hurdle in obtaining a high-resolution X-ray structure is growing crystals, a process that requires the preparation of highly homogenous, reproducible and stable protein samples. To understand the properties of hp-12LOX, we have expressed and studied the behavior, function and low-resolution structure of the hp-12LOX His-tagged recombinant enzyme and its mutants in solution. We have found that it is a dimer easily converted into bigger aggregates, which are soluble/covalent-noncovalent/reversible. The heavier oligomers show a higher activity at pH 8, in contrast to dimers with lower activity showing two maxima at pH 7 and pH 8, indicating the existence of two different conformers. In the seven-point C-->S mutant, aggregation is diminished, activity has one broad peak at pH 8 and there is no change in specificity. Truncation of the N(t)-beta-barrel domain (PLAT, residues 1-116) reduces activity to approximately 20% of that shown by the whole enzyme, does not affect regio- or stereospecificity and lowers membrane binding by a factor of approximately 2. "NoPLAT" mutants show strong aggregation into oligomers containing six or more catalytic domains regardless of the status of the seven cysteine residues tested. Time-of-flight mass spectrometry suggests two arachidonic acid molecules bound to one molecule of enzyme. Small angle X-ray scattering studies (16 A resolution, chi approximately 1) suggest that two hp-12LOX monomers are joined by the catalytic domains, with the PLAT domains floating on the flexible linkers away from the main body of the dimer.

Mechanisms of adeno-associated virus genome encapsidation.

The defective parvovirus, adeno-associated virus (AAV), is under close scrutiny as a human gene therapy vector. AAV's non-pathogenic character, reliance on helper virus co-infection for replication and wide tissue tropism, make it an appealing vector system. The virus' simplicity and ability to generate high titer vector preparations have contributed to its wide spread use in the gene therapy community. The single stranded AAV DNA genome is encased in a 20-25 nm diameter, icosahedral protein capsid. Assembly of AAV occurs in two distinct phases. First, the three capsid proteins, VP1-3, are rapidly synthesized and assembled into an empty virion in the nucleus. In the second, rate-limiting phase, single-strand genomic DNA is inserted into pre-formed capsids. Our rudimentary knowledge of these two phases comes from radioactive labeling pulse-chase experiments, cellular fractionation and immunocytological analysis of infected cells. Although the overall pattern of virus assembly and encapsidation is known, the biochemical mechanisms involved in these processes are not understood. Elucidation of the processes of capsid assembly and encapsidation may lead to improved vector production. While all of the parvoviruses share the characteristic icosahedral particle, differences in their surface topologies dictate different receptor binding and tissue tropism. Based on the analysis of the molecular structures of the parvoviruses and capsid mutagenesis studies, investigators have manipulated the capsid to change tissue tropism and to target different cell types, thus expanding the targeting potential of AAV vectors.