The structure of chloroplast cytochrome c6 at 1.9 A resolution: evidence for functional oligomerization.

The molecular structure of cytochrome c6 from the green alga Chlamydomonas reinhardtii has been determined from two crystal forms and refined to 1.9 A resolution. The two crystal forms are likely the result of different levels of post-translational modification of the protein. This is the first report of a high-resolution structure of a chloroplast-derived class I c-type cytochrome. The overall fold is similar to that of other class I c-type cytochromes, consisting of a series of alpha-helices and turns that envelop the heme prosthetic group. There is also a short two-stranded anti-parallel beta-sheet in the vicinity of the methionine axial ligand to the heme; this region of the molecule is formed by the most highly conserved residues in c6-type cytochromes. Although class I c-type cytochromes are assumed to function as monomers, both crystal forms of cytochrome c6 exhibit oligomerization about the heme crevice that is, in part, mediated by the short anti-parallel beta-sheet. The functional significance of this oligomerization is supported by the appearance of similar interfaces in other electron transfer couples, HPLC and light-scattering data, and is furthermore consistent with kinetic data on electron transfer reactions of c6-type cytochromes.

Hepatocyte growth factor and macrophage inflammatory protein 1 beta: structurally distinct cytokines that induce rapid cytoskeletal changes and subset-preferential migration in T cells.

T-cell migration into tissue depends on a cascade of rapid and selective adhesive interactions with endothelium. "Triggering" is a step in that cascade required to activate T-cell integrins. Hepatocyte growth factor (HGF) may be a physiologically relevant trigger, since we demonstrate that HGF can induce both adhesion and migration of human T-cell subsets and can be detected immunohistochemically on inflamed endothelium. HGF preferentially induces responses from T cells of memory phenotype, in contrast to macrophage inflammatory protein 1 beta (MIP-1 beta), a chemokine which acts preferentially on naive cells. HGF, like the chemokines, binds to heparin, and HGF retained in extracellular matrix is efficient in promoting migration. Further, both MIP-1 beta and HGF induce actin polymerization within seconds, kinetics that approach those required to contribute to physiologic triggering. HGF is a member of a structural family distinct from the chemokines, whose only known receptor is the tyrosine kinase c-Met. HGF induces tyrosine phosphorylation on T cells apparently via a distinct receptor, since no c-Met is detectable by surface staining, PCR, or anti-phosphotyrosine immunoprecipitation. Thus, promotion of T-cell adhesion and migration are previously undescribed functions of HGF that we propose are relevant to selective T-cell recruitment.