The generation and analyses of a novel combination of recombinant adenovirus vaccines targeting three tumor antigens as an immunotherapeutic.

Phenotypic heterogeneity of human carcinoma lesions, including heterogeneity in expression of tumor-associated antigens (TAAs), is a well-established phenomenon. Carcinoembryonic antigen (CEA), MUC1, and brachyury are diverse TAAs, each of which is expressed on a wide range of human tumors. We have previously reported on a novel adenovirus serotype 5 (Ad5) vector gene delivery platform (Ad5 [E1-, E2b-]) in which regions of the early 1 (E1), early 2 (E2b), and early 3 (E3) genes have been deleted. The unique deletions in this platform result in a dramatic decrease in late gene expression, leading to a marked reduction in host immune response to the vector. Ad5 [E1-, E2b-]-CEA vaccine (ETBX-011) has been employed in clinical studies as an active vaccine to induce immune responses to CEA in metastatic colorectal cancer patients. We report here the development of novel recombinant Ad5 [E1-, E2b-]-brachyury and-MUC1 vaccine constructs, each capable of activating antigen-specific human T cells in vitro and inducing antigen-specific CD4+ and CD8+ T cells in vaccinated mice. We also describe the use of a combination of the three vaccines (designated Tri-Ad5) of Ad5 [E1-, E2b-]-CEA, Ad5 [E1-, E2b-]-brachyury and Ad5 [E1-, E2b-]-MUC1, and demonstrate that there is minimal to no "antigenic competition" in in vitro studies of human dendritic cells, or in murine vaccination studies. The studies reported herein support the rationale for the application of Tri-Ad5 as a therapeutic modality to induce immune responses to a diverse range of human TAAs for potential clinical studies.

Investigation of the biophysical and cell biological properties of ferroportin, a multipass integral membrane protein iron exporter.

Ferroportin is a multipass membrane protein that serves as an iron exporter in many vertebrate cell types. Ferroportin-mediated iron export is controlled by the hormone hepcidin, which binds ferroportin, causing its internalization and degradation. Mutations in ferroportin cause a form of the iron overload hereditary disease hemochromatosis. Relatively little is known about ferroportin's properties or the mechanism by which mutations cause disease. In this study, we expressed and purified human ferroportin to characterize its biochemical/biophysical properties in solution and conducted cell biological studies in mammalian cells. We found that purified detergent-solubilized ferroportin is a well-folded monomer that binds hepcidin. In cell membranes, the N- and C-termini were both cytosolic, implying an even number of transmembrane regions, and ferroportin was mainly localized to the plasma membrane. Hepcidin addition resulted in a redistribution of ferroportin to intracellular compartments that labeled with early endosomal and lysosomal, but not Golgi, markers and that trafficked along microtubules. An analysis of 16 disease-related ferroportin mutants revealed that all were expressed and trafficked to the plasma membrane but that some were resistant to hepcidin-induced internalization. The characterizations reported here form a basis upon which models for ferroportin's role in regulating iron homeostasis in health and disease can be interpreted.

Crystal structures, metal activation, and DNA-binding properties of two-domain IdeR from Mycobacterium tuberculosis.

The iron-dependent regulator IdeR is a key transcriptional regulator of iron uptake in Mycobacterium tuberculosis. In order to increase our insight into the role of the SH3-like third domain of this essential regulator, the metal-binding and DNA-binding properties of two-domain IdeR (2D-IdeR) whose SH3-like domain has been truncated were characterized. The equilibrium dissociation constants for Co2+ and Ni2+ activation of 2D-IdeR for binding to the fxbA operator and the DNA-binding affinities of 2D-IdeR in the presence of excess metal ions were estimated using fluorescence spectroscopy. 2D-IdeR binds to fxbA operator DNA with similar affinity as full-length IdeR in the presence of excess metal ion. However, the Ni2+ concentrations required to activate 2D-IdeR for DNA binding appear to be smaller than that for full-length IdeR while the concentration of Co2+ required for activation remains the same. We have determined the crystal structures of Ni2+-activated 2D-IdeR at 1.96 A resolution and its double dimer complex with the mbtA-mbtB operator DNA in two crystal forms at 2.4 A and 2.6 A, the highest resolutions for DNA complexes for any structures of iron-dependent regulator family members so far. The 2D-IdeR-DNA complex structures confirm the specificity of Ser37 and Pro39 for thymine bases and suggest preferential contacts of Gln43 to cytosine bases of the DNA. In addition, our 2D-IdeR structures reveal a remarkable property of the TEV cleavage sequence remaining after removal of the C-terminal His6. This C-terminal tail promotes crystal contacts by forming a beta-sheet with the corresponding tail of neighboring subunits in two unrelated structures of 2D-IdeR, one with and one without DNA. The contact-promoting properties of this C-terminal TEV cleavage sequence may be beneficial for crystallizing other proteins.

Structures of Mycobacterium tuberculosis DosR and DosR-DNA complex involved in gene activation during adaptation to hypoxic latency.

On encountering low oxygen conditions, DosR activates the transcription of 47 genes, promoting long-term survival of Mycobacterium tuberculosis in a non-replicating state. Here, we report the crystal structures of the DosR C-terminal domain and its complex with a consensus DNA sequence of the hypoxia-induced gene promoter. The DosR C-terminal domain contains four alpha-helices and forms tetramers consisting of two dimers with non-intersecting dyads. In the DNA-bound structure, each DosR C-terminal domain in a dimer places its DNA-binding helix deep into the major groove, causing two bends in the DNA. DosR makes numerous protein-DNA base contacts using only three amino acid residues per subunit: Lys179, Lys182, and Asn183. The DosR tetramer is unique among response regulators with known structures.

The crystal structure of the periplasmic domain of the type II secretion system protein EpsM from Vibrio cholerae: the simplest version of the ferredoxin fold.

The terminal branch of the general secretion pathway (Gsp or type II secretion system) is used by several pathogenic bacteria for the secretion of their virulence factors across the outer membrane. In these secretion systems, a complex of 12-15 Gsp proteins spans from the pore in the outer membrane via several associated signal or energy-transducing proteins in the inner membrane to a regulating ATPase in the cytosol. The human pathogen Vibrio cholerae uses such a system, called the Eps system, for the export of the cholera toxin and other virulence factors from its periplasm into the lumen of the gastrointestinal tract of the host. Here, we report the atomic structure of the periplasmic domain of the EpsM protein from V.cholerae, which is a part of the interface between the regulating part and the rest of the Eps system. The crystal structure was determined by Se-Met MAD phasing and the model was refined to 1.7A resolution. The monomer consists of two alphabetabeta-subdomains forming a sandwich of two alpha-helices and a four-stranded antiparallel beta-sheet. In the dimer, a deep cleft with a polar rim and a hydrophobic bottom made by conserved residues is located between the monomers. This cleft contains an extra electron density suggesting that this region might serve as a binding site of an unknown ligand or part of a protein partner. Unexpectedly, the fold of the periplasmic domain of EpsM is an undescribed circular permutation of the ferredoxin fold.

Intramolecular dephosphorylation of ERK by MKP3.

The dual specificity mitogen-activated protein kinase phosphatase MKP3 downregulates mitogenic signaling through dephosphorylation of extracellular signal-regulated kinase (ERK). Like other MKPs, MKP3 consists of a noncatalytic N-terminal domain and a catalytic C-terminal domain. ERK binding to the N-terminal noncatalytic domain of MKP3 has been shown to increase (up to 100-fold) the catalytic activity of MKP3 toward small artificial substrates. Here, we address the function of the N-terminal domain of MKP3 in either inter- or intramolecular dephosphorylation of pERK (phosphorylated ERK) and the stoichiometry of the MKP3/pERK Michaelis complex. These are important mechanistic distinctions given the observation that ERK exists in a monomer/dimer equilibrium that is shifted toward the dimer when phosphorylated and given that MKP3 undergoes catalytic activation toward other substrates when bound to ERK. Wild-type and engineered mutants of ERK and MKP3, binding analyses, reaction kinetics, and chemical cross-linking studies were used to demonstrate that the monomer of MKP3 binds to the monomeric form of pERK and that MKP3 within the resulting heterodimer performs intramolecular dephosphorylation of pERK. This study provides the first direct evidence that MKP3 utilizes intramolecular dephosphorylation between a complex consisting of one molecule each of MKP3 and ERK. Catalytic activation and substrate tethering by MKP3 lead to a >or=4000-fold rate enhancement (k(cat)/K(m)) for dephosphorylation of pERK.

Structural basis for the recognition of a bisphosphorylated MAP kinase peptide by human VHR protein Phosphatase.

Human VHR (vaccinia H1 related phosphatase) is a member of the dual-specificity phosphatases (DSPs) that often act on bisphosphorylated protein substrates. Unlike most DSPs, VHR displays a strong preference for dephosphorylating phosphotyrosine residues over phosphothreonine residues. Here we describe the 2.75 A crystal structure of the C124S inactive VHR mutant in complex with a bisphosphorylated peptide corresponding to the MAP kinase activation lip. This structure and subsequent biochemical studies revealed the basis for the strong preference for hydrolyzing phosphotyrosine within bisphosphorylated substrates containing -pTXpY-. In the structure, the two phospho residues are oriented into distinct pockets; the phosphotyrosine is bound in the exposed yet deep active site cleft while the phosphothreonine is loosely tethered into a nearby basic pocket containing Arg(158). As this structure is the first substrate-enzyme complex reported for the DSP family of enzymes, these results provide the first glimpse into how DSPs bind their protein substrates.