Structural analysis reveals pathomechanisms associated with pseudoxanthoma elasticum-causing mutations in the ABCC6 transporter.

Mutations in ABC subfamily C member 6 (ABCC6) transporter are associated with pseudoxanthoma elasticum (PXE), a disease resulting in ectopic mineralization and affecting multiple tissues. A growing number of mutations have been identified in individuals with PXE. For most of these variants, no mechanistic information is available regarding their role in normal and pathophysiologies. To assess how PXE-associated mutations alter ABCC6 biosynthesis and structure, we biophysically and biochemically evaluated the N-terminal nucleotide-binding domain. A high-resolution X-ray structure of nucleotide-binding domain 1 (NBD1) of human ABCC6 was obtained at 2.3 Å that provided a template on which to evaluate PXE-causing mutations. Biochemical analysis of mutations in this domain indicated that multiple PXE-causing mutations altered its structural properties. Analyses of the full-length protein revealed a strong correlation between the alterations in NBD properties and the processing and expression of ABCC6. These results suggest that a significant fraction of PXE-associated mutations located in NBD1 causes changes in its structural properties and that these mutation-induced alterations directly affect the maturation of the full-length ABCC6 protein.

Stabilization of Nucleotide Binding Domain Dimers Rescues ABCC6 Mutants Associated with Pseudoxanthoma Elasticum.

ABC transporters are polytopic membrane proteins that utilize ATP binding and hydrolysis to facilitate transport across biological membranes. Forty-eight human ABC transporters have been identified in the genome, and the majority of these are linked to heritable disease. Mutations in the ABCC6 (ATP binding cassette transporter C6) ABC transporter are associated with pseudoxanthoma elasticum, a disease of altered elastic properties in multiple tissues. Although ∼200 mutations have been identified in pseudoxanthoma elasticum patients, the underlying structural defects associated with the majority of these are poorly understood. To evaluate the structural consequences of these missense mutations, a combination of biophysical and cell biological approaches were applied to evaluate the local and global folding and assembly of the ABCC6 protein. Structural and bioinformatic analyses suggested that a cluster of mutations, representing roughly 20% of the patient population with identified missense mutations, are located in the interface between the transmembrane domain and the C-terminal nucleotide binding domain. Biochemical and cell biological analyses demonstrate these mutations influence multiple steps in the biosynthetic pathway, minimally altering local domain structure but adversely impacting ABCC6 assembly and trafficking. The differential impacts on local and global protein structure are consistent with hierarchical folding and assembly of ABCC6. Stabilization of specific domain-domain interactions via targeted amino acid substitution in the catalytic site of the C-terminal nucleotide binding domain restored proper protein trafficking and cell surface localization of multiple biosynthetic mutants. This rescue provides a specific mechanism by which chemical chaperones could be developed for the correction of ABCC6 biosynthetic defects.

Axial ligand replacement mechanism in heme transfer from streptococcal heme-binding protein Shp to HtsA of the HtsABC transporter.

The heme-binding protein Shp of Group A Streptococcus rapidly transfers its heme to HtsA, the lipoprotein component of the HtsABC transporter, in a concerted two-step process with one kinetic phase. Heme axial residue-to-alanine replacement mutant proteins of Shp and HtsA (Shp(M66A), Shp(M153A), HtsA(M79A), and HtsA(H229A)) were used to probe the axial displacement mechanism of this heme transfer reaction. Ferric Shp(M66A) at high pH and Shp(M153A) have a pentacoordinate heme iron complex with a methionine axial ligand. ApoHtsA(M79A) efficiently acquires heme from ferric Shp but alters the reaction mechanism to two kinetic phases from a single phase in the wild-type protein reactions. In contrast, apoHtsA(H229A) cannot assimilate heme from ferric Shp. The conversion of pentacoordinate holoShp(M66A) into pentacoordinate holoHtsA(H229A) involves an intermediate, whereas holoHtsA(H229A) is directly formed from pentacoordinate holoShp(M153A). Conversely, apoHtsA(M79A) reacts with holoShp(M66A) and holoShp(M153A) in mechanisms with one and two kinetic phases, respectively. These results imply that the Met79 and His229 residues of HtsA displace the Met66 and Met153 residues of Shp, respectively. Structural docking analysis supports this mechanism of the specific axial residue displacement. Furthermore, the rates of the cleavage of the axial bond in Shp in the presence of a replacing HtsA axial residue are greater than that in the absence of a replacing HtsA axial residue. These findings reveal a novel heme transfer mechanism of the specific displacement of the Shp axial residues with the HtsA axial residues and the involvement of the HtsA axial residues in the displacement.

Type 1 interferons suppress accelerated osteoclastogenesis and prevent loss of bone mass during systemic inflammatory responses to Pneumocystis lung infection.

HIV infection causes loss of CD4(+) T cells and type 1 interferon (IFN)-producing and IFN-responsive dendritic cells, resulting in immunodeficiencies and susceptibility to opportunistic infections, such as Pneumocystis. Osteoporosis and bone marrow failure are additional unexplained complications in HIV-positive patients and patients with AIDS, respectively. We recently demonstrated that mice that lack lymphocytes and IFN a/b receptor (IFrag(-/-)) develop bone marrow failure after Pneumocystis lung infection, whereas lymphocyte-deficient, IFN α/ß receptor-competent mice (RAG(-/-)) had normal hematopoiesis. Interestingly, infected IFrag(-/-) mice also exhibited bone fragility, suggesting loss of bone mass. We quantified bone changes and evaluated the potential connection between progressing bone fragility and bone marrow failure after Pneumocystis lung infection in IFrag(-/-) mice. We found that Pneumocystis infection accelerated osteoclastogenesis as bone marrow failure progressed. This finding was consistent with induction of osteoclastogenic factors, including receptor-activated nuclear factor-κB ligand and the proapoptotic factor tumor necrosis factor-related apoptosis-inducing ligand, in conjunction with their shared decoy receptor osteoprotegerin, in the bone marrow of infected IFrag(-/-) mice. Deregulation of this axis has also been observed in HIV-positive individuals. Biphosphonate treatment of IFrag(-/-) mice prevented bone loss and protected loss of hematopoietic precursor cells that maintained activity in vitro but did not prevent loss of mature neutrophils. Together, these data show that bone loss and bone marrow failure are partially linked, which suggests that the deregulation of the receptor-activated nuclear factor-κB ligand/osteoprotegerin/tumor necrosis factor-related apoptosis-inducing ligand axis may connect the two phenotypes in our model.

Spectroscopic identification of heme axial ligands in HtsA that are involved in heme acquisition by Streptococcus pyogenes.

The heme-binding proteins Shp and HtsA of Streptococcus pyogenes are part of the heme acquisition machinery in which Shp directly transfers its heme to HtsA. Mutagenesis and spectroscopic analyses were performed to identify the heme axial ligands in HtsA and to characterize axial mutants of HtsA. Replacements of the M79 and H229 residues, not the other methionine and histidine residues, with alanine convert UV-vis spectra of HtsA with a low-spin, hexacoordinate heme iron into spectra of high-spin heme complexes. Ferrous M79A and H229A HtsA mutants possess magnetic circular dichroism (MCD) spectra that are similar with those of proteins with pentacoordinate heme iron. Ferric M79A HtsA displays UV-vis, MCD, and resonance Raman (RR) spectra that are typical of a hexacoordinate heme iron with histidine and water ligands. In contrast, ferric H229A HtsA has UV-vis, MCD, and RR spectra that represent a pentacoordinate heme iron complex with a methionine axial ligand. Imidazole readily forms a low-spin hexacoordinate adduct with M79A HtsA with a K(d) of 40.9 muM but not with H229A HtsA, and cyanide binds to M79A and H229A with K(d) of 0.5 and 19.1 microM, respectively. The ferrous mutants rapidly bind CO and form simple CO complexes. These results establish the H229 and M79 residues as the axial ligands of the HtsA heme iron, indicate that the M79 side is more accessible to the solvent than the H229 side of the bound heme in HtsA, and provide unique spectral features for a protein with pentacoordinate, methionine-ligated heme iron. These findings will facilitate elucidation of the molecular mechanism and structural basis for rapid and direct heme transfer from Shp to HtsA.

Bis-methionine ligation to heme iron in the streptococcal cell surface protein Shp facilitates rapid hemin transfer to HtsA of the HtsABC transporter.

The surface protein Shp of Streptococcus pyogenes rapidly transfers its hemin to HtsA, the lipoprotein component of the HtsABC transporter, in a concerted two-step process with one kinetic phase. The structural basis and molecular mechanism of this hemin transfer have been explored by mutagenesis and truncation of Shp. The heme-binding domain of Shp is in the amino-terminal region and is functionally active by itself, although inclusion of the COOH-terminal domain speeds up the process approximately 10-fold. Single alanine replacements of the axial methionine 66 and 153 ligands (Shp(M66A) and Shp(M153A)) cause formation of pentacoordinate hemin-Met complexes. The association equilibrium constants for hemin binding to wild-type, M66A, and M153A Shp are 5,300, 22,000, and 38 microM(-1), respectively, showing that the Met(153)-Fe bond is critical for high affinity binding and that Met(66) destabilizes hemin binding to facilitate its rapid transfer. Shp(M66A) and Shp(M153A) rapidly bind to hemin-free HtsA (apoHtsA), forming stable transfer intermediates. These intermediates appear to be Shp-hemin-HtsA complexes with one axial ligand from each protein and decay to the products with rate constants of 0.4-3 s(-1). Thus, the M66A and M153A replacements alter the kinetic mechanism and unexpectedly slow down hemin transfer by stabilizing the intermediates. These results, in combination with the structure of the Shp heme-binding domain, allow us to propose a "plug-in" mechanism in which side chains from apoHtsA are inserted into the axial positions of hemin in Shp to extract it from the surface protein and pull it into the transporter active site.

Inhibiting severe acute respiratory syndrome-associated coronavirus by small interfering RNA.

OBJECTIVE: To evaluate the effectiveness of small interfering RNA (siRNA) on inhibiting severe acute respiratory syndrome (SARS)-associated coronavirus replication, and to lay bases for the future clinical application of siRNA for the treatment of viral infectious diseases. METHODS: Vero-E6 cells was transfected with siRNA before SARS virus infection, and the effectiveness of siRNA interference was evaluated by observing the cytopathic effect (CPE) on Vero-E6 cells. RESULTS: Five pairs of siRNA showed ability to reduce CPE dose dependently, and two of them had the best effect. CONCLUSION: siRNA may be effective in inhibiting SARS-associated coronavirus replication.

[Influence of the reductase deficient Escherichia coli on the solubility of recombinant proteins produced in it].

The cytoplasm of E. coli is a reducing environment where cysteines do not engage in disulfide bonds. Any disulfide bonds that do appear are rapidly reduced through the action of disulfide reducing enzymes such as thioredoxin and glutaredoxin. To study the influence of E. coli cytoplasm on the solubility of recombinant proteins produced in it, bovine fibroblast growth factor (BbFGF), with single disulfide bond, and anti-HBsAg single-chain Fv (HBscFv), with two disulfide bonds, were selected as the pattern molecules of simple protein and complex protein, respectively. pJN98-BbFGF, a BbFGF expressing plasmid based on the vector pET3c, was constructed and transformed into normal host BL21(DE3) and a reductase deficient strain, E. coli Origami(DE3). At the same time, pQE-HBscFv, a HBscFv expressing plasmid was constructed and transformed into M15 [pREP4] and Origami(DE3). The recombinant BbFGF and HBscFv were produced in 2 types of bacteria and their solubilities and bioactivities were determined, respectively. It was found that the majority of BbFGF had formed inclusion body in the cytoplasm of BL21 (DE3) and all of them turned into soluble protein in Origami(DE3). It was also found the productivity of BbFGF in Origami (DE3) was 5% - 10% of the total protein and the value was 15% - 23% in BL21(DE3). BbFGFs produced in 2 recombinant bacteria were purified by cation exchange and heparin affinity chromatography. MTT assay revealed that the bioactivity of BbFGF purified from Origami(DE3) was higher than its counterpart from BL21(DE3). The ED50 of BbFGFs from different bacteria was 1.6ng/mL and 2.2ng/mL, respectively. As far as HBscFvs, both of them formed inclusion body in the cytoplasm of M15 [pQE-HBscFv] and Origami [pQE-HBscFv]. The inclusion body was solubilized in 6mol/L GuHCl, purified with a His-Trap column and then refolded by dialysis step-by-step against buffers containing downtrend concentration of GuHCl. Indirect ELISA was applied to determine the HBsAg binding activity of HBscFvs. It was found there was no obvious difference between the bioactivity of refolded HBscFvs produced from 2 recombinant bacteria. On the other hand, the supernatant of Origami [pQE-HBscFv] lysate displayed weak bioactivity and its counterpart from M15 [pQE-HBscFv] displayed without any bioactivity. The soluble HBsFv in the cytoplasm of Origami [pQE-HBscFv] was purified by cation exchange and immobilized metal affinity chromatography (IMAC) and the yield was 1 - 2mg/L. Those results suggested that modification of the redox environment of E. coli cytoplasm greatly improved the solubility of recombinant disulfide-bonded proteins produced in it. In the next step, we had like to co-express of molecular chaperones or refoldase to raise the yield of soluble recombinant proteins, as well as optimizing the culture condition of the "oxidizing" E. coli.