Eiji Majima

Expression of the bovine heart mitochondrial ADP/ATP carrier in yeast mitochondria: significantly enhanced expression by replacement of the N-terminal region of the bovine carrier by the corresponding regions of the yeast carriers

To characterize the transport mechanism mediated by the mammalian mitochondrial ADP/ATP carrier (AAC), we tried to express bovine heart mitochondrial AAC (bhAAC) in Saccharomyces cerevisiae. The open reading frame of the bhAAC was introduced into the haploid strain WB-12, in which intrinsic AAC genes were disrupted. Growth of the transformant was very low in glycerol medium, and a little amount of bhAAC was detected in the mitochondrial membrane. For improvement of bhAAC expression in WB-12, we introduced DNA fragments encoding chimeric bhAACs, in which the N-terminal region of the bhAAC extending into the cytosol was replaced by the corresponding regions of the type 1 and type 2 yeast AAC isoforms (yAAC1 and yAAC2). These transformants grew well, and the amounts of the chimeric bhAACs in their mitochondria were as high as that of yAAC2. The carriers expressed showed essentially the same ADP transport activities as that of AAC in bovine heart mitochondria.

Domain organization and movements in heavy metal ion pumps : Papain digestion of copa, A Cu+ -TRANSPORTING ATPase

To study domain organization and movements in the reaction cycle of heavy metal ion pumps, CopA, a bacterial Cu+-ATPase from Thermotoga maritima was cloned, overexpressed, and purified, and then subjected to limited proteolysis using papain. Stable analogs of intermediate states were generated using AMPPCP as a nonhydrolyzable ATP analog and AlFx as a phosphate analog, following conditions established for Ca2+-ATPase (SERCA1). Characteristic digestion patterns obtained for different analog intermediates show that CopA undergoes domain rearrangements very similar to those of SERCA1. Digestion sites were identified on the loops connecting the A-domain and the transmembrane helices M2 and M3 as well as on that connecting the N-terminal metal binding domain (NMBD) and the first transmembrane helix, Ma. These digestion sites were protected in the E1P·ADP and E2P analogs, whereas the M2–A-domain loop was cleaved specifically in the absence of ions to be transported, just as in SERCA1. ATPase activity was lost when the link between the NMBD and the transmembrane domain was cleaved, indicating that the NMBD plays a critical role in ATP hydrolysis in T. maritima CopA. The change in susceptibility of the loop between the NMBD and Ma helix provides evidence that the NMBD is associated to the A-domain and recruited into domain rearrangements and that the Ma helix is the counterpart of the M1 helix in SERCA1 and Mb and Mc are uniquely inserted before M2.

Stabilities of the fluorescent SH-reagent eosin-5-maleimide and its adducts with sulfhydryl compounds

The stabilities of the SH-reagent eosin-5-maleimide (EMA) and its adducts with the SH-compounds L-cysteine, N-acetyl-L-cysteine and glutathione (reduced form) were studied under various conditions in comparison with those of the adducts of N-ethylmaleimide (NEM). Studies by reversed-phase high performance liquid chromatography and mass spectrometry showed that EMA was less stable than NEM at neutral and moderately alkaline pH values. EMA formed a succinimide-type adduct with SH-compounds, and then underwent further modification by nucleophilic attack of OH- or an amino group. The succinimide-type adducts with acetylcysteine and glutathione were converted to open-type adducts, in which the succinimide ring was cleaved, whereas the adduct with cysteine was modified to a thiazine-type adduct. Kinetic analyses showed that these open-type and thiazine-type adducts were readily formed and were stable at moderately alkaline pH values such as pH 8.0 or 9.0.

Initial sites of insulin cleavage and stereospecificity of carboxyl proteinases from Aspergillus sojae and Pycnoporus coccineus.

Initial cleavage sites of native insulin at a pH of about 3 and stereospecificity were investigated by fungal carboxyl proteinases (EC 3.4.23.6) from ASpergillus sojae, a species of fungi imperfecti, and Pycnoporus coccineus (formerly designated Trametes sanguinea), a wood deteriorating Basidiomycete, respectively. Fungal carboxyl proteinases were used as a model of vertebrate insulin degradation. A. sojae carboxyl proteinase I primarily hydrolyzed two peptide bonds located on the surface of native insulin monomer, the B16-B17 (Tyr-Leu) and B24-B25 (Phe-Phe) bonds, and secondarily the buried bonds, A15-A16 (Gln-Leu), B15-B16 (Leu-Tyr) and B14-B15 (ala-Leu), at pH 3.2 and 30 degree C. The initial cleavage sites of A. sojae carboxyl proteinases I towards native insulin were not identical with the initial cleavage sites towards the oxidized B chain of insulin. P. coccineus carboxyl proteinase Ia selectively hydrolyzed B14-B15 (Ala-Leu), B16-B17 (Tyr-Leu) and B24-B25 (Phe-Phe) bonds in the native insulin at pH 2.7. Based on these findings we suggest that the stereospecificity of the fungal carboxyl proteinases is similar to that of cathepsin D (EC 3.4.23.5), and that the synthesis and degradation of insulin may occur in microorganisms.

Functionally important conserved length of C-terminal regions of yeast and bovine ADP/ATP carriers, identified by deletion mutants studies, and water accessibility of the amino acids at the C-terminal region of the yeast carrier

Comparison of the amino acid sequence of yeast type 2 ADP/ATP carrier (yAAC2) with that of bovine type 1 AAC (bAAC1) revealed that the N- and C-terminus of yAAC2 are 15- and 6-amino acids longer, respectively, than those of bAAC1. In the present study, we focused on the difference in the C-terminal region between yAAC2 and bAAC1. Deletion of first six residues of C-terminus of yAAC did not markedly affect the function of yAAC2; however, further deletion of 1 amino acid (7th amino acid from the C-terminus) destroyed its function. On the contrary, deletion of the first amino acid residue of the C-terminus of bAAC1 caused failure of its functional expression in yeast mitochondria. Based on these results, we concluded that the 6-amino acid residue extension of the C-terminus of yAAC2 was not necessary for the function of this carrier and that the remainder of the C-terminal region of yAAC2, having a length conserved with that of bAAC1, is important for the transport function of AACs. We next prepared various single-Cys mutants in which each of 32 residues in the C-terminus of yAAC2 was replaced by a Cys residue. Since all mutants were successfully expressed in yeast mitochondria, we examined the reactivity of these cysteine residues with the membrane-impermeable sulfhydryl reagent eosin 5-maleimide (EMA). As a result, all cysteine residues that replaced the 9 continuous amino acids in Met310-Lys318 showed high reactivity with EMA regardless of the presence of carboxyatractyloside or bongkrekic acid; and so this region was concluded to be exposed to the water-accessible environment. Furthermore, based on the reactivities of cysteine residues that replaced amino acids in the sixth transmembrane segment, the probable structural features of the C-terminal region of this carrier in the presence of bongkrekic acid were discussed.

Effective capture of proteins inside living cells by antibodies indirectly linked to a novel cell-penetrating polymer-modified protein A derivative

Antibodies against cytoplasmic proteins are useful tools that can control cellular function and clarify signaling mechanisms. However, it is difficult to capture proteins inside living cells, and thus appropriate methods for antibody delivery to the cytoplasm of living cells are required. Cell‐penetrating materials, such as the TAT‐peptide, have received attention for their ability to deliver various cargos into living cells. However, the direct modification of cargos with cell‐penetrating materials is time‐consuming and lacks versatility. Therefore, we conceived that protein A, which can bind to the fragment crystallizable region of an antibody, could indirectly link antibodies with cell‐penetrating materials, creating an efficient and simple antibody delivery system. Here, we constructed a novel antibody delivery system using a cell‐penetrating polymer‐modified protein A derivative (CPP‐pAd). Living cells treated with CPP‐pAd/antibody complexes showed significantly higher antibody levels than those achieved with the commercially available reagent HVJ‐E. Pre‐treatment with sucrose prevented cellular uptake of the CPP‐pAd/antibody complex, suggesting that the CPP‐pAd/antibody internalization mechanism occurs through clathrin‐dependent endocytosis. Interestingly, intracellularly delivered antibodies did not colocalize with endosome/lysosome markers, further suggesting that antibodies were delivered to the cytoplasm by escape from endosome/lysosome. Moreover, we observed that anti‐nuclear pore complex antibodies, delivered to cells using CPP‐pAd, localized to the nuclear membrane and inhibited nuclear factor κB dependent luciferase activity. Together, these results suggest that the antibodies delivered by CPP‐pAd captured functional proteins, making CPP‐pAd a promising strategy for effective capture of proteins inside living cells.

How does the mitochondrial ADP/ATP carrier distinguish transportable ATP and ADP from untransportable AMP and GTP?Dynamic modeling of the recognition/translocation process in the major substrate binding region.

To understand the transport mechanism of the bovine heart mitochondrial ADP/ATP carrier at the atomic level, we studied the four-dimensional features of the interaction of various purine nucleotides with the adenine nucleotide binding region (ABR) consisting of Arg(151)-Asp(167) in the second loop facing the matrix side. After three-dimensional modeling of ABR based on the experimental results, its structural changes on interaction with purine nucleotides were examined by molecular dynamics computation at 300 K. ATP/ADP were translocated to a considerable degree from the matrix side to the inner membrane region accompanied by significant backbone conformational changes, whereas neither appreciable translocation nor a significant conformational change was observed with the untransportable nucleotides AMP/GTP. The results suggested that binding of the terminal phosphate group and the adenine ring of ATP/ADP with Arg(151) and Lys(162), respectively, and subsequent interaction of a phosphate group(s) other than the terminal phosphate with Lys(162) triggered the expansion and subsequent contraction of the backbone conformation of ABR, leading to the translocation of ATP/ADP. Based on a simplified molecular dynamic simulation, we propose a dynamic model for the initial recognition process of ATP/ADP with the carrier.