Zn(2+) modulation of neuronal transient K(+) current: fast and selective binding to the deactivated channels

Modulation of voltage-dependent transient K(+) currents (A type K(+) or K(A) current) by Zn(2+) was studied in rat hippocampal neurons by the whole-cell patch-clamp technique. It is found that Zn(2+) selectively binds to the resting (deactivated or closed) K(A) channels with a dissociation constant (K(d)) of approximately 3 &mgr;M, whereas the affinity between Zn(2+) and the inactivated K(A) channels is 1000-fold lower. Zn(2+) therefore produces a concentration-dependent shift of the K(A) channel inactivation curve and enhances the K(A) current elicited from relatively positive holding potentials. It is also found that the kinetics of Zn(2+) action are fast enough to compete with the transition rates between different gating states of the channel. The rapid and selective binding of Zn(2+) to the closed K(A) channels keeps the channel in the closed state and explains the ion's concentration-dependent slowing effect on the activation of K(A) current. This in turn accounts for the inhibitory effect of Zn(2+) on the K(A) current elicited from hyperpolarized holding potentials. Because the molecular mechanisms underlying these gating changes are kinetic interactions between the binding-unbinding of Zn(2+) and the intrinsic gating processes of the channel, the shift of the inactivation curve and slowing of K(A) channel activation are quantitatively correlated with ambient Zn(2+) over a wide concentration range without "saturation"; i.e., The effects are already manifest in micromolar Zn(2+), yet are not saturated even in millimolar Zn(2+). Because the physiological concentration of Zn(2+) could vary over a similarly wide range according to neural activities, Zn(2+) may be a faithful physiological "fine tuner," controlling and controlled by neural activities through its effect on the K(A) current.     

Identification of human porins. II. Characterization and primary structure of a 31-lDa porin from human B lymphocytes (Porin 31HL)

We characterize and describe for the first time the primary structure of a human porin with the molecular mass of 31 kDa derived from the plasmalemm of B-lymphocytes (Porin 31HL). Porin 31HL is shown to be a basic, channel forming membrane protein. The protein chain is composed of 282 amino acids with a relative molecular mass of 30641 Da without derivatisation. It is not a glycoprotein. The N-terminus is acetylated. Altogether the amino-acid sequence shows 56% hydrophilic or charged amino acids arranged in alternating regions of hydrophilic or hydrophobic character as it is typical for porins. In addition the 18 N-terminal amino acids of Porin 31HL can be arranged to an amphilic alpha-helix like in other porins. Porin 31HL shows approx. 29% or 24% identity to the primary structure of mitochondrial porins of Neurospora crassa and Saccharomyces cerevisiae. Partial data on mitochondrial porins from rat kidney and beef heart show sequence identity of about 90% to the human B cell porin elaborated here.     

Identification of human porins. I. Purification of a porin from human B-lymphocytes (Porin 31HL) and the topochemical proof of its expression on the plasmalemma of the progenitor cell

We describe for the first time a porin (Porin 31HL) on the plasmalemm of an eukaryontic cell line, where porins have been found only on the outer mitochondrial membranes. The expression of the porin on the plasmalemm of transformed human B-lymphocytes is demonstrated by cytotoxicity- and indirect immunofluorescence techniques with living and fixed cells. The rabbit xenoantisera used were directed against purified Porin 31HL and free or acetylated synthetic peptides of its nineteen N-terminal amino acids. The three-step purification procedure for Porin 31HL started from a total membrane fraction of the B-cell line, followed by ion-exchange chromatography on CM- and DEAE-cellulose and a final gel filtration in SDS on Sephacryl S-300.     

Peptide-specific antibodies and proteases as probes of the transmembrane topology of the bovine heart mitochondrial porin.

We have investigated the transmembrane topology of the bovine heart mitochondrial porin by means of proteases and antibodies raised against the amino-terminal region of the protein. The antisera against the human N-terminus reacted with porin in Western blots of NaDodSO4-solubilized bovine heart mitochondria and with the membrane-bound porin in enzyme-linked immunosorbent assay (ELISA). The immunoreaction with mitochondria coated on microtiter wells showed that the amino-terminal region of the protein is not embedded in the lipid bilayer but is exposed to the cytosol. Back-titration of unreacted anti-N-terminal antibodies after their incubation with intact mitochondria demonstrated that the porin N-terminus is also exposed in "noncoated" mitochondria. No difference in antisera reactivity was observed between intact and broken mitochondria. Intact and broken mitochondria were subjected to proteolysis by specific proteases. The membrane-bound bovine heart porin was strongly resistant to proteolysis, but a few specific cleavage sites were observed. Staphylococcus aureus V8 protease gave a large 24K N-terminal peptide, trypsin produced a 12K N-terminal and an 18K C-terminal peptide, and chymotrypsin gave two peptides of Mr 19.5K and 12.5K, which were both recognized by the antiserum against the human N-terminus. Carboxypeptidase A was ineffective in cleaving the membrane-bound porin in both intact and broken mitochondria. Thus, the carboxy-terminal part of the protein is probably not exposed to the water phase. The cleavage patterns of membrane-bound porin, obtained with S. aureus V8 protease, trypsin, and chymotrypsin, showed no difference between intact and broken mitochondria, thus indicating that all porin molecules have the same orientation in the membrane. The computer analysis of the sequence of human B-lymphocyte porin suggested that 16 beta-strands can span the phospholipid bilayer. This result, together with the overall information presented, allowed us to draw a possible scheme of the transmembrane arrangement of mammalian mitochondrial porin.     

Proteins of cytosol and amniotic fluid increase the voltage dependence of human type-1 porin

Heat-stable proteins from human and porcine cytosol and human amniotic fluid were found to increase the voltage dependence of human type-1 porin reconstituted in planar phospholipid bilayers. Purification processes revealed that these regulatory molecules were characterized by anionic charge and apparent molecular weights of between 23 and 64 kDa. The human cytosol proteins exerted inhibitory activity only when added to the compartment with applied negative potential. The observed increase in voltage dependence of porin was due to the presence of specific proteins in cytosol and amniotic fluid, since human cerebral spinal fluid in comparable amounts had no significant effect on the channel properties. Furthermore, other anionic proteins and polypeptides investigated demonstrated no inhibitory activity, indicating that anionic charge alone could not mimic the molecular properties of the regulatory proteins. With respect to the well-documented expression of porin in the plasma membrane of various cells and species, the presented data give first clues for a biochemical regulation of the channel in this compartment.Studies on Human Porin, Part XV.     

Purification procedure and monoclonal antibodies: two instruments for research on vertebrate porins.

On Western blots of skeletal muscle preparations of different vertebrate classes, four monoclonal anti-human type 1 porin antibodies recognize one single band of either 30.5 or 31 kDa, respectively. To confirm that it is eukaryotic porin which is labeled by the antibodies, we used a purification procedure developed for human type 1 porin for porins from skeletal muscle of shark, frog, and turkey. Applied to different mammalian species and tissues, this procedure exclusively provides type 1 porin. However, applied to shark skeletal muscle, it provides two porin isotypes in nearly equal amounts. In the case of frog skeletal muscle, the procedure provides mainly type 2 porin and a lower amount of type 1 porin. Applied to turkey skeletal muscle, the method provides exclusively type 2 porin. As demonstrated by two-dimensional Western blots, both shark and frog porin isotypes and the turkey type 2 porin are recognized by our antibodies. Furthermore, we elucidated the entire amino acid sequence of frog type 2 porin.     

A tetravalent dengue nanoparticle stimulates antibody production in mice

Background

Dengue is a major public health problem worldwide, especially in the tropical and subtropical regions of the world. Infection with a single Dengue virus (DENV) serotype causes a mild, self-limiting febrile illness called dengue fever. However, a subset of patients experiencing secondary infection with a different serotype progresses to the severe form of the disease, dengue hemorrhagic fever/dengue shock syndrome. Currently, there are no licensed vaccines or antiviral drugs to prevent or treat dengue infections. Biodegradable nanoparticles coated with proteins represent a promising method for in vivo delivery of vaccines.

Findings

Here, we used a murine model to evaluate the IgG production after administration of inactivated DENV corresponding to all four serotypes adsorbed to bovine serum albumin nanoparticles. This formulation induced a production of anti-DENV IgG antibodies (p < 0.001). However, plaque reduction neutralization assays with the four DENV serotypes revealed that these antibodies have no neutralizing activity in the dilutions tested.

Conclusions

Our results show that while the nanoparticle system induces humoral responses against DENV, further investigation with different DENV antigens will be required to improve immunogenicity, epitope specicity, and functional activity to make this platform a viable option for DENV vaccines.     

Human voltage-dependent anion-selective channel expressed in the plasmalemma of Xenopus laevis oocytes

Recent studies indicate a plasmalemmal localisation of eukaryotic porin, i.e. voltage-dependent anion-selective channel (VDAC), and there is evidence that the channel in this cell compartment is engaged in cell volume regulation. Until recently, others and we have used immuno-topochemical and biochemical methods to demonstrate the integration of the channel into the cell membrane and endoplasmic reticulum of vertebrate cells. In the present study, we used molecular biological methods to induce the heterologous expression of tagged human type-1 porin in oocytes of Xenopus laevis and to illustrate its appearance at the plasma membrane of these cells. Applying confocal fluorescent microscopy, green fluorescent protein attached to the C-terminus of porin could clearly be recorded at the cell surface. N-terminal green fluorescent protein-porin fusion proteins remained in the cytoplasm, indicating a strong influence of the porin N-terminus on protein trafficking to the plasma membrane. FLAG-tagged porin was also expressed in frog oocytes. Here, plasmalemmal expression was observed using anti-FLAG M2 monoclonal antibodies and gold-conjugated secondary antibodies, followed by silver enhancement through scanning electron microscopy. In contrast to the EGFP-porin fusion protein, the influence of the small FLAG-epitope (8 amino acids) did not prevent plasmalemmal expression of N-terminally tagged porin. These results indicate the definite expression of human type-1 porin in the plasma membrane of Xenopus oocytes. They thus corroborate our early data on the extra-mitochondrial expression of the eukaryotic porin channel and are essential for future electrophysiological studies on the channel.     

Mitochondria-derived and extra-mitochondrial human type-1 porin are identical as revealed by amino acid sequencing and electrophysiological characterisation

In mammalian cells porin channels are localised in both mitochondrial outer membranes and extra-mitochondrial membranes. We isolated mitochondria-derived porin of a human lymphoblastoid B cell line, determined its amino acid sequence and characterised its channel properties. Interestingly, the amino acid sequence of this porin preparation and, correspondingly, its electrophysiological characteristics in a reconstituted system were identical to those of 'Porin 31HL', the human type-1 porin purified from a crude membrane preparation of the same cell line using a different purification protocol. The results raise questions about targeting, insertion and orientation of human type-1 porin in different membranes.