Echinocyte shapes: bending, stretching, and shear determine spicule shape and spacing

We study the shapes of human red blood cells using continuum mechanics. In particular, we model the crenated, echinocytic shapes and show how they may arise from a competition between the bending energy of the plasma membrane and the stretching/shear elastic energies of the membrane skeleton. In contrast to earlier work, we calculate spicule shapes exactly by solving the equations of continuum mechanics subject to appropriate boundary conditions. A simple scaling analysis of this competition reveals an elastic length Lambda(el), which sets the length scale for the spicules and is, thus, related to the number of spicules experimentally observed on the fully developed echinocyte.     

Molecular organization of amyloid protofilament-like assembly of betabellin 15D: helical array of beta-sandwiches

Betabellin is a 32-residue peptide engineered to fold into a four-stranded antiparallel beta-sheet protein. Upon air oxidation, the betabellin peptides can fold and assemble into a disulfide-bridged homodimer, or beta-sandwich, of 64 residues. Recent biophysical and ultrastructural studies indicate that betabellin 15D (B15D) (a homodimer of HSLTAKIpkLTFSIAphTYTCAVpkYTAKVSH, where p = DPro, k = DLys, and h = DHis) forms unbranched, 35-A wide assemblies that resemble the protofilaments of amyloid fibers. In the present study, we have analyzed in detail the X-ray diffraction patterns of B15D prepared from acetonitrile. The fiber diffraction analysis indicated that the B15D fibril was composed of a double helix defined by the selection rule l = n + 7m (where l is even, and n and m are any integers), and having a 199-A period and pitch, 28-A rise per unit, and 10-A radius. This helical model is equivalent to a reverse-handed, single helix with half the period and defined by the selection rule l = -3n + 7m (where l is any integer). The asymmetric unit is the single B15D beta-sandwich molecule. These results suggest that the betabellin assembly that models the protofilaments of amyloid fibers is made up of discrete subunits on a helical array. Multiple intersheet hydrogen bonds in the axial direction and intersandwich polar interactions in the lateral direction stabilize the array.     

Fluorescence analysis of receptor-G protein interactions in cell membranes

The dynamics of G protein heterotrimer complex formation and disassembly in response to nucleotide binding and receptor activation govern the rate of responses to external stimuli. We use a novel flow cytometry approach to study the effects of lipid modification, isoform specificity, lipid environment, and receptor stimulation on the affinity and kinetics of G protein subunit binding. Fluorescein-labeled myristoylated Galpha(i1) (F-alpha(i1)) was used as the ligand bound to Gbetagamma in competition binding studies with differently modified Galpha subunit isoforms. In detergent solutions, the binding affinity of Galpha(i) to betagamma was 2 orders of magnitude higher than for Galpha(o) and Galpha(s) (IC50 of 0.2 nM vs 17 and 27 nM, respectively), while in reconstituted bovine brain lipid vesicles, binding was slightly weaker. The effects of receptor on the G protein complex were assessed in alpha(2A)AR receptor expressing CHO cell membranes into which purified betagamma subunits and F-alpha(i1) were reconstituted. These cell membrane studies led to the following observations: (1) binding of alpha subunit to the betagamma was not enhanced by receptor in the presence or absence of agonist, indicating that betagamma contributed essentially all of the binding energy for alpha(i1) interaction with the membrane; (2) activation of the receptor facilitated GTPgammaS-stimulated detachment of F-alpha(i1) from betagamma and the membrane. Thus flow cytometry permits quantiatitive and real-time assessments of protein-protein interactions in complex membrane environments.     

Generation of carbon monoxide and iron from hemeproteins in the presence of 7,8-dihydroneopterin

7,8-Dihydroneopterin and neopterin are secreted by human and primate macrophages after activation by interferon-gamma in a ratio of 2:1. 7,8-Dihydroneopterin is known to suppress radical-mediated processes, but it is also able in the presence of iron ions to generate superoxide radical anion and hydroxyl radicals from molecular oxygen. Effects of 7,8-dihydroneopterin were investigated on (met)myoglobin and (met)hemoglobin. Addition of 7,8-dihydroneopterin to heme proteins in air-saturated solution resulted in dose-dependent cleavage of the porphyrin moiety. The liberation of non-heme iron and carbon monoxide originating from the cleaved porphyrin was quantified. Both were generated at equimolar concentrations with a linear correlation coefficient of 0.9. Addition of ferrous iron significantly accelerated the pteridine-mediated cleaving of the porphyrin. However, the total yield of porphyrin cleaved was controlled by the pterin rather than by the ferrous ion concentration. 7,8-Dihydroneopterin is assumed to reduce the heme iron in intact protein molecules, thereby preparing the conditions for binding of oxygen and carbon monoxide as ligands. Beyond that, it is concluded that hydroxyl radicals might be generated via reduction of molecular oxygen to superoxide anion in the autoxidation process and dismutation to hydrogen peroxide and subsequent Fenton reaction.     

Protective effect of metallothionein-III on DNA damage in response to reactive oxygen species

Metallothionein (MT)-III is a member of a brain-specific MT family, in contrast to MT-I and MT-II that are found in most tissues and are implicated in metal ion homeostasis and as an antioxidant. To investigate the defensive role of MT-III in terms of hydroxyl radical-induced DNA damage, we used purified human MT-III. DNA damage was detected by single-strand breaks of plasmid DNA and deoxyribose degradation. In this study, we show that MT-III is able to protect against the DNA damage induced by ferric ion-nitrilotriacetic acid and H(2)O(2), and that this protective effect is inhibited by the alkylation of the sulfhydryl groups of MT-III by treatment with EDTA and N-ethylmaleimide. MT-III was also able to efficiently remove the superoxide anion, which was generated from the xanthine/xanthine oxidase system. These results strongly suggest that MT-III is involved in the protection of reactive oxygen species-induced DNA damage, probably via direct interaction with reactive oxygen species, and that MT-III acts as a neuroprotective agent.     

The hepatocyte glucose-6-phosphatase subcomponent T3: its relationship to GLUT2

Glucose-6-phosphatase (G6Pase) is a multiple protein complex in the endoplasmic reticulum (ER) that includes a mechanism (known as T3) for glucose exit from the ER to the cytosol. The molecular identity of T3 is not known. T3 has been shown to be functional in the absence of GLUT2, indicating that it is not GLUT2. Here we found a 55-kDa protein in high-density microsomal fraction (HDM) of rat hepatocytes that is recognized by polyclonal GLUT2 antibody raised against the GLUT2 C-terminal 14-amino-acid-sequence peptide. HDM contained calnexin but no integrin-beta1 or Na/K ATPase in Western blotting. Significant GLUT2 immunoreactivity was colocalized with colligin, an ER marker, in confocal microscopy. Furthermore, the 55-kDa protein in HDM was labeled with a covalently reactive, impermeable glucose transporter substrate, 1,3-bis-(3-deoxy-D-glucopyranose-3-yloxy)-2-propyl 4-benzoyl-benzoate (B3GL) when hepatocyte homogenates, but not intact cells, were labeled. In addition glucose efflux from HDM vesicles was sensitive to B3GL treatment in a dose-dependent manner. Based on these findings, we suggest that T3 may be a novel facilitative glucose transporter that is highly homologous to GLUT2 in the C-terminal sequence, thus cross-reacting with the GLUT2 antibody. The finding will be useful in molecular identification and cloning of T3.     

The origin of tobacco's T genome is traced to a particular lineage within Nicotiana tomentosiformis (Solanaceae)

Nicotiana tabacum (tobacco) is a natural allotetraploid. The maternal genome donor is not controversial and is probably derived from an ancestor of N. sylvestris. The paternal, T-genome donor has been less clear, with N. tomentosiformis, N. otophora, or an introgression hybrid proposed. Here we provide evidence that the T genome of N. tabacum is derived from a particular lineage of N. tomentosiformis. We show that the repetitive sequences of geminiviral origin, GRD53 and GRD3, are present in the genomes of N. tabacum cultivars, a tobacco cell suspension culture TBY-2, and N. tomentosiformis ac. NIC 479/84. Surprisingly, they are not present in another three varieties of N. tomentosiformis. A detailed cytogenetic analysis also revealed that N. tomentosiformis ac. NIC 479/84 most closely resembles the N. tabacum T genome in the location of other tandem repetitive sequences. Thus, tobacco formed after divergence within N. tomentosiformis, and the spectrum of potential donors of the paternal genome can be narrowed to a genotype of N. tomentosiformis characterized by the presence of GRD53 and GRD3 repeats. It is clear that future paternity studies in tobacco should use N. tomentosiformis ac. NIC 479/84 rather than any other accession.     

Recognition of diverse RNAs by a single protein structural framework

The coat proteins of different single-strand RNA phages utilize a common structural framework to recognize different RNA targets, making them suitable models for studies of RNA-protein recognition generally, especially for the class of proteins that bind RNA on a beta-sheet surface. Here we show that structurally distinct molecules are capable of satisfying the requirements for binding to Qbeta coat protein. Although the predicted secondary structures of the RNAs differ markedly, we contend that they are approximately equivalent structurally in their complexes with coat protein. Based on our prior observations that the RNA-binding specificities of Qbeta and MS2 coat proteins can be interconverted with as few as one amino acid substitution each, and taking into account details of the structures of complexes of MS2 coat protein with wild-type and aptamer RNAs, we propose a model for the Qbeta coat protein-RNA complex.     

Hsp90 makes the human HBV Pol competent for in vitro priming rather than maintaining the human HBV Pol/pregenomic RNA complex

Previous studies show that the Hsp90 complex facilitates binding of duck hepatitis B virus polymerase on the epsilon stem-loop region in pregenomic RNA for the priming of Pol. In this report, we found that Hsp90 also binds to human HBV Pol and its binding seems to be involved in in vitro priming of human HBV Pol. (i) Inhibition of Hsp90 by anti-Hsp90 antibody (3G3) and (ii) the stripping of the Hsp90 by 1 M NaCl buffer containing 1% NP-40 almost completely reduced in vitro priming activity of human HBV Pol expressed in insect cells. However, binding of human HBV Pol to pregenomic RNA is different from that of duck HBV Pol. It seems that Hsp90 makes the human HBV Pol competent for in vitro priming rather than maintaining the human HBV Pol/pregenomic RNA complex as duck HBV Pol. In addition, although Hsp70 is a component of the Hsp90 complex, Hsp70 can directly bind to human HBV Pol without Hsp90.     

Protein kinase C-zeta phosphorylates insulin-responsive aminopeptidase in vitro at Ser-80 and Ser-91

Insulin-responsive aminopeptidase (IRAP) colocalizes with glucose transporter type 4 (GLUT4) in adipocytes and is recruited to the plasma membrane in response to insulin. Microinjection of peptides corresponding to the IRAP cytoplasmic domain sequences causes GLUT4 recruitment in adipocytes. Inhibitors of protein kinase C-zeta (PKC-zeta) abolish the insulin-induced GLUT4 recruitment in rat adipocytes. These findings suggest an interesting possibility that PKC-zeta may phosphorylate IRAP, playing a key role in GLUT4/IRAP recruitment. To test this possibility, here we studied the (32)P incorporation into IRAP catalyzed by PKC-zeta in insulin-stimulated cells. There was a small but significant (32)P incorporation into IRAP in rat adipocytes, which was partly abolished upon addition of a PKC-zeta pseudosubstrate, suggesting that PKC-zeta may be responsible in part for the IRAP phosphorylation in adipocytes. PKC-zeta also catalyzed the incorporation of (32)P not only into IRAP in GLUT4 vesicles isolated from rat adipocytes but also into the IRAP cytoplasmic domain inserts in glutathione S-transferase-fusion proteins, demonstrating direct IRAP phosphorylation by PKC-zeta. Reversed-phase HPLC, matrix-assisted laser desorption ionization mass spectrometry, and radiosequencing of the tryptic digests of the (32)P-labeled IRAP fusion proteins identified Ser-80 and Ser-91 as major phosphorylation sites. In GLUT4 vesicles, the (32)P incorporation into IRAP was exclusively localized at a 6.9-kDa tryptic fragment identified as IRAP(76-138) and the (32)P labeling at Ser-80 accounted for 80-90% of the total IRAP labeling, suggesting that Ser-80 is the major phosphorylation site in intact IRAP. These findings are consistent with the possibility that the IRAP cytoplasmic domain phosphorylation by PKC-zeta plays a key role in insulin-induced IRAP or GLUT4 recruitment in adipocytes.