Expression,purification, and PC1-mediated processing of (H10D,P28K,and K29P)-human proinsulin

Our previous methods for the generation of recombinant human proinsulin were inadequate in terms of reproducibility and yield. In addition, it was difficult to perform structure/function studies on proinsulin because of its tendency to form hexamers. We have developed an improved procedure, which overcomes many of the technical purification problems, and results in a potentially monomeric version of modified proinsulin. Inclusion bodies were prepared using a commercial bacterial lysis solution. The inclusion bodies were solubilized and the fusion protein's affinity tag was removed by chemical cleavage. The polypeptide was then reduced and transferred into a refolding buffer. Following an overnight incubation, only a single form of proinsulin was detected using analytical reversed-phase high-performance liquid chromatography. The refolded (H10D, P28K, and K29P)-human proinsulin (DKP-hPI) was subjected to a final purification step using reversed-phase chromatography. The method is reproducible and produces milligram quantities of purified DKP-hPI from a single liter of bacterial culture. The final product is greater than 95% pure and is suitable for use as a substrate for the propeptide convertase PC1.     

Pollen tube growth and early ovule development following self- and cross-pollination in<Emphasis Type="Italic"> Eucalyptus nitens</Emphasis>

Controlled self- and cross-pollinations were conducted on flowers of five mature Eucalyptus nitens trees. Levels of self-sterility of the trees ranged from 25.8 to 93.6%. Pollen tube numbers in styles and ovule penetration by pollen tubes was investigated 2 weeks after pollination by fluorescence microscopy. There were no significant differences between treatments in the number of pollen tubes present in styles or in the percentage of ovules penetrated by pollen tubes. Embryology of material harvested 2 and 4 weeks after pollination was investigated by bright-field microscopy. Fertilisation had taken place by 2 weeks after pollination with nearly every ovule showing evidence of fertilisation. Cross-pollination resulted in a greater proportion of healthy, developing ovules, at both 2 and 4 weeks after pollination, compared with self-pollination. The proportion of degenerating ovules increased from 2 to 4 weeks after pollination. The reduced ability of E. nitens to set self-pollinated seed compared with cross-pollinated seed appears to be controlled by a post-zygotic mechanism. Differences in ovule size may potentially assist in the identification of trees incapable of setting self-pollinated seed.     

Inhibition of the 26S proteasome induces expression of GLCLC, the catalytic subunit for gamma-glutamylcysteine synthetase

The majority of short- and long-lived cellular proteins are degraded by the activities of the 26S proteasome, a large multi-catalytic protease. Its unique function places it as a central regulatory activity for many important physiological processes. Lactacystin is a very specific 26S proteasome inhibitor and represents an excellent tool for demonstrating that a pathway exhibits proteasome-dependent biochemical regulation. Exposure of HepG2 cells to lactacystin resulted in robust elevation of GLCLC mRNA levels, followed by an increase in GSH concentrations. GLCLC is the gene that encodes the catalytic subunit for gamma-glutamylcysteine synthetase, the rate-limiting enzyme for the synthesis of glutathione (GSH). Inhibition of non-proteasome, protease activities did not induce GLCLC. Gel mobility shift assays and expression of CAT activity from heterologous reporter vectors identified Nrf2 mediation of the GLCLC antioxidant response element, ARE4, as the mechanism by which lactacystin induced GLCLC. These studies have identified 26S proteasome activity as a central regulatory pathway for glutathione synthesis.     

Mutational analysis of the C-terminus in ion transport peptide (ITP) expressed in Drosophila Kc1 cells

Ion transport peptide (ITP) stimulates Cl(-) transport (measured as short-circuit current, I(sc)) and fluid reabsorption in Schistocerca gregaria ilea. We report that Drosophila Kc1 cells transfected with preproITP cDNA secrete a peptide (KcITP(75)) that, while cleaved correctly at the N-terminus, had reduced (10-fold) stimulatory activity on ileal I(sc) compared to both native ITP (ScgITP) and synthetic ITP (synITP). We provide evidence that the reduced activity of KcITP(75) is due to incomplete processing of the C-terminal sequence LGKK (KcITP(75)) to L-amide. In support of this, in vitro amidation of glycine extended ITP (i.e., KcITP(73) ending in LG) but not KcITP(75) (ending in LGKK) significantly increased specific activity in the bioassay. Further evidence for C-terminus involvement includes complete loss of stimulation by truncated mutants (e.g., KcITP(71) which lacks LGKK) and a mutant in which alanine is substituted for the terminal glycine in KcITP(73). Moreover a natural homologue (KcITP-L, which differs only in the C-terminal sequence) expressed by Kc1 cells does not stimulate ileal I(sc). Rather KcITP-L acts as a weak ITP antagonist, as does the truncated mutant KcITP(71). KcITP(70) has no antagonistic effect. A short synthetic peptide fragment of the C-terminus (VEIL-amide) does not stimulate ileal I(sc), indicating that other regions of ITP are also essential to biological activity. Arch.     

Two-dimensional structure of beta-amyloid(10-35) fibrils

Beta-amyloid (Abeta) peptides are the main protein component of the pathognomonic plaques found in the brains of patients with Alzheimer's disease. These heterogeneous peptides adopt a highly organized fibril structure both in vivo and in vitro. Here we use solid-state NMR on stable, homogeneous fibrils of Abeta(10-35). Specific interpeptide distance constraints are determined with dipolar recoupling NMR on fibrils prepared from a series of singly labeled peptides containing (13)C-carbonyl-enriched amino acids, and skipping no more that three residues in the sequence. From these studies, we demonstrate that the peptide adopts the structure of an extended parallel beta-sheet in-register at pH 7.4. Analysis of DRAWS data indicates interstrand distances of 5.3 +/- 0.3 A (mean +/- standard deviation) throughout the entire length of the peptide, which is compatible only with a parallel beta-strand in-register. Intrastrand NMR constraints, obtained from peptides containing labels at two adjacent amino acids, confirm the secondary structural findings obtained using DRAWS. Using peptides with (13)C incorporated at the carbonyl position of adjacent amino acids, structural transitions from alpha-helix to beta-sheet were observed at residues 19 and 20, but using similar techniques, no evidence for a turn could be found in the putative turn region comprising residues 25-29. Implications of this extended parallel organization for Abeta(10-35) for overall fibril formation, stability, and morphology based upon specific amino acid contacts are discussed.     

Viral Oncoproteins Discriminate between p53 and the p53 Homolog p73

p73 is a recently identified member of the p53 family. Previously it was shown that p73 can, when overproduced in p53-defective tumor cells, activate p53-responsive promoters and induce apoptosis. In this report we describe the generation of anti-p73 monoclonal antibodies and confirm that two previously described p73 isoforms are produced in mammalian cells. Furthermore, we show that these two isoforms can bind to canonical p53 DNA-binding sites in electrophoretic mobility shift assays. Despite the high degree of similarity between p53 and p73, we found that adenovirus E1B 55K, simian virus 40 T, and human papillomavirus E6 do not physically interact with p73. The observation that viral oncoproteins discriminate between p53 and p73 suggests that the functions of these two proteins may differ under physiological conditions. Furthermore, they suggest that inactivation of p73 may not be required for transformation.     

Efficient,Large Area,and Thick Junction Polymer Solar Cells with Balanced Mobilities and Low Defect Densities

The high power conversion efficiencies (PCEs) of laboratory‐scale polymer‐based organic solar cells are yet to translate to large area modules because of a number of factors including the relatively large sheet resistance of available transparent conducting electrodes (TCEs), and the high defect densities associated with thin organic semiconductor junctions. The TCE problem limits device architectures to narrow connected strips (<1 cm) causing serious fabrication difficulties and extra costs. Thin junctions are required because of poor charge transport (imbalanced mobilities) in the constituent organic semiconductors. These issues are addressed using a combination of approaches to create thick junctions conformally coated on low sheet resistance metal grid TCEs. An essential feature of these thick junctions is balanced carrier mobilities, which affords high fill factors and efficient carrier extraction. Conformal coating is achieved by promoting enhanced intermolecular interactions in the coating solution using a high molecular weight polymeric semiconductor and appropriate solvent system. This combination of balanced mobilities, conformal coating and metallic grid TCEs is a simple and generic approach to the fabrication of defect‐free large area organic solar cells (OSCs). The approach is demonstrated with 25 cm² monolithic devices possessing aperture‐corrected power conversion efficiencies of 5% and fill factors exceeding 0.5.