The HSP co-inducer BGP-15 can prevent the metabolic side effects of the atypical antipsychotics

Weight gain and dysfunction of glucose and lipid metabolism are well-known side effects of atypical antipsychotic drugs (AAPD). Here, we address the question whether a heat-shock protein (HSP) co-inducer, insulin sensitizer drug candidate, BGP-15, can prevent AAPD-induced glucose, lipid, and weight changes. We also examined how an AAPD alters HSP expression and whether BGP-15 alters that expression. Four different experiments are reported on the AAPD BGP-15 interventions in a human trial of healthy men, a rodent animal model, and an in vitro adipocyte cell culture system. Olanzapine caused rapid insulin resistance in healthy volunteers and was associated with decreased level of HSP72 in peripheral mononuclear blood cells. Both changes were restored by the administration of BGP-15. In Wistar rats, weight gain and insulin resistance induced by clozapine were abolished by BGP-15. In 3T3L1 adipocytes, clozapine increased intracellular fat accumulation, and BGP-15 inhibited this process. Taken together, our results indicate that BGP-15 inhibits multiple metabolic side effects of atypical antipsychotics, and this effect is likely to be related to its HSP co-inducing ability.     

Characterization of cycA mutants of Escherichia coli. An assay for measuring in vivo mutation rates

Quantitative assessment of the spontaneous or induced genomic mutation rate, a fundamental evolutionary parameter, usually requires the use of well-characterized mutant selection systems. Although there is a great number of genetic selection schemes available in Escherichia coli, the selection of D-cycloserine resistant mutants is shown here to be particularly useful to yield a general view of mutation rates and spectra. The combination of a well-defined experimental protocol with the Ma-Sandri-Sarkar maximum likelihood method of fluctuation analysis results in reproducible data, adequate for statistical comparisons. The straightforward procedure is based on a simple phenotype-genotype relationship, and detects mutations in the single-copy, chromosomal cycA gene, involved in the uptake of D-cycloserine. In contrast to the widely used rifampicin resistance assay, the procedure selects mutations which are neutral in respect of cell growth. No specific genetic background is needed, and practically the entire mutation spectrum (base substitutions, frameshifts, deletions, insertions) can simultaneously be measured. A systematic analysis of cycA mutations revealed a spontaneous mutation rate of 6.54 x 10(-8) in E. coli K-12 MG1655. The mutation spectrum was dominated by point mutations (base substitutions, frameshifts), spread over the entire gene. IS insertions, caused by IS1, IS2, IS3, IS4, IS5 and IS150, represented 24% of the mutations.     

Evolution of genes and repeats in the Nimrod superfamily

The recently identified Nimrod superfamily is characterized by the presence of a special type of EGF repeat, the NIM repeat, located right after a typical CCXGY/W amino acid motif. On the basis of structural features, nimrod genes can be divided into three types. The proteins encoded by Draper-type genes have an EMI domain at the N-terminal part and only one copy of the NIM motif, followed by a variable number of EGF-like repeats. The products of Nimrod B-type and Nimrod C-type genes (including the eater gene) have different kinds of N-terminal domains, and lack EGF-like repeats but contain a variable number of NIM repeats. Draper and Nimrod C-type (but not Nimrod B-type) proteins carry a transmembrane domain. Several members of the superfamily were claimed to function as receptors in phagocytosis and/or binding of bacteria, which indicates an important role in the cellular immunity and the elimination of apoptotic cells. In this paper, the evolution of the Nimrod superfamily is studied with various methods on the level of genes and repeats. A hypothesis is presented in which the NIM repeat, along with the EMI domain, emerged by structural reorganizations at the end of an EGF-like repeat chain, suggesting a mechanism for the formation of novel types of repeats. The analyses revealed diverse evolutionary patterns in the sequences containing multiple NIM repeats. Although in the Nimrod B and Nimrod C proteins show characteristics of independent evolution, many internal NIM repeats in Eater sequences seem to have undergone concerted evolution. An analysis of the nimrod genes has been performed using phylogenetic and other methods and an evolutionary scenario of the origin and diversification of the Nimrod superfamily is proposed. Our study presents an intriguing example how the evolution of multigene families may contribute to the complexity of the innate immune response.     

Characterization of the interaction between Aβ 1–42 and glyceraldehyde phosphodehydrogenase

Advances in the understanding of AD pathogenesis have recently provided strong support for a modified Aβ protein cascade hypothesis, stating that several different Aβ assemblies contribute to the triggering of a complex pathological cascade leading to neurodegeneration. Both in vitro and in vivo, Aβ rapidly forms fibrils (fAβ), which are able to interact with various molecular partners, including proteins, lipids and proteoglycans. In a previous study aimed to identify some of these molecular partners of fAβ, we demonstrated that the GAPDH was specifically coprecipitated with fAβ. The aim of this study was to characterize this interaction. First, it was shown by TEM that synthetic GAPDH directly binds fAβ 1–42. Then rat synaptosomal proteins were purified and incubated with different forms of Aβ in various conditions, and the presence of GAPDH among the proteins coprecipitated with Aβ was studied by western blotting. Results showed that the interaction between GAPDH and fAβ 1–42 is nonionic, as is not impaired by increasing salt concentrations. GAPDH is coprecipitated not only by fAβ, but also by nonfibrillar forms of Aβ 1–42. The 41–42 Aβ sequence seems to be important in the interaction of GAPDH and Aβ, as more GAPDH was coprecipitated with fAβ 1–42 than with fAβ 1–40. GAPDH extracted from various subcellular fractions including mitochondria, was shown to interact with fAβ. Our data demonstrate a direct interaction between Aβ and GAPDH and support the possibility that this interaction has an important pathogenic role in AD. Copyright © 2008 European Peptide Society and John Wiley & Sons, Ltd.     

Investigation of penetratin peptides. Part 1. The environment dependent conformational properties of penetratin and two of its derivatives.

The homeodomain, the DNA-binding domain of Antennapedia homeoprotein, is composed of three alpha-helices and one beta-turn between helices II and III. Its third helix from the N-terminal (helix III) can translocate through the cell membrane into the nucleus and can be used as an intracellular vehicle for the delivery of oligopeptides and oligonucleotides. To the best of our knowledge, this helix III, called penetratin, which consists of 16 amino acids, is internalized by cells in a specific, non-receptor-mediated manner. For a better understanding of the mechanism of the transfer, the structure of penetratin was examined in both extracellular matrix-mimetic and membrane-mimetic environments: 1H-NMR and CD spectroscopic measurements were performed in mixtures of TFE/water with different ratios. The molecular conformations of two analogue peptides [(6,14-Phe)-penetratin and a 12 amino acid penetratin derivative (peptide 3)] were also studied. An atomic level comprehensive analysis of penetratin and its two analogues was performed. In a membrane-mimetic solvent system (TFEd2/water = 9: 1), on the basis of 553 distance restraints, the 4-12 region of penetratin exhibits a bent, irregular helical structure on NMR examination. Interactions between hydrophobic amino acid residues in conjunction with H-bonds stabilize the secondary structure of the molecule. Thus, both derivatives adopt a helix-like conformation. However, while (6,14-Phe)-penetratin displays both alpha-helical and 310-helical features, the structure of peptide 3 is predominantly a 310-helix. Of the three peptides, surprisingly (6,14-Phe)-penetratin has the largest helical content. An increase in the polarity of the molecular environment gradually disintegrates these helix-like secondary structures. In a highly aqueous molecular system (TFEd2/water = 1 : 9), the fast exchange of multiple conformers leads to too few distance restraints being extracted, therefore the NMR structures can no longer be determined. The NMR data show that only short-range order can be traced in these peptides. Under these conditions, the molecules adopt nascent helix-like structures. On the other hand, CD spectra could be recorded at any TFE/water ratio and the conformational interconversion could therefore be monitored as a function of the polarity of the molecular environment. The CD data were analysed comprehensively by the quantitative deconvolution method (CCA+). All three penetratin peptides display helical conformational features in a low dielectric medium, with significant differences as a function of their amino acid composition. However, these conformational features are gradually lost during the shift from an apolar to a polar molecular environment.     

A new acid hydrolysis method for determining tryptophan in peptides and proteins

Three different methods for hydrolysis and determination of amino acid composition of peptides and proteins were compared. We found, that the method of Matsubara and Sasaki (using 6N HCl and thioglycolic acid) gives comparatively low recoveries for tryptophan, while Liu and Chang's method, using p-toluenesulfonic acid and tryptamine, is more suitable. To eliminate the difficulties of the latter method, we used mercaptoethane-sulfonic acid, which, in the concentration used, results in total hydrolysis of peptide bonds within 22 hr and gives very high tryptophan recoveries. Both sulfonic acid methods were used for hydrolysis of the pentapeptide “pentagastrine” as well as of the proteins lysozyme, cytochrome c, and chymotrypsine. Their amino acid composition was determined using an automatic amino acid analyzer. Similarly to the p-toluenesulfonic acid method, the results of our method are totally reliable only for pure peptides and proteins, though the results obtained with our method using samples containing carbohydrates are better than those of all earlier methods.     

Synthesis of Peptide Nucleic Acid Monomers

Abstract

The chemical synthesis of peptide nucleic acid (PNA) monomers is described using Fmoc (backbone), anisoyl (cytosine, adenine), 4-tert-butylbenzoyl (cytosine) and isobutyryl/diphenylcarbamoyl (guanine) protecting group combinations. For the guanine monomer the alkylation was realized both in a Mitsunobu [DIAD, triphenylphosphine or (4-dimethylaminophenyl)diphenylphosphine, tert-butyl glycolate] and in a low-temperature, sodium-hydride mediated alkylation (tert-butyl bromoacetate) to give the N⁹ -substituted derivative.