14-3-3 proteins in neurodegeneration

Among the first reported functions of 14-3-3 proteins was the regulation of tyrosine hydroxylase (TH) activity suggesting a possible involvement of 14-3-3 proteins in Parkinson's disease. Since then the relevance of 14-3-3 proteins in the pathogenesis of chronic as well as acute neurodegenerative diseases, including Alzheimer's disease, polyglutamine diseases, amyotrophic lateral sclerosis and stroke has been recognized. The reported function of 14-3-3 proteins in this context are as diverse as the mechanism involved in neurodegeneration, reaching from basal cellular processes like apoptosis, over involvement in features common to many neurodegenerative diseases, like protein stabilization and aggregation, to very specific processes responsible for the selective vulnerability of cellular populations in single neurodegenerative diseases.Here, we review what is currently known of the function of 14-3-3 proteins in nervous tissue focussing on the properties of 14-3-3 proteins important in neurodegenerative disease pathogenesis.     

APRT缺陷型CHO细胞系的建立及其重组蛋白表达能力评价北大核心CSCD

中国仓鼠卵巢(Chinese hamster ovary,CHO)细胞是生产复杂重组药物蛋白的首选宿主细胞,腺嘌呤磷酸核糖转移酶(adenine phosphoribosyltransferase,APRT)催化腺嘌呤与磷酸核糖缩合形成腺苷一磷酸,是嘌呤生物合成步骤中的关键酶。采用基因编辑技术敲除CHO细胞中aprt基因,验证获得的APRT缺陷型CHO细胞系的生物学特性;构建两种真核表达载体:对照载体(含有目的基因增强型绿色荧光蛋白(enhanced green fluorescent protein,EGFP)和弱化载体(含有启动子和起始密码子突变的aprt弱化表达盒及EGFP),分别转染APRT缺陷型和野生型CHO细胞并筛选获得稳定转染的细胞池;重组CHO细胞传代培养60代并用流式细胞术检测EGFP表达的平均荧光强度,并比较不同实验组重组蛋白EGFP的表达稳定性。PCR扩增和测序结果表明,CHO细胞aprt基因成功敲除;获得的APRT缺陷型CHO细胞系在细胞形态、生长增殖、倍增时间等生物学特性方面与野生CHO细胞无显著差异。目的蛋白瞬时表达结果表明,与野生型CHO细胞相比,转染对照载体和弱化载体的APRT缺陷型CHO细胞系中EGFP的表达分别提高了42%±6%和56%±9%;特别是长期传代培养时,转染弱化载体的APRT缺陷型细胞中EGFP表达量显著高于野生型CHO细胞(P<0.05);构建的基于APRT缺陷型CHO细胞系能够明显提高重组蛋白的长期表达稳定性。研究结果为建立高效稳定的CHO细胞表达系统提供了一种有效的细胞工程策略。     

Structural and functional analysis of the riboflavin synthesis genes encoding GTP cyclohydrolase II (ribA), DHBP synthase (ribBA), riboflavin synthase (ribC), and riboflavin deaminase/reductase (ribD) from Helicobacter pylori strain P1

The functions of the riboflavin synthesis gene homologues ribA, ribBA, ribC, and ribD from Helicobacter pylori strain P1 were confirmed by complementation of defined Escherichia coli mutant strains. The H. pylori ribBA gene, which is similar to bifunctional ribBA genes of Gram-positive bacteria, fully complemented the ribB mutation and partially restored growth in a ribC mutant. However, ribBA did not complement the ribA mutation in E. coli, thus explaining the presence of the additional separate copy of the ribA gene in the H. pylori chromosome. In E. coli exclusively ribA conferred hemolytic activity and gave rise to production of molecules with fluorescence characteristics similar to flavins, as observed earlier. The E. coli hemolysin ClyA was not involved in causing the hemolytic phenotype. No riboflavin synthesis genes on plasmids conferred iron uptake functions to a siderophore-deficient mutant of E. coli. Marker exchange mutagenesis of the genes in H. pylori was not successful indicating that riboflavin synthesis is essential for basic metabolic functions of the gastric pathogen.     

The dynamic regulation of myocardial oxidative phosphorylation: Analysis of the response time of oxygen consumption

Although usually steady-state fluxes and metabolite levels are assessed for the study of metabolic regulation, much can be learned from studying the transient response during quick changes of an input to the system. To this end we study the transient response of O₂ consumption in the heart during steps in heart rate. The time course is characterized by the mean response time of O₂ consumption which is the first statistical moment of the impulse response function of the system (for mono-exponential responses equal to the time constant). The time course of O₂ uptake during quick changes is measured with O₂ electrodes in the arterial perfusate and venous effluent of the heart, but the venous signal is delayed with respect to O₂ consumption in the mitochondria due to O₂ diffusion and vascular transport. We correct for this transport delay by using the mass balance of O₂, with all terms (e.g. O₂ consumption and vascular O₂ transport) taken as function of time. Integration of this mass balance over the duration of the response yields a relation between the mean transit time for O₂ and changes in cardiac O₂ content. Experimental data on the response times of venous [O₂] during step changes in arterial [O₂] or in perfusion flow are used to calculate the transport time between mitochondria and the venous O₂ electrode. By subtracting the transport time from the response time measured in the venous outflow the mean response time of mitochondrial O₂ consumption (t_mito) to the step in heart rate is obtained.In isolated rabbit heart we found that t_mito to heart rate steps is 4-12 s at 37°C. This means that oxidative phosphorylation responds to changing ATP hydrolysis with some delay, so that the phosphocreatine levels in the heart must be decreased, at least in the early stages after an increase in cardiac ATP hydrolysis. Changes in ADP and inorganic phosphate (P_i) thus play a role in regulating the dynamic adaptation of oxidative phosphorylation, although most steady state NMR measurements in the heart had suggested that ADP and P_i do not change. Indeed, we found with ³¹P-NMR spectroscopy that phosphocreatine (PCr) and P_i change in the first seconds after a quick change in ATP hydrolysis, but remarkably they do this significantly faster (time constant ~2.5 s) than mitochondrial O₂ consumption (time constant 12 s). Although it is quite likely that other factors besides ADP and P_i regulate cardiac oxidative phosphorylation, a fascinating alternative explanation is that the first changes in PCr measured with NMR spectroscopy took exclusively place in or near the myofibrils, and that a metabolic wave must then travel with some delay to the mitochondria to stimulate oxidative phosphorylation. The t_mito slows with falling temperature, intracellular acidosis, and sometimes also during reperfusion following ischemia and with decreased mitochondrial aerobic capacity. In conclusion, the study of the dynamic adaptation of cardiac oxidative phosphorylation to demand using the mean response time of cardiac mitochondrial O₂ consumption is a very valuable tool to investigate the regulation of cardiac mitochondrial energy metabolism in health and disease.     

Characterization of the complete mitochondrial genome of Bombyx mori strain H9 (Lepidoptera: Bombycidae)

The complete mitochondrial genome (mitogenome) of Bombyx mori strain H9 (Lepidoptera: Bombycidae) is 15,670 base pairs (bp) in length, encoding 13 protein-coding genes (PCGs), two rRNA genes, 22 tRNA genes and a control region. The nucleotide composition of the genome is highly A + T biased, accounting for 81.31%, with a slightly positive AT skewness (0.059). The arrangement of 13 PCGs is similar to that of other sequenced lepidopterans. All the PCGs are initiated by ATN codons, except for the cytochrome c oxidase subunit 1 (cox1) gene, which is proposed by the TTAG sequence as observed in other lepidopterans. Unlike the other PCGs, the cox1 and cytochrome c oxidase subunit 2 (cox2) genes have incomplete stop codons consisting of just a T. All tRNAs have typical structures of insect mitochondrial tRNAs, which is different from other sequenced lepidopterans. The structure of A + T-rich region is similar to that of other sequenced lepidopterans, including non-repetitive sequences, the ATAGA binding domain, a 18 bp poly-T stretch and a poly-A element upstream of transfer RNA M (trnM) gene. Phylogenetic analysis shows that the domesticated silkmoth B. mori originated from the Chinese Bombyx mandarina.     

Sequence context dependence of tandem guanine:adenine mismatch conformations in RNA: a continuum solvent analysis

Guanine:adenine (G:A) mismatches and in particular tandem G:A (tG:A) mismatches are frequently observed in biological RNA molecules and can serve as sites for tertiary interaction, metal binding and protein recognition. Depending on the surrounding sequence tG:A mismatches can adopt different basepairing topologies. In the sequence context (5'-) GGAC (tandem G:A in bold) a face-to-face (imino or Watson-Crick-like) pairing is preferred whereas in the CGAG context, G and A adopt a sheared arrangement. Systematic conformational searches with a generalized Born continuum model and molecular dynamics simulations including explicit water molecules and ions have been used to generate face-to-face and sheared tG:A mismatches in both CGAG and GGAC sequence contexts. Conformations from both approaches were evaluated using the same force field and a Poisson-Boltzmann continuum solvent model. Although the substate analysis predicted the sheared arrangement to be energetically preferred in both sequence contexts, a significantly greater preference of the sheared form was found for the CGAG context. In agreement with the experimental observation, the analysis of molecular dynamics trajectories indicated a preference of the sheared form in the case of the CGAG-context and a favorization of the face-to-face form in the case of the GGAC context. The computational studies allowed to identify energetic contributions that stabilize or destabilize the face-to-face and sheared tandem mismatch topologies. The calculated nonpolar solvation and Lennard-Jones packing interaction were found to stabilize the sheared topology independent of the sequence context. Electrostatic contributions are predicted to make the most significant contribution to the sequence context dependence on the structural preference of tG:A mismatches.     

Mitochondrial permeability transition as a novel principle of hepatorenal toxicity in vivo

Atractyloside (Atr) binds to the adenine nucleotide translocator (ANT) and inhibits ANT-mediated ATP/ADP exchange on the inner mitochondrial membrane. In addition, Atr can trigger opening of a non-specific ion channel, within the ANT-containing permeability transition pore complex (PTPC), which is subject to redox regulation and inhibited by cyclosporin A (CsA). Here we show that the cytotoxic effects of Atr, both in vivo and in vitro, are determined by its capacity to induce PTPC opening and consequent mitochondrial membrane permeabilization (MMP). Thus, the Atr-induced MMP and death of cultured liver cells are both inhibited by CsA as well as by glutathione (GSH) and enhanced by GSH depletion. Similarly, the hepatorenal toxicity of Atr, assessed in vivo, was reduced by treating mice with CsA or a diet rich in sulfur amino acids, a regime which enhances mitochondrial GSH levels. Atr injection induced MMP in hepatocytes and proximal renal tubular cells, and MMP was reduced by either CsA or GSH. Acetaminophen (paracetamol)-induced acute poisoning was also attenuated by CsA and GSH, both in vitro and in vivo. Altogether these data indicate that PTPC-mediated MMP may determine the hepatorenal toxicity of xenobiotics in vivo.     

Plastoquinones are effectively reduced by ferredoxin:NADP+ oxidoreductase in the presence of sodium cholate micelles. Significance for cyclic electron transport and chlororespiration

The effect of sodium cholate and other detergents (Triton X-100, sodium dodecyl sulphate, octyl glucoside, myristyltrimethylammonium bromide) on the reduction of plastoquinones (PQ) with a different length of the side-chain by spinach ferredoxin:NADP(+) oxidoreductase (FNR) in the presence of NADPH has been studied. Both NADPH oxidation and oxygen uptake due to plastosemiquinone autoxidation were highly stimulated only in the presence of sodium cholate among the used detergents. Sodium cholate at the concentration of 20 mM was found to be the most effective on both PQ-4 and PQ-9-mediated oxygen uptake. The FNR-dependent reduction of plastoquinones incorporated into sodium cholate micelles was stimulated by spinach ferredoxin but inhibited by Mg(2+) ions. It was concluded that the structure of sodium cholate micelles facilitates contact of plastoquinone molecules with the enzyme and creates favourable conditions for the reaction similar to those found in thylakoid membranes for PQ-9 reduction. The obtained results were discussed in terms of the function of FNR as a ferredoxin:plastoquinone reductase both in cyclic electron transport and chlororespiration.     

Partial purification and characterization of mitochondrial DNA polymerase from Plasmodium falciparum

Mitochondria of chloroquine-resistant Plasmodium falciparum (K1 strain) were isolated from mature trophozoites by differential centrifugation. The mitochondrial marker enzyme cytochrome c reductase was employed to monitor the steps of mitochondria isolation. Partial purification of DNA polymerase from P. falciparum mitochondria was performed using fast protein liquid chromatography (FPLC). DNA polymerase of P. falciparum mitochondria was characterized as a gamma-like DNA polymerase based on its sensitivity to the inhibitors aphidicolin, N-ethylmaleimide and 9-beta-D-arabinofuranosyladenine-5'-triphosphate. In contrast, the enzyme was found to be strongly resistant to 2',3'-dideoxythymidine-5'-triphosphate (IC(50)>400 microM) and differed in this aspect from the human homologue, possibly indicating structural differences between human and P. falciparum DNA polymerase gamma. In addition, the DNA polymerase of parasite mitochondria was shown to be resistant (IC(50)>1 mM) to the nucleotide analogue (S)-1-[3-hydroxy-2-phosphonylmethoxypropyl]adenine diphosphate (HPMPApp).