Molecular physiology of glutamine and glutamate biosynthesis in developing seedlings of conifers

Nitrogen is a limiting factor in tree growth and development. The incorporation of ammonium ions in carbon skeletons is catalyzed by the sequential action of the enzymes glutamine synthetase (GS) and glutamate synthase (GOGAT). Most studies on nitrogen‐assimilating enzymes have been reported for annual crop plants. Knowledge of these enzymes in woody plants is much more limited, particularly at the molecular level. Here, we review current available information on glutamine/glutamate biosynthesis and chloroplast development in conifers.     

Bcs1p can rescue a large and productive cytochrome bc1 complex assembly intermediate in the inner membrane of yeast mitochondria

The yeast cytochrome bc₁ complex, a component of the mitochondrial respiratory chain, is composed of ten distinct protein subunits. In the assembly of the bc₁ complex, some ancillary proteins, such as the chaperone Bcs1p, are actively involved. The deletion of the nuclear gene encoding this chaperone caused the arrest of the bc₁ assembly and the formation of a functionally inactive bc₁ core structure of about 500-kDa. This immature bc₁ core structure could represent, on the one hand, a true assembly intermediate or, on the other hand, a degradation product and/or an incorrect product of assembly. The experiments here reported show that the gradual expression of Bcs1p in the yeast strain lacking this protein was progressively able to rescue the bc₁ core structure leading to the formation of the functional homodimeric bc₁ complex. Following Bcs1p expression, the mature bc₁ complex was also progressively converted into two supercomplexes with the cytochrome c oxidase complex. The capability of restoring the bc₁ complex and the supercomplexes was also possessed by the mutated yeast R81C Bcsp1. Notably, in the human ortholog BCS1L, the corresponding point mutation (R45C) was instead the cause of a severe bc₁ complex deficiency. Differently from the yeast R81C Bcs1p, two other mutated Bcs1p's (K192P and F401I) were unable to recover the bc₁ core structure in yeast. This study identifies for the first time a productive assembly intermediate of the yeast bc₁ complex and gives new insights into the molecular mechanisms involved in the last steps of bc₁ assembly.     

Enhanced plasminogen activation by staphylokinase in the presence of streptokinase beta/betagamma domains: plasminogen kringles play a role

Presence of isolated beta or betagamma domains of streptokinase (SK) increased the catalytic activity of staphylokinase (SAK)-plasmin (Pm) complex up to 60%. In contrast, fusion of SK beta or betagamma domains with the C-terminal end of SAK drastically reduced the catalytic activity of the activator complex. The enhancement effect mediated by beta or betagamma domain on Pg activator activity of SAK-Pm complex was reduced greatly (45%) in the presence of isolated kringles of Pg, whereas, kringles did not change cofactor activity of SAK fusion proteins (carrying beta or betagamma domains) significantly. When catalytic activity of SAK-microPm (catalytic domain of Pm lacking kringle domains) complex was examined in the presence of isolated beta and betagamma domains, no enhancement effect on Pg activation was observed, whereas, enzyme complex formed between microplasmin and SAK fusion proteins (SAKbeta and SAKbetagamma) displayed 50-70% reduction in their catalytic activity. The present study, thus, suggests that the exogenously present beta and betagamma interact with Pg/Pm via kringle domains and elevate catalytic activity of SAK-Pm activator complex resulting in enhanced substrate Pg activation. Fusion of beta or betagamma domains with SAK might alter these intermolecular interactions resulting in attenuated functional activity of SAK.     

Interplay of cis- and trans-regulatory mechanisms in the spliceosomal RNA helicase Brr2

RNA helicase Brr2 is implicated in multiple phases of pre-mRNA splicing and thus requires tight regulation. Brr2 can be auto-inhibited via a large N-terminal region folding back onto its helicase core and auto-activated by a catalytically inactive C-terminal helicase cassette. Furthermore, it can be regulated in trans by the Jab1 domain of the Prp8 protein, which can inhibit Brr2 by intermittently inserting a C-terminal tail in the enzyme's RNA-binding tunnel or activate the helicase after removal of this tail. Presently it is unclear, whether these regulatory mechanisms functionally interact and to which extent they are evolutionarily conserved. Here, we report crystal structures of Saccharomyces cerevisiae and Chaetomium thermophilum Brr2-Jab1 complexes, demonstrating that Jab1-based inhibition of Brr2 presumably takes effect in all eukaryotes but is implemented via organism-specific molecular contacts. Moreover, the structures show that Brr2 auto-inhibition can act in concert with Jab1-mediated inhibition, and suggest that the N-terminal region influences how the Jab1 C-terminal tail interacts at the RNA-binding tunnel. Systematic RNA binding and unwinding studies revealed that the N-terminal region and the Jab1 C-terminal tail specifically interfere with accommodation of double-stranded and single-stranded regions of an RNA substrate, respectively, mutually reinforcing each other. Additionally, such analyses show that regulation based on the N-terminal region requires the presence of the inactive C-terminal helicase cassette. Together, our results outline an intricate system of regulatory mechanisms, which control Brr2 activities during snRNP assembly and splicing.     

Nitrogen assimilation in opaque and normal sorghum during grain development

Activity of key nitrogen assimilating enzymes was studied in developing grains of high-lysine opaque sorghum P-721 and normal sorghum CSV-5. The higher percentage of protein in opaque sorghum was mainly due to lower starch content since protein per grain was less than in CSV-5. During grain development, albufn and globulin decreased while prolafne and glutelin increased. Prolafne content in CSV-5 was higher than in opaque sorghum. Average nitrate reductase activity in flag and long leaf were similar in both the varieties. The nitrate reductase activity decreased during grain development. Glutamate dehydrogenase activity was higher during early development and lower at later stages in opaque sorghum than in CSV-5. Glutamate oxaloacetate transaminase activity was higher and glutamine synthetase lower in opaque sorghum than in CSV-5 grains during development. Glutamate synthase activity was higher in opaque sorghum up to day 20 and lower thereafter than in CSV-5. It is suggested that reduced activities of glutamine synthetase as well as glutamate synthase in opaque sorghum as compared to CSV-5 during later stages of development may restrict protein accumulation in the former.     

All-Atom Structural Models for Complexes of Insulin-Like Growth Factors IGF1 and IGF2 with Their Cognate Receptor

Type 1 insulin-like growth factor receptor (IGF1R) is a membrane-spanning glycoprotein of the insulin receptor family that has been implicated in a variety of cancers. The key questions related to molecular mechanisms governing ligand recognition by IGF1R remain unanswered, partly due to the lack of testable structural models of apo or ligand-bound receptor complexes. Using a homology model of the IGF1R ectodomain IGF1RΔβ, we present the first experimentally consistent all-atom structural models of IGF1/IGF1RΔβ and IGF2/IGF1RΔβ complexes. Our explicit-solvent molecular dynamics (MD) simulation of apo-IGF1RΔβ shows that it displays asymmetric flexibility mechanisms that result in one of two binding pockets accessible to growth factors IGF1 and IGF2, as demonstrated via an MD-assisted Monte Carlo docking procedure. Our MD-generated ensemble of structures of apo and IGF1-bound IGF1RΔβ agrees reasonably well with published small-angle X-ray scattering data. We observe simultaneous contacts of each growth factor with sites 1 and 2 of IGF1R, suggesting cross-linking of receptor subunits. Our models provide direct evidence in favor of suggested electrostatic complementarity between the C-domain (IGF1) and the cysteine-rich domain (IGF1R). Our IGF1/IGF1RΔβ model provides structural bases for the observation that a single IGF1 molecule binds to IGF1RΔβ at low concentrations in small-angle X-ray scattering studies. We also suggest new possible structural bases for differences in the affinities of insulin, IGF1, and IGF2 for their noncognate receptors.     

Minority of mammalian orthologs can be regarded as physiologically closest genes

Orthologs are genes from different genomes that originate from a common ancestor gene by speciation event. They are most similar by the structure of encoded proteins and therefore should have a similar function. Here I apply the principle used for detection of structural orthology for a genome-wide analysis of gene expression. For this purpose, I determine the mutual similarity rank in all-by-all comparison of among-tissues expression patterns. The expression of most part of human–mouse orthologs in homologous tissues is poorly correlated (average mutual coexpression rank is only 4835 out of 18,092). Genes from evolutionarily labile gene families, which experience rapid turnover of family composition, are among those with the strongest expression change. However, the revealed phenomenon is not limited to them. There is no or very weak relationship between protein sequence divergence and mutual coexpression rank. Also, generally there is no relationship between the ratio of nonsynonymous to synonymous nucleotide substitutions and coexpression rank. This relationship is tangible only within evolutionarily labile gene families. These results indicate that despite of a similar biochemical function of orthologs reflected in the conserved protein sequence, the physiological (systemic) context of this function can be changed. Also, these results suggest that gene biochemical function and its physiological role in the organism can evolve independently.     

Reversible Activation of Glutamate Transport in Rat Brain Glia by Protein Kinase C and an Okadaic Acid-Sensitive Phosphoprotein Phosphatase

High-affinity L-glutamate (GLU) transport is an important regulator of excitatory amino acid (EAA) concentrations in brain extracellular fluid and may play a key role in excitatory synaptic transmission. In view of evidence that EAA transporters (EAAT) are heterogenous and contain consensus sites for phosphorylation, this investigation was undertaken to contrast the effects of transporter phosphorylation in fractions derived from glia and neurons (synaptosomes) of the adult rat forebrain. Treatment with phorbol-12,13-dibutyrate (PDBu), an activator of protein kinase C (PKC), increased the maximal rate of GLU transport in glial plasmalemmal vesicles by greater than 50 percent (237 ± 18 vs. 365 ± 27 pmol/mg protein/90s, p < 0.05) but caused no change in synaptosomes. The effect by PDBu was concentration and time-dependent and was inhibited completely by the PKC inhibitor calphostin C. Inhibition of serine-threonine phosphoprotein phosphatases with okadaic acid produced similar effects which were not additive with PDBu. Together, these results demonstrate that glial EAAT can be regulated by multiple phosphorylation processes.     

神经前体细胞表达发育性下调蛋白4在消化系统肿瘤发生中的作用

神经前体细胞表达发育性下调蛋白4(neural precursor cell expressed,developmentally down-regulated protein 4,NEDD4-1,部分文章也称NEDD4)是近年来才备受关注的肿瘤相关基因,属于E3 HECT(homologous to E6 associated protein C terminus,E6蛋白c端同源基因)泛素连接酶NEDD4样家族成员。泛素连接酶,能够参与多种蛋白质的泛素化、溶酶体及蛋白酶体的降解、胞核-胞质转位等,间接影响不同恶性肿瘤的多种信号通路。随着大量NEDD4-1与肿瘤相关实验的不断深入,目前已发现其可通过调控细胞周期、癌细胞侵袭转移、拮抗耐药性等许多途径影响肿瘤的生物学行为。在消化系统肿瘤中,NEDD4-1主要通过PTEN/PI3K/AKT、TGF-β、Hippo、LDLRAD4等多条通路促进肝细胞癌的增殖、侵袭和迁移能力;在胰腺癌中发现,NEDD4-1在PI3K/AKT信号通路中发挥癌基因作用,但在与Myc-SIRT2所形成的信号环路中,却发挥抑癌基因的作用;在胃癌和结直肠癌中,NEDD4-1所参与的信号通路与其他消化系统肿瘤均不相同,NEDD4-1能独立于PTEN/PI3K/AKT通路而发挥促进胃癌恶化、转移(EGFR信号通路)和抑制结直肠癌肿瘤生长(WNT信号通路)的作用。NEDD4-1已经成为人们治愈肿瘤的热门研究方向。本文通过系统总结NEDD4-1在不同消化系统肿瘤中的功能、信号通路和潜在抑制剂等,进行探讨NEDD4-1与不同信号通路的关系,旨为临床在癌症治疗领域提供重要的参考数据。     

海洋微生物裂解二甲基巯基丙酸内盐(DMSP)的酶促催化机制

二甲基巯基丙酸内盐(dimethylsulfoniopropionate,DMSP)是全球硫循环和碳循环的重要载体物质。海洋浮游植物、大型藻类和临海被子植物是DMSP的主要生产者。每年DMSP的产量可以达到1×10~9吨。在北大西洋表面的某些区域,DMSP的产量可以达到碳固定总量的10%。微生物介导的DMSP的裂解是全球硫循环和碳循环的重要步骤。目前,8种参与裂解DMSP的DMSP裂解酶已被报道。在已发现的8种DMSP裂解酶中,3种DMSP裂解酶的催化机制得到了研究和阐明。本文根据国内外研究成果,主要对DMSP裂解过程的酶促催化机制的研究进展进行综述,认为在今后工作中需要继续发现新的DMSP裂解酶,并进一步揭示海洋微生物裂解DMSP的分子机制。