Stabilizing the eIF4G1 α-helix increases its binding affinity with eIF4E: implications for peptidomimetic design strategies

Eukaryotic initiation factor (eIF)4E is overexpressed in many types of cancer such as breast, head and neck, and lung. A consequence of increased levels of eIF4E is the preferential translation of pro-tumorigenic proteins such as c-Myc, cyclin D1, and vascular endothelial growth factor. Inhibition of eIF4E is therefore a potential therapeutic target for human cancers. A novel peptide based on the eIF4E-binding peptide eIF4G1, where the α-helix was stabilized by the inclusion of α-helix inducers as shown by CD measurements, was synthesized. The helically stabilized peptide binds with an apparent K_d of 9.43 ± 2.57 nM, which is ∼ 15.7-fold more potent than the template peptide from which it is designed. The helically stabilized peptide showed significant biological activity at a concentration of 400 μM, unlike the naturally occurring eIFG1 peptide when measured in cell-based cap-dependent translational reporter and WST-1 (4-[3-(4-iodophenyl)-2-(4-nitrophenyl)-2H-5-tetrazolio]-1,3-benzene disulfonate) assays. Fusion of the template peptide and the stabilized peptide to the cell-penetrating peptide TAT produced more active but equally potent inhibitors of cap-dependent translation in cell lines. They also equally disrupted cell metabolism as measured in a WST-1 assay. Propidium iodide staining revealed that the TAT-fused, helically stabilized peptide caused more cell death than the TAT-fused eIF4G1 template peptide with substantial decreases in the G1 and G2 cell populations. Annexin-staining experiments also indicated that the TAT-fused eIF4G1 derivative peptides caused cell death by apoptosis. The results presented should offer further insight into peptidomimetics development for eIF4E.     

eIF4E作用及调节机制

eIF4E作为翻译启动因子复合体eIF4-F的关键部分,调节细胞的蛋白质合成的限速步骤,ras基因加强eIF4E的磷酸化,c-myc基因增加eIF4E mRNA水平,eIF4E活性随其本身磷酸化的加强而加强,随其结合蛋白的磷酸化加强而减弱。eIF4E是新近发现的原癌,这量的eIF4E选择性地加强原癌基因等“弱mRNA”的翻译：可以通过加强蛋白质合成的速度,也可以加速mRNA由细胞核由胞浆转移。     

eIF4A1与TrkA相互作用后抑制TrkA的泛素化

神经生长因子（NGF）结合细胞表面受体p75NTR(p75神经营养素受体)和TrkA（酪氨酸蛋白激酶A）后介导了细胞分化、细胞生存、凋亡、增殖和侵袭等多个重要的生理病理过程. TrKA能与细胞内多个蛋白质相互作用,但是由于NGF信号通路的复杂性,现在仍有必要发现与之相互作用的蛋白质以更准确地了解NGF信号通路. 本研究中我们通过酵母双杂交的方法筛选到了一个新的与TrKA相互作用的蛋白质——真核生物翻译起始因子4A1（eIF4A1）,然后通过谷胱甘肽巯基转移酶融合蛋白沉降实验（GST-pull-down）和免疫共沉淀实验（Co-IP）证明了TrkA和eIF4A1的相互作用. 此外NGF能够增强TrkA和eIF4A1的相互作用. 在鉴定相互作用位点实验中,我们发现eIF4A1的氨基端结构域和TrkA的TK结构域参与了相互作用. TrkA和eIF4A1共定位在细胞膜上. NGF能够引起TrkA与泛素蛋白63位的赖氨酸连接,而eIF4A1与TrkA相互作用后能够抑制TrkA与泛素蛋白63位的赖氨酸连接. 综上,得出结论 eIF4A1通过与TrkA相互作用抑制其泛素化调控NGF信号通路.     

eIF4E抑制性蛋白翻译调控机制

真核生物mRNA的翻译调控,通常发生在起始阶段。异源三聚体复合物eIF4F中的eIF4E与mRNA5'端帽子结构的结合是该阶段的核心,而eIF4E抑制性蛋白正是通过与eIF4E的相互作用而调控着翻译起始过程,进而调控着翻译的速率。eIF4E抑制性蛋白对翻译的这种调控作用对细胞的生长、发育、癌症以及神经生物学方面有巨大影响,现主要就eIF4E抑制性蛋白的翻译调控机制进行综述。     

Large G3BP-induced granules trigger eIF2α phosphorylation

Stress granules are large messenger ribonucleoprotein (mRNP) aggregates composed of translation initiation factors and mRNAs that appear when the cell encounters various stressors. Current dogma indicates that stress granules function as inert storage depots for translationally silenced mRNPs until the cell signals for renewed translation and stress granule disassembly. We used RasGAP SH3-binding protein (G3BP) overexpression to induce stress granules and study their assembly process and signaling to the translation apparatus. We found that assembly of large G3BP-induced stress granules, but not small granules, precedes phosphorylation of eIF2α. Using mouse embryonic fibroblasts depleted for individual eukaryotic initiation factor 2α (eIF2α) kinases, we identified protein kinase R as the principal kinase that mediates eIF2α phosphorylation by large G3BP-induced granules. These data indicate that increasing stress granule size is associated with a threshold or switch that must be triggered in order for eIF2α phosphorylation and subsequent translational repression to occur. Furthermore, these data suggest that stress granules are active in signaling to the translational machinery and may be important regulators of the innate immune response.     

Specific in vitro phosphorylation of plant eIF2α by eukaryotic eIF2α kinases

Phosphorylation of the subunit of eukaryotic initiation factor 2 (eIF2) is known to be an important translational control mechanism in all eukaryotes with the major exception of plants. Regulation of mammalian and yeast eIF2 activity is directly governed by specific phosphorylation on Ser-51. We now demonstrate that recombinant wheat wild-type (51S) but not mutant 51-Ala (51A) protein is phosphorylated by human PKR and yeast GCN2, which are defined eIF2 kinases. Further, only wheat wild-type eIF2 is a substrate for plant-encoded, double-stranded RNA-dependent kinase (pPKR) activity. Plant PKR and GCN2 phosphorylate recombinant yeast eIF2 51S but not the 51A mutant demonstrating that pPKR has recognition site capability similar to established eIF2 kinases. A truncated version of wild-type wheat eIF2 containing 51S but not the KGYID motif is not phosphorylated by either hPKR or pPKR suggesting that this putative eIF2 kinase docking domain is essential for phosphorylation. Taken together, these results demonstrate the homology among eukaryotic eIF2 species and eIF2 kinases and support the presence of a plant eIF2 phosphorylation pathway.     

Does phosphorylation of the cap-binding protein eIF4E play a role in translation initiation?

Eukaryotic initiation factor 4E (eIF4E) plays an important role in mRNA translation by binding the 5'-cap structure of the mRNA and facilitating the recruitment to the mRNA of other translation factors and the 40S ribosomal subunit. eIF4E can interact either with the scaffold protein eIF4G or with repressor proteins termed eIF4E-binding proteins (4E-BPs). High levels of expression can disrupt cellular growth control and are associated with human cancers. A fraction of the cellular eIF4E is found in the nucleus where it may play a role in the transport of certain mRNAs to the cytoplasm. eIF4E undergoes regulated phosphorylation (at Ser209) by members of the Mnk group of kinases, which are activated by multiple MAP kinases (hence Mnk = MAP-kinase signal integrating kinase). The functional significance of its phosphorylation has been the subject of considerable interest. Recent genetic studies in Drosophila point to a key role for phosphorylation of eIF4E in growth and viability. Initial structural data suggested that phosphorylation of Ser209 might allow formation of a salt bridge with a basic residue (Lys159) that would clamp eIF4E onto the mRNA and increase its affinity for ligand. However, more recent structural data place Ser209 too far away from Lys159 to form such an interaction, and biophysical studies indicate that phosphorylation actually decreases the affinity of eIF4E for cap or capped RNA. The implications of these studies are discussed in the light of other, in vitro and in vivo, investigations designed to address the role of eIF4E phosphorylation in mRNA translation or its control.     

shRNA干扰eIF4A1基因对胶质瘤细胞体内外生物学特征的影响

胶质瘤是颅内常见的肿瘤,其中恶性脑胶质瘤成弥漫性生长,尽管给予手术、放疗或化疗等综合治疗,仍极易复发,迫切需要探索新的治疗方法.但是胶质瘤的治疗靶点匮乏,因此探索有效的靶点对其治疗具有重要的意义.本研究中首先利用中国脑胶质瘤基因组图谱计划数据库(Chinese glioma genome altas, CGGA)分析了真核生物翻译起始因子中eIF4A1与脑胶质瘤的关系.生物信息学分析显示, eIF4A与胶质瘤病理分级相关并且在胶质瘤细胞中高表达. eIF4A1的抑制剂Silvestrol明显抑制胶质瘤细胞的增殖能力.利用慢病毒感染胶质瘤细胞建立shRNA干扰eIF4A1基因的胶质瘤细胞株,进行了一系列体内外生物学特征的实验,研究结果发现, shRNA干扰eIF4A1基因后能够有效抑制胶质瘤细胞的增殖、克隆形成、细胞侵袭和迁移.因此,本实验研究证实eIF4A1是胶质瘤治疗的有效靶点,为胶质瘤的临床治疗提供可靠的理论基础.     

Cannabinoid Modulation of Eukaryotic Initiation Factors (eIF2α and eIF2B1) and Behavioral Cross-Sensitization to Cocaine in Adolescent Rats

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UsingGCN4as a Reporter of eIF2α Phosphorylation and Translational Regulation in Yeast

Molecular genetic analyses in yeast are a powerful method to study gene regulation. Conservation of the mechanism and regulation of protein synthesis between yeast and mammalian cells makes yeast a good model system for the analysis of translation. One of the most common mechanisms of translational regulation in mammalian cells is the phosphorylation of serine-51 on the α subunit of the translation initiation factor eIF2, which causes an inhibition of general translation. In contrast, in the yeastSaccharomyces cerevisiaephosphorylation of eIF2α on serine-51 by theGCN2protein kinase mediates the translational induction ofGCN4expression. The unique structure of theGCN4mRNA makesGCN4expression especially sensitive to eIF2α phosphorylation, and the simple microbiological tests developed in yeast to analyzeGCN4expression serve as good reporters of eIF2α phosphorylation. It is relatively simple to express heterologous proteins in yeast, and it has been shown that the mammalian eIF2α kinases will functionally substitute forGCN2.Structure–function analyses of translation factors or translational regulators can also be performed by assaying for effects on general andGCN4-specific translation. Three tests can be used to study eIF2α phosphorylation and/or translational activity in yeast. First, general translation can be monitored by simple growth tests, whileGCN4expression can be analyzed using sensitive replica-plating tests. Second,GCN4translation can be quantitated by measuring expression fromGCN4–lacZreporter constructs. Finally, isoelectric focusing gels can be used to directly monitorin vivophosphorylation of eIF2α in yeast.     

Superoxide activates mTOR–eIF4E–Bax route to induce enhanced apoptosis in leukemic cells

Mammalian target of rapamycin (mTOR) is a central kinase that regulates cell survival, proliferation and translation. Reactive oxygen species (ROS) are second messengers with potential in manipulating cellular signaling. Here we report that two ROS generating phytochemicals, hydroxychavicol and curcumin synergize in leukemic cells in inducing enhanced apoptosis by independently activating both mitogen activated protein kinase (MAPK) (JNK and P³⁸) and mTOR pathways. Low level transient ROS generated after co-treatment with these phytochemicals led to activation of these two pathways. Both mTOR and MAPK pathways played important roles in co-treatment-induced apoptosis, by knocking down either mTOR or MAPKs inhibited apoptosis. Activation of mTOR, as evident from phosphorylation of its downstream effector eukaryotic translation initiation factor 4E-binding protein 1, led to release of eukaryotic translation initiation factor 4E (eIF4E) which was subsequently phosphorylated by JNK leading to translation of pro-apoptotic proteins Bax and Bad without affecting the expression of anti-apoptotic protein Bcl-xl. Our data suggest that mTOR and MAPK pathways converge at eIF4E in co-treatment-induced enhanced apoptosis and provide mechanistic insight for the role of mTOR activation in apoptosis.     

Sequential Eukaryotic Translation Initiation Factor 5 (eIF5) Binding to the Charged Disordered Segments of eIF4G and eIF2β Stabilizes the 48S Preinitiation Complex and Promotes Its Shift to the Initiation Mode

During translation initiation in Saccharomyces cerevisiae, an Arg- and Ser-rich segment (RS1 domain) of eukaryotic translation initiation factor 4G (eIF4G) and the Lys-rich segment (K-boxes) of eIF2β bind three common partners, eIF5, eIF1, and mRNA. Here, we report that both of these segments are involved in mRNA recruitment and AUG recognition by distinct mechanisms. First, the eIF4G-RS1 interaction with the eIF5 C-terminal domain (eIF5-CTD) directly links eIF4G to the preinitiation complex (PIC) and enhances mRNA binding. Second, eIF2β-K-boxes increase mRNA binding to the 40S subunit in vitro in a manner reversed by the eIF5-CTD. Third, mutations altering eIF4G-RS1, eIF2β-K-boxes, and eIF5-CTD restore the accuracy of start codon selection impaired by an eIF2β mutation in vivo, suggesting that the mutual interactions of the eIF segments within the PIC prime the ribosome for initiation in response to start codon selection. We propose that the rearrangement of interactions involving the eIF5-CTD promotes mRNA recruitment through mRNA binding by eIF4G and eIF2β and assists the start codon-induced release of eIF1, the major antagonist of establishing tRNA(i)(Met):mRNA binding to the P site.     

Interaction Between Yeast Eukaryotic Initiation Factor eIF4E and mRNA 5′ Cap Analogues Differs from That for Murine eIF4E

Abstract

Measurements of interaction of 7-methyl-GTP eIF4E from S. cerevisiae were performed by means of two methods: Isothermal Titration Calorimetry (ITC) and fluorescence titration. The equilibrium association constants (K_as) derived from the two methods show significantly different affinity of yeast eIF4E for the mRNA 5′ cap than those of the murine and human proteins. The observed differences in the K_as values and the enthalpy changes of the association (ΔH°) suggest some dissimilarity in the mode of binding and stabilization of cap in the complexes with eIF4E from various sources.     

eIF2α kinases control chalone production in Dictyostelium discoideum

Growing Dictyostelium cells secrete CfaD and AprA, two proteins that have been characterized as chalones. They exist within a high-molecular-weight complex that reversibly inhibits cell proliferation, but not growth, via cell surface receptors and a signaling pathway that includes G proteins. How the production of these two proteins is regulated is unknown. Dictyostelium cells possess three GCN2-type eukaryotic initiation factor 2 α subunit (eIF2α) kinases, proteins that phosphorylate the translational initiation factor eIF2α and possess a tRNA binding domain involved in their regulation. The Dictyostelium kinases have been shown to function during development in regulating several processes. We show here that expression of an unregulated, activated kinase domain greatly inhibits cell proliferation. The inhibitory effect on proliferation is not due to a general inhibition of translation. Instead, it is due to enhanced production of a secreted factor(s). Indeed, extracellular CfaD and AprA proteins, but not their mRNAs, are overproduced in cells expressing the activated kinase domain. The inhibition of proliferation is not seen when the activated kinase domain is expressed in cells lacking CfaD or AprA or in cells that contain a nonphosphorylatable eIF2α. We conclude that production of the chalones CfaD and AprA is translationally regulated by eIF2α phosphorylation. Both proteins are upregulated at the culmination of development, and this enhanced production is lacking in a strain that possesses a nonphosphorylatable eIF2α.     

我国辣椒种质资源eIF4E基因多态性分析

利用国家蔬菜种质资源库的1904份辣椒资源材料,采用测序技术获得eIF4E(eukaryotic translation initiation 4E)基因exon1序列,研究e IF4E基因多样性及我国辣椒种质资源群体多样性。结果表明:在1904份材料中共发现17个单倍型,14个有义多态性位点,其中9个为新的位点,位点大多集中在eIF4E蛋白表面环上;8个地理群体的平均单倍型多样性(Hd)和平均核苷酸多样性(Pi)分别为0.519和0.00210;群体间分化指数(Fst值)及基因流(Nm)表明不同群体间表现差异的分化程度;AMOVA分析表明总变异主要来源于群体内个体间的变异(97.23%),只有2.77%变异发生在群体间。本研究将有助于了解我国辣椒eIF4E基因多样性,为抗PVY育种提供更多抗源材料。     

Roles of yeast eIF2α and eIF2β subunits in the binding of the initiator methionyl-tRNA

Heterotrimeric eukaryotic/archaeal translation initiation factor 2 (e/aIF2) binds initiator methionyl-tRNA and plays a key role in the selection of the start codon on messenger RNA. tRNA binding was extensively studied in the archaeal system. The γ subunit is able to bind tRNA, but the α subunit is required to reach high affinity whereas the β subunit has only a minor role. In Saccharomyces cerevisiae however, the available data suggest an opposite scenario with β having the most important contribution to tRNA-binding affinity. In order to overcome difficulties with purification of the yeast eIF2γ subunit, we designed chimeric eIF2 by assembling yeast α and β subunits to archaeal γ subunit. We show that the β subunit of yeast has indeed an important role, with the eukaryote-specific N- and C-terminal domains being necessary to obtain full tRNA-binding affinity. The α subunit apparently has a modest contribution. However, the positive effect of α on tRNA binding can be progressively increased upon shortening the acidic C-terminal extension. These results, together with small angle X-ray scattering experiments, support the idea that in yeast eIF2, the tRNA molecule is bound by the α subunit in a manner similar to that observed in the archaeal aIF2–GDPNP–tRNA complex.     

eIF4A1与TrkA相互作用后抑制TrkA的泛素化（英文）

神经生长因子(NGF)结合细胞表面受体p75NTR (p75神经营养素受体)和TrkA (酪氨酸蛋白激酶A)后介导了细胞分化、细胞生存、凋亡、增殖和侵袭等多个重要的生理病理过程. TrKA能与细胞内多个蛋白质相互作用,但是由于NGF信号通路的复杂性,现在仍有必要发现与之相互作用的蛋白质以更准确地了解NGF信号通路.本研究中我们通过酵母双杂交的方法筛选到了一个新的与TrKA相互作用的蛋白质——真核生物翻译起始因子4A1 (eIF4A1),然后通过谷胱甘肽巯基转移酶融合蛋白沉降实验(GST-pull-down)和免疫共沉淀实验(Co-IP)证明了TrkA和eIF4A1的相互作用.此外NGF能够增强TrkA和eIF4A1的相互作用.在鉴定相互作用位点实验中,我们发现eIF4A1的氨基端结构域和TrkA的TK结构域参与了相互作用. TrkA和e IF4A1共定位在细胞膜上. NGF能够引起TrkA与泛素蛋白63位的赖氨酸连接,而eIF4A1与TrkA相互作用后能够抑制TrkA与泛素蛋白63位的赖氨酸连接.综上,得出结论 e IF4A1通过与TrkA相互作用抑制其泛素化调控NGF信号通路.     

实时逆转录PCR检测G1、G2和G4型轮状病毒方法的建立

目的建立3种用于检测G1、G2和G4型轮状病毒VP7基因的一步法实时逆转录PCR,用于本实验室G1、G2和G4型轮状病毒的快速检测和定量、定性分析。方法设计G1、G2和G4型轮状病毒VP7基因特异性引物和探针,采用G1、G2和G4型轮状病毒特异性体外转录RNAs,建立实时逆转录PCR,特异性检测G1、G2和G4型轮状病毒VP7基因方法。结果 3种实时逆转录PCR标准曲线R~2均大于0.99,扩增效率均在90%～110%之间。不同浓度体外转录RNAs重复性检测结果 CV均5%,且可以对单拷贝RNAs样本进行检测。结论本检测方法快速、灵敏且重复性好,可以对轮状病毒VP7基因进行特异而有效的检测,为实验室轮状病毒毒株的分型和定量检测提供了特异而有效的检测方法,也为今后多重实时逆转录PCR的建立奠定了试验基础。