Project description:This SuperSeries is composed of the SubSeries listed below.

Project description:Flaviviruses are enveloped viruses that infect multiple hosts. Envelope proteins are the outermost proteins in the structure of flaviviruses and mediate viral infection. Studies indicate that flaviviruses mainly use envelope proteins to bind to cell attachment receptors and endocytic receptors for the entry step. Here, we present current findings regarding key envelope protein amino acids that participate in the flavivirus early infection process. Among these sites, most are located in special positions of the protein structure, such as the α-helix in the stem region and the hinge region between domains I and II, motifs that potentially affect the interaction between different domains. Some of these sites are located in positions involved in conformational changes in envelope proteins. In summary, we summarize and discuss the key envelope protein residues that affect the entry process of flaviviruses, including the process of their discovery and the mechanisms that affect early infection.

Project description:Protein synthesis is metabolically costly, and the level of translation must match nutrient availability and cellular needs. Overall protein synthesis levels are modulated by regulating translation initiation. The cap-binding protein eIF4E—the earliest contact between mRNAs and the translation machinery—serves as one point of control, but its contributions to mRNA-specific translation regulation remain poorly understood. We acutely depleted eIF4E, which is essential in budding yeast, and observed surprisingly modest effects on cell growth and protein synthesis. Long-lived transcripts were downregulated, likely reflecting accelerated turnover, and the strongest gene-specific effects arose as secondary effects of reduced protein biosynthesis on amino acid pools. Futile cycles of amino acid synthesis and degradation were accompanied by translational activation of GCN4, which is typically induced by amino acid starvation. We further identified translational tuning of PCL5, a negative regulator of Gcn4, that provides a consistent protein-to-mRNA ratio under varying translation environments. This translational control depended in part on a uniquely long poly-(A) tract in the PCL5 5’ UTR and on poly-(A) binding protein. These results highlight the intricate interplay between translation, amino acid homeostasis, and gene regulation and uncover new layers of feedback control in cellular response to stress and nutrient availability.

Project description:Protein synthesis is metabolically costly, and the level of translation must match nutrient availability and cellular needs. Overall protein synthesis levels are modulated by regulating translation initiation. The cap-binding protein eIF4E—the earliest contact between mRNAs and the translation machinery—serves as one point of control, but its contributions to mRNA-specific translation regulation remain poorly understood. We acutely depleted eIF4E, which is essential in budding yeast, and observed surprisingly modest effects on cell growth and protein synthesis. Long-lived transcripts were downregulated, likely reflecting accelerated turnover, and the strongest gene-specific effects arose as secondary effects of reduced protein biosynthesis on amino acid pools. Futile cycles of amino acid synthesis and degradation were accompanied by translational activation of GCN4, which is typically induced by amino acid starvation. We further identified translational tuning of PCL5, a negative regulator of Gcn4, that provides a consistent protein-to-mRNA ratio under varying translation environments. This translational control depended in part on a uniquely long poly-(A) tract in the PCL5 5’ UTR and on poly-(A) binding protein. These results highlight the intricate interplay between translation, amino acid homeostasis, and gene regulation and uncover new layers of feedback control in cellular response to stress and nutrient availability.

Project description:Soybean mosaic virus (SMV), a potyvirus, is the most prevalent and destructive viral pathogen in soybean-planting regions of China. Moreover, other potyviruses, including bean common mosaic virus (BCMV) and watermelon mosaic virus (WMV), also threaten soybean farming. The eukaryotic translation initiation factor 4E (eIF4E) plays a critical role in controlling resistance/susceptibility to potyviruses in plants. In the present study, much higher SMV-induced eIF4E1 expression levels were detected in a susceptible soybean cultivar when compared with a resistant cultivar, suggesting the involvement of eIF4E1 in the response to SMV by the susceptible cultivar. Yeast two-hybrid and bimolecular fluorescence complementation assays showed that soybean eIF4E1 interacted with SMV VPg in the nucleus and with SMV NIa-Pro/NIb in the cytoplasm, revealing the involvement of VPg, NIa-Pro, and NIb in SMV infection and multiplication. Furthermore, transgenic soybeans silenced for eIF4E were produced using an RNA interference approach. Through monitoring for viral symptoms and viral titers, robust and broad-spectrum resistance was confirmed against five SMV strains (SC3/7/15/18 and SMV-R), BCMV, and WMV in the transgenic plants. Our findings represent fresh insights for investigating the mechanism underlying eIF4E-mediated resistance in soybean and also suggest an effective alternative for breeding soybean with broad-spectrum viral resistance.

Project description:Protein synthesis is metabolically costly, and the level of translation must match nutrient availability and cellular needs. Overall protein synthesis levels are modulated by regulating translation initiation. The cap-binding protein eIF4E—the earliest contact between mRNAs and the translation machinery—serves as one point of control, but its contributions to mRNA-specific translation regulation remain poorly understood. We acutely depleted eIF4E, which is essential in budding yeast, and observed surprisingly modest effects on cell growth and protein synthesis. Long-lived transcripts were downregulated, likely reflecting accelerated turnover, and the strongest gene-specific effects arose as secondary effects of reduced protein biosynthesis on amino acid pools. Futile cycles of amino acid synthesis and degradation were accompanied by translational activation of GCN4, which is typically induced by amino acid starvation. We further identified translational tuning of PCL5, a negative regulator of Gcn4, that provides a consistent protein-to-mRNA ratio under varying translation environments. This translational control depended in part on a uniquely long poly-(A) tract in the PCL5 5’ UTR and on poly-(A) binding protein. These results highlight the intricate interplay between translation, amino acid homeostasis, and gene regulation and uncover new layers of feedback control in cellular response to stress and nutrient availability.

Project description:Amino acids fulfil a diverse range of roles in proteins, each utilising its chemical properties in different ways in different contexts to create required functions. For example, cysteines form disulphide or hydrogen bonds in different circumstances and charged amino acids do not always make use of their charge. The repertoire of amino acid functions and the frequency at which they occur in proteins remains understudied. Measuring large numbers of mutational consequences, which can elucidate the role an amino acid plays, was prohibitively time-consuming until recent developments in deep mutational scanning. In this study, we gathered data from 28 deep mutational scanning studies, covering 6,291 positions in 30 proteins, and used the consequences of mutation at each position to define a mutational landscape. We demonstrated rich relationships between this landscape and biophysical or evolutionary properties. Finally, we identified 100 functional amino acid subtypes with a data-driven clustering analysis and studied their features, including their frequencies and chemical properties such as tolerating polarity, hydrophobicity or being intolerant of charge or specific amino acids. The mutational landscape and amino acid subtypes provide a foundational catalogue of amino acid functional diversity, which will be refined as the number of studied protein positions increases.

Project description:The ability of phytochromes (Phy) to act as photointerconvertible light switches in plants and microorganisms depends on key interactions between the bilin chromophore and the apoprotein that promote bilin attachment and photointerconversion between the spectrally distinct red light-absorbing Pr conformer and far red light-absorbing Pfr conformer. Using structurally guided site-directed mutagenesis combined with several spectroscopic methods, we examined the roles of conserved amino acids within the bilin-binding domain of Deinococcus radiodurans bacteriophytochrome with respect to chromophore ligation and Pr/Pfr photoconversion. Incorporation of biliverdin IXalpha (BV), its structure in the Pr state, and its ability to photoisomerize to the first photocycle intermediate are insensitive to most single mutations, implying that these properties are robust with respect to small structural/electrostatic alterations in the binding pocket. In contrast, photoconversion to Pfr is highly sensitive to the chromophore environment. Many of the variants form spectrally bleached Meta-type intermediates in red light that do not relax to Pfr. Particularly important are Asp-207 and His-260, which are invariant within the Phy superfamily and participate in a unique hydrogen bond matrix involving the A, B, and C pyrrole ring nitrogens of BV and their associated pyrrole water. Resonance Raman spectroscopy demonstrates that substitutions of these residues disrupt the Pr to Pfr protonation cycle of BV with the chromophore locked in a deprotonated Meta-R(c)-like photoconversion intermediate after red light irradiation. Collectively, the data show that a number of contacts contribute to the unique photochromicity of Phy-type photoreceptors. These include residues that fix the bilin in the pocket, coordinate the pyrrole water, and possibly promote the proton exchange cycle during photoconversion.

Project description:Translational control of gene expression plays a key role in many biological processes. Consequently, the activity of the translation apparatus is under tight homeostatic control. eIF4E, the mRNA 5' cap-binding protein, facilitates cap-dependent translation and is a major target for translational control. eIF4E activity is controlled by a family of repressor proteins, termed 4E-binding proteins (4E-BPs). Here, we describe the surprising finding that despite the importance of eIF4E for translation, a drastic knockdown of eIF4E caused only minor reduction in translation. This conundrum can be explained by the finding that 4E-BP1 is degraded in eIF4E-knockdown cells. Hypophosphorylated 4E-BP1, which binds to eIF4E, is degraded, whereas hyperphosphorylated 4E-BP1 is refractory to degradation. We identified the KLHL25-CUL3 complex as the E3 ubiquitin ligase, which targets hypophosphorylated 4E-BP1. Thus, the activity of eIF4E is under homeostatic control via the regulation of the levels of its repressor protein 4E-BP1 through ubiquitination.

Project description:All eukaryotic mRNAs possess a 5'-cap (m(7)GpppN) that is recognized by a family of cap-binding proteins. These participate in various processes, such as RNA transport and stabilization, as well as in assembly of the translation initiation complex. The 5'-cap of trypanosomatids is complex; in addition to 7-methyl guanosine, it includes unique modifications on the first four transcribed nucleotides, and is thus denoted cap-4. Here we analyze a cap-binding protein of Leishmania, in an attempt to understand the structural features that promote its binding to this unusual cap. LeishIF4E-1, a homolog of eIF4E, contains the conserved cap-binding pocket, similar to its mouse counterpart. The mouse eIF4E has a higher K(as) for all cap analogs tested, as compared with LeishIF4E-1. However, whereas the mouse eIF4E shows a fivefold higher affinity for m(7)GTP than for a chemically synthesized cap-4 structure, LeishIF4E-1 shows similar affinities for both ligands. A sequence alignment shows that LeishIF4E-1 lacks the region that parallels the C terminus in the murine eIF4E. Truncation of this region in the mouse protein reduces the difference that is observed between its binding to m(7)GTP and cap-4, prior to this deletion. We hypothesize that variations in the structure of LeishIF4E-1, possibly also the absence of a region that is homologous to the C terminus of the mouse protein, promote its ability to interact with the cap-4 structure. LeishIF4E-1 is distributed in the cytoplasm, but its function is not clear yet, because it cannot substitute the mammalian eIF4E in a rabbit reticulocyte in vitro translation system.