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trans it insect transfection reagent  (Mirus Bio)


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    Mirus Bio trans it insect transfection reagent
    Global alanine-scanning mutagenesis of the protein A elbow identifies amino acid contributions to RNA replication. ( A–C ) Alanine substitutions were introduced across the 17-amino acid elbow (aa 379–395) as blocks (5 alanines, A), pairs (2 alanines, B), or single residues (1 alanine, C). Top panels: western blot detecting protein A, with tubulin as a loading control. Middle panels: northern blot analysis of RNA1 and RNA3 replication following <t>co-transfection</t> of mutant protein A plasmids with the RNA1 fs template. Bottom panels: bar graphs summarizing RNA3 replication relative to wt control across three or more experimental replicates. ( D ) Summary diagram mapping replication values from block, pair, and single alanine substitutions onto the elbow sequence. Color-coded gradients indicate functional impact: white represents mutations that abolish RNA3 replication (0%), and blue represents full replication comparable to wt (100%), allowing visualization of residues and segments critical for RNA replication. ( E ) Structure mapping of elbow (aa 379–395) characteristics. The surface diagrams use the indicated color gradients to show RNA3 replication levels (% of wt) induced by single alanine substitutions [gradient as in panel (D)], electrostatic potential (negative: red, positive: blue), and hydrophobicity (hydrophilic: blue, hydrophobic: yellow) to highlight functional features. Gray shading of the arrows indicates amino acids facing the back, while white shading indicates amino acids facing the front.
    Trans It Insect Transfection Reagent, supplied by Mirus Bio, used in various techniques. Bioz Stars score: 96/100, based on 256 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
    https://www.bioz.com/result/trans it insect transfection reagent/product/Mirus Bio
    Average 96 stars, based on 256 article reviews
    trans it insect transfection reagent - by Bioz Stars, 2026-03
    96/100 stars

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    1) Product Images from "Nodavirus protein A’s interdomain elbow controls RNA replication organelle formation and function"

    Article Title: Nodavirus protein A’s interdomain elbow controls RNA replication organelle formation and function

    Journal: Nucleic Acids Research

    doi: 10.1093/nar/gkag151

    Global alanine-scanning mutagenesis of the protein A elbow identifies amino acid contributions to RNA replication. ( A–C ) Alanine substitutions were introduced across the 17-amino acid elbow (aa 379–395) as blocks (5 alanines, A), pairs (2 alanines, B), or single residues (1 alanine, C). Top panels: western blot detecting protein A, with tubulin as a loading control. Middle panels: northern blot analysis of RNA1 and RNA3 replication following co-transfection of mutant protein A plasmids with the RNA1 fs template. Bottom panels: bar graphs summarizing RNA3 replication relative to wt control across three or more experimental replicates. ( D ) Summary diagram mapping replication values from block, pair, and single alanine substitutions onto the elbow sequence. Color-coded gradients indicate functional impact: white represents mutations that abolish RNA3 replication (0%), and blue represents full replication comparable to wt (100%), allowing visualization of residues and segments critical for RNA replication. ( E ) Structure mapping of elbow (aa 379–395) characteristics. The surface diagrams use the indicated color gradients to show RNA3 replication levels (% of wt) induced by single alanine substitutions [gradient as in panel (D)], electrostatic potential (negative: red, positive: blue), and hydrophobicity (hydrophilic: blue, hydrophobic: yellow) to highlight functional features. Gray shading of the arrows indicates amino acids facing the back, while white shading indicates amino acids facing the front.
    Figure Legend Snippet: Global alanine-scanning mutagenesis of the protein A elbow identifies amino acid contributions to RNA replication. ( A–C ) Alanine substitutions were introduced across the 17-amino acid elbow (aa 379–395) as blocks (5 alanines, A), pairs (2 alanines, B), or single residues (1 alanine, C). Top panels: western blot detecting protein A, with tubulin as a loading control. Middle panels: northern blot analysis of RNA1 and RNA3 replication following co-transfection of mutant protein A plasmids with the RNA1 fs template. Bottom panels: bar graphs summarizing RNA3 replication relative to wt control across three or more experimental replicates. ( D ) Summary diagram mapping replication values from block, pair, and single alanine substitutions onto the elbow sequence. Color-coded gradients indicate functional impact: white represents mutations that abolish RNA3 replication (0%), and blue represents full replication comparable to wt (100%), allowing visualization of residues and segments critical for RNA replication. ( E ) Structure mapping of elbow (aa 379–395) characteristics. The surface diagrams use the indicated color gradients to show RNA3 replication levels (% of wt) induced by single alanine substitutions [gradient as in panel (D)], electrostatic potential (negative: red, positive: blue), and hydrophobicity (hydrophilic: blue, hydrophobic: yellow) to highlight functional features. Gray shading of the arrows indicates amino acids facing the back, while white shading indicates amino acids facing the front.

    Techniques Used: Mutagenesis, Western Blot, Control, Northern Blot, Cotransfection, Blocking Assay, Sequencing, Functional Assay

    Plasmid-based trans -RNA replication assay. ( A ) Schematic of the trans -RNA replication assay in Drosophila S2 cells. Co-transfection of two plasmids separates protein A expression from RNA replication template functions: the left protein A plasmid expresses functional protein A from a nonreplicable mRNA lacking viral 5′ and 3′ replication signals, and the right RNA1 fs plasmid expresses a full-length RNA1 template containing an early frameshift (fs) to prevent translation of protein A. This approach largely stabilizes expression levels of different protein A mutants and allows more direct assessment of their effects on RNA replication, measured by genomic RNA1 and subgenomic RNA3 accumulation. Color coding follows Fig. . ( B ) Northern blot analysis validating the trans -RNA replication assay, with RNA and protein collected ∼65 h post-transfection. The top panel shows a western blot detecting protein A, with tubulin as a loading control. The bottom panel shows the northern blot: Lanes 1 and 2 show no RNA1 or RNA3 signals when either the protein A plasmid or RNA1 fs plasmid is transfected alone. Lane 3 shows strong replication of both genomic RNA1 and RNA3 when wtwt protein A is co-expressed with the RNA1 fs template, confirming robust replication in trans . Lane 4 shows that co-expression of the RNA1 fs template with a protein A deletion mutant lacking the 17–amino acid elbow (Δ379–395) completely abolishes RNA replication, confirming that the elbow region is essential for FHV RNA replication.
    Figure Legend Snippet: Plasmid-based trans -RNA replication assay. ( A ) Schematic of the trans -RNA replication assay in Drosophila S2 cells. Co-transfection of two plasmids separates protein A expression from RNA replication template functions: the left protein A plasmid expresses functional protein A from a nonreplicable mRNA lacking viral 5′ and 3′ replication signals, and the right RNA1 fs plasmid expresses a full-length RNA1 template containing an early frameshift (fs) to prevent translation of protein A. This approach largely stabilizes expression levels of different protein A mutants and allows more direct assessment of their effects on RNA replication, measured by genomic RNA1 and subgenomic RNA3 accumulation. Color coding follows Fig. . ( B ) Northern blot analysis validating the trans -RNA replication assay, with RNA and protein collected ∼65 h post-transfection. The top panel shows a western blot detecting protein A, with tubulin as a loading control. The bottom panel shows the northern blot: Lanes 1 and 2 show no RNA1 or RNA3 signals when either the protein A plasmid or RNA1 fs plasmid is transfected alone. Lane 3 shows strong replication of both genomic RNA1 and RNA3 when wtwt protein A is co-expressed with the RNA1 fs template, confirming robust replication in trans . Lane 4 shows that co-expression of the RNA1 fs template with a protein A deletion mutant lacking the 17–amino acid elbow (Δ379–395) completely abolishes RNA replication, confirming that the elbow region is essential for FHV RNA replication.

    Techniques Used: Plasmid Preparation, Cotransfection, Expressing, Functional Assay, Northern Blot, Transfection, Western Blot, Control, Mutagenesis



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    Global alanine-scanning mutagenesis of the protein A elbow identifies amino acid contributions to RNA replication. ( A–C ) Alanine substitutions were introduced across the 17-amino acid elbow (aa 379–395) as blocks (5 alanines, A), pairs (2 alanines, B), or single residues (1 alanine, C). Top panels: western blot detecting protein A, with tubulin as a loading control. Middle panels: northern blot analysis of RNA1 and RNA3 replication following <t>co-transfection</t> of mutant protein A plasmids with the RNA1 fs template. Bottom panels: bar graphs summarizing RNA3 replication relative to wt control across three or more experimental replicates. ( D ) Summary diagram mapping replication values from block, pair, and single alanine substitutions onto the elbow sequence. Color-coded gradients indicate functional impact: white represents mutations that abolish RNA3 replication (0%), and blue represents full replication comparable to wt (100%), allowing visualization of residues and segments critical for RNA replication. ( E ) Structure mapping of elbow (aa 379–395) characteristics. The surface diagrams use the indicated color gradients to show RNA3 replication levels (% of wt) induced by single alanine substitutions [gradient as in panel (D)], electrostatic potential (negative: red, positive: blue), and hydrophobicity (hydrophilic: blue, hydrophobic: yellow) to highlight functional features. Gray shading of the arrows indicates amino acids facing the back, while white shading indicates amino acids facing the front.
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    Global alanine-scanning mutagenesis of the protein A elbow identifies amino acid contributions to RNA replication. ( A–C ) Alanine substitutions were introduced across the 17-amino acid elbow (aa 379–395) as blocks (5 alanines, A), pairs (2 alanines, B), or single residues (1 alanine, C). Top panels: western blot detecting protein A, with tubulin as a loading control. Middle panels: northern blot analysis of RNA1 and RNA3 replication following <t>co-transfection</t> of mutant protein A plasmids with the RNA1 fs template. Bottom panels: bar graphs summarizing RNA3 replication relative to wt control across three or more experimental replicates. ( D ) Summary diagram mapping replication values from block, pair, and single alanine substitutions onto the elbow sequence. Color-coded gradients indicate functional impact: white represents mutations that abolish RNA3 replication (0%), and blue represents full replication comparable to wt (100%), allowing visualization of residues and segments critical for RNA replication. ( E ) Structure mapping of elbow (aa 379–395) characteristics. The surface diagrams use the indicated color gradients to show RNA3 replication levels (% of wt) induced by single alanine substitutions [gradient as in panel (D)], electrostatic potential (negative: red, positive: blue), and hydrophobicity (hydrophilic: blue, hydrophobic: yellow) to highlight functional features. Gray shading of the arrows indicates amino acids facing the back, while white shading indicates amino acids facing the front.
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    Image Search Results


    Global alanine-scanning mutagenesis of the protein A elbow identifies amino acid contributions to RNA replication. ( A–C ) Alanine substitutions were introduced across the 17-amino acid elbow (aa 379–395) as blocks (5 alanines, A), pairs (2 alanines, B), or single residues (1 alanine, C). Top panels: western blot detecting protein A, with tubulin as a loading control. Middle panels: northern blot analysis of RNA1 and RNA3 replication following co-transfection of mutant protein A plasmids with the RNA1 fs template. Bottom panels: bar graphs summarizing RNA3 replication relative to wt control across three or more experimental replicates. ( D ) Summary diagram mapping replication values from block, pair, and single alanine substitutions onto the elbow sequence. Color-coded gradients indicate functional impact: white represents mutations that abolish RNA3 replication (0%), and blue represents full replication comparable to wt (100%), allowing visualization of residues and segments critical for RNA replication. ( E ) Structure mapping of elbow (aa 379–395) characteristics. The surface diagrams use the indicated color gradients to show RNA3 replication levels (% of wt) induced by single alanine substitutions [gradient as in panel (D)], electrostatic potential (negative: red, positive: blue), and hydrophobicity (hydrophilic: blue, hydrophobic: yellow) to highlight functional features. Gray shading of the arrows indicates amino acids facing the back, while white shading indicates amino acids facing the front.

    Journal: Nucleic Acids Research

    Article Title: Nodavirus protein A’s interdomain elbow controls RNA replication organelle formation and function

    doi: 10.1093/nar/gkag151

    Figure Lengend Snippet: Global alanine-scanning mutagenesis of the protein A elbow identifies amino acid contributions to RNA replication. ( A–C ) Alanine substitutions were introduced across the 17-amino acid elbow (aa 379–395) as blocks (5 alanines, A), pairs (2 alanines, B), or single residues (1 alanine, C). Top panels: western blot detecting protein A, with tubulin as a loading control. Middle panels: northern blot analysis of RNA1 and RNA3 replication following co-transfection of mutant protein A plasmids with the RNA1 fs template. Bottom panels: bar graphs summarizing RNA3 replication relative to wt control across three or more experimental replicates. ( D ) Summary diagram mapping replication values from block, pair, and single alanine substitutions onto the elbow sequence. Color-coded gradients indicate functional impact: white represents mutations that abolish RNA3 replication (0%), and blue represents full replication comparable to wt (100%), allowing visualization of residues and segments critical for RNA replication. ( E ) Structure mapping of elbow (aa 379–395) characteristics. The surface diagrams use the indicated color gradients to show RNA3 replication levels (% of wt) induced by single alanine substitutions [gradient as in panel (D)], electrostatic potential (negative: red, positive: blue), and hydrophobicity (hydrophilic: blue, hydrophobic: yellow) to highlight functional features. Gray shading of the arrows indicates amino acids facing the back, while white shading indicates amino acids facing the front.

    Article Snippet: Transfection mixtures were prepared by complexing 1.5 μg of total plasmid DNA (1 μg of RNA1 template plasmid and 0.5 μg of protein A expression plasmid[s]), 6 μl of Trans IT-Insect Transfection Reagent (Mirus Bio), and 100 μl of Opti-MEM (Gibco/ThermoFisher).

    Techniques: Mutagenesis, Western Blot, Control, Northern Blot, Cotransfection, Blocking Assay, Sequencing, Functional Assay

    Plasmid-based trans -RNA replication assay. ( A ) Schematic of the trans -RNA replication assay in Drosophila S2 cells. Co-transfection of two plasmids separates protein A expression from RNA replication template functions: the left protein A plasmid expresses functional protein A from a nonreplicable mRNA lacking viral 5′ and 3′ replication signals, and the right RNA1 fs plasmid expresses a full-length RNA1 template containing an early frameshift (fs) to prevent translation of protein A. This approach largely stabilizes expression levels of different protein A mutants and allows more direct assessment of their effects on RNA replication, measured by genomic RNA1 and subgenomic RNA3 accumulation. Color coding follows Fig. . ( B ) Northern blot analysis validating the trans -RNA replication assay, with RNA and protein collected ∼65 h post-transfection. The top panel shows a western blot detecting protein A, with tubulin as a loading control. The bottom panel shows the northern blot: Lanes 1 and 2 show no RNA1 or RNA3 signals when either the protein A plasmid or RNA1 fs plasmid is transfected alone. Lane 3 shows strong replication of both genomic RNA1 and RNA3 when wtwt protein A is co-expressed with the RNA1 fs template, confirming robust replication in trans . Lane 4 shows that co-expression of the RNA1 fs template with a protein A deletion mutant lacking the 17–amino acid elbow (Δ379–395) completely abolishes RNA replication, confirming that the elbow region is essential for FHV RNA replication.

    Journal: Nucleic Acids Research

    Article Title: Nodavirus protein A’s interdomain elbow controls RNA replication organelle formation and function

    doi: 10.1093/nar/gkag151

    Figure Lengend Snippet: Plasmid-based trans -RNA replication assay. ( A ) Schematic of the trans -RNA replication assay in Drosophila S2 cells. Co-transfection of two plasmids separates protein A expression from RNA replication template functions: the left protein A plasmid expresses functional protein A from a nonreplicable mRNA lacking viral 5′ and 3′ replication signals, and the right RNA1 fs plasmid expresses a full-length RNA1 template containing an early frameshift (fs) to prevent translation of protein A. This approach largely stabilizes expression levels of different protein A mutants and allows more direct assessment of their effects on RNA replication, measured by genomic RNA1 and subgenomic RNA3 accumulation. Color coding follows Fig. . ( B ) Northern blot analysis validating the trans -RNA replication assay, with RNA and protein collected ∼65 h post-transfection. The top panel shows a western blot detecting protein A, with tubulin as a loading control. The bottom panel shows the northern blot: Lanes 1 and 2 show no RNA1 or RNA3 signals when either the protein A plasmid or RNA1 fs plasmid is transfected alone. Lane 3 shows strong replication of both genomic RNA1 and RNA3 when wtwt protein A is co-expressed with the RNA1 fs template, confirming robust replication in trans . Lane 4 shows that co-expression of the RNA1 fs template with a protein A deletion mutant lacking the 17–amino acid elbow (Δ379–395) completely abolishes RNA replication, confirming that the elbow region is essential for FHV RNA replication.

    Article Snippet: Transfection mixtures were prepared by complexing 1.5 μg of total plasmid DNA (1 μg of RNA1 template plasmid and 0.5 μg of protein A expression plasmid[s]), 6 μl of Trans IT-Insect Transfection Reagent (Mirus Bio), and 100 μl of Opti-MEM (Gibco/ThermoFisher).

    Techniques: Plasmid Preparation, Cotransfection, Expressing, Functional Assay, Northern Blot, Transfection, Western Blot, Control, Mutagenesis