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$Characterization of the DNE exerted on WT <t>p53</t> by the R248Q variant. A, Experimental schematic for the CRISPR/Ca9-mediated generation of human isogenic MOLM13- TP53 AML cell lines and their subsequent phenotypic and functional characterization. CRISPR-HDR, CRISPR-Cas9–mediated homology-directed repair; CRISPR-KO, CRISPR-Cas9–mediated gene knockout. B, Whole-cell lysates of isogenic MOLM13- TP53 AML cell lines of the indicated genotypes treated for 3 hours with either DMSO or 100 nmol/L Dauno were separated on a polyacrylamide gel and immunoblotted for p53, p21, and vinculin (representative blot of n = 3 independent experiments). C, Cell-cycle distribution of isogenic MOLM13- TP53 isogenic AML cell lines of the indicated genotypes treated for 6 hours with either DMSO or 100 nmol/L Dauno as determined by CytoPhase Violet staining ( n = 3 independent experiments). Bar graphs represent averages. Error bars, SEM. **, P ≤ 0.01; ****, P ≤ 0.0001, one-way ANOVA, Tukey multiple comparison. D, Fraction of apoptotic MOLM13- TP53 isogenic AML cell lines as determined by Annexin V staining after treatment with either DMSO or 100 nmol/L Dauno for 72 hours ( n = 3 independent experiments). Bar graphs represent averages. Error bars, SEM. *, P ≤ 0.05; ****, P ≤ 0.0001, two-way ANOVA, Tukey multiple comparison. E, Cell viability of MOLM13- TP53 isogenic AML cell lines was determined using the CellTiter-Glo reagent after being exposed to increasing concentrations of the indicated drugs for 72 hours ( n = 3 independent experiments). Symbols represent averages. Error bars, SD, Friedman test. F, Schematic depicting the experiment principle of the in vitro competition assay. Fluorescently labeled MOLM13- TP53 isogenic AML cell lines of various TP53 genotypes were cocultured at a 1:9 ratio in the presence of DMSO or 1 μmol/L nutlin-3a, and the relative fractions of each genotype were determined by flow cytometry every other day for 10 days. G, Heatmaps depict the results of the in vitro competition assays described in F . n = 3 independent experiments; color-coded averages are shown. d, day. H, Representative images of a colony-forming unit assay. MOLM13- TP53 isogenic AML cell lines of the indicated genotypes were cultured for 7 days in methylcellulose-based medium with DMSO or 2.5 μmol/L nutlin-3a. Images were taken using a Leica DMI6000B inverted microscope, and analysis was performed using the Colony Area ImageJ plugin, followed by manual counting of the colonies (representative images of n = 3 independent experiments). I, Counted colonies from colony-forming unit assay as described in H . n = 3 independent experiments. Bar graphs represent averages. Error bars, SEM. ****, P ≤ 0.0001, one-way ANOVA, Tukey multiple comparison. J, Quantification of the bioluminescent signal (i.e., total flux per second) for each group of mice 12 and 16 days after sublethal irradiation and subsequent injection with MOLM13- TP53 -GFP-luciferase isogenic AML cell lines (of the indicated genotypes). One week after injection, mice were treated with idasanutlin (Ida, 25 mg/kg of BW per day) or vehicle (Veh) for seven consecutive days. n = 7 animals per group. Symbols represent averages. Error bars, SD; ***, P ≤ 0.001, Mann–Whitney test. K, Survival analysis of NSG mice engrafted with MOLM13- TP53 -GFP-luciferase isogenic AML cell lines of the indicated genotypes and treated with idasanutlin (25 mg/kg of BW per day) or vehicle for seven consecutive days. n = 7 animals per group. ****, P ≤ 0.0001, Kaplan–Meier simple survival analysis. ns, nonsignificant.$
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1) Product Images from "The Prolonged Half-Life of the p53 Missense Variant R248Q Promotes Accumulation and Heterotetramer Formation with Wild-Type p53 to Exert the Dominant-Negative Effect"

Article Title: The Prolonged Half-Life of the p53 Missense Variant R248Q Promotes Accumulation and Heterotetramer Formation with Wild-Type p53 to Exert the Dominant-Negative Effect

Journal: Cancer Research

doi: 10.1158/0008-5472.CAN-24-1136

$Characterization of the DNE exerted on WT p53 by the R248Q variant. A, Experimental schematic for the CRISPR/Ca9-mediated generation of human isogenic MOLM13- TP53 AML cell lines and their subsequent phenotypic and functional characterization. CRISPR-HDR, CRISPR-Cas9–mediated homology-directed repair; CRISPR-KO, CRISPR-Cas9–mediated gene knockout. B, Whole-cell lysates of isogenic MOLM13- TP53 AML cell lines of the indicated genotypes treated for 3 hours with either DMSO or 100 nmol/L Dauno were separated on a polyacrylamide gel and immunoblotted for p53, p21, and vinculin (representative blot of n = 3 independent experiments). C, Cell-cycle distribution of isogenic MOLM13- TP53 isogenic AML cell lines of the indicated genotypes treated for 6 hours with either DMSO or 100 nmol/L Dauno as determined by CytoPhase Violet staining ( n = 3 independent experiments). Bar graphs represent averages. Error bars, SEM. **, P ≤ 0.01; ****, P ≤ 0.0001, one-way ANOVA, Tukey multiple comparison. D, Fraction of apoptotic MOLM13- TP53 isogenic AML cell lines as determined by Annexin V staining after treatment with either DMSO or 100 nmol/L Dauno for 72 hours ( n = 3 independent experiments). Bar graphs represent averages. Error bars, SEM. *, P ≤ 0.05; ****, P ≤ 0.0001, two-way ANOVA, Tukey multiple comparison. E, Cell viability of MOLM13- TP53 isogenic AML cell lines was determined using the CellTiter-Glo reagent after being exposed to increasing concentrations of the indicated drugs for 72 hours ( n = 3 independent experiments). Symbols represent averages. Error bars, SD, Friedman test. F, Schematic depicting the experiment principle of the in vitro competition assay. Fluorescently labeled MOLM13- TP53 isogenic AML cell lines of various TP53 genotypes were cocultured at a 1:9 ratio in the presence of DMSO or 1 μmol/L nutlin-3a, and the relative fractions of each genotype were determined by flow cytometry every other day for 10 days. G, Heatmaps depict the results of the in vitro competition assays described in F . n = 3 independent experiments; color-coded averages are shown. d, day. H, Representative images of a colony-forming unit assay. MOLM13- TP53 isogenic AML cell lines of the indicated genotypes were cultured for 7 days in methylcellulose-based medium with DMSO or 2.5 μmol/L nutlin-3a. Images were taken using a Leica DMI6000B inverted microscope, and analysis was performed using the Colony Area ImageJ plugin, followed by manual counting of the colonies (representative images of n = 3 independent experiments). I, Counted colonies from colony-forming unit assay as described in H . n = 3 independent experiments. Bar graphs represent averages. Error bars, SEM. ****, P ≤ 0.0001, one-way ANOVA, Tukey multiple comparison. J, Quantification of the bioluminescent signal (i.e., total flux per second) for each group of mice 12 and 16 days after sublethal irradiation and subsequent injection with MOLM13- TP53 -GFP-luciferase isogenic AML cell lines (of the indicated genotypes). One week after injection, mice were treated with idasanutlin (Ida, 25 mg/kg of BW per day) or vehicle (Veh) for seven consecutive days. n = 7 animals per group. Symbols represent averages. Error bars, SD; ***, P ≤ 0.001, Mann–Whitney test. K, Survival analysis of NSG mice engrafted with MOLM13- TP53 -GFP-luciferase isogenic AML cell lines of the indicated genotypes and treated with idasanutlin (25 mg/kg of BW per day) or vehicle for seven consecutive days. n = 7 animals per group. ****, P ≤ 0.0001, Kaplan–Meier simple survival analysis. ns, nonsignificant.$
Figure Legend Snippet: Characterization of the DNE exerted on WT p53 by the R248Q variant. A, Experimental schematic for the CRISPR/Ca9-mediated generation of human isogenic MOLM13- TP53 AML cell lines and their subsequent phenotypic and functional characterization. CRISPR-HDR, CRISPR-Cas9–mediated homology-directed repair; CRISPR-KO, CRISPR-Cas9–mediated gene knockout. B, Whole-cell lysates of isogenic MOLM13- TP53 AML cell lines of the indicated genotypes treated for 3 hours with either DMSO or 100 nmol/L Dauno were separated on a polyacrylamide gel and immunoblotted for p53, p21, and vinculin (representative blot of n = 3 independent experiments). C, Cell-cycle distribution of isogenic MOLM13- TP53 isogenic AML cell lines of the indicated genotypes treated for 6 hours with either DMSO or 100 nmol/L Dauno as determined by CytoPhase Violet staining ( n = 3 independent experiments). Bar graphs represent averages. Error bars, SEM. **, P ≤ 0.01; ****, P ≤ 0.0001, one-way ANOVA, Tukey multiple comparison. D, Fraction of apoptotic MOLM13- TP53 isogenic AML cell lines as determined by Annexin V staining after treatment with either DMSO or 100 nmol/L Dauno for 72 hours ( n = 3 independent experiments). Bar graphs represent averages. Error bars, SEM. *, P ≤ 0.05; ****, P ≤ 0.0001, two-way ANOVA, Tukey multiple comparison. E, Cell viability of MOLM13- TP53 isogenic AML cell lines was determined using the CellTiter-Glo reagent after being exposed to increasing concentrations of the indicated drugs for 72 hours ( n = 3 independent experiments). Symbols represent averages. Error bars, SD, Friedman test. F, Schematic depicting the experiment principle of the in vitro competition assay. Fluorescently labeled MOLM13- TP53 isogenic AML cell lines of various TP53 genotypes were cocultured at a 1:9 ratio in the presence of DMSO or 1 μmol/L nutlin-3a, and the relative fractions of each genotype were determined by flow cytometry every other day for 10 days. G, Heatmaps depict the results of the in vitro competition assays described in F . n = 3 independent experiments; color-coded averages are shown. d, day. H, Representative images of a colony-forming unit assay. MOLM13- TP53 isogenic AML cell lines of the indicated genotypes were cultured for 7 days in methylcellulose-based medium with DMSO or 2.5 μmol/L nutlin-3a. Images were taken using a Leica DMI6000B inverted microscope, and analysis was performed using the Colony Area ImageJ plugin, followed by manual counting of the colonies (representative images of n = 3 independent experiments). I, Counted colonies from colony-forming unit assay as described in H . n = 3 independent experiments. Bar graphs represent averages. Error bars, SEM. ****, P ≤ 0.0001, one-way ANOVA, Tukey multiple comparison. J, Quantification of the bioluminescent signal (i.e., total flux per second) for each group of mice 12 and 16 days after sublethal irradiation and subsequent injection with MOLM13- TP53 -GFP-luciferase isogenic AML cell lines (of the indicated genotypes). One week after injection, mice were treated with idasanutlin (Ida, 25 mg/kg of BW per day) or vehicle (Veh) for seven consecutive days. n = 7 animals per group. Symbols represent averages. Error bars, SD; ***, P ≤ 0.001, Mann–Whitney test. K, Survival analysis of NSG mice engrafted with MOLM13- TP53 -GFP-luciferase isogenic AML cell lines of the indicated genotypes and treated with idasanutlin (25 mg/kg of BW per day) or vehicle for seven consecutive days. n = 7 animals per group. ****, P ≤ 0.0001, Kaplan–Meier simple survival analysis. ns, nonsignificant.

Techniques Used: Variant Assay, CRISPR, Functional Assay, Gene Knockout, Staining, Comparison, In Vitro, Competitive Binding Assay, Labeling, Flow Cytometry, Colony-forming Unit Assay, Cell Culture, Inverted Microscopy, Irradiation, Injection, Luciferase, MANN-WHITNEY

R248Q impairs the ability of WT p53 to bind to promoter DNA and to transactivate expression of target genes. A, Immunofluorescence microscopy images showing p53 (magenta), DAPI (blue), and CellBrite Fix 640 membrane stain (green) in MOLM13- TP53 isogenic AML cell lines treated for 3 hours with 100 nM Dauno ( n = 3 independent experiments; one representative example is shown; confocal microscope Leica DMI6000B, 63× objective). Scale bar, 2.5 μm. B, ChIP followed by NGS in isogenic MOLM- TP53 AML cell lines of the indicated genotypes after treatment with DMSO or 100 nmol/L Dauno for 6 hours. Plots show genome-wide relative enrichment of p53 variants (WT or R248Q) over p53 null cells over TSS-proximal regions (−10 kb to first intron). C, Tornado plots of WT and R248Q ChIP-seq peaks over TSS-proximal regions (−10kb, first intron with a horizontal window of 1 kb around the peak center) in isogenic MOLM- TP53 AML cell lines of the indicated genotypes. Cells were treated as described in B . Plots show relative enrichment and mutual overlap of the peaks identified in each cell line. D, Representative Integrative Genome Viewer images depicting the ChIP-seq peaks for p53 over the TSS of CDKN1A or MDM2 in isogenic MOLM- TP53 AML cell lines of the indicated genotypes after treatment as described in B . E, Relative expression of CDKN1A and MDM2 transcripts normalized to ACTB in isogenic MOLM- TP53 AML cell lines of the indicated genotypes after treatment with DMSO or 100 nmol/L Dauno for 6 hours ( n = 3 independent experiments). Bar graphs represent averages. Error bars, SD. ns, nonsignificant; ****, P ≤ 0.0001, one-way ANOVA, Tukey multiple comparison.

Figure Legend Snippet: R248Q impairs the ability of WT p53 to bind to promoter DNA and to transactivate expression of target genes. A, Immunofluorescence microscopy images showing p53 (magenta), DAPI (blue), and CellBrite Fix 640 membrane stain (green) in MOLM13- TP53 isogenic AML cell lines treated for 3 hours with 100 nM Dauno ( n = 3 independent experiments; one representative example is shown; confocal microscope Leica DMI6000B, 63× objective). Scale bar, 2.5 μm. B, ChIP followed by NGS in isogenic MOLM- TP53 AML cell lines of the indicated genotypes after treatment with DMSO or 100 nmol/L Dauno for 6 hours. Plots show genome-wide relative enrichment of p53 variants (WT or R248Q) over p53 null cells over TSS-proximal regions (−10 kb to first intron). C, Tornado plots of WT and R248Q ChIP-seq peaks over TSS-proximal regions (−10kb, first intron with a horizontal window of 1 kb around the peak center) in isogenic MOLM- TP53 AML cell lines of the indicated genotypes. Cells were treated as described in B . Plots show relative enrichment and mutual overlap of the peaks identified in each cell line. D, Representative Integrative Genome Viewer images depicting the ChIP-seq peaks for p53 over the TSS of CDKN1A or MDM2 in isogenic MOLM- TP53 AML cell lines of the indicated genotypes after treatment as described in B . E, Relative expression of CDKN1A and MDM2 transcripts normalized to ACTB in isogenic MOLM- TP53 AML cell lines of the indicated genotypes after treatment with DMSO or 100 nmol/L Dauno for 6 hours ( n = 3 independent experiments). Bar graphs represent averages. Error bars, SD. ns, nonsignificant; ****, P ≤ 0.0001, one-way ANOVA, Tukey multiple comparison.

Techniques Used: Expressing, Immunofluorescence, Microscopy, Membrane, Staining, Genome Wide, ChIP-sequencing, Comparison

Heterotetramers consisting of R248Q and WT p53 are transcriptionally inactive, but overexpression of WT p53 can overcome the DNE of R248Q. A, MOLM13- TP53 isogenic cell lines were treated with DMSO or 100 nmol/L Dauno for 3 hours, followed by collection of whole-cell protein lysates by using IGEPAL lysis buffer. Lysates were fixed with 0.03% glutaraldehyde and subsequently separated on a polyacrylamide gel under nonreducing conditions. The PVDF membrane was immunoblotted for p53 ( n = 3 independent experiments; one representative blot is shown). B, MOLM13- TP53 null or K562- TP53 null AML cell lines lentivirally transduced to stably express full-length R248Q, tetramerization-deficient R248Q (R248Q-L344A), or dimerization-deficient R248Q (R248Q-L344P or R248Q-OD lacking the OD of p53) were treated for 3 hours with either DMSO or 100 nmol/L Dauno. Glutaraldehyde-fixed whole-cell protein lysates were separated on a polyacrylamide gel and immunoblotted for p53 ( n = 3 independent experiments; representative blots are shown). C, Experimental schematic depicting the general principle of the flow cytometry–based FRET assay in K562- TP53 null AML cells. For experimental details, please refer to the Materials and Methods. D, Representative FACS plots showing results of the FRET assay in K562- TP53 null AML cells for the interaction between WT monomers (top), or WT and R248Q monomers (bottom). FRET donor and acceptor plasmids encoding p53 WT or R248Q variants either oligomerization-proficient (WT) or -deficient (WT-L344A, WT-L344P, or WT-OD) were co-electroporated into K562- TP53 null AML cells, followed by FRET measurement (FRET fluorescence measured using the 525/50-nm detector). E, Pooled results of the FRET assays in K562- TP53 null AML cells ( n = 3 independent experiments). Bar graphs represent averages. Error bars, SD. ***, P ≤ 0.001; ****, P ≤ 0.0001, one-way ANOVA, Tukey multiple comparison. F, Experimental schematic and pooled results of the transcriptional reporter assay in K562- TP53 null -p21-GFP cells electroporated with plasmids encoding oligomerization-proficient or -deficient WT p53 variants ( n = 3 independent experiments). Bar graphs represent averages. Error bars, SEM. *, P ≤ 0.05; **, P ≤ 0.01; ****, P ≤ 0.0001, one-way ANOVA, Tukey multiple comparison. G, Experimental schematic and pooled results of the transcriptional reporter assay in K562- TP53 WT -p21-GFP cells electroporated with pRK5 plasmids encoding oligomerization-proficient or -deficient R248Q p53 variants ( n = 3 independent experiments). Bar graphs represent averages. Error bars, SEM. **, P ≤ 0.01; ****, P ≤ 0.0001, one-way ANOVA, Tukey multiple comparison. H, Quantification of the bioluminescent signal (i.e., total flux per second) for each group of mice 12 and 16 days after sublethal irradiation and subsequent injection with MOLM13- TP53 +/− -GFP-luciferase AML cell lines overexpressing either R248Q (WT + R248Q) or oligomerization-deficient R248Q-L344P (WT + R248Q-L344P). Following, mice were treated with idasanutlin (Ida, 25 mg/kg of BW per day) or vehicle (Veh) for seven consecutive days ( n = 7 animals per group). Symbols represent averages. Error bars, SD. ***, P ≤ 0.001, Mann–Whitney test. I, Survival analysis of NSG mice engrafted with MOLM13- TP53 +/− -GFP-luciferase AML cell lines overexpressing either R248Q (WT + R248Q) or R248Q-L344P (WT + R248Q-L344P) and treated with idasanutlin (25 mg/kg of BW per day) or vehicle for seven consecutive days ( n = 7 animals per group). ****, P ≤ 0.0001, Kaplan–Meier simple survival analysis. J, Experimental schematic and pooled results of the transcriptional reporter assay in K562- TP53 R248Q -p21-GFP cells electroporated with the pRK5 plasmid encoding oligomerization-proficient WT p53 variant ( n = 3 independent experiments). Bar graphs represent averages. Error bars, SEM. ****, P ≤ 0.0001, Welch t test. CNTR, control; FRET-Acc, FRET acceptor; FRET-Don, FRET donor. ns, nonsignificant.

Figure Legend Snippet: Heterotetramers consisting of R248Q and WT p53 are transcriptionally inactive, but overexpression of WT p53 can overcome the DNE of R248Q. A, MOLM13- TP53 isogenic cell lines were treated with DMSO or 100 nmol/L Dauno for 3 hours, followed by collection of whole-cell protein lysates by using IGEPAL lysis buffer. Lysates were fixed with 0.03% glutaraldehyde and subsequently separated on a polyacrylamide gel under nonreducing conditions. The PVDF membrane was immunoblotted for p53 ( n = 3 independent experiments; one representative blot is shown). B, MOLM13- TP53 null or K562- TP53 null AML cell lines lentivirally transduced to stably express full-length R248Q, tetramerization-deficient R248Q (R248Q-L344A), or dimerization-deficient R248Q (R248Q-L344P or R248Q-OD lacking the OD of p53) were treated for 3 hours with either DMSO or 100 nmol/L Dauno. Glutaraldehyde-fixed whole-cell protein lysates were separated on a polyacrylamide gel and immunoblotted for p53 ( n = 3 independent experiments; representative blots are shown). C, Experimental schematic depicting the general principle of the flow cytometry–based FRET assay in K562- TP53 null AML cells. For experimental details, please refer to the Materials and Methods. D, Representative FACS plots showing results of the FRET assay in K562- TP53 null AML cells for the interaction between WT monomers (top), or WT and R248Q monomers (bottom). FRET donor and acceptor plasmids encoding p53 WT or R248Q variants either oligomerization-proficient (WT) or -deficient (WT-L344A, WT-L344P, or WT-OD) were co-electroporated into K562- TP53 null AML cells, followed by FRET measurement (FRET fluorescence measured using the 525/50-nm detector). E, Pooled results of the FRET assays in K562- TP53 null AML cells ( n = 3 independent experiments). Bar graphs represent averages. Error bars, SD. ***, P ≤ 0.001; ****, P ≤ 0.0001, one-way ANOVA, Tukey multiple comparison. F, Experimental schematic and pooled results of the transcriptional reporter assay in K562- TP53 null -p21-GFP cells electroporated with plasmids encoding oligomerization-proficient or -deficient WT p53 variants ( n = 3 independent experiments). Bar graphs represent averages. Error bars, SEM. *, P ≤ 0.05; **, P ≤ 0.01; ****, P ≤ 0.0001, one-way ANOVA, Tukey multiple comparison. G, Experimental schematic and pooled results of the transcriptional reporter assay in K562- TP53 WT -p21-GFP cells electroporated with pRK5 plasmids encoding oligomerization-proficient or -deficient R248Q p53 variants ( n = 3 independent experiments). Bar graphs represent averages. Error bars, SEM. **, P ≤ 0.01; ****, P ≤ 0.0001, one-way ANOVA, Tukey multiple comparison. H, Quantification of the bioluminescent signal (i.e., total flux per second) for each group of mice 12 and 16 days after sublethal irradiation and subsequent injection with MOLM13- TP53 +/− -GFP-luciferase AML cell lines overexpressing either R248Q (WT + R248Q) or oligomerization-deficient R248Q-L344P (WT + R248Q-L344P). Following, mice were treated with idasanutlin (Ida, 25 mg/kg of BW per day) or vehicle (Veh) for seven consecutive days ( n = 7 animals per group). Symbols represent averages. Error bars, SD. ***, P ≤ 0.001, Mann–Whitney test. I, Survival analysis of NSG mice engrafted with MOLM13- TP53 +/− -GFP-luciferase AML cell lines overexpressing either R248Q (WT + R248Q) or R248Q-L344P (WT + R248Q-L344P) and treated with idasanutlin (25 mg/kg of BW per day) or vehicle for seven consecutive days ( n = 7 animals per group). ****, P ≤ 0.0001, Kaplan–Meier simple survival analysis. J, Experimental schematic and pooled results of the transcriptional reporter assay in K562- TP53 R248Q -p21-GFP cells electroporated with the pRK5 plasmid encoding oligomerization-proficient WT p53 variant ( n = 3 independent experiments). Bar graphs represent averages. Error bars, SEM. ****, P ≤ 0.0001, Welch t test. CNTR, control; FRET-Acc, FRET acceptor; FRET-Don, FRET donor. ns, nonsignificant.

Techniques Used: Over Expression, Lysis, Membrane, Stable Transfection, Flow Cytometry, Fluorescence, Comparison, Reporter Assay, Irradiation, Injection, Luciferase, MANN-WHITNEY, Plasmid Preparation, Variant Assay, Control

The longer protein half-life of R248Q leads to an increase of the R248Q:WT ratio. A, Bone marrow biopsies of patients with TP53 WT or TP53 R248Q -mutant AML, high-grade B-cell lymphoma (HGBCL), or early T precursor lymphoblastic leukemia (ETP-ALL) stained with hematoxylin and eosin (H&E) and p53 IHC ( n = 6 representative images; ×100 magnification) show strong nuclear p53 staining in neoplastic cells of TP53 R248Q mutated cases. B, Experimental schematic for the CRISPR/Ca9-mediated generation of human isogenic cancer cell lines with TP53 WT or R248Q alleles and their subsequent use for p53 quantification and half-life determination as shown in C and E . CRC, colorectal cancer; CRISPR-HDR, CRISPR-Cas9–mediated homology-directed repair; NSCLC, non–small cell lung cancer. C, Whole-cell lysates of isogenic MOLM13- TP53 , K562- TP5 3, A549- TP53 , and HCT116- TP53 isogenic cell lines with WT and R248Q alleles treated for 6 hours with either DMSO or 100 nM Dauno were separated on a polyacrylamide gel and immunoblotted for p53 and vinculin. P53 was quantified via ImageJ software using vinculin to normalize p53 levels ( n = 3–4 independent experiments; representative blots are shown). Bar graphs represent averages. Error bars, SEM. *, P ≤ 0.05; **, P ≤ 0.01; ***, P ≤ 0.001, two-way ANOVA, Tukey multiple comparison. D, NGS of cDNA from isogenic MOLM13- TP53 AML cell lines of the indicated genotypes. Number of NGS reads supporting the WT (gray) or R248Q (blue) allele are shown ( n = 3 independent experiments). Bar graphs represent averages. Error bars, SD. Two-way ANOVA, Tukey multiple comparison. ns, nonsignificant; n.d., not detectable. E, Half-life determination of p53 WT and R248Q in untreated isogenic MOLM13- TP53 , K562- TP53 , A549- TP53 , and HCT116- TP53 isogenic cell lines. Whole-cell lysates of cycloheximide-treated cells were collected at the indicated time points and separated on a polyacrylamide gel and immunoblotted for p53 and vinculin. p53 was quantified using ImageJ software ( n = 3–4 independent experiments; representative blots are shown). Error bars, SEM. ****, P ≤ 0.0001, Mann–Whitney test.

Figure Legend Snippet: The longer protein half-life of R248Q leads to an increase of the R248Q:WT ratio. A, Bone marrow biopsies of patients with TP53 WT or TP53 R248Q -mutant AML, high-grade B-cell lymphoma (HGBCL), or early T precursor lymphoblastic leukemia (ETP-ALL) stained with hematoxylin and eosin (H&E) and p53 IHC ( n = 6 representative images; ×100 magnification) show strong nuclear p53 staining in neoplastic cells of TP53 R248Q mutated cases. B, Experimental schematic for the CRISPR/Ca9-mediated generation of human isogenic cancer cell lines with TP53 WT or R248Q alleles and their subsequent use for p53 quantification and half-life determination as shown in C and E . CRC, colorectal cancer; CRISPR-HDR, CRISPR-Cas9–mediated homology-directed repair; NSCLC, non–small cell lung cancer. C, Whole-cell lysates of isogenic MOLM13- TP53 , K562- TP5 3, A549- TP53 , and HCT116- TP53 isogenic cell lines with WT and R248Q alleles treated for 6 hours with either DMSO or 100 nM Dauno were separated on a polyacrylamide gel and immunoblotted for p53 and vinculin. P53 was quantified via ImageJ software using vinculin to normalize p53 levels ( n = 3–4 independent experiments; representative blots are shown). Bar graphs represent averages. Error bars, SEM. *, P ≤ 0.05; **, P ≤ 0.01; ***, P ≤ 0.001, two-way ANOVA, Tukey multiple comparison. D, NGS of cDNA from isogenic MOLM13- TP53 AML cell lines of the indicated genotypes. Number of NGS reads supporting the WT (gray) or R248Q (blue) allele are shown ( n = 3 independent experiments). Bar graphs represent averages. Error bars, SD. Two-way ANOVA, Tukey multiple comparison. ns, nonsignificant; n.d., not detectable. E, Half-life determination of p53 WT and R248Q in untreated isogenic MOLM13- TP53 , K562- TP53 , A549- TP53 , and HCT116- TP53 isogenic cell lines. Whole-cell lysates of cycloheximide-treated cells were collected at the indicated time points and separated on a polyacrylamide gel and immunoblotted for p53 and vinculin. p53 was quantified using ImageJ software ( n = 3–4 independent experiments; representative blots are shown). Error bars, SEM. ****, P ≤ 0.0001, Mann–Whitney test.

Techniques Used: Mutagenesis, Staining, CRISPR, Software, Comparison, MANN-WHITNEY

$A supraphysiologic protein abundance of R248Q is required for the DNE. A, Experimental schematic showing the principle of the p53 target degradation assay. B, Whole-cell lysates of iberdomide- and/or nutlin-3a–treated K562 cells with TP53 WT and degR248Q or K562 cells with TP53 WT and degGFP were separated on a polyacrylamide gel and immunoblotted for p53, p21, and vinculin ( n = 3 independent experiments; one representative blot is shown). C, Correlation between the WT p53 transcriptional activity as determined by the normalized p21/vinculin and the R248Q/WT ratio in K562 cells with TP53 WT and degR248Q. Cells were treated with 2.5 μmol/L nutlin-3a and increasing concentrations of iberdomide, whole-cell lysates were prepared, run on a polyacrylamide gel, immunoblotted for p53, p21, and vinculin, and bands were quantified using ImageJ software ( n = 3 independent experiments, pooled data, including averages and SEM are shown). D, Cell-cycle distribution of MOLM13 cells with WT TP53 and degR248Q or MOLM13 cells with WT TP53 and degGFP cells in the absence or presence of 1 μmol/L iberdomide and/or 2.5 μmol/L nutlin-3a for 24 hours as determined by CytoPhase Violet staining ( n = 3 independent experiments). Bar graphs represent averages. Error bars, SEM. ****, P ≤ 0.0001, one-way ANOVA, Tukey multiple comparison. E, Fraction of apoptotic MOLM13 cells with WT TP53 and degR248Q or degGFP as determined by Annexin V staining in the absence or presence of 1 μmol/L iberdomide and/or 2.5 μmol/L nutlin-3a for 24 to 72 hours ( n = 3 independent experiments). Bar graphs represent averages. Error bars, SEM. **, P ≤ 0.01; ***, P ≤ 0.001; ****, P ≤ 0.0001, two-way ANOVA, Tukey multiple comparison. F, Representative images of a colony-forming unit assay was performed in MOLM13 cells with WT TP53 and degR248Q or degGFP in methylcellulose-based medium containing DMSO, 5 μmol/L iberdomide, and/or 2.5 μmol/L nutlin-3a. After 7 days, images were taken using a Leica DMI6000 B inverted microscope, and analysis was performed using the Colony Area ImageJ plugin, followed by manual counting of the colonies (representative images of n = 3 independent experiments). G, Summary of counted colonies from the colony-forming unit assay as described in F ( n = 3 independent experiments). Bar graphs represent averages. Error bars, SEM. ****, P ≤ 0.0001, one-way ANOVA, Tukey multiple comparison. H, Results of in vitro competition assays of K562 cells with WT TP53 and degR248Q cocultured together with isogenic K562- TP53 WT cells (left) or K562- TP53 R248Q cells (right) in the absence or presence of 2.5 μmol/L nutlin-3a and/or 1 μmol/L iberdomide. The relative fractions of each genotype were determined by flow cytometry every other day for 8 days ( n = 3 independent experiments). Averages are shown. Error bars, SD. ****, P ≤ 0.0001, unpaired t test. I, The results of in vitro competition assays of MOLM13 cells with WT TP53 and degR248Q cocultured together with isogenic MOLM13 cells with WT TP53 (left) or MOLM13 cells with R248Q (right) in the absence or presence of 2.5 μmol/L nutlin-3a and/or 1 μmol/L iberdomide. The relative fractions of each genotype were determined by flow cytometry every other day for 8 days ( n = 3 independent experiments). Symbols indicate averages. Error bars, SD. ****, P ≤ 0.0001, unpaired t test; ns, nonsignificant.$
Figure Legend Snippet: A supraphysiologic protein abundance of R248Q is required for the DNE. A, Experimental schematic showing the principle of the p53 target degradation assay. B, Whole-cell lysates of iberdomide- and/or nutlin-3a–treated K562 cells with TP53 WT and degR248Q or K562 cells with TP53 WT and degGFP were separated on a polyacrylamide gel and immunoblotted for p53, p21, and vinculin ( n = 3 independent experiments; one representative blot is shown). C, Correlation between the WT p53 transcriptional activity as determined by the normalized p21/vinculin and the R248Q/WT ratio in K562 cells with TP53 WT and degR248Q. Cells were treated with 2.5 μmol/L nutlin-3a and increasing concentrations of iberdomide, whole-cell lysates were prepared, run on a polyacrylamide gel, immunoblotted for p53, p21, and vinculin, and bands were quantified using ImageJ software ( n = 3 independent experiments, pooled data, including averages and SEM are shown). D, Cell-cycle distribution of MOLM13 cells with WT TP53 and degR248Q or MOLM13 cells with WT TP53 and degGFP cells in the absence or presence of 1 μmol/L iberdomide and/or 2.5 μmol/L nutlin-3a for 24 hours as determined by CytoPhase Violet staining ( n = 3 independent experiments). Bar graphs represent averages. Error bars, SEM. ****, P ≤ 0.0001, one-way ANOVA, Tukey multiple comparison. E, Fraction of apoptotic MOLM13 cells with WT TP53 and degR248Q or degGFP as determined by Annexin V staining in the absence or presence of 1 μmol/L iberdomide and/or 2.5 μmol/L nutlin-3a for 24 to 72 hours ( n = 3 independent experiments). Bar graphs represent averages. Error bars, SEM. **, P ≤ 0.01; ***, P ≤ 0.001; ****, P ≤ 0.0001, two-way ANOVA, Tukey multiple comparison. F, Representative images of a colony-forming unit assay was performed in MOLM13 cells with WT TP53 and degR248Q or degGFP in methylcellulose-based medium containing DMSO, 5 μmol/L iberdomide, and/or 2.5 μmol/L nutlin-3a. After 7 days, images were taken using a Leica DMI6000 B inverted microscope, and analysis was performed using the Colony Area ImageJ plugin, followed by manual counting of the colonies (representative images of n = 3 independent experiments). G, Summary of counted colonies from the colony-forming unit assay as described in F ( n = 3 independent experiments). Bar graphs represent averages. Error bars, SEM. ****, P ≤ 0.0001, one-way ANOVA, Tukey multiple comparison. H, Results of in vitro competition assays of K562 cells with WT TP53 and degR248Q cocultured together with isogenic K562- TP53 WT cells (left) or K562- TP53 R248Q cells (right) in the absence or presence of 2.5 μmol/L nutlin-3a and/or 1 μmol/L iberdomide. The relative fractions of each genotype were determined by flow cytometry every other day for 8 days ( n = 3 independent experiments). Averages are shown. Error bars, SD. ****, P ≤ 0.0001, unpaired t test. I, The results of in vitro competition assays of MOLM13 cells with WT TP53 and degR248Q cocultured together with isogenic MOLM13 cells with WT TP53 (left) or MOLM13 cells with R248Q (right) in the absence or presence of 2.5 μmol/L nutlin-3a and/or 1 μmol/L iberdomide. The relative fractions of each genotype were determined by flow cytometry every other day for 8 days ( n = 3 independent experiments). Symbols indicate averages. Error bars, SD. ****, P ≤ 0.0001, unpaired t test; ns, nonsignificant.

Techniques Used: Quantitative Proteomics, Degradation Assay, Activity Assay, Software, Staining, Comparison, Colony-forming Unit Assay, Inverted Microscopy, In Vitro, Flow Cytometry

Therapeutic efficacy of lowering the increased R248Q:WT protein ratio in vivo . A, Experimental workflow for in vivo p53-targeted R248Q degradation xenograft assay. MOLM13 cells with WT TP53 with degradable BFP (degBFP) or R248Q (degR248Q) as well as GFP-luciferase were transplanted into sublethally irradiated NSG mice. After 5 to 7 days, treatment with vehicle (Veh), iberdomide (Iber), and/or idasanutlin (Ida) at the indicated concentrations was initiated and continued for 7 to 10 days, respectively. Leukemic burden was assessed by bioluminescent imaging 12 and 16 days after injection, and survival was monitored. B, Representative bioluminescent images of mice treated according to the experimental workflow depicted in A . C, Quantification of the bioluminescent signal (i.e., total flux per second) for each group of mice 12 and 16 days after sublethal irradiation and injection of MOLM13 cells with WT TP53 and degR248Q or degBFP and GFP-luciferase. Mice were treated as described in A ( n = 7 animals per group). Symbols represent averages. Error bars, SD. ***, P ≤ 0.001, Mann–Whitney test. D, Survival analysis of NSG mice engrafted with MOLM13 cells with WT TP53 and degR248Q or degBFP and GFP-luciferase and treated as described in A ( n = 7 animals per group). ****, P ≤ 0.0001, Kaplan–Meier simple survival analysis.

Figure Legend Snippet: Therapeutic efficacy of lowering the increased R248Q:WT protein ratio in vivo . A, Experimental workflow for in vivo p53-targeted R248Q degradation xenograft assay. MOLM13 cells with WT TP53 with degradable BFP (degBFP) or R248Q (degR248Q) as well as GFP-luciferase were transplanted into sublethally irradiated NSG mice. After 5 to 7 days, treatment with vehicle (Veh), iberdomide (Iber), and/or idasanutlin (Ida) at the indicated concentrations was initiated and continued for 7 to 10 days, respectively. Leukemic burden was assessed by bioluminescent imaging 12 and 16 days after injection, and survival was monitored. B, Representative bioluminescent images of mice treated according to the experimental workflow depicted in A . C, Quantification of the bioluminescent signal (i.e., total flux per second) for each group of mice 12 and 16 days after sublethal irradiation and injection of MOLM13 cells with WT TP53 and degR248Q or degBFP and GFP-luciferase. Mice were treated as described in A ( n = 7 animals per group). Symbols represent averages. Error bars, SD. ***, P ≤ 0.001, Mann–Whitney test. D, Survival analysis of NSG mice engrafted with MOLM13 cells with WT TP53 and degR248Q or degBFP and GFP-luciferase and treated as described in A ( n = 7 animals per group). ****, P ≤ 0.0001, Kaplan–Meier simple survival analysis.

Techniques Used: Drug discovery, In Vivo, Xenograft Assay, Luciferase, Irradiation, Imaging, Injection, MANN-WHITNEY

Proposed models for DNE exerted by R248Q on WT p53. A, Visual summary of the findings of the present study demonstrating that the increased R248Q:WT ratio is a critical determinant of the DNE of R248Q and a putative therapeutic target. B, Hypothetical model (model A, top) and proposed model (model B, bottom) for the oligomerization of R248Q and WT p53 monomers in cells with monoallelic TP53 R248Q missense mutations based on the findings of the present study and refs. and .

Figure Legend Snippet: Proposed models for DNE exerted by R248Q on WT p53. A, Visual summary of the findings of the present study demonstrating that the increased R248Q:WT ratio is a critical determinant of the DNE of R248Q and a putative therapeutic target. B, Hypothetical model (model A, top) and proposed model (model B, bottom) for the oligomerization of R248Q and WT p53 monomers in cells with monoallelic TP53 R248Q missense mutations based on the findings of the present study and refs. and .

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Journal: Cancer Research

Article Title: The Prolonged Half-Life of the p53 Missense Variant R248Q Promotes Accumulation and Heterotetramer Formation with Wild-Type p53 to Exert the Dominant-Negative Effect

doi: 10.1158/0008-5472.CAN-24-1136

Figure Lengend Snippet: Characterization of the DNE exerted on WT p53 by the R248Q variant. A, Experimental schematic for the CRISPR/Ca9-mediated generation of human isogenic MOLM13- TP53 AML cell lines and their subsequent phenotypic and functional characterization. CRISPR-HDR, CRISPR-Cas9–mediated homology-directed repair; CRISPR-KO, CRISPR-Cas9–mediated gene knockout. B, Whole-cell lysates of isogenic MOLM13- TP53 AML cell lines of the indicated genotypes treated for 3 hours with either DMSO or 100 nmol/L Dauno were separated on a polyacrylamide gel and immunoblotted for p53, p21, and vinculin (representative blot of n = 3 independent experiments). C, Cell-cycle distribution of isogenic MOLM13- TP53 isogenic AML cell lines of the indicated genotypes treated for 6 hours with either DMSO or 100 nmol/L Dauno as determined by CytoPhase Violet staining ( n = 3 independent experiments). Bar graphs represent averages. Error bars, SEM. **, P ≤ 0.01; ****, P ≤ 0.0001, one-way ANOVA, Tukey multiple comparison. D, Fraction of apoptotic MOLM13- TP53 isogenic AML cell lines as determined by Annexin V staining after treatment with either DMSO or 100 nmol/L Dauno for 72 hours ( n = 3 independent experiments). Bar graphs represent averages. Error bars, SEM. *, P ≤ 0.05; ****, P ≤ 0.0001, two-way ANOVA, Tukey multiple comparison. E, Cell viability of MOLM13- TP53 isogenic AML cell lines was determined using the CellTiter-Glo reagent after being exposed to increasing concentrations of the indicated drugs for 72 hours ( n = 3 independent experiments). Symbols represent averages. Error bars, SD, Friedman test. F, Schematic depicting the experiment principle of the in vitro competition assay. Fluorescently labeled MOLM13- TP53 isogenic AML cell lines of various TP53 genotypes were cocultured at a 1:9 ratio in the presence of DMSO or 1 μmol/L nutlin-3a, and the relative fractions of each genotype were determined by flow cytometry every other day for 10 days. G, Heatmaps depict the results of the in vitro competition assays described in F . n = 3 independent experiments; color-coded averages are shown. d, day. H, Representative images of a colony-forming unit assay. MOLM13- TP53 isogenic AML cell lines of the indicated genotypes were cultured for 7 days in methylcellulose-based medium with DMSO or 2.5 μmol/L nutlin-3a. Images were taken using a Leica DMI6000B inverted microscope, and analysis was performed using the Colony Area ImageJ plugin, followed by manual counting of the colonies (representative images of n = 3 independent experiments). I, Counted colonies from colony-forming unit assay as described in H . n = 3 independent experiments. Bar graphs represent averages. Error bars, SEM. ****, P ≤ 0.0001, one-way ANOVA, Tukey multiple comparison. J, Quantification of the bioluminescent signal (i.e., total flux per second) for each group of mice 12 and 16 days after sublethal irradiation and subsequent injection with MOLM13- TP53 -GFP-luciferase isogenic AML cell lines (of the indicated genotypes). One week after injection, mice were treated with idasanutlin (Ida, 25 mg/kg of BW per day) or vehicle (Veh) for seven consecutive days. n = 7 animals per group. Symbols represent averages. Error bars, SD; ***, P ≤ 0.001, Mann–Whitney test. K, Survival analysis of NSG mice engrafted with MOLM13- TP53 -GFP-luciferase isogenic AML cell lines of the indicated genotypes and treated with idasanutlin (25 mg/kg of BW per day) or vehicle for seven consecutive days. n = 7 animals per group. ****, P ≤ 0.0001, Kaplan–Meier simple survival analysis. ns, nonsignificant.

Article Snippet: Afterward, mutagenized p53 variants were amplified and cloned into Cilantro 2 (a great gift from Benjamin Ebert, Addgene plasmid #74450, http://n2t.net/addgene:74450 , q RRID: Addgene_74450) while cutting out the included enhanced green fluorescent protein (EGFP) sequence.

Techniques: Variant Assay, CRISPR, Functional Assay, Gene Knockout, Staining, Comparison, In Vitro, Competitive Binding Assay, Labeling, Flow Cytometry, Colony-forming Unit Assay, Cell Culture, Inverted Microscopy, Irradiation, Injection, Luciferase, MANN-WHITNEY

Journal: Cancer Research

Article Title: The Prolonged Half-Life of the p53 Missense Variant R248Q Promotes Accumulation and Heterotetramer Formation with Wild-Type p53 to Exert the Dominant-Negative Effect

doi: 10.1158/0008-5472.CAN-24-1136

Figure Lengend Snippet: R248Q impairs the ability of WT p53 to bind to promoter DNA and to transactivate expression of target genes. A, Immunofluorescence microscopy images showing p53 (magenta), DAPI (blue), and CellBrite Fix 640 membrane stain (green) in MOLM13- TP53 isogenic AML cell lines treated for 3 hours with 100 nM Dauno ( n = 3 independent experiments; one representative example is shown; confocal microscope Leica DMI6000B, 63× objective). Scale bar, 2.5 μm. B, ChIP followed by NGS in isogenic MOLM- TP53 AML cell lines of the indicated genotypes after treatment with DMSO or 100 nmol/L Dauno for 6 hours. Plots show genome-wide relative enrichment of p53 variants (WT or R248Q) over p53 null cells over TSS-proximal regions (−10 kb to first intron). C, Tornado plots of WT and R248Q ChIP-seq peaks over TSS-proximal regions (−10kb, first intron with a horizontal window of 1 kb around the peak center) in isogenic MOLM- TP53 AML cell lines of the indicated genotypes. Cells were treated as described in B . Plots show relative enrichment and mutual overlap of the peaks identified in each cell line. D, Representative Integrative Genome Viewer images depicting the ChIP-seq peaks for p53 over the TSS of CDKN1A or MDM2 in isogenic MOLM- TP53 AML cell lines of the indicated genotypes after treatment as described in B . E, Relative expression of CDKN1A and MDM2 transcripts normalized to ACTB in isogenic MOLM- TP53 AML cell lines of the indicated genotypes after treatment with DMSO or 100 nmol/L Dauno for 6 hours ( n = 3 independent experiments). Bar graphs represent averages. Error bars, SD. ns, nonsignificant; ****, P ≤ 0.0001, one-way ANOVA, Tukey multiple comparison.

Techniques: Expressing, Immunofluorescence, Microscopy, Membrane, Staining, Genome Wide, ChIP-sequencing, Comparison

Journal: Cancer Research

Article Title: The Prolonged Half-Life of the p53 Missense Variant R248Q Promotes Accumulation and Heterotetramer Formation with Wild-Type p53 to Exert the Dominant-Negative Effect

doi: 10.1158/0008-5472.CAN-24-1136

Figure Lengend Snippet: Heterotetramers consisting of R248Q and WT p53 are transcriptionally inactive, but overexpression of WT p53 can overcome the DNE of R248Q. A, MOLM13- TP53 isogenic cell lines were treated with DMSO or 100 nmol/L Dauno for 3 hours, followed by collection of whole-cell protein lysates by using IGEPAL lysis buffer. Lysates were fixed with 0.03% glutaraldehyde and subsequently separated on a polyacrylamide gel under nonreducing conditions. The PVDF membrane was immunoblotted for p53 ( n = 3 independent experiments; one representative blot is shown). B, MOLM13- TP53 null or K562- TP53 null AML cell lines lentivirally transduced to stably express full-length R248Q, tetramerization-deficient R248Q (R248Q-L344A), or dimerization-deficient R248Q (R248Q-L344P or R248Q-OD lacking the OD of p53) were treated for 3 hours with either DMSO or 100 nmol/L Dauno. Glutaraldehyde-fixed whole-cell protein lysates were separated on a polyacrylamide gel and immunoblotted for p53 ( n = 3 independent experiments; representative blots are shown). C, Experimental schematic depicting the general principle of the flow cytometry–based FRET assay in K562- TP53 null AML cells. For experimental details, please refer to the Materials and Methods. D, Representative FACS plots showing results of the FRET assay in K562- TP53 null AML cells for the interaction between WT monomers (top), or WT and R248Q monomers (bottom). FRET donor and acceptor plasmids encoding p53 WT or R248Q variants either oligomerization-proficient (WT) or -deficient (WT-L344A, WT-L344P, or WT-OD) were co-electroporated into K562- TP53 null AML cells, followed by FRET measurement (FRET fluorescence measured using the 525/50-nm detector). E, Pooled results of the FRET assays in K562- TP53 null AML cells ( n = 3 independent experiments). Bar graphs represent averages. Error bars, SD. ***, P ≤ 0.001; ****, P ≤ 0.0001, one-way ANOVA, Tukey multiple comparison. F, Experimental schematic and pooled results of the transcriptional reporter assay in K562- TP53 null -p21-GFP cells electroporated with plasmids encoding oligomerization-proficient or -deficient WT p53 variants ( n = 3 independent experiments). Bar graphs represent averages. Error bars, SEM. *, P ≤ 0.05; **, P ≤ 0.01; ****, P ≤ 0.0001, one-way ANOVA, Tukey multiple comparison. G, Experimental schematic and pooled results of the transcriptional reporter assay in K562- TP53 WT -p21-GFP cells electroporated with pRK5 plasmids encoding oligomerization-proficient or -deficient R248Q p53 variants ( n = 3 independent experiments). Bar graphs represent averages. Error bars, SEM. **, P ≤ 0.01; ****, P ≤ 0.0001, one-way ANOVA, Tukey multiple comparison. H, Quantification of the bioluminescent signal (i.e., total flux per second) for each group of mice 12 and 16 days after sublethal irradiation and subsequent injection with MOLM13- TP53 +/− -GFP-luciferase AML cell lines overexpressing either R248Q (WT + R248Q) or oligomerization-deficient R248Q-L344P (WT + R248Q-L344P). Following, mice were treated with idasanutlin (Ida, 25 mg/kg of BW per day) or vehicle (Veh) for seven consecutive days ( n = 7 animals per group). Symbols represent averages. Error bars, SD. ***, P ≤ 0.001, Mann–Whitney test. I, Survival analysis of NSG mice engrafted with MOLM13- TP53 +/− -GFP-luciferase AML cell lines overexpressing either R248Q (WT + R248Q) or R248Q-L344P (WT + R248Q-L344P) and treated with idasanutlin (25 mg/kg of BW per day) or vehicle for seven consecutive days ( n = 7 animals per group). ****, P ≤ 0.0001, Kaplan–Meier simple survival analysis. J, Experimental schematic and pooled results of the transcriptional reporter assay in K562- TP53 R248Q -p21-GFP cells electroporated with the pRK5 plasmid encoding oligomerization-proficient WT p53 variant ( n = 3 independent experiments). Bar graphs represent averages. Error bars, SEM. ****, P ≤ 0.0001, Welch t test. CNTR, control; FRET-Acc, FRET acceptor; FRET-Don, FRET donor. ns, nonsignificant.

Techniques: Over Expression, Lysis, Membrane, Stable Transfection, Flow Cytometry, Fluorescence, Comparison, Reporter Assay, Irradiation, Injection, Luciferase, MANN-WHITNEY, Plasmid Preparation, Variant Assay, Control

Journal: Cancer Research

Article Title: The Prolonged Half-Life of the p53 Missense Variant R248Q Promotes Accumulation and Heterotetramer Formation with Wild-Type p53 to Exert the Dominant-Negative Effect

doi: 10.1158/0008-5472.CAN-24-1136

Figure Lengend Snippet: The longer protein half-life of R248Q leads to an increase of the R248Q:WT ratio. A, Bone marrow biopsies of patients with TP53 WT or TP53 R248Q -mutant AML, high-grade B-cell lymphoma (HGBCL), or early T precursor lymphoblastic leukemia (ETP-ALL) stained with hematoxylin and eosin (H&E) and p53 IHC ( n = 6 representative images; ×100 magnification) show strong nuclear p53 staining in neoplastic cells of TP53 R248Q mutated cases. B, Experimental schematic for the CRISPR/Ca9-mediated generation of human isogenic cancer cell lines with TP53 WT or R248Q alleles and their subsequent use for p53 quantification and half-life determination as shown in C and E . CRC, colorectal cancer; CRISPR-HDR, CRISPR-Cas9–mediated homology-directed repair; NSCLC, non–small cell lung cancer. C, Whole-cell lysates of isogenic MOLM13- TP53 , K562- TP5 3, A549- TP53 , and HCT116- TP53 isogenic cell lines with WT and R248Q alleles treated for 6 hours with either DMSO or 100 nM Dauno were separated on a polyacrylamide gel and immunoblotted for p53 and vinculin. P53 was quantified via ImageJ software using vinculin to normalize p53 levels ( n = 3–4 independent experiments; representative blots are shown). Bar graphs represent averages. Error bars, SEM. *, P ≤ 0.05; **, P ≤ 0.01; ***, P ≤ 0.001, two-way ANOVA, Tukey multiple comparison. D, NGS of cDNA from isogenic MOLM13- TP53 AML cell lines of the indicated genotypes. Number of NGS reads supporting the WT (gray) or R248Q (blue) allele are shown ( n = 3 independent experiments). Bar graphs represent averages. Error bars, SD. Two-way ANOVA, Tukey multiple comparison. ns, nonsignificant; n.d., not detectable. E, Half-life determination of p53 WT and R248Q in untreated isogenic MOLM13- TP53 , K562- TP53 , A549- TP53 , and HCT116- TP53 isogenic cell lines. Whole-cell lysates of cycloheximide-treated cells were collected at the indicated time points and separated on a polyacrylamide gel and immunoblotted for p53 and vinculin. p53 was quantified using ImageJ software ( n = 3–4 independent experiments; representative blots are shown). Error bars, SEM. ****, P ≤ 0.0001, Mann–Whitney test.

Techniques: Mutagenesis, Staining, CRISPR, Software, Comparison, MANN-WHITNEY

Journal: Cancer Research

Article Title: The Prolonged Half-Life of the p53 Missense Variant R248Q Promotes Accumulation and Heterotetramer Formation with Wild-Type p53 to Exert the Dominant-Negative Effect

doi: 10.1158/0008-5472.CAN-24-1136

Figure Lengend Snippet: A supraphysiologic protein abundance of R248Q is required for the DNE. A, Experimental schematic showing the principle of the p53 target degradation assay. B, Whole-cell lysates of iberdomide- and/or nutlin-3a–treated K562 cells with TP53 WT and degR248Q or K562 cells with TP53 WT and degGFP were separated on a polyacrylamide gel and immunoblotted for p53, p21, and vinculin ( n = 3 independent experiments; one representative blot is shown). C, Correlation between the WT p53 transcriptional activity as determined by the normalized p21/vinculin and the R248Q/WT ratio in K562 cells with TP53 WT and degR248Q. Cells were treated with 2.5 μmol/L nutlin-3a and increasing concentrations of iberdomide, whole-cell lysates were prepared, run on a polyacrylamide gel, immunoblotted for p53, p21, and vinculin, and bands were quantified using ImageJ software ( n = 3 independent experiments, pooled data, including averages and SEM are shown). D, Cell-cycle distribution of MOLM13 cells with WT TP53 and degR248Q or MOLM13 cells with WT TP53 and degGFP cells in the absence or presence of 1 μmol/L iberdomide and/or 2.5 μmol/L nutlin-3a for 24 hours as determined by CytoPhase Violet staining ( n = 3 independent experiments). Bar graphs represent averages. Error bars, SEM. ****, P ≤ 0.0001, one-way ANOVA, Tukey multiple comparison. E, Fraction of apoptotic MOLM13 cells with WT TP53 and degR248Q or degGFP as determined by Annexin V staining in the absence or presence of 1 μmol/L iberdomide and/or 2.5 μmol/L nutlin-3a for 24 to 72 hours ( n = 3 independent experiments). Bar graphs represent averages. Error bars, SEM. **, P ≤ 0.01; ***, P ≤ 0.001; ****, P ≤ 0.0001, two-way ANOVA, Tukey multiple comparison. F, Representative images of a colony-forming unit assay was performed in MOLM13 cells with WT TP53 and degR248Q or degGFP in methylcellulose-based medium containing DMSO, 5 μmol/L iberdomide, and/or 2.5 μmol/L nutlin-3a. After 7 days, images were taken using a Leica DMI6000 B inverted microscope, and analysis was performed using the Colony Area ImageJ plugin, followed by manual counting of the colonies (representative images of n = 3 independent experiments). G, Summary of counted colonies from the colony-forming unit assay as described in F ( n = 3 independent experiments). Bar graphs represent averages. Error bars, SEM. ****, P ≤ 0.0001, one-way ANOVA, Tukey multiple comparison. H, Results of in vitro competition assays of K562 cells with WT TP53 and degR248Q cocultured together with isogenic K562- TP53 WT cells (left) or K562- TP53 R248Q cells (right) in the absence or presence of 2.5 μmol/L nutlin-3a and/or 1 μmol/L iberdomide. The relative fractions of each genotype were determined by flow cytometry every other day for 8 days ( n = 3 independent experiments). Averages are shown. Error bars, SD. ****, P ≤ 0.0001, unpaired t test. I, The results of in vitro competition assays of MOLM13 cells with WT TP53 and degR248Q cocultured together with isogenic MOLM13 cells with WT TP53 (left) or MOLM13 cells with R248Q (right) in the absence or presence of 2.5 μmol/L nutlin-3a and/or 1 μmol/L iberdomide. The relative fractions of each genotype were determined by flow cytometry every other day for 8 days ( n = 3 independent experiments). Symbols indicate averages. Error bars, SD. ****, P ≤ 0.0001, unpaired t test; ns, nonsignificant.

Techniques: Quantitative Proteomics, Degradation Assay, Activity Assay, Software, Staining, Comparison, Colony-forming Unit Assay, Inverted Microscopy, In Vitro, Flow Cytometry

Journal: Cancer Research

Article Title: The Prolonged Half-Life of the p53 Missense Variant R248Q Promotes Accumulation and Heterotetramer Formation with Wild-Type p53 to Exert the Dominant-Negative Effect

doi: 10.1158/0008-5472.CAN-24-1136

Figure Lengend Snippet: Therapeutic efficacy of lowering the increased R248Q:WT protein ratio in vivo . A, Experimental workflow for in vivo p53-targeted R248Q degradation xenograft assay. MOLM13 cells with WT TP53 with degradable BFP (degBFP) or R248Q (degR248Q) as well as GFP-luciferase were transplanted into sublethally irradiated NSG mice. After 5 to 7 days, treatment with vehicle (Veh), iberdomide (Iber), and/or idasanutlin (Ida) at the indicated concentrations was initiated and continued for 7 to 10 days, respectively. Leukemic burden was assessed by bioluminescent imaging 12 and 16 days after injection, and survival was monitored. B, Representative bioluminescent images of mice treated according to the experimental workflow depicted in A . C, Quantification of the bioluminescent signal (i.e., total flux per second) for each group of mice 12 and 16 days after sublethal irradiation and injection of MOLM13 cells with WT TP53 and degR248Q or degBFP and GFP-luciferase. Mice were treated as described in A ( n = 7 animals per group). Symbols represent averages. Error bars, SD. ***, P ≤ 0.001, Mann–Whitney test. D, Survival analysis of NSG mice engrafted with MOLM13 cells with WT TP53 and degR248Q or degBFP and GFP-luciferase and treated as described in A ( n = 7 animals per group). ****, P ≤ 0.0001, Kaplan–Meier simple survival analysis.

Techniques: Drug discovery, In Vivo, Xenograft Assay, Luciferase, Irradiation, Imaging, Injection, MANN-WHITNEY

Journal: Cancer Research

Article Title: The Prolonged Half-Life of the p53 Missense Variant R248Q Promotes Accumulation and Heterotetramer Formation with Wild-Type p53 to Exert the Dominant-Negative Effect

doi: 10.1158/0008-5472.CAN-24-1136

Figure Lengend Snippet: Proposed models for DNE exerted by R248Q on WT p53. A, Visual summary of the findings of the present study demonstrating that the increased R248Q:WT ratio is a critical determinant of the DNE of R248Q and a putative therapeutic target. B, Hypothetical model (model A, top) and proposed model (model B, bottom) for the oligomerization of R248Q and WT p53 monomers in cells with monoallelic TP53 R248Q missense mutations based on the findings of the present study and refs. and .

Techniques:

Bright-field differential interference contrast (DIC) microscopy images were collected, revealing ( a ) the concentration-dependent demixing of p63C and p73C, and ( b ) the demixing of p53C from the PEG solution. c The temperature dependence of p53C, M237I, p63C, and p73C demixing and aggregation (arrows). d The time dependence of p53C aggregation from droplets at 25 °C (see methods); Schematic representations of ( e ) p63C and p73C demixing concentrations, and ( f ) the temperature dependence of the studied proteins. Colored circles indicate the phase separation of p53C (green), M237I (gray), p63C (red), and p73C (blue). Circles filled with an asterisk depict aggregation conditions.

Journal: Communications Chemistry

Article Title: Oncogenic p53 triggers amyloid aggregation of p63 and p73 liquid droplets

doi: 10.1038/s42004-024-01289-x

Figure Lengend Snippet: Bright-field differential interference contrast (DIC) microscopy images were collected, revealing ( a ) the concentration-dependent demixing of p63C and p73C, and ( b ) the demixing of p53C from the PEG solution. c The temperature dependence of p53C, M237I, p63C, and p73C demixing and aggregation (arrows). d The time dependence of p53C aggregation from droplets at 25 °C (see methods); Schematic representations of ( e ) p63C and p73C demixing concentrations, and ( f ) the temperature dependence of the studied proteins. Colored circles indicate the phase separation of p53C (green), M237I (gray), p63C (red), and p73C (blue). Circles filled with an asterisk depict aggregation conditions.

Article Snippet: After reaching 70% of confluency, H1299 cells were transfected with ten μg of pEGFP-N1 vector (Clontech), containing a C-terminus EGFP-tagged sequence of the full-length M237I p53 protein (Addgene, #11770), and 4 μL of Lipofectamine 2000 reagent.

Techniques: Microscopy, Concentration Assay

Microscopy images were captured, presenting the Congo red (CR) fluorescence and bright-field channels of ( a ) p53C, ( b ) M237I, ( c ) p63C, and ( d ) p73C at 4 and 37 °C. White arrows indicate the presence of p53C and M237I aggregates. Scale bar: 20 μm; Line plots showing the area under the light scattering curve as a function of increasing temperatures (4, 25, and 37 °C) of ( e ) p53C (green), ( f ) M237I (gray), ( g ) p63C (light red), and ( h ) p73C (light blue) in the absence (colored circles) and the presence (colored squares) of PEG. Plots in ( g , h ) show two segments in the y-axis to highlight negligible scattering. Line plots with the filled area showing turbidity at 600 nm as a function of increasing concentrations of ( i ) p53C (green palette), ( j ) M237I (gray palette), ( k ) p63C (red palette), and ( l ) p73C (blue palette) at 4, 25, and 37 °C. Plots in ( k , l ) show two segments in the y-axis to highlight negligible turbidity. Red and blue palettes are not depicted in ( k , l ) due to similar values across studied temperatures. Scatter dot plots showing the thioflavin T fluorescence as a function of increasing temperatures (4, 25, and 37 °C) of ( m ) p53C, ( n ) M237I, ( o ) p63C, and ( p ) p73C. The color palette is the same as in ( i – l ). Plots show two segments in the y-axis to evidence large changes in the thioflavin T signal across studied proteins. The data are shown as the mean ± s.e.m. of n = 3 independent experiments using the same protein batch.

Journal: Communications Chemistry

Article Title: Oncogenic p53 triggers amyloid aggregation of p63 and p73 liquid droplets

doi: 10.1038/s42004-024-01289-x

Figure Lengend Snippet: Microscopy images were captured, presenting the Congo red (CR) fluorescence and bright-field channels of ( a ) p53C, ( b ) M237I, ( c ) p63C, and ( d ) p73C at 4 and 37 °C. White arrows indicate the presence of p53C and M237I aggregates. Scale bar: 20 μm; Line plots showing the area under the light scattering curve as a function of increasing temperatures (4, 25, and 37 °C) of ( e ) p53C (green), ( f ) M237I (gray), ( g ) p63C (light red), and ( h ) p73C (light blue) in the absence (colored circles) and the presence (colored squares) of PEG. Plots in ( g , h ) show two segments in the y-axis to highlight negligible scattering. Line plots with the filled area showing turbidity at 600 nm as a function of increasing concentrations of ( i ) p53C (green palette), ( j ) M237I (gray palette), ( k ) p63C (red palette), and ( l ) p73C (blue palette) at 4, 25, and 37 °C. Plots in ( k , l ) show two segments in the y-axis to highlight negligible turbidity. Red and blue palettes are not depicted in ( k , l ) due to similar values across studied temperatures. Scatter dot plots showing the thioflavin T fluorescence as a function of increasing temperatures (4, 25, and 37 °C) of ( m ) p53C, ( n ) M237I, ( o ) p63C, and ( p ) p73C. The color palette is the same as in ( i – l ). Plots show two segments in the y-axis to evidence large changes in the thioflavin T signal across studied proteins. The data are shown as the mean ± s.e.m. of n = 3 independent experiments using the same protein batch.

Techniques: Microscopy, Fluorescence

Microscopy images showing the Alexa Fluor 488 (AF488) labeled ( a , c ) p53C or ( b , d ) M237I (green), the rhodamine-labeled (Rhod) ( a , b ) p63C or ( c , d ) p73C (red) fluorescent channels together with the bright-field and merged images at 4 and 37 °C. Scale bar: 20 μm. e Schematic representation of the crosstalk within the p53 family members at 4 (dashed cyan) and 37 °C (dashed orange). Red and blue circles depict demixing with droplet formation. Red and white circles filled with an asterisk indicate a mixture of droplets and aggregates, and mainly aggregates, respectively. NA stands for not analyzed.

Journal: Communications Chemistry

Article Title: Oncogenic p53 triggers amyloid aggregation of p63 and p73 liquid droplets

doi: 10.1038/s42004-024-01289-x

Figure Lengend Snippet: Microscopy images showing the Alexa Fluor 488 (AF488) labeled ( a , c ) p53C or ( b , d ) M237I (green), the rhodamine-labeled (Rhod) ( a , b ) p63C or ( c , d ) p73C (red) fluorescent channels together with the bright-field and merged images at 4 and 37 °C. Scale bar: 20 μm. e Schematic representation of the crosstalk within the p53 family members at 4 (dashed cyan) and 37 °C (dashed orange). Red and blue circles depict demixing with droplet formation. Red and white circles filled with an asterisk indicate a mixture of droplets and aggregates, and mainly aggregates, respectively. NA stands for not analyzed.

Techniques: Microscopy, Labeling

Scatter dot plots showing area under the light scattering curves of ( a , b ) p63C (red bars), seeds of ( a ) p53C (green bar) or ( b ) p53C M237I (black bar), after mixing p63C with ( a ) p53C seeds (red bars colored green) or ( b ) p53C M237I seeds (red bars colored black), in the absence (-) or presence (+) of PEG 15%. c Changes in the light scattering (Δ area) show the p63C aggregation in the presence of PEG after subtracting the p53C (red bar colored green) or M237I (red bar colored black) seeds contribution. d Confocal images showing rhodamine-labeled p63C (red), Thioflavin T (green), and the intrinsic fluorescence (blue) of p63C aggregates.

Journal: Communications Chemistry

Article Title: Oncogenic p53 triggers amyloid aggregation of p63 and p73 liquid droplets

doi: 10.1038/s42004-024-01289-x

Figure Lengend Snippet: Scatter dot plots showing area under the light scattering curves of ( a , b ) p63C (red bars), seeds of ( a ) p53C (green bar) or ( b ) p53C M237I (black bar), after mixing p63C with ( a ) p53C seeds (red bars colored green) or ( b ) p53C M237I seeds (red bars colored black), in the absence (-) or presence (+) of PEG 15%. c Changes in the light scattering (Δ area) show the p63C aggregation in the presence of PEG after subtracting the p53C (red bar colored green) or M237I (red bar colored black) seeds contribution. d Confocal images showing rhodamine-labeled p63C (red), Thioflavin T (green), and the intrinsic fluorescence (blue) of p63C aggregates.

Techniques: Labeling, Fluorescence

a – e Collection of images showing endogenous p73 colocalization with exogenous full-length p53 M237I inside membraneless compartments. Five distinct regions of interest and the corresponding channels: p73 (red), EGFP-tagged p53 M237I (green), nuclei (blue), bright-field, and merged. Last panel show zoomed images from dashed rectangles to emphasize p53 and p73 colocalization spots (white and black arrowheads).

Journal: Communications Chemistry

Article Title: Oncogenic p53 triggers amyloid aggregation of p63 and p73 liquid droplets

doi: 10.1038/s42004-024-01289-x

Figure Lengend Snippet: a – e Collection of images showing endogenous p73 colocalization with exogenous full-length p53 M237I inside membraneless compartments. Five distinct regions of interest and the corresponding channels: p73 (red), EGFP-tagged p53 M237I (green), nuclei (blue), bright-field, and merged. Last panel show zoomed images from dashed rectangles to emphasize p53 and p73 colocalization spots (white and black arrowheads).

Techniques:

a , b Images of individually tagged p53 family members p63C and p73C co-transfected with full-length p53 M237I in H1299 p53-null cells. Arrows indicate membranelle compartments. Dot plots showing the time-dependent fluorescence recovery of ( c ) the p53 M237I/p63C and ( d ) the p53 M237I/p73C nuclear (black) and nucleolar (red) regions. The data are shown as the mean ± s.d. of n = 5 cells of the same coverslip.

Journal: Communications Chemistry

Article Title: Oncogenic p53 triggers amyloid aggregation of p63 and p73 liquid droplets

doi: 10.1038/s42004-024-01289-x

Figure Lengend Snippet: a , b Images of individually tagged p53 family members p63C and p73C co-transfected with full-length p53 M237I in H1299 p53-null cells. Arrows indicate membranelle compartments. Dot plots showing the time-dependent fluorescence recovery of ( c ) the p53 M237I/p63C and ( d ) the p53 M237I/p73C nuclear (black) and nucleolar (red) regions. The data are shown as the mean ± s.d. of n = 5 cells of the same coverslip.

Techniques: Transfection, Fluorescence

Bar plots show heparin’s effect on p63C aggregation when mixing p63C with ( a ) p53C or ( b ) p53C M237I in the presence of PEG. The data are shown as the mean ± s.e.m. of n = 3 independent experiments using the same protein batch. Microscopy images showing the AF488-labeled ( c ) p53C or ( d ) M237I, the Rhodamine-labeled p63C, the bright-field, and merged channels in the absence (-) or presence (+) of heparin. Scale bar: 20 μm.

Journal: Communications Chemistry

Article Title: Oncogenic p53 triggers amyloid aggregation of p63 and p73 liquid droplets

doi: 10.1038/s42004-024-01289-x

Figure Lengend Snippet: Bar plots show heparin’s effect on p63C aggregation when mixing p63C with ( a ) p53C or ( b ) p53C M237I in the presence of PEG. The data are shown as the mean ± s.e.m. of n = 3 independent experiments using the same protein batch. Microscopy images showing the AF488-labeled ( c ) p53C or ( d ) M237I, the Rhodamine-labeled p63C, the bright-field, and merged channels in the absence (-) or presence (+) of heparin. Scale bar: 20 μm.

Techniques: Microscopy, Labeling

Schematic showing the effects of p53C and M237I converting p63C and p73C droplets into amyloid aggregates at physiologically relevant temperatures. Heparin averts p53C/p63C or p53/p73C aggregates. At 4 °C, phase separation but not phase transition occurs.

Journal: Communications Chemistry

Article Title: Oncogenic p53 triggers amyloid aggregation of p63 and p73 liquid droplets

doi: 10.1038/s42004-024-01289-x

Figure Lengend Snippet: Schematic showing the effects of p53C and M237I converting p63C and p73C droplets into amyloid aggregates at physiologically relevant temperatures. Heparin averts p53C/p63C or p53/p73C aggregates. At 4 °C, phase separation but not phase transition occurs.

Techniques: Sublimation