Article Figures & Data
Figures
- Figure 1.
ENGRAILED protection of embryonic midbrain neurons. A, hEN1 dose-dependent survival of embryonic neurons after H2O2 oxidative stress. B, Preadsorption of hEN1 with an anti-ENGRAILED antibody abrogates hEN1 neuroprotection. C, hEN1 subjected to repeated freeze–thaw cycles (left) or maintained at 4°C for 6 weeks (right) has significant neuroprotective activity against oxidative stress. D, ENGRAILED internalization and high-affinity DNA binding are necessary for ENGRAILED neuroprotection. LDH assay was used for A–D. ns, nonsignificant, ****p < 0.0001.
- Figure 2.
Homeoproteins protect embryonic neurons but not non-neuronal cells in the LDH assay. A, hEN1, mOTX2, GBX2, and hLHX9 protect embryonic ventral midbrain cells against H2O2 oxidative stress, while hMYC does not. B, hEN1, mOTX2, GBX2, and hLHX9 protect embryonic striatal neurons against H2O2 oxidative stress, while hMYC does not. C, hE1 and hGBX2 protect primary astrocytes against H2O2 oxidative stress. D, hEN1, hGBX2, and hMYC do not protect fibroblasts against H2O2 oxidative stress. E, hEN1, hGBX2, and hMYC do not protect HeLa cells against H2O2 oxidative stress. F, hEN1, hGBX2, and hMYC do not protect macrophages against H2O2 oxidative stress. G, qRT-PCR reveals the expression of GBX2, LHX9, and OTX2 in embryonic striatum, and LHX9, OTX2, and EN1 in ventral midbrain. ns, nonsignificant, ****p < 0.0001.
- Figure 3.
HPs reduce DNA breaks after H2O2. A, Cultures of E14.5 ventral midbrain neurons (red) untreated (control) show few bright γH2AX foci (green), while those treated with 100 μm H2O2 have numerous foci and those pretreated with mEN1 have only a few. B, Quantification of γH2AX foci. H2O2 increases the number of foci from ∼1-2 per neuron to ∼8. mEN1, mOTX2, hGBX2, and hLHX9 reduce the number of foci in a dose-dependent manner. C, D, Inhibition of reverse transcriptase activity protects against H2O2 oxidative stress in midbrain (C) and striatal neurons (D). In the control condition, few γH2AX foci are observed in embryonic midbrain neurons, while those challenged with 100 μm H2O2 show multiple DNA damaged foci. Pretreatment with 10 μm stavudine or 2.5 nm hEn1 completely blocks the formation of DNA damage foci. ****p < 0.0001.
- Figure 4.
hEN1 protects immortalized human dopaminergic neuronal precursors, LUHMES cells, against H2O2 oxidative stress by LDH assay. A, Three hundred and 200 μm 6-OHDA reduce the number of LUHMES cells surviving, while 50 nm hEN1 completely protects against this oxidative stress. B, Quantification of γH2AX foci. 6-OHDA increases the number of foci by twofold to fourfold. Preincubation with hEN1 reduces the number of foci to the control level. ns, nonsignificant, ****p < 0.0001.
Tables
Data structure Type of test Power Trypan blue Control vs H2O2 Post hoc t test, two-tailed 1.00 H2O2 vs 12.5 nm 0.92 Figure 1A H2O2 vs 12.5 nm Dunnett’s multiple comparisons 1.000 H2O2 vs 2.5 nm 1.000 H2O2 vs 25 pm 1.000 H2O2 vs 12.5 pm 1.00 H2O2 vs 2.5 pm 1.000 H2O2 vs 1.25 nm 1.000 Figure 1B H2O2 vs 12.5 nm Dunnett’s multiple comparisons 1.000 H2O2 vs 2.5 nm 1.00 Figure 1C H2O2 vs 12.5 nm 1× frozen Dunnett’s multiple comparisons 1.000 H2O2 vs 2.5 nm 1× frozen 1.00 H2O2 vs 12.5 nm 5× frozen 1.00 H2O2 vs 2.5 nm 5× frozen 1.000 H2O2 vs 12.5 nm 4°C 1.000 H2O2 vs 2.5 nm 4°C 1.000 Figure 1D H2O2 vs 12.5 nm chEn2 Dunnett’s multiple comparisons 1.000 H2O2 vs 2.5 nm chEn2 1.000 H2O2 vs 12.5 nm hEn1Q50A 1.000 H2O2 vs 2.5 nm hEn1Q50A 1.000 H2O2 vs 12.5 nm hEn2 1.000 H2O2 vs 2.5 nm hEn2 1.000 Figure 2A H2O2 vs 12.5 nm hEn1 Dunnett’s multiple comparisons 1.000 H2O2 vs 2.5 nm hEn1 1.000 H2O2 vs 12.5 nm mOtx2 1.000 H2O2 vs 2.5 nm mOtx2 1.000 H2O2 vs 12.5 nm hGbx2 1.000 H2O2 vs 2.5 nm hGbx2 1.000 H2O2 vs 12.5 nm hLhx9 1.000 Figure 2B H2O2 vs 12.5 nm hEn1 Dunnett’s multiple comparisons 1.000 H2O2 vs 2.5 nm hEn1 1.000 H2O2 vs 12.5 nm mOtx2 1.000 H2O2 vs 2.5 nm mOtx2 1.000 H2O2 vs 12.5 nm hGbx2 1.000 H2O2 vs 2.5 nm hGbx2 1.000 H2O2 vs 12.5 nm hLhx9 1.000 H2O2 vs 2.5 nm hLhx9 1.000 Figure 2C H2O2 vs 12.5 nm hEn1 Dunnett’s multiple 1.000 H2O2 vs 2.5 nm hEn1 comparisons 1.000 H2O2 vs 12.5 nm hGbx2 1.000 H2O2 vs 12.5 nm hLhx9 1.00 Figure 3B H2O2 vs 2.5 nm mEn1 Dunnett’s multiple comparisons 1.00 H2O2 vs 1.25 nm mEn1 1.000 H2O2 vs 0.62 nm mEn1 1.00 H2O2 vs 0.31 nm mEn1 1.00 H2O2 vs 3.3 nm mOtx2 1.000 H2O2 vs 1.65 nm mOtx2 1.00 H2O2 vs 0.82 nm mOtx2 1.000 H2O2 vs 0.41 nm mOtx2 1.00 H2O2 vs 2.68 nm hGbx2 1.000 H2O2 vs 1.34 nm hGbx2 1.000 H2O2 vs 0.67 nm hGbx2 1.000 H2O2 vs 0.33 nm hGbx2 1.000 H2O2 vs 2.27 nm hLhx9 1.000 H2O2 vs 1.14 nm hLhx9 1.000 H2O2 vs 0.56 nm hLhx9 1.000 H2O2 vs 0.28 nm hLhx9 1.000 Figure 3C H2O2 vs stavudine Dunnett’s multiple comparisons 1.000 H2O2 vs hEn1 1.000 Figure 3D H2O2 vs stavudine Dunnett’s multiple comparisons 1.000 H2O2 vs hEn1 1.000 Figure 4A −hEN1 vs +hEN1 at 300 μm 6-OHDA Post hoc t test, two-tailed 1.000 −hEN1 vs +hEN1 at 200 μm 6-OHDA Post hoc t test, two-tailed 1.000 Figure 4B −hEN1 vs +hEN1 at 10 μm 6-OHDA Post hoc t test, two-tailed 1.000 −hEN1 vs +hEN1 at 50 μm 6-OHDA Post hoc t test, two-tailed 1.000
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