The GLYT1 inhibitor bitopertin mitigates erythroid PPIX production and liver disease in erythroid protoporphyria
Sarah Ducamp, Min Wu, Juan Putra, Dean R. Campagna, Yi Xiang, Vu Hong, Matthew M. Heeney, Amy K. Dickey, Rebecca K. Leaf, Mark D. Fleming, Brian MacDonald, Paul J. Schmidt
Sarah Ducamp, Min Wu, Juan Putra, Dean R. Campagna, Yi Xiang, Vu Hong, Matthew M. Heeney, Amy K. Dickey, Rebecca K. Leaf, Mark D. Fleming, Brian MacDonald, Paul J. Schmidt
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Research Article Genetics Hematology

The GLYT1 inhibitor bitopertin mitigates erythroid PPIX production and liver disease in erythroid protoporphyria

Abstract

Erythropoietic protoporphyria (EPP) is a genetic disorder typically resulting from decreased ferrochelatase (FECH) activity, the last enzyme in heme biosynthesis. Patients with X-linked protoporphyria (XLPP) have an overlapping phenotype caused by increased activity of 5-aminolevulinic acid synthase 2 (ALAS2), the first enzyme in erythroid heme synthesis. In both cases, protoporphyrin IX (PPIX) accumulates in erythrocytes and secondarily in plasma and tissues. Patients develop acute phototoxicity reactions upon brief exposure to sunlight. Some also experience chronic liver disease, and a small fraction develop acute cholestatic liver failure. Therapeutic options are limited, and none, save hematopoietic stem cell transplantation, directly targets erythroid PPIX accumulation. Bitopertin is an investigational orally available small-molecule inhibitor of the erythroid cell-surface glycine transporter GLYT1. We established the bitopertin PPIX inhibitory half-maximal effective concentration in a human erythroblast EPP model and confirmed a marked reduction of PPIX in erythroblasts derived from patients with EPP. We demonstrate that bitopertin also reduced erythrocyte and plasma PPIX accumulation in vivo in both EPP and XLPP mouse models. Finally, the reduction in erythroid PPIX ameliorated liver disease in the EPP mouse model. Altogether, these data support the development of bitopertin to treat patients with EPP or XLPP.

Authors

Sarah Ducamp, Min Wu, Juan Putra, Dean R. Campagna, Yi Xiang, Vu Hong, Matthew M. Heeney, Amy K. Dickey, Rebecca K. Leaf, Mark D. Fleming, Brian MacDonald, Paul J. Schmidt

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Figure 8

PPIX accumulation in reticulocytes and erythrocytes of EPP mice fed a 200 ppm bitopertin diet.

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PPIX accumulation in reticulocytes and erythrocytes of EPP mice fed a 20...
(A) PPIX in TO+ (reticulocytes) PB versus the time after introduction of the bitopertin diet. (B) PPIX in TO (erythrocytes) PB versus the time after introduction of the bitopertin diet. (C) PPIX in CD71hi (young reticulocytes) PB versus time after introduction of bitopertin diet. (D) PPIX in CD71med (young erythrocytes) PB versus the time after introduction of the bitopertin diet. (E) Comparison of PPIX MFI in CD71hi/med/lo PB populations versus time in EPP animals fed the control or 200 ppm bitopertin diet. Data are replotted from C and D along with CD71lo (older erythrocytes) population. Note the rapid decrease in PPIX on day 1 in the CD71hi population that could then be observed over the next 2 days in the CD71med population, as indicated by the red arrows. *P < 0.05, **P <0.01, ***P < 0.001, and ****P < 0.0001, by unpaired, 2-tailed Welch’s t test with Holm-Šídák’s multiple-comparison test. Data are presented as the mean ± SD.