Development of an RNAi therapeutic for alpha-1-antitrypsin liver disease
Christine I. Wooddell, Keith Blomenkamp, Ryan M. Peterson, Vladimir M. Subbotin, Christian Schwabe, James Hamilton, Qili Chu, Dawn R. Christianson, Julia O. Hegge, John Kolbe, Holly L. Hamilton, Maria F. Branca-Afrazi, Bruce D. Given, David L. Lewis, Edward Gane, Steven B. Kanner, Jeffrey H. Teckman
Christine I. Wooddell, Keith Blomenkamp, Ryan M. Peterson, Vladimir M. Subbotin, Christian Schwabe, James Hamilton, Qili Chu, Dawn R. Christianson, Julia O. Hegge, John Kolbe, Holly L. Hamilton, Maria F. Branca-Afrazi, Bruce D. Given, David L. Lewis, Edward Gane, Steven B. Kanner, Jeffrey H. Teckman
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Research Article Hepatology Therapeutics

Development of an RNAi therapeutic for alpha-1-antitrypsin liver disease

Abstract

The autosomal codominant genetic disorder alpha-1 antitrypsin (AAT) deficiency (AATD) causes pulmonary and liver disease. Individuals homozygous for the mutant Z allele accumulate polymers of Z-AAT protein in hepatocytes, where AAT is primarily produced. This accumulation causes endoplasmic reticulum (ER) stress, oxidative stress, damage to mitochondria, and inflammation, leading to fibrosis, cirrhosis, and hepatocellular carcinoma. The magnitude of AAT reduction and duration of response from first-generation intravenously administered RNA interference (RNAi) therapeutic ARC-AAT and then with next-generation subcutaneously administered ARO-AAT were assessed by measuring AAT protein in serum of the PiZ transgenic mouse model and human volunteers. The impact of Z-AAT reduction by RNAi on liver disease phenotypes was evaluated in PiZ mice by measuring polymeric Z-AAT in the liver; expression of genes associated with fibrosis, autophagy, apoptosis, and redox regulation; inflammation; Z-AAT globule parameters; and tumor formation. Ultrastructure of the ER, mitochondria, and autophagosomes in hepatocytes was evaluated by electron microscopy. In mice, sustained RNAi treatment reduced hepatic Z-AAT polymer, restored ER and mitochondrial health, normalized expression of disease-associated genes, reduced inflammation, and prevented tumor formation. RNAi therapy holds promise for the treatment of patients with AATD-associated liver disease. ARO-AAT is currently in phase II/III clinical trials.

Authors

Christine I. Wooddell, Keith Blomenkamp, Ryan M. Peterson, Vladimir M. Subbotin, Christian Schwabe, James Hamilton, Qili Chu, Dawn R. Christianson, Julia O. Hegge, John Kolbe, Holly L. Hamilton, Maria F. Branca-Afrazi, Bruce D. Given, David L. Lewis, Edward Gane, Steven B. Kanner, Jeffrey H. Teckman

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Figure 5

RNAi-mediated reduction of Z-AAT prevented tumor formation.

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RNAi-mediated reduction of Z-AAT prevented tumor formation. Male PiZ mic...
Male PiZ mice 64–69 weeks old were euthanized at baseline (AC) or given 16 Q2W injections of saline (DL) or 8 mg/kg ARC-AAT (MO) and euthanized at 32 weeks. (A, D, and M) PAS-D–stained liver, periportal areas indicated with dotted line; HV, hepatic vein; PV, portal vein; animal 277 in A, animal 309 in D, and animal 290 in M. (B and C) H&E-stained liver specimens from baseline animals. (B) Arrows indicate globules and cell debris surrounded by inflammatory cells in animal 277. (C) Arrowhead indicates enlarged hepatocyte with giant hyperchromic nucleus in animal 280. Arrows point to hepatocytes with normal-size nuclei. (EL) H&E-stained liver specimens from saline group mouse 309 showing globules, inflammation, and necrosis with inflammatory infiltration (arrows, E), inflammatory foreign body (arrow in F and G, arrowhead in H), and regenerative parenchymal nodule (arrows, H). (I) Liver parenchyma-adenoma interface with arrowheads pointing to hepatic adenoma and arrows pointing to preserved liver parenchyma in animal 309. (J) Liver tumor occupies most of the left lateral lobe of saline group mouse 315 liver, indicated by arrows. (K) Arrows identify the tumor-parenchyma interface and inset shows hepatic adenoma with enlarged aplastic hepatocytes and complete loss of hepatic architecture in animal 315 (L). (N and O) H&E-stained liver specimens from mice treated with ARC-AAT. (N) Arrows point to rare globules in animal 282. (O) Liver parenchyma-adenoma interface with arrowheads pointing to hepatic adenoma and arrows pointing to preserved liver parenchyma in animal 279. (P) The numbers of animals with and without tumors are shown for the 8–9 animals in each group. Scale bars: 100 μm (A, D, H, I, M, and O), 50 μm (B, E, F, L, and N), 20 μm (C and G), 1000 μm (J), 200 μm (K).