A hypomorphic Mpi mutation unlocks an in vivo tool for studying global N-glycosylation deficiency
Elisa B. Lin, Steve Meregini, Zhao Zhang, Avishek Roy, Tandav Argula, James M. Mitchell, William J. Israelsen, Sara Ludwig, Jamie Russell, Jiexia Quan, Sara Hildebrand, Evan Nair-Gill, Bruce Beutler, Jeffrey A. SoRelle
Elisa B. Lin, Steve Meregini, Zhao Zhang, Avishek Roy, Tandav Argula, James M. Mitchell, William J. Israelsen, Sara Ludwig, Jamie Russell, Jiexia Quan, Sara Hildebrand, Evan Nair-Gill, Bruce Beutler, Jeffrey A. SoRelle
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Research Article Gastroenterology Genetics

A hypomorphic Mpi mutation unlocks an in vivo tool for studying global N-glycosylation deficiency

Abstract

Glycans are one of the 4 major macromolecules essential for life and are the most abundant family of organic molecules. However, in contrast with DNA and RNA, glycan structures have no template; this results in limited tools to study this challenging macromolecule with a diversity of glycan structures. A central bottleneck in studying glycosylation in vivo is that inhibitors and complete KOs are lethal. In a forward genetic screen, we identified a viable, hypomorphic mutation at a conserved site in mannose phosphate isomerase (Mpi) that causes a multisystemic phenotype affecting RBCs, liver, stomach, intestines, skin, size, fat, and fluid balance in mice. The phenotype could be rescued with mannose. Analyses of glycopeptides in mice with this mutation showed a 500% increase in unoccupied N-glycan sites. This is equivalent to a “glycan knockdown,” which would be useful for examining the role of glycans in biology and disease. Therefore, we report an in vivo tool to study global N-glycosylation deficiency with tissue-specific targeting and a rescue mechanism with mannose.

Authors

Elisa B. Lin, Steve Meregini, Zhao Zhang, Avishek Roy, Tandav Argula, James M. Mitchell, William J. Israelsen, Sara Ludwig, Jamie Russell, Jiexia Quan, Sara Hildebrand, Evan Nair-Gill, Bruce Beutler, Jeffrey A. SoRelle

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Figure 4

Mpi deficiency causes a microcytic, hypochromic iron deficiency anemia due to causes extrinsic to hematopoietic cells.

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Mpi deficiency causes a microcytic, hypochromic iron deficiency anemia ...
(A) Serum iron was measured by the VITROS 350 System in Mpi+/+ and Mpiben/ben mice (n = 18, 8). (B) RBC indices included RBC count, hemoglobin (Hgb), mean corpuscular volume (MCV), and mean corpuscular hemoglobin content (MCHC) in Mpi+/+ and Mpiben/ben mice (n = 4, 9). (C) Reciprocal BM chimeras between CD45.1 (black) and Mpiben/ben (red) mice (n = 4, 7) were performed by transplanting BM into lethally irradiated mice (lightning symbol). (D) RBC number, Hgb, MCV, and MCHC of CD45.1 mice transplanted with Mpiben/ben BM (black and white circles: n = 4) or Mpiben/ben mice transplanted with CD45.1 BM (red and black circle: n = 7). Data were combined from 2 experiments (A) or 1 experiment (BD). Data points represent individual mice. Error bars indicate SD. P values were determined by Student’s t test (A, B, and D). *P < 0.05, **P < 0.01, ***P < 0.001, ****P < 0.0001.