Mutations in pregnancy‐associated plasma protein A2 cause short stature due to low IGF‐I availability

Mutations in multiple genes of the growth hormone/IGF‐I axis have been identified in syndromes marked by growth failure. However, no pathogenic human mutations have been reported in the six high‐affinity IGF‐binding proteins (IGFBPs) or their regulators, such as the metalloproteinase pregnancy‐associated plasma protein A2 (PAPP‐A2) that is hypothesized to increase IGF‐I bioactivity by specific proteolytic cleavage of IGFBP‐3 and ‐5. Multiple members of two unrelated families presented with progressive growth failure, moderate microcephaly, thin long bones, mildly decreased bone density and elevated circulating total IGF‐I, IGFBP‐3, and ‐5, acid labile subunit, and IGF‐II concentrations. Two different homozygous mutations in PAPPA2 , p.D643fs25* and p.Ala1033Val, were associated with this novel syndrome of growth failure. In vitro analysis of IGFBP cleavage demonstrated that both mutations cause a complete absence of PAPP‐A2 proteolytic activity. Size‐exclusion chromatography showed a significant increase in IGF‐I bound in its ternary complex. Free IGF‐I concentrations were decreased. These patients provide important insights into the regulation of longitudinal growth in humans, documenting the critical role of PAPP‐A2 in releasing IGF‐I from its BPs. Synopsis Pregnancy‐associated plasma protein‐A2 (PAPP‐A2) is a highly specific protease for the cleavage of insulin‐like growth factor (IGF)‐binding proteins. PAPP‐A2 homozygous loss‐of‐function mutations alter IGF‐I transport and cause growth defects in patients. This new syndrome of short stature is characterized by: Mild but progressive postnatal growth failure, moderate microcephaly, and decreased bone density with mild skeletal abnormalities. Elevated concentrations of circulating total IGF‐I, IGFBP‐3, and IGFBP‐5, acid labile subunit, IGF‐II, and basal insulin, with increased ternary complex formation. Very low levels of free IGF‐I and bioactive IGF. Graphical Abstract Pregnancy‐associated plasma protein‐A2 (PAPP‐A2) is a highly specific protease for the cleavage of insulin‐like growth factor (IGF)‐binding proteins. PAPP‐A2 homozygous loss‐of‐function mutations alter IGF‐I transport and cause growth defects in patients.