Proteinuria in cubilin-deficient patients with selective vitamin B12 malabsorption.

Selective vitamin B(12) malabsorption or Gräsbeck-Imerslund disease (megaloblastic anemia 1) is frequently accompanied by proteinuria. The malabsorption-proteinuric syndrome of Finnish patients is caused by a defect in the multiligand receptor cubilin. We studied the urinary proteins of control subjects and 13 adult patients with three defined cubilin mutations (FM1, FM2, FM3), all diagnosed during childhood and subsequently observed. The overall kidney function was unimpaired and did not deteriorate with time. The excretion of total protein and albumin, and to lesser extent of transferrin, immunoglobulin light chains, and alpha(1)- and beta(2)-microglobulins, was clearly elevated in 3 patients, mildly elevated in 3, and hardly or not at all increased in the rest. The urinary cobalamin-intrinsic factor receptor was low in 5 patients studied and lowest in the group with clear-cut proteinuria. The proteinuria was not of the classical glomerular or tubular type, but apparently due to the lack of cubilin function needed for tubular reabsorption of some, but not all, proteins of the primary urine.

Amnionless, essential for mouse gastrulation, is mutated in recessive hereditary megaloblastic anemia.

The amnionless gene, Amn, on mouse chromosome 12 encodes a type I transmembrane protein that is expressed in the extraembryonic visceral layer during gastrulation. Mice homozygous with respect to the amn mutation generated by a transgene insertion have no amnion. The embryos are severely compromised, surviving to the tenth day of gestation but seem to lack the mesodermal layers that normally produce the trunk. The Amn protein has one transmembrane domain separating a larger, N-terminal extracellular region and a smaller, C-terminal cytoplasmic region. The extracellular region harbors a cysteine-rich domain resembling those occurring in Chordin, found in Xenopus laevis embryos, and Sog, found in Drosophila melanogaster. As these cysteine-rich domains bind bone morphogenetic proteins (Bmps), it has been speculated that the cysteine-rich domain in Amn also binds Bmps. We show that homozygous mutations affecting exons 1-4 of human AMN lead to selective malabsorption of vitamin B12 (a phenotype associated with megaloblastic anemia 1, MGA1; OMIM 261100; refs. 5,6) in otherwise normal individuals, suggesting that the 5' end of AMN is dispensable for embryonic development but necessary for absorption of vitamin B12. When the 5' end of AMN is truncated by mutations, translation is initiated from alternative downstream start codons.