Partial MCM4 deficiency in patients with growth retardation, adrenal insufficiency, and natural killer cell deficiency
Laure Gineau, … , Jean-Laurent Casanova, Emmanuelle Jouanguy
Laure Gineau, … , Jean-Laurent Casanova, Emmanuelle Jouanguy
Published February 22, 2012
Citation Information: J Clin Invest. 2012;122(3):821-832. https://doi.org/10.1172/JCI61014.
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Research Article

Partial MCM4 deficiency in patients with growth retardation, adrenal insufficiency, and natural killer cell deficiency

Abstract

Natural killer (NK) cells are circulating cytotoxic lymphocytes that exert potent and nonredundant antiviral activity and antitumoral activity in the mouse; however, their function in host defense in humans remains unclear. Here, we investigated 6 related patients with autosomal recessive growth retardation, adrenal insufficiency, and a selective NK cell deficiency characterized by a lack of the CD56dim NK subset. Using linkage analysis and fine mapping, we identified the disease-causing gene, MCM4, which encodes a component of the MCM2-7 helicase complex required for DNA replication. A splice-site mutation in the patients produced a frameshift, but the mutation was hypomorphic due to the creation of two new translation initiation methionine codons downstream of the premature termination codon. The patients’ fibroblasts exhibited genomic instability, which was rescued by expression of WT MCM4. These data indicate that the patients’ growth retardation and adrenal insufficiency likely reflect the ubiquitous but heterogeneous impact of the MCM4 mutation in various tissues. In addition, the specific loss of the NK CD56dim subset in patients was associated with a lower rate of NK CD56bright cell proliferation, and the maturation of NK CD56bright cells toward an NK CD56dim phenotype was tightly dependent on MCM4-dependent cell division. Thus, partial MCM4 deficiency results in a genetic syndrome of growth retardation with adrenal insufficiency and selective NK deficiency.

Authors

Laure Gineau, Céline Cognet, Nihan Kara, Francis Peter Lach, Jean Dunne, Uma Veturi, Capucine Picard, Céline Trouillet, Céline Eidenschenk, Said Aoufouchi, Alexandre Alcaïs, Owen Smith, Frédéric Geissmann, Conleth Feighery, Laurent Abel, Agata Smogorzewska, Bruce Stillman, Eric Vivier, Jean-Laurent Casanova, Emmanuelle Jouanguy

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Figure 3

Characterization of the MCM4 isoforms detected in the cells of the patient tested.

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Characterization of the MCM4 isoforms detected in the cells of the patie...
Reinitiation of MCM4 protein translation. (A) Schematic diagram of the two potential reinitiation sites after the premature STOP codon and the corresponding isoforms of MCM4. Two ATG codons, at positions 51 and 75, are in the same open reading frame as the premature stop codon, leading to the production of two new isoforms, of 813 and 789 amino acids, respectively. The 5′ part of the MCM4 sequence is enlarged (×6) and shown at greater magnification than the 3′ part of the MCM4 sequence (×1). The two variants of MCM4 mRNA from the NCBI database are shown (NM 005914.3 and NM 182746.2). (B) MCM4 protein levels, in HEK293T cells, following transient transfection with a C-terminal Flag-tagged pCMV6 empty vector or pCMV6 MCM4 WT, pCMV6 MCM4 MUT, pCMV6 MCM4 MUT-ATG1, pCMV6 MCM4 MUT-ATG2, pCMV6 MCM4 MUT-ATG1+2, pCMV6 MCM4-ATG1, and pCMV6 MCM4-ATG1+2 vectors, were assessed by Western blotting of total protein extracts from each transfection with antibodies against Flag and against the MCM4 protein. Total protein extracts from non-transfected control SV40 fibroblast (SV40-Fib) cell lines from a control and patient P2.1 were used as a positive control. An antibody against β-actin was used as a loading control.