Human NK cell deficiency as a result of biallelic mutations in MCM10
Emily M. Mace, … , Anja K. Bielinsky, Jordan S. Orange
Emily M. Mace, … , Anja K. Bielinsky, Jordan S. Orange
Published August 31, 2020
Citation Information: J Clin Invest. 2020;130(10):5272-5286. https://doi.org/10.1172/JCI134966.
View: Text | PDF
Research Article Immunology

Human NK cell deficiency as a result of biallelic mutations in MCM10

Abstract

Human natural killer cell deficiency (NKD) arises from inborn errors of immunity that lead to impaired NK cell development, function, or both. Through the understanding of the biological perturbations in individuals with NKD, requirements for the generation of terminally mature functional innate effector cells can be elucidated. Here, we report a cause of NKD resulting from compound heterozygous mutations in minichromosomal maintenance complex member 10 (MCM10) that impaired NK cell maturation in a child with fatal susceptibility to CMV. MCM10 has not been previously associated with monogenic disease and plays a critical role in the activation and function of the eukaryotic DNA replisome. Through evaluation of patient primary fibroblasts, modeling patient mutations in fibroblast cell lines, and MCM10 knockdown in human NK cell lines, we have shown that loss of MCM10 function leads to impaired cell cycle progression and induction of DNA damage–response pathways. By modeling MCM10 deficiency in primary NK cell precursors, including patient-derived induced pluripotent stem cells, we further demonstrated that MCM10 is required for NK cell terminal maturation and acquisition of immunological system function. Together, these data define MCM10 as an NKD gene and provide biological insight into the requirement for the DNA replisome in human NK cell maturation and function.

Authors

Emily M. Mace, Silke Paust, Matilde I. Conte, Ryan M. Baxley, Megan M. Schmit, Sagar L. Patil, Nicole C. Guilz, Malini Mukherjee, Ashley E. Pezzi, Jolanta Chmielowiec, Swetha Tatineni, Ivan K. Chinn, Zeynep Coban Akdemir, Shalini N. Jhangiani, Donna M. Muzny, Asbjørg Stray-Pedersen, Rachel E. Bradley, Mo Moody, Philip P. Connor, Adrian G. Heaps, Colin Steward, Pinaki P. Banerjee, Richard A. Gibbs, Malgorzata Borowiak, James R. Lupski, Stephen Jolles, Anja K. Bielinsky, Jordan S. Orange

×

Figure 3

Independent damaging effects of R426C and R582X mutations.

Options: View larger image (or click on image) Download as PowerPoint
Independent damaging effects of R426C and R582X mutations. (A) WT MCM10-...
(A) WT MCM10-GFP or R426C MCM10-GFP constructs transiently expressed in 293T cells. GFP was immunoprecipitated and blots probed for POLA, MCM2, PCNA, CDC45. (B) Whole cell extract (WCE) of parental (WT), R426C homozygous patient mutation (R426C/R426C), and R582X heterozygous patient mutation (R582X/+) hTERT RPE-1 cell lines probed for MCM10. Data are representative of 3 technical replicates. (C) Parental (WT), R426C homozygous patient mutation (R426C/R426C), and 3 R582X heterozygous mutation clones (R582X/+ 1, 2 and 3) counted after 72 hours to calculate doubling time. Data are represented as mean ± 95% CI. n = 3–6 technical replicates. Symbols directly over bars indicate significance of mutant compared with WT. (D) γH2AX imaged by confocal microscopy. Scale bar: 10 μm. (E) Mean number of γH2AX foci counted from cells treated with 20J UV or untreated. Data are represented as mean ± 95% CI; each point represents an independent technical replicate. n = 35–68 cells per condition. *P < 0.05; **P < 0.01; ****P < 0.0001, parametric 1-way ANOVA with multiple comparisons.