Partial loss-of-function mutations in GINS4 lead to NK cell deficiency with neutropenia
Matilde I. Conte, M. Cecilia Poli, Angelo Taglialatela, Giuseppe Leuzzi, Ivan K. Chinn, Sandra A. Salinas, Emma Rey-Jurado, Nixa Olivares, Liz Veramendi-Espinoza, Alberto Ciccia, James R. Lupski, Juan Carlos Aldave Becerra, Emily M. Mace, Jordan S. Orange
Matilde I. Conte, M. Cecilia Poli, Angelo Taglialatela, Giuseppe Leuzzi, Ivan K. Chinn, Sandra A. Salinas, Emma Rey-Jurado, Nixa Olivares, Liz Veramendi-Espinoza, Alberto Ciccia, James R. Lupski, Juan Carlos Aldave Becerra, Emily M. Mace, Jordan S. Orange
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Research Article Cell biology Immunology

Partial loss-of-function mutations in GINS4 lead to NK cell deficiency with neutropenia

Abstract

Human NK cell deficiency (NKD) is a primary immunodeficiency in which the main clinically relevant immunological defect involves missing or dysfunctional NK cells. Here, we describe a familial NKD case in which 2 siblings had a substantive NKD and neutropenia in the absence of other immune system abnormalities. Exome sequencing identified compound heterozygous variants in Go-Ichi-Ni-San (GINS) complex subunit 4 (GINS4, also known as SLD5), an essential component of the human replicative helicase, which we demonstrate to have a damaging impact upon the expression and assembly of the GINS complex. Cells derived from affected individuals and a GINS4-knockdown cell line demonstrate delayed cell cycle progression, without signs of improper DNA synthesis or increased replication stress. By modeling partial GINS4 depletion in differentiating NK cells in vitro, we demonstrate the causal relationship between the genotype and the NK cell phenotype, as well as a cell-intrinsic defect in NK cell development. Thus, biallelic partial loss-of-function mutations in GINS4 define a potentially novel disease-causing gene underlying NKD with neutropenia. Together with the previously described mutations in other helicase genes causing NKD, and with the mild defects observed in other human cells, these variants underscore the importance of this pathway in NK cell biology.

Authors

Matilde I. Conte, M. Cecilia Poli, Angelo Taglialatela, Giuseppe Leuzzi, Ivan K. Chinn, Sandra A. Salinas, Emma Rey-Jurado, Nixa Olivares, Liz Veramendi-Espinoza, Alberto Ciccia, James R. Lupski, Juan Carlos Aldave Becerra, Emily M. Mace, Jordan S. Orange

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Figure 5

Individual-derived BLCLs do not show increased DNA damage or replication fork aberrations.

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Individual-derived BLCLs do not show increased DNA damage or replication...
(A) Representative imaging flow cytometry images of individual II.1 and HD; DAPI (left), bright-field (center), and γH2aX (right) are shown. (B) Relative percentage of individuals’ cells with low foci count (1–3 foci) and high foci count (4–10 foci) compared with HD. Data show the mean ± range of 2 independent experiments. For each experiment, 5,000 cells were analyzed. (C) Relative percentage of individuals’ cells with low foci area (0.5–1.5 μm) and high foci area (>1.5 µm) compared with 1 HD. Data show mean ± range of 2 independent experiments. For each experiment, 5,000 cells were analyzed. (D) Analysis of fork symmetry in the indicated individual-derived BLCLs. A schematic representation of symmetric and asymmetric forks is shown. The graph shows the length of the left fork (x axis) plotted against the length of the right fork (y axis) for each replication origin (indicated with dot). The fork was considered asymmetric if the ratio between the left-fork length and the right-fork length deviated by more than 25% from 1. N represents the number of forks analyzed in 2 independent biological replicates. R represents the linear correlation coefficient. (E) Analysis of fork speed in the indicated individual-derived BLCLs. Dot plot graphs with the median of IdU tract lengths (μm) are shown and individual points are derived from 2 independent experiments. P ≥ 0.05 by Mann-Whitney U test.