Allelic Variation of KIR and HLA Tunes the Cytolytic Payload and Determines Functional Hierarchy of NK Cell Repertoires

Overview

Journal Blood Adv

Specialty Hematology

Date 2023 Jun 16

PMID 37327114

Authors

Camille Philippon

Sudan Tao

Dennis Clement

Alvaro Haroun-Izquierdo

Katherine M Kichula

Herman Netskar

Ludwig Brandt

Vincent Sheng Oei

Minoru Kanaya

Pilar Maria Lanuza

Marie Schaffer

Jodie P Goodridge

Amir Horowitz

Faming Zhu

Quirin Hammer

Ebba Sohlberg

Rakesh Kumar Majhi

Lise Kveberg

Bjorn Onfelt

Paul J Norman

Karl-Johan Malmberg

Affiliations

Soon will be listed here.

Abstract

The functionality of natural killer (NK) cells is tuned during education and is associated with remodeling of the lysosomal compartment. We hypothesized that genetic variation in killer cell immunoglobulin-like receptor (KIR) and HLA, which is known to influence the functional strength of NK cells, fine-tunes the payload of effector molecules stored in secretory lysosomes. To address this possibility, we performed a high-resolution analysis of KIR and HLA class I genes in 365 blood donors and linked genotypes to granzyme B loading and functional phenotypes. We found that granzyme B levels varied across individuals but were stable over time in each individual and genetically determined by allelic variation in HLA class I genes. A broad mapping of surface receptors and lysosomal effector molecules revealed that DNAM-1 and granzyme B levels served as robust metric of the functional state in NK cells. Variation in granzyme B levels at rest was tightly linked to the lytic hit and downstream killing of major histocompatibility complex-deficient target cells. Together, these data provide insights into how variation in genetically hardwired receptor pairs tunes the releasable granzyme B pool in NK cells, resulting in predictable hierarchies in global NK cell function.

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