LILRB3 (ILT5) is a myeloid cell checkpoint that elicits profound immunomodulation
Muchaala Yeboah, Charys Papagregoriou, Des C. Jones, H.T. Claude Chan, Guangan Hu, Justine S. McPartlan, Torbjörn Schiött, Ulrika Mattson, C. Ian Mockridge, Ulla-Carin Tornberg, Björn Hambe, Anne Ljungars, Mikael Mattsson, Ivo Tews, Martin J. Glennie, Stephen M. Thirdborough, John Trowsdale, Björn Frendeus, Jianzhu Chen, Mark S. Cragg, Ali Roghanian
Muchaala Yeboah, Charys Papagregoriou, Des C. Jones, H.T. Claude Chan, Guangan Hu, Justine S. McPartlan, Torbjörn Schiött, Ulrika Mattson, C. Ian Mockridge, Ulla-Carin Tornberg, Björn Hambe, Anne Ljungars, Mikael Mattsson, Ivo Tews, Martin J. Glennie, Stephen M. Thirdborough, John Trowsdale, Björn Frendeus, Jianzhu Chen, Mark S. Cragg, Ali Roghanian
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Research Article Immunology

LILRB3 (ILT5) is a myeloid cell checkpoint that elicits profound immunomodulation

Abstract

Despite advances in identifying the key immunoregulatory roles of many of the human leukocyte immunoglobulin-like receptor (LILR) family members, the function of the inhibitory molecule LILRB3 (ILT5, CD85a, LIR3) remains unclear. Studies indicate a predominant myeloid expression; however, high homology within the LILR family and a relative paucity of reagents have hindered progress toward identifying the function of this receptor. To investigate its function and potential immunomodulatory capacity, a panel of LILRB3-specific monoclonal antibodies (mAbs) was generated. LILRB3-specific mAbs bound to discrete epitopes in Ig-like domain 2 or 4. LILRB3 ligation on primary human monocytes by an agonistic mAb resulted in phenotypic and functional changes, leading to potent inhibition of immune responses in vitro, including significant reduction in T cell proliferation. Importantly, agonizing LILRB3 in humanized mice induced tolerance and permitted efficient engraftment of allogeneic cells. Our findings reveal powerful immunosuppressive functions of LILRB3 and identify it as an important myeloid checkpoint receptor.

Authors

Muchaala Yeboah, Charys Papagregoriou, Des C. Jones, H.T. Claude Chan, Guangan Hu, Justine S. McPartlan, Torbjörn Schiött, Ulrika Mattson, C. Ian Mockridge, Ulla-Carin Tornberg, Björn Hambe, Anne Ljungars, Mikael Mattsson, Ivo Tews, Martin J. Glennie, Stephen M. Thirdborough, John Trowsdale, Björn Frendeus, Jianzhu Chen, Mark S. Cragg, Ali Roghanian

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Figure 1

Generation of fully human mAbs against LILRB3.

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Generation of fully human mAbs against LILRB3. (A) Schematic of antibody...
(A) Schematic of antibody generation by phage-display via 3 independent “panning” techniques; (i) immobilized target (LILRB3), (ii) biotinylated target and excess nontarget (LILRB1), and (iii) LILRB3-transfected cell lines (from left to right). Biopanning was performed against generated target protein using an scFv library; “nontarget” cross-reactive scFv clones were removed by competition, and target-specific scFv clones were then eluted and converted to a soluble format, sequenced, and screened by various cell- and protein-based assays. (B and C) Screening of generated LILRB3 clones. (B) FMAT and (C) ELISA were performed and scFv clones screened against LILRB3 target– and LILRB1/LILRB2 nontarget–transfected CHO-S cells and extracellular LILRB1 protein, respectively. The relative binding to each target was calculated, with target-specific scFv clones depicted in yellow and the irrelevant isotype control shown in green. Nonbinding and cross-reactive scFv clones depicted in blue. (D) Screening of LILRB3 scFv clones by high-throughput flow cytometry. PBMCs (left plot) or LILR-transfected CHO-S (middle plot) cells were incubated with His-tagged scFv supernatants, followed by secondary anti-His staining. Where transfected CHO-S cells were used, LILRB1- and LILRB2-transfected cells were used as nontargets for LILRB3. Clones were compared against both gated CD14+ monocytes and target-transfected CHO-S cells (right plot). LILRB3-specific clones highlighted in yellow, nonspecific or nonbinding clones in red, and isotype control in green. (E) Specificity of LILRB3 clones against human LILR-transfected 2B4 cells. LILRB3 mAbs were tested against cells stably transfected with the indicated LILR family members by flow cytometry; a representative specific clone (A16; top panel) and a nonspecific cross-reactive clone (A30; bottom panel) are shown. (FG) Testing the specificity of directly fluorochrome-labeled LILRB3 clones against primary cells by flow cytometry. (F) Fresh whole peripheral blood stained with either APC-labeled LILRB3 (represented by clone A16) or an irrelevant human (h) IgG1 isotype control as well as various leukocyte surface markers, as indicated. Dot plots and histograms are representative of multiple donors indicating gating of each leukocyte subset as indicated: T cells, B cells, NK cells, monocytes, and granulocytes. (G) Graph showing relative expression of LILRB3 on each leukocyte subset. One-way ANOVA test performed (*P < 0.05; **P < 0.005); n = 5 independent donors (each color represents an individual donor). (EF) Histogram pink and blue traces indicate staining with irrelevant isotype control or LILRB3 mAb, respectively.