Journal List > Immune Netw > v.20(1) > 1148280

Kim, Kim, and Shin: Peripheral Blood Immune Cell-based Biomarkers in Anti-PD-1/PD-L1 Therapy

Abstract

Immune checkpoint blockade targeting PD-1 and PD-L1 has resulted in unprecedented clinical benefit for cancer patients. Anti-PD-1/PD-L1 therapy has become the standard treatment for diverse cancer types as monotherapy or in combination with other anti-cancer therapies, and its indications are expanding. However, many patients do not benefit from anti-PD-1/PD-L1 therapy due to primary and/or acquired resistance, which is a major obstacle to broadening the clinical applicability of anti-PD-1/PD-L1 therapy. In addition, hyperprogressive disease, an acceleration of tumor growth following anti-PD-1/PD-L1 therapy, has been proposed as a new response pattern associated with deleterious prognosis. Anti-PD-1/PD-L1 therapy can also cause a unique pattern of adverse events termed immune-related adverse events, sometimes leading to treatment discontinuation and fatal outcomes. Investigations have been carried out to predict and monitor treatment outcomes using peripheral blood as an alternative to tissue biopsy. This review summarizes recent studies utilizing peripheral blood immune cells to predict various outcomes in cancer patients treated with anti-PD-1/PD-L1 therapy.

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Table 1.
Summary of relevant biomarker studies predicting treatment response and prognosis
Biomarker Cancer type No. of patients Main results Reference
(%Ki-67+ cells/PD-1+ CD8+ T cells 3-wk post-treatment)/baseline Melanoma Discovery cohort: 23 Higher Ki67/TB significantly associated with superior ORR (p=0.03) and PFS (p=0.004). Huang et al. (34)
tumor burden (Ki67/TB)   Validation cohort: 18 Higher Ki67/TB associated with superior ORR (p=0.14) and PFS (p=0.06).  
(%Ki-67+ cells/PD-1+ CD8+ T cells 1-wk post-treatment)/(%Ki-67+ cells/PD-1+ CD8+ T cells at TET Discovery cohort: 31 Higher Ki-67 D7/D0 significantly associated with durable clinical benefit (PR, or SD for 6 months or longer; p<0.001) and PFS (p=0.027) Kim et al. (32)
baseline) (Ki-67 D7/D0) NSCLC Discovery cohort: 33 Higher Ki-67 D7/D0 significantly associated with durable clinical benefit (PR, or SD for 6 months or longer; p<0.01), PFS (p=0.004), and OS (p=0.001)  
    Validation cohort: 46 Higher Ki-67 D7/D0 significantly associated with durable clinical benefit (PR, or SD for 6 months or longer; p<0.01), PFS (p=0.002), and OS (p=0.037)  
%FoxP3 PD-1 hi CD4+ T cells/ CD4+ T cells (4PD1 hi) 3-wk post-treatment Fold change of 4PD1hi Melanoma 52 Higher frequency of 4PD1 hi 3-wks post treatment (p=0.0005) and fold change of 4PD1 hi (p=0.046) associated with poorer OS. Zappasodi et al. (36)
TCR diversity of PD-1+ CD8+ T cells at baseline and post-treatment NSCLC Discovery cohort: 25 Validation cohort: 15 Higher baseline diversity in PD-1+ CD8+ T cells (p=0.021) and increased clonality after treatment (p=0.002) associated with superior PFS. Han et al. (39)
%CD27 CD28 cells/CD4+ T cells at baseline NSCLC 51 Higher frequency of CD27 CD28 CD4+ T cells associated superior PFS (p=0.001). Zuazo et al. (42)
Ratio of the frequency of Treg cells and PMN-MDSCs at baseline NSCLC Discovery cohort: 34 Validation cohort: 29 Higher ratio of the frequency of Treg cells and PMN-MDSCs associated with superior PFS (p=0.0079). Higher ratio of the frequency of Treg cells and PMN-MDSCs associated with superior PFS (p=0.0017). Kim et al. (44)
%Effector/memory (CCR7 CD45RA) cells/CD8+ T cells at baseline NSCLC 263 (flow cytometry analysis in 144) Lower frequency of effector/memory CD8+ T cells with development of hyperprogressive disease (p<0.001) and poor PFS (p<0.001) and OS (p<0.001). Kim et al. (53)
%TIGIT+ cells/PD-1+ CD8+ T cells at baseline     Higher frequency of TIGIT+ cells among PD-1+ CD8+ T cells in peripheral blood at baseline significantly associated with development of hyperprogressive disease (p<0.001) and poor PFS (p<0.001) and OS (p=0.01).  

NSCLC, non-small-cell lung cancer; ORR, objective response rate; OS, overall survival; PFS, progression-free survival; PR, partial response; SD, stable disease; TET, thymic epithelial tumor; CCR7, C-C chemokine receptor type 7.

Table 2.
Summary of relevant biomarker studies predicting irAEs
Biomarker Cancer type No. of patients Main results Reference
Fold change of effector Treg cells 1-wk post-treatment Th17 to Th1 ratio at baseline %Ki-67+/PD-1+CD8+ T cells 1-wk post-treatment %TNF-α+/CD4+ or CD8+ T cells 1-wk post-treatment TET NSCLC 31
60
Patients with irAEs can be distinguished into 4 distinct subtypes according to the T-cell parameters and each T-cell parameter predicts the corresponding subtype of irAEs Kim et al. (63)
Memory cytotoxic (CD45RO+ GzmB+ Ki-67+) CD4+ T cells Melanoma 3 Activated memory CD4+ T cells were highly enriched in inflammed, affected region of cases with encephalitis. Johnson et al. (68)
Early B cell changes (decline in B cells, increase in CD21 lo B cells) Melanoma 23 Decline in B cells but an increase in CD21 lo B cells more prominent in patients with severe irAEs that received combined anti-PD-1 and anti-CTLA-4 Das et al. (72)
Cytokine expression-based score Melanoma Discovery cohort: 98 Eleven cytokines were integrated into a single score (CYTOX) and it significantly predicted development of severe irAEs in patients treated with combined anti-PD-1 and anti-CTLA-4. Lim et al. (77)
    Validation cohort: 49 CYTOX score significantly predicted development of severe irAEs.  
Auto-Abs (rheumatoid factor, antinuclear Ab, antithyroglobulin, and antithyroid peroxidase) NSCLC 137 Preexisting rheumatoid factor or auto-Abs significantly correlates with development of any grade irAEs Toi et al. (75)
Anti-thyroid Abs (anti-microsomal and anti-thyroglobulin) NSCLC 51 Presence of anti-thyroid Abs either at baseline or during anti-PD-1 treatment was significantly associated with thyroid dysfunction Osorio et al. (76)

NSCLC, non-small-cell lung cancer; TET, thymic epithelial tumor.

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