Expression of Three Clones of PD-L1 in Lung Cancer: A Single-center Experience

Discussion

Cancer immune surveillance is thought to be an important host-protective process that prevents cancer development and maintains cellular homeostasis (14). In the body’s immune system, T cells are activated by recognizing the MHC-antigen complex through T cell receptors and regulating T cell activation through the regulation of co-stimulatory and co-inhibitory signals (15). However, in cancer cells, the immune evasion mechanism is activated, which defends against the immune attack of T cells by expressing a protein that prevents the destruction of cancer cells (14). Historically, lung cancer was considered non-immunogenic due to loss of tumor antigens, loss of sensitivity to complement, and lysis of T cells and natural killer cells (16). However, recent studies have shown that lung cancers can develop mechanisms that evade the attention of the immune system for development and progression (17), such as the loss of MHC antigen expression, secretion of immunosuppressive cytokines, induction of immunosuppressive T cells, and failure of immune competence due to the disease itself or treatment in the later stages of the disease (18). Finally, a complex set of immune checkpoint regulators appears to be important for fine-tuning the immune response, a process that tumors may adopt to protect against immune attacks (18).

One of the first inhibitory immune checkpoints targeted was cytotoxic T lymphocyte-associated protein 4 (CTLA-4), an immune checkpoint receptor expressed on the surface of T cells interacting with B7 molecules on the APCs as ligands (18). However, recently, much attention has been paid to how this interaction is blocked in lung cancers such as NSCLC by immunomodulatory therapies, such as PD-1 and its ligand PD-L1, and therapeutic monoclonal antibodies specific for PD-1 or PD-L1 (19).

Cancer cells express PD-L1 as a cell surface protein, which binds to PD-1 expressed on T cells and suppresses the antitumor immunity of T cells (15). Immunotherapy induces immune cells to selectively attack cancer cells by injecting artificial immune proteins, including ICIs (CTLA-4, PD-1, and PD-L1 inhibitors), immune cell therapy agents, and immune virus therapeutic agents, into the body to stimulate the immune system. Immune anticancer drugs improve the side effects of first-generation anticancer drugs and overcome the resistance to second-generation targeted anticancer drugs (15, 20). Owing to these advantages, interest in immunotherapy is increasing, and after the autologous tumor vaccine Provenge^® (Sipuleucel-T) was approved as a treatment for prostate adenocarcinoma in 2010, several drugs that suppress immune checkpoints have been approved (15).

Recently, to target the PD-1/PD-L1 signaling pathway, PD-1 and PD-L1 inhibitors have been developed and approved to induce T-cell apoptosis against cancer cells (21). Keytruda^® (pembrolizumab), the first PD-1 inhibitor approved by the US Food and Drug Administration (FDA) in 2014, was approved for the treatment of metastatic melanoma and NSCLC in 2015 (22). In Korea, it has been approved for the treatment of metastatic melanoma, NSCLC, lymphoma, squamous cell carcinoma (SqCC) of the head and neck, and urothelial cancer (UC) (23). Opdivo^® (nivolumab) was approved by the US FDA in 2015 as an inhibitor of PD-1 (22). In Korea, it has since been approved for the treatment of metastatic melanoma, NSCLC, lymphoma, SqCC of the head and neck, and UC (23).

Following the development of PD-1 inhibitors, inhibitors of PD-L1 expression in cancer cells have also been developed. The first PD-L1 inhibitor, Tecentriq^® (atezolizumab), was approved by the US FDA in 2016 (22). In 2017, it was approved for the treatment of locally advanced or metastatic NSCLC and UC in Korea (23). In the same year, a second PD-L1 inhibitor, Imfinzi^® (durvalumab), was approved by the FDA for the treatment of severe bladder cancer that progresses after surgery or chemotherapy (22). These immunotherapeutic agents that inhibit the interaction between PD-1 of immune cells and PD-L1 in cancer cells have obtained good clinical results for the treatment of early melanoma, and the indications are expanding to various cancer treatments, such as lymphoma (20).

The assessment of PD-L1 expression is now routinely used in clinical practice, but it is not a simple task as PD-L1 exhibits intratumoral heterogeneity (24). IHC for detecting protein activity can be influenced by the selection of various factors, including primary antibody clones, detection systems, and platforms involving complex biochemistry (24). It is important to select the correct cutoff level to define the PD-L1 (+) and PD-L1 (−) groups (24).

Pathologists must understand the unique nature of the PD-L1 test to correctly interpret PD-L1 IHC results and communicate with clinicians to recommend the most effective treatment options (24). Currently, three commercially available antibodies are available at our institution for measuring PD-L1 protein expression in FFPE lung tissue specimens (SP263, SP142, and 22C3 assays). Each assay uses different automated staining systems, detection systems, and assessment means and thresholds to determine positive PD-L1 protein expression. The 22C3 pharmDx assay has been developed for use on the Dako platform, whereas SP263 and SP142 use the Ventana BenchMark platforms, which are more common in pathology laboratories. Regarding the interpretation of PD-L1 staining, in the 22C3PharmDx assay, complete circumferential or partial linear membrane staining of cancer cells, regardless of staining intensity, is considered positive. In the SP263 and SP142 assays, any membranous and/or cytoplasmic expression in cancer cells is considered positive (24). In the SP142 analysis, expression in immune and cancer cells is included as a positive criterion.

There are many issues related to the interpretation of PD-L1, which are important for pathologists, such as distinguishing the immunoreactivity of tumor cells from that of inflammatory cells, the localization of immunostaining (membrane or cytoplasm), and the scoring of expression percentages, particularly around the thresholds of clinical significance, regardless of the assay type (24). Additionally, each assay has a specific cutoff value for positive tumor cells, and even the same drug may have different percentages depending on whether it is a first-line, second-line, or add-on treatment. In addition, when an assay is applied for two-drug prescriptions, such as SP263, different cutoffs may be applied depending on the drug (durvalumab and nivolumab) (24). Pathologists should also pay close attention to insurance policies related to PD-L1 testing, as these inconsistent cutoffs have not been proven in clinical trials and are a special circumstance related to Korea’s national insurance (24).

Several international projects have been initiated to standardize various PD-L1 assays, and among them, the result of the Blueprint project led by “the International Association for the Study of Lung Cancer”is attracting attention.

In this study, clones SP263, 22C3PharmDx, and 28-8 showed high agreement in the staining ratio of tumor cells regardless of the staining intensity. Conversely, when the SP142 clone was used, low expression of PD-L1 was observed in tumor cells (25). In the present study, we analyzed PD-L1 expression and clinical characteristics of Korean patients with NSCLC. Of the 76 patients whose samples were evaluated for PD-L1 using the IHC 22C3 pharmDx assay, 19 (25.0%) had a PD-L1 TPS of ≥50%, and 41 (53.9%) had a PD-L1 TPS of ≥1%. Using SP263, 48.7% had a TPS of ≥1% and 18.4% had a TPS of >50%. The SP142 assay was evaluated for TC and IC. Twenty (26.3%) cases were positive for TC and 25 (32.9%) were reactive for IC.

The interpretation and reporting format for PD-L1 IHC analysis in lung cancer are different from those of conventional IHC assays, in that each assay should be interpreted according to the relevant criteria for each drug. Therefore, specialized training programs for pathologists are required to maintain consistency and quality of interpretation (24). Moreover, closer collaboration between oncologists and pathologists is needed to ensure that each patient receives the most appropriate treatment.