Biomarkers for immunotherapy in non-small cell lung cancer: a current and future reality

Immunotherapy has now become one of the mainstays in the treatment of non-small cell lung cancer (NSCLC). Immunotherapy based on immune checkpoint inhibitors (ICIs) has become a standard for treatment at all stages, ranging from neoadjuvant or adjuvant to advanced stages (Table 1) (1). One of the main problems encountered in clinical practice in recent years since the development of immunotherapy in NSCLC and other solid tumours is the poor prediction of response to these treatments. Different biomarkers have been validated as predictors of immunotherapy in NSCLC, however, only two have demonstrated validity and clinical applicability, namely programmed death-ligand 1 (PD-L1) and tumour mutational burden (TMB) (2). Another biomarker that is not as well known (although it has been described in multiple studies), and which is fundamental in NSCLC, is the patient’s general condition measured by different scales, which marks with a high probability the possibility of response to immunotherapy in NSCLC (3).

PD-L1 and TMB

The best known and validated of all biomarkers is undoubtedly PD-L1. This molecule is the ligand of the programmed death-1 (PD-1) receptor, whose alterations are one of the most important immune evasion mechanisms (4). Different studies have validated its applicability in NSCLC, being the only biomarker, whose value so far implies changes in NSCLC therapeutics (5). Even though a high value implies a higher probability of response to ICIs, multiple obstacles have been found in its applicability that have hindered its value as a biomarker. The main one is that PD-L1 expression is heterogeneous at the tumour level, so its value depends on the tumour site analysed. Furthermore, the methods of evaluation also differ depending on the pharmaceutical company that developed it, which makes its interpretation even more complex. Nevertheless, high PD-L1 values, especially above 50%, imply a very high probability of response to immunotherapy in NSCLC, which is why, despite its limitations, it is now considered a powerful predictive biomarker in NSCLC (6). In addition, the value of amplification of the PD-L1 gene found in the 9p24.1 region of the genome as a biomarker is under investigation due to the development of molecular diagnostic methods (7,8).

Along with PD-L1, the other validated predictive biomarker, although less applicable in clinical practice, is TMB. The accumulation of the number of mutations in the tumour leads to a greater genesis of neoantigens, so the action of the immune system and immunotherapy on these tumours is greater (9). Among the tumours with the highest mutational burden, the two with the highest TMB are melanoma and NSCLC, which has led to higher TMB being a strong predictor of greater response to immunotherapy. The main study that has validated this biomarker in NSCLC is the CheckMate227 clinical trial (10). In this study in patients with NSCLC and high TMB (≥10 mutations/megabase), the Nivolumab-Ipilimumab combination had a progression-free survival (PFS) of 7.2 months versus chemotherapy of 5.5 months [hazard ratio (HR) 0.58; P<0.001]. Thus, although its clinical applicability is currently low, it is a promising biomarker with important applications.

Performance status

The patient’s general condition is key in clinical practice. In many cases of NSCLC, the need for a response due to the high symptomatology of the patients makes it necessary to consider chemotherapy treatments in the search for a high response, regardless of other values such as PD-L1. The latency in the appearance of response with immunotherapy means that the probability of response to immunotherapy is lower in patients with poor general condition (11). The absence of immediate cytotoxicity on the tumour means that the response to ICIs in the different clinical trials takes about three months, so it is important to take this biomarker into account when making decisions. Therefore, measuring general condition using different scales such as the Karnofsky or Eastern Cooperative Oncology Group (ECOG) scales is a predictive biomarker that is possibly more predictive than others such as PD-L1 (12).

Biomarkers in development

In addition to the above, there are other biomarkers that, although they have not been validated, have a very promising future and are currently under investigation. Probably, due to their importance in other tumours, alterations in the mismatch repair (MMR) system are one of the most promising biomarkers in NSCLC. It is estimated that about 4–5% of NSCLC have MMR system alterations, although these values can vary up to 8–10% (13). The value of these MMR system genes (MLH1, MSH2, MSH6 and PMS2) as predictive biomarkers in solid tumours is already known, especially in tumours of gastrointestinal origin. Several studies have investigated their association with immunotherapy in NSCLC, showing a greater benefit of immunotherapy in NSCLC with MMR alterations in terms of both response and survival (14,15). However, their use in these tumours has not been validated, so their value is still in the preclinical stages.

Along with all the biomarkers mentioned above, there are several other biomarkers which are in different stages of development and which to date have shown promising results. One of the most interesting is the microbiome, understood as the set of micro-organisms living in a particular environment (16). In the case of the gut microbiome, commensal germs that colonise the gut are considered essential for the homeostasis of the digestive tract. They have multiple functions, one of the most important of which is an anti-inflammatory effect through modification of regulatory T-cells. Alterations in the microbiome may lead to a greater or lesser effect of immunotherapy, whereby the microbiome could be altered to increase the effect of ICIs or decrease in cases of immunotoxicity. Therefore, the microbiome could be both a predictive and prognostic biomarker for immunotherapy (17). The use of antibiotics prior to and during immunotherapy treatment could modulate the effects of immunotherapy through regulation of the microbiome, although its use is in pre-clinical stages.

Tumour-infiltrating lymphocytes (TILs) are another biomarker under investigation both preclinically and clinically. TILs are lymphocytes that are found infiltrating tumours, generating a pro-inflammatory environment that enhances the anti-tumour response of the immune system (18). Multiple studies have shown that increased TILs at the tumour level led to a better response to ICIs in different solid tumours, including NSCLC (19,20). TILs are so important in the anti-tumour immune response that two types of tumours can now be distinguished according to the presence of TILs: tumours with high inflammation and a better response to immunotherapy, and non-inflamed tumours with a poorer response (21). Therefore, although TILs are not very useful in clinical practice, their role could be essential in the future in immunotherapy treatment of NSCLC.

Along with all the above-mentioned biomarkers, there are multiple biomarkers currently under development (Table 2). Different genomic signatures are under development to try to find patterns of response to immunotherapy in NSCLC (STK11/LKB1 o LAMC3), and there are some promising genes that could have great future relevance in the treatment of NSCLC. Other biomarkers are the lactate dehydrogenase (LDH) which is a marker of tumour proliferation and whose values have been inversely related to the response to ICIs (22), the expression of interferon-γ as a marker of anti-tumour inflammatory response (23) and the neutrophil-to-lymphocyte ratio (NLR) with a high serum value being related to worse responses to immunotherapy in NSCLC (24). Finally, the main driver mutations in NSCLC (EGFR, ALK and ROS1) should not be forgotten. These mutations are known biomarkers predictive of non-response to immunotherapy, and therefore, targeted therapy against these mutations in NSCLC is essential over and above immunotherapy treatments (25).

Acknowledgments

Funding: None.

Footnote

Provenance and Peer Review: This article was commissioned by the editorial office, Precision Cancer Medicine. The article did not undergo external peer review.

Conflicts of Interest: All authors have completed the ICMJE uniform disclosure form (available at https://pcm.amegroups.com/article/view/10.21037/pcm-22-68/coif). The authors have no conflicts of interest to declare.

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