ARID1A genomic alterations driving microsatellite instability through somatic MLH1 methylation with response to immunotherapy in metastatic lung adenocarcinoma: a case report

Abstract

Background

Tumor molecular screening allows categorization of molecular alterations to select the best therapeutic strategy. AT-rich interactive domain-containing 1A (ARID1A) gene mutations are present in gastric, endometrial, and clear cell ovarian tumors. Inactivation of this gene impairs mismatch repair (MMR) machinery leading to an increased mutation burden that correlates with microsatellite instability (MSI), associated with tumor-infiltrating lymphocytes and programmed death ligand 1 (PD-L1) expression. This is the first case report in lung adenocarcinoma of ARID1A gene alterations leading to sporadic MSI, through somatic mutL homolog 1 (MLH1) promoter methylation, with an MLH1 gene mutation as the second somatic hit.

Case presentation

A 50-year-old never-smoker Bulgarian woman, with no comorbidities and no family history of cancer, was diagnosed with metastatic lung adenocarcinoma. PD-L1 immunohistochemistry (IHC) of tissue biopsies on right groin adenopathies resulted in 30% positivity. Liquid biopsy test reported actionable alterations in ARID1A gene, rearranged during transfection (RET) gene fusions, epidermal growth factor receptor (EGFR) gene R776H mutation, breast cancer (BRCA) genes 1/2, and cyclin-dependent kinase inhibitor 2A (CDKN2A) gene mutations. The patient was treated with immunotherapy, and showed a treatment response lasting for 19 months until a new metastasis appeared at the right deltoid muscle. Genomic analysis of a sample of this metastasis confirmed PD-L1 positivity of greater than 50% with CD8+ T cells expression and showed MSI with a deleterious c.298C>T (p.R100*) MLH1 gene mutation. Multiplex ligation-dependent probe amplification (MLPA) of this sample unveiled MLH1 gene promoter methylation. The MLH1 gene mutation and the MLH1 gene methylation were not present at the germline setting.

Conclusions

In this particular case, we show that ARID1A gene mutations with sporadic MSI due to somatic MLH1 gene promoter methylation and MLH1 gene mutation could change the prognosis and define the response to immunotherapy in a patient with lung adenocarcinoma. Comprehensive solid and liquid biopsy tests are useful to find out resistance mechanisms to immune checkpoint inhibitors. Our data encourages the development of new therapies against ARID1A mutations and epigenomic methylation when involved in MSI neoplasms.

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Introduction

Tumor molecular screening allows categorization of molecular alterations to select the best therapeutic strategy. Targeted drugs have marked and durable efficacy in advanced lung adenocarcinoma. In the absence of these specific biomarkers, systemic immune checkpoint inhibitors are also active against neoplasms with other biological profiles: microsatellite instability (MSI), high tumor mutational burden (TMB), or programmed death ligand 1 (PD-L1) expression. Identification of molecular mechanisms for immunotherapy response can be helpful to clinicians choosing this kind of treatment. AT-rich interactive domain-containing 1A (ARID1A) gene mutations are known to occur in gastric, endometrial, and clear cell ovarian tumors. Inactivation of this gene impairs mismatch repair (MMR) machinery leading to an increased mutation burden that correlates with MSI, associated with tumor-infiltrating lymphocytes and PD-L1 expression. This is the first case report in lung adenocarcinoma of ARID1A gene alterations leading to sporadic MSI, through somatic MLH1 promoter methylation, with an MLH1 gene mutation as the second somatic hit, showing a clinical and radiologic response to an immune checkpoint inhibitor.

Case description

A 50-year-old never-smoker Bulgarian woman, with no comorbidities and no family history of cancer, was diagnosed in June 2015 with stage IV lung adenocarcinoma metastatic to the peritoneum, retroperitoneum, adrenal glands, iliac and inguinal lymph nodes, as revealed by physical examination and computed tomography (CT) scan. Tissue biopsies from the primary tumor and right groin adenopathies revealed an adenocarcinoma, with positive cytokeratin-7 (CK7), epithelial membrane antigen (EMA), thyroid transcription factor-1 (TTF-1) immunohistochemistry (IHC), and negative cytokeratin-20 (CK20) staining. Real-time polymerase chain reaction (RT-PCR) (COBAS 4800 system) showed no epidermal growth factor receptor (EGFR) or v-RAF murine sarcoma viral oncogene homolog B (BRAF) gene V600E mutations. Fluorescence in situ hybridization (FISH) did not detect anaplastic lymphoma kinase (ALK) gene fusions, proto-onocogene 1 receptor tyrosine kinase of ROS (ROS-1) gene rearrangements, or tyrosine-protein kinase Met (hepatocyte growth factor receptor) (MET) gene amplifications. In July 2015, she started chemotherapy with cisplatin plus pemetrexed, developing adrenal insufficiency secondary to bilateral adrenal metastases, which required glucocorticoid and mineralocorticoid supplementation. Four cycles later, a partial response (PR) by Response Evaluation Criteria in Solid Tumors (RECIST) version 1.1 was obtained. After maintenance treatment with pemetrexed for 12 cycles, in July 2016 radiological progressive disease (PD) was documented at retroperitoneum and adrenal glands. In August 2016 and September 2016, three cycles of docetaxel were administered with growing metastasis only at the left adrenal gland.

With the advent of the ChekMate057 results [1], immunotherapy was proposed. PD-L-1 IHC (DAKO 22C3 antibody) on right groin adenopathies resulted in positivity of 30% and tumor sample was exhausted. To make sure the patient did not have any actionable genomic alteration, a comprehensive liquid biopsy Guardant360 test was performed. It reported 97 genomic variants with 19 actionable alterations (six at ARID1A gene, RET fusions, EGFR R776H mutation, BRCA1/2 and CDKN2A mutations) (Table 1).

Table 1 Guardant360 liquid biopsy genomic alterations

PD-L1 positivity, with the inference of a hypermutator phenotype, was considered to support the choice of immunotherapy with the patient’s agreement. Nivolumab 3 mg/kg intravenously every 2 weeks was administered for 38 cycles. After seven cycles, a PR by RECIST in cancer immunotherapy trials (iRECIST) was achieved (iPR). Immunotherapy was maintained for 19 months, from December 2016 to September 2018, with further confirmed PD iRECIST (iCPD) by solid biopsy of a new metastasis at the right deltoid muscle (Fig. 1).

Fig. 1
figure1

Disease response. a Partial response by Response Evaluation Criteria in Solid Tumors (in cancer immunotherapy trials) after 7 cycles of nivolumab, with disappearance of right adrenal metastasis and reduction of left suprarenal mass. b New metastasis at the right deltoid muscle (confirmed progressive disease by Response Evaluation Criteria in Solid Tumors, in cancer immunotherapy trials), vanishing on cisplatin plus pemetrexed rechallenge. Blue arrow points to right adrenal metastasis. Red arrow points to left adrenal metastasis. Yellow arrow points to right deltoid muscle metastasis

The sample of this metastasis went into a multinational, prospective molecular screening program called ARCHE (OncoDNA S.A., Belgium), performing OncoDEEP™ comprehensive panel with 76 genes and personalized tumor immunogram. In the metastasis at the right deltoid muscle, the platform revealed PD-L1 positivity of greater than 50% with CD8+ T cells expression by IHC, and showed MSI with a deleterious c.298C>T (p.R100*) mutL homolog 1 (MLH1) gene mutation (variant allele frequency [VAF] 30%) (Table 2).

Table 2 OncoDEEP™ Integrated report results

In December 2018, a PR was achieved with cisplatin plus pemetrexed reintroduction since October 2018 (Fig. 1), but the disease progressed shortly after. Immunotherapy rechallenge and vinorelbine did not succeed either.

Discussion

Mutations in ARID1A gene occur in a variety of tumors: gastric, endometrial, and clear cell ovarian cancers. Neoplasms formed by ARID1A deficiency have increased mutation rates, elevated tumor-infiltrating lymphocytes, and PD-L1 expression [2]. An 8% prevalence of ARID1A gene mutations has been described with next-generation sequencing (NGS) in lung adenocarcinoma samples [3]. In a Spanish cohort of 185 treatment-naïve patients, 12% of advanced lung adenocarcinoma cell-free DeoxyriboNucleic Acid (cfDNA) samples analyzed with Guardant360 harbored ARID1A mutations (61% pathogenic/likely pathogenic) [4]. To date, no clear epidemiological, clinicopathological, or molecular features have been specifically related to lung adenocarcinoma with ARID1A mutations.

In our patient, the PD-L1 positivity of 30%, and the presence of 97 genomic alterations (with five different exon deletions and one mutation in ARID1A gene accounting for 33.6% of altered cfDNA) (Table 1), made us estimate ARID1A aberrations as driver events.

The majority of ARID1A mutations are inactivating with loss of ARID1A expression, making them not easily druggable. However, molecular consequences of ARID1A deficiency in cancer may be exploited therapeutically. ARID1A interacts with MMR MutS protein homolog 2 (MSH2), recruiting MSH2 to chromatin during DeoxyriboNucleic Acid (DNA) replication, and promoting MMR. By contrast, ARID1A inactivation impairs MMR machinery leading to an increased mutation burden that correlates with MSI [2].

In deficient MMR cancers across 12 different histologies, overall response rate (ORR) of 53% (48/86) (95% CI 42–64) and complete response (CR) in 21% of patients, with a 2-year overall survival (OS) rate of 64%, were observed with anti-PD-1 antibody pembrolizumab [5]. Anti-PD-1 inhibitor nivolumab has shown an ORR of 36% (7% CR) in 42 patients with pretreated deficient MMR tumors [6]. However, no patients with non-small cell lung cancer (NSCLC) were included in these studies.

ARID1A mutations have been correlated with higher TMB (median 17.6 versus 7.4 mutations/Mb, p < 0.001) in microsatellite stable (MSS) tumors [7]. Conversely, in our tumor with MSI, the mutator phenotype could have been triggered by ARID1A driver alterations impairing MSH2 recruitment for DNA repair, without initial detection/no presence of MMR gene mutations, and with immunotherapy response due to MMR deficiency.

However, ARID1A has also been described as a causative gene for MSI through epigenetic silencing of the MLH1 gene. Loss of ARID1A expression has been associated with sporadic MSI in endometrial carcinoma secondary to MLH1 gene promoter methylation [8]. Since Guardant360 is not equipped for analyzing epigenomic changes, we hypothesized that ARID1A driver alterations could have also prompted this sporadic epigenomic pathway of MSI in our patient, leading to a high mutational rate.

The OncoDEEP comprehensive panel in the deltoid tumor sample confirmed the suspected MSI, with a pathogenic MLH1 gene mutation. In sporadic colon tumors with MSI, there is a high, but not complete, correlation between MLH1 methylation and BRAF V600E mutation [9]. Likewise, the absence of BRAF V600E mutation could not definitively preclude an MLH1 methylation in this lung adenocarcinoma. We proceeded to study MLH1 gene promoter methylation (SALSA MS-MLPA Probemix ME011-C1 Mismatch Repair Genes) and its presence was unveiled in the deltoid metastasis (Fig. 2).

Fig. 2
figure2

Genmapper of mutL homolog 1 (MLH1) methylation study. a Upper graph: Blood DNA pattern. b Bottom graph: Tumor DNA pattern, with peaks (red arrows and pair bases) marking the 5 methylation regions of MLH1 gene

MLH1 gene promoter methylation can follow novel patterns of inheritance [10]. Its germline prevalence in colorectal cancers (CRC) with MSI and loss of MLH1 expression is 0.6% [11]. In our patient, we discarded the presence of the MLH1 methylation at the germline setting. MLH1 gene promoter methylation has also been described as a second allele inactivating hit in patients with MLH1 germline mutations [9]. The VAF of the c.298C>T (p.R100*) MLH1 gene mutation was not close to 50% for the inference of an inherited mutation [12], but tumor purity could have influenced VAF. We also ruled out a germline origin for the MLH1 mutation, utterly excluding a Lynch syndrome diagnosis.

The VAF and its absence in the liquid biopsy do not confirm the MLH1 gene variant as the first allelic event for MMR deficiency. Although not impossible, it is difficult to conceive a mutation with VAF of 30% in solid biopsy not detected in cfDNA. We consider that MLH1 methylation was the first somatic hit and the MLH1 gene mutation a second variant with, most probably, a low VAF when the liquid biopsy was taken which could have hindered its detection. The clonal evolution of a growing disease with MMR deficiency would have been accompanied by a rise in VAF of the MLH1 gene mutation, mainly at the site of progression, enabling its identification in solid sample with OncoDEEP platform many months later.

To determine a possible immune response pattern in the resistant tumor biopsy, we reviewed the RNAseq data from the deltoid muscle metastasis. A high expression of C-X-C motif chemokine ligand 9 (CXCL9) gene was discovered, indicating the activation of the interferon-gamma pathway. Despite the persistence of this positive predictive biomarker along with MSI, and the lack of aberrations in resistance genes (Janus kinase 2 [JAK2], phosphatase and tensin homolog [PTEN], serine/threonine kinase 11 [STK11]), the patient ended up with tumor progression on immunotherapy.

In the current clinical scenario of progression, prioritization of therapy options for a tumor with MSI and other actionable genomic alterations in the original liquid biopsy is a challenging issue [13]. Categorizing molecular alterations according to therapeutic targets requires consideration of dominant signaling/repair pathways and scientific evidence.

In CRC with MLH1 methylation and BRAF wild type, a 42% prevalence of actionable fusions has been reported [14]. Respectively 38% and 45.5% of MSI CRC harbor secondary BRCA2 and EGFR mutations [15]. In our case, kinesin family member 5B-rearranged during transfection (KIF5B-RET) fusion, with higher VAF, could have been targeted over BRCA mutations (which need biallelic inactivation for actionability) and EGFR mutations. Tracking the evolution of targetable genomic alterations may help select the proliferating clone to be treated. Addressing the main stems of the disease is also appealing: ARID1A loss sensitizes cancer cells to poly(ADP-ribose) polymerase (PARP) inhibitors [16], and some agents have shown demethylating activity [17], providing candidate therapeutic opportunities for clinical trials.

To our knowledge, this is a unique case of lung adenocarcinoma with ARID1A gene alterations leading to sporadic MSI, through somatic MLH1 epigenomic changes, with an MLH1 gene mutation as the second somatic hit. Association of ARID1A mutations, MSI, high TMB, and PD-L1 expression contributes to more active immunotherapeutic responsiveness in advanced gastrointestinal cancers [18]. Coexistence of these molecular changes can also define a subset of lung adenocarcinoma with different prognosis and high vulnerability to immunotherapy. Although biomarker validation studies are encouraged, we suggest that ARID1A gene should be included in NGS panels used in metastatic lung adenocarcinoma. When ARID1A alterations are uncovered, MSI status should be known, even with comprehensive NGS platforms as well, to possibly predict durable antineoplastic response with immunotherapy.

Strikingly, with traditional hallmarks still leading to treatment response, we faced an usual case of PD after long-term immunotherapy. In the setting of MSI neoplasms, more research with complex tests based on solid and/or liquid biopsy are needed to find out primary and secondary resistance mechanisms to immune checkpoint inhibitors. After progression to immunotherapy in tumors with MSI, choosing the correct target among multiple actionable genomic aberrations is a difficult task. Development of therapies against ARID1A mutations and epigenomic methylation (when MLH1 methylation is involved) is warranted.

Conclusions

Reliable predictive biomarkers for sustained efficacy with targeted drugs have successfully emerged in recent years for metastatic lung adenocarcinoma. But in this era of precision oncology, more tumor molecular hallmarks related to systemic immunotherapy activity are urgently needed. The response to immune checkpoint inhibitors presented in this case report reflects that ARID1A genomic aberrations may contribute to this purpose, due to its relation to sporadic MSI through somatic MLH1 epigenomic methylation. It is our opinion that ARID1A gene should be included in comprehensive NGS molecular platforms used in advanced lung adenocarcinoma. On the other hand, resistance to immunotherapy and lack of clearly validated biomarkers constitute a huge field for future research.

Availability of data and materials

All data analyzed during this study are included in this published article. The sequencing data generated and analyzed during the current study is available from the authors upon reasonable request and with permission of Guardant Health and OncoDNA.

Abbreviations

ARID1A :

AT-rich interactive domain-containing 1A

cfDNA:

Cell-free DNA

CRC:

Colorectal cancers

DNA:

DeoxyriboNucleic Acid

FISH:

Fluorescence in situ hybridization

iCPD:

Confirmed progressive disease by iRECIST

IHC:

Immunohistochemistry

iPR:

Partial response by iRECIST

iRECIST:

Response Evaluation Criteria in Solid Tumors, in cancer immunotherapy trials

MLH1 :

MutL homolog 1

MMR:

Mismatch repair

MSI:

Microsatellite instability

MSH2:

MutS protein homolog 2

MSS:

Microsatellite stable

NSCLC:

Non-small cell lung cancer

NGS:

Next-generation sequencing

ORR:

Overall response rate

PD:

Progressive disease

PD-L1:

Programmed death ligand 1

PR:

Partial response

RT-PCR:

Real-time polymerase chain reaction

TMB:

Tumor mutational burden

VAF:

Variant allele frequency

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Acknowledgements

We express our sincere gratitude to Asociación La Concepción, Burgos (Spain).

Funding

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Authors

Contributions

EL provided clinical assistance to the patient, analyzed the results for choosing the diagnostic procedures and therapeutics, and interpreted the data for the case report. RSE contributed to the selection of the genomic tests. JFL and ABR were responsible for the OncoDEEP comprehensive panel. JFL analyzed RNAseq data for predictive biomarkers to immunotherapy and reviewed the case report. IF was involved in the Guardant360 liquid biopsy study. MD performed the MLPA technique. ABR submitted the article to the journal. EL and JFL are major equal contributors. All authors read and approved the final manuscript.

Corresponding author

Correspondence to Enrique Lastra.

Ethics declarations

Ethics approval and consent to participate

This study was conducted in accordance with the fundamental principles of the Declaration of Helsinki. The case report is part of the project “OncoDeep Immune RNA-seq panel for predicting response to immunotherapy in recurrent locally advanced or metastatasic, NSCLC: a pilot study” approved by the ethical committee of Complejo Asistencial Universitario de Burgos.

Consent for publication

Written informed consent was obtained from the patient for the publication of this case report and any accompanying images. A copy of the written consent is available for review by the Editor-in-Chief of this journal.

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The authors declare that they have no competing interests.

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Durán, M., Faull, I., Lastra, E. et al. ARID1A genomic alterations driving microsatellite instability through somatic MLH1 methylation with response to immunotherapy in metastatic lung adenocarcinoma: a case report. J Med Case Reports 15, 89 (2021). https://doi.org/10.1186/s13256-020-02589-1

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Keywords

  • Microsatellite instability
  • MLH1
  • Lung adenocarcinoma
  • Immunotherapy
  • Liquid biopsy
  • Molecular screening
  • ARID1A gene
  • NGS platforms