Endometrial Tumors with MSI-H and dMMR Share a Similar Tumor Immune Microenvironment.

PURPOSE: Microsatellite instability (MSI) and mismatch repair deficiency (dMMR) are important biomarkers for predicting responses to immune checkpoint inhibitor (ICI) therapies. Although PCR-based tests for high MSI (MSI-H) and dMMR yield highly concordant results in endometrial cancer (EC), it is unclear whether this is true for MSI-H and MMR detected by next-generation sequencing (NGS) and immunohistochemistry (IHC), respectively. This study investigated whether EC with MSI-H identified by NGS and dMMR identified by IHC have similar tumor immune microenvironments. PATIENTS AND METHODS: EC tissue and corresponding peripheral blood lymphocyte samples were collected from 99 randomly selected patients. MSI status and tumor mutation burden (TMB) were examined by NGS. MMR protein and programmed death ligand (PD-L)1 expression and tumor-infiltrating lymphocyte (TIL) abundance were evaluated by IHC.
RESULTS: Of the 99 EC samples, 29 (29%) had dMMR by IHC, while 18 (18%) had MSI-H by NGS. MSI and MMR status identified by the two methods were discordant in the 99 EC patients, and 2/18 NGS-identified MSI-H patients (11%) retained MMR protein expression. MSI-H and dMMR endometrial tumors had similar numbers of cluster of differentiation (CD)3+ TILs (T cells) and CD8+ TILs (cytotoxic T cells) in the tumor center and periphery, which differed from those in microsatellite stable (MSS) and mismatch repair-proficient (pMMR) EC; they also showed similar TMB, PD-L1 expression, and TIL counts with higher TMB and PD-L1 expression than MSS and pMMR ECs. The abundance of CD3+ and CD8+ TILs was increased in PD-L1-positive EC.
CONCLUSION: NGS-identified MSI status and IHC-identified MMR status were inconsistent in EC, and 11% of NGS-identified MSI-H tumors retained MMR protein expression. Conversely, MSI and MMR status determined by the two methods provided similar data on TMB, PD-L1 expression, and TIL abundance, which can guide treatment decisions with ICIs.

Introduction

The incidence of endometrial cancer (EC) is increasing yearly, and EC is one of the three most prevalent gynecologic tumors affecting women.1,2 Most patients with EC have a low risk of recurrence and can be managed by surgery alone.3 For metastatic and relapsed EC, chemotherapy and hormone therapy are the only available treatment options, but these are toxic and do not significantly improve 5-year overall survival, progression-free survival, or relapse rate.4,5 Many new targeted therapies have recently been evaluated in clinical trials, but only a few have improved survival and therapeutic responses. Therefore, it is important to identify molecular subgroups of EC that are likely to benefit from targeted therapies including immunotherapy.

EC is a heterogeneous disease comprising multiple histotypes with different risk factors, clinical behaviors, and outcomes. In the 1970s, a traditional classification of EC into types 1 and 2 was proposed.6 The classification applied in clinical practice to guide therapeutic decision-making is based on histopathologic assessment of cell type and grade;7,8 however, this can be highly subjective, difficult to validate, and has limited utility for predicting responses to therapy.9,10 Thus, there is a need for a more reproducible, objective, and biologically informative classification system for EC. The Cancer Genome Atlas (TCGA) research network described four distinct prognostic EC subtypes in 2013 based on genomic abnormalities that reflect EC tumor biology, which can provide more precise guidance for surgery, adjuvant therapy, and disease surveillance.11 One of these subtypes is high microsatellite instability (MSI-H) or a hypermutated phenotype resulting from a defective mismatch repair (MMR) mechanism (known as MMR-deficient [dMMR]), which is observed in approximately 30% of endometrial tumors.3,12

The algorithm for EC screening may include an immunohistochemistry (IHC)-based test for MMR, PCR-based test for MSI, or both, as they are equally valid initial screening tools in EC. However, IHC is the preferred method because of the high false negative rates of MSI tests in EC.13–15 Next-generation sequencing (NGS) platforms use different technologies to decode the identity of nucleotides in DNA or detect covalent modifications such as methylated nucleotides; a distinctive genomic signature for the high MSI (MSI-H) phenotype of EC was identified using a targeted NGS gene panel. Although PCR-based tests for MSI and MMR in EC have high concordance, there is little or no agreement between NGS gene panel results for MSI and IHC results for MMR.11,16 This is clinically significant, because tumor-infiltrating lymphocytes (TILs) are more abundant in the immune microenvironment of MSI-H EC compared to microsatellite-stable (MSS) EC.17 Additionally, programmed death ligand (PD-L)1 expression was elevated in dMMR EC compared to MMR-proficient (pMMR) cases. It is therefore important to compare the tumor immune microenvironment in EC with NGS-identified MSI-H and IHC-identified dMMR to determine whether there are any discrepancies that could influence decisions concerning immune checkpoint inhibitor (ICI) therapies.

In the present study we analyzed the degree of concordance between NGS-identified MSI-H and IHC-identified dMMR ECs—specifically with respect to the tumor immune environment (eg, neoantigens, PD-L1 expression, and TIL levels)—with the aim of identifying EC subgroups that could potentially benefit from targeted immunotherapy regimens.

Materials and Methods

Patients and Tissues

We obtained EC tissues and corresponding peripheral blood lymphocyte samples from 99 randomly selected (in terms of age and personal or family history of cancer) patients who were treated at our institution between 2015 and 2018. Clinical information obtained from hospital records included age at diagnosis, surgical stage, adjuvant treatment, and disease status. The patients were staged according to the International Federation of Gynecology and Obstetrics criteria. Tumor grade, histologic subtype, depth of myometrial invasion, and lymphovascular invasion were reviewed by a gynecologic pathologist based on the 2014 World Health Organization criteria. This study was approved by the Human Investigation Ethics Committee of the Shanghai First Maternity and Infant Hospital. Samples were collected from patients after they had provided written, informed consent.

IHC

Deparaffinized tissue sections were rehydrated in dewaxing solution (Maixin, Fuzhou, China) for 10 min, and antigens were retrieved by heating the sections in EDTA (pH 9.0) for 20 min at 99°C. IHC was performed using a Titan S autostainer (Lumatas Biosystems, Fremont, CA, USA) as follows. Endogenous peroxidase activity was blocked with H2O2 (Maixin, Fuzhou, China) and the sections were incubated with primary antibodies diluted 1:100 or 1:200 () at room temperature for 30 min, followed by incubation with secondary antibodies. The sections were stained with 3,3′-diaminobenzidine (DAB) as the chromogen (Maixin, Fuzhou, China) using the Elivision Super kit (Maixin, Fuzhou, China), followed by staining with prediluted anti–PD-L1 antibody (clone SP263; Ventana Medical Systems, Tucson, AZ, USA). The negative control was a matched rabbit IgG. The sections were assessed using an OptiView DAB IHC Detection Kit (Thermo Fisher Scientific, Waltham, MA, USA) on a BenchMark ULTRA automated staining platform (Roche, Basel, Switzerland). The specificity and sensitivity of the assay were evaluated using control placental tissue samples with known PD-L1 expression levels.

Evaluation of IHC Staining

Three pathologists who were blinded to the MSI status of patient samples independently reviewed the stained sections. Nuclear staining of adjacent normal endometrial lymphocytes served as the internal positive control. We judged the complete absence of nuclear staining in the tumor cells as a loss of MMR protein expression, and manually counted TILs in the five areas with the highest lymphocyte aggregation within or adjacent to the tumor (Figure 1). The sections were scanned at 20× magnification using an Aperio Scanscope AT Turbo scanner (Leica Biosystems, Nussloch, Germany) as previously described.17 Immune cells in the tumor periphery (Figure 1, green boxes) were defined as those that were +1 or −1 mm from the invasive tumor front or endometrium–myometrium interface. The center (Figure 1A, yellow boxes) was defined as the area >1 mm away from the invasive tumor front or endometrium–myometrium interface toward the luminal aspect (Figure 1B). The box with the highest signal intensity was considered as a hotspot (Figure 1C, red boxes). Intraepithelial TILs were counted in a 1-mm2 area of tumor located within the boundary of tumor cell nests or glands. Stromal TILs were those in the stroma of the endometrial tumor. The numbers of positive cells in the periphery, center, hotspot, and intraepithelial and stromal areas were summed and divided by the number of cells in the total area (mm2). The results for cluster of differentiation (CD)3 and CD8 cells are shown as positive cells/mm2.

Figure 1

Strategy for quantifying TILs in endometrioid EC. (A) Representative H&E staining of endometrioid EC to define the tumor center and periphery. (B and C) Quantification of CD3+ cells (B) and CD8+ cells (C) in the tumor center and periphery. Red box, hotspot (single 1-mm2 box); green boxes, tumor periphery (five 1-mm2 boxes); yellow boxes, central areas (five 1-mm2 boxes). Scale bars: 1 mm.

PD-L1 was predominantly expressed at the margin or the infiltrating edge of the interface between the tumor and immune stroma (). PD-L1 expression was evaluated in tumor cells and tumor-infiltrating immune cells. The proportion of PD-L1–positive tumor cells was estimated as the ratio (%) of total tumor cells, and the ratio of PD-L1–positive tumor-infiltrating immune cells in tumors was also calculated. We chose 1% and 5% cutoffs as the PD-L1–positive thresholds for tumor and immune cells, respectively ().

Detection of MSI-H by NGS

MSI status was determined by analyzing total genomic DNA extracted from formalin-fixed paraffin-embedded (FFPE) tumor tissues by NGS. Areas of interest with the highest tumor cellularity and viability (minimum 10% for both parameters) in sections stained with hematoxylin and eosin were selected. Tumor cellularity was enriched by macrodissection using a sterile 1-mm tissue punch. Total genomic DNA was extracted from tissue cores or unstained slides using the QIAamp DNA FFPE tissue kit (Qiagen, Valencia, CA, USA), and DNA concentrations were measured using Qubit dsDNA assays (Thermo Fisher Scientific). Fragments of DNA obtained using a Covaris M220 focused ultrasonicator (Covaris, Woburn, MA, USA), were selected using AMPure beads and the Agencourt AMPure XP kit (Beckman Coulter, Brea, CA, USA). The genetic profile of all tissue samples was assessed by capture-based targeted deep sequencing using the NGS genetic testing panel OncoScreen Plus (Burning Rock Dx, Guangzhou, China) with a modified Roche/Nimblegen SeqCap EZ method (Roche). This panel selects 520 genes that are associated with cancer pathogenesis and targeted therapies via probe hybridization and high-throughput sequencing, including whole exon regions of 312 genes and hotspot mutation regions (exons, introns, and promoter regions) of 208 genes. The panel can comprehensively and accurately detect variations in gene mutations, amplifications, and fusions with clinical relevance to tumors as well as biomarkers for response to ICIs such as the tumor mutation burden (TMB) and MSI. DNA quality and size were assessed using a high-sensitivity DNA assay and bioanalyzer. All indexed samples were sequenced using a NovaSeq 6000 system (Illumina, San Diego, CA, USA) with paired-end reads.

TMB

TMB is reported as mutations per megabases of sequenced DNA and was calculated based on the number of somatic mutations identified by NGS to exclude any known single nucleotide polymorphisms in the database.18

Statistical Analysis

Statistical analyses were performed using SPSS v20.0 (SPSS Inc, Chicago, IL, USA) and Prism v8.1.2 (GraphPad, La Jolla, CA, USA). Categorical data are described as frequency and percentage, and quantitative variables are expressed as mean±SEM. Fisher’s exact test or the chi-squared test was used to compare categorical variables. The Student’s t test was used to compare parametric data with a normal distribution, and the Mann–Whitney U-test was used for nonparametric data. Differences with P<0.05 were considered significant.

Results

MSI Status of EC Determined by NGS and dMMR Detected by IHC

The clinical and pathologic characteristics of the 99 patients included in this study are summarized in . Most patients were diagnosed with grade 1 EC (Table 1). The MSI status of the patients as determined by NGS and IHC was compared (). The levels of the MMR proteins MutL homolog (MLH)1, MSH2, MSH6, and PMS1 homolog (PMS)2 in 99 endometrial tumors were assessed by IHC. Staining of MMR proteins was normal in 70 tumors with pMMR (78%), indicating MSS; 29 (29%) showed no immunoreactivity against one or two MMR proteins and were thus identified as dMMR, indicating MSI-H. Most of these tumors lacked expression of both MLH1 and PMS2 (Figure 2). The NGS results showed that 18/99 tumors (18%) had MSI; 2 of these (11%) retained MMR protein expression, and 16 (89%) were confirmed as dMMR by IHC. Additionally, 10 tumors (10%) had germline mutations in MMR-related genes, of which 6 (60%) had NGS-identified MSI-H (). A total of 26 tumors (26%) had somatic mutations in MMR-related genes and 11 of these had NGS-identified MSI-H (). Compared to the detection of MSI status by NGS, IHC-identified dMMR had a sensitivity of 55.2% (95% confidence interval [CI]: 37.07%, 73.27%), specificity of 97.1% (95% CI: 93.24%, 101.05%), positive predictive value of 88.9% (95% CI: 74.37%, 103.41%), and negative predictive value of 84.0% (95% CI: 75.96%, 91.94%) for detecting MSI status (Table 2).

Table 1

Clinical and Pathological Characteristics of the Study Population

Histology	Grade	Total Patients	%
Endometrioid	1–3	88	88.89
	1	66	66.67
	2	16	16.16
	3	6	6.06
Serous	3	3	3.03
Clear cell	3	1	1.01
Mixed carcinomas	3	1	1.01
Carcinosarcoma	3	6	6.06
Total		99	100

Figure 2

Detection of MMR protein expression by IHC. (A and B) Loss of MLH (A) and PSM2 (B) staining. (C and D) Intact MSH2 (C) and MSH6 (D) staining. Note the presence of nuclear staining in adjacent glands and benign stromal cells, validating the IHC method. Scale bars: 100 μm.

Table 2

Classification of MSI by NGS Compared with Classification of MMR by IHC

		IHC
		MSI-H	MSI-L/MSS
OncoScreen Plus (NGS)	MSI-H	16	2	PPV=88.9%
	MSI-L/MSS	13	68	NPV=84.0%
	Accuracy	Sensitivity = 55.2%	Specificity = 97.1%

Abbreviations: IHC, immunohistochemistry; MSI-H, microsatellite instability-high; MSI-L, microsatellite instability-low; MSS, microsatellite stable; NPV, negative predictive value; PPV, positive predictive value.

TMB and PD-L1 Expression in MSI-H and dMMR EC

We next examined the relationship between TMB, MSI-H or dMMR, and PD-L1 expression. MSI-H tumors had high TMB (Figure 3A) and showed increased PD-L1 expression in tumor and immune cells compared to MSS tumors (Figures 3B and 4). Increased TMB (Figure 5A) and an increasing trend in PD-L1 expression in tumor and immune cells were observed in dMMR tumors compared to pMMR tumors (Figures 5B and 6). MSI-H tumors had TMB and PD-L1 expression levels similar to dMMR tumors (Figure 7A and B).

Figure 3

Neoantigen load and PD-L1 expression level in MSI-H and MSS EC. (A) TMB per megabase in tumor DNA exons and introns detected by ColoSeq. Blue and green represent MSI-H and MSS tumors, respectively. (B–D) Average numbers of PD-L1–expressing tumor cells and TILs (B), CD3+ immune cells (C), and CD8+ immune cells (D) identified by IHC. NS, nonsignificant at p>0.05, *p<0.05, **p<0.01 (Mann–Whitney U-test).

Figure 4

Upregulation of PD-L1 in MSI-H EC. (A–D) H&E staining and positive membrane staining for PD-L1 in MSI-H ECs. Scale bars: 60 μm.

Figure 5

Neoantigen load and PD-L1 expression level in dMMR and PMMR endometrial tumors. (A) TMB per megabase in tumor DNA exons and introns detected by ColoSeq. Red and black represent dMMR and PMMR tumors, respectively. (B) Average numbers of PD-L1–expressing tumor cells and TILs (B), CD3+ immune cells (C), and CD8+ immune cells (D) identified by IHC. NS, nonsignificant at p>0.05, *p<0.05, (Mann–Whitney U-test).

Figure 6

Upregulation of PD-L1 expression in dMMR EC. (A–D) H&E staining and positive membrane staining for PD-L1 in dMMR ECs. H&E, hematoxylin and eosin. Scale bars: 60 μm.

Figure 7

Neoantigen load and PD-L1 expression level in dMMR and MSI-H endometrial tumors. (A) TMB per megabase in tumor DNA exons and introns detected by ColoSeq. Red and blue represent dMMR and pMMR tumors, respectively. (B) Average numbers of PD-L1–expressing tumor cells and TILs (B), CD3+ immune cells (C), and CD8+ immune cells (D) identified by IHC. NS, nonsignificant at p>0.05 (Mann–Whitney U-test).

TILs in MSI-H and dMMR EC

To compare the tumor immune environments in EC identified as MSI-H by NGS and dMMR by IHC, we performed IHC-based quantification of CD3+ and CD8+ TILs. CD3+ and CD8+ cells in the tumor center and periphery were counted in the tumor center (Figure 1, yellow boxes), hotspot (Figure 1, red boxes), and periphery (Figure 1, green boxes) in areas of highest staining density in five fields with an area of 1 mm2. MSI-H and MSS EC had comparable numbers of CD3+ TILs (T cells) and CD8+ TILs (cytotoxic T cells) in the tumor center (CD3+: 558.2 vs 517.3, P=0.638; CD8+: 138.6 vs 148.5, P=0.428) and periphery (CD3+: 669.9 vs 549.9, P=0.270; CD8+: 163.5 vs 199.2, P=0.953) (Table 3 and Figure 3C and ); dMMR and pMMR EC also showed similar numbers of CD3+ TILs (T cells) and CD8+ TILs (cytotoxic T cells) in the tumor center (CD3+: 571.8 vs 531.6, P=0.734; CD8+: 97.0 vs 148.5, P=0.276) and periphery (CD3+: 593.4 vs 555.5, P=0.270; CD8+: 124.1 vs 205.6, P=0.793) (Table 4 and Figure 5C and D). MSI-H tumors had similar numbers of CD3+ TILs and CD8+ TILs as dMMR tumors (Figure 7C and D).

Table 3

TILs in MSI-H and MSS ECs

Variable	MSI-H (N = 17)		MSS (N = 80)		P
	Mean (SD)	Median	Mean (SD)	Median
Mean CD3 (cells/mm2)
Glands	166.4 (148.3)	111	143.1 (169.9)	90.5	0.234
Interstitium	517.3 (383.5)	433	448.2 (297.1)	405.5	0.413
Hotspot	872.6 (459.4)	843	749.7 (544.8)	685	0.389
Center	558.2 (390.6)	469	513.7 (343.6)	433	0.638
Periphery	669.9 (499.4)	494	549.9 (488.4)	424.5	0.27
Mean CD8 (cells/mm2)
Glands	60.8 (40.6)	58.5	57.5 (70.9)	35	0.13
Interstitium	120.8 (154.5)	72.5	156.5 (154.5)	90	0.271
Hotspot	243.2 (217.5)	175.5	254.3 (258.4)	164	0.761
Center	138.6 (93.2)	130.5	148.5 (158.7)	95	0.482
Periphery	163.5 (139.2)	122	199.2 (223.9)	119	0.953

Abbreviations: MSI-H, microsatellite instability-high; MSS, microsatellite stable.

Table 4

TILs in dMMR and PMMR ECs

Variable	dMMR (N=12)		PMMR (N=70)		P
	Mean (SD)	Median	Mean (SD)	Median
Mean CD3 (cells/mm2)
Glands	204.4 (242.8)	113.5	152.5 (178.7)	92.5	0.281
Interstitium	433.0 (275.2)	275.2	459.6 (309.5)	409.5	0.781
Hotspot	774.3 (509.6)	509.6	759.9 (555.1)	673	0.933
Center	571.8 (458.7)	458.7	531.6 (360.8)	455.5	0.734
Periphery	593.4 (494.0)	494.1	555.5 (469.6)	424.5	0.799
Mean CD8 (cells/mm2)
Glands	54.9 (45.1)	43	59.9 (74.6)	34	0.508
Interstitium	76.6 (45.7)	70.5	164.2 (171.4)	91.5	0.081
Hotspot	163.4 (81.2)	157.5	257.9 (272.8)	149.5	0.713
Center	97.0 (79.7)	84	152.3 (162.2)	98.5	0.276
Periphery	124.1 (52.9)	122	205.6 (233.0)	119	0.793

Abbreviations: dMMR, deficient mismatch repair; PMMR, proficient mismatch repair.

TILs are Increased in PD-L1–Positive EC

PD-L1 expression was detected in tumor cells in 75/98 tumors (76.5%) and immune cells in 93/98 tumors (94.9%) with the 1% cutoff (Tables 5 and 6); and in tumor cells in 52/98 tumors (53.1%) and immune cells in 82/98 tumors (83.7%) with the 5% cutoff (Tables 7 and 8). PD-L1 expression increased significantly with CD3+ and CD8+ TIL numbers in the tumor microenvironment with both cutoff values (Tables 5–8). IHC analysis revealed that endometrial tumors with high PD-L1 expression had higher numbers of CD3+ and CD8+ TILs in the tumor microenvironment (Figure 8).

Table 5

TILs in ECs with or without Positive PD-L1 Expression in Tumor Cells (Cutoff Value: 1%)

Variable	PD-L1-Negative Tumor		PD-L1-Positive Tumor		P
	N = 23		N = 75
	Mean (SD)	Median	Mean (SD)	Median
Mean CD3 (cells/mm2)
Glands	55.5 (41.2)	45.5	184.9 (197.2)	115.5	<0.0001
Interstitium	381.2 (363.5)	328	492.3 (300.6)	454	0.15
Hotspot	547.9 (509.0)	380.5	856.6 (539.1)	754.5	0.019
Centre	371.6 (315.2)	302	582.9 (374.1)	496	0.018
Periphery	444.8 (583.0)	310	627.6 (478.6)	537.5	0.02
Mean CD8 (cells/mm2)
Glands	39.1 (70.8)	18	63.6 (64.3)	47.5	0.001
Interstitium	118.7 (136.8)	72	159.7 (160.1)	94	0.054
Hotspot	168.5 (192.4)	116	277.7 (260.8)	191.5	0.005
Centre	110.9 (126.3)	83	157.2 (154.2)	109	0.03
Periphery	129.6 (166.4)	85	212.4 (220.3)	143.5	0.005

Abbreviations: TILs, tumor-infiltrating lymphocytes; EC, endometrial cancer.

Table 6

TILs in ECs with or without Positive PD-L1 Expression in Immune Cells (Cutoff Value: 1%)

Variable	PD-L1-Negative Immune Cells		PD-L1-Positive Immune Cells		P
	N = 5		N = 93
	Mean (SD)	Median	Mean (SD)	Median
Mean CD3 (cells/mm2)
Glands	34.5 (39.3)	20.5	160.5 (184.4)	95	0.015
Interstitium	131.8 (108.6)	128	481.4 (315.8)	422	0.03
Hotspot	132.8 (61.0)	124	814.3 (539.5)	715	0.014
Center	153.5 (139.1)	132.5	551.1 (369.1)	460	0.035
Periphery	162.5 (113.9)	139	604.1 (509.7)	496.5	0.025
Mean CD8 (cells/mm2)
Glands	12.2 (11.4)	7	60.3 (67.2)	40.5	0.003
Interstitium	102.8 (153.3)	34	152.5 (155.7)	91.5	0.085
Hotspot	68.6 (40.7)	58	261.8 (252.6)	174	0.005
Center	46.8 (40.9)	21	151.6 (150.7)	104.5	0.02
Periphery	44.6 (37.6)	27	200.8 (213.6)	131.5	0.003

Abbreviations: TILs, tumor-infiltrating lymphocytes; EC, endometrial cancer.

Table 7

TILs in ECs with or without Positive PD-L1 Expression in Tumor Cells (Cutoff Value: 5%)

Variable	PD-L1-Negative Tumor Cells		PD-L1-Positive Tumor Cells		P
	N = 46		N = 52
	Mean (SD)	Median	Mean (SD)	Median
Mean CD3 (cells/mm2)
Glands	94.1 (107.5)	53	209.1 (216.1)	131	0
Interstitium	377.1 (309.9)	335	546.0 (305.6)	475	0.009
Hotspot	589.2 (471.9)	462	959.4 (551.3)	860	0.001
Centre	410.8 (324.2)	341	643.7 (377.8)	607	0.002
Periphery	463.9 (508.1)	310	693.2 (486.0)	627	0.002
Mean CD8 (cells/mm2)
Glands	42.5 (55.8)	26.5	71.6 (72.4)	50	0.001
Interstitium	123.0 (114.6)	79.5	174.3 (182.1)	94	0.165
Hotspot	189.6 (174.1)	126	307.9 (292.8)	195	0.005
Centre	122.2 (115.4)	86	167.9 (171.8)	114	0.08
Periphery	147.0 (147.3)	100.5	233.9 (249.6)	149	0.008

Abbreviations: TILs, tumor-infiltrating lymphocytes; EC, endometrial cancer.

Table 8

TILs in ECs with or without Positive PD-L1 Expression in Immune Cells (Cutoff Value: 5%)

Variable	PD-L1-Negative Immune Cells		PD-L1-Positive Immune Cells		P
	N = 16		N = 82
	Mean (SD)	Median	Mean (SD)	Median
Mean CD3 (cells/mm2)
Glands	40.5 (24.8)	35	176.5 (190.9)	111	0
Interstitium	271.3 (204.0)	259	503.1 (322.4)	448	0.009
Hotspot	388.5 (282.0)	359	859.5 (551.7)	750	0.002
Centre	276.6 (196.1)	246	582.3 (376.5)	485	0.003
Periphery	233.7 (215.0)	188	650.9 (519.3)	536	0
Mean CD8 (cells/mm2)
Glands	20.0 (14.7)	15	65.2 (70.0)	47	0
Interstitium	78.1 (86.0)	56.5	164.2 (162.1)	94	0.003
Hotspot	93.3 (48.7)	85.5	283.1 (261.6)	195	0
Centre	61.4 (39.6)	60.5	163.0 (156.7)	114	0.001
Periphery	68.7 (43.7)	49.5	217.2 (222.2)	147	0

Abbreviations: TILs, tumor-infiltrating lymphocytes; EC, endometrial cancer.

Figure 8

Detection of PD-L1, CD3, and CD8 expression in the tumor center by IHC. (A) H&E staining. (B–D) Positive staining for PD-L1 (B), CD3 (C), and CD8 (D). Scale bars: 60 μm.

Discussion

MSI-H is an important biomarker for predicting response to ICI therapies, and defects in DNA MMR proteins are the primary cause of MSI.19 In our study, 100% of IHC-identified dMMR and NGS-identified MSI-H endometrial tumors belonged to different subgroups but had similar TMB, PD-L1 expression, and TIL counts, which can be useful for predicting response to ICI therapies.

MSI-H is a tumor biomarker in a variety of tumors including colorectal and gastric cancers and EC,20–22 and can be determined either by PCR with or without specific fragment sizes or by NGS depending on the individual tumor entity.23–25 DNA MMR is a critical DNA repair pathway that contributes to genomic stability,26 and tumors with dMMR—which is the primary cause of MSI-H9—have shown a remarkable response to immunotherapy in clinical trials.27 Gene mutations and slipped-strand mispairing contribute to the instability of DNA strands during the replication of repeated DNA sequences and can also give rise to a strong mutator phenotype and MSI.9,28 The expression of MMR proteins corresponds to MSI-H detection results in >90% of cases, while approximately 6% of MSI-H tumors retain MMR protein expression.29,30 In this study, 18% of tumors were identified as MSI-H by NGS and 29% as dMMR by IHC; 16% had both NGS-identified MSI-H and IHC-identified dMMR. The MMR and MSI status were discordant in all 99 endometrial tumors, and two NGS-identified MSI-H cases (11%) retained MMR protein expression. Determining the level of agreement between MSI and MMR status is critical for predicting the response to ICI therapy in EC.

MSI-H and dMMR tumors usually harbor a large number of neoantigens that contribute to immune activation.31,32 Targeting checkpoints related to immune cell activation is the most effective way to activate the antitumor immune response.33 In advanced carcinomas, MSI-H is an established predictor of therapeutic response to checkpoint-directed immunotherapies.34,35 Additionally, dMMR was shown to enhance the efficacy of ICIs in solid tumors. We determined that NGS-identified MSI-H and IHC-identified dMMR EC has similar TMB, PD-L1 expression, and TIL counts. TMB and PD-L1 expression were higher in NGS-identified MSI-H and IHC-identified dMMR EC samples than in those with MSS and pMMR, respectively. There were no differences in CD3+ and CD8+ TIL counts between ECs with MSI-H and MSS identified by NGS or between ECs with dMMR and pMMR identified by IHC. The higher TMB and PD-L1 expression in MSI-H and dMMR endometrial tumors supports the clinical efficacy of programmed death (PD)-1 inhibitors in the treatment of solid tumors with MSI24 and dMMR.27,31,34 Furthermore, PD-L1 expression increased with TIL abundance in the endometrial tumor microenvironment, indicating that PD-1 inhibitors can elicit an effective antitumor immune response in EC with high PD-L1 expression.

Conclusion

NGS-identified MSI and IHC-identified MMR status was inconsistent in 100% of examined EC samples and 11% of NGS-identified MSI-H cases retained MMR protein expression. Furthermore, MSI-H and dMMR endometrial tumors had similar tumor immune microenvironments with comparable TMB, PD-L1 expression, and TIL abundance. A combination of MSI-H and dMMR may better reflect the pathologic status of EC patients and can facilitate clinical decision-making regarding ICI therapy.