Clinical Next-Generation Sequencing Panels Reveal Molecular Differences Between Merkel Cell Polyomavirus–Negative Merkel Cell Carcinomas and Neuroendocrine Carcinomas

Emily Hartsough, MD; Mari Mino-Kenudson, MD; Jochen K. Lennerz, MD; Dora Dias-Santagata, PhD; Mai P. Hoang, MD

Am J Clin Pathol. 2023;159(4):395-406.

Abstract and Introduction

Abstract

Objectives: We aim to determine molecular differences between Merkel cell polyomavirus (MCPyV)–negative Merkel cell carcinomas (MCCs) and neuroendocrine carcinomas (NECs).

Methods: Our study included 56 MCCs (28 MCPyV negative, 28 MCPyV positive) and 106 NECs (66 small cell NECs, 21 large cell NECs, and 19 poorly differentiated NECs) submitted for clinical molecular testing.

Results: APC, MAP3K1, NF1, PIK3CA, RB1, ROS1, and TSC1 mutations, in addition to high tumor mutational burden and UV signature, were frequently noted in MCPyV-negative MCC in comparison to small cell NEC and all NECs analyzed, while KRAS mutations were more frequently noted in large cell NEC and all NECs analyzed. Although not sensitive, the presence of either NF1 or PIK3CA is specific for MCPyV-negative MCC. The frequencies of KEAP1, STK11, and KRAS alterations were significantly higher in large cell NEC. Fusions were detected in 6.25% (6/96) of NECs yet in none of 45 analyzed MCCs.

Conclusions: High tumor mutational burden and UV signature, as well as the presence of NF1 and PIK3CA mutations, are supportive of MCPyV-negative MCC, whereas KEAP1, STK11, and KRAS mutations are supportive of NEC in the appropriate clinical context. Although rare, the presence of a gene fusion is supportive of NEC.

Introduction

Epithelial neuroendocrine neoplasms are broadly classified into either neuroendocrine tumors (NETs), including "carcinoid," or neuroendocrine carcinomas (NECs). NECs consist of a group of poorly differentiated and high-grade neuroendocrine neoplasms.^[1,2] The latest World Health Organization classification identifies two subtypes of NEC: small cell NEC (SCNEC) and large cell NEC (LCNEC). Merkel cell carcinoma (MCC) represents a unique site-specific NEC.^[1,2] These tumors are all characterized by their high-grade histologic appearance, growing predominantly in solid sheets with a high proliferation rate associated with necrosis, and apoptotic debris.^[1,2]

Differentiating these neoplasms is imperative, as in the setting of metastasis the distinction of cutaneous MCC from other NECs has significant therapeutic implications. For example, while immunotherapy is the frontline treatment for advanced MCC, a combination of platinum and etoposide is the most widely used chemotherapy for small cell lung carcinoma (SCLC).^[3,4]

Despite thorough clinical and imaging workup, the origin of a metastatic NEC remains unknown in some cases. In this setting, immunohistochemical stains can be of help. As NECs are epithelial neoplasms, a cytokeratin stain (keratin AE1/AE3 and/or CAM 5.2, MNF116) should be positive, although in a subset of NEC cases, cytokeratins may be only focally expressed, sometimes with a dotlike paranuclear pattern mimicking a staining pattern that is more characteristic of MCC. MCC classically exhibits dotlike positivity for keratin 20 and other keratins, including keratin AE1/AE3, CAM5.2, and MNF116.^[5] The CM2B4 antibody that detects the Merkel cell polyomavirus (MCPyV) LT antigen can be useful in diagnosing MCPyV-positive cases. An immunohistochemical panel including keratin 20, neurofilament, SATB2, MCPyV, and TTF1 together with clinical findings and imaging studies would be helpful in the distinction of high-grade NEC from MCC.^[6–8] The coexpression of keratin and neurofilament is typical of MCC and excludes small cell carcinoma.^[6] In a study of 103 MCCs vs 70 extracutaneous NECs, Kervarrec et al^[6] reported neurofilament, SATB2, and MCPyV to be the most discriminant markers. However, distinguishing poorly differentiated NEC from MCPyV-negative MCC remains challenging, as they can often have significant morphologic and immunohistochemical overlap.

In recent years, there has been an increased interest in using novel molecular methods to further understand and characterize NEC. For example, SCLC is characterized by nearly universal inactivation of the tumor suppressor gene tumor protein (TP53) and RB transcriptional corepressor (RB1). Recurrent genetic alterations have also been identified in LCNEC. Targeted next-generation sequencing (NGS) of 241 cancer genes of 45 LCNECs revealed alterations involving TP53 (78%), RB1 (38%), STK11 (33%), KEAP1 (31%), and KRAS (22%).^[9] Interestingly, LCNEC could be grouped into two major subsets, SCLC-like and non-SCLC-like (NSCLC-like), based on their genomic profiles.^[9] Fifty-six percent of LCNECs in a study by Rekhtman et al^[10] exhibited NSCLC-like molecular profiles (lack of RB1 and TP53 coalteration and mutations of STK11, KRAS, KEAP1, and NFE2L2 with STK11/HRAS in 80% of the tumors), whereas 40% of LCNECs demonstrated a SCLC-like molecular profile (RB1 and TP53 coalteration, other SCLC-type alterations such as MYCL amplification, and complete absence of STK11 and KRAS mutations; MYCL, SOX2, FGFR1 amplifications; or PTEN mutations/loss).

Cutaneous MCC has two hypothesized pathogenetic pathways: UV-induced and clonal integration of MCPyV.^[3] Specifically, MCPyV-negative MCCs have been found to exhibit a high tumor mutational burden (TMB), with frequent mutations in RB1 and TP53 along with mutations in genes involved in chromatin modification, JNK, and DNA damage pathways, whereas MCPyV-positive tumors demonstrate a lower TMB with none of the genetic alterations observed in the MCPyV-negative tumors.^[3]

The diagnosis of MCPyV-positive tumors has recently been facilitated by CM2B4 immunohistochemistry; however, the distinction between MCPyV-negative MCC and NEC remains challenging in some cases. Since TP53 and RB1 mutations are signature molecular changes of UV-induced/MCPyV-negative MCC as well as SCNEC and a subset of LCNEC, detection of other molecular abnormalities is needed to separate the two entities in diagnostically challenging cases.^[3] In this retrospective study, we aim to examine the results of our clinical NGS-based mutational analyses and targeted gene rearrangement testing to determine significant molecular differences that would be helpful in the clinical distinction of MCPyV-negative MCC vs NEC.

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Table 1. Summary of Available immunohistochemical Staining for Merkel Cell Carcinoma and Neuroendocrine Carcinomas
Characteristic	Merkel Cell Carcinoma, No. (%)	Neuroendocrine Carcinoma, No. (%)	P Value
One or more neuroendocrine markers^a	50/51 (98)	98/98 (100)	1
Dotlike keratin staining^b	35/53 (66)	13/46 (28)	.0003^c
TTF1	1/32 (3)	54/76 (71)	.0001^c

^aINSM1, synaptophysin, chromogranin, CD56, and neuron-specific enolase.
^bKeratin 20, keratin AE1/3, keratin CAM5.2, keratin AE1/AE3 and CAM5.2, and MNF116.
^c P < .05, statistically significant.

Table 2. Summary of Single-Nucleotide and Copy Number Variant Results, Tumor Mutational Burden (TMB), and UV Signature
Characteristic	MCPyV-Negative MCC vs SCNEC		MCPyV-Negative MCC vs LCNEC		MCPyV-Negative MCC vs NEC
Characteristic	No. (%)	P Value	No. (%)	P Value	No. (%)	P Value
SNV
APC	7/28 (25) vs 4/66 (6)	.015^a	7/28 (25) vs 2/21 (10)	.27	7/28 (25) vs 9/106 (8)	.04^a
ARID1A	6/28 (21) vs 4/66 (6)	.06	6/28 (21) vs 1/21 (5)	.21	6/28 (21) vs 7/106 (7)	.029^a
ATM	7/28 (25) vs 2/66 (3)	.0026^a	7/28 (25) vs 3/21 (14)	.48	7/28 (25) vs 6/106 (6)	.44
KEAP1	0/28 (0) vs 0/66 (0)	1	0/28 (0) vs 5/21 (24)	.011^a	0/28 (0) vs 5/106 (5)	.58
KRAS	0/28 (0) vs 2/66 (3)	1	0/28 (0) vs 8/21 (38)	.0005^a	0/28 (0) vs 15/106 (14)	.04^a
MAP3K1	5/28 (18) vs 2/66 (3)	.023^a	5/28 (18) vs 1/21 (5)	.22	5/28 (18) vs 3/106 (3)	.01^a
MYC	2/28 (7) vs 0/66 (0)	.087	2/28 (7) vs 0/21 (0)	.5	2/28 (7) vs 0/106 (0)	.04^a
NF1	9/28 (32) vs 3/66 (5)	.0007^a	9/28 (32) vs 3/21 (14)	.19	9/28 (32) vs 8/106 (8)	.0017^a
PIK3CA	6/28 (21) vs 2/66 (3)	.008^a	6/28 (21) vs 2/21 (10)	.44	6/28 (21) vs 5/106 (5)	.011^a
RB1	24/28 (86) vs 36/66 (55)	.0046^a	24/28 (86) vs 6/21 (29)	.0001^a	24/28 (86) vs 50/106 (47)	.0002^a
ROS1	3/28 (11) vs 0/66 (0)	.024^a	3/28 (11) vs 0/21 (0)	.25	3/28 (11) vs 0/106 (0)	.0084^a
SMAD4	1/28 (4) vs 0/66 (0)	.078	1/28 (4) vs 1/21 (5)	.63	1/28 (4) vs 1/106 (1)	.029^a
STAG2	3/28 (11) vs 1/66 (2)	.078	3/28 (11) vs 0/21 (0)	.25	3/28 (11) vs 1/106 (1)	.029^a
STK11	2/28 (7) vs 0/66 (0)	.087	2/28 (7) vs 7/21 (33)	.028^a	2/28 (7) vs 8/106 (8)	1
TP53	25/28 (89) vs 57/66 (86)	1	25/28 (89) vs 13/21 (62)	.037^a	25/28 (89) vs 86/106 (81)	.41
TSC1	5/28 (18) vs 0/66 (0)	.0018^a	5/28 (18) vs 2/21 (10)	.68	5/28 (18) vs 2/106 (2)	.0045^a
Both TP53 and RB1	23/28 (82) vs 36/66 (55)	.019^a	23/28 (82) vs 6/21 (29)	.0003^a	23/28 (82) vs 51/106 (48)	.0013^a
UV signature	21/28 (75) vs 2/61 (3)	<.0001^a	21/28 (75) vs 0/21 (0)	<.0001^a	21/28 (75) vs 3/101 (3)	<.0001^a
TMB high	23/28 (82) vs 11/61 (18)	<.0001^a	23/28 (82) vs 8/21 (0)	.003^a	23/28 (82) vs 24/101 (24)	<.0001^a
CNV
FLT3 loss	2/28 (7) vs 1/66 (2)	.21	2/28 (7) vs 0/21 (0)	.5	2/28 (7) vs 1/106 (1)	.11
MYC gain	0/28 (0) vs 1/66 (2)	1	0/28 (0) vs 2/21 (10)	.072	0/28 (0) vs 4/106 (4)	.3
MYCN gain	0/28 (0) vs 2/66 (3)	.5	0/28 (0) vs 0/21 (0)	1	0/28 (0) vs 3/106 (3)	.55
PTEN loss	1/28 (4) vs 5/66 (8)	.67	1/28 (4) vs 0/21 (0)	1	1/28 (4) vs 6/106 (6)	1
RB1 loss	3/28 (11) vs 12/66 (18)	.54	3/28 (11) vs 0/21 (0)	.25	3/28 (11) vs 13/106 (12)	1

CNV, copy number variant; LCNEC, large cell neuroendocrine carcinoma; MCPyV, Merkel cell polyomavirus; NEC, neuroendocrine carcinoma; SCNEC, small cell neuroendocrine carcinoma; SNV, single nucleotide variant; TMB, tumor mutational burden.
^aStatistically significant.

Table 3. Clinical Data of Neuroendocrine Carcinomas With Positive Fusion Results
Case, Age, y^a/Sex	Primary Tumor	Clinical Presentation	Tumor Tested for Fusion	Fusion	Treatment	Prognosis
Case 1: 71/M	Prostatic adenocarcinoma diagnosed 15 years prior, following treatment with EBRT, ADT	1 year prior, developed biopsy-confirmed small cell carcinoma metastatic to the bladder, found to have disseminated metastatic disease	Liver metastasis	TMPRSS2 exon 1 and ERG exon 4	Palliative chemotherapy and radiation	Died several months after diagnosis
Case 2: 55/M	Prostatic adenocarcinoma metastatic to bone 2 years prior, treated with ADT, chemotherapy	New liver and lung nodules on imaging studies	Liver metastasis	TMPRSS2 exon 2 and ERG exon 4	Chemotherapy and atezolizumab	Alive 1 year after diagnosis with progression of disease in pelvis
Case 3: 74/M	Prostatic adenocarcinoma diagnosed 14 years prior, treated with radiotherapy, complicated by osseous metastasis	New pelvic mass	Pelvic metastasis	RAD54L exon 3 and MAST2 exon 5	Palliative chemotherapy	Died several months later with widely metastatic disease
Case 4: 79/F	Unknown primary	Weight loss, abdominal pain, hematuria, and found to have multiple hepatic lesions	Liver metastasis	FGFR3 exon 17 and UVSSA 5'UTR	Following palliative chemotherapy, now on maintenance atezolimumab	Alive at 6-month follow-up, with mixed treatment response
Case 5: 25/F	Unknown primary	Presented with back pain and breast lump, found to have extensive metastatic disease including to brain on imaging	Chest wall metastasis	SQSTM1 exon 6 and NTRK3 exon 15	Larotrecitinib, entrectinib, placed on clinical trial	Died 1 year later
Case 6: 70/M	RET-rearranged large cell neuroendocrine carcinoma of the lung diagnosed 4 years prior, treated with wedge resection, complicated by local recurrence and metastatic disease, including to brain	Surveillance imaging demonstrated progression of solitary brain mass	Brain metastasis	KIF5B exon 24 and RET exon 11	Resection of metastasis, postoperative radiation, palliative selpercatinib	Alive at 6 months after diagnosis, stable disease

ADT, androgen deprivation therapy; EBRT, external beam radiation therapy.
^aAge at time of molecular testing.

Table 4. Reported Fusions in Literature Associated With Various Neuroendocrine Neoplasms
Tumor Type	Fusion	References
Small cell lung carcinoma	CCDC57::BRCA1 CREBBP::RHBDF1 EML4::ALK ETV6::NTRK3 KIAA1432::JAK MPRIP::TP53 MYCL1::COL9A2 MYCL1::JAZF1 MYCL1::MACF1 MYCL1::MSRB2 MYCL1::PABPC4 NEK4::SFMBT1 NPEPPS::EPHA6 PLEKHM2::ALK PVT1::CHD7 RLF::MYCL SKP1::CDKL3 TMPRSS2::ERG ZAK::RAPGEF4	Ciampricotti et al, 2021²⁴ Li et al, 2020²⁷ Qin et al, 2021³⁹ Iwakawa et al, 2013⁴⁰ Rudin et al, 2012⁴¹ Peifer et al, 2012⁴² Hu et al, 2019⁴³ Ogino et al, 2021⁴⁴ Shen et al, 2021⁴⁵
Small cell lung carcinoma combined with adenocarcinoma	EML4::ALK ^a KLC1::ALK ^a	Toyokawa et al, 2012⁴⁶ Bai et al, 2018⁴⁷
Small cell transformation in lung adenocarcinoma following gefitinib therapy	CAV1::MET	Liu et al, 2019⁴⁸
Large cell neuroendocrine carcinoma	ALK fusion EML4::ALK KIF5B::ALK NTRK3::intergenic region	Omachi et al, 2014⁴⁹ Sigal et al, 2018⁵⁰ Shimizu et al, 2019⁵¹ Hayashi et al, 2018⁵²
Large cell neuroendocrine carcinoma combined with adenocarcinoma	KLC1::ALK	Zheng et al, 2018⁵³
CD99+ large cell neuroendocrine carcinoma	EWSR1 rearrangement	Malone et al, 2010⁵⁴
High-grade neuroendocrine lung carcinoma	EML4::ALK	Ricciuti et al, 2018⁵⁵
Primary undifferentiated neuroendocrine carcinoma	PIP5K1A::NTRK1 SQSTM1::NTRK2	Sigal et al, 2018⁵⁰
Prostate small cell carcinoma	TMPRSS2::ERG	Williamson et al, 2011³⁰
Bladder neuroendocrine carcinoma	PVT1::ERBB2 TMPRSS2::ERG	Williamson et al, 2011³⁰ Shen et al, 2018⁵⁶
Head and neck neuroendocrine carcinoma	CHD4::AFF2 FGFR3::TACC3	Ohmoto et al, 2021⁵⁷ Miller et al, 2022⁵⁸
Gallbladder neuroendocrine carcinoma	BTG3::CCDC40 FGFR3::TACC3 NCAM2::SGCZ	Li et al, 2017⁵⁹ de Bitter et al, 2021⁶⁰
Gynecologic high-grade neuroendocrine carcinomas	ASH1L::YY1AP1 CDK6::MALAT1 EEF1A1::MALAT1 MALAT1::FAT1 MALAT1::RMRP MALAT1::RNF213 MALAT1::SMG MALAT1::XIST	Mahdi et al, 2021⁶¹
Mixed adenoid cystic and neuroendocrine small cell carcinoma of the uterine cervix	FGFR2::TACC2	Gill et al, 2020⁶²
Uterine neuroendocrine carcinoma	NTRK1::GPATCH4	Sigal et al, 2018⁵⁰

^aFusion in both histologic components.

Table 5. Summary of Literature ^5–8 and the Current Study
Characteristic	MCPyV-Negative Merkel Cell Carcinoma	MCPyV-Positive Merkel Cell Carcinoma	Small Cell Lung Carcinoma	Other Neuroendocrine Carcinoma
Neuroendocrine markers^a	+++	+++	+++	+++
Keratins^b	Dotlike +++	Dotlike +++	+++	+++
Keratin 7	+	+	+++	+
Keratin 20	Dotlike	Dotlike	–	+ (Gastrointestinal)
SATB2	+++	+++	–	+ (Gastrointestinal)
TTF1	–	–	+++	–
Neurofilament	Dotlike +	Dotlike +	–	–
MCPyV/CM2B4	–	+++	–	–
Distinguishing mutation	NF1, PIK3CA		KRAS	KEAP1, STK11, and KRAS (large cell NEC)
Fusion	Absent	Absent	Rarely present	Rarely present
Tumor mutational burden	Frequently high	Frequently low	Frequently low	Frequently low
UV signature	Present	Absent	Absent	Absent

MCPyV, Merkel cell polyomavirus; NEC, neuroendocrine carcinoma; +, focal or <25%; +++, 25%-100%; –, negative or 0%.
^aINSM1, synaptophysin, chromogranin, CD56, and neuron-specific enolase.
^bKeratin AE1/AE3, keratin CAM5.2, combined AE1/AE3 and CAM5.2, and MNF116.