MATERIALS AND METHODS

Case selection

The HN SCC dataset of this study were derived from two of Catholic Medical Center hospitals, Seoul St. Mary’s Hospital and Bucheon St. Mary’s Hospital. The pathology file of Seoul St. Mary’s Hospital was searched for HN SCCs that underwent p16 IHC and/or HPV DNA PCR test as ancillary tests during the period from January 2011 to December 2019. A total of 717 HN SCC cases from 717 patients were retrieved, which includes small biopsies as well as resection cases. Bucheon St. Mary’s Hospital dataset consists of 70 HN SCC cases accessioned from January 2011 to December 2019. Thirty-one of Bucheon St. Mary’s Hospital cases had undergone p16 IHC and/or HPV DNA PCR at the time of diagnosis. For the remaining 39 cases for which p16 IHC and/or HPV PCR was not already done, paraffin-embedded tissue blocks were used to perform p16 IHC and HPV PCR. The paraffin blocks of Bucheon St. Mary’s Hospital cases were loaned from Bucheon St. Mary’s Biobank of The Catholic University of Korea (B2019091702). In total, 787 HN SCC cases from the two hospitals were analyzed. Included in the dataset were 28 cases for which p16 IHC and/or HPV PCR were not performed on the primary tumor but on the metastatic tumors of neck lymph nodes (n=23) or on the recurrent tumors (n=5). The p16 and HPV status of the primary tumor were assumed to be the same as in the metastatic/recurrent tumor [25] for these cases. Squamous cell carcinomas of unknown origin, nasopharyngeal carcinomas, and adenosquamous carcinomas were excluded.

p16 IHC

Formalin-fixed paraffin-embedded (FFPE) tissue sections of 4-μm thickness were used for IHC employing Ventana BenchMark autostainer (Ventana Medical Systems, Tucson, AZ, USA) in each of the two hospitals. The p16 antibody used during the year 2011–2015 at Seoul St. Mary’s Hospital was a mouse monoclonal antibody (JC8, 1:200, Santa Cruz Biotechnology, Santa Cruz, CA, USA). Cases from year 2016 onward at Seoul St. Mary’s Hospital and all of Bucheon St. Mary’s Hospital were stained with a ready-to-use antibody of E6H4 clone (CINtec Histology, Ventana Medical Systems). p16 IHC result was considered positive when there was diffuse moderate or strong nuclear and cytoplasmic staining in more than 70% of the tumor cells.

PCR-based HPV DNA detection and genotyping

DNA was extracted from four 10-μm-thick FFPE tissue sections of each case using QIASymphony DNA mini kit (Qiagen, Hilden, Germany) before 2016, and Maxwell 16 automated system (Promega Corp., Madison, WI, USA) later. HPV DNA detection and genotyping were done using either of the two commercial PCR-based kits. For cases accessioned before March 2018, a DNA chip-based genotyping kit (BMT HPV 9G DNA kit, Biometrix Technology, Chuncheon, Korea) was used. The later cases were tested using PANA RealTyper HPV Kit (PANAGENE Inc., Daejeon, Korea) that employs peptide nucleic acid probe-based multiplex real-time PCR and melting curve analysis. These tests were run at the department of pathology laboratories of Seoul St. Mary’s Hospital, where Bucheon St. Mary’s Hospital specimens were sent out. The HPV genotypes identified by the BMT HPV 9G DNA kit are 14 HR types (16, 18, 31, 33, 35, 39, 45, 51, 52, 56, 58, 59, 66, 68) and five low-risk (LR) types (6, 11, 34, 40, 42), and the rest of HPV DNA are reported as ‘other’ types. The PANA RealTyper HPV Kit specifies 20 HR types (16, 18, 26, 31, 33, 35, 39, 45, 51, 52, 53, 56, 58, 59, 66, 68, 69, 70, 73, 82) and two LR types (6, 11) while reporting 18 LR types (30, 32, 34, 40, 42, 43, 44, 54, 55, 61, 62, 67, 74, 81, 83, 84, 87, 90) as ‘other’ types. Statistical analyses were done using Excel 2013 (Microsoft Corp., Seattle, WA, USA) and SPSS statistics ver. 20.0 (IBM SPSS, Armonk, NY, USA) programs. A p-value<.05, double-sided, was considered statistically significant.

RESULTS

Prevalence of HR HPV and p16 positivity in HN SCCs according to subsites

The dataset of 787 HN SCCs (Table 1) consisted of 271 oral cavity (34.4%), 257 oropharynx (32.7%), 156 larynx (19.8%), 76 hypopharynx (9.7%), and 27 sinonasal tract (3.4%) carcinomas. p16 IHC was done for 771 of 787 cases. HPV DNA PCR was run for 466 cases, including 16 cases devoid of p16 IHC results. p16 positivity was 29.6% (228/771) in HN SCCs being the most prevalent in oropharyngeal carcinomas (184/252, 73.0%) and secondly in sinonasal tract carcinomas (7/25, 28.0%). HR HPV PCR-positivity was detected in 34.1% (159/466) of HN SCCs, 93.7% (149/159) of which was oropharyngeal carcinomas. The HR HPV PCR-positivity among oropharyngeal carcinomas was 72.7%, comparable to its p16-positive rate (73.0%). The prevalence of HR HPV in other subsites were 21.4%, 11.6%, 2.6% and 0.6%, for sinonasal tract, larynx, hypopharynx, and oral cavity, respectively. Among the HR HPV genotypes, HPV16 was overall the most common (84.3%, 134/159). HPV35 and 33 were the second and third most common ones, detected at 6.9% (n=11) and 4.4% (n=7), respectively. HPV58 and HPV18, each, was observed at 1.9% (n=3). HPV18 co-occurred with HPV16 in two of the three cases. Multiple genotypes were detected in seven cases as a combination of HR types (2 of 16 & 18; 16, 51 & 68) or both HR and LR types (16, 52 & 81; 16 & 34; 16, 31, 39 & 6; 58 & 11). HR HPV prevalence in the oropharynx was further stratified according to its four subsites of tonsil (palatine), base of tongue, soft palate, and other oropharynx (posterior wall or unspecified). The tonsil and base of tongue showed high rates of HR HPV positivity (78.9% and 61.3%, respectively) compared with soft palate (0%, 0/5) and other oropharynx (37.5%, 3/8). There were 15 cases (3.2%, 15/466) where only a LR (n=5) or ‘other’ type (n=10) was detected. Cases positive for ‘other’ type were detected with the chip-based genotyping kit, and the HPV type could include either a minority of HR type (26, 53, 69, 70, 73, and 82) or an LR type according to the manufacturer.

Comparison of p16 IHC results with that of HPV DNA PCR tests

The correlation of p16 overexpression with transcriptionallyactive HR HPV infection is well known for oropharyngeal SCCs [5]. We calculated the sensitivity, specificity, positive predictive value (PPV), and negative predictive value of p16 IHC in predicting HR HPV DNA positivity in 450 HN SCCs (Table 2). Differences in these measures were notable among HN subsites. The oropharynx (n=200) demonstrated high rates for the sensitivity, specificity, and PPV: 98.6 and 94.3 and 98.0%, respectively. When limited to the tonsil (n=157), the sensitivity even reached 99.2%, with the specificity of 93.8%. By contrast, the sensitivity was 0% for oral cavity carcinomas (n=159), the only HR HPV-harboring carcinoma being p16-negative. Among the nine p16-positive oral cavity carcinomas, one was positive for LR HPV, and the rest was negative for HPV. The numbers of hypopharyngeal and sinonasal tract carcinomas were not large enough in our dataset to consider their 100% sensitivity values significant.

Proportion of HR HPV-positive tonsillar SCCs compared across time periods and between different studies

The incidence of HR HPV-associated oropharyngeal SCCs has been shown to be rising over the past few decades in various parts of the world [9]. Our group had previously published a study on tonsillar SCCs diagnosed during 1994–2010 at Seoul St. Mary’s Hospital [26], in which the proportion of p16-positive cases was 62.0% (n=31 of 50). As p16 IHC is a reliable surrogate test for HR HPV in the oropharynx, we compared the proportion of p16-positive tonsillar SCCs across the time periods 1994–2010 and 2011–2019. The p16-positive fraction for 2011–2019, 80.6% (137 of 170), was significantly different from that of 1994–2010, 62.0% (chi-square test, p=.008), demonstrating an increase in HR HPV-positive tonsillar SCCs cases over a decade of time diagnosed in a tertiary care hospital. However, from 2011 to 2019, a significant increasing trend in the proportion of HR HPV-positive carcinomas was not detected (linear-by-linear association test, p=.097) (Fig. 1). Of note, the proportion of HR HPV-positive tonsillar carcinomas for Bucheon St. Mary’s Hospital cohort of current study was 70.8% (17 of 24), not significantly different from 81.5% (110 of 135) of Seoul St. Mary’s Hospital (chi-square test, p=.269).

Searching the literature for HPV-associated HN SCCs of Korea identified 15 studies, which are summarized in Table 3. Most of these studies dealt with time periods earlier than that of our study, from 1990s to 2000s. Studies of tonsillar SCCs employing HPV DNA PCR reported HR HPV prevalence ranging from 23.4% to 73.5%. A roughly bimodal distribution of previously reported HPV prevalence in tonsillar SCCs could be assumed, one peak at ~30% (n=4) and the other at ~70% (n=3). Those rates at 64.1, 73.1, and 73.5% [17,23,27] were not significantly different from the 78.1% of the current study (chi-square test, p>.05 for each) although derived from cohorts much earlier than (dated 2007 or prior) the current study. On the other hand, rates at 20%–30% level in four studies [18,19,22,28] were far lower compared with the others at 70% level. Another four studies of tonsillar or oropharyngeal SCCs documented p16 IHC results without performing HPV-specific tests; the p16-positive rates were all greater than 50%, from 62.0% to 82.5% [16,20, 26,29]. For other HN subsites, reports of HR HPV prevalence were found for oral cavity and hypopharyngeal carcinomas (Table 3). The oral cavity HR HPV positivity (0.6%) of the current study was the least of all Korean studies while the sample size was the largest (n=166).

DISCUSSION

The present study is the first to survey the HPV prevalence and p16 positivity for SCCs of multiple HN subsites in Korea. HR HPV was predominantly found in oropharyngeal carcinomas, with 72.7% positivity. Meta-analysis studies have shown overall HPV prevalence of 40%–50% for oropharyngeal carcinomas globally, with the highest rates of 70%–75% belonging to North American and Northern European countries [10,30-32]. It is interesting that the oropharyngeal HPV positivity, 72.3%, of the current Korean dataset corresponds to the upper range of prevalence values observed in some Western populations and is higher than those of other Asian countries (mostly at about 50% or lower) [32,33]. Among oropharyngeal subsites in our series, HR HPV prevalence was highest in the tonsil (78.9%) and second highest in the tongue base (BOT) (59.4%) while zero in the soft palate/uvula. The prevailing association of HR HPV with lymphoepithelial subsites of oropharynx, the tonsil and to a lesser extent the BOT, is well established [33]. p16 positivity demonstrated a good concordance with HR HPV DNA in our series of oropharyngeal carcinomas, especially for tonsillar carcinomas, reassuring the surrogate use of p16 IHC for classification of HPVassociated oropharyngeal carcinomas [8]. As p16 overexpression likely represents transcriptionally-active HPV infection, p16- negative HR HPV DNA positivity may suggest inactive infection or DNA contamination [34,35]. Such incidences were rare for oropharyngeal carcinomas in our series (1.6%, 2 out of 140 HR HPV-positive cases).

HR HPV has been recognized as a carcinogenic agent and also a favorable prognostic factor for oropharyngeal carcinomas, but the significance of HPV in non-oropharyngeal HN SCCs are controversial [7,36]. We observed the second highest HR HPV prevalence (21.4%) in sinonasal tract SCCs with a good concordance (100%) between p16 and HR HPV in a series of 12 cases. This corroborates the previous demonstration in sinonasal SCCs of 20%–30% HR HPV prevalence with reliable p16 IHC for HR HPV [37-39]. For oral cavity and laryngeal SCCs, the concordance between p16 and HR HPV status was poor in the current study, which is also in line with previous findings [41]. We observed the lowest HR HPV positivity in oral cavity SCCs, at 0.6% out of 166 cases tested. This is lower than the rates reported in other Korean studies (Table 3) and the prevalence summarized for oral cavity carcinomas in meta-analysis studies (24%–58%) [42]. As we obtained a high rate of HR HPV positivity for oropharyngeal carcinomas backed by a good concordance with p16 positivity, the low rate in oral cavity carcinomas is not likely due to a low sensitivity of the HPV detection methods we used. One possibility for higher HR HPV rates of oral cavity carcinomas in other studies could be inadvertent classification of HR HPVpositive base of tongue cancers as oral cavity (mobile tongue) cancers. Additional larger cohort studies are awaited to evaluate the proportion of HR HPV-positive oral cavity SCCs in Korea.

We noted that the proportion of HPV-associated tonsillar SCCs significantly increased, from 62.0% to 79.5%, over a decade of time by comparing the p16-positive proportion of the previous and current case series from a single hospital. The seven earlier Korean studies documenting HPV DNA status in tonsillar SCCs showed either a rate comparable to the 78.9% of our series or a much lower rate at 20%–30% (Table 3). If not attributable to a lower sensitivity of the particular HPV detection method used in the latter group of studies, the explanation for the lower HPV prevalence may be sought in the cohort characteristics. HPV-positive oropharyngeal SCCs are known to be associated with certain epidemiologic factors, such as younger age at onset, higher socioeconomic status, less tobacco/alcohol consumption and a greater number of lifetime sexual partners in Western studies [43]. Two of the four studies reporting lower HPV prevalence provided p16 positivity rates that did not vary greatly from their HPV detection rates [19,28]; this supports the possibility of true heterogeneity in HPV prevalence among different Korean cohorts. Further studies using a large cohort with consideration of socioeconomic risk factors are warranted to examine the prevalence of HPV-associated tonsillar/oropharyngeal carcinomas in Korea.

HPV16 was the most common HR HPV genotype both among non-oropharyngeal HN SCCs (90%, 9/10) and among oropharyngeal SCCs (83.9%) (Table 1) in our dataset as it has been known [2,31]. For the oropharyngeal SCC series, the second most common HR HPV type was HPV35 (7.4%, 11/149). Literature on HPV types of oropharyngeal SCCs in other countries shows that HPV16 almost always comprised 85%–90% and that HPV33 and HPV35 frequently ranked second or third comprising usually less than 5% each [11,44-46]. In the six Korean tonsillar SCC studies reporting HPV genotypes (Table 3), HPV33 and/or HPV18 were often second most frequent to HPV16. Of note is that the recently developed 9-valent HPV vaccine targets seven HR types including HPV16, 18, 31, 33, 45, 52, and 58, thus not likely offering protection against HPV35. More studies on HPV genotypes in Korean oropharyngeal carcinomas are anticipated to evaluate the prevalence of HPV35.

In conclusion, we have examined the prevalence of HR HPV in 466 HN SCCs according to the five subsites of oral cavity, oropharynx, larynx, hypopharynx and sinonasal tract. The oropharyngeal SCCs showed the highest rate of HR HPV positivity among the HN subsites at 72.3%, and the rate peaked at 78.9% when only tonsillar carcinomas were considered. The proportion of HR HPV-positive tonsillar carcinomas significantly increased over a decade of time in a single hospital. As it has been known, p16 immunopositivity showed a good concordance with HR HPV DNA for oropharyngeal and especially tonsillar carcinomas. The use of p16 IHC may further be extended to predict HR HPV positivity in sinonasal tract SCCs.

Fig. 1.

High-risk (HR) human papillomavirus (HPV) prevalence and p16 positivity in tonsillar squamous cell carcinomas (SCCs) across years at diagnosis. Trends in the proportion of HR HPV-positive (black line) and p16-positive (grey line) newly diagnosed tonsillar SCCs for the Seoul St. Mary’s Hospital cohort. Numbers above or below a datapoint indicate the total number of tests done in the corresponding year (black, HPV polymerase chain reaction; grey, p16 immunohistochemistry).

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Figure & Data

References

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