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Introduction

Head and neck squamous cell carcinomas (HNSCCs) are a group of common malignant cancers and account for more than 550,000 cases annually worldwide, and involve the oral cavity, larynx, hypopharynx and oropharynx (1). Tobacco use and alcohol consumption are two well-established risk factors, while epidemiological evidence suggests that a subgroup of HNSCCs results from the infection of high-risk types of human papillomavirus (HPV), particularly HPV16 (2,3).

One of the most frequent alteration in HNSCCs is perturbation of the p53 pathway which regulates the cell cycle to conserve genomic stability and prevent mutations (4). Most of the TP53 mutations occur in exon 5–8. Traditional risk factors such as tobacco use lead to abrogation of p53 by mutation. In contrast, HPV obviates the need for mutation by encoding the E6 oncoprotein, which promotes degradation of wild-type p53 in the presence of the E6-AP complex (5), causing perturbation of cell cycle regulation. It has been found that HNSCCs with HPV infection show a lower frequency of mutations in TP53 when compared to HNSCCs without HPV infection (6,7). However, whether this phenomenon exists in Chinese patients is not definitive.

The TP53 gene has more than 200 single-nucleotide polymorphisms (SNPs), most of which have no biological effects. However, SNP of codon 72 (SNP72) within exon 4, which encodes either proline (Pro, by codon CCC) or arginine (Arg, by codon CGC), appears to be able to influence the function of p53. Compared to TP53 encoding proline, TP53 encoding arginine is more effective at inducing apoptosis and preventing cells from neoplastic development (8,9). Although the association of the SNP72 with various types of cancers including lung and cervical cancer has been reported (10,11), the effect of the polymorphisms on HNSCCs with HPV infection remains uncertain.

In the present study, we analyzed mutations of TP53, the phenotype of SNP72 and the expression profiles of p53 in 93 Chinese patients with HNSCCs. Collectively with the HPV infection status and pathological and clinical data as previously described (12), possible correlations among the mutations in TP53, the phenotype of SNP72, the expression profiles of p53, HPV infection, and the pathological and clinical features were comprehensively analyzed in the group of laryngeal carcinomas and other HNSCCs (from other sites).

Materials and methods

Patients and specimens

A total of 93 patients with malignant squamous tumors were enrolled in the present study. The specimens consisted of 64 laryngocarcinoma and 29 other HNSCCs (5 oropharyngeal, 15 hypopharynx and 9 lip carcinoma). Details of the cases are provided in Table I. The professions of the patients varied and included laborers, teachers, medical staff and clients. The permanent residences of the patients were widely distributed throughout China. All samples were surgically removed and were conventionally fixed in 10% formalin and paraffin-embedded. Pathological assays verified that all cancers were squamous cell cancers. The pathological and clinical grades were assessed by pathologists and surgeons at the Peking University Cancer Hospital and Institute, respectively.

Table I Clinicopathological features and p53 status in the HNSCC patients.

Table I

Clinicopathological features and p53 status in the HNSCC patients.

Patient characteristics	N	TP53 mutation n/N (%)	p53 IHC positive n/N (%)
All patients	93	35/93 (37.6)	34/93 (36.6)
Gender
Male	84	33/84 (39.3)	32/84 (38.1)
Female	9	2/9 (22.2)	2/9 (22.2)
Age (years)
<40	5	2/5 (40.0)	3/5 (60.0)
40–65	69	26/69 (37.7)	24/69 (34.8)
>65	19	7/19 (36.8)	7/19 (36.8)
Anatomical diagnosis
Larynx	64	22/64 (34.4)	20/64 (31.3)
Other carcinomas	29	13/29 (44.8)	14/29 (48.3)
Pathological grades
1 (carcinoma in situ)	2	1/2 (50.0)	0/2 (0)
2 (poorly diff.)	15	5/15 (33.3)	7/15 (46.7)
3 (moderately diff.)	50	19/50 (38.0)	19/50 (38.0)
4 (highly diff.)	26	9/26 (34.6)	8/26 (30.8)
Clinical stage
I	28	12/28 (42.9)	13/28 (46.4)
II	35	15/35 (42.9)	9/35 (25.7)
III	25	7/25 (28.0)	11/25 (44.0)
IV	5	1/5 (20.0)	1/5 (20.0)

[i] HNSCCs, head and neck squamous cell carcinomas; IHC, immunohistochemistry.

DNA extraction

Total DNAs from the tumor tissues were extracted from the paraffin-embedded tissue blocks with a commercial genomic DNA extraction FFPE kit (Qiagen). Briefly, 4 to 5 formalin-fixed, paraffin-embedded (FFPE) sections (10 μm) were soaked in xylene and vortexed vigorously for at least 1 h. Then the pellet was acquired and purified in accordance with the kit protocol. The DNA extraction was evaluated by electrophoresis on 2% agarose gel. Quality of the extracted DNAs was assessed with a settled PCR protocol with a pair of β-actin-specific primers.

PCR protocol for SNP72 in exon 4 and exons 5–8 of P53

SNP72 in exon 4 and exons 5–8 of the TP53 gene was amplified using polymerase chain reaction (PCR) in a Bio-Rad S1000 Thermal Cycler. The primer sequences and amplicons are listed in Table II. The reaction mixtures consisted of a total of 50 μl containing 1 μl of gDNA, 20 pmol of sense and antisense primers, 21 μl RNase-free water and 25 μl 2X Taq MasterMix (CW0682; CWBIO, China). Touchdown method was adopted to increase the specificity of the PCR products. Details of the PCR condition were as follows: denaturing at 95°C for 30 sec, annealing at 65°C for 45 sec with a decrease of 1°C every cycle in the first 10 cycles and 55°C for the other 35 cycles, and extension at 72°C for 45 sec. All PCR assays were carefully carried out in the PCR laboratory with 4 separated rooms to avoid DNA contamination.

Table II Primer sequences and amplicons of SNP72 and exon 5–8 in the TP53 gene.

Table II

Primer sequences and amplicons of SNP72 and exon 5–8 in the TP53 gene.

	Primer pairs (5′-3′)	Amplicons (bp)
SNP72	F: TTGCCGTCCCAAGCAATGGATGA	199
	R: TCTGGGAAGGGACAGAAGATGAC
Exon 5	F: TGTTCACTTGTGCCCTGACT	268
	R: CAGCCCTGTCGTCTCTCCAG
Exon 6	F: GCCTCTGATTCCTCACTGAT	181
	R: TTAACCCCTCCTCCCAGAGA
Exon 7	F: CTTGCCACAGGTCTCCCCAA	237
	R: AGGGGTCAGAGGCAAGCAGA
Exon 8	F: TTCCTTACTGCCTCTTGCTT	231
	R: AGGCATAACTGCACCCTTGG

[i] SNP72, single-nucleotide polymorphisms in codon 72. F, forward; R, reverse.

Direct sequencing

The PCR products were analyzed on 2% agarose gel and recovered from the gel using the QIAquick Gel extraction kit (cat. no. 28706; Qiagen, Germany) according to the manufacturer’s instructions. Direct sequencing was performed using the same PCR primers by the ABI PRISM™ 3730xl DNA analyzer.

Immunohistochemical (IHC) assay

Paraffin sections (5 μm) were routinely deparaffinized in xylene for 5 min twice and gradually rehydrated. Sections were quenched for endogenous peroxidases in 3% H2O2 in methanol for 15 min, pretreated with enzyme digestion antigen retrieval for 1 min. After blocking in 1% normal goat serum to avoid nonspecific binding, the sections were incubated overnight at 4°C with a 1:500-diluted mAb for p53 (Novus). The sections were then incubated for 60 min with 1:1,000-diluted HRP-conjugated goat anti-mouse secondary antibody (Vector Laboratories, USA), and visualized by incubation with 3,3-diaminobenzidine tetrahydrochloride (DAB). The slices were dehydrated and mounted in Permount. For the negative controls, the primary antibody for p53 was replaced with mouse non-immuno IgG. Images were captured with a DP70 digital camera mounted on a BX5 microscope (Olympus Optical, Japan) (12). The slides were analyzed separately by 2 independent observers blinded to the clinical data. The immunoreactivity in the malignant cells in each section was graded according to the number of positively stained nuclei: <1% as negative, ≥1 and ≤10% as weakly positive, >10% as strongly positive.

Prediction of p53 protein function for the different mutations in each Transcriptional activity (TA) class

Functional classification was based on the overall TA of 8 different promoters (WAF1, MDM2, BAX, H1433s, AIP1, GADD45, NOXA and P53R2) as measured by Kato et al(13). For each mutant, the median of the 8 promoter-specific activities was calculated, and missense mutations were classified as ‘non-functional’ (median ≤20), ‘partially functional’ (median >20 and ≤75), ‘functional’ (median >75 and ≤140) and ‘supertrans’ (median >140).

Sorting intolerant from tolerant (SIFT) class

SIFT (14) predicts whether an amino acid substitution affects protein function based on sequence homology and the physical properties of amino acids. Briefly, SIFT searches for similar sequences to the query sequence, chooses closely related sequences that may share similar function to the query sequence, obtains the alignment of these chosen sequences, and calculates normalized probabilities for all possible substitutions from the alignment. Positions with normalized probabilities <0.05 are predicted to be deleterious; those ≥0.05 are predicted to be tolerated.

Statistical analysis

Statistical analysis was performed using Chi-square and Fisher’s exact tests for correlations between groups in regards to HPV infection, SNP72 phenotype, P53 mutations and IHC. Mann-Whitney U test was used for the relationship between SNP72 and age. Probability values of <0.05 were considered to indicate statistically significant results. All statistical analyses were performed by SPSS 20 (IBM, US).

Statement of ethics

Written consent for further investigation and publication was obtained from the patients or the patients’ relatives, respectively. Usage of the stored human samples in this study was approved by the Ethics Committees of Peking University Cancer Hospital and Institute and the National Institute for Viral Disease Prevention and Control, China CDC.

Results

Mutations in the TP53 gene in laryngeal carcinoma and other HNSCCs

Altogether, 45 mutations within the TP53 gene were found in the tissues of 35 cases (37.6%) out of the 93 recruited patients by direct sequencing, including 30 mutations in 34.4% (22/64) of patients in the group of laryngeal carcinoma and 15 mutations in 44.8% (13/29) of patients in the group of other HNSCCs. The detailed information of the individual mutations is documented in Tables I and III. Most of the mutations (93.3%, 42/45) were missense and only 3 were nonsense. Six mutations generated stop codons, 2 deletions and 1 insertion led to frameshift mutations. The mutations at codon 245 within exon 7 and codon 271 within exon 8 were most frequently observed; both were detected in 4 cases. A mutation at codon 266 was observed in 3 cases and mutations at codons 248, 267 and 298 were detected in 2 cases, respectively. Meanwhile, most of the patients (28/35, 80%) had only one mutation in the TP53 gene. Only one patient had 4 mutations, 1 case had 3 mutations and 5 cases had 2 mutations. Two cases contained 2 mutations in the same exon region. Additionally, the locations of the mutations were frequently distributed at the hypervariable region of TP53.

Table III Individual TP53 mutations and the predicted functional changes of p53 proteins.

Table III

Individual TP53 mutations and the predicted functional changes of p53 proteins.

Group	Sample no.	Exon	Mutated codon	Mutation by sequencing	Amino acid change	Change in properties	Motif structure	Protein function
								TA class	SIFT class
Larynx	20	8	281	GAC>AAC	Asp>Asn	Acid>polar	LSH	NF	D
	23	7	249	AGG>ACG	Arg>Thr	Alkaline>polar	L3	NF	D
	37	5	163	TAC>TGC	Tyr>Cys	Aromatic>sulfurated	S4	NF	D
	38	5	158	CGC>GGC	Arg>Gly	Alkaline>hydrophobic	S4	NF	D
		7	248	CGG>CAG	Arg>Gln	Alkaline>polar	L3	NF	D
	41	5	145	CTG>ATG	Leu>Met	Hydrophobic>polar	S3	F	N
	46	7	245	GGC>TGC	Gly>Cys	Hydrophobic>polar	L3	NF	D
	50	6	194	CTT>CAT	Leu>His	Hydrophobic>alkaline	L2	NF	D
		7	245	GGC>AGC	Gly>Ser	Hydrophobic>polar	L3	NF	D
	63	5	151	CCC>TCC	Pro>Ser	Hydrophobic>polar	L	NF	D
	64	7	242	TGC>TTC	Cys>Phe	Polar>hydrophobic	L3	NF	D
	65	8	266	GGA>GAA	Gly>Glu	Hydrophobic>acid	S10	NF	D
	66	8	298	GAG>TAG	Glu>stop	NA	C-term	NF	D
	69	5	175	CGC>CAC	Arg>His	No change	L2	NF	D
	70	5	179	CAT>CGT	His>Arg	No change	L2	NF	D
		8	298	GAG>GGG	Glu>Gly	Acid>hydrophobic	C-term	F	N
	74	6	207	GAT>AAT	Asp>Asn	Acid>polar	S6	F	D
	79	7	259	GAC>AAC	Asp>Asn	Acid>polar	L	PF	N
	81	7	245	GGC>GAC	Gly>Asp	Hydrophobic>acid	L3	NF	D
	83	7	Intron	AGGTC>AGATC		NA	NA	NA	NA
		8	266	GGA>TGA	Gly>stop	NA	S10	ND	ND
		8	267	CGG>CGT	Arg>Arg	No	change	S10	NA
	84	4	47	CCG>TCG	Pro>Ser	Hydrophobic>polar	N-term	S	N
	85	4	51	GAA>TAA	Glu>stop	NA	N-term	ND	ND
		7	Intron	ACCCT>ACTCT		NA	NA	NA	NA
		8	266	GGA>TGA	Gly>stop	NA	S10	ND	ND
		8	267	CGG>CGT	Arg>Arg	No	change	S10	NA
	86	5	166	7 base deletion	Frameshift mutation	NA	L2	NA	NA
	88	7	251	ATC>ATT	Lle>Lle	No change	S9	NA	NA
	92	8	303	AGC>AAC	Ser>Asn	No change	C-term	F	N
Other carcinomas	1	8	271	GAG>TTG	Glu-Val	Acid>hydrophobic	S10	NF	D
	2	8	271	GAG>TTG	Glu-Val	Acid>hydrophobic	S10	NF	D
	5	7	241	1 base insert	Frameshift mutation	/	L3	NA	NA
	8	5	168	CAC>CCC	His>Pro	Alkaline>hydrophobic	L2	NF	D
	9	7	245	GGC>GAC	Gly>Asp	Hydrophobic>acid	L3	NF	D
	11	8	274	GTT>TTT	Val>Phe	No change	LSH	NF	D
	14	6	219	CCC>TCC	Pro>Ser	Hydrophobic>polar	S7	NF	D
	15	5	157	10 base deletion	Frameshift mutation	NA	S4	NA	NA
		8	271	GAG>TTG	Glu-Val	Acid>hydrophobic	S10	NF	D
	16	8	271	GAG>TTG	Glu-Val	Acid>hydrophobic	S10	NF	D
	17	5	146	TGG>TGA	Trp-stop	NA	S3	ND	ND
	22	7	248	CGG>CAG	Arg>Gln	Alkaline>polar	L3	NF	D
Other	27	6	220	TAT>TGT	Tyr>Cys	No change	S	NF	D
		7	Intron	GGTCA>GGCCA	NA	NA	NA	NA	NA
	30	8	286	GAA>TAA	Glu>stop	NA	LSH	ND	ND

[i] TA class, transactivation class: NF, non-functional protein; F, functional protein; PF, partial functional protein; S, supertrans; ND, no data; NA, not available. Sorting intolerant from tolerant (SIFT) class: D, deleterious; N, neutral; ND, no data; NA, not available.

Based on the structure domains of p53 described in the IARC p53 database, 6.7% (3/45) of the mutations affected the LSH (loop-sheet-helix) motif (codons 119–135 and 272–287), 11.1% (5/45) affected the L2 domain (between codons 164 and 194), which was needed for the correct folding and stabilization of the central part of the protein, and 20% (9/45) affected the L3 domain (between codons 237 and 250), directly involved in the interaction between the protein and DNA.

With the help of the protocol described by Kato et al(13) and an online software, the possible influences of the identified TP53 mutations on p53 protein function were analyzed and are summarized in Table III. Notably, the two methodologies revealed similar results. Among the 36 point-mutations, 25 were non-functional mutations that will abolish the normal function of p53. Four point-mutations were neutral ones that will not affect the p53 function. Other 5 point-mutations were stop codon mutations, which were not available by the two methods. Only 2 point-mutations (at codons 47 and 207) showed different consequences on p53 function by the two techniques. Additionally, there were 3 different frameshift insertions whose effects on p53 function were also unable to be predicted by the two techniques.

The numbers of patients with mutations in the different exons of the TP53 gene varied largely. Two patients (2/92, 2.2%) contained mutations in exon 4, 10 (10/85, 11.8%) in exon 5, 4 (4/92, 4.3%) in exon 6, 14 (14/89, 15.7%) in exon 7 and 13 (13/92, 14.1%) in exon 8. Although various mutation rates were detected in exons, there was no significant difference in TP53 mutations between the laryngeal carcinoma group and the other HNSCC group.

Correlation of the TP53 mutation status with IHC for p53 protein

The expression profiles of p53 protein in sections of the tumor samples were analyzed by p53-specific IHC. Out of 93 tested primary HNSCCs, 34 showed positive staining for p53 protein. The brown color staining was distributed prominently in the malignant cells, and was localized in the cell nuclei (Fig. 1). Based on the semi-quantitative protocol for p53 immunostaining, the expression profiles of p53 were classified into strongly positive, weakly positive and negative. Twenty-two of the 34 (64.7%, 22/34) p53-positive cases were characterized as strongly positive, while 12 (35.3%, 12/34) were weakly positive. In the group of laryngeal carcinomas, 12 of 64 (18.8%) cases were strongly positive for p53, 8 cases were weakly positive (12.5%) and 44 were negative (68.8%). In the other HNSCC group, 10 of 29 (34.5%) cases were strongly positive for p53, 4 cases were weakly positive (13.8%) and 15 were negative (51.7%). Despite a higher frequency of cases with strongly positivity for p53 in the other HNSCC group, no statistical difference in p53 expression profile was observed between the two groups.

Figure 1 IHC assays of p53 in the tissues of HNSCCs with the anti-p53 monoclonal antibody. According to the percentage of positive nuclei in the cancer cells, the p53 expression profiles in IHC were classified into 3 groups: strongly positive (>10%), weakly positive (1–10%) and negative (<1%), respectively, as shown from top to bottom. From left to right, images are viewed at a magnification of ×40 and ×100, respectively. IHC, immunohistochemistry; HNSCCs, head and neck squamous cell carcinomas.

In the cases with strong positivity for p53, 63.6% (14/22) of the cases contained mutation(s) in the TP53 gene, while 33.3% (4/12) of the cases with weak positivity for p53 presented with TP53 mutations. Further analyses revealed that mutations in exon 5 (P<0.05) and exon 7 (P<0.01) had a significant correlation with p53 positivity in the IHC assays in the laryngeal carcinoma group, as well as in the context of all tested patients (P<0.05), but not in that of the other HNSCC group (Table IV). No significant difference between the mutations in the other exons of TP53 and positivity for p53 in IHC was noted in all the tested groups (Table IV).

Table IV Relationship between mutations in TP53 exon 4–8 and p53 IHC.

Table IV

Relationship between mutations in TP53 exon 4–8 and p53 IHC.

		p53 IHC
		All samples		Larynx		Other HNSCCs
		Pos (%)	Neg (%)	Pos (%)	Neg (%)	Pos (%)	Neg (%)
Exon 4	Pos (%)	2/92 (2.2)	0/92 (0.0)	2/63 (3.2)	0/63 (0.0)	0/29 (0.0)	0/29 (0.0)
	Neg (%)	32/92 (34.8)	58/92 (63.0)	18/63 (28.6)	43/63 (68.2)	14/29 (48.3)	15/29 (51.7)
Exon 5	Pos (%)	7/85 (8.2)b	3/85 (3.5)	5/57 (8.8)b	2/57 (3.5)	2/28 (7.1)	1/28 (3.6)
	Neg (%)	26/85 (30.6)	49/85 (57.7)	14/57 (24.5)	36/57 (63.2)	12/28 (42.9)	13/28 (46.4)
Exon 6	Pos (%)	2/92 (2.2)	2/92 (2.2)	1/63 (1.6)	1/63 (1.6)	1/29 (3.4)	1/29 (3.4)
	Neg (%)	32/92 (34.8)	56/92 (60.8)	19/63 (30.1)	42/63 (66.7)	13/29 (44.9)	14/29 (48.3)
Exon 7	Pos (%)	9/89 (10.1)b	5/89 (5.6)	7/60 (11.7)a	3/60 (5.0)	2/29 (6.9)	2/29 (6.9)
	Neg (%)	23/89 (25.9)	52/89 (58.4)	11/60 (18.3)	39/60 (65.0)	12/29 (41.4)	13/29 (44.8)
Exon 8	Pos (%)	5/92 (5.4)	8/92 (8.7)	2/63 (3.2)	5/63 (7.9)	3/29 (10.3)	3/29 (10.3)
	Neg (%)	29/92 (31.5)	50/92 (54.4)	18/63 (28.6)	38/63 (60.3)	11/29 (38.0)	12/29 (41.4)

a P<0.01,

b P<0.05.

{ label (or @symbol) needed for fn[@id='tfn6-or-30-06-2811'] } IHC, immunohistochemistry; HNSCC, head and neck squamous cell carcinomas; Pos, positive; Neg, negative.

Correlation of p53 positivity and HPV E6 positivity in the IHC assays

Our previous study of the 93 patients with head and neck carcinomas demonstrated that 29 samples were HPV16/18 E6-positive in the IHC assays: 18 (18/64, 28.1%) in the laryngeal carcinoma group and 11 (11/29, 37.9%) in the other HNSCC group (12). Further analyses of the possible correlation between HPV E6 positivity and p53 positivity in the tumor tissues showed that in the laryngeal carcinoma group, an equal amount of HPV E6-positive cases were p53 positive, while a higher percentage of HPV E6-negative cases were p53 negative (Table V). In the group of other HNSCCs, markedly fewer numbers of patients with HPV E6 positivity were p53 positive, while a relatively higher percentage of HPV E6-negative cases were p53 positive (Table V). Moreover, the correlation between HPV DNA and p53 protein expression was analyzed, and no difference was found in the laryngeal carcinoma group, the other HNSCCs and all the patients tested.

Table V Relationship between HPV IHC and p53 IHC.

Table V

Relationship between HPV IHC and p53 IHC.

		p53 IHC
		All samples		Larynxa		Other HNSCCsb
		Pos (%)	Neg (%)	Pos (%)	Neg (%)	Pos (%)	Neg (%)
HPV IHC	Pos (%)	12/93 (12.9)	17/93 (18.3)	9/64 (14.1)	9/64 (14.1)	3/29 (10.4)	8/29 (27.6)
	Neg (%)	22/93 (23.7)	42/93 (45.1)	11/64 (17.1)	35/64 (54.7)	11/29 (37.9)	7/29 (24.1)

a P<0.05,

b P<0.1.

{ label (or @symbol) needed for fn[@id='tfn9-or-30-06-2811'] } HPV, human papillomavirus; IHC, immunohistochemistry; Pos, positive; Neg, negative.

Correlation of TP53 codon 72 polymorphism with HNSCCs

The codon 72 of the TP53 gene shows polymorphisms among human beings. Sequencing assays of the tumor samples of the 92 HNSCCs found that the numbers of Arg/Arg homozygotes, Pro/Pro homozygotes and Arg/Pro heterozygotes were 29/92 (31.5%), 17/92 (18.5%) and 46/92 (50.0%), respectively. The potential correlations of the codon 72 polymorphism with a series of characteristics of HNSCCs were evaluated. It demonstrated that the average median age of disease onset (74 years) for patients with the Arg phenotype was significantly older than the age of disease onset (54 years) for the patient with the Pro phenotype in the group of other HNSCCs (P<0.05), whereas the age was slightly older but without statistical difference in the group of laryngeal carcinomas with the Arg phenotype (60 years) compared with patients with the Pro phenotype (55 years) (Fig. 2A). Assessment of the relationship with the pathological features of HNSCCs revealed that all poorly differentiated SCCs in the other HNSCC group had the Pro phenotype, while these phenotypes in poorly differentiated SCCs in the laryngeal carcinoma group were almost equal (Fig. 2B). Evaluation of the linkage of codon 72 polymorphism and the p53 expression profiles found that predominantly more HNSCC cases with the Pro phenotype had strong staining for p53 in the tumor tissues, particularly the laryngeal carcinomas in which all p53 strongly stained cases had the Pro phenotype (Fig. 2B). In contrast, the codon 72 polymorphism showed a weak correlation with the p53 expression profile in the other HNSCC group, as a similar frequency of cases with the Pro phenotype was observed in the cases with strong and weak positivity for p53. The pathological features of the carcinomas were classified into 4 degrees including in situ, highly differentiated, moderately differentiated and weakly differentiated cases. In the group of other HNSCCs, all the tumors with weak differentiation had the Pro phenotype, but there was no obvious difference in pathological classification in the laryngeal carcinoma group (Fig. 2C). Additionally, no significant association between SNP72 polymorphism and other factors, including HPV infection, clinical stage, tobacco use and alcohol consumption was found (data not shown).

Figure 2 Association of SNP72 with the features of HNSCC patients. (A) Age of disease onset of the patients with Pro and Arg phenotypes. *P<0.05. (B) p53 expression profiles in IHC with Pro and Arg phenotypes. *P<0.05. (C) Pathological classifications of HNSCCs with Pro and Arg phenotypes. *P<0.05. SNP72, single-nucleotide polymorphisms in codon 72; HNSCCs, head and neck squamous cell carcinomas; IHC, immunohistochemistry.

Discussion

It has been established that TP53, a tumor-suppressor gene, plays a key role in organizing cellular responses to various types of stress, including DNA damage and oncogene activation followed by apoptosis, cell cycle arrest, senescence, DNA repair, cell metabolism or autophagy (15). Malfunction and mutations of p53 have been found in most types of human cancers, leading to deregulated p53 activity of proliferation and uncontrolled survival.

Most TP53 mutations in human cancers are missense mutations and focus on exon 5–8. In many cases, the mutations can either cause a loss of tumor-suppressor function (LOF) or, in some cases, a gain of oncogenic function (GOF) (16). A total of 45 mutations in 35 cases were detected in the patients recruited in our study. The relatively high frequency of point-mutations of p53 protein including codons 245, 248, 266, 267, 271 and 298 in the present study was similar with the commonly observed mutation regions of p53. All of these mutated codons were noted in the above 2 cases. For codon 245, all mutations, including Gly to Cys, Gly to Ser and Gly to Asp, led to a change from hydrophobic protein to a polar or acid one. At codon 271, 4 cases had the same mutation from Glu to Val, resulting in a change from acid protein to a hydrophobic one. Moreover, most of the mutations occurred in the L or S motif structure of p53. Compared with the mutation rates reported in other countries, the mutation rate in the present study (35/93, 37.6%) was slightly higher than the data in Indian (17,18) HNSCC tissues which showed various TP53 mutations in 17–21% of patients, but was slightly lower than the TP53 mutations reported from USA, Europe and Japan ranging from 39 to 69% (19–21).

Based on the functional assays of a published protocol (13) and an online software, we forecasted that most of the identified point-mutations in TP53 (25/36) in this study p53 protein will result in changes of wild-type p53 to a non-functional form. A few point-mutations (4/36) are a neutral form that do not affect p53 function. Only the mutation at codon 47 in 1 case was predicted by one technique to be able to induce a change to the supertrans form that may result in stronger p53 activity. In addition, 5 stop codon point-mutations and 3 different frameshift insertions, which were not recognized with the above two methodologies, definitely interrupt the expression of normal p53 and eventually cause p53 dysfunction. Wide distributions in the non-functional p53-related point-mutations, as well as stop codon mutations and frameshift insertions in the TP53 gene in HNSCC cells emphasize again the essential role of p53 in carcinogenesis.

Normally, the half-life of wild-type p53 protein is short which makes it difficult to be detected by immunohistochemistry, whereas the mutated p53 protein is fairly stable which can easily be identified in tumor cells by immunohistochemistry (22). In agreement with previous data, we also determined that p53 overexpression is a frequently observed event in Chinese patients with HNSCCs (23). However, we did not find any significant correlation between the p53 expression profiles in the tumor tissues and a series of parameters, including gender and age of the patients, various pathological classifications and clinical stage. Compared with previous studies that demonstrated that p53 overexpression is more prevalent in laryngeal tumors than in tumors in other anatomical sites (24), our data found a relatively lower positive rate of p53 in laryngeal tumors (31.3%) than that in other HNSCCs (48.3%), although no statistical difference was achieved.

HPV is another important etiologic factor, in addition to tobacco and alcohol for HNSCCs, particularly for oropharyngeal cancer (25). During the past few decades, HPV DNA has been detected in ~25% of HNSCCs overall. More importantly, 45–100% of oral SCC cases are reported to be HPV-positive (25,26). The data in our previous study also showed that HPV-positive rates had a significant association with the anatomic sites of tumors (12). In line with many published data, we also found that the p53-positive rate of patients with HPV16/18 E6 positivity was lower than that of the cases with HPV E6 negativity in the group of other HNSCCs. However, this phenomenon was not observable in the patients with laryngeal tumors, in which the p53-positive rates of the patients with HPV16/18 E6 positivity or negativity were comparable. These data highlight that the contrary correlation between HPV16/18 E6 positivity and p53 positivity was more likely detected in the SCCs that occurred in the oropharyngeal site. Further statistical analysis of the presence of p53 mutations and HPV infection or between HPV DNA and p53 protein expression failed to reveal any significant relationship in HNSCCs in our study. This possibly implies that either TP53 mutation or expression of high-risk HPV E6 may independently lead to p53 inactivation during the pathogenesis of HNSCCs.

The codon 72 polymorphism of p53 results in a substitution of Pro for Arg in the amino acid sequence and thus has an impact on the binding capacity and functional properties of p53 (27). Previous reports suggest that the p53 codon 72 polymorphism is associated with the susceptibility to several types of cancers and the survival of cancer patients (28,29). In the present study, we found that the p53 Arg/Pro heterozygote was the major phenotype (49.5%) among the cohort of 92 patients, while the homozygous phenotype Arg/Arg and Pro/Pro accounted for a lower percentage of 31.2 and 18.3%, respectively. The SNP72 polymorphism has not been significantly linked with many factors, such as HPV infection, clinical stage, tobacco use and alcohol consumption. However, the cases having the Arg phenotype exhibited an obvious tendency to have an older age of disease onset and a higher degree of differentiation in pathology than the cases having Pro72. In addition, in the group of laryngeal carcinomas, all patients showing strongly positive p53 overexpression had the Pro phenotype. These results are in accordance with the conclusion that the wild-type Arg allele has a greater ability to localize to mitochondria, thereby inducing apoptosis to a greater exent than Pro72 (30,31). It has been confirmed that Arg/Pro and Prp/Pro phenotypes of p53 codon 72 are significantly associated with an increased risk of secondary primary malignancy (SPM) in patients with HNSCCs (32). Whether such an association exists in our patient cohort deserves long-term follow-up.

Acknowledgements

This study was supported by the China Mega-Project for Infectious Disease (2011ZX10004-101, 2012ZX10004215), the Young Scholar Scientific Research Foundation of China CDC (2012A102) and the SKLID Development Grant (2012SKLID102 and 2011SKLID211).

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References