Presently, CD133 is one of the hottest markers to characterize cancer stem cells and KAI1/CD82 is reported as an important marker for the metastasis and prognosis of many cancers. The purpose of our study is to explore the relationship between cancer stem cells (CSCs) marked by CD133 and KAI1/CD82 expression and the clinicopathological characteristics of patients with laryngeal squamous cell carcinoma (LSCC).
Methods
Immunohistochemical analysis was used to detect the expression of CD133 and KAI1/CD82 in 83 archival surgical specimens of human LSCC and 83 cases of normal laryngeal tissues.
Results
In LSCC, positive rates of 49.4% and 41.0% were obtained for CD133 and KAI1/CD82, respectively. The expression of CD133 in LSCC tissues was significantly higher than that in normal tissues (P < 0.001), and the expression of CD133 was positively associated with pTNM stage (P = 0.005), pathological grade (P = 0.001), and lymph node metastasis (P < 0.001). The reduced expression of KAI1/CD82 was present in LSCC tissues. The positive rate of KAI1/CD82 expression was negatively correlated with pTNM stage (P = 0.014), pathological grade (P < 0.001), and lymph node metastasis (P = 0.007). A correlation analysis showed that there was a negative relationship between the expression of CD133 and KAI1/CD82 protein in LSCC tissues (P < 0.001). By Kaplan-Meier analysis, the expression of CD133 was negatively correlated with overall survival (OS) (log-rank = 40.949, P < 0.001) and disease-free survival (DFS) (log-rank = 39.307, P < 0.001) time of LSCC. The expression of KAI1/CD82 was positively correlated with OS (log-rank = 40.279, P < 0.001) and DFS (log-rank = 39.271, P < 0.001) time of LSCC. Cox regression analysis: the expression of CD133 and KAI1/CD82, and pTNM stages were independent prognostic factors of LSCC (P < 0.05).
Conclusions
Thus the detection of CD133 and KAI1/CD82 proteins may be used as a potential indicator of LSCC prognosis.
The online version of this article (doi:10.1186/1477-7819-12-118) contains supplementary material, which is available to authorized users.
Lan Yu, Lei Zhou, Shiwu Wu contributed equally to this work.
Competing interests
The authors declare that they have no competing interests.
Authors’ contributions
YL, ZL and WSW carried out the design, analysis of pathology and drafted the manuscript. GXM, FZZ, ML, ZB and YN carried out sample collections and coordination. WDN and DHM performed the immunohistochemical staining. All authors read and approved the manuscript.
Abkürzungen
LSCC
laryngeal squamous cell carcinoma
CSC
cancer stem cells
pTNM
pathological tumor-node-metastasis
OS
overall survival
DFS
disease free survival
TM4SF
tetraspan transmembrane superfamily
DAB
diaminobenzidine.
Background
In the United States, laryngeal carcinoma accounted for approximately 0.82% of new cancer diagnoses and 0.40% of all cancer deaths in 2012 [1]. The major pathological type of laryngeal cancers is squamous cell carcinoma, accounting for 99% of laryngeal malignant tumors. Although rapid progress has recently been made in treatment, the prognosis for patients with laryngeal squamous cell carcinoma (LSCC) remains unsatisfactory. A major problem in finding treatments is the frequent resistance to drugs which emerges. This is linked to the development and maintenance of a small population of tumor cells, termed cancer stem cells (CSCs). These cells have the properties of self-renewal, proliferation, and multilineage differentiation and are responsible for sustaining the tumor [2] and are also thought to initiate tumor metastasis and therapy-resistance [3, 4]. A commonly investigated potential CSC marker is CD133 (also known as prominin-1), a 120 kDa five transmembrane domain cell surface glycoprotein, which was initially considered to be one marker of hematopoietic stem cells [5, 6]. Now, CD133 may represent a putative cancer stem cell marker in many solid tumors, such as human colon cancer [7, 8], breast cancer [9, 10], gastric cancer [11, 12], glioblastoma [13], lung cancer [14, 15], liver cancer [16, 17], pancreatic cancer [18], prostate cancer [19], and cholangiocarcinoma [20].
Cancer metastasis involves multiple steps with a high degree of complexity and requires the contribution of a variety of molecules. The KAI1/CD82 gene was originally identified as a suppressor of metastasis of tumor in prostate carcinoma [21]. Recent study has shown that KAI1/CD82 gene expression is under-regulated in most metastatic cancers [22]. It is a member of the tetraspan transmembrane superfamily (TM4SF) and is a gene located on human chromosome 11p11.2. KAI1/CD82 plays an important role in cell fusion, adhesion, migration, signaling, fertilization, differentiation, and invasion [22‐26]. Decreased KAI1/CD82 expression has been observed to correlate with metastasis and poor prognosis in many human solid tumors, such as prostate cancer [27], lung cancer [28], breast cancer [29], colon cancer [30], gastric cancer [31], liver cancer [32], and kidney cancer [33].
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To date, the correlation between CD133 and KAI1/CD82 expression in LSCC is unknown. Therefore, this study intends to investigate CD133 and KAI1/CD82 expression in the specimens of postoperative LSCC patients following primary laryngeal resection in order to determine the correlation between the expression of CD133 and KAI1/CD82 and clinicopathological characteristics acceptable.
Methods
Patients and specimens
Paraffin embedded sections of 83 LSCCs and 83 normal laryngeal tissues were obtained from the Department of Pathology, the First Hospital Affiliated to Bengbu Medical College from January to November 2003. We excluded patients who received preoperative chemotherapy or radiotherapy. Approval for this study was not required by the ethical committee because the experiments carried out did not relate to patient privacy, impairment or treatment. The age of the patients ranged from 43 to 84 years; the median age was 62.1 years. The patients consisted of 75 males and 8 females. There were 43 cases whose tumors were < 2.0 cm in diameter and 40 cases whose tumors were ≥ 2.0 cm. Thirty were at grade I, 47 were at grade II, and 6 were at grade III, according to the grading system of the World Health Organization. Fifty-one were of supraglottic type, 29 were glottic type, and three were subglottic type. A total of 49 specimens had no lymph node metastasis, whereas 34 specimens showed lymph node metastasis. According to clinical staging of pTNM, 21 were stage I, 32 were stage II, 22 were stage III, and 8 were stage IV.
Immunohistochemical analysis
All samples were fixed in 10% buffered formalin and embedded in paraffin. Four- micrometer thick tissue sections were used for analysis. All sections were deparaffinized and dehydrated with graded alcohol. Then, the sections were washed for ten minutes in PBS at pH 7.2. The endogenous peroxidase activity was quenched by incubation in methanol containing 3% H2O2 for ten minutes at room temperature, then heated for 30 minutes at 95°C to repair the antigens and finally rinsed in PBS. After several washes in PBS, sections were blocked with goat serum for 20 minutes at room temperature, and then incubated with mouse monoclonal CD133 (Santa Cruz Biotechnology Inc., Santa Cruz, CA, USA) and KAI1/CD82 (Santa Cruz Biotechnology Inc., Santa Cruz, CA, USA) primary antibodies overnight at 4°C in a humidified chamber. The slides were treated with polymer enhancer (reagent A) for 20 minutes at room temperature. Washing in PBS, the slides were treated with goat anti-mouse antibody (reagent B) for 30 minutes at room temperature. After a complete wash in PBS, the slides were developed in freshly prepared diaminobenzidine (DAB) solution for eight minutes, and then counterstained with hematoxylin, dehydrated, air-dried, and mounted.
Serial sections of LSCC were run in parallel with the primary antibody replaced by PBS and rabbit IgG1 as blank and negative controls.
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Evaluation of score
Slides were reviewed independently by two observers to evaluate the staining pattern of the protein under the light microscope. Ten visual fields were randomly selected from each slide. In scoring expression of CD133 and KAI1/CD82 proteins, both the extent and intensity of immunopositivity were considered. The intensity of the positive result was scored as follows: 0, negative; 1, weak; 2, moderate; 3, strong. The extent of positivity was scored according to the percentage of cells that stained positive: < 10% is 1; 11 to 50% is 2; 51 to 75% is 3; > 75% is 4. The final score was determined by multiplying the intensity of positivity and the extent of positivity scores, which yielded a range from 0 to 12. Expression of CD133 and KAI1/CD82 were considered positive when the scores were ≥ 3.
The positive expression of CD133 was found mainly on the membrane and cytoplasm of LSCC cells and normal laryngeal tissues. The positive expression of KAI1/CD82 was found mainly on the membrane and cytoplasm of LSCC cells and normal laryngeal tissues. They were presented as a brown granular material.
Statistical analysis
Fisher’s exact test, Pearson Chi-square test for trends in proportions, Spearman’s correlate analysis, and Kaplan-Meier’s method with log-rank test or Cox regression method for univariate or multivariate OS analysis were used to assess the associations among the positive staining of CD133 or KAI1/CD82 and clinicopathological indices. SPSS 17.0 software for windows (Chicago, IL, USA) was used for this purpose. A value of P < 0.05 was considered statistically significant.
Results
The association between the expression of CD133 or KAI1/CD82 and clinicopathological factors
CD133 protein was expressed positively in 49.4% (41/83) of LSCC and 4.8% (4/83) of normal laryngeal tissues. There was a significant difference between the LSCC group and the normal laryngeal tissues (P < 0.01) (Figure 1A and B). There was a positive relationship between the expression of CD133 and histological grade, pTNM stage, and lymph node metastasis (P < 0.05). The positive expression of KAI1/CD82 was 41.0% (34/83) in the LSCC group and 96.4% (80/83) in normal laryngeal tissues. A significant difference was found between the LSCC group and the normal group (P < 0.05) (Figure 2A and B). There was a negative relationship between the expression of KAI1/CD82 protein and alcohol, histological grade, pTNM stage, and lymph node metastasis (P < 0.05). However, the expression of CD133 and KAI1/CD82 was not associated with gender, age, tumor localization, smoking, and tumor diameter (P > 0.05) (Table 1).
Figure 1
Expression of CD133 protein in laryngeal squamous cell carcinoma. (A) CD133 was expressed as positive in the membrane of cancer cells (CD133 × 400). (B) CD133 was expressed as positive in the membrane of cancer cells at the invasive cancer (CD133 × 400).
Figure 2
Expression of KAI1/CD82 protein in laryngeal squamous cell carcinoma. (A) KAI1/CD82 was expressed as positive in the membrane of cancer cells (KAI1/CD82 × 400). (B) KAI1/CD82 was expressed as positive in membrane and cytoplasm of cancer cells (KAI1/CD82 × 400).
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Table 1
Correlation of CD133 and KAI1/CD82 expression to clinicopathogical characteristics in laryngeal squamous cell carcinoma (LSCC)
Variable
CD133
P-value
KAI1/CD82
P-value
Negative
Positive
Negative
Positive
Gender
> 0.05
> 0.05
Male
36
39
46
29
Female
6
2
3
5
Age
> 0.05
> 0.05
< 60
15
12
15
12
≥ 60
27
29
35
22
Location
> 0.05
> 0.05
Supraglottic
26
25
26
25
Glottic
15
14
20
9
Subglottic
1
2
3
0
Diameter of tumor
> 0.05
> 0.05
< 2.0 cm
23
20
22
21
≥ 2.0 cm
19
21
27
13
Smoking
> 0.05
> 0.05
No
18
13
15
16
Yes
24
28
34
18
Alcohol
> 0.05
< 0.05
No
20
13
14
19
Yes
22
28
35
15
Grade of tumor
< 0.01
< 0.001
Well-differentiated
23
7
9
21
Moderately-differentiated
18
29
35
12
Poorly-differentiated
1
5
5
1
Lymph node metastasis
< 0.001
< 0.01
No
33
16
23
26
Yes
9
25
26
8
pTNM stage
< 0.05
< 0.05
I and II
33
20
26
27
III and IV
9
21
23
7
Prognosis and multivariate analysis
Follow-up data showed that the OS rate and DFS rate for CD133-positive patients were significantly poorer than that of CD133-negative patients (P < 0.001, P < 0.001, Figure 3). Also, there was a significantly increasing trend in the mean OS survival time and DFS time between the carcinomas with the expression of KAI1/CD82 and those without (P < 0.001, P < 0.001, Figure 4). In the 83 LSCC patients, a univariate analysis (Table 2) revealed that the DFS survival significantly correlated with expression of CD133 (P < 0.001) and KAI1/CD82 (P < 0.001), tumor location (P = 0.033), grade of tumor (P = 0.002), lymph node metastasis (P = 0.004), and pTNM stages (P < 0.001). A multivariate analysis revealed expression of CD133 and KAI1/CD82, lymph node metastasis, and pTNM stages were independent prognostic factors for DFS and OS (P < 0.05) (Tables 3 and 4).
Figure 3
Kaplan-Meier survival analysis by CD133 status (n = 83). (A) The green line represents the CD133-positive group patients with a trend of worse survival than the blue line representing CD133-negative group patients (log-rank = 40.949, P = 0.000). Mean overall survival (OS) time was 42.4 months for the CD133-positive group and 73.3 months for the CD133-negative group. (B) The green line represents CD133-positive group patients with a trend of worse survival than the blue line representing CD133-negative group patients (log-rank = 39.307, P = 0.000). Mean DFS for patients was 37.1 months for the CD133-positive group and 65.6 months for the CD133-negative group.
Figure 4
Kaplan-Meier survival analysis by KAI1/CD82 status (n = 83). (A) The green line represents the KAI1/CD82-positive patient group with a trend of better survival than the blue line representing the KAI1/CD82-negative patient group (log-rank = 40.279, P = 0.000). Mean overall survival (OS) time was 76.0 months for the KAI1/CD82-positive group and 45.5 months for the KAI1/CD82-negative group. (B) The green line represents the KAI1/CD82-positive patient group with a trend of better survival than the blue line representing the KAI1/CD82-negative group patients (log-rank = 39.271, P = 0.000). Mean DFS patients was 68.0 months for the KAI1/CD82-positive group and 40.1 months for the KAI1/CD82-negative group.
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×
Table 2
Results of univariate analyses of disease-free survival (DFS) and overall survival (OS) time
Variable
n
Mean DFS
P-value
Mean OS
P-value
(months)
(months)
CD133
< 0.001
< 0.001
+
41
42.4 ± 18.2
37.1 ± 17.7
-
42
73.3 ± 16.7
65.6 ± 15.4
KAI1/CD82
< 0.001
< 0.001
+
34
76.0 ± 19.3
68.0 ± 17.5
-
49
45.5 ± 16.8
40.1 ± 16.7
Gender
0.035
0.067
Male
75
56.4 ± 23.0
50.0 ± 21.9
Female
8
73.1 ± 21.9
65.6 ± 17.0
Age
0.854
0.280
< 60
27
58.2 ± 21.5
50.9 ± 19.5
≥ 60
56
57.9 ± 24.3
51.8 ± 23.0
Location
0.004
0.065
Supraglottic
51
60.3 ± 24.1
53.9 ± 22.5
Glottic
29
56.4 ± 21.8
49.6 ± 20.5
Subglottic
3
35.0 ± 13.7
29.3 ± 11.2
Diameter of tumor
0.015
0.217
< 2.0 cm
43
65.5 ± 19.5
58.5 ± 18.5
≥ 2.0 cm
40
50.0 ± 24.6
44.0 ± 22.9
Smoking
0.122
0.132
No
31
62.0 ± 26.4
55.3 ± 22.4
Yes
52
55.6 ± 21.2
49.3 ± 20.1
Alcohol
0.365
0.163
No
33
62.4 ± 24.1
54.9 ± 22.5
Yes
50
55.1 ± 22.6
49.2 ± 21.3
Grade of tumor
< 0.001
0.009
Well-differentiated
30
71.7 ± 18.7
64.4 ± 17.6
Moderately-differentiated
47
50.4 ± 22.1
44.5 ± 20.7
Poorly-differentiated
6
49.3 ± 25.3
42.2 ± 22.8
Lymph node metastasis
< 0.001
0.003
No
49
67.6 ± 18.9
60.5 ± 17.4
Yes
34
44.2 ± 22.4
38.6 ± 21.3
pTNM
< 0.001
< 0.001
I and II
53
68.3 ± 19.2
61.3 ± 17.4
III and IV
30
40.0 ± 18.4
34.3 ± 18.0
Table 3
Results of multivariate analyses of disease-free survival (DFS) time
Covariate
B
SE
Sig
Exp(B)
95%CI
CD133
0.747
0.354
0.035
2.110
1.055 to 4.221
KAI1/CD82
-1.282
0.432
0.003
0.278
0.119 to 0.647
pTNM
1.203
0.350
0.001
3.331
1.678 to 6.611
Lymph node metastasis
0.643
0.291
0.027
1.903
1.075 to 3.366
Table 4
Results of multivariate analyses of overall survival (OS) time
Covariate
B
SE
Sig
Exp(B)
95%CI
CD133
0.734
0.351
0.037
2.083
1.046 to 4.146
KAI1/CD82
-1.486
0.449
0.001
0.226
0.094 to 0.545
pTNM
1.191
0.349
0.001
3.292
1.659 to 6.530
Lymph node metastasis
0.747
0.287
0.009
2.110
1.203 to 3.701
Correlation of CD133 and KAI1/CD82 in LSCC
There was a negative correlation between CD133 expression and KAI1/CD82 expression in LSCC (r = -0.578, P < 0.001).
Discussion
Cancer stem cells (CSCs), also known as tumor initiating cells (TICs), are a subpopulation of tumor cells with the stem cell capacity for self-renewal. They give rise to the differentiated cells, and generate the heterogeneous lineages of cancer cells that comprise the bulk of the tumor [2, 7, 11, 20, 34‐39]. CSCs may originate by malignant transformation of normal stem cells or arise from restricted progenitors of more differentiated cells [40]. The protein CD133 is one of the hot CSC markers in a variety of tumors [7‐20]. In this study, we found that the positive expression of CD133 was 49.4% in LSCC patients. The study investigated the expression of CD133 protein in 83 LSCC specimens with follow-up data and the results indicated that CD133 protein expression level was positively correlative with grade of tumor (P = 0.001), lymph node metastasis (P < 0.001), and pTNM stage (P = 0.005). Furthermore, we also found the expression of CD133 was significantly associated with OS time (P < 0.001) and DFS time (P < 0.001), suggesting the expression of CD133 might be a potential prognostic factor in LSCC. Another result is that not only LSCC cell express CD133 but also normal laryngeal tissue (squamous epithelial cells). This indicated that CD133 might play an important role in tumorigenesis [8].
The metastasis suppressor gene KAI1/CD82 might be a useful marker for the metastatic and prognostic potential in a series of human tumors. The precise mechanism for the regulation of KAI1/CD82 is unclear. But, in the progression of many tumors, the most common mechanism was down-regulation or loss-regulation rather than mutation [22, 24]. Our study results showed that KAI1/CD82 was negatively associated with grade of tumors (P < 0.001), lymph node metastasis (P = 0.007), and pTNM stage (P = 0.014). From further research, we found that the KAI/CD82-positive-group correlated with longer survival time, a result which was in agreement with previous reports [32, 41, 42].
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Our research also showed that CD133 expression was negatively correlated with KAI1/CD82 expression (P < 0.001). CSCs can manipulate stromal cells to their needs in distant organs and thus prime the foreign soil for their arrival by inducing a premetastatic niche [43]. This indicates that CSCs have high migratory potential and may be responsible for metastasis [44]. Down-regulation of KAI1/CD82 may further promote the metastatic ability of CSCs. Although the precise molecular mechanism involved in this process is unclear, our research has potential clinical benefits. CD133 and KAI1/CD82 expression, which could be detected by immunohistochemistry, might be a useful molecular marker to predict the prognosis in LSCC patients. It is concluded that the expression of CD133 and KAI1/CD82 protein could be correlated with lymph node metastasis, grade of tumor, and pTNM stage in LSCC, and also concluded that they are useful prognostic factors for OS and DFS in LSCC. The combined detection of CD133 and KAI1/CD82 can, to some extent, reflect the biological behavior of LSCC, thus giving the choice of molecular targeting therapy. However, the number of specimens in our study was relatively small. Further studies with larger sized specimens and molecular experiments are needed to verify the present observations.
Conclusions
It is suggested that CD133 and KAI1/CD82 may play an important role in the evolution of LSCC. And CD133 and KAI1/CD82 should be considered as potential marker for the prognosis in patients with LSCC.
Acknowledgments
We thank all colleagues in Department of Pathology, the First Hospital Affiliated to Bengbu Medical College for their help and support in this study. This study was partially supported by Anhui Province College Excellent Young Talents Found Project (No.2012SQRL094 and 2012SQRL095) and the Natural Science Foundation of Anhui Province (No.1208085MH152) and Education Department of Anhui General Project (KJ2011B100). All authors have contributed greatly, and all authors are in agreement with the content of the manuscript.
Open Access
This article is published under license to BioMed Central Ltd. This is an Open Access article is distributed under the terms of the Creative Commons Attribution License (
https://creativecommons.org/licenses/by/2.0
), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.
Competing interests
The authors declare that they have no competing interests.
Authors’ contributions
YL, ZL and WSW carried out the design, analysis of pathology and drafted the manuscript. GXM, FZZ, ML, ZB and YN carried out sample collections and coordination. WDN and DHM performed the immunohistochemical staining. All authors read and approved the manuscript.
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