Introduction
Since cancer stem cells (CSCs) in solid cancers [
1,
2] were first reported in the early half of the 2000s, the establishment of a treatment targeting CSCs for radical cure of cancer has become an important goal. Therefore, the search for markers to isolate CSCs and characterize cells isolated with these markers has been active throughout the world.
CD133 is a 120-kDa glycoprotein with five transmembrane domains and is a CSC marker. Despite various theories, the biological function of CD133 is still not well understood. Originally, CD133 was known as a surface marker of hematopoietic stem cells and progenitor cells, but CD133 has also recently been reported as a marker of CSCs in solid cancers such as brain tumors [
2], lung cancer [
3], liver cancer [
4], colon cancer [
5,
6], pancreatic cancer [
7], and prostate cancer [
8]. In addition, in lung cancer [
9], breast cancer [
10], hepatocellular carcinoma [
11], colon cancer [
12], and pancreatic cancer [
13], CD133 expression has been reported to be strongly related not only to tumor progression, but also to treatment resistance.
However, despite the large number of patients with gastric cancer in Japan, CSCs in gastric cancer have not been definitively reported, and few studies evaluating CD133 expression have been reported. In highly advanced gastric cancer and recurrent gastric cancer, compared to colon cancer, there is still no effective treatment, and survival rates remain low. Therefore, identification of gastric CSCs and establishment of treatment will be highly important in future gastric cancer therapy.
Regarding CSCs, a hypoxic environment has recently been shown to be necessary to maintain CSCs [
14]. Hypoxia-inducing factor-1alpha (HIF-1α) is a downstream molecule in the mammalian target of rapamycin signaling pathway, is induced by hypoxemia, and acts as a transcription factor. HIF-1α has attracted attention as a factor that regulates CD133 expression, and the relationship between CD133 expression and HIF-1α expression has been investigated in various solid cancers. Most studies have shown a correlation between CD133 expression and HIF-1α expression [
15,
16], but interestingly, downregulation of CD133 expression by HIF-1α expression in a gastric cancer cell line has also been reported [
17].
In this study, we investigated the clinicopathological role of CD133 expression in gastric cancer by immunostaining clinical specimens from gastric cancer patients. We also evaluated the relationship between CD133 expression and prognosis of gastric cancer. In addition, we examined the relationship between CD133 expression and HIF-1α expression using immunohistological staining of gastric cancer tissue specimens.
Materials and methods
Patients
Paraffin specimens from 189 gastric cancer patients who underwent gastrectomy between January 2004 and August 2006 at Kurume University Hospital were selected. Double cancer, multiple cancer, mucosal cancer, postendoscopic mucosal resection, and endoscopic submucosal dissection cases were excluded from this study. Histopathological characteristics and each classification are defined in the Japan Classification of Gastric Carcinoma (14th edition) [
18]. The patient characteristics are shown in Table
1. Mean age was 66 years, and there were more men than women. Regarding histological type, we divided the patients into a differentiated group (tub1, tub2, pap), and an undifferentiated group (por1, por2, sig, muc). The residual tumor (R) was defined as R0, no residual tumor; R1, microscopic residual tumor (positive resection margin or CY1); or R2, macroscopic residual tumor. None of the patients had received preoperative adjuvant therapy, but 82 patients had received postoperative adjuvant therapy.
Table 1
Patient information
Age (mean ± SD), years | 66 ± 11 |
Gender (male/female) | 133/56 |
Tumor size (mean ± SD), mm | 66 ± 38 |
Histological typea (differentiated/undifferentiated) | 81/108 |
Stage (I/II/III/IV) | 62/41/52/36 |
Surgery |
Total gastrectomy (include remnant gastrectomy) | 72 |
Distal gastrectomy | 99 |
Proximal gastrectomy | 11 |
Segmental gastrectomy | 7 |
R (residual tumor)b, 0/1/2 | 144/11/34 |
Adjuvant chemotherapy (−/+) | 107/82 |
Regimen |
TS-1c
| 37 |
Oral anticancer drug except TS-1 | 25 |
TS-1 + continuous infusion anticancer drug | 15 |
Details unknown | 5 |
This study was authorized in advance by the Ethics Committee of Kurume University (study number 11040).
CD133 staining
CD133 expression and HIF-1α expression were examined with immunohistochemical staining. Surgical specimens were fixed in 10 % formaldehyde, embedded in paraffin, and cut into 4-μm-thick sections. We chose the most invasive section from the gastric cancer tumor. Sections were deparaffinized in xylene and rehydrated in a graded series of ethanol. Slides were heated at 120 °C in an autoclave in 10 mM sodium citrate (pH 6.0) for 10 min and then cooled to room temperature. After blocking with 10 % horse serum, the sections were incubated overnight at 4 °C with mouse monoclonal anti-CD133 antibody [Milteny Biotec, Auburn, CA, USA; diluted 1:100 in phosphate-buffered saline (PBS)]. After washing, sections were overlaid with secondary antibody (VECTASTAIN elite ABC kit Universal; Vector Laboratories, Burlingame, CA, USA) for 30 min at room temperature. Sections were incubated in 3.0 % hydrogen peroxide in PBS for 30 min to block endogenous peroxidase activity. The reaction was developed using avidin–biotin–peroxidase complex. The peroxidase reaction was developed with 3-amino-9-ethylcarbazole, and sections were counterstained with hematoxylin. Colon cancer sections were used as a positive control. Negative control sections (isotype control) were incubated with normal mouse serum instead of the primary antibody.
HIF-1α staining
Isobe et al. [
19] have reported detailed methods for immunohistochemical staining of HIF-1α. Briefly, 4-μm-thick sections were cut from archival formalin-fixed paraffin-embedded tissue blocks. Slides were irradiated at 99 °C in a microwave oven for 30 min in 10 mM citrate buffer (pH 9.0) and cooled to room temperature. The sections were incubated overnight at 4 °C with rabbit polyclonal anti-HIF-1α antibody H206 (Santa Cruz Biotechnology, Santa Cruz, CA, USA; diluted 1:100 in PBS), and reactions were developed using the same method as CD133 staining.
Double immunohistochemical staining
To clarify the localization of CD133 in gastric cancer cells, double immunohistochemical staining with anti-CD133 antibody and anti-cytokeratin 8 antibody was performed in some cases. The reaction was developed using anti-mouse poly-alkaline phosphatase (AP) and anti-rabbit poly-horseradish peroxidase (HRP) polymerization technology. We used a cocktail of primary antibodies containing the same anti-CD133 antibody (diluted 1:100 in PBS) and rabbit monoclonal anti-cytokeratin 8 antibody (Abcam, Cambridge, UK; diluted 1:50 in PBS). After incubating overnight at 4 °C, sections were overlaid with secondary antibody (MACH2 Double Stain 1 Mouse-AP ± Rabbit-HRP; Biocare Medical, Concord, CA, USA). The alkaline phosphatase reaction for the anti-CD133 antibody was developed with Vulcan fast red chromogen (Biocare Medical; Vulcan Fast Red Chromogen Kit2), and the peroxidase reaction for the cytokeratin 8 antibody was developed with 3,3′-diaminobenzidine (DAB).
In addition, to confirm both CD133 and HIF-1α expression in gastric cancer, double immunohistochemical staining was performed in some cases. The reaction was developed using AP and HRP polymerization technology as described above. We used a cocktail of primary antibodies containing the same anti-CD133 antibody (diluted 1:100 in PBS) and the same anti-HIF-1α antibody (diluted 1:100 in PBS). The secondary antibody and the alkaline phosphatase reaction were developed using the same methods as described for the CD133 + cytokeratin 8 staining. The peroxidase reaction for the anti-HIF-1α antibody was developed with DAB.
Statistical analysis
For comparison of categorical data, the chi-square test and Fisher’s exact test were used. The overall survival rate was calculated using Kaplan–Meier analysis, and differences between the groups were compared using the log-rank test. For multivariate analysis, prognostic factors were analyzed using Cox’s proportional hazard model. All statistical analysis was performed using statistical software (JMP 9.0; SAS, Cary, NC, USA). P < 0.05 was considered statistically significant.
Discussion
We found that CD133 protein expression in gastric cancer clinical specimens was the same as that in other solid cancers. CD133 expression was detected in about 30 % of cases. This expression could be broadly divided into two types: glandular-luminal cell membrane surface expression (luminal expression, L-type) and cytoplasmic expression (C-type). Luminal expression was more common in differentiated gastric cancer, and cytoplasmic expression was more common in undifferentiated gastric cancer, and both expression types were seen in some tissue sections. Ishigami et al. [
23] and Zhao et al. [
24] also evaluated CD133 expression in gastric cancer using clinical specimens, and both reported two types of staining results, similar to our findings. Originally, luminal expression of CD133 was reported in colorectal cancer, and cytoplasmic expression of CD133 was reported in pancreatic cancer [
20,
21]. However, both expression types have recently been reported at the same time in colon cancer and in hepatocellular carcinoma [
25,
26].
These reports also support the possibility of two types of CD133 expression in gastric cancer. A definitive difference was reported in another article about the expression of CD133 in gastric cancer [
23]. Ishigami et al. [
23] evaluated the overall CD133 expression in gastric cancer, without dividing the cases into expression types. On the other hand, in our study, we focused on these two expression types, with the analysis divided for each expression type. Ishigami et al. [
23] reported that CD133 expression in gastric cancer is a risk factor for tumor progression, prognosis, depth of invasion, and lymph node metastases. In our study, the CD133 cytoplasmic expression was certainly related to tumor progression, primarily metastasis such as lymph node metastasis, peritoneal dissemination, and vascular invasion. With multivariate analysis, cytoplasmic CD133 expression was an independent prognostic factor. However, we did not find a definitive relationship between luminal CD133 expression and the degree of malignancy.
Sasaki et al. [
25] reported that in hepatocellular carcinoma, cytoplasmic CD133 expression, rather than membranous expression, is related to the degree of malignancy and prognosis. In rectal cancer as well, cytoplasmic CD133 expression is related to local recurrence and prognosis in a group that underwent preoperative chemotherapy and radiotherapy [
27]. These reports suggest that cytoplasmic CD133 expression alone may also be involved in the degree of malignancy of gastric cancer. It is widely known that some proteins gain biological function based on their site of expression. CD133 may be one of these types of proteins.
What is the significance of CD133 luminal expression? In an interesting report, Fukamachi et al. [
28] used fluorescence-activated cell sorting (FACS) analysis of gastric cancer tissue and reported that loss of CD133 expression on the glandular luminal surface may be related to gastric tumor progression. However, our study results suggest that release of CD133 from the cytoplasm of undifferentiated gastric cancer cells into the glandular lumen may promote gland duct formation. In any case, CD133 expression likely plays some role in differentiation, as shown by Yang et al. [
29].
Therefore, are CD133-expressing cancer cells actually CSCs? Characteristics of CSCs include tumorigenicity, treatment resistance, and tumor recurrence. Among these, tumorigenicity would be difficult to demonstrate in this study. Therefore, we investigated treatment resistance and tumor recurrence. The survival rate in the postoperative adjuvant chemotherapy group and the curative resection group was regarded as an indicator of treatment resistance and recurrence. Among these patients, the survival rate in the cytoplasmic CD133 expression group was significantly lower than in the other groups. This finding showed that the cytoplasmic CD133 expression group acquired treatment resistance and was more likely related to tumor recurrence. In summary, cancer cells with cytoplasmic CD133 expression were related to tumor progression (primarily metastases) and prognosis, and were associated with more undifferentiated tumors, treatment resistance, and more likely recurrence. These results suggested that these cells may have CSC-like characteristics.
Finally, regarding the relationship between CD133 expression and HIF-1α expression, in the luminal CD133 expression group in our study, the HIF-1α expression rate was lower, similar to that which was reported by Matumoto et al. [
17]. However, in the cytoplasmic CD133 expression group, the HIF-1α expression rate was higher, similar to that reported for other organs. This finding suggests that for cytoplasmic CD133 expression with a high degree of malignancy, HIF-1α may upregulate its expression. In fact, in our study as well, the survival rate in gastric cancer in the HIF-1α expression group was lower. Even among cases in the HIF-1α expression group, in the group that was also CD133 positive, the survival rate was even lower. This result may have been because HIF-1α upregulated the cytoplasmic CD133 expression. However, in our study, even when the HIF-1α (+) CD133 (+) poor prognosis group was further classified based on CD133 expression type, no differences in survival rate based on expression type were observed. One possibility is that among the luminal CD133 expression group, those with HIF-1α expression also showed cytoplasmic CD133 expression.
Considering the relationship between CD133 and HIF-1α based on our study results, HIF-1α expression is increased with hypoxia, CD133 is expressed or retained in cancer cell cytoplasm, and tumor progression occurs as a result of this CSC-like function. In addition, release from this hypoxic state, namely via decreased HIF-1α, promotes the release of CD133 from the cytoplasm, which may then function in gland duct formation. If this is the case, then inhibiting HIF-1α expression may lead to improved prognosis in gastric cancer. However, before reaching this conclusion, it will be necessary to establish an accurate method for isolating the CD133 expression types and to conduct studies in gastric cancer cell lines using these isolated expression types.