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Essential Genes to Consider in Epstein-Barr Virus-Associated Gastric Cancer: A Systematic Review

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Raheela Khalid at California Institute of Behavioural Neurosciences and Psychology
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Paramvijay Singh Dhalla at Cibnp
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Jian Garcia at Universidad Autónoma de Guadalajara
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Abstract and Figures

Gastric cancer (GC) is a prevalent malignancy worldwide; the Epstein-Barr Virus (EBV) also affects many people worldwide. An important association has been seen in these two diseases that could explain causality and a possible viral etiology of GC as has been seen with Helicobacter pylori. This study aims to identify genes expressed in malignant cells that are infected with EBV and see if one could be more oncogenic than the other. We conducted a systematic review based on the preferred reporting items for systematic reviews and meta-analysis (PRISMA) guidelines. We had 29 observational studies after inclusion/exclusion criteria and quality assessment for every single study. A total of 1022 patients were evaluated for different types of genes in 29 papers. It was demonstrated that the most expressed genes or the gene most involved were genes that are seen in Epstein-Barr virus-associated gastric cancer (EBVaGC) as latent genes of the EBV-infected cells, which are found in tumor cells. The genes that were mostly involved were LMP2, BNLF2a, and the absence of LMP1 that lead to the expression of BARF1, among other genes. These studies were made on mostly Asian populations, so it is still unknown if these genes involved have a geographical association more than an EBV and GC association.
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Received 08/31/2020
Review began 09/23/2020
Review ended 11/02/2020
Published 11/21/2020
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Essential Genes to Consider in Epstein-Barr
Virus-Associated Gastric Cancer: A Systematic
Review
Ana S. Armenta-Quiroga , Raheela Khalid , Paramvijay Singh Dhalla , Jian Garcia , Anusha Bapatla ,
Arunima Kaul , Safeera Khan
1. Internal Medicine, California Institute of Behavioral Neurosciences & Psychology, Fairfield, USA 2. Medicine,
California Institute of Behavioral Neurosciences & Psychology, Fairfield, USA
Corresponding author: Ana S. Armenta-Quiroga, anasofia.armentaq@gmail.com
Abstract
Gastric cancer (GC) is a prevalent malignancy worldwide; the Epstein-Barr Virus (EBV) also affects many
people worldwide. An important association has been seen in these two diseases that could explain causality
and a possible viral etiology of GC as has been seen with Helicobacter pylori. This study aims to identify genes
expressed in malignant cells that are infected with EBV and see if one could be more oncogenic than the
other. We conducted a systematic review based on the preferred reporting items for systematic reviews and
meta-analysis (PRISMA) guidelines. We had 29 observational studies after inclusion/exclusion criteria and
quality assessment for every single study. A total of 1022 patients were evaluated for different types of genes
in 29 papers. It was demonstrated that the most expressed genes or the gene most involved were genes that
are seen in Epstein-Barr virus-associated gastric cancer (EBVaGC) as latent genes of the EBV-infected cells,
which are found in tumor cells. The genes that were mostly involved were LMP2, BNLF2a, and the absence of
LMP1 that lead to the expression of BARF1, among other genes. These studies were made on mostly Asian
populations, so it is still unknown if these genes involved have a geographical association more than an EBV
and GC association.
Categories: Internal Medicine, Infectious Disease, Oncology
Keywords: stomach neoplasms, epstein-barr virus, viral genes
Introduction And Background
Epstein-Barr virus-associated gastric cancer (EBVaGC) is 10% of all gastric carcinomas, representing the
fifth-most common cancer worldwide and the third-most deadly cancer [1, 2].
Gastric cancer is a multifactorial disease that is associated with several risk factors that could contribute to
the cause of this disease. This cancer has been linked to the presence of Helicobacter pylori, which suggests
an infectious etiology related to this malignancy [1]. There are variations in incidence between countries,
age, and sex. That is why it is also believed that because it's a multifactorial disease, the genetic part plays
an essential role in developing gastric cancer [2, 3].
On the other hand, the Epstein-Barr virus is characterized by its double-stranded DNA and belonging to the
herpes virus family [4]. It is a virus that has infected approximately 90% of adult individuals and is known for
being self-limiting. In a few cases, it has been distinguished by developing malignancy of lymphoid and
epithelial origin [5, 6]. This virus can remain latent in the B lymphocytes of the infected individual [4].
EBVaGC has important molecular characteristics because of the expression of different genes and its
epigenetic profile [7]. It is believed that the Epstein-Barr virus could be another infectious agent that
contributes to the transformation of gastric cells into malignant cells due to different cellular processes and
signaling pathways [8].
As mentioned, an infectious etiology has been suggested. The mechanism of Helicobacter pylori and gastric
cancer is very well known; however, another infectious agent has been identified as significantly associated
with this type of cancer. The specific variables of the Epstein-Barr virus that cause this cancer and the
expressed genes that are involved are still not well understood, and it is still unknown if any of these is more
oncogenic than the others.
Today, the different genes associated with gastric cancer are still being investigated. Likewise, the
mechanisms and pathways that produce overexpression or loss are studied [9, 10]. There is already a bit of
information about new therapeutic approaches considering the evidence on the subject [11].
This study aims to search for the specific genes of the Epstein-Barr virus that are expressed in gastric cancer
and determine if any of these is more oncogenic than the other. Studying this is very useful since these
1 1 2 1 1
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Open Access Review
Article DOI: 10.7759/cureus.11610
How to cite this article
Armenta-Quiroga A S, Khalid R, Dhalla P, et al. (November 21, 2020) Essential Genes to Consider in Epstein-Barr Virus-Associated Gastric
Cancer: A Systematic Review. Cureus 12(11): e11610. DOI 10.7759/cureus.11610
genes can eventually serve as a target for the specific treatment of the disease.
Review
Methods
Study Design
We conducted a systematic review based on the preferred reporting items for systematic reviews and meta-
analysis (PRISMA) guidelines.
Eligibility Criteria
We selected all observational studies related to this topic, Epstein-Barr virus, gene expression, and gastric
cancer, for the last 10 years. We included all types of studies found in full text and done in humans,
excluding all those studies in animals. The articles included were in the English and Spanish languages.
Finally, gray literature and narrative review were excluded.
Databases and Search Methods
We used the PubMed database to search for relevant studies for our data collection. This search was done
between the 9th and the 13th of July 2020. For this, we used the medical subject headings (MeSH) Keyword.
First, we searched "Stomach Neoplasm," "Herpes 4, Human" and "Epstein-Barr Virus Nuclear Antigens,"
which showed 110,438, 13,075, and 3,377 results, respectively. We then decided to use a MeSH Strategy
instead of a more effective search of articles related to the topic. The combined keywords we used in this
strategy were the following: "Stomach Neoplasms/microbiology"[MeSH] AND "Herpesvirus 4, Human"
[MeSH] AND "Viral Matrix Proteins"[MeSH], "Stomach Neoplasms/microbiology"[MeSH] AND "Epstein-Barr
Virus Nuclear Antigens"[MeSH] and "Stomach Neoplasms/microbiology"[MeSH] AND "Herpesvirus 4,
Human/pathogenicity"[MeSH] AND "Proteins"[MeSH].
Study Selection
The eligibility process is shown in Table 1, which represents the evolution of the use of inclusion/exclusion
criteria and screening process to select studies.
MeSH Strategy Database
Before
Inclusion/exclusion
criteria (results)
After
Inclusion/exclusion
criteria (results)
After the
screening
process
"Stomach Neoplasms/microbiology"[Mesh] AND
"Herpesvirus 4, Human"[Mesh] AND "Viral Matrix Proteins"
[MeSH]
PubMed 52 12 11
"Stomach Neoplasms/microbiology"[Mesh] AND "Epstein-
Barr Virus Nuclear Antigens"[MeSH] PubMed 42 14 10
"Stomach Neoplasms/microbiology"[Mesh] AND
"Herpesvirus 4, Human/pathogenicity"[MeSH] AND
"Proteins"[MeSH]
PubMed 40 13 8
TABLE 1: MeSH strategy used in the literature search
Inclusion/exclusion criteria and screening process for article eligibility.
After the first search, we had 134 articles, and once we applied the inclusion-exclusion criteria, we had 40.
We excluded all the articles that were duplicated and not relevant to the topic of the screening process. We
excluded four articles because they were not pertinent and seven because of duplicates in the search giving
us 29 papers.
Risk of Bias and Quality Assessment
To reduce the risk of bias, we did a quality assessment of every paper to avoid this risk. We used the New-
Castle-Ottawa questionnaire to assess all of the observational studies.
2020 Armenta-Quiroga et al. Cureus 12(11): e11610. DOI 10.7759/cureus.11610 2 of 8
Results
The search results focused on observational studies that discussed specific genes that were expressed in
EBVaGC. This was done to point out genes present in Epstein-Barr virus and see if any is more oncogenic
than the others, especially for the evolution of gastric cancer. After we used the inclusion/exclusion criteria,
29 articles were obtained from which the data were abstracted. Figure 1 shows the evolution of the search.
FIGURE 1: PRISMA flow diagram.
From the 29 observational studies, 15 cohort studies and 14 cases and controls were obtained. A quality
assessment was carried out of these studies, getting favorable results. Of the 29 papers, we evaluated 1022
patients for the expression of a different gene. As shown in Table 2, all the included studies are mentioned,
the type of study of each one, year of publication, country, and the genes studied by paper. These articles
include samples from countries such as China, Japan, Korea, Thailand, United States, India, Portugal, Iran,
Canada, and Zambia. It is worth highlighting the fact that most of the population studied in these articles is
Asian.
2020 Armenta-Quiroga et al. Cureus 12(11): e11610. DOI 10.7759/cureus.11610 3 of 8
Author Year of publication Type of study Country Gene
1 Armero et al. [7] 2017 Cohort USA EBNA1
2 Chang et al. [12] 2013 Case Control Korea BARF1
3 Chen et al. [13] 2012 Case Control China EBER1, EBNA1
4 Cho et al. [14] 2018 Cohort Japan PD-L1
5 Han et al. [15] 2012 Cohort China LMP2, EBER1
6 He et al. [16] 2015 Case Control China EBER1, p16, FHIT, CRBP1, WWOX, DLC-1
7 Rymbai et al. [3] 2015 Case Control India EBNA1
8 Kayamba et al. [17] 2016 Case Control Zambia EBNA1
9 Kosari-monfared et al. [18] 2019 Cohort Iran CTNNBIP-1
10 Luo et al. [19] 2012 Case Control China EBER1, EBNA3-C, gp350/220
11 Moon et al. [20] 2017 Case Control Korea PD-L1
12 Nakayama et al. [21] 2019 Cohort Japan EBNA1, PD-L1
13 Ribeiro et al. [22] 2017 Cohort Portugal LMP2, EBER
14 Liu et al. [23] 2015 Cohort China EBER1, BNLF2a, BNLF2a-A, BNLF2a-B1
15 Shinozaki-Ushiku et al. [24] 2015 Cohort Japan BART4-5p
16 Sivachandran et al. [25] 2012 Case Control Canada EBER, EBNA1
17 Strong et al. [26] 2015 Cohort USA BNLF2a
18 Sundar et al. [27] 2018 Case Control Korea EBER, PD-L1
19 Wang et al. [28] 2016 Case Control China LMP1, EBER1, VEGF-C, BARF1
20 Wang et al. [10] 2019 Cohort China LMP2, DNMT3a
21 Wang et al. [29] 2010 Cohort China LMP2, EBER1
22 Wang et al. [30] 2013 Case Control China EBER1, EBNA3-A
23 Kawazoe et al. [31] 2017 Case Control China EBER1, EBNA2-A, EBNA2-B, EBNA2-C
24 Wanvimonsuk et al. [32] 2019 Case Control Thailand LMP1, EBER
25 Wu et al. [33] 2012 Cohort China EBER1, EBNA3-C
26 Liu et al. [34] 2016 Cohort China LMP2, EBNA1, BZLF1
27 Zhang et al. [35] 2015 Case Control China LMP2, EBER1, HER2
28 Zhao et al. [36] 2013 Cohort China LMP1, EBER, DNMT1, DNMT3b
29 Zhao et al. [2] 2016 Cohort China GPC4
TABLE 2: Qualitative aspects of the included studies
At first glance the article summary demonstrates that the genes that are most seen in EBVaGC are the latent
genes of the EBV-infected cells, which are found in tumor cells. In Figure 2, we see the comparison made
between the number of evaluated patients per gene and the number of patients who express that gene. The
most expressed genes are shown on the right side.
2020 Armenta-Quiroga et al. Cureus 12(11): e11610. DOI 10.7759/cureus.11610 4 of 8
FIGURE 2: Comparison of the number of patients evaluated by each
gene and the total number of patients who expressed the said gene.
Discussion
Genes Expressed in Latently Infected Cells
Most of the EBVaGC patients studied were sought for association with genes expressed in latently infected
cells; infected cells which showed a higher detection of EBER, EBNA 1, EBNA3A, and LMP2. As shown in
Figure 2, most patients express the Epstein-Barr virus encoded-small RNAs (EBERs), however this only
means that the virus is present in the malignant cells since it represents the non-coding RNA associated
with Epstein-Barr virus. It is essential to recognize this fact because it means that the presence of the virus
in gastric cells can be an important factor in the development of malignancy [27].
An additional possible oncogenic expression may include the latent membrane protein 2 (LMP2) expression
that has been seen to induce hypermethylation of various factors through up-regulation that has enormous
carcinogenic potential. Ribeiro et al. state that LMP2 causes up-regulation of DNMT1 and phosphorylation
of STAT3 [22]. Wang et al. mention the hypermethylation of AQP3, and Zhao et al. talk about the up-
regulation of DNMT3b, which causes hypermethylation of almost 886 genes that are involved in cancer-
related pathways [10, 36]. It is essential to recognize that the presence of LMP2 leads to many different
pathways with the potential to develop a malignancy. The fact that it is present in so many patients suggests
that it is an essential factor that could cause EBVaGC.
Studies by Wang et al. and Han et al. have shown that PY and ITAMs regions are highly conserved in LMP2,
suggesting that they play an essential role in the viral infection. These regions are considered crucial for
possible treatment options targeted LMP2 directed explicitly to these regions. Epitope mutations still have
to be considered, this will make target immunotherapy more challenging, but it is an excellent place to start
[15,30].
Regarding LMP1, it has been determined that it has an oncogenic activity. According to Wanvimonsuk et al.,
it has been noted that it is expressed in a decreased way or absent in this disease [28,32]. However,
according to Wang et al., the presence of LMP1 leads to the expression of BARF1, which might also play a
role in the development of malignant cells [28].
Finally, the Epstein-Barr virus nuclear antigen (EBNA) expression shows that it is more common in most
patients to express EBNA1 and EBNA3C. Moreover, EBNA1 has been seen to have an essential role in
malignancy development. Armero et al. mention that it interacts with cellular splicing factors, and
Nakayama et al. say that it induces the expression of PD-L1, which plays a vital role in diseases such as
cancer [7,21]. This suggests that it is a possible factor that can contribute as a cause of EBVaGC [21].
However, it was seen by Chen et al. that polymorphisms can have geographic-associated polymorphisms
rather than tumor-specific mutations, which is why it is essential to do more studies in different patients to
determine if this is true [13]. Likewise, EBNA3C is known to be a geographic-associated polymorphism in
China [33].
Other Expressed Genes
Other expressed genes that were seen with greater frequency were BNLF2a, PD-L1, GPC4, and BARF. BNL2a
is a gene expressed in EBV with the function of viral evasion against HLA I, giving T-cell immunity. In some
studies, it has a protective role in latently infected tumor cells [26]. It was seen that type A, BNLFaA, is
dominant in a study done in the Chinese population, and B1, BNLF2aB1, is geographically restricted to this
population. BNLFa expression in the patients seen in Liu et al. study demonstrated a highly conserved gene
2020 Armenta-Quiroga et al. Cureus 12(11): e11610. DOI 10.7759/cureus.11610 5 of 8
that gives us another option for targeted immunotherapy. However, it is essential to consider that more
studies should be made to see if it is highly conserved in patients from other countries [23].
The presence of PD-L1 has been detected in patients' tumor cells in some studies; however, it's common to
see the expression of this gene in many different types of cancer. It is not a specific gene for EBVaGC, but the
overexpression of PD-L1 does regulate some signaling pathways with malignant potential [14,21]. Even
though it's not specific for this malignancy, it is an immunotherapy option for many cancers [14]. A recent
paper by Sundar et al. studies LMP1 expression. Even though LMP1 expression is higher in EBVaGC, it states
that EBVaGC with lower expression of PD-L1 in tumor cells leads to the worst prognosis, which is also an
excellent point to consider [27].
There is not much information about GPC4 expression. Still, it was seen in Zhao et al. study that in a
Chinese population, there is a polymorphism of this gene that may represent a risk factor given by the
susceptibility associated with this polymorphism to develop EBVaGC [2]. Nevertheless, we come back to the
same issue; it is unknown if this polymorphism is of the Chinese population only and if the susceptibility
changes depending on the population.
Finally, BARF1 is another crucial factor to consider. This is because in the absence of LMP1, as it was already
mentioned, BARF1 is expressed, causing its protein to promote the proliferation of EBV-infected malignant
gastric cells. It does this through some pathways that may have essential functions in gastric cancer
tumorigenesis. In the papers that studied the expression of this gene, in most cases, the expression of BARF1
was found. Then again, more studies are needed to determine this factor as a possible cause [12,28].
The rest of the genes mentioned before may play a role in malignancy development; however, this role is not
found in most cases. This means that even though they are essential, they are not the priority since it could
not help a general population, only specific patients. Perhaps when more is known about EBVaGC and the
most common genes involved, it will be useful to research these genes.
This study had limitations mostly since it is very little published evidence on the subject. This could lead to
publication bias; however, the data abstraction and review were done from a complete database available at
the time. Another limitation is that most of the patients studied are from the Asian population; however,
there could be variations between populations that we do not see or dominant polymorphisms in the
different populations that predominate in the Asia population and differ from those of the rest. The lack of
information only prompts more studies to be carried out in other populations.
Conclusions
Different genes were studied and identified in patients with EBVaGC. We can conclude that latent EBV genes
were mostly expressed in malignant cells such as LMP2, BNLF2a, and the absence of LMP1 showed that lead
to the expression of BARF1, among other genes. It is important to emphasize that most of the patients are
Asian, so it is unknown if these genes could be associated with this disease in this population only. It would
be recommended in the future to carry out more studies in patients from different countries to determine
whether these genes are expressed in EBVaGC of all patients or only of this population.
Additional Information
Disclosures
Conflicts of interest: In compliance with the ICMJE uniform disclosure form, all authors declare the
following: Payment/services info: All authors have declared that no financial support was received from
any organization for the submitted work. Financial relationships: All authors have declared that they have
no financial relationships at present or within the previous three years with any organizations that might
have an interest in the submitted work. Other relationships: All authors have declared that there are no
other relationships or activities that could appear to have influenced the submitted work.
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... Las evidencias de los estudios recientes sugieren un papel del VEB en la etiología del carcinoma gástrico [40]. Se considera que el VEB contribuye a la transformación de células gástricas mediante diferentes procesos celulares y vías de señalización [41]. Por otra parte, la expresión del virus en el carcinoma gástrico se asocia con una latencia tipo I o II, y ha mostrado un mayor grado de hipermetilación del ADN, comparado con el carcinoma gástrico no asociado a VEB [1,42], además, se diferencia de los otros carcinomas gástricos por la presencia de un infiltrado linfoide abundante [43]. ...
Virus de Epstein-Barr: más que una mononucleosis infecciosa
Article
Full-text available
  • Jan 2023
El virus de Epstein-Barr (VEB) fue el primer virus asociado a neoplasias en humanos. Infecta el 95 % de la población mundial, y aunque usualmente es asintomático, puede causar mononucleosis infecciosa y se relaciona con más de 200.000 casos de neoplasias al año. De igual forma, se asocia con esclerosis múltiple y otras enfermedades autoinmunes. A pesar de ser catalogado como un virus oncogénico, solo un pequeño porcentaje de los individuos infectados desarrollan neoplasias asociadas a VEB. Su persistencia involucra la capacidad de alternar entre una serie de programas de latencia, y de reactivarse cuando tiene la necesidad de colonizar nuevas células B de memoria, con el fin de sostener una infección de por vida y poder transmitirse a nuevos hospederos. En esta revisión se presentan las generalidades del VEB, además de su asociación con varios tipos de neoplasias, como son el carcinoma nasofaríngeo, el carcinoma gástrico, el linfoma de Hodgkin y el linfoma de Burkitt, y la esclerosis múltiple. Adicionalmente, se describen los mecanismos fisiopatológicos de las diferentes entidades, algunos de ellos no completamente dilucidados.
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Viral loads correlate with upregulation of PD-L1 and worse patient prognosis in Epstein–Barr Virus-associated gastric carcinoma
Article
Full-text available
Epstein–Barr virus (EBV)-associated gastric carcinoma (EBVaGC), one of four major gastric cancer types, consists of clonal growth of EBV-infected epithelial cells. However, the significance of viral loads in each tumor cell has not been evaluated. EBV-DNA is stably maintained in episomal form in the nucleus of each cancer cell. To estimate EBV copy number per genome (EBV-CN), qPCR of viral EBNA1 and host GAPDH, standardized by Namalwa DNA (one copy/genome), was applied to the formalin-fixed paraffin embedded (FFPE) surgically resected EBVaGC specimens (n = 43) and EBVaGC cell lines (SNU-719 and NCC-24). In surgical specimens, the cancer cell ratio (CCR) was determined with image analysis, and EBV-CN was obtained by adjusting qPCR value with CCR. Fluorescent in situ hybridization (FISH) was also applied to the FFPE sections using the whole EBV-genome as a probe. In surgical specimens, EBV-CN obtained by qPCR/CCR was between 1.2 and 185 copies with a median of 9.9. EBV-CN of SNU-719 and NCC-24 was 42.0 and 1.1, respectively. A linear correlation was observed with qPCR/CCR data up to 20 copies/genome (40 signals/nucleus), the limit of FISH analysis. In addition, substantial variation in the number of EBV foci was observed. Based on qPCR/CCR, high EBV-CN (>10 copies) correlated with PD-L1 expression in cancer cells (P = 0.015), but not with other pathological indicators. Furthermore, EBVaGC with high EBV-CN showed worse disease-specific survival (P = 0.041). Our findings suggest that cancer cell viral loads may contribute to expression of the immune checkpoint molecule and promotion of cancer progression in EBVaGC.
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Epstein-Barr virus miR-BART3-3p promotes tumorigenesis by regulating senescence pathway in gastric cancer
Article
Full-text available
  • Jan 2019
Epstein–Barr virus–associated gastric cancer (EBVaGC) accounts for about 10% of all gastric cancer cases and has unique pathological and molecular characteristics. EBV encodes a large number of microRNAs, which actively participate in the development of EBV-related tumors. Here, we report that EBV-miR-BART3-3p (BART3-3p) promotes gastric cancer cell growth in vitro and in vivo. Moreover, BART3-3p inhibits the senescence of gastric cancer cells induced by an oncogene (RAS G12V ) or chemotherapy (irinotecan). LMP1 and EBNA3C encoded by EBV have also been reported to have antisenescence effects; however, in EBVaGC specimens, LMP1 expression is very low, and EBNA3C is not expressed. BART3-3p inhibits senescence of gastric cancer cells in a nude mouse model and inhibits the infiltration of natural killer cells and macrophages in tumor by altering the senescence-associated secretory phenotype (SASP). Mechanistically, BART3-3p directly targeted the tumor suppressor gene TP53 and caused down-regulation of p53’s downstream target, p21. Analysis from clinical EBVaGC samples also showed a negative correlation between BART3-3p and TP53 expression. It is well known that mutant oncogene RAS G12V or chemotherapeutic drugs can induce senescence, and here we show that both RAS G12V and a chemotherapy drug also can induce BART3-3p expression in EBV-positive gastric cancer cells, forming a feedback loop that keeps the EBVaGC senescence at a low level. Our results suggest that, although TP53 is seldom mutated in EBVaGC, its expression is finely regulated such that EBV-encoded BART3-3p may play an important role by inhibiting the senescence of gastric cancer cells. © 2019 Wang et al. Published under exclusive license by The American Society for Biochemistry and Molecular Biology, Inc.
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Functional loss of ARID1A is tightly associated with high PD‐L1 expression in gastric cancer
Article
Full-text available
Notwithstanding remarkable treatment success with anti‐PD‐1 monoclonal antibody, oncogenic mechanism of PD‐L1 regulation in gastric cancer (GC) remains poorly understood. We hypothesized that ARID1A might be related to tumor PD‐L1 expression in GC. We found that tumor PD‐L1 positivity was associated with loss of ARID1A and showed trend toward better survival of patients with various molecular subtypes of GC (experimental set, n = 273). Considering heterogeneous ARID1A expression, we validated this using whole tissue sections (n = 159) and found that loss of ARID1A was correlated with microsatellite instability‐high (MSI‐H), Epstein–Barr virus (EBV), and PD‐L1 positivity. Furthermore, for patients with MSI‐H tumors, the degree of PD‐L1 expression was significantly higher in ARID1A‐deficient tumors. After ARID1A knockdown in GC cell lines, total and membranous PD‐L1 protein, and PD‐L1 mRNA levels were increased based on Western blot, flow cytometry, and qRT‐PCR, respectively. With IFN‐γ treatment, PD‐L1 expression was significantly increased both in ARID1A‐deficient cancer cells and controls, but the increase was not more pronounced in the former. Loss of ARID1A increased PD‐L1 via activating AKT signaling, while LY294002 (PI3K inhibitor) decreased PD‐L1 levels. Furthermore, we found that 3 MSI‐H tumors showing highest expression of PD‐L1 had simultaneous KRAS mutation and loss of ARID1A, suggesting a possible synergistic role boosting PD‐L1. Our results strongly indicate that loss of ARID1A is tightly associated with high PD‐L1 expression in GC. These results would increase our understanding of the oncogenic mechanism of PD‐L1 regulation in GC, and also help to find the optimal candidates for immunotherapy.
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Distribution of the Epstein-Barr virus in the normal stomach and gastric lesions in Thai population: WANVIMONSUK et al.
Article
Full-text available
  • Sep 2018
The Epstein‐Barr virus (EBV) is one of the infectious agents found in stomach tissue. Recently, EBV associated gastric carcinoma (EBVaGC) was classified as a new subtype of gastric carcinoma. To date, there is a lack of knowledge about the distribution and prevalence of EBV infection in both the normal stomach and various gastric lesions, including EBVaGC, in the Thai population. In this study, we detected EBV in the normal stomach (NS; n=19), chronic gastritis (CG; n=36), intestinal metaplasia (IM; n=40), gastric dysplasia (GD; n=15), and gastric adenocarcinoma (GC; n=33) by polymerase chain reaction (PCR) amplification of the latent membrane protein (LMP1) gene of EBV. EBV‐PCR amplification was positive in 42.1%, 36.1%, 22.5%, 13.3%, and 33.3% of NS, CG, IM, GD, and GC, respectively. For further clarification in EBVaGC, we performed EBV‐encoded small RNA in situ hybridization (EBER‐ISH) in PCR positive cases of GD and GC. Four GC cases were EBER‐ISH positive (12.1%), while both GD cases were EBER‐ISH negative. In addition, we determined the distribution of the EBV strain (type A or B) based on EBNA3C sequence and EBV variants based on LMP1 variation (wild‐type and 30 bp‐deletion variants; wt‐LMP1 or del‐LMP1). The results showed that type A and wt‐LMP1 were the most prevalent in all lesions. In conclusion, EBV is common in both the normal stomach and gastric lesions and the frequency of EBVaGC was 12.1% in Thai patients. This article is protected by copyright. All rights reserved.
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IFNγ induces PD-L1 overexpression by JAK2/STAT1/IRF-1 signaling in EBV-positive gastric carcinoma
Article
Full-text available
  • Dec 2017
Programmed death-ligand 1 (PD-L1) acts as an immune checkpoint inhibitor in various cancers. PD-L1 is known to be more frequently expressed in EBV (+) gastric cancer (GC). However, the mechanisms underlying the regulation of PD-L1 expression in EBV (+) GC remain unclear. We investigated the basal and inducible PD-L1 expressions in GC cells. PD-L1 expression was upregulated upon treatment with IFNγ in both EBV (-) and EBV (+) GC cells. Upon stimulation with the same concentration of IFNγ for 24 h, EBV (+) SNU-719 cells showed dramatically higher PD-L1 expression levels by activating JAK2/STAT1/IRF-1 signaling than those of EBV (-) AGS cells. PD-L1 promoter assays, chromatin immunoprecipitation, and electrophoretic mobility shift assays revealed that IFNγ-inducible PD-L1 overexpression is primarily mediated by the putative IRF-1α site of the PD-L1 promoter in EBV (+) SNU-719 cells. Moreover, EBNA1 knockdown reduced both constitutive and IFNγ-inducible PD-L1 promoter activity by decreasing the transcript and protein levels of JAK2 and subsequently STAT1/IRF-1/PD-L1 signaling. EBNA1 is suggested to be moderately enhance both constitutive and IFNγ-inducible PD-L1 expression in EBV (+) GC cells. Thus, the signaling proteins and EBNA1 that regulate PD-L1 expression are potential therapeutic targets in EBV (+) GC.
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LMP2A induces DNA methylation and expression repression of AQP3 in EBV-associated gastric carcinoma
Article
  • Jun 2019
  • VIROLOGY
Epstein-Barr virus (EBV)-associated gastric carcinoma (EBVaGC) is a unique type of gastric carcinomas that promoter hypermethylation of tumor-related genes is extremely frequent to be found. Aquaporin 3 (AQP3) is a small membrane transport protein that plays a crucial role in cancer progression and metastasis. However, there is no experimental study on the expression of AQP3 in EBVaGC and the regulation mechanism of EBV on AQP3. In this study, the loss of AQP3 was contributed by the hypermethylation status of AQP3 promoter in EBVaGC which was caused by elevated expression of DNMT3a. In addition, stable and transient transfection system in SGC7901 showed that viral latent membrane protein 2A (LMP2A) activated phosphorylated ERK and up-regulated DNMT3a. Taken together, LMP2A induced the phosphorylation of ERK, which activated DNMT3a transcription and caused AQP3 expression loss through CpG island methylation of AQP3 promoter in EBVaGC.
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CTNNBIP1 downregulation is associated with tumor grade and viral infections in gastric adenocarcinoma
Article
  • Aug 2018
  • J CELL PHYSIOL
Gastric cancer is a life-threatening disease; resulting from interaction among genetic, epigenetic, and environmental factors. Aberrant dysregulation and methylation changes in Wnt/β-catenin signaling downstream elements are a prevalent phenomenon encountered in gastric tumorigenesis. Also, viral infections play a role in gastric cancer development. CTNNBIP1 (β-catenin interacting protein 1) gene is an antagonist of Wnt signaling which binds to the β-catenin molecules. The CTNNBIP1 function as tumor suppressor gene or oncogene in different types of cancer is controversial. Moreover, its function and regulatory mechanisms in gastric cancer progression is unknown. In the present study, we examined CTNNBIP1 gene expression, the methylation status of the regulatory region of the gene, and their association with Epstein-Barr virus (EBV), and cytomegalovirus (CMV) and Helicobacter pylori infections in human gastric adenocarcinoma tissues in comparison with their adjacent nontumoral tissues. Our data revealed a significant downregulation of CTNNBIP1 in gastric tumors. Female patients showed lower level of CTNNBIP1 than males (p < 0.05). Also, decreased expression of CTNNBIP1 was markedly associated with well-differentiated tumor grades (p < 0.05). No methylation change was observed between tumoral and nontumoral tissues. Additionally, CTNNBIP1 down regulation was significantly associated with CMV infection (p < 0.05). In the absence of EBV infection, lower expression of CTNNBIP1 was observed. There was no association between H. pylori infection and CTNNBIP1 expression. Our findings revealed the tumor suppressor role for CTNNBIP1 in gastric adenocarcinoma. Interestingly, EBV and CMV infections modulate CTNNBIP1 expression.
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Transcriptional analysis of immune genes in Epstein–Barr virus-associated gastric cancer and association with clinical outcomes
Article
  • Jun 2018
Background: Epstein-Barr virus-associated gastric cancer (EBVaGC) has traditionally been associated with high expression of PD-L1 and immune infiltration. Correlations between PD-L1 and other immune-related gene (IRG) expressions in EBVaGC have not been previously described. Methods: We performed NanoString® transcriptomic profiling and PD-L1 immunohistochemistry (IHC) (using the FDA approved Dako PD-L1 IHC 22C3) on EBVaGC samples from gastric cancer patients undergoing primary tumor resections at Samsung Medical Centre, South Korea. For controls, EBV-negative samples from the previously reported Asian Cancer Research Group (EBVnegACRG) cohort were used. Genes tested included PD-L1 and other IRGs related to intra-tumoral cytolytic activity, cytokines and immune checkpoints. Samples with PD-L1 expression > 34th percentile were defined as PD-L1high and the remaining as PD-L1low. Results: We identified 71 cases of EBVaGC and 193 EBV-negative ACRG samples as controls. EBVaGC showed higher expression of all queried immune genes compared to EBVnegACRG samples (p < 0.01). PD-L1 immunohistochemistry expression correlated with PD-L1 transcript expression (r = 0.63, p < 0.001). Tumor-infiltrating lymphocyte patterns were also found to be different between PD-L1low and PD-L1high groups. PD-L1low EBVaGC samples (n = 24, 34%) had consistently decreased expression of all other immune genes, such as CD8A, GZMA and PRF1 and PD-1 (p < 0.001). PD-L1low EBVaGC samples were also associated with worse disease-free survival (HR 5.03, p = 0.032) compared to PD-L1high EBVaGC samples. Conclusions: A substantial proportion of EBVaGC does not express high levels of PD-L1 and other immune genes. EBVaGCs which have lower transcriptomic expression of PD-L1 tend to have a similarly low expression of other immune genes, IHC scores and a poorer prognosis.
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Poor prognosis in Epstein–Barr virus-negative gastric cancer with lymphoid stroma is associated with immune phenotype
Article
  • Apr 2018
Background: Gastric cancer with lymphoid stroma (GCLS) is pathologically characterized by poorly developed tubular structures with a prominent lymphocytic infiltration. Its clinical and prognostic features differ in patients positive and negative for Epstein-Barr virus (EBV) infection. This study analyzed the expression of programmed cell death-1 (PD-1), programmed cell death ligand-1 (PD-L1), and the density of tumor-infiltrating lymphocytes (TILs) including CD3+ and CD8+ T cells, as well as their prognostic significance in patients with GCLS. Methods: The study included 58 patients with GCLS (29 EBV+ and 29 EBV-) who underwent curative resection. Expression of CD3, CD8, PD-1, and PD-L1 in tumor cells and TILs was analyzed using a quantitative multispectral imaging system (Opal™), with these results validated by immuno-histochemical assays for PD-L1 on whole slide sections. Results: The proportion of tumors overexpressing PD-L1 (31.0 vs. 0%, P = 0.002), TIL density (4548 vs. 2631/mm2, P < 0.001), and intra-tumoral CD8+ T-cell density (2650 vs. 1060/mm2, P < 0.001) were significantly higher in EBV+ than in EBV- GCLS. In addition, CD8+/CD3+ T-cell ratio was higher in EBV+ than in EBV- GCLS (55.3 vs. 35.8%, P < 0.001). Lower TIL density, defined as < 1350/mm2, was a significant negative factor of survival. Conclusions: Despite histopathological similarity, quantitative multispectral imaging revealed differences in the tumor immune micro-environment between EBV+ and EBV- GCLS, indicating that the underlying pathogenesis differs in these two disease entities. TIL density may be a prognostic marker in patients with GCLS.
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