Lung Tumorigenesis Alters the Expression of Slit2-exon15 Splicing Variants in Tumor Microenvironment
Slit2 expression is downregulated in various cancers, including lung cancer. We identified two Slit2 splicing variants at exon15—Slit2-WT and Slit2-ΔE15. In the RT-PCR analyses, the Slit2-WT isoform was predominantly expressed in all the lung cancer specimens and in their normal lung counterparts, w...
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| Published in | Cancers Vol. 11; no. 2; p. 166 |
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| Main Authors | , , , , , , , |
| Format | Journal Article |
| Language | English |
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01.02.2019
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| Abstract | Slit2 expression is downregulated in various cancers, including lung cancer. We identified two Slit2 splicing variants at exon15—Slit2-WT and Slit2-ΔE15. In the RT-PCR analyses, the Slit2-WT isoform was predominantly expressed in all the lung cancer specimens and in their normal lung counterparts, whereas Slit2-ΔE15 was equivalently or predominantly expressed in 41% of the pneumothorax specimens. A kRasG12D transgenic mice system was used to study the effects of tumorigenesis on the expressions of the Slit2-exon15 isoforms. The results revealed that a kRasG12D-induced lung tumor increased the Slit2-WT/Slit2-ΔE15 ratio and total Slit2 expression level. However, the lung tumors generated via a tail vein injection of lung cancer cells decreased the Slit2-WT/Slit2-ΔE15 ratio and total Slit2 expression level. Interestingly, the lipopolysaccharide (LPS)-induced lung inflammation also decreased the Slit2-WT/Slit2-ΔE15 ratio. Since Slit2 functions as an anti-inflammatory factor, the expression of Slit2 increases in kRasG12D lungs, which indicates that Slit2 suppresses immunity during tumorigenesis. However, an injection of lung cancer cells via the tail vein and the LPS-induced lung inflammation both decreased the Slit2 expression. The increased Slit2 in the tumor microenvironment was mostly Slit2-WT, which lacks growth inhibitory activity. Thus, the results of our study suggested that the upregulation of Slit2-WT, but not Slit2-ΔE15, in a cancer microenvironment is an important factor in suppressing immunity while not interfering with cancer growth. |
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| AbstractList | Slit2 expression is downregulated in various cancers, including lung cancer. We identified two Slit2 splicing variants at exon15—Slit2-WT and Slit2-ΔE15. In the RT-PCR analyses, the Slit2-WT isoform was predominantly expressed in all the lung cancer specimens and in their normal lung counterparts, whereas Slit2-ΔE15 was equivalently or predominantly expressed in 41% of the pneumothorax specimens. A kRasG12D transgenic mice system was used to study the effects of tumorigenesis on the expressions of the Slit2-exon15 isoforms. The results revealed that a kRasG12D-induced lung tumor increased the Slit2-WT/Slit2-ΔE15 ratio and total Slit2 expression level. However, the lung tumors generated via a tail vein injection of lung cancer cells decreased the Slit2-WT/Slit2-ΔE15 ratio and total Slit2 expression level. Interestingly, the lipopolysaccharide (LPS)-induced lung inflammation also decreased the Slit2-WT/Slit2-ΔE15 ratio. Since Slit2 functions as an anti-inflammatory factor, the expression of Slit2 increases in kRasG12D lungs, which indicates that Slit2 suppresses immunity during tumorigenesis. However, an injection of lung cancer cells via the tail vein and the LPS-induced lung inflammation both decreased the Slit2 expression. The increased Slit2 in the tumor microenvironment was mostly Slit2-WT, which lacks growth inhibitory activity. Thus, the results of our study suggested that the upregulation of Slit2-WT, but not Slit2-ΔE15, in a cancer microenvironment is an important factor in suppressing immunity while not interfering with cancer growth. Slit2 expression is downregulated in various cancers, including lung cancer. We identified two Slit2 splicing variants at exon15—Slit2-WT and Slit2-ΔE15. In the RT-PCR analyses, the Slit2-WT isoform was predominantly expressed in all the lung cancer specimens and in their normal lung counterparts, whereas Slit2-ΔE15 was equivalently or predominantly expressed in 41% of the pneumothorax specimens. A kRas G12D transgenic mice system was used to study the effects of tumorigenesis on the expressions of the Slit2-exon15 isoforms. The results revealed that a kRas G12D -induced lung tumor increased the Slit2-WT/Slit2-ΔE15 ratio and total Slit2 expression level. However, the lung tumors generated via a tail vein injection of lung cancer cells decreased the Slit2-WT/Slit2-ΔE15 ratio and total Slit2 expression level. Interestingly, the lipopolysaccharide (LPS)-induced lung inflammation also decreased the Slit2-WT/Slit2-ΔE15 ratio. Since Slit2 functions as an anti-inflammatory factor, the expression of Slit2 increases in kRas G12D lungs, which indicates that Slit2 suppresses immunity during tumorigenesis. However, an injection of lung cancer cells via the tail vein and the LPS-induced lung inflammation both decreased the Slit2 expression. The increased Slit2 in the tumor microenvironment was mostly Slit2-WT, which lacks growth inhibitory activity. Thus, the results of our study suggested that the upregulation of Slit2-WT, but not Slit2-ΔE15, in a cancer microenvironment is an important factor in suppressing immunity while not interfering with cancer growth. Slit2 expression is downregulated in various cancers, including lung cancer. We identified two Slit2 splicing variants at exon15-Slit2-WT and Slit2-ΔE15. In the RT-PCR analyses, the Slit2-WT isoform was predominantly expressed in all the lung cancer specimens and in their normal lung counterparts, whereas Slit2-ΔE15 was equivalently or predominantly expressed in 41% of the pneumothorax specimens. A kRasG12D transgenic mice system was used to study the effects of tumorigenesis on the expressions of the Slit2-exon15 isoforms. The results revealed that a kRasG12D-induced lung tumor increased the Slit2-WT/Slit2-ΔE15 ratio and total Slit2 expression level. However, the lung tumors generated via a tail vein injection of lung cancer cells decreased the Slit2-WT/Slit2-ΔE15 ratio and total Slit2 expression level. Interestingly, the lipopolysaccharide (LPS)-induced lung inflammation also decreased the Slit2-WT/Slit2-ΔE15 ratio. Since Slit2 functions as an anti-inflammatory factor, the expression of Slit2 increases in kRasG12D lungs, which indicates that Slit2 suppresses immunity during tumorigenesis. However, an injection of lung cancer cells via the tail vein and the LPS-induced lung inflammation both decreased the Slit2 expression. The increased Slit2 in the tumor microenvironment was mostly Slit2-WT, which lacks growth inhibitory activity. Thus, the results of our study suggested that the upregulation of Slit2-WT, but not Slit2-ΔE15, in a cancer microenvironment is an important factor in suppressing immunity while not interfering with cancer growth.Slit2 expression is downregulated in various cancers, including lung cancer. We identified two Slit2 splicing variants at exon15-Slit2-WT and Slit2-ΔE15. In the RT-PCR analyses, the Slit2-WT isoform was predominantly expressed in all the lung cancer specimens and in their normal lung counterparts, whereas Slit2-ΔE15 was equivalently or predominantly expressed in 41% of the pneumothorax specimens. A kRasG12D transgenic mice system was used to study the effects of tumorigenesis on the expressions of the Slit2-exon15 isoforms. The results revealed that a kRasG12D-induced lung tumor increased the Slit2-WT/Slit2-ΔE15 ratio and total Slit2 expression level. However, the lung tumors generated via a tail vein injection of lung cancer cells decreased the Slit2-WT/Slit2-ΔE15 ratio and total Slit2 expression level. Interestingly, the lipopolysaccharide (LPS)-induced lung inflammation also decreased the Slit2-WT/Slit2-ΔE15 ratio. Since Slit2 functions as an anti-inflammatory factor, the expression of Slit2 increases in kRasG12D lungs, which indicates that Slit2 suppresses immunity during tumorigenesis. However, an injection of lung cancer cells via the tail vein and the LPS-induced lung inflammation both decreased the Slit2 expression. The increased Slit2 in the tumor microenvironment was mostly Slit2-WT, which lacks growth inhibitory activity. Thus, the results of our study suggested that the upregulation of Slit2-WT, but not Slit2-ΔE15, in a cancer microenvironment is an important factor in suppressing immunity while not interfering with cancer growth. Slit2 expression is downregulated in various cancers, including lung cancer. We identified two Slit2 splicing variants at exon15-Slit2-WT and Slit2-ΔE15. In the RT-PCR analyses, the Slit2-WT isoform was predominantly expressed in all the lung cancer specimens and in their normal lung counterparts, whereas Slit2-ΔE15 was equivalently or predominantly expressed in 41% of the pneumothorax specimens. A kRas transgenic mice system was used to study the effects of tumorigenesis on the expressions of the Slit2-exon15 isoforms. The results revealed that a kRas -induced lung tumor increased the Slit2-WT/Slit2-ΔE15 ratio and total Slit2 expression level. However, the lung tumors generated via a tail vein injection of lung cancer cells decreased the Slit2-WT/Slit2-ΔE15 ratio and total Slit2 expression level. Interestingly, the lipopolysaccharide (LPS)-induced lung inflammation also decreased the Slit2-WT/Slit2-ΔE15 ratio. Since Slit2 functions as an anti-inflammatory factor, the expression of Slit2 increases in kRas lungs, which indicates that Slit2 suppresses immunity during tumorigenesis. However, an injection of lung cancer cells via the tail vein and the LPS-induced lung inflammation both decreased the Slit2 expression. The increased Slit2 in the tumor microenvironment was mostly Slit2-WT, which lacks growth inhibitory activity. Thus, the results of our study suggested that the upregulation of Slit2-WT, but not Slit2-ΔE15, in a cancer microenvironment is an important factor in suppressing immunity while not interfering with cancer growth. |
| Author | Lin, Pinpin Su, Shang-Er Jan, Ming-Shiou Liao, Chen-Yi Chuang, Cheng-Yen Wu, Ming-Fang Chen, Wei-Ting Chang, Jinghua Tsai |
| AuthorAffiliation | 4 National Institute of Environmental Health Sciences, National Health Research Institutes, Zhunan 35053, Taiwan; pplin@nhri.org.tw 2 Divisions of Medical Oncology and Pulmonary Medicine, Chung Shan Medical University Hospital, Taichung 40201, Taiwan 5 Institute of Medicine, Chung Shan Medical University, Taichung 40201, Taiwan; jc610067@gmail.com (W.-T.C.); glucosewater@yahoo.com.tw (S.-E.S.); firmsky02@yahoo.com.tw (C.-Y.L.) 6 Department of Microbiology and Immunology, Chung Shan Medical University, Taichung 40201, Taiwan 3 Division of Thoracic Surgery, Taichung Veterans General Hospital, Taichung 40705 Taiwan; cychuangtw@gmail.com 7 Division of Allergy, Immunology and Rheumatology, Department of Internal Medicine, Chung-Shan Medical University Hospital, Taichung 40201, Taiwan 1 School of Medicine, Chung Shan Medical University, Taichung 40201, Taiwan; mfwu0111@gmail.com |
| AuthorAffiliation_xml | – name: 1 School of Medicine, Chung Shan Medical University, Taichung 40201, Taiwan; mfwu0111@gmail.com – name: 3 Division of Thoracic Surgery, Taichung Veterans General Hospital, Taichung 40705 Taiwan; cychuangtw@gmail.com – name: 4 National Institute of Environmental Health Sciences, National Health Research Institutes, Zhunan 35053, Taiwan; pplin@nhri.org.tw – name: 2 Divisions of Medical Oncology and Pulmonary Medicine, Chung Shan Medical University Hospital, Taichung 40201, Taiwan – name: 6 Department of Microbiology and Immunology, Chung Shan Medical University, Taichung 40201, Taiwan – name: 5 Institute of Medicine, Chung Shan Medical University, Taichung 40201, Taiwan; jc610067@gmail.com (W.-T.C.); glucosewater@yahoo.com.tw (S.-E.S.); firmsky02@yahoo.com.tw (C.-Y.L.) – name: 7 Division of Allergy, Immunology and Rheumatology, Department of Internal Medicine, Chung-Shan Medical University Hospital, Taichung 40201, Taiwan |
| Author_xml | – sequence: 1 givenname: Ming-Fang orcidid: 0000-0002-7208-7067 surname: Wu fullname: Wu, Ming-Fang – sequence: 2 givenname: Cheng-Yen orcidid: 0000-0002-8656-9462 surname: Chuang fullname: Chuang, Cheng-Yen – sequence: 3 givenname: Pinpin orcidid: 0000-0001-5459-907X surname: Lin fullname: Lin, Pinpin – sequence: 4 givenname: Wei-Ting surname: Chen fullname: Chen, Wei-Ting – sequence: 5 givenname: Shang-Er surname: Su fullname: Su, Shang-Er – sequence: 6 givenname: Chen-Yi surname: Liao fullname: Liao, Chen-Yi – sequence: 7 givenname: Ming-Shiou surname: Jan fullname: Jan, Ming-Shiou – sequence: 8 givenname: Jinghua Tsai surname: Chang fullname: Chang, Jinghua Tsai |
| BackLink | https://www.ncbi.nlm.nih.gov/pubmed/30717252$$D View this record in MEDLINE/PubMed |
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| Copyright | 2019 by the authors. Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (http://creativecommons.org/licenses/by/4.0/). Notwithstanding the ProQuest Terms and Conditions, you may use this content in accordance with the terms of the License. 2019 by the authors. 2019 |
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| Keywords | LPS treatment lung cancer inflammation Slit2 splicing variants tumor microenvironment kRasG12D pneumothorax |
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| Snippet | Slit2 expression is downregulated in various cancers, including lung cancer. We identified two Slit2 splicing variants at exon15—Slit2-WT and Slit2-ΔE15. In... Slit2 expression is downregulated in various cancers, including lung cancer. We identified two Slit2 splicing variants at exon15-Slit2-WT and Slit2-ΔE15. In... |
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| SubjectTerms | Angiogenesis Brain Cell growth Inflammation Injection Isoforms Lipopolysaccharides Lung cancer Metastasis Pneumothorax Polymerase chain reaction Roles Transgenic mice Tumor microenvironment Tumorigenesis Tumors Veins & arteries |
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| Title | Lung Tumorigenesis Alters the Expression of Slit2-exon15 Splicing Variants in Tumor Microenvironment |
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