Adult lung stem cells and their contribution to lung tumourigenesis

The isolation and characterization of lung stem and progenitor cells represent an important step towards the understanding of lung repair after injury, lung disease pathogenesis and the identification of the target cells of transformation in lung carcinogenesis. Different approaches using prospective isolation of progenitor cells by flow cytometry or lineage-tracing experiments in mouse models of lung injury have led to the identification of distinct progenitor subpopulations in different morphological regions of the adult lung. Genetically defined mouse models of lung cancer are offering new perspectives on the cells of origin of different subtypes of lung cancer. These mouse models pave the way to further investigate human lung progenitor cells at the origin of lung cancers, as well as to define the nature of the lung cancer stem cells. It will be critical to establish the link between oncogenic driver mutations recently discovered in lung cancers, target cells of transformation and subtypes of lung cancers to enable better stratification of patients for improved therapeutic strategies.     

Benzamide riboside induced mitochondrial mediated apoptosis in human lung cancer H520 cells

Benzamide riboside (BR) is a novel anticancer agent exhibiting pronounced activity against several human tumor cell lines via the inhibition of inosine 5'-monophosphate dehydrogenase (IMPDH), thereby restricting the biosynthesis of guanylates. Although it has been demonstrated that BR inhibits IMPDH and induces apoptosis, however, not much attention has been directed to the mechanism of apoptosis induction by this compound. The purpose of the present investigation was to investigate the mechanism of cytotoxicity induced by BR in human lung cancer cells. Non-small cell lung cancer [NSCLC] is the most prevalent type of lung cancer especially in India, and displays resistance to anticancer treatment. The results reveal that BR at a dose of 50 microM induces apoptosis in NSCLC H520 cells. This was ascertained by alteration in cellular morphology, TUNEL assay and flow cytometry. While Bax protein level was unaffected there was down regulation of anti-apoptotic Bcl-2 protein and up regulation of p53 as observed by Western blotting. Induction of apoptosis was accompanied by significant increase in caspase-3 activity. BR is a potent growth inhibitory pro-drug rationally synthesized to mimic NAD and inhibits PARP at high concentrations when assayed in permeabilized leukemic cells. Our observations showed that increased caspase-3 activity was accompanied by PARP cleavage. We also observed release of cytochrome c from mitochondria to the cytosol whereas no change was seen in the levels of apoptosis inducing factor (AIF). These findings indicate that BR induces apoptosis in H520 cells via the intrinsic mitochondrial pathway.     

Induction of senescence by adenosine suppressing the growth of lung cancer cells

Extracellular adenosine is well reported to suppress tumor growth by induction of apoptosis. However, in this study we found that adenosine treatment results in cellular senescence in A549 lung cancer cells both in vitro and in vivo; adenosine induces cell cycle arrest and senescence in a p53/p21 dependent manner; adenosine elevates the level of phosphor-γH2AX, pCHK2 and pBRCA1, the markers for prolonged DNA damage response which are likely responsible for initiating the cellular senescence. Our study first demonstrates that adenosine suppresses growth of cancer cells by inducing senescence and provides additional evidence that adenosine could act as an effective anticancer agent for targeted cancer therapy.     

Selective inhibition of human lung cancer cell growth by peptides derived from retinoblastoma protein

Peptides containing retinoblastoma protein (RB) fragment 649-654 (LFYKKV) were tested for their ability to block the proliferation of RB-negative and RB-positive human non-small cell lung cancer (NSCLC) cells. These peptides potently restrained the growth of both types of tumor cells, as measured by metabolic (MTT) and cellular viability (trypan blue exclusion) assays. As such, and remarkably, the peptides were able to overcome the resistance of RB-positive cells usually observed with RB gene or protein replacement therapy. Compared to the overall performance of conventional chemotherapy tested in parallel, the peptides were more cytotoxic against RB-negative neoplastic cells and equipotent toward RB-positive tumor cells, yet less toxic toward normal human cells. Thus, these new molecules hold great promise to evolve into an efficient therapy for human lung cancer, a common malignancy still defying treatment and holding a poor prognosis, as well as for other human neoplasias.     

Cigarette smoke alters the secretome of lung epithelial cells

Cigarette smoke is the most relevant risk factor for the development of lung cancer and chronic obstructive pulmonary disease. Many of its more than 4500 chemicals are highly reactive, thereby altering protein structure and function. Here, we used subcellular fractionation coupled to label‐free quantitative MS to globally assess alterations in the proteome of different compartments of lung epithelial cells upon exposure to cigarette smoke extract. Proteomic profiling of the human alveolar derived cell line A549 revealed the most pronounced changes within the cellular secretome with preferential downregulation of proteins involved in wound healing and extracellular matrix organization. In particular, secretion of secreted protein acidic and rich in cysteine, a matricellular protein that functions in tissue response to injury, was consistently diminished by cigarette smoke extract in various pulmonary epithelial cell lines and primary cells of human and mouse origin as well as in mouse ex vivo lung tissue cultures. Our study reveals a previously unrecognized acute response of lung epithelial cells to cigarette smoke that includes altered secretion of proteins involved in extracellular matrix organization and wound healing. This may contribute to sustained alterations in tissue remodeling as observed in lung cancer and chronic obstructive pulmonary disease.     

Protein arginine methyltransferase 5 is essential for growth of lung cancer cells

PRMT5 (protein arginine methyltransferase 5) is an enzyme that catalyses transfer of methyl groups from S-adenosyl methionine to the arginine residues of histones or non-histone proteins and is involved in a variety of cellular processes. Although it is highly expressed in some tumours, its direct role in cancer growth has not been fully investigated. In the present study, in human lung tissue samples we found that PRMT5 was highly expressed in lung cancer cells, whereas its expression was not detectable in benign lung tissues. Silencing PRMT5 expression strongly inhibited proliferation of lung adenocarcinoma A549 cells in tissue culture, and silencing PRMT5 expression in A549 cells also abolished growth of lung A549 xenografts in mice. In vitro and in vivo studies showed that the cell growth arrest induced by loss of PRMT5 expression was partially attributable to down-regulation of fibroblast growth factor receptor signalling. These results suggest that PRMT5 and its methyltransferase activity is essential for proliferation of lung cancer cells and may serve as a novel target for the treatment of lung cancer.     

Autophagy upregulation by inhibitors of caspase-3 and mTOR enhances radiotherapy in a mouse model of lung cancer

Autophagy has been reported to be increased in irradiated cancer cells resistant to various apoptotic stimuli. We therefore hypothesized that induction of autophagy via mTOR inhibition enhances radiosensitization in apoptosis-inhibited H460 lung cancer cells in vitro and in a lung cancer xenograft model. To test this hypothesis, combinations of Z-DEVD (caspase-3 inhibitor), RAD001 (mTOR inhibitor) and irradiation were tested in cell and mouse models. The combination of Z-DEVD and RAD001 more potently radiosensitized H460 cells than individual treatment alone. The enhancement in radiation response was not only evident in clonogenic survival assays, but also was demonstrated through markedly reduced tumor growth, cellular proliferation (Ki67 staining), apoptosis (TUNEL staining), and angiogenesis (vWF staining) in vivo. Additionally, upregulation of autophagy as measured by increased GFP-LC3-tagged autophagosome formation accompanied the noted radiosensitization in vitro and in vivo. The greatest induction of autophagy and associated radiation toxicity was exhibited in the tri-modality treatment group. Autophagy marker, LC-3-II, was reduced by 3-methyladenine (3-MA), a known inhibitor of autophagy, but further increased by the addition of lysosomal protease inhibitors (pepstatin A and E64d), demonstrating that there is autophagic induction through type III PI3 kinase during the combined therapy. Knocking down of ATG5 and beclin-1, two essential autophagic molecules, resulted in radiation resistance of lung cancer cells. Our report suggests that combined inhibition of apoptosis and mTOR during radiotherapy is a potential therapeutic strategy to enhance radiation therapy in patients with non-small cell lung cancer.     

Autophagy upregulation by inhibitors of caspase-3 and mTOR enhances radiotherapy in a mouse model of lung cancer

Autophagy has been reported to be increased in irradiated cancer cells resistant to various apoptotic stimuli. We therefore hypothesized that induction of autophagy via mTOR inhibition could enhance radiosensitization in apoptosis-inhibited H460 lung cancer cells in vitro and in a lung cancer xenograft model. To test this hypothesis, combinations of Z-DEVD (caspase-3 inhibitor), RAD001 (mTOR inhibitor) and irradiation were tested in cell and mouse models. The combination of Z-DEVD and RAD001 more potently radiosensitized H460 cells than individual treatment alone. The enhancement in radiation response was not only evident in clonogenic survival assays, but also was demonstrated through markedly reduced tumor growth, cellular proliferation (Ki67 staining), apoptosis (TUNEL staining) and angiogenesis (vWF staining) in vivo. Additionally, upregulation of autophagy as measured by increased GFP-LC3-tagged autophagosome formation accompanied the noted radiosensitization in vitro and in vivo. The greatest induction of autophagy and associated radiation toxicity was exhibited in the tri-modality treatment group. Autophagy marker, LC-3-II, was reduced by 3-methyladenine (3-MA), a known inhibitor of autophagy, but further increased by the addition of lysosomal protease inhibitors (pepstatin A and E64d), demonstrating that there is autophagic induction through type III PI3 kinase during the combined therapy. Knocking down of ATG5 and beclin-1, two essential autophagic molecules, resulted in radiation resistance of lung cancer cells. Our report suggests that combined inhibition of apoptosis and mTOR during radiotherapy is a potential therapeutic strategy to enhance radiation therapy in patients with non-small cell lung cancer.     

肺部微生态与肺癌的关系

近年来肿瘤相关微生物的研究已成为热点,主要涉及细菌、免疫细胞和肿瘤细胞之间的相互作用、细菌致癌途径及其在肿瘤诊断及治疗意义等方面。随着微生物检测手段的飞速发展,人们发现,肺部具有独特的微生态,越来越多的研究在求证肺部微生态与呼吸系统疾病之间的联系。肺癌目前仍然是威胁人类健康的最常见、预后极差的恶性肿瘤。寻求早期筛查、干预、诊治手段是目前攻克肺癌的重点和难点。肺癌患者的肺微生态有其特征性改变,微生物可能通过产生细菌毒素和其他炎性因子而影响肺癌的发生及发展。本文对肺微生态与肺癌相关性进行了综述,并对今后的研究提出了展望。     

Combination therapy with KRAS siRNA and EGFR inhibitor AZD8931 suppresses lung cancer cell growth in vitro

Lung cancer is a leading cause of cancer-related deaths worldwide, with less than a 5-year survival rate for both men and women. Epidermal growth factor receptor (EGFR) and Kirsten rat sarcoma oncogene (KRAS) signaling pathways play a critical role in the proliferation and progression of various cancers, including lung cancer. Genetic studies have shown that amplification, over-expression, or mutation of EGFR is an early and major molecular event in many human tumors. KRAS mutation is a negative factor in various cancer, including non-small-cell lung cancer, and complicates therapeutic approaches with adjuvant chemotherapy and anti-EGFR directed therapies. This article is dedicated to evaluating the synergistic effect of a novel EGFR inhibitor AZD8931 and KRAS small interfering RNA (siRNA) on the proliferation and apoptosis of lung adenocarcinoma cancer cells. A549 lung cancer cells were treated with KRAS siRNA and the EGFR inhibitor alone or in combination. The cytotoxic effects of KRAS siRNA and te EGFR inhibitor were determined usingMTT assay, and induction of apoptosis was determined by FACS analysis. Suppression of KRAS, Her-2, and EGFR expression by treatments was measured by qRT-PCR and western blotting. KRAS siRNA and the EGFR inhibitor significantly reduced the proliferation of A549 cells as well as KRAS and EGFR mRNA levels 24 hr after treatment. The results also indicated that the silencing of KRAS and EGFR has synergistic effects on the induction of apoptosis on the A549 cells. These results indicated that KRAS and EGFR might play important roles in the progression of lung cancer and could be potential therapeutic targets for treatment of lung cancer.     

Adipose tissue displays trophic properties on normal lung cellular components without promoting cancer cells growth

Surgical removal is the mainstay for early lung cancer treatment and persistent air leaks represent one of the most common clinical complications after lung surgery. Adipose tissue transplantation has been proposed as a new strategy for regenerative therapy after breast cancer surgery; however its efficacy and safety of lung tissue healing after lung resections are unknown. The purpose of this study was to test the biological activity of adipose tissue to facilitate lung tissue healing and evaluate its effect on cancer cells growth, thus providing insight for a possible clinical application. Different in vitro cellular models were used to prove the potential biologic effect of autologous fat tissue (AFT) in repairing injured lung tissue, and in vivo xenograft models were used to evaluate tumor promoting potential of AFT on putative residual cancer cells. Treatment of both embryonic (WI‐38) and adult lung fibroblasts and of normal bronchial epithelial cells (HBEC‐KT) with AFT samples, harvested from subcutaneous tissue layer of 20 patients undergoing pulmonary metastasectomy, improved wound healing and cell proliferation indicating a trophic effect on both mesenchymal and epithelial cell types. Conversely AFT‐conditioned medium was unable to stimulate in vitro proliferation of a lung adenocarcinoma reporter cellular system (A549). Moreover, co‐injection of AFT and A549 cells in nude mice did not promote engraftment and progression of A549 cells. These preclinical findings provide preliminary evidence on the potential efficacy of AFT to accelerate lung tissue repair without undesired tumor promoting effects on putative residual cancer cells. J. Cell. Physiol. 228: 1166–1173, 2013. © 2012 Wiley Periodicals, Inc.     

Paving the road for lung stem cell biology: bronchioalveolar stem cells and other putative distal lung stem cells

New discoveries in stem cell biology are making the biology of solid tissues increasingly complex. Important seminal studies demonstrating the presence of damage-resistant cell populations together with new isolation and characterization techniques suggest that stem cells exist in the adult lung. More detailed in vivo molecular and cellular characterization of bronchioalveolar stem cells (BASCs), other putative lung stem and progenitor cells, and differentiated cells is needed to determine the lineage relationships in adult lung. Lung diseases such as cystic fibrosis or chronic obstructive pulmonary disease, as well as the most common form of lung cancer in the United States, all involve apparent bronchiolar and alveolar cell defects. It is likely that the delicate balance of stem, progenitor, and differentiated cell functions in the lung is critically affected in patients with these devastating diseases. Thus the discovery of BASCs and other putative lung stem cells will lay the foundation for new inroads to understanding lung biology related to lung disease.     

PTPN3 is a potential target for a new cancer immunotherapy that has a dual effect of T cell activation and direct cancer inhibition in lung neuroendocrine tumor

In our previous study, we found that inhibition of protein tyrosine phosphatase non-receptor type 3 (PTPN3), which is expressed in lymphocytes, enhances lymphocyte activation, suggesting PTPN3 may act as an immune checkpoint molecule. However, PTPN3 is also expressed in various cancers, and the biological significance of PTPN3 in cancer cells is still not well understood, especially for lung neuroendocrine tumor (NET).Therefore, we analyzed the biological significance of PTPN3 in small cell lung cancer and examined the potential for PTPN3 inhibitory treatment as a cancer treatment approach in lung NET including small cell lung cancer (SCLC) and large cell neuroendocrine cancer (LCNEC).Experiments in a mouse xenograft model using allo lymphocytes showed that PTPN3 inhibition in SCLC cells enhanced the anti-tumor effect of PTPN3-suppressed activated lymphocytes. In addition, PTPN3 was associated with increased vascularization, decreased CD8/FOXP3 ratio and cellular immunosuppression in SCLC clinical specimens. Experiments in a mouse xenograft model using autocrine lymphocytes also showed that PTPN3 inhibition in LCNEC cells augmented the anti-tumor effect of PTPN3-suppressed activated lymphocytes. In vitro experiments showed that PTPN3 is involved in the induction of malignant traits such as proliferation, invasion and migration. Signaling from PTPN3 is mediated by MAPK and PI3K signals via tyrosine kinase phosphorylation through CACNA1G calcium channel. Our results show that PTPN3 suppression is associated with lymphocyte activation and cancer suppression in lung NET. These results suggest that PTPN3 suppression could be a new method of cancer treatment and a major step in the development of new cancer immunotherapies.