Joseph Gerrein

MicroRNA 4423 is a primate-specific regulator of airway epithelial cell differentiation and lung carcinogenesis

Significance MicroRNAs are small noncoding RNAs that negatively regulate gene expression and have been implicated in a variety of cellular processes. Using small RNA sequencing, we identified microRNA 4423 (miR-4423) as a primate-specific microRNA whose expression is largely restricted to airway epithelium and which functions as a regulator of airway epithelium differentiation and a repressor of lung carcinogenesis. Understanding miR-4423’s role in airway development may provide insights into primate-specific aspects of airway biology and the evolution of primate-specific tumor suppressors. Moreover, this study opens the possibility that microRNAs might be useful for the early detection of lung cancer in the proximal airway and that miR-4423 mimetics might also be used as therapeutic agents to specifically target lung cancer. Smoking is a significant risk factor for lung cancer, the leading cause of cancer-related deaths worldwide. Although microRNAs are regulators of many airway gene-expression changes induced by smoking, their role in modulating changes associated with lung cancer in these cells remains unknown. Here, we use next-generation sequencing of small RNAs in the airway to identify microRNA 4423 (miR-4423) as a primate-specific microRNA associated with lung cancer and expressed primarily in mucociliary epithelium. The endogenous expression of miR-4423 increases as bronchial epithelial cells undergo differentiation into mucociliary epithelium in vitro, and its overexpression during this process causes an increase in the number of ciliated cells. Furthermore, expression of miR-4423 is reduced in most lung tumors and in cytologically normal epithelium of the mainstem bronchus of smokers with lung cancer. In addition, ectopic expression of miR-4423 in a subset of lung cancer cell lines reduces their anchorage-independent growth and significantly decreases the size of the tumors formed in a mouse xenograft model. Consistent with these phenotypes, overexpression of miR-4423 induces a differentiated-like pattern of airway epithelium gene expression and reverses the expression of many genes that are altered in lung cancer. Together, our results indicate that miR-4423 is a regulator of airway epithelium differentiation and that the abrogation of its function contributes to lung carcinogenesis.

Shared Gene Expression Alterations in Nasal and Bronchial Epithelium for Lung Cancer Detection

Background: We previously derived and validated a bronchial epithelial gene expression biomarker to detect lung cancer in current and former smokers. Given that bronchial and nasal epithelial gene expression are similarly altered by cigarette smoke exposure, we sought to determine if cancer-associated gene expression might also be detectable in the more readily accessible nasal epithelium. Methods: Nasal epithelial brushings were prospectively collected from current and former smokers undergoing diagnostic evaluation for pulmonary lesions suspicious for lung cancer in the AEGIS-1 (n = 375) and AEGIS-2 (n = 130) clinical trials and gene expression profiled using microarrays. All statistical tests were two-sided. Results: We identified 535 genes that were differentially expressed in the nasal epithelium of AEGIS-1 patients diagnosed with lung cancer vs those with benign disease after one year of follow-up (P < .001). Using bronchial gene expression data from the AEGIS-1 patients, we found statistically significant concordant cancer-associated gene expression alterations between the two airway sites (P < .001). Differentially expressed genes in the nose were enriched for genes associated with the regulation of apoptosis and immune system signaling. A nasal lung cancer classifier derived in the AEGIS-1 cohort that combined clinical factors (age, smoking status, time since quit, mass size) and nasal gene expression (30 genes) had statistically significantly higher area under the curve (0.81; 95% confidence interval [CI] = 0.74 to 0.89, P = .01) and sensitivity (0.91; 95% CI = 0.81 to 0.97, P = .03) than a clinical-factor only model in independent samples from the AEGIS-2 cohort. Conclusions: These results support that the airway epithelial field of lung cancer–associated injury in ever smokers extends to the nose and demonstrates the potential of using nasal gene expression as a noninvasive biomarker for lung cancer detection.

Assessment of microRNA differential expression and detection in multiplexed small RNA sequencing data

Small RNA sequencing can be used to gain an unprecedented amount of detail into the microRNA transcriptome. The relatively high cost and low throughput of sequencing bases technologies can potentially be offset by the use of multiplexing. However, multiplexing involves a trade-off between increased number of sequenced samples and reduced number of reads per sample (i.e., lower depth of coverage). To assess the effect of different sequencing depths owing to multiplexing on microRNA differential expression and detection, we sequenced the small RNA of lung tissue samples collected in a clinical setting by multiplexing one, three, six, nine, or 12 samples per lane using the Illumina HiSeq 2000. As expected, the numbers of reads obtained per sample decreased as the number of samples in a multiplex increased. Furthermore, after normalization, replicate samples included in distinct multiplexes were highly correlated (R > 0.97). When detecting differential microRNA expression between groups of samples, microRNAs with average expression >1 reads per million (RPM) had reproducible fold change estimates (signal to noise) independent of the degree of multiplexing. The number of microRNAs detected was strongly correlated with the log2 number of reads aligning to microRNA loci (R = 0.96). However, most additional microRNAs detected in samples with greater sequencing depth were in the range of expression which had lower fold change reproducibility. These findings elucidate the trade-off between increasing the number of samples in a multiplex with decreasing sequencing depth and will aid in the design of large-scale clinical studies exploring microRNA expression and its role in disease.

Characterizing the small RNA transcriptome associated with COPD and ILD using next-generation sequencing

Background Despite the increasing public health burden associated with chronic obstructive pulmonary disease (COPD) and interstitial lung disease (ILD), the molecular mechanisms responsible for the pathogenesis of these diseases remain unclear. The goal of this study was to comprehensively profile the lung small RNA transcriptome via next-generation sequencing, and elucidate microRNAs that might contribute to COPD and ILD pathogenesis.

Abstract A1-66: Leveraging Gene Expression in the Bronchial Airway to Develop a Nasal Biomarker for Early Detection of Lung Cancer

Rationale: Lung cancer results in five times more deaths per year than car accidents in the United States. Approximately 57% of lung cancers diagnosed this year will be diagnosed at a late stage and these patients will exhibit a 5-year survival rate of only 4%. Annual screening of high-risk current and former smokers by chest-CT can reduce cancer mortality, however this procedure has a 95% false positive rate. It is therefore critical to develop methods to rapidly and accurately determine which patients with nodules on chest CT have lung cancer and potentially spare those with benign disease an unnecessary invasive procedure. We have previously demonstrated that specific gene expression alterations in cytologically normal bronchial epithelial cells from patients with lung cancer can be leveraged to form a clinically informative lung cancer biomarker in the population of patients undergoing bronchoscopy for suspect lung cancer. We hypothesized that there might be similar expression differences in nasal epithelium and that these could form the basis of a less invasive test that could be applied more broadly to individuals with screen detected nodules on chest CT. Methods: Bronchial (n=676) and nasal (n=280) epithelial brushings were collected from current and former smokers undergoing bronchoscopy for clinical suspicion of lung cancer within the AEGIS clinical trial. 271 subjects had matched bronchial and nasal samples. RNA was extracted and hybridized to Affymetrix Human Gene ST 1.0 Arrays. To establish a connection between bronchial and nasal epithelial gene expression signal for cancer, we first applied the bronchial gene expression-based diagnostic test, BronchoGen, directly to our nasal cohort. Gene Set Enrichment Analysis was then used to determine the concordance of cancer signal between the bronchial and nasal epithelium. To develop the nasal gene expression biomarker for lung cancer detection, we examined the correlation of each gene between the bronchial and nasal epithelium as well as the significance of each gene9s association with cancer in each tissue. Genes passing our selection criteria were passed to a biomarker discovery pipeline in which we examined the performance of different biomarker algorithm configurations (e.g. feature-selection algorithms, classification algorithms, and other biomarker parameters) using cross-validation. Results: Direct application of BronchoGen to our nasal cohort resulted in an AUC of 0.64 on a set of NE samples (n=110) with a matched bronchial sample in the training set used to develop the test. On an independent set of nasal samples (n=109), BronchoGen achieved an AUC of 0.67. Gene Set Enrichment Analysis revealed high levels of concordance between cancer-associated nasal and bronchial gene expression. Using a cross-validation approach, we found that nasal biomarkers built from sets of genes showing significant correlation (p Conclusions: Given the larger sample size, more isolated location in the airway, and higher RIN scores that characterize the bronchial cohort, we sought to leverage bronchial airway epithelial gene-expression to inform which genes in the nasal epithelium should be indicative of the presence of cancer. We have shown that gene expression in the nasal epithelium reflects the presence of lung cancer and can serve as a diagnostic biomarker. We have further demonstrated concordance between bronchial and nasal airway gene expression differences associated with lung cancer. These results suggest the potential to develop a robust nasal gene expression biomarker for lung cancer diagnosis that leverages cancer-associated gene expression differences occurring at other airway sites. Citation Format: Joseph F. Perez-Rogers, Joseph Gerrein, Christina Anderlind, Rebecca L. Kusko, Joshua D. Campbell, Teresa W. Wang, Kate Porta, Duncan Whitney, Avrum Spira, Marc Lenburg. Leveraging Gene Expression in the Bronchial Airway to Develop a Nasal Biomarker for Early Detection of Lung Cancer. [abstract]. In: Proceedings of the AACR Special Conference on Translation of the Cancer Genome; Feb 7-9, 2015; San Francisco, CA. Philadelphia (PA): AACR; Cancer Res 2015;75(22 Suppl 1):Abstract nr A1-66.

Abstract 1574: Leveraging bronchial airway gene expression to develop a nasal biomarker for lung cancer detection

Proceedings: AACR 106th Annual Meeting 2015; April 18-22, 2015; Philadelphia, PA Rationale: Using nasal gene expression to predict the presence of lung cancer would offer a less invasive alternative to diagnostic approaches we have pioneered using bronchial airway epithelial (BE) gene expression. We have previously demonstrated that cytologically normal BE and nasal epithelial (NE) cells harbor gene expression differences that reflect tobacco-related lung disease and that these changes in the BE form the basis of a clinically informative lung cancer biomarker. Given the concordance of BE and NE gene-expression, we hypothesized that gene signatures associated with the presence of lung cancer extend from the airway to the nose and that lung cancer associated BE gene-expression could be leveraged to develop more accurate nasal lung cancer biomarkers. Methods: BE (n = 676) and NE (n = 280) brushings were collected from current and former smokers undergoing bronchoscopy for clinical suspicion of lung cancer. We leveraged two methods to determine the concordance between BE and NE gene-expression signal for cancer. First we applied the bronchial gene expression-based diagnostic test directly to our nasal cohort. Second, we used Gene Set Enrichment Analysis (GSEA) to quantify the relationship between the BE and NE. To develop the nasal gene expression biomarker, we examined the correlation of each gene between the BE and NE. Genes passing our selection criteria were passed to a biomarker discovery pipeline in which we examined the performance of different biomarker algorithm configurations using cross-validation. Results: Direct application of the bronchial airway gene-expression classifier to an independent set of nasal samples (n = 109) resulted in an AUC of 0.67. GSEA revealed high concordance (p<0.001) between cancer-associated nasal and bronchial gene expression profiles from the same patients. Using a cross-validation approach, we found that nasal biomarkers built from sets of genes showing significant correlation (p<0.05) between the BE and NE as well as significance for cancer in both tissues (p<0.05) perform better, on average, than biomarkers built from genes significant for cancer (p<0.05) in the NE alone. Conclusions. We have demonstrated concordance between BE and NE gene expression differences associated with lung cancer. We have further shown that gene expression in the NE reflects the presence of lung cancer and can serve as a diagnostic biomarker. These results demonstrate the feasibility of leveraging cancer-associated gene expression changes throughout the airway to develop a minimally invasive and robust nasal gene expression biomarker for lung cancer diagnosis. Citation Format: Joseph Perez-Rogers, Joseph Gerrein, Christina Anderlind, Xiaohui Xiao, Hanqiao Liu, Rebecca Kusko, Joshua Campbell, Teresa Wang, Yuriy Alekseyev, Gang Liu, Kate Porta, Duncan Whitney, Avrum Spira, Marc Lenburg. Leveraging bronchial airway gene expression to develop a nasal biomarker for lung cancer detection. [abstract]. In: Proceedings of the 106th Annual Meeting of the American Association for Cancer Research; 2015 Apr 18-22; Philadelphia, PA. Philadelphia (PA): AACR; Cancer Res 2015;75(15 Suppl):Abstract nr 1574. doi:10.1158/1538-7445.AM2015-1574

MicroRNA 4423 is a primate-specific regulator of airway epithelial cell differentiation and lung carcinogenesis - eScholarship

Significance MicroRNAs are small noncoding RNAs that negatively regulate gene expression and have been implicated in a variety of cellular processes. Using small RNA sequencing, we identified microRNA 4423 (miR-4423) as a primate-specific microRNA whose expression is largely restricted to airway epithelium and which functions as a regulator of airway epithelium differentiation and a repressor of lung carcinogenesis. Understanding miR-4423’s role in airway development may provide insights into primate-specific aspects of airway biology and the evolution of primate-specific tumor suppressors. Moreover, this study opens the possibility that microRNAs might be useful for the early detection of lung cancer in the proximal airway and that miR-4423 mimetics might also be used as therapeutic agents to specifically target lung cancer. Smoking is a significant risk factor for lung cancer, the leading cause of cancer-related deaths worldwide. Although microRNAs are regulators of many airway gene-expression changes induced by smoking, their role in modulating changes associated with lung cancer in these cells remains unknown. Here, we use next-generation sequencing of small RNAs in the airway to identify microRNA 4423 (miR-4423) as a primate-specific microRNA associated with lung cancer and expressed primarily in mucociliary epithelium. The endogenous expression of miR-4423 increases as bronchial epithelial cells undergo differentiation into mucociliary epithelium in vitro, and its overexpression during this process causes an increase in the number of ciliated cells. Furthermore, expression of miR-4423 is reduced in most lung tumors and in cytologically normal epithelium of the mainstem bronchus of smokers with lung cancer. In addition, ectopic expression of miR-4423 in a subset of lung cancer cell lines reduces their anchorage-independent growth and significantly decreases the size of the tumors formed in a mouse xenograft model. Consistent with these phenotypes, overexpression of miR-4423 induces a differentiated-like pattern of airway epithelium gene expression and reverses the expression of many genes that are altered in lung cancer. Together, our results indicate that miR-4423 is a regulator of airway epithelium differentiation and that the abrogation of its function contributes to lung carcinogenesis.

From the Cover: MicroRNA 4423 is a primate-specific regulator of airway epithelial cell differentiation and lung carcinogenesis

Significance MicroRNAs are small noncoding RNAs that negatively regulate gene expression and have been implicated in a variety of cellular processes. Using small RNA sequencing, we identified microRNA 4423 (miR-4423) as a primate-specific microRNA whose expression is largely restricted to airway epithelium and which functions as a regulator of airway epithelium differentiation and a repressor of lung carcinogenesis. Understanding miR-4423’s role in airway development may provide insights into primate-specific aspects of airway biology and the evolution of primate-specific tumor suppressors. Moreover, this study opens the possibility that microRNAs might be useful for the early detection of lung cancer in the proximal airway and that miR-4423 mimetics might also be used as therapeutic agents to specifically target lung cancer. Smoking is a significant risk factor for lung cancer, the leading cause of cancer-related deaths worldwide. Although microRNAs are regulators of many airway gene-expression changes induced by smoking, their role in modulating changes associated with lung cancer in these cells remains unknown. Here, we use next-generation sequencing of small RNAs in the airway to identify microRNA 4423 (miR-4423) as a primate-specific microRNA associated with lung cancer and expressed primarily in mucociliary epithelium. The endogenous expression of miR-4423 increases as bronchial epithelial cells undergo differentiation into mucociliary epithelium in vitro, and its overexpression during this process causes an increase in the number of ciliated cells. Furthermore, expression of miR-4423 is reduced in most lung tumors and in cytologically normal epithelium of the mainstem bronchus of smokers with lung cancer. In addition, ectopic expression of miR-4423 in a subset of lung cancer cell lines reduces their anchorage-independent growth and significantly decreases the size of the tumors formed in a mouse xenograft model. Consistent with these phenotypes, overexpression of miR-4423 induces a differentiated-like pattern of airway epithelium gene expression and reverses the expression of many genes that are altered in lung cancer. Together, our results indicate that miR-4423 is a regulator of airway epithelium differentiation and that the abrogation of its function contributes to lung carcinogenesis.

Abstract 3173: Identification of miR-4423 as a primate-specific microRNA highly expressed in airway epithelium and associated with lung cancer

Smoking is a significant risk factor for lung cancer, the leading cause of cancer-related deaths worldwide. Our group has previously shown that epithelial gene expression is altered throughout the airway of smokers and that some of these changes are regulated by microRNAs. Moreover, we have previously identified gene expression differences in cytologically normal bronchial airway epithelial cells between smokers with and without lung cancer that can serve as an early diagnostic biomarker for lung cancer. Here, we use next-generation sequencing of small RNAs to identify novel microRNAs expressed in airway epithelium and associated with lung cancer. We identify miR-4423 as a primate-specific microRNA highly expressed in the airway epithelium. In vitro, the expression of miR-4423 increases as Normal Human Bronchial Epithelial cells are differentiated into mucociliary epithelium at an Air Liquid Interface, while its mRNA targets decrease in expression. Furthermore, the expression of miR-4423 is reduced in lung tumors and in the cytologically normal bronchial airway epithelium of smokers with lung cancer. In gain-of-function experiments, ectopic expression of miR-4423 in lung cancer cell lines resulted in reduced colony formation in soft agar. Taken together, these data support the power of next-generation sequencing in identifying novel cell type- specific transcripts and provides evidence that this newly characterized microRNA may play a role in promoting the differentiation and/or maintenance of airway epithelium, and can reduce anchorage-independent lung cancer cell growth. Citation Format: {Authors}. {Abstract title} [abstract]. In: Proceedings of the 103rd Annual Meeting of the American Association for Cancer Research; 2012 Mar 31-Apr 4; Chicago, IL. Philadelphia (PA): AACR; Cancer Res 2012;72(8 Suppl):Abstract nr 3173. doi:1538-7445.AM2012-3173

Abstract 1987: RNA-seq of the bronchial airway transcriptome identifies novel gene and microRNA expression changes associated with smoking and lung cancer

Proceedings: AACR 101st Annual Meeting 2010‐‐ Apr 17‐21, 2010; Washington, DC Prior studies have shown that cigarette smoke creates a field of molecular injury in the airway epithelium. Using microarrays, our group has previously identified gene and microRNA expression differences in bronchial airway epithelial cells that are associated with smoking and lung cancer. We hypothesize that RNA-seq of the airway transcriptome will enhance our understanding of the response to tobacco smoke exposure and lung cancer pathogenesis by identifying mRNA splice variants, non-coding RNA, and novel RNA not interrogated by microarrays. We profiled pooled bronchial airway epithelial cell brushings (n=3 patients/pool) obtained during bronchoscopy from healthy never and current smoker volunteers and smokers with and without lung cancer undergoing surgery for suspicion of lung cancer. The high MW fraction (>200 bp) was amplified using a combination of oligo d(T) and random hexamers (NuGEN, San Carlos, CA) followed by library preparation with Illuminas mRNA Seq Library Prep Kit and sequencing using Illuminas Genome Analyzer generating ∼27-30 million 36 bp reads/sample. The low MW fraction (15-40 bp) was processed using ABIs Small RNA Library Sequencing Kit and sequenced using ABIs SOLiD system generating ∼50-90 million 35 bp reads/sample. The high MW reads were aligned to rRNA (5-13%), the human genome (33-40%), and to computationally generated splice junctions (1%) using BowTie. Differential gene and isoform expression was evaluated using Cufflinks and the R package Genominator. Low MW reads were aligned using both RNA2MAP and Geospiza to a filter containing rRNA, tRNA, and repeats (4-14%), to miRBase (4-10%), and the human genome minus miRBase sequences (4-8%). Expression values were calculated for microRNAs. We compared Affymetrix Exon 1.0 ST, HGU133A2, and Invitrogen miRNA microarrays to RNA-seq and found strong correlation for genes/miRNAs interrogated by microarrays, with most smoking- and cancer related changes in transcript expression being identified by sequencing and not by arrays. Genes found differentially expressed only by sequencing were validated by RT-PCR. RNA-seq also reveals differentially expressed isoforms, potential novel miRNAs, and several isoforms of known miRNAs which are being further investigated. RNA-seq provides a comprehensive and high-resolution view of the airway transcriptome and will provide insights into the molecular field of injury induced by smoking and the pathogenesis of smoking-related lung disease. Citation Format: {Authors}. {Abstract title} [abstract]. In: Proceedings of the 101st Annual Meeting of the American Association for Cancer Research; 2010 Apr 17-21; Washington, DC. Philadelphia (PA): AACR; Cancer Res 2010;70(8 Suppl):Abstract nr 1987.