Chad A. Newton

Telomere-related lung fibrosis is diagnostically heterogeneous but uniformly progressive.

Heterozygous mutations in four telomere-related genes have been linked to pulmonary fibrosis, but little is known about similarities or differences of affected individuals. 115 patients with mutations in telomerase reverse transcriptase (TERT) (n=75), telomerase RNA component (TERC) (n=7), regulator of telomere elongation helicase 1 (RTEL1) (n=14) and poly(A)-specific ribonuclease (PARN) (n=19) were identified and clinical data were analysed. Approximately one-half (46%) had a multidisciplinary diagnosis of idiopathic pulmonary fibrosis (IPF); others had unclassifiable lung fibrosis (20%), chronic hypersensitivity pneumonitis (12%), pleuroparenchymal fibroelastosis (10%), interstitial pneumonia with autoimmune features (7%), an idiopathic interstitial pneumonia (4%) and connective tissue disease-related interstitial fibrosis (3%). Discordant interstitial lung disease diagnoses were found in affected individuals from 80% of families. Patients with TERC mutations were diagnosed at an earlier age than those with PARN mutations (51±11 years versus 64±8 years; p=0.03) and had a higher incidence of haematological comorbidities. The mean rate of forced vital capacity decline was 300 mL·year−1 and the median time to death or transplant was 2.87 years. There was no significant difference in time to death or transplant for patients across gene mutation groups or for patients with a diagnosis of IPF versus a non-IPF diagnosis. Genetic mutations in telomere related genes lead to a variety of interstitial lung disease (ILD) diagnoses that are universally progressive. Mutations in four telomere-related genes lead to progressive pulmonary fibrosis, regardless of ILD diagnosis http://ow.ly/TH2B300Yjvt

Pulmonary fibrosis in the era of stratified medicine

Both common and rare variants contribute to the genetic architecture of pulmonary fibrosis. Genome-wide association studies have identified common variants, or those with a minor allele frequency of >5%, that are linked to pulmonary fibrosis. The most widely replicated variant (rs35705950) is located in the promoter region of the MUC5B gene and has been strongly associated with idiopathic pulmonary fibrosis (IPF) and familial interstitial pneumonia (FIP) across multiple different cohorts. However, many more common variants have been identified with disease risk and in aggregate account for approximately one-third of the risk of IPF. Moreover, several of these common variants appear to have prognostic potential. Next generation sequencing technologies have facilitated the identification of rare variants. Recent whole exome sequencing studies have linked pathogenic rare variants in multiple new genes to FIP. Compared with common variants, rare variants have lower population allele frequencies and higher effect sizes. Pulmonary fibrosis rare variants genes can be subdivided into two pathways: telomere maintenance and surfactant metabolism. Heterozygous rare variants in telomere-related genes co-segregate with adult-onset pulmonary fibrosis with incomplete penetrance, lead to reduced protein function, and are associated with short telomere lengths. Despite poor genotype-phenotype correlations, lung fibrosis associated with pathogenic rare variants in different telomere genes is progressive and displays similar survival characteristics. In contrast, many of the heterozygous rare variants in the surfactant genes predict a gain of toxic function from protein misfolding and increased endoplasmic reticulum (ER) stress. Evidence of both telomere shortening and increased ER stress have been found in sporadic IPF patients, suggesting that the mechanisms identified from rare variant genetic studies in unique individuals and families are applicable to a wider spectrum of patients. The ability to sequence large cohorts of individuals rapidly has the potential to further our understanding of the relative contributions of common and rare variants in the pathogenesis of pulmonary fibrosis. The UK 100,000 Genomes Project will provide opportunities to interrogate both common and rare variants and to investigate how these biological signals provide diagnostic and prognostic information in the era of stratified medicine.

Whole-Exome Sequencing in Adults With Chronic Kidney Disease: A Pilot Study

Chronic kidney disease (CKD) affects an estimated 14% of Americans (1, 2). These persons have 10- to 15-fold higher morbidity and mortality rates than the general population (1, 3). In most patients with CKD, the diagnosis is based on standard office work-up and sometimes kidney biopsy findings. However, early-stage CKD is often clinically silent, and subtypes can be difficult to distinguish on the basis of clinical data alone. Thus, in many persons, the precise cause of kidney failure remains unknown. Approximately 10% to 25% of patients with CKD note a family history of nephropathy (46), suggesting that in many cases the disease has a hereditary component. Recent advances in genomic technologies, such as chromosomal microarray and massively parallel (next-generation) sequencing, enable genome-wide analysis at a modest cost and precise definition of the molecular cause of many complex diseases (713). Application of these methods has suggested opportunities for individualized diagnosis and risk stratification, including targeted work-up and surveillance for associated disease complications (1113) and sometimes precision therapy (1215). However, studies to date have focused mainly on a limited range of disorders in pediatric cohorts or on cancer in adults (717); thus, the clinical utility of these approaches for a broader spectrum of diseases, particularly among adults, remains unclear. Applying chromosomal microarray analysis, we recently showed that 7.4% of 419 children with various forms of CKD had a major known pathogenic genomic imbalance that was not suspected after clinical assessment (18). These disorders were evenly distributed among patients clinically diagnosed with congenital and noncongenital forms of CKD, indicating that genetic analysis has utility across broad clinical categories. In most of these cases, the genetic findings either reclassified the disease or provided information that could guide subsequent clinical care, such as evaluation for metabolic or neuropsychiatric disease. Similarly, next-generation sequencing has been shown to have great utility for diagnosing genetic forms of nephrotic syndrome or congenital kidney defects in pediatric populations, albeit mainly in the context of targeted panels (1921). Whole-exome sequencing (WES) is a genome-wide testing approach that allows selective sequencing of the protein-coding regions of the genome, which are enriched for disease-associated variants (1215). Because of its genome-wide coverage, WES enables screening of most genes associated with kidney disease and can therefore be applied across diverse categories of renal disorders. Moreover, it can potentially identify novel etiologic genes for nephropathy or detect actionable incidental mutations unrelated to the primary indications for testing. For these reasons, WES is emerging as a preferred diagnostic tool for hereditary disorders (1215, 22, 23). In pediatric cohorts, WES recently identified diagnostic mutations in up to 11.5% of patients with congenital kidney anomalies and 26% of patients with steroid-resistant nephrotic syndrome, supporting its diagnostic utility for early-onset CKD (24, 25). However, the value of this sequencing method for the diagnosis and management of CKD in adults has not been adequately studied. We did a pilot study to test the utility of WES in adults referred for evaluation of CKD or hypertension. Methods Study Design The results of WES in a convenience sample of patients referred for evaluation of CKD were reviewed for their potential to inform clinical practice. To facilitate diagnostic interpretation of WES data, we compiled a list of genes encompassing most common Mendelian forms of kidney and hypertensive disorders. We next annotated the exomes for diagnostic variants in nephropathy genes and then analyzed other genes, including those recommended by the American College of Medical Genetics (ACMG), for return of medically actionable incidental findings (26). Patient Population and Setting The study sample was selected from a group of 344 patients seen at outpatient nephrology clinics between October 2013 and May 2014 at Columbia University Medical Center, a tertiary care medical center with a nephrology division offering highly specialized care for glomerular disorders. These 344 patients were referred for evaluation and management of kidney disease and consented to a general genetic research and biobanking protocol. Supplement Table 1 presents the characteristics of these 344 patients. From this group, we selected 81 adult patients (aged >18 years) (Supplement Table 2) for WES who fulfilled 1 of the following inclusion criteria: a family history of kidney disease (defined as any family member with urinary abnormalities or impaired kidney function, as reported by the patient), undiagnosed kidney disease, or clinical suspicion of a genetic kidney disease (for example, in a proband with young age of onset and no family history of nephropathy). The PKD1 gene is not well-captured by WES because of gene duplication (27), so patients fulfilling clinical diagnostic criteria for autosomal dominant polycystic kidney disease were not included in the WES study. Supplement. Supplementary Tables In addition to these 81 patients from Columbia University Medical Center, we also included 11 patients referred for suspected inherited kidney disease or hypertension from outside institutions. Three patients with familial tubulointerstitial nephropathy and 1 with early-onset hypertension were referred from 3 local practices in the United States (New York University and nephrology practices in suburban New York and Delaware). Four were referred for evaluation of Mendelian hypertension from the Polish Kidney Genetics Network (POLYGENES, www.polygenes.org), centered in the Department of Genetics at Pozna University of Medical Sciences and The Center of Medical Genetics GENESIS (Pozna, Poland). Three other patients were referred from Gaslini Institute (Genova, Italy) for evaluation of glomerulonephritis with nondiagnostic kidney biopsies. All participants gave informed consent, and the study was approved by the Columbia University Institutional Review Board and local ethics committees. WES and Sequence Interpretation Staff extracted DNA from whole blood. Telomere length was measured using genomic DNA from whole blood, as previously described (28, 29). For WES, fragment libraries using 200 ng of genomic DNA were constructed from each sample, following the Agilent standard library preparation protocol for TruSeq (Illumina). Exome capture was done with the SureSelectXT Human All Exon V4 (51 Mb) kit (Agilent), and sequencing was done using the HiSeq 2000 or 2500 (Illumina) at the Columbia Genome Center. On average, 92.83 million independent paired-end reads (18.56-Gb bases) were generated per sample to provide an average coverage of 110-fold, with 99.17% of target regions being covered at least 10-fold. The paired-end reads (read size, 101 bp) were mapped to the human reference genome National Center for Biotechnology Information build 37 using BurrowsWheeler Aligner, version 0.5.9. The Genome Analysis Toolkit, version 1.6-13, was used to call germline single nucleotide variants and insertions or deletions (indels). Variants were annotated for predicted effect on protein function (using ANNOVAR and SnpEff); allele frequency in public databases (ExAC, dbSNP, and the 1000 Genomes Project); and predicted pathogenicity with in silico algorithms, including PolyPhen and Combined Annotation Dependent Depletion scores (3036). Evidence for disease causality was assessed using ClinVar and the Human Genome Mutation Database (Qiagen), followed by manual review of the cited primary literature (33, 36). In addition, we developed a curated priority list of 287 Online Mendelian Inheritance in Man (OMIM; http://omim.org) genes implicated in Mendelian forms of kidney disorders and hypertension to facilitate clinical annotation (hereon, we refer to this gene list as nephropathy genes; see Supplement Table 3. A known limitation of exome sequencing is that some segments of the genome are not amenable to capture (23). Among the 287 nephropathy genes, 29 were identified with at least 1 exon that is not captured by the Agilent kit, representing potential blind spots in the analysis (Supplement Table 3). Variant interpretation was done by a panel of nephrologists or molecular geneticists with domain expertise in inherited kidney diseases (K.K., S.S.C., C.A., L.R., E.G., and A.G.G.), bioinformaticians (S.L. and D.A.F.), and a clinical molecular geneticist (V.J.), using the ACMG guidelines for clinical sequence interpretation (37). Detailed classification criteria for pathogenic and likely pathogenic variants are in Supplement Table 4. We also reviewed potentially pathogenic mutations in OMIM genes associated with other heritable disorders and in the ACMGs 59 actionable genes (26). All diagnostic variants were confirmed by Sanger sequencing. Finally, we verified the distribution of potentially functional variants in nephropathy genes in each exome. These potentially functional variants were defined as missense, nonsense, splice site, or indel variants with a minor allele frequency less than 1% in ExAC (a database of genetic variation in >60000 persons) and a Combined Annotation Dependent Depletion score greater than 10 (indicating a variant score in the top 10% of deleteriousness in a large reference data set of variants). We also verified allele frequencies using an anonymized in-house control data set derived from 9012 persons who had undergone WES for indications other than nephropathy; these control data included healthy parents of children with a developmental disorder and participants from genetic studies of amyotrophic lateral sclerosis or seizure disorders. Role of the Funding Source The study was funded by the New York State Empire Clinical Research Investigator Program, the Renal Research Institut

The MUC5B promoter polymorphism and telomere length in patients with chronic hypersensitivity pneumonitis: an observational cohort-control study

SUMMARY Background Patients with hypersensitivity pneumonitis (HP) may develop lung fibrosis, which is associated with reduced survival. Families with pulmonary fibrosis can present with members diagnosed with idiopathic pulmonary fibrosis (IPF) or chronic HP (cHP), suggesting that fibrotic HP may share risk factors with IPF. Methods In an observational study of two independent cohorts of patients with cHP (UCSF n=145, UTSW n=72), we measured two common single nucleotide polymorphisms associated with IPF (MUC5B rs35705950 & TOLLIP rs5743890) and peripheral blood leukocyte telomere length and evaluated their associations with cHP disease, survival, and clinical-radiograph-pathologic features. Findings The frequency of the MUC5B minor allele, but not the TOLLIP minor allele, was significantly increased in cHP patients in both cohorts (UCSF MAF 24.4% & UTSW MAF 32.3%) compared to healthy controls (MAF 10.7%; p-values for comparison = <0.0001 for both cohorts) and similar to IPF (UCSF MAF 33.3% & UTSW MAF 32.0%, p-values for comparison=0.10 & 0.95, respectively). The MUC5B minor allele (adjusted OR 1.91, p=0.045) and shorter telomere length (adjusted OR 0.23, p=0.002) were associated with extent of radiographic fibrosis and other measures of lung remodeling and fibrosis in the combined cHP cohorts. Shorter telomere length had a significant association (adjusted HR 0.18, p=0.001) with reduced survival in the combined cHP cohorts. Interpretation The MUC5B promoter polymorphism rs35705950 and shorter telomere length are associated with extent of fibrosis in cHP. Shorter telomere length is associated with histopathology findings typical of usual interstitial pneumonia and reduced survival in cHP. Funding NIH grants KL2TR001870, T32HL098040, UL1TR001105, R01HL093096, and the Nina Ireland Program for Lung Health.

Telomere length in patients with pulmonary fibrosis associated with chronic lung allograft dysfunction and post–lung transplantation survival

BACKGROUND Prior studies have shown that patients with pulmonary fibrosis with mutations in the telomerase genes have a high rate of certain complications after lung transplantation. However, few studies have investigated clinical outcomes based on leukocyte telomere length. METHODS We conducted an observational cohort study of all patients with pulmonary fibrosis who underwent lung transplantation at a single center between January 1, 2007, and December 31, 2014. Leukocyte telomere length was measured from a blood sample collected before lung transplantation, and subjects were stratified into 2 groups (telomere length <10th percentile vs ≥10th percentile). Primary outcome was post-lung transplant survival. Secondary outcomes included incidence of allograft dysfunction, non-pulmonary organ dysfunction, and infection. RESULTS Approximately 32% of subjects had a telomere length <10th percentile. Telomere length <10th percentile was independently associated with worse survival (hazard ratio 10.9, 95% confidence interval 2.7-44.8, p = 0.001). Telomere length <10th percentile was also independently associated with a shorter time to onset of chronic lung allograft dysfunction (hazard ratio 6.3, 95% confidence interval 2.0-20.0, p = 0.002). Grade 3 primary graft dysfunction occurred more frequently in the <10th percentile group compared with the ≥10th percentile group (28% vs 7%; p = 0.034). There was no difference between the 2 groups in incidence of acute cellular rejection, cytopenias, infection, or renal dysfunction. CONCLUSIONS Telomere length <10th percentile was associated with worse survival and shorter time to onset of chronic lung allograft dysfunction and thus represents a biomarker that may aid in risk stratification of patients with pulmonary fibrosis before lung transplantation.

Somatic mutations in telomerase promoter counterbalance germline loss-of-function mutations

Germline coding mutations in different telomere-related genes have been linked to autosomal-dominant familial pulmonary fibrosis. Individuals with these inherited mutations demonstrate incomplete penetrance of clinical phenotypes affecting the lung, blood, liver, skin, and other organs. Here, we describe the somatic acquisition of promoter mutations in telomerase reverse transcriptase (TERT) in blood leukocytes of approximately 5% of individuals with inherited loss-of-function coding mutations in TERT or poly(A)-specific ribonuclease (PARN), another gene linked to telomerase function. While these promoter mutations were initially identified as oncogenic drivers of cancer, individuals expressing the mutations have no history of cancer. Neither promoter mutation was found in population-based cohorts of similar or advanced age. The TERT promoter mutations were found more frequently in cis with the WT allele than the TERT coding sequence mutation. EBV-transformed lymphoblastoid B cell lines (LCLs) derived from subjects with TERT promoter mutations showed increased telomerase expression and activity compared with cell lines from family members with identical coding mutations. TERT promoter mutations resulted in an increased proliferation of LCLs and demonstrated positive selection over time. The persistence and recurrence of noncoding gain-of-function mutations in these cases suggests that telomerase activation is not only safely tolerated but also advantageous for clonal expansion.

Pleuroparenchymal fibroelastosis associated with telomerase reverse transcriptase mutations

We thank H. Nunes and colleagues for their interest in our study of patients with telomere-related gene mutations associated with pleuroparenchymal fibroelastosis (PPFE) [1]. Their cohort of five patients with PPFE and rare variants in telomerase reverse transcriptase (TERT) is similar to ours with regard to its female predominance. Here we provide additional details of our eight cases to point out additional similarities and differences between these two cohorts (table 1). A diagnosis of PPFE is linked to pathogenic variants in three different telomere-related genes http://ow.ly/eGOq30aPkgx

Utility of Bronchoalveolar Lavage and Transbronchial Biopsy in Patients with Hypersensitivity Pneumonitis

IntroductionMaking the diagnosis of HP is challenging due to a lack of consensus criteria and variability of both pathologic and radiographic findings. The purpose of this retrospective study was to determine the diagnostic utility of the combination of BAL lymphocyte count and TBBX in patients with HP.MethodsWe conducted a retrospective cohort study of all patients with a MDD diagnosis of HP at a single center.Results155 patients were included in the study. 49% of patients who underwent BAL had a lymphocyte count > 20, 42% had a lymphocyte count > 30, and 34% had lymphocyte count > 40%. The median BAL lymphocyte count was higher in inflammatory HP compared to fibrotic HP. The addition of TBBX to BAL significantly increased the diagnostic yield regardless of the BAL lymphocyte cutoff used. The yield of bronchoscopy with TBBX and BAL when a lymphocyte count > 40% was used as a cutoff was 52%.ConclusionsOur study suggests that the combination of TBBX with BAL significantly increases the likelihood that the procedure will provide adequate additional information to allow a confident MDD diagnosis of HP and may reduce the need for SLB in the diagnostic workup of HP.

Resident versus faculty member simulation debriefing

Near‐peer teaching is effective in graduate medical education, but it has not been compared with faculty member teaching in resident simulation. In this study, we sought to compare debriefing sessions of internal medicine (IM) intern simulation sessions led by academic faculty doctors with those led by senior IM residents in order to measure the effectiveness of near‐peer teaching in this setting.