Immune aging: biological mechanisms, clinical symptoms, and management in lung transplant recipients.

While chronologic age can be precisely defined, clinical manifestations of advanced age occur in different ways and at different rates across individuals. The observed phenotype of advanced age likely reflects a superposition of several biological aging mechanisms which have gained increasing attention as the world contends with an aging population. Even within the immune system, there are multiple age-associated biological mechanisms at play, including telomere dysfunction, epigenetic dysregulation, immune senescence programs, and mitochondrial dysfunction. These biological mechanisms have associated clinical syndromes, such as telomere dysfunction leading to short telomere syndrome (STS), and optimal patient management may require recognition of biologically based aging syndromes. Within the clinical context of lung transplantation, select immune aging mechanisms are particularly pronounced. Indeed, STS is increasingly recognized as an indication for lung transplantation. At the same time, common aging phenotypes may be evoked by the stress of transplantation because lung allografts face a potent immune response, necessitating higher levels of immune suppression and associated toxicities, relative to other solid organs. Age-associated conditions exacerbated by lung transplant include bone marrow suppression, herpes viral infections, liver cirrhosis, hypogammaglobulinemia, frailty, and cancer risk. This review aims to dissect the molecular mechanisms of immune aging and describe their clinical manifestations in the context of lung transplantation. While these mechanisms are more likely to manifest in the context of lung transplantation, this mechanism-based approach to clinical syndromes of immune aging has broad relevance to geriatric medicine.

Genetic Counseling and Family Screening Recommendations in Patients with Telomere Biology Disorders.

PURPOSE OF REVIEW: Telomere biology disorders (TBDs) encompass a spectrum of genetic diseases with a common pathogenesis of defects in telomerase function and telomere maintenance causing extremely short telomere lengths. Here, we review the current literature surrounding genetic testing strategies, cascade testing, reproductive implications, and the role of genetic counseling. RECENT FINDINGS: The understanding of the genetic causes and clinical symptoms of TBDs continues to expand while genetic testing and telomere length testing are nuanced tools utilized in the diagnosis of this condition. Access to genetic counseling is becoming more abundant and is valuable in supporting patients and their families in making informed decisions. Patient resources and support groups are valuable to this community. Defining which populations should be offered genetic counseling and testing is imperative to provide proper diagnoses and medical management for not only the primary patient, but also their biological relatives.

Genetics in Idiopathic Pulmonary Fibrosis: A Clinical Perspective.

BACKGROUND: Unraveling the genetic background in a significant proportion of patients with both sporadic and familial IPF provided new insights into the pathogenic pathways of pulmonary fibrosis. AIM: The aim of the present study is to overview the clinical significance of genetics in IPF. PERSPECTIVE: It is fascinating to realize the so-far underestimated but dynamically increasing impact that genetics has on aspects related to the pathophysiology, accurate and early diagnosis, and treatment and prevention of this devastating disease. Genetics in IPF have contributed as no other in unchaining the disease from the dogma of a "a sporadic entity of the elderly, limited to the lungs" and allowed all scientists, but mostly clinicians, all over the world to consider its many aspects and "faces" in all age groups, including its co-existence with several extra pulmonary conditions from cutaneous albinism to bone-marrow and liver failure. CONCLUSION: By providing additional evidence for unsuspected characteristics such as immunodeficiency, impaired mucus, and surfactant and telomere maintenance that very often co-exist through the interaction of common and rare genetic variants in the same patient, genetics have created a generous and pluralistic yet unifying platform that could lead to the understanding of the injurious and pro-fibrotic effects of many seemingly unrelated extrinsic and intrinsic offending factors. The same platform constantly instructs us about our limitations as well as about the heritability, the knowledge and the wisdom that is still missing.

Pulmonary fibrosis in non-mutation carriers of families with short telomere syndrome gene mutations.

BACKGROUND AND OBJECTIVE: Diagnostic and predictive genetic testing for disease cause and risk estimation is common in many countries. For genetic diseases, predictive test results are commonly straightforward: presence of the mutation involves increased risk for disease and absence of the mutation involves no inherit risk for disease. Germline mutations in telomere-related genes (TRGs) can lead to telomere shortening and are associated with short telomere syndrome (STS). Telomere length is heritable, and in families with STS due to a TRG mutation, progeny with and without the TRG mutation is known to have shorter than average telomeres. We hypothesize that progeny of TRG mutation carriers who did not inherit the TRG mutation may still develop pulmonary fibrosis. METHODS: A genetic screen of 99 unrelated families with familial pulmonary fibrosis revealed five patients with features of pulmonary fibrosis but without carrying the familial disease-causing TRG mutation. RESULTS: Features of STS were present in each family, including short telomeres in blood and tissue of the non-mutation carrying patients. Additional genetic, clinical or environmental risk factors for pulmonary fibrosis were present in each non-mutation carrying patient. CONCLUSION: Our study shows that non-mutation carrying first-degree relatives in families with STS are at increased risk for pulmonary fibrosis. Disease development may be triggered by inherited short telomeres and additional risk factors for disease. This observation has profound consequences for genetic counselling. Unlike any other genetic syndrome, absence of the mutation does not imply absence of disease risk. Therefore, clinical follow-up is still urged for non-mutation carrying first-degree family members.

Liver transplant recipient with respiratory failure due to pulmonary fibrosis related to telomere disease requiring lung transplantation.

Short telomere syndrome (STS) is characterized as multiorgan dysfunction presenting with unexplained cytopenias, cryptogenic cirrhosis and pulmonary fibrosis. We present a liver transplant recipient that gradually developed hypoxic respiratory failure attributed to idiopathic pulmonary fibrosis associated telomere disease that culminated in a successful single lung transplantation.

Pulmonary Fibrosis and a TERT Founder Mutation With a Latency Period of 300 Years.

BACKGROUND: Germline mutations in the gene encoding TERT cause haploinsufficiency with subsequent telomere shortening. TERT mutations are associated with short telomere syndromes, such as pulmonary fibrosis (PF), which is often the first manifestation of a short telomere syndrome. Telomere length is heritable, and progeny of telomerase mutation carriers are known to have shorter telomeres. In families with TERT mutations, genetic anticipation, the earlier onset of symptoms with successive generation, is described. Little is known on the number of generations that may pass before disease occurs in families with a TERT mutation. RESEARCH QUESTION: The objective of this study was to determine classification and origin of the new TERT c.2005T mutation from population genetics and genealogic data and disease history of affected families. STUDY DESIGN AND METHODS: The TERT gene of 240 patients with familial PF was screened for mutations. Additionally, 1,015 patients with PF, 1,237 patients with an interstitial lung disease (ILD) without PF, and 529 healthy control subjects were genotyped for the TERT c.2005C>T mutation. Genealogic research was performed on all patients who carried the TERT c.2005T mutation. RESULTS: We detected the TERT c.2005T (p.Arg669Trp) mutation in 13 out of 1,255 patients with PF vs none of the patients with ILD without PF and the healthy control subjects. Genealogic research connected four of the TERT c.2005T mutation carriers to a common ancestor who lived seven generations back, spanning a period of 300 years. INTERPRETATION: The TERT c.2005T mutation is a pathogenic mutation and associates with PF. This study learns that a latency period of > 300 years may pass before the cumulative effect of telomere shortening eventually leads to PF. This finding underlines the complexity of the clinical interpretation of TERT mutations because, not the presence of the mutation, but the result of genetic anticipation, is associated with disease. Therefore, multidisciplinary discussion between pulmonary physicians, clinical geneticists, and genetic laboratory experts is recommended.