Alveolar epithelial progenitor cells require Nkx2-1 to maintain progenitor-specific epigenomic state during lung homeostasis and regeneration.

Lung epithelial regeneration after acute injury requires coordination cellular coordination to pattern the morphologically complex alveolar gas exchange surface. During adult lung regeneration, Wnt-responsive alveolar epithelial progenitor (AEP) cells, a subset of alveolar type 2 (AT2) cells, proliferate and transition to alveolar type 1 (AT1) cells. Here, we report a refined primary murine alveolar organoid, which recapitulates critical aspects of in vivo regeneration. Paired scRNAseq and scATACseq followed by transcriptional regulatory network (TRN) analysis identified two AT1 transition states driven by distinct regulatory networks controlled in part by differential activity of Nkx2-1. Genetic ablation of Nkx2-1 in AEP-derived organoids was sufficient to cause transition to a proliferative stressed Krt8+ state, and AEP-specific deletion of Nkx2-1 in adult mice led to rapid loss of progenitor state and uncontrolled growth of Krt8+ cells. Together, these data implicate dynamic epigenetic maintenance via Nkx2-1 as central to the control of facultative progenitor activity in AEPs.

Twin-twin transfusion syndrome recipient with arterial calcification and heterozygous variant in ABCC6: Evidence of a gene-environment interaction?

We report a case of a twin-twin transfusion syndrome (TTTS) recipient who, after successful fetoscopic surgery, developed a large pericardial effusion and calcifications of the aorta and main pulmonary artery. The donor fetus never had cardiac strain and never developed cardiac calcifications. A heterozygous likely pathogenic variant in ABCC6 (c.2018T > C, p.Leu673Pro) was identified in the recipient twin. While TTTS recipient twins are at risk of arterial calcifications and right heart failure secondary to the disease, calcifications of the great vessels are also observed in generalized arterial calcification of infancy, a Mendelian genetic disorder with associated biallelic pathogenic variations in ABCC6 or ENPP1, which can result in significant pediatric morbidity or mortality. The recipient twin in this case had some degree of cardiac strain prior to TTTS surgery; however, the progressive calcification of the aorta and pulmonary trunk occurred weeks after TTTS resolution. This case raises the possibility of a gene-environment interaction and emphasizes the need for genetic evaluation in the setting of TTTS and calcifications.

Sleep Apnea in Children With Down Syndrome.

OBJECTIVE: The authors of this study aimed to evaluate the use of polysomnography (PSG) in children with Down syndrome (DS) between ages 0 and 7 years, to assess the prevalence and severity of obstructive sleep apnea (OSA) and associated comorbidities, and to describe interventions used for OSA. METHODS: A retrospective cohort study was performed at Cincinnati Children's Hospital Medical Center for children with DS born between 2013 and 2019. Data were extracted from the electronic medical record, including demographics, age at PSG, PSG results, and interventions after an abnormal PSG. Statistical analysis included unadjusted bivariate association testing and multivariable logistic regression modeling to investigate associations with OSA severity. RESULTS: Among 397 patients in the cohort, 59% (n = 235) had a documented PSG and 94% (n = 221) had an abnormal study with 60% (n = 141) demonstrating moderate or severe OSA. There was an inverse relationship between age and OSA severity (P < .001). In a multiple regression model, OSA severity was associated with increased rates of failure to thrive (P < .01), aspiration (P = .02), and laryngomalacia (P < .01). After medical or surgical intervention, 73% of patients experienced the resolution of OSA or an improvement in OSA severity. CONCLUSION: In this study of pediatric patients with DS, OSA was identified most frequently in the first year of life. In addition, to prompt evaluation of symptomatic infants, our data support earlier PSG screening for patients requiring neonatal ICU care and those with feeding difficulties, airway abnormalities, and/or pulmonary hypertension given their increased risk for severe OSA.

PRDM3/16 Regulate Chromatin Accessibility Required for NKX2-1 Mediated Alveolar Epithelial Differentiation and Function.

Differential chromatin accessibility accompanies and mediates transcriptional control of diverse cell fates and their differentiation during embryogenesis. While the critical role of NKX2-1 and its transcriptional targets in lung morphogenesis and pulmonary epithelial cell differentiation is increasingly known, mechanisms by which chromatin accessibility alters the epigenetic landscape and how NKX2-1 interacts with other co-activators required for alveolar epithelial cell differentiation and function are not well understood. Here, we demonstrate that the paired domain zinc finger transcriptional regulators PRDM3 and PRDM16 regulate chromatin accessibility to mediate cell differentiation decisions during lung morphogenesis. Combined deletion of Prdm3 and Prdm16 in early lung endoderm caused perinatal lethality due to respiratory failure from loss of AT2 cell function. Prdm3/16 deletion led to the accumulation of partially differentiated AT1 cells and loss of AT2 cells. Combination of single cell RNA-seq, bulk ATAC-seq, and CUT&RUN demonstrated that PRDM3 and PRDM16 enhanced chromatin accessibility at NKX2-1 transcriptional targets in peripheral epithelial cells, all three factors binding together at a multitude of cell-type specific cis-active DNA elements. Network analysis demonstrated that PRDM3/16 regulated genes critical for perinatal AT2 cell differentiation, surfactant homeostasis, and innate host defense. Lineage specific deletion of PRDM3/16 in AT2 cells led to lineage infidelity, with PRDM3/16 null cells acquiring partial AT1 fate. Together, these data demonstrate that NKX2-1-dependent regulation of alveolar epithelial cell differentiation is mediated by epigenomic modulation via PRDM3/16.

PI3K signaling specifies proximal-distal fate by driving a developmental gene regulatory network in SOX9+ mouse lung progenitors.

The tips of the developing respiratory buds are home to important progenitor cells marked by the expression of SOX9 and ID2. Early in embryonic development (prior to E13.5), SOX9+progenitors are multipotent, generating both airway and alveolar epithelium, but are selective progenitors of alveolar epithelial cells later in development. Transcription factors, including Sox9, Etv5, Irx, Mycn, and Foxp1/2 interact in complex gene regulatory networks to control proliferation and differentiation of SOX9+progenitors. Molecular mechanisms by which these transcription factors and other signaling pathways control chromatin state to establish and maintain cell-type identity are not well-defined. Herein, we analyze paired gene expression (RNA-Seq) and chromatin accessibility (ATAC-Seq) data from SOX9+ epithelial progenitor cells (EPCs) during embryonic development in Mus musculus. Widespread changes in chromatin accessibility were observed between E11.5 and E16.5, particularly at distal cis-regulatory elements (e.g. enhancers). Gene regulatory network (GRN) inference identified a common SOX9+ progenitor GRN, implicating phosphoinositide 3-kinase (PI3K) signaling in the developmental regulation of SOX9+ progenitor cells. Consistent with this model, conditional ablation of PI3K signaling in the developing lung epithelium in mouse resulted in an expansion of the SOX9+ EPC population and impaired airway epithelial cell differentiation. These data demonstrate that PI3K signaling is required for epithelial patterning during lung organogenesis, and emphasize the combinatorial power of paired RNA and ATAC seq in defining regulatory networks in development.

Studying how lungs develop has helped us understand and treat often-devastating lung diseases. This includes diseases like cystic fibrosis which result from spelling mistakes known as mutations in a person's genetic code. However, not all lung diseases involve mutations. Many other diseases, in both adults and children, are caused by genes failing to switch on or off at some point during lung development. DNA is surrounded by various proteins which package it into a compressed structure known as chromatin. Cells can control which genes are turned on or off by modifying how tightly packed parts of the genetic code are within chromatin. Changes in chromatin accessibility, also known as 'epigenetic' changes, are a normal part of development, and guide cells towards specific jobs or identities as an organ matures. However, how this happens in the developing lung is poorly understood. Here, Khattar, Fernandes et al. set out to determine how chromatin accessibility shapes development of the tissue lining the lungs, focusing on a group of progenitor cells which produce the protein SOX9. These cells are initially found at the tips of the early lung, where they go on to develop into the cells that line the whole of the mature organ. Initial experiments used large-scale genetic techniques to measure gene activity and chromatin accessibility simultaneously in progenitor cells extracted from the lungs of mice. Khattar, Fernandes et al. were then able to predict the signaling pathways that shape the lung lining based on which genes were surrounded by unpacked chromatin, and determine the proteins responsible for these epigenetic changes. This included the signaling pathway Phosphatidylinositol 3 kinase (PI3K) which is involved in a number of cellular processes. Additional experiments in mice confirmed that the PI3K pathway became active very early in lung development and remained so until adulthood. In contrast, mice lacking a gene that codes for a key part of the PI3K pathway had defective lungs which failed to develop a proper lining. The data generated in this study will provide an important resource for future studies investigating how epigenetic changes drive normal lung development. Khattar, Fernandes et al. hope that this knowledge will help researchers to better understand the cause of human lung diseases, and identify already available 'epigenetic drugs' which could be repurposed to treat them.

Fetal maturation revealed by amniotic fluid cell-free transcriptome in rhesus macaques.

Accurate estimate of fetal maturity could provide individualized guidance for delivery of complicated pregnancies. However, current methods are invasive, have low accuracy, and are limited to fetal lung maturation. To identify diagnostic gestational biomarkers, we performed transcriptomic profiling of lung and brain, as well as cell-free RNA from amniotic fluid of preterm and term rhesus macaque fetuses. These data identify potentially new and prior-associated gestational age differences in distinct lung and neuronal cell populations when compared with existing single-cell and bulk RNA-Seq data. Comparative analyses found hundreds of genes coincidently induced in lung and amniotic fluid, along with dozens in brain and amniotic fluid. These data enable creation of computational models that accurately predict lung compliance from amniotic fluid and lung transcriptome of preterm fetuses treated with antenatal corticosteroids. Importantly, antenatal steroids induced off-target gene expression changes in the brain, impinging upon synaptic transmission and neuronal and glial maturation, as this could have long-term consequences on brain development. Cell-free RNA in amniotic fluid may provide a substrate of global fetal maturation markers for personalized management of at-risk pregnancies.

Perinatal Outcomes of Fetuses and Infants Diagnosed with Trisomy 13 or Trisomy 18.

OBJECTIVES: To identify factors associated with prenatal, perinatal, and postnatal outcomes, and determine medical care use for fetuses and infants with trisomy 13 (T13) and trisomy 18 (T18). STUDY DESIGN: This population-based retrospective cohort study included all prenatal and postnatal diagnoses of T13 or T18 in the greater Cincinnati area from January 1, 2012, to December 31, 2018. Overall survival, survival to hospital discharge, medical management, and maternal, fetal, and neonatal characteristics are analyzed. RESULTS: There were 124 pregnancies (125 fetuses) that were identified, which resulted in 72 liveborn infants. Male fetal sex and hydrops were associated with a higher rate of spontaneous loss. The median length of survival was 7 and 29 days, for infants with T13 and T18, respectively. Of the 27 infants alive at 1 month of age, 13 (48%) were alive at 1 year of age. Only trisomy type (T13), goals of care (comfort care), and extremely low birthweight were associated with a shorter length of survival. A high degree of variability existed in the use of medical services, with 28% of infants undergoing at least 1 surgical procedure and some children requiring repeated (≤29) or prolonged (>1 year) hospitalizations. CONCLUSIONS: Although many infants with T13 or T18 did not survive past the first week of life, nearly 20% lived for more than 1 year with varying degrees of medical support. The length of survival for an infant cannot be easily predicted, and surviving infants have high health care use throughout their lifespans.

Inflammatory blockade prevents injury to the developing pulmonary gas exchange surface in preterm primates.

Perinatal inflammatory stress is associated with early life morbidity and lifelong consequences for pulmonary health. Chorioamnionitis, an inflammatory condition affecting the placenta and fluid surrounding the developing fetus, affects 25 to 40% of preterm births. Severe chorioamnionitis with preterm birth is associated with significantly increased risk of pulmonary disease and secondary infections in childhood, suggesting that fetal inflammation may markedly alter the development of the lung. Here, we used intra-amniotic lipopolysaccharide (LPS) challenge to induce experimental chorioamnionitis in a prenatal rhesus macaque (Macaca mulatta) model that mirrors structural and temporal aspects of human lung development. Inflammatory injury directly disrupted the developing gas exchange surface of the primate lung, with extensive damage to alveolar structure, particularly the close association and coordinated differentiation of alveolar type 1 pneumocytes and specialized alveolar capillary endothelium. Single-cell RNA sequencing analysis defined a multicellular alveolar signaling niche driving alveologenesis that was extensively disrupted by perinatal inflammation, leading to a loss of gas exchange surface and alveolar simplification, with notable resemblance to chronic lung disease in newborns. Blockade of the inflammatory cytokines interleukin-1ß and tumor necrosis factor-α ameliorated LPS-induced inflammatory lung injury by blunting stromal responses to inflammation and modulating innate immune activation in myeloid cells, restoring structural integrity and key signaling networks in the developing alveolus. These data provide new insight into the pathophysiology of developmental lung injury and suggest that modulating inflammation is a promising therapeutic approach to prevent fetal consequences of chorioamnionitis.

Detection and impact of genetic disease in a level IV neonatal intensive care unit.

OBJECTIVE: To determine detection rates of genetic disease in a level IV neonatal intensive care unit (NICU) and cost of care. STUDY DESIGN: We divided 2703 neonates, admitted between 2013 and 2016 to a level IV NICU, into two epochs and determined how genetic testing utilization, genetic diagnoses identified, and cost of NICU care changed over time. RESULT: The increasing use of multi-gene panels 104 vs 184 (P = 0.02) and whole exome sequencing (WES) 9 vs 28 (P = 0.03) improved detection of genetic disease, 9% vs 12% (P < 0.01). Individuals with genetic diagnoses had higher mean NICU charges, $723,422 vs $417,013 (P < 0.01) secondary to longer lengths of stay, not genetic services. CONCLUSION: The increased utilization of broad genetic testing improved the detection of genetic disease but contributed minimally to the cost of care while bolstering understanding of the patient's condition and prognosis.

Beyond diagnostic yield: prenatal exome sequencing results in maternal, neonatal, and familial clinical management changes.

PURPOSE: Previous studies have reported that prenatal exome sequencing (pES) can detect monogenic diseases in fetuses with congenital anomalies with diagnostic yields ranging from 6% to 81%, but there are few reports of its clinical utility. METHODS: We conducted a retrospective chart review of patients who had pES to determine whether results led to clinical management changes. RESULTS: Of 20 patients, 8 (40%) received a definitive diagnosis. Seven patients (35%) had medical management changes based on the pES results, including alterations to their delivery plan and neonatal management (such as use of targeted medications, subspecialty referrals, additional imaging and/or procedures). All patients who received a definitive diagnosis and one who received a likely pathogenic variant (n = 9; 45%) received specific counseling about recurrence risk and the medical/developmental prognosis for the baby. In five (25%) cases, the result facilitated a diagnosis in parents and/or siblings. CONCLUSION: pES results can have significant impacts on clinical management, some of which would not be possible if testing is deferred until after birth. To maximize the clinical utility, pES should be prioritized in cases where multiple care options are available and the imaging findings alone are not sufficient to guide parental decision-making, or where postnatal testing will not be feasible.

Preterm infant with diprosopus and holoprosencephaly.

Diprosopus is an extremely rare congenital anomaly involving craniofacial duplication. The etiology and pathophysiology remain unknown, and no genetic mutations have been definitively associated with the condition. This case describes an infant born at 27-weeks completed gestation with multiple congenital anomalies including diprosopus and discusses the implications of prenatal diagnosis.

Making a Genetic Diagnosis in a Level IV Neonatal Intensive Care Unit Population: Who, When, How, and at What Cost?

OBJECTIVE: To investigate the prevalence of genetic disease and its economic impact in a level IV neonatal intensive care unit (NICU) by identifying and describing diseases diagnosed, genetic testing methodologies used, timing of diagnosis, length of NICU stay, and charges for NICU care. STUDY DESIGN: A retrospective chart review of patients admitted to a level IV NICU from 2013 to 2014 (n = 1327) was undertaken and data collected up to 2 years of age from the electronic medical record. RESULTS: In total, 117 patients (9%) received 120 genetic diagnoses using a variety of methodologies. A significant minority of diagnoses, 36%, were made after NICU discharge and 41% were made after 28 days of age. Patients receiving a genetic diagnosis had significantly longer mean lengths of stay (46 days vs 29.1 days; P < .01) and costlier mean charges ($598 712 vs $352 102; P < .01) for their NICU care. The NICU stay charge difference to care for a newborn with a genetic condition was on average $246 610 in excess of that for a patient without a genetic diagnosis, resulting in more than $28 000 000 in excess charges to care for all patients with genetic conditions in a single NICU over a 2-year period. CONCLUSIONS: Given the high prevalence of genetic disease in this population and the documented higher cost of care, shortening the time to diagnosis and targeting therapeutic interventions for this population could make a significant impact on neonatal care in level IV NICUs.

The long noncoding RNA Falcor regulates Foxa2 expression to maintain lung epithelial homeostasis and promote regeneration.

Transcription factors (TFs) are dosage-sensitive master regulators of gene expression, with haploinsufficiency frequently leading to life-threatening disease. Numerous mechanisms have evolved to tightly regulate the expression and activity of TFs at the transcriptional, translational, and posttranslational levels. A subset of long noncoding RNAs (lncRNAs) is spatially correlated with transcription factors in the genome, but the regulatory relationship between these lncRNAs and their neighboring TFs is unclear. We identified a regulatory feedback loop between the TF Foxa2 and a downstream lncRNA, Falcor (Foxa2-adjacent long noncoding RNA). Foxa2 directly represses Falcor expression by binding to its promoter, while Falcor functions in cis to positively regulate the expression of Foxa2. In the lung, loss of Falcor is sufficient to lead to chronic inflammatory changes and defective repair after airway epithelial injury. Moreover, disruption of the Falcor-Foxa2 regulatory feedback loop leads to altered cell adhesion and migration, in turn resulting in chronic peribronchial airway inflammation and goblet cell metaplasia. These data reveal that the lncRNA Falcor functions within a regulatory feedback loop to fine-tune the expression of Foxa2, maintain airway epithelial homeostasis, and promote regeneration.

Congenital Cystic Lung Lesions: Redefining the Natural Distribution of Subtypes and Assessing the Risk of Malignancy.

Asymptomatic cystic lung lesions-congenital pulmonary airway malformations (CPAMs), sequestrations, and bronchogenic cysts-are commonly diagnosed prenatally. Indications to resect are to eliminate risk of malignancy or infection. CPAMs consist of a spectrum of malformations, with type 1 historically considered the most common. Mucinous cell clusters, seen almost exclusively in type 1, are premalignant lesions at risk for progression to mucinous adenocarcinoma. We reviewed and classified 2.5 years of consecutive, prenatally diagnosed lesions as extralobar sequestration, intralobar sequestration, type 1 CPAM, type 2 CPAM/bronchial atresia, or "other" to determine the distribution of lesion types and risk of malignancy. One hundred eighty-four lesions in 174 patients showed type 1 CPAM to be least common subtype. Type 1 CPAMs had more severe presentation, infrequently had features of obstruction, and usually had cysts ≥2 cm. Fifteen of eighteen type 1 CPAMs had mucinous cell clusters (total risk, 8%), with mucous cells outside main cyst in 12/15. No pleuropulmonary blastomas were identified. Additional historic cases were reviewed to further evaluate risk of malignancy. Over 14 years, 28 infants with fetal/type 1 lesions were identified, with clusters of mucinous cells in 75% of cases. A total of 9 pleuropulmonary blastomas were diagnosed in 6 patients over 16 years. Contrary to historical studies, type 1 CPAMs are much less common than type 2, likely related to detection of asymptomatic lesions prenatally. A majority of type 1 CPAMs contain mucinous cell clusters. This data is useful in management of patients in centers that do not resect asymptomatic lesions.

Novel Molecular and Phenotypic Insights into Congenital Lung Malformations.

RATIONALE: Disruption of normal pulmonary development is a leading cause of morbidity and mortality in infants. Congenital lung malformations are a unique model to study the molecular pathogenesis of isolated structural birth defects, as they are often surgically resected. OBJECTIVES: To provide insight into the molecular pathogenesis of congenital lung malformations through analysis of cell-type and gene expression changes in these lesions. METHODS: Clinical data, and lung tissue for DNA, RNA, and histology, were obtained from 58 infants undergoing surgical resection of a congenital lung lesion. Transcriptome-wide gene expression analysis was performed on paired affected and unaffected samples from a subset of infants (n = 14). A three-dimensional organoid culture model was used to assess isolated congenital lung malformation epithelium (n = 3). MEASUREMENTS AND MAIN RESULTS: Congenital lung lesions express higher levels of airway epithelial related genes, and dysregulated expression of genes related to the Ras and PI3K-AKT-mTOR (phosphatidylinositol 3-kinase-AKT-mammalian target of rapamycin) signaling pathways. Immunofluorescence confirmed differentiated airway epithelial cell types throughout all major subtypes of congenital lung lesions, and three-dimensional cell culture demonstrated a cell-autonomous defect in the epithelium of these lesions. CONCLUSIONS: This study provides the first comprehensive analysis of the congenital lung malformation transcriptome and suggests that disruptions in Ras or PI3K-AKT-mTOR signaling may contribute to the pathology through an epithelial cell-autonomous defect.

Systematic Review and Meta-analysis: Gene Association Studies in Neonatal Sepsis.

Background Association studies of various gene variants in neonatal sepsis show conflicting results. Objective We performed a systematic review of candidate gene association studies in neonatal sepsis to provide pooled estimates of risk for selected gene variants. Methods We performed a search using MeSH terms "infection," "sepsis," "infant," "genetic variation," "polymorphism," and "genetic association studies." We included studies evaluating associations between neonatal sepsis and genetic variants (2000-2015). We excluded case reports/series, commentaries, narrative reviews, and nonhuman research. We assessed quality of studies using STREGA guidelines. Following estimation of odds ratios (ORs), data were pooled using random effects models. Results Twenty eight of 1,404 identified studies were included. Meta-analyses were performed for interleukin (IL)-6, tumor necrosis factor-α (TNF-α), and IL-10 as these gene variants were tested in multiple studies. TNF-α 308GG genotype demonstrated trends toward increased sepsis risk in the primary analysis of culture-proven sepsis (OR 1.18, 95% confidence interval [CI] 0.97-1.44). IL-10 1082GG genotype was associated with lower sepsis odds in very low-birth-weight (VLBW) infants (OR 0.51, 95% CI 0.29-0.91). Conclusion We uncovered an association between IL-10 1082 gene variation and sepsis in VLBW infants but did not identify associations between neonatal sepsis and TNF-α 308 or IL-6 gene variation. Larger cohort replication studies are required to validate these findings.

Accelerating Scientific Advancement for Pediatric Rare Lung Disease Research. Report from a National Institutes of Health-NHLBI Workshop, September 3 and 4, 2015.

Pediatric rare lung disease (PRLD) is a term that refers to a heterogeneous group of rare disorders in children. In recent years, this field has experienced significant progress marked by scientific discoveries, multicenter and interdisciplinary collaborations, and efforts of patient advocates. Although genetic mechanisms underlie many PRLDs, pathogenesis remains uncertain for many of these disorders. Furthermore, epidemiology and natural history are insufficiently defined, and therapies are limited. To develop strategies to accelerate scientific advancement for PRLD research, the NHLBI of the National Institutes of Health convened a strategic planning workshop on September 3 and 4, 2015. The workshop brought together a group of scientific experts, intramural and extramural investigators, and advocacy groups with the following objectives: (1) to discuss the current state of PRLD research; (2) to identify scientific gaps and barriers to increasing research and improving outcomes for PRLDs; (3) to identify technologies, tools, and reagents that could be leveraged to accelerate advancement of research in this field; and (4) to develop priorities for research aimed at improving patient outcomes and quality of life. This report summarizes the workshop discussion and provides specific recommendations to guide future research in PRLD.

Lung endoderm morphogenesis: gasping for form and function.

The respiratory endoderm develops from a small cluster of cells located on the ventral anterior foregut. This population of progenitors generates the myriad epithelial lineages required for proper lung function in adults through a complex and delicately balanced series of developmental events controlled by many critical signaling and transcription factor pathways. In the past decade, understanding of this process has grown enormously, helped in part by cell lineage fate analysis and deep sequencing of the transcriptomes of various progenitors and differentiated cell types. This review explores how these new techniques, coupled with more traditional approaches, have provided a detailed picture of development of the epithelial lineages in the lung and insight into how aberrant development can lead to lung disease.

Detection of mutually exclusive mosaicism in a girl with genotype-phenotype discrepancies.

Discordance between clinical phenotype and genotype has multiple causes, including mosaicism. Phenotypes can be modified due to tissue distribution, or the presence of multiple abnormal cell lines with different genomic contributions. We have studied a 20-month-old female whose main phenotypes were failure to thrive, developmental delay, and patchy skin pigmentation. Initial chromosome and SNP microarray analysis of her blood revealed a non-mosaic ∼24 Mb duplication of 15q25.1q26.3 resulting from the unbalanced translocation of terminal 15q to the short arm of chromosome 15. The most common feature associated with distal trisomy 15q is prenatal and postnatal overgrowth, which was not consistent with this patient's phenotype. The phenotypic discordance, in combination with the patchy skin pigmentation, suggested the presence of mosaicism. Further analysis of skin biopsies from both hyper- and hypopigmented regions confirmed the presence of an additional cell line with the short arm of chromosome X deleted and replaced by the entire long arm of chromosome 15. The Xp deletion, consistent with a variant Turner Syndrome diagnosis, better explained the patient's phenotype. Parental studies revealed that the alterations in both cell lines were de novo and the duplicated distal 15q and the deleted Xp were from different parental origins, suggesting a mitotic event. The possible mechanism for the occurrence of two mutually exclusive structural rearrangements with both involving the long arm of chromosome 15 is discussed.