Cystic Fibrosis Genetics: From Molecular Understanding to Clinical Application (2015) PDF

Summary

This 2015 review discusses cystic fibrosis genetics, from molecular understanding to clinical application. It highlights recent advancements in elucidating disease mechanisms and developing treatments, emphasizing the ongoing role of genetics in cystic fibrosis research. 25 years after the discovery of the disease-causing gene, the review details how molecular insights inform clinical care.

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Nat Rev Genet. Author manuscript; available in PMC 2015 March 18.
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Published in final edited form as:
Nat Rev Genet. 2015 January ; 16(1): 45–56. doi:10.1038/nrg3849.

Cystic fibrosis genetics: from molecular understanding to
clinical application
Garry R. Cutting
McKusick-Nathans Institute of Genetic Medicine, Johns Hopkins University School of Medicine,
733 North Broadway, MRB 559, Baltimore, Maryland 21205, USA
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Abstract
The availability of the human genome sequence and tools for interrogating individual genomes
provide an unprecedented opportunity to apply genetics to medicine. Mendelian conditions, which
are caused by dysfunction of a single gene, offer powerful examples that illustrate how genetics
can provide insights into disease. Cystic fibrosis, one of the more common lethalautosomal
recessive Mendelian disorders, is presented here as an example. Recent progress in elucidating
disease mechanism and causes of phenotypic variation, as well as in the development of
treatments, demonstrates that genetics continues to play an important part in cystic fibrosis
research 25 years after the d iscove1y of the disease-causing gene.

Cystic fibrosis (OMIM 219700) is a life-limiting autosomal recessive disorder that affects
70,000 individuals worldwide. The condition affects primarily those of European descent,
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although cystic fibrosis has been reported in all races and ethnicities. Abnormally viscous
secretions in the airways of the lungs and in the ducts of the pancreas in individuals with
cystic fibrosis cause obstructions that lead to inflammation, tissue damage and destruction of
both organ systems (FIG 1). Other organ systems containing epithelia -such as the sweat
gland, biliary duct of the liver, the male reproductive tract and the intestine -are also
affected. Loss of pancreatic exocrine function results in malnutrition and poor growth,
which leads to death in the first decade of life for most untreated individuals. Replacement
of pancreatic enzymes and intensive therapy guided by multidisciplinary teams have
revolutionized the treatment of cystic fibrosis, resulting in progressive improvements in
survival to a median predicted age of 37years for children born with cystic fibrosis today1.
Obstructive lung disease is currently the primary cause of morbidity and is responsible for
80% of mortality2.
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Twenty-five years ago, a variant (p.Phe508del; also known as F508del in legacy
nomenclature) in the cystic fibrosis transmembrane conductance regulator (CFTR) gene was
found to be the most common cause of cystic fibrosis3-5. Demonstration that CFTR
functions as a chloride channel regulated by cyclic AMP (cAMP)-dependent
phosphorylation 6 was consistent with the ion transport disturbances documented in cystic
fibrosis tissuesM Key insights into cystic fibrosis pathophysiology were derived from the

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study of CFTR mutants9, correlation ofCFTR dysfunction with the cellular manifestations of
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cystic fibrosis10 and elucidation of protein partners involved in biogenesis and membrane
functionu Identification of disease-causing variants in CFTR contributed a tool for both the
diagnosis of cystic fibrosis and the identification of cystic fibrosis carriers12, demonstrated
the degree to which CFTR dysfunction correlates with clinical features1 and revealed that
CFTR dysfunction can create phenotypes other than cystic fibrosis14 Over the past 5 years,
there has been remarkable progress in the development of small-molecule therapy targeting
CFTR bearing select disease-causing variants15,16

The purpose of this Review is to highlight advances over the past decade in our
understanding and treatment of cystic fibrosis that were informed by genetics. Given the
breadth of the cystic fibrosis field, not all of the important contributions and publications
relevant to the topic can be included. Examples have been chosen to illustrate that genetics
continues to have a role in the research of Mendelian disorders long after the causative
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variants and the responsible gene have been discovered. This Review covers new insights
into the processing defect caused by the F508del variant, advances in stem cell technology
that can enable testing of therapeutics for a wide range of CFTR genotypes and the
development of new animal models that are informing our understanding of organ pathology
in cystic fibrosis. I also summarize progress in parsing genetic and nongenetic contributions
to variability in cystic fibrosis and in the identification of modifier loci. The final section
describes efforts to determine the molecular and phenotypic consequences of the majority of
cystic fibrosiscausing variants and to develop molecular treatments for every defect in
CFTR.

Insights into disease mechanism
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Molecular basis of CFI'R dysfunction. Almost 2,000 variants have been reported to the
Cystic Fibrosis Mutation Database, one of the first and most successful locus-specific
databases. Among these variants, 40% are predicted to cause substitution of a single amino
acid, 36% are expected to alter RNA processing (including nonsense, frameshift and mis-
splicing variants), 3% involve large rearra ngem ents of CFTR, and 1% affects promoter
regions; 14% seem to be neutral variants, and the effect of the remaining 6% is unclear.
Diseasecausing variants can affect the quantity and/or function of CFTR at the cell
membrane (FIG 2). Historically, CFTR variants have been grouped into five (and sometimes
six) functional classes9 The class system provides a useful framework for understanding the
primary defect at the cellular level. However, binning of variants into one class is
problematic, as multiple processes can be affected by a single variant. For example, F508del
causes aberrant folding ofCFTR and subsequent degradation of the majority of the
synthesized protein 17 The minor fraction of F508del-CFTR that is trafficked to the cell
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membrane has severely reduced membrane residency and aberrant chloride channel
function18. Furthermore, the three-nucleotide deletion responsible for the F508del variant
also causes a synonymous change in the triplet that encodes isoleucine at codon 507
(ATC-7ATT). The change alters the structure of the F508del-CFTR mRNA, which leads to
a reduction in translation efficiency19. Thus, F508del could be assigned to at least three
classes. Various missense variants also cause defective processing and alter chloride channel

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function of CFTR20,21. Appreciating the diversity of effects caused by a CFTR variant is
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important in the design of molecular treatments for cystic fibrosis (see below).

Disease-causing variants provide a reservoir of naturally occurring deleterious amino acid
deletions and substitutions that have proved to be informative for dissecting the tertiary
structure of CFTR. CFTR is composed of three major motifs: domains that interact with
ATP, termed nucleotide-binding domain 1 (NBDl) and NBD2; regions that anchor the
protein in the membrane known as membrane-spanning domain 1 (MSD 1) and MSD2; and
an area containing numerous sites for phosphorylation called the regulatory domain (also
known as the R domain) (FIG 2). It had been recognized for some time that deletion of
phenylalanine at codon 508 (F508) causes instability of NBD 1, but how this localized
structural defect causes m isfolding of the entire protein was poorly understood22.
Furthermore, it was known that disease-causing missense variants outside the NBD 1
domain - notably, a cluster in the fourth cytosolic loop (CL4) within MSD2 -also cause
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misfolding of the protein224. Modelling based on the atomic structure of related proteins25,26
and cysteinecrosslinking experiments27 revealed an interaction between the NBDs and
MSDs of CFTR. Notably, F508 occurs at an interface between NBDl and CL4, and seems to
be capable of forming hydrogen bonds with arginine at codon 1070 (R1070)26. Restoration
of NBD 1 assembly using suppressor mutations produces only partial recovery of CFTR
processing, which indicates that the F508del variant also affects interactions elsewhere in
the full-length protein 28. Intriguingly, introduction of the disease-associated p.Arg1070Trp
(legacy R1070W)29 variant in CL4 and correction of NBD 1 misfolding using synthetic
suppressor mutations could restore processing to F508del-CFTR 28,30,31. These findings lay
the groundwork for structure-based selection of molecules that correct the processing defects
in CFTR caused by disease-causing variants32.
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Tissue culture. Assessment of the functional consequence of variants requires the
appropriate cellular context. For CFTR, primary epithelial cells are the most relevant
system; however, these cells are short-lived and require accessioning from internal organs
such as the lung. Furthermore, availability and compliance substantially limit acquisition of
primary cells from individuals with rare CFTR genotypes. Recent advances in stem cell
biology have provided new methods for generating well-differentiated cell lines from
individuals with cystic fibrosis. Human embryonic stem cells and intestinal stem cells from
individuals with cystic fibrosis have been coaxed into differentiating into secretory epithelial
cells that manifest defects in CFTR-mediated chloride transport34,35. Small-molecule
correctors for the F508del variant were efficacious in restoring CFTR function in both cell
types, which showed the utility of these systems for evaluating therapeutics32,34. Genetic
reversion of the F508del variants to wild type using CRISPR-Cas9 editing has been
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achieved in intestinal organoids36. Conversion of well-differentiated epithelial cells from
human ectocervix and trachea into 'conditionally reprogrammed' cells using Rho kinase
inhibitor offers an alternative approach to derive individual-specific cell types37.These
methods provide new tissue models for examining function and dysfunction of CFTR from
individuals with specific CFTR genotypes.

Animal models. One of the most useful tools in the investigation of genetic disorders is
animal models. Cystic fibrosis is unique among human genetic disorders in that five animal

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models (mouse38, rat39, ferret40, pig41 and zebrafish42) have been created. Although these
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animal models have not replicated human cystic fibrosis precisely, their differences have
proved to be highly instructive for understanding disease mechanisms at the organ-system
level (TABLE 1). The Cftr gene in mice has been extensively manipulated to derive lines
that do not express CFTR and lines that express CFTR bearing variants equivalent to those
observed in humans (for example, F508del and p.Gly551Asp (legacy G551D)) 4. Even
though airway epithelial cells display ion transport abnormalities that are consistent with
loss of CFTR function, overt lung disease is not evident in newborn or young mice with
cystic fibrosis44. The absence of lung disease similar to that seen in humans with cystic
fibrosis has been ascribed to the presence of alternative pathways for chloride transport in
mouse epithelial cells45. This observation suggests that ion channels other than CFTR might
be exploited to recover chloride transport in cystic fibrosis cells. Indeed, a suitable candidate
may have already been identified in TMEM16A (also known as ANOl), which encodes a
calcium-activated chloride channel first identified in mouse airways46. Despite the
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phenotypic differences between mice and humans, the study of cystic fibrosis mouse models
has provided invaluable insights into the role of other ion channels in the development of
lung disease, the biology ofintestinal obstruction and the evaluation of candidate
modifiers47, and such models also provide an in vivo platform for testing therapeutics43.

To create animal models that are more likely to recapitulate disease mechanisms operating
in the lung, investigators have selected species on the basis of specific anatomical features.
Of particular importance are the number and distribution of airway submucosal glands — a
site of high CFTR expression - in humans48. The lungs of pigs and ferrets represent
reasonable approximations of human lung architecture, and successful CFTR knockouts
have been achieved in both species using homologous recombination40,49. The porcine
model of cystic fibrosis develops lung disease comparable to that observed in humans, albeit
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at an earlier stage of life50. Consequently, the cystic fibrosis pig provides an opportunity to
address the sequence of events in early-stage lung disease and to evaluate therapeutics in
new-born animals. One of the key issues in the early stages of human cystic fibrosis is the
genesis of inflammation in the lungs. Some studies suggest that infection of the airways
trigger inflammation, whereas others demonstrate the presence of an inflammatory response
in the absence oflung infection51. This distinction is important, as treatment strategy of each
scenario is markedly different. In the lungs of cystic fibrosis pigs, inflammatory markers are
not elevated until polymicrobial infection ensues50. Furthermore, pigs with cystic fibrosis
exhibit an inability to eradicate bacterial pathogens, which may be partly due to
abnormalities in the pH of the airway surface liquid caused by reduced CFTR-dependent
bicarbonate transport 52. Reduction in the size of the large airways in newborn pigs with
cystic fibrosis has been associated with air trapping, a defect noted in human infants with
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cystic fibrosis53. Congenital anomalies in tracheal rings in mice, pigs and humans with
cystic fibrosis (TABLE 1) support the concept that defects in the development of the
pulmonary tree contribute to early-stage lung disease in cystic fibrosis. Finally, ion transport
studies in newborn cystic fibrosis pigs have questioned the longstanding concept that
sodium absorption is increased in the airway epithelia54. The cystic fibrosis pig model
provides compelling evidence that loss of chloride and bicarbonate transport,

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maldevelopment of the airways and infection are the important drivers of early-stage lung
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disease in cystic fibrosis.

Box 1
Twin studies for estimating heritability
A twin study represents a naturally balanced, age-matched design that provides a
powerful method for determining the contribution of genetics too trait. This opprooch
capitalizes on the different rotes of variant shoring among monozygotic twins (who ore
presumed to be 100%identical except for de novo mutations), and dizygotic twins and
siblings(who shore −50% oftheir variants). Environmental exposures ore similar (but not
identical) in utero and continue to be similar os twins grow in the some household. Thus,
by comparing the degree of similarity among mono zygotic twin pairs to di zygotic twin
pairs, on estimate con be obtained ofthe degree to which trait variance con be attributed
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to genetic variation (that is, heritability)117. Heritability measures generated in this
manner range from 0 to 1. Estimates approaching 1.0 indicate strong genetic influence,
whereas those near zero exclude a prominent role for genetic variation. The effect of
shored environment can be estimated by comparing trait variance among twin pairs
living together to those living apart. finally, within-pair variance for monozygotic twins
provides a measure of unique environmental and stochastic components, as the genetic
variance is, by definition, almost zero between mono zygotic twins. As the number of
twin pairs aviilable for study of a Mendelian disorder isgenerally small, only crude
estimates of genetic control of trait variance can be obtained. Nevertheless, the approach
outlined above is widely applicable, as family-based studies can be used to estimate
genetic control of traits that constitute any Mendelion disorder.
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Mammalian models of cystic fibrosis have also provided insights into disease processes
in other affected organ systems. Pancreatic exocrine dysfunction is closely correlated
with the development of neonatal intestinal obstruction in humans with cystic fibrosis.
However, animal models exhibit minimal (mouse) to severe (pig) pancreatic exocrine
disease com pared with humans, yet the incidence of intestinal obstruction is higher in all
mammalian models than in humans (TABLE 1). Recovery of intestinal expression of
CFTR prevents obstruction in cystic fibrosis mice, pigs and ferrets40,55,56.These two
observations suggest that loss of CFTR function in the intestine rather than pancreatic
exocrine dysfunction is the primary cause of intestinal obstruction in cystic fibrosis.
Diabetes mellitus is an age-dependent complication that affects 40% of individuals with
cystic fibrosis by 35 years of age2 this disorder is also closely correlated with pancreatic
exocrine dysfunction. Destruction of the exocrine pancreas has been proposed to stress
the endocrine pancreas, which leads to loss of insulin-secreting cells57. However,
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features of diabetes occur before the development of severe pancreatic exocrine disease
in ferrets58 and in the absence of substantial loss of insulin-producing cells in cystic
fibrosis pigs59. Both observations suggest that cystic fibrosisrelated diabetes is the result
of an intrinsic defect in the endocrine pancreas caused by loss of CFTR function.

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Variation in disease severity
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The relative contribution of genetic modifiers. Individuals with cystic fibrosis show a high
degree of variability in disease severity, complications and survival. It was initially
postulated that a substantial fraction of phenotypic variability would be explained by allelic
heterogeneity in the dysfunctional gene60. CFTR genotype correlates well with pancreatic
exocrine disease severity and modestly with sweat chloride concentration61,62. However, it
has been difficult to detect a relationship between lung function and CFTR genotype61,63,
with a few notable exceptions64. Analyses of families with affected twins (BOX 1) have
quantified the degree to which variables beyond CFTR — such as genetic modifiers,
environmental factors and/or stochasticity -influence variability in lung disease severity
(FIG 1). Affected monozygotic twin pairs exhibit greater similarity for lung function than
affected dizygotic twin and sibling pairs (siblings were used as a proxy for dizygotic
twins)65,66. By comparing clinical measures of affected twin pairs when they lived together
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to the same measures after they moved apart, 50% of the difference in lung function
measures could be attributed to genetic modifiers. The remaining variation was due to
environmental exposures, primarily those unique to each individual, and to stochastic
factors67. Together, these family-based studies demonstrate that genetic modifiers have
considerable influence on lung function variation in cystic fibrosis.

The contribution of genetic modifiers to four other traits that are relevant to survival in
cystic fibrosis has been estimated (FIG 1). Chronic colonization of the lungs with the
bacterial pathogen Pseudomonas aeruginosa is a feature of advancing lung disease in cystic
fibrosis and is associated with reduced survival68. Establishment of chronic P aeruginosa
infection and age at establishment are highly influenced by genetic factors69. Poor growth is
a hallmark of cystic fibrosis owing to pancreatic exocrine disease and deficiency of insulin-
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like growth factor 1. Although replacement of pancreatic digestive enzymes has improved
nutritional status of individuals with cystic fibrosis, those with extremely low body mass
index (BMI) remain challenging to treat. Genetic control of BMI independent of CFTR
seems to be substantial, as estimated heritability ranges from 0.54 to 0.8 (REFS 70,71).
Affected-twin analysis also revealed that genetic modifiers are primarily responsible for the
age at onset of diabetes (heritability: l.O; confidence interval: 0.42-1.0)n. Diabetes mellitus
is associated with more rapid decline in lung function in individuals with cystic fibrosis, and
medical management of glucose levels improves surviva17. Finally, obstruction of the
small intestine (a condition known as meconium ileus) complicates the management of 15%
of newborns with cystic fibrosis. Strain-specific differences in the rate of intestinal
obstruction in cystic fibrosis mice first showed that this trait could be modified by genes
other than Cftr74. Analysis of twins with cystic fibrosis demonstrated that genetic modifiers
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have the predominant role in the development of intestinal obstruction (heritability: l.0) 75.

Finding variants that modify cysticfibrosis. Extensive understanding of cystic fibrosis
pathophysiology presents an opportunity to interrogate candidate genes as potential
modifiers. In the lungs, loss of CFTR leads to exuberant inflammation, neutrophil
recruitment, tissue damage and eventual replacement with fibrotic connective tissue. At least
SO genes encoding proteins that participate in these cellular and tissue functions have been
investigated as candidate modifiers of lung disease severity in cystic fibrosis76. As the

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results of candidate modifier gene studies have been extensively reviewed elsewhere76,80,
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this Review highlights the insights gained from the study of one candidate gene that
illustrates the potential and challenges in dissecting the complex interactions that modify
disease severity.

A key element of lung disease in cystic fibrosis is the response to recurrent tissue injury.
Transforming growth factor beta 1 (TGFBl) was an intriguing candidate for a modifier of
cystic fibrosis lung disease, as it is involved in tissue repair and extracellular matrix
production. Furthermore, variants in TGFBl have been associated with risk of asthma and
chronic obstructive pulmonary disease (COPD) -two conditions that have features in
common with cystic fibrosis lung disease. Two variants that increase levels ofTGFBl were
correlated with severe lung disease as determined by airway flow measurements81.
However, the direction of effect differs between cystic fibrosis and COPD; the same alleles
show a deleterious consequence in one disorder but a protective effect in the other. It has
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been speculated that the presence of functional CFTR may invert the clinical consequences
of increased TGFBl expression in individuals with COPD81 Gene-gene and gene-
environment studies using TGFBl variants have begun to address the issue of context. An
obvious first place to look for gene-gene interaction is between TGFBl modifier variants and
CFTR disease-causing variants. Drumm, Knowles and colleagues established TGFBl as a
modifier primarily in individuals who are homozygous for the common cystic fibrosis-
causing variant F508del81. A subsequent study demonstrated that the alternative alleles of
the same TGFBl variants were associated with less severe lung disease, but the effect was
limited to individuals with CFTR genotypes other than F508del homozygosity82. Interaction
has been reported between TGFBl and mannose-binding lectin 2 (MBL2), which is another
genetic modifier of cystic fibrosis. Variants associated with increased TGFBl expression
amplify the deleterious effects of MEL deficiency upon lung infection and airway
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deterioration84. Environmental context is also important, as variants in TGFBl exacerbate
the pernicious effects of exposure to second-hand smoke in patients with cystic fibrosis85.
These observations indicate that deducing the clinical effect of a modifier variant greatly
depends on the context in which it occurs.

To identify novel modifiers, research groups have combined patient populations to achieve
sufficient power in genome-wide methods. Formation of a North American Cystic Fibrosis
Gene Modifier Consortium — composed of investigators at the University of North
Carolina, USA; the Hospital for Sick Kids in Toronto, Canada; and Johns Hopkins
University in Baltimore, Maryland, USA - facilitated both association and linkage studies on
3,500 individuals. Although the three sites used different study designs, each agreed to use
the same measure of lung disease severity, thereby enabling an analysis of unrelated subjects
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recruited by the centres in North Carolina and Toronto, as well as replication in related
subjects participating in the Johns Hopkins study. In a genome-wide association study
(GWAS), a significant region was detected between two genes on chromosome 11: EHF,
which encodes an epithelial transcription factor, and APIP, which encodes an inhibitor
ofapoptosis86. The known functions ofEHFand APIP suggest biologically plausible roles in
modifying lung function in cystic fibrosis86. To search for rare variants that modify lung
function, linkage analysis was carried out on 486 affected sibling pairs. A locus on

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chromosome 20ql3.2 harbouring only 4 genes was identified86. The identification of each
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locus demonstrates the feasibility of genome-wide approaches for uncovering new pathways
that modify disease severity in cystic fibrosis.

Searching for genetic modifiers of other cystic fibrosis traits has provided mechanistic
insights on several fronts. First, risk variants for other diseases operate as modifiers of
similar conditions in patients with cystic fibrosis. Variants in four genes that confer risk for
type 2 diabetes mellitus on the general population (TCF7L2, CDKALl, CDKN2A/B and
IGF2BP2) modify age at onset of diabetes in cystic fibrosiif7(FIG 1). The Z allele
ofSERYINA, which causes al-an ti trypsin deficiency and confers risk for emphysema and
liver disease, modifies risk of cirrhotic liver disease in cystic fibrosis88 Second, modifiers
exhibit pleiotropic effects on the cystic fibrosis phenotype. Variants in SLC26A9 - which
encodes a chloride and bicarbonate channel that interacts with CFTR -modify risk for
neonatal intestinal obstruction and diabetes8iw. Furthermore, solute carriers associated with
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risk of neonatal intestinal obstruction also modify lung disease severity in young patients
with cystic fibrosis (SLC9A3 and SLC6A14) and age at first infection with P. aeruginosa
(SLC6A14)90. Third, informing GWASs with knowledge ofCFTR function increases the
yield of significant associations. This approach, termed hypothesis-driven GWASs, revealed
that proteins residing in the same cellular location as CFTR are enriched for modifiers of
neonatal intestinal obstructionw. Fourth, exome sequencing can find rare modifier variants.
Variants in DCTN4 - which encodes a dynactin protein involved in autophagy- are
associated with age at onset of chronic infection with P. aeruginosa91. The identification of
DCTN4 as a modifier may provide a mechanistic link to defective autophagy in cystic
fibrosis cells92. Conversely, loss-of-function variants in CFTR have been linked to a variety
of other conditions (BOX 2). Together, these findings illustrate that the complex
mechanisms underlying trait modification in cystic fibrosis can be informed by genetics,
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especially if approaches beyond standard association and linkage are undertaken.

Molecular diagnosis and therapy
Screening, diagnosis and functional annotation of CFTR variants. For almost 2 decades, a
panel of 23 of the most common variants - vetted by an expert committee of the American
College of Medical Genetics — has been used to diagnose cystic fibrosis and to screen for
carriers and affected newborns. Expansion of the panel to increase sensitivity remained
challenging, and the disease liability for most of the remaining CFTR variants was not
known94. The Clinical and Functional Translation of CFTR (CFTR2) project was initiated in
2010 to increase the number of annotated CFTR variants. Clinical and CFTR genotype data
collected on 39,696 individuals enrolled in cystic fibrosis patient registries and clinics in
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North America and Europe were used to determine the penetrance of variants for cystic
fibrosiszo. To widely and rapidly disseminate results, features associated with each variant
are available on a public website (see CFTR2 ). Content is tailored to educate patients,
family and the public about the clinical implications that can and cannot be inferred from
CFTR genotype. Inclusion of 127CFTR variants annotated as disease-causing in screening
assays increased the sensitivity for detection of cystic fibrosis alleles in white European
individuals from 85% to 95%20_ Although this improvement seems modest, the recessive
nature of cystic fibrosis requires ascertaining variant status in two CFTR genes. Thus, at

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95% sensitivity, only 0.25% of individuals with cystic fibrosis will have neither
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diseasecausing variant identified. Translation of these findings should improve the accuracy
of screening programmes, and will aid diagnosis and treatment, as 99.75% of individuals
with cystic fibrosis should carry at least one disease-causing CFTR variant. Owing to
population differences in the frequency of CFTR variants, in particular the F508del variant,
the sensitivity of screening is lower in non-white individuals. Inclusion of affected
individuals from South America, Africa, the Middle East and East Asia in the current phase
ofCFTR2 recruitment will provide a more complete inventory of variants found in non-
white populations. As of late 2014, CFTR2 has obtained data on73,000 individuals, thereby
exceeding the estimated number of individuals with cystic fibrosis worldwide (70,000).
Given the completeness of the ascertainment, the sensitivity of screening in all populations
will be improved, substantially in some cases, once variant annotation is completed.

Molecular therapyfor cysticfibrosis. The most exciting development in cystic fibrosis
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research since the identification of CFTR has been the successful implementation of therapy
that augments the function of mutant CFTR. Increasing the chloride channel
activityofmutant forms ofCFTR was shown to be a viable therapeutic approach two decades
ago95. Development of compounds that selectively activated CFTR at doses that could be
achieved in vivo proved to be difficult, and attention was focused on gene replacement
methods for the next decade. However, the search for a molecular correction ofCFTR has
not been abandoned. A unique partnership between a biotech company and the US Cystic
Fibrosis Foundation initiated empirical screens for small molecules that target CFTR
mutants. A promising compound termed ivacaftor (also known as VX-770 and Kalydeco
(Vertex Pharmaceuticals)) increased chloride transport of primary airway cells bearing the
G551D variant up to 50% of wild-type level96. Significant but more modest increases in
G551D-CFTR activity were observed in immortalized cell lines (10-30% of wild-type
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CFTR)97,98. The increase in CFTR function observed in cell lines achieved levels that would
be expected to produce a clinical response in lung function (BOX 3). Indeed, Phase Ill
clinical trials over 4-week and 48-week intervals demonstrated that ivacaftor improved lung
function (by 10% on average) and reduced sweat chloride concentration (to an average
concentration below the diagnostic threshold of 60 mM) in individuals with cystic fibrosis
carrying the G551D variant 15,99 (FIG 3a). Assessment of in vivo response to ivacaftor using
sweat volume measures in 5 patients estimated recovery of 1.6-7.7% of wild-type CFTR
function, while estimates derived from sweat chloride concentration and nasal potential
difference measurements in 39 individuals indicated recovery of 35-40% of normal CFTR
function100,101.

Box 2
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CFTR in other diseases
Male infertility

The concept that dysfunction of cysticfibrosistronsmembrone conductonce regulator
(CFTR) could create disorders other than cysticfibrosis was first illustrated by obstructive
mole infertility due to congenital bilaterol obsence of the vas deferens (CBAVD; OMIM
277180)118 The onotomicol features of CBAVD ore identical to those seen in moles with

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cysticfibrosis, and some individuals with CBAVD hove subtle features of cysticfibrosis,
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such os mildly elevated sweat chloride concentration or minimol oirwoydiseose119
However, a fraction of moles with CBAVD manifest no evidence of cysticfibrosis in
detailed studies ofthe lungs, pancreas and S1Neot glond 120. Furthermore, the distribution
of CFTR variants differs between CBAVD and cystic fibrosis, and a much higher fraction
of variants isassociated with residual function occurring in CBAVD 121. Thus, CBAVD
is port of the cystic fibrosis spectrum caused by CFTR dysfunction (FIG. 1), but it is also
viewed as clinically distinct, particularly in moles with features limited to the vos
deferens.

Pancreatitis

Loss-of-function variants in CFTR have also been linked too variety of conditions
collectively termed 'CFTR-opothies', asreviewed by others14,122. Discovery of a
pothologicol role for CFTR has proved to be particularly instructive for the study of
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poncreotitis. Poncreotitis is a known complication of cysticfibrosis, primarily occuring in
individuals with preserved pancreatic exocrine function123 Poncreotitis in the general
population is a heterogeneous disorder with heritable and idiopathic sporadic forms124. A
subset of heritable forms of recurrent acute and chronicponcreotitis can be attributed to
CFTR dysfunction124 As with CBAVD, the distribution of CFTR variants differs from
that of cystic fibrosis. Recent evidence suggeststhat cells expressing CFTR bearing
variants associated with poncreotitis, but not with cystic fibrosis, manifest defective
bicarbonate transport, while chloride channel function is preserved125. This concept
aligns well with the role of CFTR as an important mediator of bicarbonate transport in
the poncreoticducts 126.

Manifestations in cystic fibrosis carriers
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CFTR variants also act as risk alleles for multigenic disorders in the general population.
Idiopathic disseminated bronchiectasis is a relatively rare pulmonary airway disease that
manifests features similar to those observed in the lungs of individuals with cystic
fibrosis. Several studies have shown a higher frequency of deleterious CFTR variants in
individuals with bronchiectosisthon in control subjects". Bronchiectosisthot is
complicated by infection with non-tuberculous mycobocterio or with the fungus
Aspergillu.s fumigatus has also been associated with on increased frequency of CFTR
variants127,128 Chronic rhinosinusitis (CRS) is an aetiologically heterogeneous condition
affecting ~15% of the general population in the United States. CRS is a common
complication in individuals with cysticfibrosis. Genotyping of subjects meeting rigorous
criteria for CRS revealed on excess of carriers of a single deleterious CFTR variant
compared to disease-free controls129. In these studies, the entire coding region of
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CFTRwosexomined to exclude a second deleteriousvoriont. Support for the concept that
presence of a single loss-of-function variant in CFTR predisposes to CRS was derived
from the observation that the obligate heterozygous carriers of the deleterious CFTR
variant (that is, the parents of individuals with cystic fibrosis) hod a threefold increase in
prevalence of CRS130
Assessing whether poncreotitis, bronchiectosis or sinusitis con be attributed to CFTR
dysfunction in a heterozygouscysticfibrosiscorrier requires detailed phenotyping to

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exclude other conditions, including mild forms of cystic fibrosis 131. This challenge will
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become porticulorlypertinent oswe enter into on age where CFTR dysfunction con be
treated ot the molecular level. Furthermore, associating CFTR variants with common
multigenic disorders hos substantial implications, os there ore on estimated 20 million
heterozygous carriers of cystic fibrosis in the world. Many carriers of deleterious CFTR
variants ore becoming owore oftheir status os population testing iswidespread in the
United States and is becoming more common in Europe. However, the penetronce of
most CFTR voriontsfor the traits discussed above is not known. Establishing the
penetronce of variants in diseose-ossocioted genesis a considerable and important
challenge132

Box 3
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Reversing cystic fibrosis: how much CFTR is needed?
Effective treatment of cystic fibrosis at the molecular level requires restoration of
cysticfibrosistronsmembrone conductance regulator (CFTR) function in affected tissues.
Genotype ond phenotype correlation revealed that organ systems hove different
requirements for CFTR function 13 Splice sitevoriontsthot reduce but do not eliminate
production of some CFTR mRNA hove been porticulorly informative in this regord 133.
Improvement in lung function meosuresond otherfeotures of cysticfibrosis (for example,
S1Neot chloride concentration) occurs at CFTR mRNA levels above 5% of
normal134,135. Splice sitevorionts that allow CFTRtronscript levels to reach 10-25% of
normal levels hove been found in individuals that do not hove cystic fibrosis lung
diseose136,137 As the residual RNA transcript isoffull length, it hos been assumed that the
quantity of transcribed CFTR protein will correspond to the level of remaining full-length
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CFTR transcripts. A lower boundary of 10%of normal levels for relieving pulmonary
disease is supported by cell mixing experiments, which indicate that oirwoy epithelial ion
transport is normalized when 6-10% of cells hove corrected CFTR function 138 Rescue of
other key functions of the respirotoryepithelio may require higher levels of CFTR
function. Restoration of mucus transport required −25% of cellsto be corrected139. These
estimates represent overages; variation in genetic ond non-genetic modifiers islikely to
broaden the range of CFTR correction required at the individual level.

The successful clinical deployment of ivacaftor encouraged the search for compounds that
can correct other defects in CFTR. The prevalence of the F508del variant has attracted
intense interest in reversing the folding defect caused by this variant. Screening of small
molecules followed by chemical modification of active compounds led to the formulation
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oflumacaftor (also known as VX-809), which increased chloride transport of primary airway
cells bearing F508del-CFTR to 14% of wild-type levels102 A clinical trial oflumacaftor
produced a dose-dependent improvement in CFTR function measured in the sweat gland of
patients carrying the F508del variant 1. However, CFTR function was not augmented in
nasal epithelia, and lung function measures were not improved 1 (FIG 3a). As ivacaftor
confers wild-type levels of open probability on F508del-CFTR, albeit as a result of a
different pattern of channel gating96 clinical trials combining ivacaftor with the corrector

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lumacaftor have been undertaken. This approach follows the reasonable logic that a
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potentiator can increase the activation of'corrected' F508del-CFTR, thus amplifying the
effect achieved by each compound alone102 (FIG 3b). A Phase II clinical trial demonstrated
that the combination oflumacaftor and ivacaftor improved measures of lung function and
sweat chloride concentration in individuals homozygous for the F508del variant 16 This
encouraging result has been followed by the announcement that 2 Phase III clinical trials of
combined lumicaftor and ivacaftor involving 1,100 F508 homozygotes over a 24-week
period documented improvement in lung function (See Vertex press release). Although the
changes in lung function measures were modest, there were concurrent improvements in
secondary end points, providing encouraging evidence of clinical efficacy. However, two
groups have recently reported that ivacaftor exposure for 48 hours diminishes the correction
of F508del-CFTR conferred by lumacaftor in primary and immortalized cells104,105
Reduction in the quantity of 'corrected' F508del-CFTR due to ivacaftor may explain the
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modest responses observed in the clinical trials (FIG 3b). Thus, compounds selected for
combinatorial therapy will have to be carefully screened for undesirable interactions. With a
panel of 'correctors' and 'potentiators' in hand, screening can proceed for combinations that
act cooperatively32,105 (FIG 3b). Furthermore, the available drugs could be used to screen
for novel compounds that interact synergistically to further recover function of F508del-
CFTR 106 (FIG 3b).

Although F508del and G551D account for a large fraction of cystic fibrosis alleles, 7% of
patients with cystic fibrosis carry neither variant. To extend available therapy to as many
individuals as possible, variants that permit translation of the CFTR protein can be evaluated
for response to clinically approved corrector and potentiator compounds. However, as
hundreds of translatable variants have been found in CFTR, it will be challenging to perform
clinical efficacy studies of all variants, and many of these variants are carried by only a few
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affected individuals. Therefore, a new approach is required to extend approved efficacious
treatments to individuals with rare variants in CFTR. It has been proposed to group CFTR
variants into theratypes according to their effect on the CFTR protein and in response to
corrector and potentiator compounds. Previously unclassified variants can be provisionally
assigned to theratypes on the basis of their effect on CFTR quantity and function in cell-
based studies. Response of CFTR bearing the unclassified variant to the profile of
compounds that define the theratype would confirm that the assignment is appropriate (FIG
3c). Measures of in vivo CFTR function can then be used to verify clinical response and to
justify ongoing treatment of individual patients 107 To this end, 9 missense variants were
shown to cause a defect in activation (that is, gating) of CFTR and reduction in chloride
transport ranging from 0% to 9.7% of normal levels108 As noted for the GSS 1D variant,
ivacaftor treatment ofimmortalized cells expressing CFTR bearing each of these variants
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increased chloride transport from 21% to 1S7% of normal levels108, thereby predicting that
clinical response should occur in individuals carrying these variants (FIG 3c). Subsequently,
a Phase III clinical trial of 39 individuals demonstrated that ivacaftor was efficacious for 8
of the 9 variants, leading to rapid approval by the US Food and Drug Administration (NDA
203188). The four individuals carrying one variant did not respond sufficiently to warrant
approval for ivacaftor treatment. The rapid expansion of small-molecule therapy for cystic
fibrosis, from cell-based studies to clinical application, provides a new paradigm for drug

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 Cutting Page 13

development for genetic disorders and an excellent example of the promise of personalized
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medicine.

To treat all patients with cystic fibrosis, it will be necessary to address variants that prevent
or severely decrease production of the CFTR protein through alterations in RNA processing.
Nonsense and frameshift variants that introduce a premature termination codon (PTC) pose
several hurdles that must be cleared to achieve therapeutic quantities of the protein. Most
PTC variants invoke RNA degradation through the nonsense-mediated RNA decay (NMD)
pathway109. Counteracting NMD to stabilize mRNA in vivo is challenging owing to the
possibility of off-target effectsno. Synthesis of a full-length protein requires readthrough of
the PTC, and some success in suppressing nonsense variants in CFTR using compounds
derived from aminoglycosides has been achieved 111 (FIG 3d). Clinical trials of PTC
suppressors have documented modest recovery of CFTR function in the nasal epithelia,
although improvement in lung function has not been reported 112·m. Even when readthrough
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is successful, the incorporation of a non-native amino acid at the location of the nonsense
variant could affect protein processing and function109.Thus, augmenting the function
ofCFTR with ivacaftor following PTC suppression seems to be a viable approach to exceed
the therapeutic threshold (FIG 3d). Alternatively, strategies such as induction of the
unfolded protein response could be used to attenuate NMD, thereby stabilizing transcripts
with PTCs for possible readthrough 114 Variants that cause aberrant RNA splicing pose a
different set of challenges. On the one hand, suppression of variants that activate cryptic
splice sites, such as c.3717 + 12191 C→7T (legacy 3849 + 10kbC-7T), can substantially
increase the amount of normally spliced RNA transcript and protein (FIG 3d). On the other
hand, variants that alter canonical nucleotides in splice sites are proving difficult to treat,
although manipulation of splicing factors (for example, U1 small nuclear RNA) and the
splicing process (for example, trans-splicing) shows some promise 115 The remaining
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variants are rearrangements, which require replacement of one or more exons or the entire
coding sequence of CFTR. Transfer of DNA to epithelial cells has been extensively explored
as a therapeutic approach for cystic fibrosis, but efficient delivery to airway cells in vivo
remains problematic116. Finally, although molecular treatment is at hand, variation in
response15,35 indicates that underlying individual differences will have to be addressed to
achieve the goal of attaining a normal lifespan for all patients with cystic fibrosis.

Conclusions
The discovery of CFTR 25 years ago was a triumph for genetics and a potent demonstration
of its ability to deliver the molecular culprit in a Mendelian disorder. Cystic fibrosis is now
positioned to reap the dividends of personalized medicine as variantspecific therapy is
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deployed, and a growing understanding of the genetic and environmental modifiers of cystic
fibrosis enables targeting of individual risk factors. The development of new genetic models
of cystic fibrosis in pigs, ferrets, rats and zebrafish provides opportunities to investigate
pathophysiology and to explore therapies at the earliest stages of disease. Newborn and
population screening enables prospective management of affected individuals from birth,
and genomic variation will provide information on the trajectories that individual patients
are likely to follow. Genetics has played and will continue to play a key part in achieving a
normal lifespan for individuals with cystic fibrosis.

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Acknowledgements
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The author thanks P. Thomas, D. Sheppard, M. Knowles, M. Drumm and B. Guggino for providing commentary
and critique of this Review, and members of the CFTR2 team (C. Penland, J. Rommens, C. Castellani and M.
Corey) for many insights regarding the clinical and functional consequences of CFTR variants. He also thanks P.
Durie, H. Corvol and the members of the International Cystic Fibrosis Modifier Consortium for discussions about
modifiers of cystic fibrosis, and members of the Cutting laboratory, especially P. Sosnay, S. Blackman, J. M.
Collaco and K. Raraigh, for contributions to concepts presented in this Review. The author’s work is supported by
grants 5R01DK044003 from the NIDDK, and grants CUTTING08A, CUTTING09A and CUTTING10A from the
US Cystic Fibrosis Foundation. Competing interests statement The authors declare competing interests: see Web
version for details.

Glossary

Pancreatic exocrine Pertaining to the portion of the pancreas that produces digestive
enzymes that are combined with alkaline secretions from the
pancreatic ducts and secreted into the intestine to aid digestion.
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Locus-specific Collections of DNA variants that have been reported in disease-
databases associated genes.
CRISPR-Cas9 A method that uses an RNA guide and a DNA-binding protein to
editing cleave DNA at a specific location to create sequence-specific
changes via homologous recombination with a donor template.
Intestinal Epithelial "mini-guts" grown in vitro from biopsies of the rectal
organoids mucosa or from stem cells from a single individual.
Airway submucosal Mucus-secretingglands found in the connective tissue that provide
glands fluid for hydrating the surface of the airway epithelial cells and
enabling ciliary function.
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Airway surface Iiquid Fluid interface between the air and the cells in the lungs that
confers protection from infection and facilitates removal of foreign
particles.
Tracheal rings Incomplete rings of highly elastic cartilage found in the anterior
two-thirds of the tracheal wall.
Endocrine Portion of the pancreas that produces hormones (insulin and
pancreas glucagon) that are essential for glucose homeostasis.
Pseudomonas Widely distributed gram-negative bacteria that show a predilection
aeruginosa for acute and chronic infection of the Iungs of individuals with
cystic fibrosis.
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Meconium ileus Obstruction of the gut that usually develops in ubero in the ileum
of the small intestine and that is highly suggestive of cystic
fibrosis.
Airway flow Series of standardized tests assessing the rate and volume of air
measurements that can be inhaled and exhaled: they are used to determine the
degree of disease in the lungs in individuals with cysticfibrosis.

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 Cutting Page 15
Author Manuscript

Vas deferens A tubular structure that conveys sperm from the testis to the
urethra of the penis.
Disseminated Pennanentdilation of the airwa}'S (bronchi) throughout the lungs.
bronchiectasis
Phase III clinical The third of four phases of evaluating a drug in affected subjects
trials that confirms its safety and efficacy.
Nasal potential Measurement of voltage across nasal epithelia th at represents the
difference transport of ions and that. under specific conditions. can assess the
function of cystic fibrosis tran smembran e conductance regulator
(CFTR) in vivo.
Open probability A measure of the average fraction of time that a channel is open.
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Phase II clinical The second of four phases of evaluating a drug in affected subjects
trial that establishes the efficacy of a drug compared to a placebo.
Theratypes A recently invented tenn used to classify disease-associated DNA
variants according to the molecular-based treatment to which they
respond.

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