Translating Molecular Technologies into Routine Newborn Screening Practice


International Journal of

Neonatal Screening

Review

Translating Molecular Technologies into Routine
Newborn Screening Practice

Sarah M. Furnier 1,2, Maureen S. Durkin 1,2,3 and Mei W. Baker 1,2,3,4,*
1 Department of Population Health Sciences, University of Wisconsin School of Medicine and Public Health,

Madison, WI 53705, USA; furnier@wisc.edu (S.M.F.); maureen.durkin@wisc.edu (M.S.D.)
2 Waisman Center, University of Wisconsin-Madison, Madison, WI 53705, USA
3 Department of Pediatrics, University of Wisconsin School of Medicine and Public Health,

Madison, WI 53705, USA
4 Wisconsin State Laboratory of Hygiene, University of Wisconsin School of Medicine and Public Health,

Madison, WI 53706, USA
* Correspondence: mei.baker@wisc.edu

Received: 22 September 2020; Accepted: 14 October 2020; Published: 15 October 2020
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Abstract: As biotechnologies advance and better treatment regimens emerge, there is a trend toward
applying more advanced technologies and adding more conditions to the newborn screening (NBS)
panel. In the current Recommended Uniform Screening Panel (RUSP), all conditions but one,
congenital hypothyroidism, have well-defined genes and inheritance patterns, so it is beneficial to
incorporate molecular testing in NBS when it is necessary and appropriate. Indeed, the applications
of molecular technologies have taken NBS to previously uncharted territory. In this paper, based
on our own program experience and what has been reported in the literature, we describe current
practices regarding the applications of molecular technologies in routine NBS practice in the era of
genomic and precision medicine.

Keywords: newborn screening; next generation sequencing; droplet digital polymerase chain
reaction; real-time polymerase chain reaction; Tetra-primer amplification refractory mutation
system–polymerase chain reaction; severe combined immunodeficiency; spinal muscular atrophy;
cystic fibrosis

1. Introduction

The goal of newborn screening (NBS) is to identify presymptomatic newborns with serious or
fatal disorders that can be successfully treated, thereby achieving a significant reduction in morbidity
and mortality. The more than 55-year history of NBS demonstrates that NBS is an extremely successful
and cost-efficient public health undertaking in the field of preventive medicine. In the United States
alone, approximately four million infants are screened annually, and over 12,000 are identified with
one of the screened conditions and receive early medical attention [1].

As biotechnologies advance and better treatment regimens emerge, there is a trend toward
applying more advanced technologies in the NBS context and adding more conditions to the NBS panel.
In the current Recommended Uniform Screening Panel (RUSP), a list of conditions recommended for
inclusion in state NBS programs by the Department of Health and Human Services, all conditions but
one, congenital hypothyroidism, have well-defined genes and inheritance patterns, so it is beneficial to
incorporate molecular testing in NBS when it is necessary and appropriate. Indeed, the application
of molecular technologies has taken NBS to previously uncharted territory. In a 1989 publication,
Jinks and colleagues reported a method to isolate DNA from NBS dried blood specimens and to use
the isolated DNA to detect a pathogenic variant of the HBB gene that causes sickle cell disease [2]. In

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1991, Wisconsin researchers adapted this DNA isolation method to detect CFTR c.1521_1523delCTT
(also-known-as F508del), the most common variant associated with cystic fibrosis (CF), in a randomized
clinical trial for NBS for CF in which NBS specimens with elevated immunoreactive trypsinogen
(IRT), a biomarker elevated in newborns with CF, underwent F508del analysis [3]. This so-called
IRT/DNA strategy in NBS for CF was later carried forward when routine NBS for CF was implemented
in Wisconsin in 1994 [4]. The IRT/DNA protocol has also successfully been implemented in routine
screening in NBS programs in Australia and Europe [5,6].

In recent years, more and more DNA-based assays have been integrated into routine NBS testing.
In this paper, based on our own Wisconsin program experience and what has been reported in
the literature, we attempt to present the current practice regarding molecular technologies in routine
NBS practice in the era of genomic and precision medicine. Here we describe those applications in
three categories (Table 1).

Table 1. Molecular technology applications in Wisconsin routine newborn screening.

Molecular
Application

Example Condition Molecular Marker Technology

First-tier markers

Severe combined
immunodeficiency

T-cell receptor excision
circles

Real-time polymerase chain
reaction (PCR)

Spinal muscular atrophy
Homozygous SMN1

exon 7 deletion
Real-time PCR

Second-tier
markers

Cystic fibrosis CFTR variants Next generation sequencing

Supplemental
“just-in-time” 1

information

Galactosemia
GALT c.563A>G,

c.404C>T, and c.940A>G

Tetra-primer amplification
refractory mutation system
(Tetra-primer ARMS)–PCR

Maple syrup urine
disease

BCKDHA c.1325 T>A Tetra-primer ARMS–PCR

Sickle cell disease HBB c.20 A>T Sanger sequencing

Pompe disease
GAA coding region and

intron-exon junctions
Sanger sequencing

Spinal muscular atrophy SMN2 copy number Droplet digital PCR
1 Screening positive determination is based on the first-tier result, and “just-in-time” gene variant information
is intended to help clinicians better interpret the first-tier testing results and be better prepared for their initial
communication and discussion with families regarding newborn screening positive results.

2. Molecular Marker Identification as Primary Screening Methods in NBS for Severe Combined
Immunodeficiency (SCID) and Spinal Muscular Atrophy (SMA)

SCID is a disorder of abnormal development of the immune system, leading to an inability to
mount an adequate immune response. When undiagnosed and untreated, the disorder has a high
mortality rate, and the success of intervention is dependent on how early it is implemented [7]. Prior
to the development of an NBS method for detecting SCID, at a 2004 Centers for Disease Control and
Preventions conference, SCID was recognized as a disorder that met important criteria for inclusion
in NBS [8]. Soon afterwards, Chan and Puck demonstrated that measurement of T-cell receptor
excision circles (TRECs) in dried blood samples can be used for SCID screening in newborns [9]
based on a method to study the effectiveness of anti-retroviral treatments in patients with acquired
immunodeficiency syndrome by measuring TREC copies as a proxy for newly generated T cells after
treatment [10]. Baker and colleagues adopted the concept of using TRECs as a SCID screening marker
and further optimized the process of isolating DNA from routine NBS dried blood specimens in order
to maximize DNA yield and improved the DNA amplification in a real-time PCR analysis. By doing
so, they reduced the false positive rate [11].



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In 2008, the Wisconsin NBS program implemented a molecular screening assay for SCID, the first
DNA-based assay used as a first-tier screen in NBS history [11,12]. In 2010, SCID screening was added
to the RUSP [13]. By the end of 2018, all NBS programs in the United States had added SCID to their
NBS panels, and the experience of NBS for SCID in 11 screening programs throughout the United
States was reported in 2014 [14,15]. Progress in population-based NBS for SCID has also been made in
many other countries, including Saudi Arabia, Spain, France, Sweden, the Netherlands, Taiwan, Brazil,
Japan, and Israel [16–24].

Although SCID screening methods are DNA-based assays, TRECs are not a genetic marker
and are used in SCID screening as a surrogate marker of T-cell development [25]. Currently, there
are two predominant methods for measuring TRECs in routine NBS for SCID: real-time PCR and
end-point PCR [26]. Three reports in the literature have reported SCID screening methods that
involve a combination of TREC assays and genetic testing by next generation sequencing (NGS). In
addition to an end-point-PCR TREC analysis (EnLite Neonatal TREC Kit, Perkin Elmer, Turku, Finland),
Al-Mousa and colleagues performed targeted NGS using a panel of genes known to be associated
with primary immunodeficiencies (PIDs), later confirmed through Sanger sequencing. They also used
a copy number-based assay (RT-qPCR and single nucleotide polymorphism microarrays) to detect
the chromosome 22q11.2 deletion, a non-SCID PID [16]. Muramatsu and colleagues used a similar
approach, but the chromosome 22q11.2 deletion was included in the NGS panel [23]. Strand and
colleagues reported a two-tier approach in a pilot NBS for SCID: the first tier consists of real-time PCR
for TREC and the second-tier NGS of a targeted panel of PID-associated genes with results confirmed
by Sanger sequencing [27]. This combination method allows the addition of relevant gene variant
information to infants identified by TREC assays as at high risk for SCID as a part of the routine NBS
process which has been demonstrated by the above cited three reports.

SMA is an autosomal recessive neuromuscular disease caused by pathogenic variants in the survival
motor neuron 1 (SMN1) gene. SMA is characterized by loss of lower motor neurons, or anterior horn
cells, in the spinal cord and brain stem nuclei leading to progressive symmetrical muscle weakness and
atrophy. It is the most common inherited cause of childhood mortality and, in the general population,
the incidence is approximately 1 in 11,000 live births [28]. The survival motor neuron 2 (SMN2) copy
number is a major modifier of the SMA phenotype with higher SMN2 copy numbers associated with
later onset and a milder phenotype. Ninety-five percent of SMA patients have a homozygous exon
7 deletion of SMN1, and infants with this deletion and two copies of SMN2 account for the most
common severe infantile form of SMA, Type I. However, symptom onset and disease severity in infants
and children who have three or more copies of SMN2 are more variable [29]. Based on a natural
history study, the SMA mortality rate is 68% by the age of two years old [30]. Recent Food and Drug
Administration-approved effective gene modulation and gene therapy treatments have enhanced
the justification for adding SMA to NBS programs. In 2018, the Advisory Committee on Heritable
Disorders in Newborns and Children recommended expanding the RUSP to include SMA caused by
homozygous deletion of exon 7 in SMN1, and the Secretary of Health and Human Services accepted
the recommendation [31]. Subsequently, the Wisconsin Department of Health Services added SMA to
the Wisconsin NBS condition panel by an emergency rule, effective on 15 October 2019.

Most NBS programs that have implemented NBS for SMA use a real-time PCR assay to
simultaneously screen for SCID and SMA. The PCR assay identifies the absence of exon 7 in the SMN1
gene while simultaneously evaluating TREC copy numbers; the additional cost for an SMA screening
test is minimal because it is multiplexed with an existing screening assay used to identify infants with
SCID. In some programs, the SMN2 copy number assessment is also carried out on specimens with
no functional copies of SMN1 to provide “just-in-time” supplemental information to clinicians. In
Wisconsin, we use our laboratory-developed and validated triplex real-time PCR assay to simultaneously
screen for SCID and SMA. In addition to TRECs and SMN1, the amplification of a reference gene,
RPP30, is included in the assay as a quality/quantity indicator for DNA isolated from 3.2-mm dried
blood NBS specimens. Specimens with absent SMN1 amplification undergo a droplet digital PCR assay



Int. J. Neonatal Screen. 2020, 6, 80 4 of 12

to assess copy numbers of SMN2. Infants with an absent SMN1 result are reported as screening positive
for SMA, with SMN2 copy number information provided to the follow-up pediatric neurologists. With
the SMN2 copy number information, clinicians are better equipped to let families know what to expect
and convey treatment options during their initial conversations with families following positive SMA
screening result. At the first follow-up clinical visit, the physician orders a confirmatory SMN1 and
SMN2 test through a diagnosis reference laboratory.

There are several publications regarding the experience of NBS for SMA [32–36]. We have
summarized these experiences in Table 2. Kay and colleagues acknowledged the first year of the New
York state SMA NBS resulted in a much lower SMA birth incidence rate than ones reported in
the literature and offered some potential explanations [35].



Int. J. Neonatal Screen. 2020, 6, 80 5 of 12

Table 2. Selected spinal muscular atrophy newborn screening studies.

Reference Region Screening Method SMN2 Inclusion
Number of
Newborns
Screened

Reported
Incidence in

Sample
Study Type

Chien et al. 2017 [33] Taiwan
Real-time PCR SMN1 assay to detect

homozygous exon 7 deletion; verified by
droplet digital PCR assay

Droplet digital PCR
assay to assess SMN2

copy number
120,267 1 in 17,181 Pilot

Boemer et al.
2019 [32]

Belgium
Real-time PCR SMN1 assay to detect

homozygous exon 7 deletion
No Not applicable Not applicable Pilot

Vill et al. 2019 [36] Germany

Real-time PCR SMN1 assay to detect
homozygous exon 7 deletion; verified by

multiplex ligation-dependent probe
amplification (MLPA)

MLPA to assess
SMN2 copy number

165,525 1 in 7096 Pilot

Kariyawasam et al.
2020 [34]

Australia
Real-time PCR SMN1 assay to detect

homozygous exon 7 deletion

Droplet digital PCR
assay to assess SMN2

copy number
103,903 1 in 10,390 Pilot

Kay et al. 2020 [35] New York
Real-time PCR SMN1 assay to detect

homozygous exon 7 deletion
No 225,093 1 in 28,137 Routine



Int. J. Neonatal Screen. 2020, 6, 80 6 of 12

3. Targeted Gene Variant Panel as Second-Tier Testing

As described earlier, the IRT/DNA strategy in NBS for CF started with one single CFTR variant,
F508del. Yet as of 2010, many newborns in Europe and most babies in North America, Australia, and
New Zealand are being screened with an IRT/DNA algorithm that often employs a CFTR variant
panel with multiple CF-causing variants [4,6,37,38]. There has been a trend in recent years to add
more CF-causing variants for screening. In 2015, a reported study demonstrated the feasibility of
incorporating NGS into CF screening, which allows the inclusion of hundreds of CFTR pathogenic
variants [39].

Since April 2016, the Wisconsin NBS program has implemented such an NGS assay to identify
CF-causing variants. Currently, IRT testing is the first-tier NBS test for CF. Specimens in the daily
highest four percent of IRT values then undergo a second-tier CFTR variant analysis using NGS
technology. A MiSeqDx Cystic Fibrosis 139-Variant Assay (Illumina, San Diego, CA, USA) is utilized
to generate sequences of the CFTR gene coding regions and intron–exon junctions. These data are then
filtered to display CF-causing variants. The assay-accompanied software identifies 139 CF-causing
variants, including the most common CFTR deletion of exon 2 and exon 3 and CFTR deletion of
exon 22 and exon 23. A laboratory-developed variant-call pipeline is also used to include additional
CF-causing variants based on CFTR2, a website that provides information about whether the variant
or variant combination is CF-causing and some functional analysis results with this variant or variant
combination [40]. The current predefined panel consists of 324 CF-causing CFTR variants. Any
newborn with one or more CF-causing variants identified is referred for a follow-up with a sweat
chloride test as confirmatory testing. NGS data are reanalyzed for infants with sweat chloride greater
than 30 mmol/L and one CF-causing variant identified through a regular NBS screening protocol.
The NGS data reanalysis is performed by removing preset panel limitations and viewing all variants.
This practice allows the identification of the additional CF-causing variants that are not included in
the predefined panel and to identify infants with the CFTR-related metabolic syndrome, also known as
Cystic Fibrosis Screen Positive, Inconclusive Diagnosis, which requires medical attention [41]. Figure 1
illustrates the Wisconsin CF screening process.

In the literature, several NBS programs have proposed using NGS to survey the whole CFTR
gene as third-tier testing in CF NBS screening after the first-tier IRT analysis and second tier of single
F508del analysis or a panel of CFTR variants for the purpose of maximizing the opportunity to identify
two CF-causing variants in true CF screening positive cases [42,43]. A drawback of this approach is
that it also identifies CFTR variants with unknown clinical significance.



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Int. J. Neonatal Screen. 2020, 6, x FOR PEER REVIEW 7 of 12 

 
Figure 1. Wisconsin NBS for cystic fibrosis workflow. 

4. Targeted Gene Variant or Variants as “Just-in-Time” Information 

The third group of applications of molecular technologies in routine NBS is a targeted 
pathogenic gene variant analysis performed as a supplemental test after the biochemical or enzymatic 
test is completed and screening positive specimens have been determined. The “just-in-time” gene 
variant information is intended to help clinicians better interpret the biochemical or enzymatic testing 
results and be better prepared for their initial communication and discussion with families regarding 
NBS-positive results. Here we provide some examples from our NBS program to demonstrate the 
rationale and clinical utility of this practice. 

For example, “just-in-time” information can help distinguish between different subtypes of a 
disorder. In the Wisconsin NBS program, galactose-1-phosphate uridylyltransferase (GALT) enzyme 
activity is the primary marker for galactosemia screening. Specimens with low or absent GALT 
activity undergo a GALT gene panel analysis. DNA isolated from dried blood specimens undergoes 
PCR amplification. With the Tetra-primer ARMS–PCR, the internal control, wild-type allele, and 
variant allele can be amplified simultaneously in the PCR reaction and, because of the difference in 
amplicon length, can be distinguished by agarose gel electrophoresis [44]. The variant panel includes 
GALT c.563A > G (Gln188Arg), c.404C > T (Ser135Leu), and c.940A > G (Asn314Asp). The GALT 
c.563A > G homozygote is the most common genotype in classic galactosemia. The GALT compound 
heterozygote of c.563A > G and c.404C > T causes clinical variant galactosemia, and the compound 

Figure 1. Wisconsin NBS for cystic fibrosis workflow.

4. Targeted Gene Variant or Variants as “Just-In-Time” Information

The third group of applications of molecular technologies in routine NBS is a targeted pathogenic
gene variant analysis performed as a supplemental test after the biochemical or enzymatic test
is completed and screening positive specimens have been determined. The “just-in-time” gene
variant information is intended to help clinicians better interpret the biochemical or enzymatic testing
results and be better prepared for their initial communication and discussion with families regarding
NBS-positive results. Here we provide some examples from our NBS program to demonstrate
the rationale and clinical utility of this practice.

For example, “just-in-time” information can help distinguish between different subtypes of
a disorder. In the Wisconsin NBS program, galactose-1-phosphate uridylyltransferase (GALT) enzyme
activity is the primary marker for galactosemia screening. Specimens with low or absent GALT activity
undergo a GALT gene panel analysis. DNA isolated from dried blood specimens undergoes PCR
amplification. With the Tetra-primer ARMS–PCR, the internal control, wild-type allele, and variant
allele can be amplified simultaneously in the PCR reaction and, because of the difference in amplicon
length, can be distinguished by agarose gel electrophoresis [44]. The variant panel includes GALT
c.563A>G (Gln188Arg), c.404C>T (Ser135Leu), and c.940A>G (Asn314Asp). The GALT c.563A>G
homozygote is the most common genotype in classic galactosemia. The GALT compound heterozygote



Int. J. Neonatal Screen. 2020, 6, 80 8 of 12

of c.563A>G and c.404C>T causes clinical variant galactosemia, and the compound heterozygote
of c.563A>G and c.940A>G results in Duarte variant galactosemia, which might not need clinical
intervention [45].

For other disorders, “just-in-time” information can help identify the true disease status that
otherwise would be masked by medical intervention prior to the collection of the dried blood spot,
such as a blood transfusion. The primary screening method for sickle cell disease is a hemoglobin
fraction pattern on an isoelectric focusing gel. However, this pattern could be altered when an infant
receives a blood transfusion, and the hemoglobin fraction pattern for a newborn with sickle cell disease
could appear instead as a sickle cell disease carrier pattern. In the Wisconsin NBS program, specimens
collected after blood transfusion that present the sickle cell disease carrier pattern are subject to sickle
cell disease genetic testing. DNA isolated from dried blood specimens undergoes PCR amplification
with a pair of primers flanking the HBB gene variant c.20A>T region, which can be detected by
a targeted Sanger sequencing analysis. The homozygous HBB c.20A>T result indicates the presence of
sickle cell disease.

“Just-in-time” information can also be used to quickly detect genetic markers of disease in
high-risk groups when immediate intervention is critical. Although maple syrup urine disease (MSUD)
is rare with an incidence of 1 in 197,714 live births in the general population based on NBS data,
among North American Old Order Mennonites, severe (”classic”) MSUD affects as many as 1 in 400
births due to a founder variant of BCKDHA (c.1312T>A, p.Tyr438Asn) [46,47]. Classic MSUD can
present metabolic encephalopathy and critical brain edema within the first 24 to 48 hours of life. In
order to identify newborns with classic MSUD in the Wisconsin Mennonite communities as early as
possible, a dried blood specimen is collected one hour after birth, the specimen is delivered to the NBS
laboratory by a family-arranged driver, and the laboratory runs the BCKDHA c.1312T>A assay based
on the Tetra-primer ARMS–PCR immediately upon receiving the specimen. The testing results can be
obtained as early as 10 h after birth. Another NBS specimen is collected between 24 and 48 hours after
birth for routine NBS, including screening for MSUD using primary markers of leucine and isoleucine
by mass spectrometry.

Finally, in the Wisconsin Pompe NBS pilot project, acid alpha-glucosidase (GAA) enzyme activity
in dried blood spots is used as a primary screening tool. Specimens with GAA activity lower than 10%
of the daily median are deemed as screening positive and undergo a GAA gene variant analysis. DNA
isolated from dried blood specimens undergoes PCR amplification with primers flanking all GAA
gene coding areas, and the GAA variant is detected by a Sanger sequencing analysis with the GAA
variant database managed by Erasmus MC University Medical Center serving as a main reference for
the pathogenicity assessment [48]. From 14 July 2017 to 31 March 2019, a total of 108,862 infants were
screened with 13 infants screening positive based on GAA enzyme activities. Two pathogenic GAA
variants were identified among these 13 infants screening positive, indicating late-onset Pompe disease.
Genetic variant information in NBS for Pompe disease can help to determine variant-phenotype and
genotype–phenotype correlations [49]. When performing the whole gene sequencing, it is possible to
encounter gene variants with unknown significance, which need to be described in the report.

5. Discussion

We have described current applications of molecular technologies in routine NBS practice with
the intention of illustrating their uses and assay principles. The NBS conditions presented here are
examples and by no means an exhaustive list. Furthermore, some routinely used NBS practices
involving molecular techniques might not have been reported in the literature at the time of this review.
Molecular technologies will likely continue to play an important role in future NBS conditions, such as
first-tier real-time assays for congenital cytomegalovirus infection [50,51], and the CF NBS two-tiered
testing approach might be applicable to NBS for Duchenne muscular dystrophy [52,53]. Additionally,
it is probable there will be increased desire to incorporate more complicated molecular or genetic
assays in routine NBS—for example, whole exome or genome sequencing. These developments call



Int. J. Neonatal Screen. 2020, 6, 80 9 of 12

for further considerations and a discussion of the many implications of technological advances in
NBS, including their clinical utility, feasibility, bioinformatics support, interpretation and reporting of
results, unintended findings and consequences, turn-around time, cost-benefit and effectiveness, and
implications for data storage.

Author Contributions: Conceptualization: M.W.B., M.S.D., S.M.F.; literature search: S.M.F., M.W.B.; data curation:
M.W.B.; writing-original draft preparation: S.M.F., M.W.B.; writing-review and editing: S.M.F., M.S.D., M.W.B.;
supervision: M.S.D. and M.W.B., All authors have read and agreed to the published version of the manuscript.

Funding: This project received no external funding.

Acknowledgments: We would like to acknowledge the staff members who have carried out all molecular testing
at the Wisconsin State Laboratory of Hygiene: Sean Mochal Michael Cogley; Amy Wiberley-Bradford; Bethany
Zeitler, and Zachary Piro.

Conflicts of Interest: The authors declare no conflict of interest.

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	Introduction 
	Molecular Marker Identification as Primary Screening Methods in NBS for Severe Combined Immunodeficiency (SCID) and Spinal Muscular Atrophy (SMA) 
	Targeted Gene Variant Panel as Second-Tier Testing 
	Targeted Gene Variant or Variants as “Just-In-Time” Information 
	Discussion 
	References