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Genotyping Is a Valuable Diagnostic Complement to Neonatal Screening for Congenital Adrenal Hyperplasia due to Steroid 21-Hydroxylase Deficiency¹

Department of Pediatrics (A.N., A.L.) and PKU Screening Laboratory (A.N., L.H.A.L.), Huddinge University Hospital, Karolinska Institute, S-141 86 Huddinge, Sweden; the Department of Pediatrics, Ryhov (A.T.), S-551 85 Jökoping, Sweden; and the Department of Molecular Medicine, CMM:02, Karolinska Hospital (A.W.), S-171 76 Stockholm, Sweden

Address all correspondence and requests for reprints to: Anna Nordenström, M.D., Department of Pediatrics, Huddinge University Hospital, Karolinska Institute, S-141 86 Huddinge, Sweden.

	Abstract

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To evaluate genotyping as a diagnostic complement to neonatal screening for congenital adrenal hyperplasia, 91 children who had been diagnosed with this condition between 1986 and 1997 were analyzed for mutations in the steroid 21-hydroxylase gene. Screening levels of 17-hydroxyprogesterone were compared in patients representing different genotypes. Genotyping was performed using allele-specific PCR, the patients were divided into four groups according to the severity of their mutations, and screening results were compared between these groups as well as with 141 values representing false positive samples. The screening levels of 17-hydroxyprogesterone were significantly different in the five groups of samples. Values above 500 nmol/L were clearly associated with the most severe genotypes, whereas conclusions concerning disease severity could not be drawn from individual samples representing lower levels. For example, values around 150–200 nmol/L could be seen in children with all degrees of disease severity and could also constitute false positive samples. We conclude that genotyping is a valuable diagnostic tool and a good complement to neonatal screening, especially in confirming or discarding the diagnosis in cases with slightly elevated 17-hydroxyprogesterone levels. An additional benefit is that it provides information on disease severity, which reduces the risk of overtreatment of mildly affected children.

	Introduction

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CONGENITAL adrenal hyperplasia (CAH) is a group of inherited disorders caused by a deficiency in one of the enzymes necessary for the synthesis of cortisol in the adrenal cortex. More than 95% of all cases of CAH are due to 21-hydroxylase deficiency (21-OHD) (1, 2). This enzyme deficiency results in a reduced ability to synthesize cortisol and aldosterone. Reduced levels of cortisol lead to increased secretion of ACTH from the pituitary, which causes hyperplasia of the adrenals and an increase in steroid precursors that are shunted into the androgen-synthesizing pathway resulting in oversecretion of androgens.

The syndrome comprises a very wide spectrum of severity (1). The most severe form, with complete absence of 21-hydroxylase function, leads to acute circulatory collapse, usually during the first weeks of life. This salt-wasting (SW) crisis is due to a severe lack of mineralocorticoid, which causes loss of sodium in the kidney. Children with the SW form of the disease are exposed to excessive androgen levels during embryogenesis. The girls present with virilization of the external genitalia, i.e. clitoromegaly, fusion of the labia majora, and a common urethral and vaginal opening. A slightly less severe form of 21-OHD, with prenatal virilization but without life-threatening salt loss, is usually referred to as the simple virilizing (SV) form of CAH. Finally, milder forms of 21-OHD are associated with slightly elevated androgen levels, which are not sufficient to cause prenatal genital malformations. These forms of the disease may present as precocious pseudopuberty or growth acceleration in childhood or may cause menstrual disturbances, hirsutism, and infertility in adult women. They are often referred to as nonclassical (NC) CAH.

CAH due to 21-OHD is inherited as an autosomal recessive trait, and the molecular genetics of the disorder has been studied extensively. The 21-hydroxylase gene (CYP21) is located on the short arm of chromosome 6, between the human leukocyte antigen class I and class II gene clusters, in tandem with a highly homologous pseudogene (CYP21P) (3, 4). This genomic structure predisposes to misalignment during meiosis, which may result in recombination events between the CYP21 and CYP21P genes. This can lead to deletion of CYP21 as well as to an exchange of sequences between the two genes (5, 6). Deletion of CYP21 together with nine smaller, pseudogene-derived sequence aberrations are responsible for around 95% of all affected Scandinavian CYP21 alleles (7) and are also responsible for the majority of CAH patients in other ethnic groups (8, 9, 10, 11). The remaining 5% of cases are due to rare, mostly population-specific mutations. In Scandinavia, we have identified 12 such rare mutations to date. Five are nonsense, splice, or frameshift mutations and have therefore not been assayed functionally in vitro (12, 13, 14). Seven are missense mutations that have displayed variable degrees of impaired enzyme function after expression in cultured cells (15, 16, 17).

We have found clear relationships between clinical disease severity and the CYP21 mutations (7). In short, one group of mutations completely inactivates the gene and is referred to as Null mutations. Homozygosity or compound heterozygosity for any of these mutations is associated with the most severe form of CAH, with salt loss and prenatal virilization of external genitalia in females. The I2 splice mutation can be regarded as slightly less severe. It is associated with severe prenatal virilization in females, but a small number of children with this mutation have escaped salt loss. The Ile¹⁷²Asn mutation is associated with the simple virilizing phenotype, although around 10% of cases with Ile¹⁷²Asn develop salt-wasting symptoms, and the degree of virilization can vary. Finally, the Val²⁸¹Leu mutation has in our experience not been found in any patient with virilized genitalia. Instead, it is associated with mild, late-onset symptoms. In conclusion, we find genotyping of CYP21 mutations to be very useful for the prediction of clinical outcome in CAH patients. Similar experiences were reported previously (11), whereas others have concluded that the phenotype is not always concordant with the genotype (10).

Neonatal screening for CAH started on a national basis in Sweden in 1986 (18). Elevated levels of 17-hydroxyprogesterone (17-OHP) are used as an indicator of the disease (19, 20). By the end of 1997, more than 1.3 million Swedish children had been screened. The prevalence of CAH among these subjects was 1 in 9800, and 85% of the patients had the SW form of the disease (21). No children with other causes of CAH, such as 3ß-hydroxysteroid or 11ß-hydroxylase deficiency, were diagnosed during these years.

There are several obvious advantages of neonatal screening for CAH, such as earlier diagnosis, avoidance of salt crises, and an earlier correct gender assignment (22, 21). At the same time, however, it has raised a few novel questions, such as how to interpret a neonatal 17-OHP screening value in terms of disease severity. In particular, we have seen a tendency for overtreatment of mildly affected cases that have been diagnosed neonatally through screening. This is a risk when treatment is initiated before symptoms have had time to develop and, thus, the disease severity is not clinically assessed. On the other hand, it is one of the benefits of screening that salt loss and its potentially harmful effects on central nervous system development can be avoided. To evaluate genotyping as a diagnostic complement to the neonatal screening for CAH, we have compared CYP21 genotypes and neonatal screening values of 17-OHP for 91 Swedish patients diagnosed with CAH between the years 1986 and 1997. Comparisons were also made to screening values of 17-OHP for 141 false positive cases.

	Subjects and Methods

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Neonatal screening for CAH

17-OHP was analyzed in filter paper blood spots collected on day 3, 4, or 5 after birth using RIA (1986–1990) or fluoroimmunoassay (1991–1997) (Delphia, Wallac, Finland) (19, 18). The cut-off limit for a positive test has gradually been lowered from 200 nmol/L in 1986 to 150 nmol/L in 1988, and, since 1991, it has been defined as 75 nmol/L plasma (assuming a hematocrit of 50%) for full-term infants. For infants born before the 37th week of gestation, a cut-off limit of 200 nmol/L after ether extraction was used. Recall was on the eighth day of life (median) (21). A second filter paper sample was requested for all cases with a positive screening value. The second sample was usually analyzed about 1 week after the first screening sample. Children in whom 17-OHP levels had decreased convincingly in the second sample (>20%) and/or in whom subsequent clinical examination excluded CAH were defined as false positive cases.

CYP21 genotyping

CYP21 mutation analysis was carried out using allele-specific PCR from genomic DNA prepared from venous blood samples (13). This detects the 95% of alleles that carry any of the common pseudogene-derived mutations. Additional rare alleles were characterized by direct DNA sequencing (12). Genotypes were divided into four groups depending on the mildest mutation: Null, I2 splice, Ile¹⁷²Asn, and Val²⁸¹Leu.

Statistical analysis

The Kruskal-Wallis test, paired t test, Mann-Whitney U ranking sum test, and the SPSS computer program (SPSS, Inc., Chicago IL) were used in the statistical analysis.

	Results

Top Abstract Introduction Subjects and Methods Results Discussion References

 
A total of 114 children were diagnosed with CAH in Sweden during 1986–1997. CYP21 mutation analysis was performed for 107 of these children. Only 2 patients had the Pro³⁰Leu mutation, 1 had the unique Gly²⁹¹Ser mutation, and 2 had combinations of more than 1 partially inactivating mutation in the same allele (Ile¹⁷²Asn+Pro⁴⁵³Ser and I2 splice+Ile¹⁷²Asn). These patients were not included in the statistical analyses. Four infants were excluded because of prematurity (<37 weeks gestation), and 2 patients had their screening samples taken on day 1 after birth and therefore were not included. Five girls who had been diagnosed prenatally and treated with dexamethasone in utero until term were also excluded.

The genotypes of the remaining 91 full-term infants who were diagnosed with CAH are summarized in Table 1. The Null genotype group consisted of 22 infants. The I2 splice group comprised 26, and the Ile¹⁷²Asn group consisted of 30 infants. Thirteen infants belonged to the mildest genotype group, represented by the Val²⁸¹Leu mutation. A second sample was obtained before steroid treatment was initiated for 19 infants in the Ile¹⁷²Asn group and 6 in the Val²⁸¹Leu group. The second sample was obtained at about 8–12 days of age.

The 17-OHP screening values for the CAH children ranged from 41–1371 nmol/L plasma. Screening values of 17-OHP were significantly different among the three genotype groups, Null, I2 splice, and Ile¹⁷²Asn+Val²⁸¹Leu (P < 0.05; Fig. 1). The two mildest groups did not differ from each other, but were different from the false positive group. Therefore, 17-OHP values representing the second sample, from the recall filter papers, were compared among the Ile¹⁷²Asn, Val²⁸¹Leu, and false positive groups (Fig. 2). The groups representing the Ile¹⁷²Asn and Val²⁸¹Leu mutations were then significantly different from each other (P < 0.05) as well as from the false positive group.

View larger version (17K): [in this window] [in a new window]   Figure 1. Neonatal screening values of 17-OHP in relation to the CYP21 genotype group. Screening values of false positive cases are also included. The box plots show median values together with the 10th, 25th, 75th, and 90th percentiles. In addition, maximum and minimum values in each group are indicated by circles. The cut-off limit for a positive test (75 nmol/L) is indicated by the dashed line. The four groups, Null, I2 splice, Ile172Asn+Val281Leu, and false positive, were significantly different from each other (P < 0.05, by Kruskal-Wallis test and Mann-Whitney U ranking sum test).

View larger version (15K): [in this window] [in a new window]   Figure 2. Neonatal screening values of 17-OHP, second sample, in relation to CYP21 genotype groups Ile172Asn and Val281Leu. Screening values of false positive cases are also included. The box plots show median values together with the 10th, 25th, 75th, and 90th percentiles. In addition, maximum and minimum values in each group are indicated by circles. The cut-off limit for a positive test (75 nmol/L) is indicated by the dashed line. The three groups were significantly different from each other (P < 0.05, by Kruskal-Wallis test and Mann-Whitney U ranking sum test).

As a rule, the full-term infants with false positive screening tests had only moderately elevated 17-OHP levels, in the same range as those in patients with genotypes associated with the SV or NC forms of the disease (Fig. 1). Among the children with false positive tests, there were 2 infants for whom the second sample showed an increased 17-OHP level compared to the first (97 to 154 and 104 to 175 nmol/L) and 4 who had unchanged levels in the second sample. In 3 of these 6 cases, including the 2 with increased values, CYP21 mutations were excluded by genotyping. In an additional 7 infants, the 17-OHP value did not decrease convincingly. Thus, in 10.3% of the false positive cases (13 of 126), the second sample was not conclusive. A relatively large group of these infants (45%) was born in gestational week 37. This is in keeping with the fact that immature infants have higher levels of 17-OHP in the screening. The symptoms of these children are not known to the screening laboratory in any great detail. However, a large proportion of these children seem to have been under perinatal stress, e.g. they had respiratory distress, intracranial hemorrhage, sepsis, or cardiac malformation with cardiac failure.

The genotypes of six children diagnosed with CAH between 1988 and 1997 despite negative screening values were also determined and compared to their neonatal 17-OHP screening values (Table 2). Four of these children with false negative screening tests had genotypes associated with the mildest form of CAH (mutation Val²⁸¹Leu). None of these had any symptoms from birth. One boy had the Pro³⁰Leu mutation. He was diagnosed neonatally because his elder sister was known to be affected with CAH. The sister, who was born before the neonatal screening program was initiated, was detected due to growth acceleration, premature pubarche, and modest clitoral enlargement at 3.8 yr of age. The Pro³⁰Leu mutation is known to be associated with nonclassical CAH, but it usually produces somewhat more symptoms, including slight clitoromegaly, compared to the Val²⁸¹Leu mutation (24). One girl had the Ile¹⁷²Asn mutation, which is associated with the simple virilizing form of CAH. When she was diagnosed at 2.5 yr of age, signs of prenatal virilization were found (clitoromegaly and moderate labial fusion). These malformations, which had been missed neonatally, were subsequently surgically corrected. Thus, the severity of symptoms of the false negative children at diagnosis was in conformity with their genotypes.

	Discussion

Top Abstract Introduction Subjects and Methods Results Discussion References

One consequence of introducing neonatal screening for CAH that must be considered is the fact that patients who would otherwise be diagnosed due to late-onset symptoms will now be identified from birth. It cannot be taken for granted that these patients will only benefit from being treated from this early age, before the onset of symptoms. In fact, we have seen a tendency for overtreatment of these mildly affected cases from birth because the degree of disease severity has not been clear. Verifying a mild genotype (e.g. the Val²⁸¹Leu mutation) means that the risk of salt loss is extremely low. In addition, there have been observations indicating that early growth may not be increased in these patients until after 18 months of age (25). Thus, with careful clinical monitoring, including measurements of bone age, height, growth velocity, and steroid levels, glucocorticoid replacement therapy can be kept to a minimum in children in whom the mildest mutations are identified. In addition to these somatic examinations, however, it may also be important to consider possible influences of excess steroid hormones on behavior (26).

The three genotype groups, Null, I2 splice, and Ile¹⁷²Asn+Val²⁸¹Leu, were already significantly different from each other in the first screening sample (days 3–5). The Ile¹⁷²Asn and Val²⁸¹Leu groups could clearly be separated by the second measurement, which was obtained around days 8–12. Thus, a more obvious increase in 17-OHP evolves over time in the moderate Ile¹⁷²Asn group compared to the milder Val²⁸¹Leu group. Increasing 17-OHP values with time was also seen in the screening program in Texas, where two screening samples were taken routinely. A relatively large proportion of patients affected by milder forms of CAH was identified with the second sample, which was obtained at 2 weeks of age (27).

We also compared 17-OHP levels after subdividing the patients according to the different genotypes within the four major groups, i.e. we compared individuals who were homozygous and hemizygous for the mutations. Hemizygosity (I2 splice/Null: median, 746 nmol/L; Ile¹⁷²Asn/Null: median, 222 nmol/L) was associated with higher screening values than homozygosity (I2 splice/I2 splice: median, 710 nmol/L; Ile¹⁷²Asn/Ile¹⁷²Asn, median, 152 nmol/L), indicating a gene dosage effect. These differences were not statistically significant, however.

The relatively large interindividual spread in screening values is not surprising, as it is well known that individual 17-OHP values are affected by factors such as concurrent illness and stress. One patient in the I2 splice/Null subgroup was delivered by elective cesarean section because he was in the breech position. This patient had the lowest 17-OHP screening value within his subgroup (186 nmol/L). This is not surprising because it has been reported that early corticosteriod levels are influenced by birth conditions (28).

The patients who had the Pro³⁰Leu mutation, which is known to be associated with nonclassical CAH (24), were not included in our calculations because only two cases were found with genotypes including this mutation. These two patients were both males, both had a Pro³⁰Leu/Null genotype, and both were born in 1991. Their screening values were considerably different from each other; one had a value of 41 nmol/L and was thus a false negative case (Table 2), whereas the other one had a value of 419 nmol/L. We have previously found that some patients with Pro³⁰Leu have gene conversions in their promoter, changing CYP21 sequences into pseudogene-derived sequences, whereas others retain the CYP21 promoter (unpublished). As the CYP21P promoter is known to be partially active compared to that of CYP21 (29), patients with Pro³⁰Leu in combination with the promoter mutation can be expected to be more severely affected than those with Pro³⁰Leu alone. However, we sequenced the CYP21 genes of the two boys who had Pro³⁰Leu up to 800 bases upstream of translation initiation. Both patients had the CYP21P promoter in the CYP21 allele that carried Pro³⁰Leu, i.e. the complete 5'-parts of CYP21 were converted into CYP21P in both cases. Thus, we could not find any explanation for the large difference in their screening values.

For 13 infants with positive screening samples who were later shown to be unaffected, i.e. in 10.3% of the false positive cases, the second screening sample was inconclusive. As CYP21 genotyping identifies 95% of all alleles causing CAH, and the majority of the remaining 5% are Null mutations, mutation analysis is a reliable as well as rapid way of discarding or verifying the diagnosis of CAH in these cases. It is important to shorten the time of uncertainty as much as possible to minimize the negative psychological effects on the family of a false positive screening result (30).

In Sweden, genotyping is performed for most, if not all, children in whom positive screening samples of 17-OHP are found. We find this to be an ideal diagnostic complement, both in providing prognostic information on the degree of disease severity as well as in discriminating against false positive cases. However, as shown in Table 2, some patients with mild and even moderate forms of the disease will invariably escape diagnosis in the screening unless it is designed to produce unacceptable numbers of false positive results. Obviously, the well-being of these children will continue to be dependent on the perceptiveness of clinicians who are skilled at identifying symptoms and signs of androgen excess.

	Acknowledgments

 
We thank Nils Larsson for advice on the statistical analyses.

	Footnotes

 
¹ This work was supported by the Swedish Medical Research Council (Projects 12198 and 4792); the Fredrik and Ingrid Thuring, Harald and Greta Jeansson, Novo Nordisk, Magnus Bergvall, and Sven Jerring Foundations; and the Ronald McDonald Pediatric Fund.

Received September 1, 1998.

Revised January 13, 1999.

Accepted January 25, 1999.

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