Anne Maddalena

Longitudinal study of cognitive abilities and adaptive behavior levels in fragile X males: A prospective multicenter analysis

Retrospective longitudinal studies have noted declines in IQ scores in many but not all fra(X) (fragile X) males and females. We report on a prospective investigation of longitudinal changes in cognitive ability (IQ) and adaptive behavior (DQ) in 24 fra(X) males from four test sites. Individuals who were tested ranged in age from 3-15 years. To determine cognitive ability, all males were administered the Stanford-Binet test (4th Edition). To assess adaptive behavior, all males were evaluated using the Vineland Adaptive Behavior Scales. Mean interest interval was 2.3 years. Using identical DNA protocols, all subjects were identified as bearing the fra(X) mutation. Results showed declines in IQ scores in 18/24 (75%) males. Four males showed no change in scores. Declines in DQ scores were noted in 22/24 (92%) of those tested. DQ scores were higher than IQ scores in 20/24 (83%) subjects. From a descriptive cohort analysis, decreases in IQ scores appear to follow a well-defined, negatively decelerating function. Declines in DQ were steeper and more nearly linear. Declining scores are not indicative of regression of intellectual and/or social skills, but of a relative inability to keep pace with their age-normed cohort. We conclude that the fra(X) mutation affects cognitive abilities in a uniform, nonlinear manner comparable to outcomes observed in earlier retrospective studies. Adaptive behavior also declines, but in a more linear fashion.

Molecular fragile X screening in normal populations

In December, 1993, we initiated a pilot project in which DNA fragile X (fraX) testing was offered during routine prenatal or genetic counseling to all pregnant women seen at the Genetics & IVF Institute, most of whom were referred for the indication of advanced maternal age. A brochure on fragile X syndrome was sent to each patient prior to her appointment and was reviewed by a counselor or physician during the counseling session. As of June 1995, 3,345 patients were offered testing; 474 women with no identified family history of mental retardation or learning disability and 214 women with a positive family history accepted the test on a self-pay basis. The second population screened was 271 potential donors in our anonymous egg donor program. DNA from blood was tested by Southern blot using EcoRI/EagI and StB12.3. If an expansion was detected, CGG repeat number was determined by PCR-based analysis. Among the 474 patients with unremarkable family histories, three fraX carriers were identified (repeat sizes = 60+), whereas none were found in the 214 patients with a positive family history. Among the potential egg donors, two high borderline patients were identified (repeat sizes = between 50 and 59). Our ongoing study indicates that screening of pregnant or preconceptual populations for fraX carrier status using DNA testing is accepted by many patients and is an important addition to current medical practice.

Longitudinal assessment of adaptive and maladaptive behaviors in fragile X males: Growth, development, and profiles

As young fully mutated fragile X [fra(X)] males age, cognitive levels (IQ scores) and adaptive behavior levels (DQ scores) decline. Given the variable behavioral profiles reported previously, we wondered whether changes in specific attributes of adaptive behavior are related to declines in composite adaptive behavior levels. We also examined maladaptive behavior to determine if changes are related to age. Therefore, we evaluated three areas of adaptive behavior, as well as maladaptive behavior, in 28 fully mutated fra(X) males, ages 4-14 years. To develop a profile of adaptive behavior, we analyzed nine subscale scores from the Vine-land Adaptive Behavior Scale (VABS). To assess maladaptive behavior, we graded part I of the VABS Maladaptive Behavior Scale. Subjects were sorted into three age cohorts, according to their initial test age: younger than 6 years; 6 to 9 years; older than 9 years. Results indicate that, in all age groups, the communications domain is the most severely impacted compared with either the socialization domain or daily living skills and that, in all age groups, the socialization domain is a relative strength compared with either the communications domain or daily living skills. The youngest cohort manifested significant increases in age-equivalent community living skills. Significant differences in age-equivalent scores between cohorts were observed in written language and play skills. Maladaptive behavior scores were available from cross-sectional data only. Twenty males (74%) showed significantly higher maladaptive scores than expected from other children their age. Our data analysis also revealed a moderate and significant negative correlation between maladaptive behavior levels and age (r = -0.54; P < 0.01). Curiously, adaptive and maladaptive behaviors did not correlate with each other.

A fragile X mosaic male with a cryptic full mutation detected in epithelium but not in blood.

Individuals with developmental delay who are found to have only fragile X premutations present an interpretive dilemma. The presence of the premutation could be an unrelated coincidence, or it could be a sign of mosaicism involving a full mutation in other tissues. To investigate three cases of this type, buccal epithelium was collected on cytology brushes for Southern blot analysis. In one notable case, the blood specimen of a boy with developmental delay was found to have a premutation of 0.1 extra kb, which was shown by PCR to be an allele of 60 +/- 3 repeats. There was no trace of a full mutation. Mosaicism was investigated as an explanation for his developmental delay, although the condition was confounded by prematurity and other factors. The cheek epithelium DNA was found to contain the premutation, plus a methylated full mutation with expansions of 0.9 and 1.5 extra kb. The three populations were nearly equal in frequency but the 1.5 kb expansion was the most prominent. Regardless of whether this patient has clinical signs of fragile X syndrome, he illustrates that there can be gross tissue-specific differences in molecular sub-populations in mosaic individuals. Because brain and epithelium are more closely related embryonically than are brain and blood, cryptic full mutations in affected individuals may be evident in epithelial cells while being absent or difficult to detect in blood. This phenomenon may explain some atypical cases of the fragile X phenotype associated with premutations or near-normal DNA findings.

Lack of association between mutation size and cognitive/behavior deficits in fragile X males: A brief report

Previously, researchers reported molecular-neurobehavioral or molecular-cognitive associations in individuals with fra(X) (fragile X) mutation. However, not all investigators have noted molecular-behavioral relationships. Consequently, we examined prospectively 30 fra(X) males age 3-15 years from four testing sites to determine whether there was a relationship between mutation size and degree of either cognitive or adaptive behavior deficit. To measure cognitive abilities, all individuals were administered the Stanford-Binet (4th edition) IQ test. To evaluate adaptive behavior (DQ) skills, all individuals were assessed using the Vineland Adaptive Behavior Scale. To determine fra(X) status, genomic DNA from all individuals was extracted and digested with EcoRI and EagI restriction enzymes. Southern blots were prepared and hybridized with the pE5.1 probe. The Pearson correlation coefficient between full mutation size and composite IQ score revealed a nonsignificant, near-zero association (r = 0.06; P > .76). The Pearson coefficient between mutation size and DQ also showed a nonsignificant, near-zero association (r = 0.06; P > .73). We conclude that while fra(X) mutation produces cognitive and behavior deficits in males who inherit the defective gene, there is no relationship between mutation size and degree of deficit.

CONTRIBUTION OF THE MOLECULAR GENETICS LABORATORY TO THE EVALUATION OF THE PERSISTENTLY HYPOTONIC INFANT. † 872

Pediatricians may be requested to elucidate the cause of nonspecific persistent generalized infantile hypotonia. Among the many causes in the differential diagnosis of a floppy baby are several familiar genetic diseases that can present with generalized hypotonia in the newborn period. Testing for these disorders, spinal muscular atrophy (SMA), myotonic dystrophy (DM) and Prader-Willi Syndrome (PWS), now requires only a small amount of peripheral blood, and positive results are diagnostic for that disease. The tests for SMA, DM, and recently PWS are done by DNA analysis to look for gene deletions(SMA), expansions (DM), or the absence of the paternal copy of chromosome 15(PWS). Previous analysis for PWS, including this study, has been done by chromosome fluorescence in-situ hybridization to look for deletions in the PWS region of chromosome 15. This technique can detect approximately 70% of those with PWS. Screening of 35 persistently hypotonic children for one or more of these three disorders revealed 7 positive results, 2 with DM, 1 with SMA and 4 with PWS, for a detection rate of 20%. In addition, in 8 of 8 cases in which a clinical diagnosis of SMA had been made, DNA analysis was used to confirm the diagnosis, aid in interpretation of prenatal results in subsequent pregnancies, or provide a conclusive diagnosis, without the need for a muscle biopsy. Positive findings for one of these genetic diseases can provide valuable information regarding clinical management and prognosis of the child, allow specific prenatal testing in future pregnancies and could lead to the identification of other at-risk relatives. Twenty per cent of hypotonic infants were found with one of these three genetic disorders, illustrating the significance of considering this panel of diseases in an infant presenting for genetic evaluation with nonspecific hypotonia.