Genetic and maternal predictors of cognitive and behavioral trajectories in females with fragile X syndrome

Families were recruited for this research through newspaper advertisements, nationwide radio announcements, and a university registry of families with children who have developmental disabilities, as well as through postings on internet sites, listservs, and newsletters of developmental disability organizations. Prior to being enrolled in the study, parents of all participants signed informed consent forms approved by Institutional Review Boards at the University of Wisconsin–Madison and the New York State Institute for Basic Research. Trained examiners (graduate students in communication disorders, education or a related field) completed all testing in a quiet testing room at the University of Wisconsin–Madison. As needed, participants were provided breaks within sessions and between sessions, with the entire protocol at any annual assessment typically being administered over two consecutive days. In general, the same examiner administered all assessments to any given participant at every annual assessment. Additionally, the scoring of all test protocols was checked by two examiners and all data entry was double-checked by two research assistants. The participants and measures reported on this project are a subset of those previously collected from a larger study (R01HD024356), with several previous reports on the study being published (see [27, 36‐38]), although none with the specific focus and measures of the present study.

Participants were 16 females with FXS who were assessed at an initial visit and at 1-year intervals over the course of 3 years. Females ranged in age from 10.2 to 15.6 years (M = 12; SD = 1.5) at the time of enrollment and from 13.2 to 18.6 years (M = 15; SD = 1.5) at the end of the study. All were previously diagnosed by an appropriate molecular genetic test as having more than 200 CGG repeats in the FMR1 gene in at least some cells, with documentation of testing provided by the mother at enrollment. During the course of the project, additional analyses were conducted on peripheral blood to confirm the diagnosis and to derive measures of ratio of affected to total chromosomes and FMRP. For all participants, the mother reported that her daughter (a) used speech as the primary means of communication, (b) regularly communicated with three-word or longer phrases, (c) functioned at a kindergarten level or above in most areas, and (d) had no (uncorrected) sensory or physical impairments that would limit performance in this project. All the participants and their mothers were native English speakers. In all cases, all mothers were the biological mother of the participants with FXS and thus, the mothers were necessarily carriers of an expanded FMR1 gene.

The participants in this study as well as one of the predictors (FMRP level) and one of the dependent variables (fluid intelligence) were the same as in the study by Kover et al. [27]. However, in the current study, we have expanded the set of dependent variables (added a verbal measure of crystallized ability, as well as anxiety and withdrawn behavior measures), and added new predictors (i.e., ratio of affected to total chromosomes maternal psychological distress, and maternal perceived closeness in the mother–child relationship) as described in the sections below.

We considered a set of genetic and environmental potential predictors, each of which was assessed at the initial visit unless otherwise noted.

The following neuropsychological assessments were administered four times (once annually since enrollment and during the next 3 years).

Repeated measures and random effects models were used to assess change over time in fluid intelligence, crystallized intelligence, and behavioral problems as well as to assess how the biological and maternal-related environmental variables were associated with level (initial visit) and change over time in these variables. The dependent variables used were children’s fluid intelligence (either standard or raw score), children’s crystallized intelligence (either standard or raw score), and CBCL anxiety T-score and CBCL withdrawn T-score. The independent variables were (1) level of FMRP expression or ratio of affected to total chromosomes as the biological factor and (2) mother’s perception of the child’s reciprocated closeness on the PAI or maternal psychological distress on the SCL-90-R, as the maternal-related environmental factor. For each outcome, we first assessed whether there was any estimated average change over time. Independent variables were all standardized by subtracting the mean and dividing by the standard deviation. Each independent variable was included in a model as a single predictor of the absolute level, and the level of change in the outcome. No joint model including multiple independent variables was fit due to the small sample size. Age at the baseline visit was considered as a potential confounder and included in all models as both a predictor of level and change over time. Random intercepts were included in all models to account for between-person variability in overall starting place. When supported by the data, random slopes were also included to account for between-person variability in change. Robust sandwich estimators were used for standard error estimation due to the small sample sizes. All analyses were conducted in SAS version 9.4, with a p value less than 0.05 considered statistically significant.

Sociodemographic data are presented in Table 1. Descriptive data at all times of assessment are presented in Table 2.

Standard scores for fluid intelligence and for crystallized intelligence at the baseline visit were both linked to the SCL-90-R GSI T score (β = − 8.6, SE = 2.2, p < 0.001; β = − 13.2, SE = 2.7, p < 0.001) and Child-PAI score (β = 6.7, SE = 2.8, p = 0.02; β = 8.8, SE = 2.7, p = 0.002). In addition, the ratio of affected to total chromosomes was associated with fluid intelligence standard scores (β = − 7.9, SE = 2.1, p < 0.001). All data are presented in Table 3. Fluid and crystallized intelligence standard scores did not change significantly over time (β = − 0.63, SE = 0.63, p = 0.32; β = 0.48, SE = 0.51, p = 0.34).

Fluid intelligence and crystallized intelligence raw scores increased by 2.0 points (β = 2.0, SE = 0.7, p = 0.02) and 5.2 points (β = 5.2, SE = 0.6, p < 0.001), respectively, on average per visit. Gains in fluid intelligence raw scores over time were predicted only by biological factors—such that a higher ratio of affected to total chromosomes was associated with a slower rate of improvement in fluid intelligence raw scores (β = − 1.5, SE = 0.6, p = 0.02) (see Fig. 1) and a higher level of FMRP was associated with a greater increase over time in fluid intelligence raw scores (β = 1.2, SE = 0.4, p = 0.01) (see Fig. 2). Gains over time in crystallized intelligence raw scores were not predicted by either biological or maternal variables (p > 0.05). All data are presented in Table 3.

In terms of genetic predictors, the ratio of affected to total chromosomes, but not FMRP level, was associated with level of withdrawal (β = 6.9, SE = 1.7, p < 0.001) and anxious/depressed (β = 5.5, SE = 1.9, p = 0.006) behaviors at baseline. In terms of environmental variables, Child-PAI score (β = − 8.1, SE = 1.7, p < 0.001) and SCL-90-R GSI T score (β = 5.2, SE = 2.2, p = 0.02) were each associated with the level of withdrawal behaviors, such that a higher Child-PAI score was associated with a lower CBCL Withdrawn T Score, and higher SCL-90-R GSI T score was associated with a higher CBCL Withdrawn T Score. Finally, there was a trend for higher child-PAI scores to be associated with lower CBCL Anxious/Depressed T Score (β = − 4.0, SE = 2.0, p = 0.053). All data are presented in Table 3.

CBCL Withdrawn and Anxious/Depressed T scores were both stable over time (β = − 0.28, SE = 0.75, p = 0.72; β = − 0.53, SE = 0.67, p = 0.44). Thus, there was no need to evaluate predictors of change. All data are presented in Table 3.