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Non-replication of the association between 5HTTLPR and response to psychological therapy for child anxiety disorders

Published online by Cambridge University Press:  02 January 2018

Kathryn J. Lester
Affiliation:
School of Psychology, University of Sussex, and King's College London, MRC Social, Genetic and Developmental Psychiatry (SGDP) Centre, Institute of Psychiatry, Psychology and Neuroscience, London, UK
Susanna Roberts
Affiliation:
King's College London, MRC Social, Genetic and Developmental Psychiatry (SGDP) Centre, Institute of Psychiatry, Psychology and Neuroscience, London, UK
Robert Keers
Affiliation:
King's College London, MRC Social, Genetic and Developmental Psychiatry (SGDP) Centre, Institute of Psychiatry, Psychology and Neuroscience, London, UK
Jonathan R. I. Coleman
Affiliation:
King's College London, MRC Social, Genetic and Developmental Psychiatry (SGDP) Centre, Institute of Psychiatry, Psychology and Neuroscience, London, UK
Gerome Breen
Affiliation:
King's College London, MRC Social, Genetic and Developmental Psychiatry (SGDP) Centre, Institute of Psychiatry, Psychology and Neuroscience, London, UK and National Institute for Health Research Biomedical Research Centre, South London and Maudsley National Health Service Trust, UK
Chloe C. Y. Wong
Affiliation:
King's College London, MRC Social, Genetic and Developmental Psychiatry (SGDP) Centre, Institute of Psychiatry, Psychology and Neuroscience, London, UK
Xiaohui Xu
Affiliation:
King's College London, MRC Social, Genetic and Developmental Psychiatry (SGDP) Centre, Institute of Psychiatry, Psychology and Neuroscience, London, UK
Kristian Arendt
Affiliation:
Department of Clinical Psychology and Experimental Psychopathology, University of Groningen, The Netherlands
Judith Blatter-Meunier
Affiliation:
Department of Psychology, University of Basel, Basel, Switzerland
Susan Bögels
Affiliation:
Research Institute Child Development and Education, University of Amsterdam, The Netherlands
Peter Cooper
Affiliation:
School of Psychology and Clinical Language Sciences, University of Reading, UK and Department of Psychology, Stellenbosch University, South Africa
Cathy Creswell
Affiliation:
School of Psychology and Clinical Language Sciences, University of Reading, UK
Einar R. Heiervang
Affiliation:
Institute of Clinical Medicine, University of Oslo, Oslo, Norway
Chantal Herren
Affiliation:
Department of Forensic Psychiatry, University of Basel Psychiatric Clinics, Basel, Switzerland
Sanne M. Hogendoorn
Affiliation:
Department of Child and Adolescent Psychiatry/De Bascule, Academic Medical Centre, Amsterdam, The Netherlands
Jennifer L. Hudson
Affiliation:
Department of Psychology, Centre for Emotional Health, Macquarie University, Sydney, Australia
Karen Krause
Affiliation:
Department of Psychology, Ruhr-Universität Bochum, Bochum, Germany
Heidi J. Lyneham
Affiliation:
Department of Psychology, Centre for Emotional Health, Macquarie University, Sydney, Australia
Anna McKinnon
Affiliation:
Brain and Mind Research Institute, University of Sydney, Sydney, Australia, and The MRC Cognition and Brain Sciences Unit, Cambridge, UK
Talia Morris
Affiliation:
Department of Psychology, Centre for Emotional Health, Macquarie University, Sydney, Australia
Maaike H. Nauta
Affiliation:
Department of Clinical Psychology and Experimental Psychopathology, University of Groningen, The Netherlands
Ronald M. Rapee
Affiliation:
Department of Psychology, Centre for Emotional Health, Macquarie University, Sydney, Australia
Yasmin Rey
Affiliation:
Child Anxiety and Phobia Program, Department of Psychology, Florida International University, Miami, USA
Silvia Schneider
Affiliation:
Department of Psychology, Ruhr-Universität Bochum, Bochum, Germany
Sophie C. Schneider
Affiliation:
Department of Psychology, Centre for Emotional Health, Macquarie University, Sydney, Australia
Wendy K. Silverman
Affiliation:
Yale University School of Medicine, Child Study Center, New Haven, Connecticut, USA
Patrick Smith
Affiliation:
King's College London, Department of Psychology, Institute of Psychiatry, Psychology and Neuroscience, London, UK
Mikael Thastum
Affiliation:
Department of Psychology and Behavioural Sciences, Aarhus University, Aarhus, Denmark
Kerstin Thirlwall
Affiliation:
School of Psychology and Clinical Language Sciences, University of Reading, UK
Polly Waite
Affiliation:
School of Psychology and Clinical Language Sciences, University of Reading, UK
Gro Janne Wergeland
Affiliation:
Department of Child and Adolescent Psychiatry, Haukeland University Hospital, Bergen, Norway
Thalia C. Eley*
Affiliation:
King's College London, MRC Social, Genetic and Developmental Psychiatry (SGDP) Centre, Institute of Psychiatry, Psychology and Neuroscience, London, UK
*
Thalia C. Eley, SGDP Centre, Institute of Psychiatry, King's College, Box PO80, London SE5 8AF, UK. Email: [email protected]
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Abstract

Background

We previously reported an association between 5HTTLPR genotype and outcome following cognitive–behavioural therapy (CBT) in child anxiety (Cohort 1). Children homozygous for the low-expression short-allele showed more positive outcomes. Other similar studies have produced mixed results, with most reporting no association between genotype and CBT outcome.

Aims

To replicate the association between 5HTTLPR and CBT outcome in child anxiety from the Genes for Treatment study (GxT Cohort 2, n = 829).

Method

Logistic and linear mixed effects models were used to examine the relationship between 5HTTLPR and CBT outcomes. Mega-analyses using both cohorts were performed.

Results

There was no significant effect of 5HTTLPR on CBT outcomes in Cohort 2. Mega-analyses identified a significant association between 5HTTLPR and remission from all anxiety disorders at follow-up (odds ratio 0.45, P = 0.014), but not primary anxiety disorder outcomes.

Conclusions

The association between 5HTTLPR genotype and CBT outcome did not replicate. Short-allele homozygotes showed more positive treatment outcomes, but with small, non-significant effects. Future studies would benefit from utilising whole genome approaches and large, homogenous samples.

Type
Papers
Copyright
Copyright © Royal College of Psychiatrists, 2016 

Anxiety disorders represent a significant global health burden due to their debilitating nature and high lifetime prevalence. Reference Kessler, Berglund, Demler, Jin, Merikangas and Walters1 They frequently occur early and show high continuity into adulthood. Reference Bittner, Egger, Erkanli, Jane Costello, Foley and Angold2 Cognitive–behavioural therapy (CBT) is the most established treatment option for childhood anxiety, with around 59% of children remitting following treatment. Reference James, James, Cowdrey, Soler and Choke3 The short, low-expression allele of the functional serotonin transporter promoter polymorphism, 5HTTLPR, has been associated with heightened anxiety and related traits Reference Lesch, Bengel, Heils, Sabol, Greenberg and Petri4 compared with the long allele, although findings are somewhat mixed. Reference Sen, Burmeister and Ghosh5,Reference Munafò, Freimer, Ng, Ophoff, Veijola and Miettunen6 Gene–environment interaction studies provide evidence that short allele carriers have the poorest outcomes in high stress environments, Reference Karg, Burmeister, Shedden and Sen7 but also show the largest benefit in response to low stress or enriching environments. Reference Eley, Sugden, Corsico, Gregory, Sham and McGuffin8Reference Stein, Campbell-Sills and Gelernter11 These findings suggest that 5HTTLPR may represent a ‘differential susceptibility’ marker, which acts ‘for better and for worse’. Reference Belsky, Jonassaint, Pluess, Stanton, Brummett and Williams12 Some individuals who are more susceptible to the negative effects of poor environments might also be more sensitive to the positive effects of an enriching experience, Reference Hankin, Nederhof, Oppenheimer, Jenness, Young and Abela13 and therefore may respond better to the supportive influence provided by psychological therapies. The field of ‘therapygenetics’ – genetic predictors of outcome following purely psychological therapies – is relatively new. Reference Lester and Eley14 In a previous study, we found that 5HTTLPR genotype was significantly associated with CBT outcome. Reference Eley, Hudson, Creswell, Tropeano, Lester and Cooper15 SS homozygotes showed a significantly greater reduction in symptom severity than long allele carriers, and were 20% (18.8%) more likely to be free of their primary (all) anxiety disorder diagnoses by follow-up. A handful of other studies have investigated 5HTTLPR and outcomes following a range of psychological therapies, although results have not been consistent. Reference Eley, Hudson, Creswell, Tropeano, Lester and Cooper15Reference Lonsdorf, Ruck, Bergstrom, Andersson, Ohman and Lindefors23 Two studies also found the SS genotype to be associated with more positive outcomes; following a problem-solving intervention with antidepressants in older adults with post-stroke depression, Reference Kohen, Cain, Buzaitis, Johnson, Becker and Teri16 and exposure-based therapy in adults with panic disorder with agoraphobia. Reference Bockting, Mocking, Lok, Koeter and Schene17 However, a third study examining CBT in post-traumatic stress disorder found poorer outcomes in SS carriers. Reference Bryant, Felmingham, Falconer, Benito, Dobson-Stone and Pierce18 Additional studies in both adults and children found no effect of 5HTTLPR outcome following psychological interventions. Of note, these studies are all of small sample size, and are generally underpowered to detect what is likely to be a small effect of 5HTTLPR genotype. Furthermore, participants in many of the studies were also on concurrent antidepressant or anxiolytic medications. These factors highlight the need for replication in a large sample to further examine the association between 5HTTLPR genotype and outcome following a purely psychological therapy.

Based on our previous research, the aim of this study was to test whether 5HTTLPR genotype was associated with outcome following CBT in a large replication sample of 829 children with anxiety disorders. This sample size far exceeded that required to detect an effect of similar magnitude to that of our previously reported findings, with greater than 95% power at a significance level of α<0.01. We hypothesised that children with the SS genotype would (a) show greater rates of remission at follow-up and (b) show a greater reduction in symptom severity at follow-up than those with the SL or LL genotype. To further increase power to detect an association between 5HTTLPR genotype and outcome and to estimate an upper bound for the magnitude of the effect, mega-analyses were performed on a combined data-set comprising both our discovery (n = 496) and replication samples (n = 829). Again, we hypothesised that SS genotype carriers would show a more positive outcome following treatment relative to SL or LL genotype carriers.

Method

Study overview

All participants come from the Genes for Treatment (GxT) study, an international multisite collaboration designed to identify clinical, demographic and genetic predictors of outcome following CBT for child anxiety. Reference Hudson, Keers, Roberts, Coleman, Breen and Arendt24

Participants and treatment

Participants aged between 5 and 18 years (mean age: 10 years) met DSM-IV criteria for primary diagnosis of an anxiety disorder. Exclusion criteria included significant physical/intellectual impairment, psychoses and concurrent treatment. All participants completed a full course of CBT either as part of a trial or as treatment as usual at one of 11 sites; Sydney, Australia (n = 293); Reading, UK (n = 199); Aarhus, Denmark (n = 112); Bergen, Norway (n = 35); Bochum, Germany (n = 50); Florida, USA (n = 36); Basel, Switzerland (n = 46); Groningen, The Netherlands (n = 35); Oxford, UK (n = 11); Cambridge, UK (n = 9) and Amsterdam, The Netherlands (n = 3). All treatments were manualised and treatment protocols across sites were comparable for core elements of CBT, including teaching of coping skills, cognitive restructuring and exposure. Treatment modalities fell into three broad groups – individual CBT (39.8%), group-based CBT (46.1%) and parent-supported guided self-help (14.1%). Further sample characteristics and site-specific trial details can be found in the online data supplement to this article.

Measures

Anxiety disorder diagnoses

Anxiety disorders were assessed at three time points; before and after treatment, and at follow-up (3, 6 or 12 months after conclusion of treatment). Diagnoses were made with the Anxiety Disorders Interview Schedule for DSM-IV (ADIS-IV-C/P) Reference Silverman and Albano25 at all sites except for Bochum and Basel, where the German equivalent (Kinder-DIPs) was used. Reference Schneider, Unnewehr and Margraf26 Clinical severity ratings (CSRs) were usually based on composite parent and child reports, and were assigned on a scale of 0–8 (see Hudson et al Reference Hudson, Keers, Roberts, Coleman, Breen and Arendt24 for further details). A diagnosis was made when the child met diagnostic criteria and received a CSR of 4 or more. Primary diagnoses included generalised anxiety disorder (GAD; 34.9%), separation anxiety disorder (SAD; 25.1%), social anxiety disorder (20.8%), specific phobias (11.9%), panic disorder (3.3%), obsessive–compulsive disorder (OCD; 2.1%), post-traumatic stress disorder (PTSD; 1.3%), selective mutism (0.2%, in the cases with primary selective mutism, a diagnosis of severe social phobia was also given; the selective mutism was considered by the clinician to be primary, the most interfering), and anxiety disorders not otherwise specified (ADNOS; 0.5%).

Ethnicity

Ethnicity was determined by parent-report regarding the ancestry of the child's grandparents. Those with four grandparents of reported White European ancestry were included in the ‘White European subset’ (n = 560, see online data supplement).

Sample collection and genotyping

DNA samples were collected using either buccal swabs or Oragene saliva kits (DNA Genotek, Ottawa, Canada) and extracted using established procedures. Reference Freeman, Smith, Curtis, Huckett, Mill and Craig27,Reference Genotek28 5HTTLPR was genotyped using polymerase chain reaction amplification and agarose gel electrophoresis according to published protocols. Reference Eley, Hudson, Creswell, Tropeano, Lester and Cooper15 A selection of samples (n = 40) were genotyped in duplicate, with consistent results for each attempt. The genotypic distribution of the sample conformed to Hardy–Weinberg proportions (LL: 25.9%, SL: 51.4%, SS: 22.7%; χ2 1 = 0.69, P = 0.444).

Ethical approval

All trials and collection of samples were approved by site-specific human ethics and biosafety committees. Parents provided informed consent, children assent. The storage and analysis of DNA was approved by the King's College London Psychiatry, Nursing and Midwifery Research Ethics Sub-Committee.

Sample size and power analyses

Participants used in this paper are referred to as Cohort 2, which consisted of 829 participants with clinical data available both at baseline and at least one outcome time-point (post-treatment, a follow-up time-point or both). However, of these, 792 had outcome data at post-treatment; 606 at follow-up.

Power calculations Reference Purcell, Cherny and Sham29 suggested a sample size of 285 would be required for 95% power to detect an effect of similar magnitude to our previously reported findings (Cohort 1, odds ratio (OR) = 0.4), at a significance level of α = 0.01 using a recessive allelic model. Our sample of >600 has >90% power to detect a smaller effect size (OR = 0.6) at a significance level of α = 0.01, and 80% power to detect an even smaller effect size of OR = 0.7 at α = 0.05.

Data analysis

Definition of outcome variables

Treatment outcome was defined in a number of ways. Participants were first classed as remitters or non-remitters based on the presence or absence of their primary anxiety disorder diagnosis (primary anxiety remission). Treatment remission was measured both at post-treatment, and at follow-up (collapsed to include all follow-up time-points; 3, 6 or 12 months). Remission was also categorised as the absence of all anxiety disorder diagnoses at post-treatment and at follow-up (all anxiety response). Finally, treatment response was defined as the change in primary anxiety disorder severity from pre- to post-treatment, and from pre-treatment to follow-up.

Mixed effects models

To investigate the effect of 5HTTLPR genotype on remission, logistic mixed effects models were used including treatment trial as a higher order random effect. For consistency with the statistical analyses used in our previous study, 5HTTLPR genotype was defined by a recessive model, where SS was coded as 1 and SL/LL were coded as 0. Gender, age and baseline severity were included as covariates in all analyses (age and baseline severity centred at the mean). Analyses were conducted for primary anxiety diagnosis remission and all anxiety disorder diagnoses remission separately at post-treatment and at follow-up. Models focusing on the follow-up time-point included the linear and quadratic effects of time as covariates.

Linear mixed effects models were used to investigate the effect of 5HTTLPR genotype on response (change in primary anxiety disorder severity). Again, trial was included as a higher order random effect, and gender, age and baseline severity were included as covariates. Time was included as a covariate for the model testing change from pre- to post-treatment; and both linear and quadratic effects of time were included as covariates in the model for follow-up.

Mega-analyses

Finally, logistic and linear mixed models were run using participants from both Cohort 1 Reference Eley, Hudson, Creswell, Tropeano, Lester and Cooper15 and Cohort 2 combined. A total of 584 samples were genotyped in Cohort 1, from children (aged 6–13) who received CBT for an anxiety disorder. In this sample, 496 had sufficient outcome data to be included in at least one analysis. The sample size of 359 reported in Eley et al Reference Eley, Sugden, Corsico, Gregory, Sham and McGuffin8 refers to the White European participants included in the main analysis of response to therapy at follow-up. Further participants were included in analyses of response to therapy at post-treatment, with a total of 496 included in at least one analysis. Participants included in Cohort 1 were recruited at two sites: Sydney, Australia and Reading, UK. Participants who were genotyped in Cohort 1 but whose clinical data were not available at the time of submission were included in Cohort 2. Combining both cohorts increased the sample size, and so the power to detect an association between 5HTTLPR genotype and outcome. Cohort was included as a covariate in these analyses.

Multiple testing corrections

For analyses of remission and response in the mega-analysis, we applied a Bonferroni multiple testing correction to account for the three outcome measures (primary anxiety remission, all anxiety remission and treatment response), giving a corrected significance level of P = 0.016. However, the outcome measures used in this study are highly related and nested within each other, and all analyses presented test the same core hypotheses; thus, the correction is likely conservative.

All analyses were performed in STATA version 11. 30

Results

Remission rates

Remission rates are given in Table 1 and were marginally higher than in previous studies, Reference James, James, Cowdrey, Soler and Choke3 with 61.1% of children remitting from their primary anxiety disorder after treatment, and 71.8% by follow-up. There were no significant differences between remitters and non-remitters for age and gender (age: primary t(604) = −0.16, P = 0.874; all anxiety t(570) = −0.76, P = 0.449; gender: primary χ2 1 = 0.42, P = 0.515; all anxiety χ2 1 = 0.47, P = 0.492). Outcome data by genotype are also given in Table 1 for the additive model, and Fig. 1 shows outcomes for the recessive model. Individuals with the SS genotype were 1.7% more likely than those with SL/LL genotype to remit from their primary anxiety diagnosis and 6.5% more likely to remit from all anxiety diagnoses at follow-up. However, differences between the groups were not statistically significant.

Table 1 Treatment outcome (response and remission) in Cohort 2 by 5HTTLPR genotype

Treatment outcome Time point Cohort 2 SS genotype SL genotype LL genotype
Primary anxiety disorder remission a Post-treatment 61.1 63.7 59.2 62.6
Follow-up 71.8 73.1 72.3 69.5
All anxiety diagnoses remission a Post-treatment 42.0 40.7 42.0 43.2
Follow-up 55.7 60.8 55.0 52.4
Primary anxiety disorder response b Post-treatment 3.39 (2.14) 3.47 (2.13) 3.29 (2.14) 3.52 (2.16)
Follow-up 4.04 (2.21) 4.18 (2.16) 3.98 (2.21) 4.04 (2.24)

Comparisons between genotype groups are not statistically significant for any treatment outcome in Cohort 2.

a. Values for remission are the percentage free of primary and all anxiety disorder diagnoses at post-treatment and at follow-up.

b. Values for primary anxiety disorder response are the mean change in severity from the initial assessment at pre-treatment to the time point specified (s.d. in brackets).

Fig. 1 Remission rates and response to cognitive–behavioural therapy (CBT).

Figure 1(a) shows the proportion of children free of their primary anxiety disorder and all anxiety diagnoses at follow-up, split by 5HTTLPR genotype in Cohort 2. Figure 1(b) shows the change in primary anxiety symptom severity rating across the course of treatment by 5HTTLPR genotype in Cohort 2. Genotype was not significantly associated with any outcome measure (P>0.05 for all analyses). Figure 1(c) shows the proportion of children free of their primary anxiety disorder and all anxiety diagnoses at follow-up, split by 5HTTLPR genotype in the combined sample. Figure 1(d) shows the change in primary anxiety symptom severity rating across the course of treatment by 5HTTLPR genotype in the combined sample. Genotype was not significantly associated with primary anxiety remission or response (P>0.05 for all analyses), but those homozygous for the short allele showed a significantly greater remission for all anxiety disorders in the combined sample, even when clinical covariates were taken into account (*OR = 0.45, P = 0.014).

Logistic mixed effects models – predicting remission

No significant effect of genotype on treatment outcome was detected for either primary or all anxiety diagnoses at post-treatment (Table 2; primary: OR = 0.92, P = 0.551; all anxiety: OR = 1.09, P = 0.607); or at follow-up (Table 2; primary: OR = 0.83, P= 0.318; all anxiety: OR = 0.66, P = 0.293). The odds ratio of less than 1 indicates that, as found previously, participants with the SS genotype were more likely to remit than SL/LL children. A similar pattern of effects was seen when analyses were restricted to the White European subset (see Table DS1 in the online data supplement).

Table 2 Mixed effect models; categorical remission and change in symptom severity at post-treatment and follow-up for primary anxiety diagnosis; remission from all anxiety disorder diagnoses at post-treatment and follow-up

Remission Response – change in CSR
Primary anxiety disorder (n = 792) All anxiety diagnoses (n = 747) Primary anxiety disorder (n = 788)
Time point OR 95% CI P OR 95% CI P β 95% CI P
Post-treatment
    Genotype 0.92 0.71 to 1.20 0.551 1.09 0.79 to 1.48 0.607 −0.04 −0.11 to 0.03 0.294
    Time −1.36 −1.41 to 1.30 0.000
    Baseline severity 1.15 1.03 to 1.29 0.013 1.22 1.07 to 1.39 0.003 0.29 0.26 to 0.32 0.000
    Age 1.02 0.97 to 1.08 0.367 1.00 0.94 to 1.07 0.936 0.01 −0.00 to 0.03 0.083
    Gender 1.07 0.86 to 1.33 0.539 1.25 0.97 to 1.62 0.088 0.03 −0.03 to 0.09 0.279
Primary anxiety disorder (n = 606) All anxiety diagnoses (n = 573) Primary anxiety disorder (n = 581)
Time point OR 95% CI P OR 95% CI P β 95% CI P
Follow-up
    Genotype 0.83 0.35 to 1.99 0.679 0.66 0.31 to 1.43 0.293 −0.04 −0.13 to 0.04 0.318
    Time 0.00 0.00 to 0.01 0.000 0.00 0.00 to 0.02 0.000 −1.03 −1.09 to 0.97 0.000
    Time2 2.72 1.76 to 4.19 0.000 2.27 1.64 to 3.13 0.000 0.15 0.13 to 0.16 0.000
    Baseline severity 2.05 1.31 to 3.21 0.002 1.99 1.36 to 2.93 0.000 0.27 0.23 to 0.30 0.000
    Age 0.96 0.80 to 1.14 0.631 1.02 0.88 to 1.20 0.750 0.00 −0.02 to 0.02 0.957
    Gender 0.79 0.39 to 1.62 0.523 1.20 0.64 to 2.23 0.569 0.03 −0.04 to 0.10 0.461

CSR, clinical severity rating.

5HTTLPR genotype is defined using a recessive model, where SS = 1 and LL/LS = 0. Age and baseline severity are centered at the mean.

Change in symptom severity

Mean primary anxiety disorder severity at pre-treatment was 6.20 (s.d. = 1.05). At post-treatment, mean severity was 2.82 (s.d. = 2.12), corresponding with a change from pre-treatment of 3.39 (s.d. = 2.14; Table 1). Mean severity at follow-up was 2.15 (s.d. = 2.17) with a mean change from pre-treatment of 4.04 (s.d. = 2.21). There were no significant effects of age or gender on change in symptom severity in Cohort 2 (age: β = −0.01, P = 0.55; gender: β = 0.04, P= 0.53). Change in severity by genotype is shown in Table 1 and Fig. 1(b). Participants with SS genotype showed a marginally greater reduction in symptom severity by post-treatment (0.10) and by follow-up (0.18) than SL/LL genotype carriers but differences between the groups were not significant.

Linear mixed effects models – predicting response

No significant effect of genotype on change in primary diagnosis symptom severity was detected, either during the course of treatment (Table 2; pre-treatment to post-treatment: β = −0.04, P = 0.294) or at follow-up (pre-treatment to follow-up: β = −0.04, P = 0.318). This was also true of the White European subset (online Table DS1). The overall standardised beta coefficient of −0.04 indicates that SS children had a 0.04 s.d. greater reduction in severity scores than SL/LL children.

Mega-analyses

Before combining Cohorts 1 and 2 for analyses, the two cohorts were compared for key variables. There were no significant differences in gender distribution (χ2 1 = 2.39, P = 0.122), treatment modality (χ2 2 = 4.07, P = 0.131) or recessive genotype (χ2 1 = 1.98, P = 0.159). Due to the recruitment from additional studies in Cohort 2, a larger age range was included and Cohort 2 was significantly older (t(1271) = 5.15, P = 0.0001). Cohort 2 also showed significantly higher rates of remission at post-treatment (primary: χ2 1 = 7.72, P = 0.005; all anxiety: χ2 1 = 7.35, P = 0.007) and at follow-up (primary: χ2 1 = 7.24, P = 0.007; all anxiety: χ2 1 = 13.60, P = 0.000).

In the entire sample (Cohorts 1 and 2 combined), SS participants were 6.6% more likely to remit from their primary anxiety disorder, and 11.4% more likely to remit from all anxiety disorder diagnoses than SL/LL carriers (Fig. 1(c)). Additionally, SS carriers showed a greater reduction in symptom severity from pre-treatment to follow-up than SL/LL carriers (Fig. 1(d); SS: change = 4.01, s.d. = 2.05; SL/LL: change = 3.79, s.d. = 2.19).

When using linear and logistic mixed effect models, the effect of genotype on primary anxiety disorder response and remission did not reach statistical significance (Table 3; change in CSR: β = −0.06, P = 0.070; remission: OR = 0.55, P = 0.095). However, there was a significant effect of genotype on all anxiety diagnoses remission (Table 3; OR = 0.45, P = 0.014), which remained nominally significant when multiple testing corrections were made. In the White European subset, a similar pattern of results was detected, although these did not reach statistical significance (see online Table DS2).

Table 3 Mega-analyses; results combining Cohorts 1 and 2. Outcome measures; primary anxiety disorder remission at follow-up, change in primary anxiety CSR from pre-treatment to follow-up, all anxiety disorder diagnoses remission at follow-up

Remission Response – change in CSR
Primary anxiety disorder (n =1044) All anxiety diagnoses (n = 1011) Primary anxiety disorder (n = 1019)
Predictor variable at follow-up OR 95% CI P OR 95% CI P β 95% CI P
Genotype 0.55 0.27 to 1.11 0.095 0.45 0.25 to 0.88 0.014 −0.06 −0.13 to 0.01 0.070
Time 0.00 0.00 to 0.01 0.000 0.00 0.00 to 0.01 0.000 −0.91 −0.95 to 0.86 0.000
Time2 2.55 1.94 to 3.36 0.000 2.17 1.73 to 2.72 0.000 0.13 0.11 to 0.14 0.000
Baseline severity 2.05 1.44 to 2.91 0.000 2.30 1.63 to 3.23 0.000 0.27 0.24 to 0.29 0.000
Age 0.95 0.83 to 1.10 0.497 0.99 0.87 to 1.12 0.833 −0.01 −0.02 to 0.01 0.360
Gender 1.21 0.70 to 2.09 0.502 1.33 0.81 to 2.20 0.257 0.05 −0.00 to 0.10 0.070
Cohort 0.65 0.33 to 1.27 0.206 0.55 0.30 to 1.02 0.056 −0.05 −0.12 to 0.01 0.100

CSR, clinical severity rating.

5HTTLPR genotype is defined using a recessive model, where SS = 1 and LL/LS = 0. Age and baseline severity are centred at the mean. Statistically significant results for genotype are highlighted.

Discussion

We attempted to replicate our previously reported association between 5HTTLPR genotype and outcome following CBT. Our replication sample comprised 829 children with a primary anxiety diagnosis. We found no significant association between genotype and remission of primary or all anxiety diagnoses at post-treatment or follow-up time-points. Furthermore, change in primary anxiety disorder symptom severity (response) across the course of treatment did not differ as a function of 5HTTLPR genotype. Mega-analyses combining data from this and our previous report Reference Eley, Hudson, Creswell, Tropeano, Lester and Cooper15 revealed a significant association between 5HTTLPR genotype and remission of all anxiety disorders at follow-up. Children carrying the SS genotype were more likely to be free of all anxiety disorder diagnoses than children with the SL/LL genotype. This effect remained significant after multiple testing corrections.

In our previous paper, 20% (18.8%) more children with the SS compared with SL/LL genotypes were free of their primary (all) anxiety disorders at follow-up. Reference Eley, Hudson, Creswell, Tropeano, Lester and Cooper15 The odds ratios were 0.39 (0.44) for primary (all) anxiety remission. In this study, the effects observed were in the same direction but were markedly smaller and non-significant. This overestimation of effect size within discovery samples is often, at least in part, responsible for the failure of subsequent studies to replicate genetic effects. This is because replication studies are usually underpowered. This study far exceeded the required N of 285 needed to detect an effect of OR = 0.39 (as observed in our previous study) with 80% power and α = 0.01. With a sample size of at least 600 in each analysis, this study was sufficiently powered to detect an OR = 0.39 with greater than 99% power and α = 0.001. However, if the true effect of 5HTTLPR in predicting CBT response is closer to the 0.66 observed in the present study, then this would require a sample of N>900 to detect this effect at α = 0.01 with 80% power (taking into account the higher remission rate in the Cohort 2).

Mega-analyses are one means of increasing statistical power. To this end, we examined the overall effect of 5HTTLPR genotype on CBT outcome using all data available from this and our previous paper. This allowed us to increase the available sample size to n = 1044. The effect of genotype on change in primary anxiety disorder symptom severity was suggestive of an improved response for SS genotype carriers but did not reach conventional levels of significance. We found weak evidence of an association between 5HTTLPR genotype and remission of all anxiety diagnoses at follow-up, which was consistent with our previous findings. Reference Eley, Hudson, Creswell, Tropeano, Lester and Cooper15 SS genotype carriers were half as likely as SL/LL carriers to retain any anxiety disorder diagnosis at follow-up (OR = 0.45). The odds ratio for primary anxiety disorder remission was in the same direction (OR = 0.55) but did not attain statistical significance. These findings suggest that the 5HTTLPR genotype accounts for only a very small amount of the variance in outcome following CBT. Importantly, the 95% confidence intervals around the OR of 0.45 (for all anxiety disorder remission) suggest that the true effect size lies somewhere between 0.25 and 0.88 and thus effectively provides an upper bound for estimating the effect of 5HTTLPR on remission following CBT. However, given the tendency of early candidate gene discoveries to overestimate the true effect, it remains highly plausible that the true effect may in fact be nearer the lower bound estimate of 0.88 (a higher value represents a smaller effect size with respect to these analyses; see results section for further details). Future research attempting to investigate outcome following psychological treatments as a function of 5HTTLPR genotype should use this information when making decisions regarding appropriate sample size.

The current paper adds to the expanding therapygenetics literature investigating the 5HTTLPR polymorphism. Reference Lester and Eley14 Although this marker is a plausible candidate for involvement in outcome following psychological therapy, 8 out of 11 studies have failed to find a significant association between the 5HTTLPR and treatment response, with the present study being by far the most highly powered. The remaining studies observed mixed effects: two studies Reference Kohen, Cain, Buzaitis, Johnson, Becker and Teri16,Reference Knuts, Esquivel, Kenis, Overbeek, Leibold and Goossens22 found a significant association between the SS genotype and a more positive treatment response, which is consistent with the mega-analyses reported herein. However, a third small study Reference Bryant, Felmingham, Falconer, Benito, Dobson-Stone and Pierce18 reported the opposite with the SS genotype associated with fewer treatment gains. The weak and contradictory findings seen thus far may reflect varying disorder and treatment response phenotypes, the role of medication in some studies and small, underpowered sample sizes. Reference Lester and Eley14

The use of a semi-structured diagnostic instrument to characterise treatment outcome and agreement across study sites on the definition of response are significant strengths of this study. This study is also the largest to date to investigate genetic predictors of outcome following psychological therapy. However, there are some limitations. First, the sample is very heterogeneous, including a range of anxiety diagnoses and several different CBT modalities. One possibility is that the 5HTTLPR may have greater predictive power when the sample and treatment is more homogeneous. Reference Beevers and McGeary31 Second, the current study takes a candidate gene approach. In all areas of psychiatric genetics, candidate gene studies typically report very small effect sizes, often fail to replicate and are sensitive to publication bias. Reference Duncan and Keller32 To be able to nominate candidate genes for investigation also requires a clear understanding of the pathophysiology of the phenotype under investigation and the putative mechanisms through which psychological therapies may act. We know that psychological treatment response is a complex trait, thus it is very unlikely that a single genetic polymorphism such as the 5HTTLPR will explain a sufficiently large amount of variance in outcome to be clinically meaningful in its own right. Although there remains a place for adequately powered studies of plausible candidate genes within the therapygenetics field, this challenge means it will become increasingly important to move towards a whole-genome array-based ‘therapygenomics’ approach. Whole-genome studies are hypothesis free and thus have the potential to identify completely novel and unexpected variants associated with psychological treatment response. Perhaps, most importantly, there is the ability to move beyond single variants and to identify groups of markers and important biological pathways and systems, which collectively capture a (clinically) significant proportion of the variance in outcome. However, it is important to note that some genetic variants (including the 5HTTLPR) cannot be adequately inferred from array data and will continue to need to be genotyped directly. Given the importance of clinical and demographic predictors, Reference Hudson, Keers, Roberts, Coleman, Breen and Arendt24 optimal prediction of CBT response is likely to come from analytic approaches, which aggregate genetic information with clinical and demographic variables. Reference Hudson, Lester, Lewis, Tropeano, Creswell and Collier33

In summary, this study failed to replicate our previously reported association between 5HTTLPR genotype and outcome following CBT for child anxiety disorders. Consistent with our previous findings SS genotype carriers had a more positive treatment response compared with SL/LL genotype carriers. However, these effects were very small and mostly non-significant. The increased sample size afforded by a mega-analytic approach revealed a significant association between SS genotype and remission of all anxiety disorders, which survived multiple testing corrections. Importantly, this work provides an upper and lower bound for estimating the effect size of association between 5HTTLPR and CBT outcomes, which are informative for other researchers working in this area. Going forward, the therapy-genetics field needs to embrace whole genome approaches and to look to recruit large, homogenous samples in which to explore genetic predictors of outcome following psychological therapies.

Acknowledgements

We thank Irma Knuistingh Neven, Marianne Bjerregaard Madsen, Lisbeth Jørgensen, Carmen Adornetto, Kristine Fonnes Griffin, Elisa Kulewski, Jonas Großekathöfer, Nora Dirks, Evelyn Kmelnitski, Sabrina Heuser, Adrian Boyle, Clare Dixon, Harma Moorlag, Nienke Boersma, Sue Cruddace, Marie Weber, Zoe Hughes, Kiri Clarke, Francoise Hentges, Liz White, Nynke Wagenaar, Luci Motoca, Yesenia Rodriguez, Klaudia Perreira, Erin Hedemann, Cristina Del Busto, Gillian O'Neill, Lucy Lindley, Rachel Banham, Nora Delvendahl, HjaltiJonsson, Kristen Lavallee, Tina In-Albon, Odd E. Havik, Krister Fjermestad, Katrin Hötzel, Richard Meiser-Stedman, Tim Dalgleish, and Carla Marin for their contributions.

Footnotes

Joint first authors.

Combined study supported by UK Medical Research Council grant G0901874/1 to Eley. Lester supported by UK Medical Research Council grant (MR/J011762/1) and Jacobs Foundation Young Scholar grant. Keers supported by UK Medical Research Council Population Health fellowship (MR/K021281/1). Individual trials support by Australian Research Council grant DP0878609 to Hudson, Rapee, and Eley; Australian NHMRC grants to Rapee, Hudson, Lyneham, Mihalopolous (1027556), Lyneham, Hudson and Rapee (488505) and Hudson and Rapee (382008); TrygFonden grant (7-10-1391) to Thastum & Esben Hougaard; Edith ogGodtfred Kirk Christiansens Fond grant (21-5675) to Thastum; Swiss National Science Foundation grant (105314-116517) to Schneider, Western Norway Regional Health Authority grants to Odd Havik (911253) and Heiervang (911366); UK Medical Research Council Clinical Fellowship (G0802821) to Richard Meiser-Stedman; NIMH R01 (MH079943) to Silverman; UK NIHR grants to Creswell (PB-PG-0110-21190) and Cooper (PB-PG-0107-12042); UK Medical Research Council Grants to Cooper and Creswell (09-800-17), Thirlwall, Cooper and Creswell (G0802326), Waite, Creswell and Cooper (G1002011), and Creswell (G0601874). Grant 09/800/17 was managed by NIHR on behalf of the MRC-NIHR partnership. UK NIHR grants to Creswell, Cooper, Emma McIntosh & Lucy Willetts (PB-PG-0110-21190) and Cooper, Creswell, Lucy Willetts & Paul Sheffied(PB-PG-0107-12042); This study presents independent research part-funded by the National Institute for Health Research (NIHR) Biomedical Research Centre at South London and Maudsley NHS Foundation Trust and King's College London. The views expressed are those of the author(s) and not necessarily those of the NHS, the NIHR or the Department of Health.

Declaration of interest

R.M.R., J.L.H. and H.J.L. are authors of the Cool Kids programme, but receive no direct payments. C.C. was joint author of a book used in treatment within the Overcoming trial and P.W. was joint editor for a book on the treatment of obsessive–compulsive disorder and they receive royalties from sales of the books. W.K.S. is an author of the Anxiety Disorders Interview Schedule for Children from which she receives royalties.

References

1 Kessler, RC, Berglund, P, Demler, O, Jin, R, Merikangas, KR, Walters, EE. Lifetime prevalence and age-of-onset distributions of DSM-IV disorders in the national comorbidity survey replication. Arch Gen Psychiatry 2005; 62: 593602.CrossRefGoogle ScholarPubMed
2 Bittner, A, Egger, HL, Erkanli, A, Jane Costello, E, Foley, DL, Angold, A. What do childhood anxiety disorders predict? J Child Psychol Psychiatry 2007; 48: 1174–83.Google Scholar
3 James, AC, James, G, Cowdrey, F, Soler, A, Choke, A. Cognitive behavioural therapy for anxiety disorders in children and adolescents. Cochrane Database Syst Rev 2013; 6: CD004690.Google Scholar
4 Lesch, K-P, Bengel, D, Heils, A, Sabol, SZ, Greenberg, BD, Petri, S, et al. Association of anxiety-related traits with a polymorphism in the serotonin transporter gene regulatory region. Science 1996; 274: 1527–31.CrossRefGoogle ScholarPubMed
5 Sen, S, Burmeister, M, Ghosh, D. Meta-analysis of the association between a serotonin transporter promoter polymorphism (5-HTTLPR) and anxiety-related personality traits. Am J Med Genet B Neuropsychiatr Genet 2004; 127B: 85–9.CrossRefGoogle ScholarPubMed
6 Munafò, MR, Freimer, NB, Ng, W, Ophoff, R, Veijola, J, Miettunen, J, et al. 5-HTTLPR genotype and anxiety-related personality traits: a meta-analysis and new data. Am J Med Genet B Neuropsychiatr Genet 2009; 150B: 271–81.CrossRefGoogle ScholarPubMed
7 Karg, K, Burmeister, M, Shedden, K, Sen, S. The serotonin transporter promoter variant (5-httlpr), stress, and depression meta-analysis revisited: evidence of genetic moderation. Arch Gen Psychiatry 2011; 68: 444–54.CrossRefGoogle ScholarPubMed
8 Eley, TC, Sugden, K, Corsico, A, Gregory, AM, Sham, P, McGuffin, P, et al. Gene-environment interaction analysis of serotonin system markers with adolescent depression. Mol Psychiatry 2004; 9: 908–15.Google Scholar
9 Taylor, SE, Way, BM, Welch, WT, Hilmert, CJ, Lehman, BJ, Eisenberger, NI. Early family environment, current adversity, the serotonin transporter promoter polymorphism, and depressive symptomatology. Biol Psychiatry 2006; 60: 671–6.Google Scholar
10 Wilhelm, K, Mitchell, PB, Niven, H, Finch, A, Wedgwood, L, Scimone, A, et al. Life events, first depression onset and the serotonin transporter gene. Br J Psychiatry 2006; 188: 210–5.Google Scholar
11 Stein, MB, Campbell-Sills, L, Gelernter, J. Genetic variation in 5HTTLPR is associated with emotional resilience. Am J Med Genet B Neuropsychiatr Genet 2009; 150B: 900–6.CrossRefGoogle ScholarPubMed
12 Belsky, J, Jonassaint, C, Pluess, M, Stanton, M, Brummett, B, Williams, R. Vulnerability genes or plasticity genes. Mol Psychiatry 2009; 14: 746–54.CrossRefGoogle ScholarPubMed
13 Hankin, B, Nederhof, E, Oppenheimer, C, Jenness, J, Young, J, Abela, J, et al. Differential susceptibility in youth: evidence that 5-HTTLPR x positive parenting is associated with positive affect “for better and worse”. Transl Psychiatry 2011; 1: e44.Google Scholar
14 Lester, KJ, Eley, TC. Therapygenetics: using genetic markers to predict response to psychological treatment for mood and anxiety disorders. Biol Mood Anxiety Disord 2013; 3: 116.Google Scholar
15 Eley, TC, Hudson, JL, Creswell, C, Tropeano, M, Lester, KJ, Cooper, P, et al. Therapygenetics: the 5HTTLPR and response to psychological therapy. Mol Psychiatry 2012; 17: 236–7.Google ScholarPubMed
16 Kohen, R, Cain, KC, Buzaitis, A, Johnson, V, Becker, KJ, Teri, L, et al. Response to psychosocial treatment in poststroke depression is associated with serotonin transporter polymorphisms. Stroke 2011; 42: 2068–70.CrossRefGoogle ScholarPubMed
17 Bockting, CL, Mocking, RJ, Lok, A, Koeter, MW, Schene, AH. Therapygenetics: the 5HTTLPR as a biomarker for response to psychological therapy? Mol Psychiatry 2012; 18: 744–5.Google ScholarPubMed
18 Bryant, R, Felmingham, K, Falconer, E, Benito, L, Dobson-Stone, C, Pierce, K, et al. Preliminary evidence of the short allele of the serotonin transporter gene predicting poor response to cognitive behavior therapy in posttraumatic stress disorder. Biol Psychiatry 2010; 67: 1217–9.Google Scholar
19 Andersson, E, Rück, C, Lavebratt, C, Hedman, E, Schalling, M, Lindefors, N, et al. Genetic polymorphisms in monoamine systems and outcome of cognitive behavior therapy for social anxiety disorder. PLoS ONE 2013; 8: e79015.Google ScholarPubMed
20 Furmark, T, Carlbring, P, Hammer, S, Wahlgren, I, Ekselius, L, Eriksson, E, et al. Effects of serotonin transporter and tryptophan hydroxylase-2 gene variation on the response to cognitive-behavior therapy in individuals with social anxiety disorder. Biol Psychiatry 2010; 67 (9 suppl): 1S271S.Google Scholar
21 Hedman, E, Andersson, E, Ljótsson, B, Andersson, G, Schalling, M, Lindefors, N, et al. Clinical and genetic outcome determinants of Internet-and group-based cognitive behavior therapy for social anxiety disorder. Acta Psychiatr Scand 2012; 126: 126–36.Google Scholar
22 Knuts, I, Esquivel, G, Kenis, G, Overbeek, T, Leibold, N, Goossens, L, et al. Therapygenetics: 5-HTTLPR genotype predicts the response to exposure therapy for agoraphobia. Eur Neuropsychopharmacol 2014; 24: 1222–8.CrossRefGoogle ScholarPubMed
23 Lonsdorf, T, Ruck, C, Bergstrom, J, Andersson, G, Ohman, A, Lindefors, N, et al. The COMTval158met polymorphism is associated with symptom relief during exposure-based cognitive-behavioral treatment in panic disorder. BMC Psychiatry 2010; 10: 99.Google Scholar
24 Hudson, JL, Keers, R, Roberts, S, Coleman, JR, Breen, G, Arendt, K, et al. Clinical predictors of response to cognitive-behavioral therapy in pediatric anxiety disorders: the Genes for Treatment (GxT) study. J Am Acad Child Adolesc Psychiatry 2015; 54: 454–63.Google Scholar
25 Silverman, WK, Albano, AM. The Anxiety Disorders Interview Schedule for Children-IV (Child and Parent Versions). Oxford University Press, 1996.Google Scholar
26 Schneider, S, Unnewehr, S, Margraf, J. Kinder-DIPS für DSM-IV-TR. Diagnostisches Interview bei psychischen Störungen im Kindes-und Jugendalter [Child-DIPS for DSM-IV-TR. Diagnostic Interview for Psychiatric Disordes in Childhood and Adolescence]. Springer, 2009.Google Scholar
27 Freeman, B, Smith, N, Curtis, C, Huckett, L, Mill, J, Craig, IW. DNA from buccal swabs recruited by mail: evaluation of storage effects on long-term stability and suitability for multiplex polymerase chain reaction genotyping. Behav Genet 2003; 33: 6772.Google ScholarPubMed
28 Genotek, DNA. Laboratory Protocol for Manual Purification of DNA from 0.5mL of Sample. DNS Genotek, 2015.Google Scholar
29 Purcell, S, Cherny, SS, Sham, PC. Genetic power calculator: design of linkage and association genetic mapping studies of complex traits. Bioinformatics 2003; 19: 149–50.CrossRefGoogle ScholarPubMed
30 StataCorp. Stata Statistical Software: release 11. Stata Corp LP, 2009.Google Scholar
31 Beevers, CG, McGeary, JE. Therapygenetics: moving towards personalized psychotherapy treatment. Trends Cogn Sci. 2011; 16: 11–2.Google ScholarPubMed
32 Duncan, LE, Keller, MC. A critical review of the first 10 years of candidate gene-by-environment interaction research in psychiatry. Am J Psychiatry 2011; 168: 1041–9.Google Scholar
33 Hudson, JL, Lester, KJ, Lewis, CM, Tropeano, M, Creswell, C, Collier, DA, et al. Predicting outcomes following cognitive behaviour therapy in child anxiety disorders: the influence of genetic, demographic and clinical information. J Child Psychol Psychiatry. 2013; 54: 1086–94.CrossRefGoogle ScholarPubMed
Figure 0

Table 1 Treatment outcome (response and remission) in Cohort 2 by 5HTTLPR genotype

Figure 1

Fig. 1 Remission rates and response to cognitive–behavioural therapy (CBT).Figure 1(a) shows the proportion of children free of their primary anxiety disorder and all anxiety diagnoses at follow-up, split by 5HTTLPR genotype in Cohort 2. Figure 1(b) shows the change in primary anxiety symptom severity rating across the course of treatment by 5HTTLPR genotype in Cohort 2. Genotype was not significantly associated with any outcome measure (P>0.05 for all analyses). Figure 1(c) shows the proportion of children free of their primary anxiety disorder and all anxiety diagnoses at follow-up, split by 5HTTLPR genotype in the combined sample. Figure 1(d) shows the change in primary anxiety symptom severity rating across the course of treatment by 5HTTLPR genotype in the combined sample. Genotype was not significantly associated with primary anxiety remission or response (P>0.05 for all analyses), but those homozygous for the short allele showed a significantly greater remission for all anxiety disorders in the combined sample, even when clinical covariates were taken into account (*OR = 0.45, P = 0.014).

Figure 2

Table 2 Mixed effect models; categorical remission and change in symptom severity at post-treatment and follow-up for primary anxiety diagnosis; remission from all anxiety disorder diagnoses at post-treatment and follow-up

Figure 3

Table 3 Mega-analyses; results combining Cohorts 1 and 2. Outcome measures; primary anxiety disorder remission at follow-up, change in primary anxiety CSR from pre-treatment to follow-up, all anxiety disorder diagnoses remission at follow-up

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