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Heritability of Transforming Growth Factor-β1 and Tumor Necrosis Factor-Receptor Type 1 Expression and Vitamin D Levels in Healthy Adolescent Twins

Published online by Cambridge University Press:  03 December 2014

Natalie T. Mills ,
Margie J. Wright ,
Anjali K. Henders ,
Darryl W. Eyles ,
Bernhard T. Baune ,
John J. McGrath ,
Enda M. Byrne ,
Narelle K. Hansell ,
Eva Birosova  and
James G. Scott
...Show all authors
Natalie T. Mills*
Affiliation:
Genetic Epidemiology, QIMR Berghofer Medical Research Institute, Brisbane, Queensland, Australia Queensland Brain Institute, University of Queensland, Brisbane, Queensland, Australia
Margie J. Wright
Affiliation:
Genetic Epidemiology, QIMR Berghofer Medical Research Institute, Brisbane, Queensland, Australia
Anjali K. Henders
Affiliation:
Genetic Epidemiology, QIMR Berghofer Medical Research Institute, Brisbane, Queensland, Australia
Darryl W. Eyles
Affiliation:
Queensland Brain Institute, University of Queensland, Brisbane, Queensland, Australia Queensland Centre for Mental Health Research, The Park Centre for Mental Health, Brisbane, Queensland, Australia
Bernhard T. Baune
Affiliation:
Discipline of Psychiatry, School of Medicine, University of Adelaide, Adelaide, South Australia, Australia
John J. McGrath
Affiliation:
Queensland Brain Institute, University of Queensland, Brisbane, Queensland, Australia Queensland Centre for Mental Health Research, The Park Centre for Mental Health, Brisbane, Queensland, Australia
Enda M. Byrne
Affiliation:
Queensland Brain Institute, University of Queensland, Brisbane, Queensland, Australia
Narelle K. Hansell
Affiliation:
Genetic Epidemiology, QIMR Berghofer Medical Research Institute, Brisbane, Queensland, Australia
Eva Birosova
Affiliation:
School of Medicine, James Cook University, Townsville, Queensland, Australia
James G. Scott
Affiliation:
Metro North Mental Health, Royal Brisbane and Women's Hospital, Brisbane, Queensland, Australia
Nicholas G. Martin
Affiliation:
Genetic Epidemiology, QIMR Berghofer Medical Research Institute, Brisbane, Queensland, Australia
Grant W. Montgomery
Affiliation:
Genetic Epidemiology, QIMR Berghofer Medical Research Institute, Brisbane, Queensland, Australia
Naomi R. Wray
Affiliation:
Queensland Brain Institute, University of Queensland, Brisbane, Queensland, Australia
Anna A. E. Vinkhuyzen
Affiliation:
Queensland Brain Institute, University of Queensland, Brisbane, Queensland, Australia
*
address for correspondence: Dr Natalie Mills, Genetic Epidemiology, QIMR Berghofer Medical Research Institute, Herston QLD 4006, Australia. E-mail: natalie.mills@qimrberghofer.edu.au

Abstract

Cytokines and vitamin D both have a role in modulating the immune system, and are also potentially useful biomarkers in mental illnesses such as major depressive disorder (MDD) and schizophrenia. Studying the variability of cytokines and vitamin D in a healthy population sample may add to understanding the association between these biomarkers and mental illness. To assess genetic and environmental contributions to variation in circulating levels of cytokines and vitamin D (25-hydroxy vitamin D: 25(OH)D3), we analyzed data from a healthy adolescent twin cohort (mean age 16.2 years; standard deviation 0.25). Plasma cytokine measures were available for 400 individuals (85 MZ, 115 DZ pairs), dried blood spot sample vitamin D measures were available for 378 individuals (70 MZ, 118 DZ pairs). Heritability estimates were moderate but significant for the cytokines transforming growth factor-β1 (TGF-β1), 0.57 (95% CI 0.26–0.80) and tumor necrosis factor-receptor type 1 (TNFR1), 0.50 (95% CI 0.11–0.63) respectively. Measures of 25(OH)D3 were within normal range and heritability was estimated to be high (0.86, 95% CI 0.61–0.94). Assays of other cytokines did not generate meaningful results. These potential biomarkers may be useful in mental illness, with further research warranted in larger sample sizes. They may be particularly important in adolescents with mental illness where diagnostic uncertainty poses a significant clinical challenge.

Keywords

cytokinesvitamin Dmajor depressionpsychosisheritability
Type
Articles
Information
Twin Research and Human Genetics , Volume 18 , Issue 1 , February 2015 , pp. 28 - 35
Copyright
Copyright © The Author(s) 2014 

Emerging evidence suggests a range of blood measures may be useful biomarkers in mental health disorders such as MDD and schizophrenia. Potential blood biomarkers include measures of vitamin D, cytokines, C-reactive protein (CRP), and antibodies to infectious agents (Arias et al., Reference Arias, Sorlozano, Villegas, de Dios Luna, McKenney, Cervilla and Gutierrez2012; Howren et al., Reference Howren, Lamkin and Suls2009; Tolppanen et al., Reference Tolppanen, Sayers, Fraser, Lewis, Zammit and Lawlor2012). Blood biomarkers may be particularly relevant in adolescence, where depression is often comorbid with other disorders (Garber & Weersing, Reference Garber and Weersing2010), resulting in diagnostic uncertainty. Genetic and environmental influences both contribute to the etiology of psychiatric disorders (Kendler, Reference Kendler2013). Heritability is estimated around 40% for MDD (Glowinski et al., Reference Glowinski, Madden, Bucholz, Lynskey and Heath2003; Sullivan et al., Reference Sullivan, Neale and Kendler2000) and around 80% for schizophrenia (Schwab & Wildenauer, Reference Schwab and Wildenauer2013). The presence of plasma pro-inflammatory cytokines (Gabbay et al., Reference Gabbay, Klein, Alonso, Babb, Nishawala, De Jesus and Gonzalez2009; Mills et al., Reference Mills, Scott, Wray, Cohen-Woods and Baune2013) and variation in vitamin D levels (Tolppanen et al., Reference Tolppanen, Sayers, Fraser, Lewis, Zammit and Lawlor2012) in adolescents with mental illness is especially interesting, with both also having a role in the modulation of the immune system (Yin & Agrawal, Reference Yin and Agrawal2014). Understanding how putative biomarkers vary in a healthy population of adolescents may help in guiding the study of these blood measures in psychiatric disorders in adolescents. Examining the link between psychiatric disorders and immune system dysregulation (Gabbay et al., Reference Gabbay, Klein, Alonso, Babb, Nishawala, De Jesus and Gonzalez2009), and the genetic contribution to these biomarkers, are both required to understand the role of plasma cytokines and vitamin D levels in adolescent psychiatric disorders.

Cytokines

Cytokines are small proteins that mediate key steps in cellular and humoral immunity (Janssen et al., Reference Janssen, Caniato, Verster and Baune2010), and have been shown to act as neuromodulators. Examples of pro-inflammatory cytokines include interleukin-1β (IL-1β), interleukin-6 (IL-6), and tumor necrosis factor-α (TNF-α) (Dowlati et al., Reference Dowlati, Herrman, Swardfager, Liu, Sham, Reim and Lanctot2010; Miller et al., Reference Miller, Buckley, Seabolt, Mellor and Kirkpatrick2011), with TNFR1 the key mediator of TNF signaling in most cells (Wajant et al., Reference Wajant, Pfizenmaier and Scheurich2003). Some cytokines, such as transforming growth factor-beta (TGF-β) and TGF-β1, have both pro-inflammatory and anti-inflammatory effects (Gressner et al., Reference Gressner, Weiskirchen, Breitkopf and Dooley2002; Wahl, Reference Wahl1992).

Cytokines, in particular pro-inflammatory cytokines, have been associated with both MDD and schizophrenia. MDD is thought to be associated with immune system dysregulation (Danese et al., Reference Danese, Pariante, Caspi, Taylor and Poulton2007; Reference Danese, Caspi, Williams, Ambler, Sugden, Mika and Arseneault2011; Gabbay et al., Reference Gabbay, Klein, Alonso, Babb, Nishawala, De Jesus and Gonzalez2009; Irwin & Miller, Reference Irwin and Miller2007). In adults, a recent meta-analysis reported an association between elevated levels of two pro-inflammatory cytokines, IL-6 and TNF-α, and MDD (Dowlati et al., Reference Dowlati, Herrman, Swardfager, Liu, Sham, Reim and Lanctot2010). It is also possible that symptoms of depression may be a result of natural variation between individuals in levels of circulating cytokines, even in the absence of specific immune challenge such as infection.

A role for immune system dysregulation in schizophrenia has also been hypothesized (Benros et al., Reference Benros, Mortensen and Eaton2012; Ripke et al., Reference Ripke, Neale, Corvin, Walters, Farh and Holmans2014). Levels of circulating cytokines have been associated with acute exacerbations of schizophrenia. Specifically, a recent meta-analysis reported an increase in the cytokines IL-1β, IL-6, and TGF-β during acute relapse and/or first episode psychosis, which normalized with antipsychotic treatment (Miller et al., Reference Miller, Buckley, Seabolt, Mellor and Kirkpatrick2011). The same meta-analysis found IL-12, TNF-α, Interferon-γ (IFN-γ), and soluble IL-2 receptor (sIL-2R) appeared to be trait markers, with levels elevated in first episode psychosis, and remaining so following antipsychotic treatment. Levels of IL-12, TNF-α, and IFN-γ were also found to be elevated in acute relapses of schizophrenia, and remained elevated following antipsychotic treatment (Miller et al., Reference Miller, Buckley, Seabolt, Mellor and Kirkpatrick2011).

Some studies have measured cytokine response in stimulated cells; for example, ex vivo stimulation with amyloid-β in whole blood (Posthuma et al., Reference Posthuma, Meulenbelt, de Craen, de Geus, Slagboom, Boomsma and Westendorp2005), or antigen-stimulated whole-blood assays (Stein et al., Reference Stein, Guwatudde, Nakakeeto, Peters, Elston, Tiwari and Whalen2003). This is likely to reflect the heritability of the immune response rather than natural variation. Few studies have estimated the heritability of circulating levels of cytokines, particularly in adolescents. Heritabilities of circulating levels of the cytokines IL-1β, IL-6, IL-10, and TNF-α have been estimated in adult females, with the cytokines IL-1β and IL-10 found to be moderately heritable (range 0.27–0.32 and 0.3 for IL-1β and IL-10, respectively), and the cytokines IL-6 and TNF-α found to be less heritable (range 0.15–0.16 and 0.17–0.23 for IL-6 and TNF-α, respectively; Sas et al., Reference Sas, Jamshidi, Zheng, Wu, Korf, Alizadeh and Snieder2012). It should also be noted that measurement of cytokines is known to present difficulties, and quantification of cytokine levels has been found to depend on a number of factors. For example, concentrations of several inflammatory markers have been found to change depending on whether serum or plasma is collected (Skogstrand, Reference Skogstrand2012), and healthy adolescents should have very low levels of circulating inflammatory cytokines (Miller et al., Reference Miller, Buckley, Seabolt, Mellor and Kirkpatrick2011). Furthermore, circulating levels of some cytokines vary throughout a 24-hour period (e.g., IL-2; Palm et al., Reference Palm, Postler, Hinrichsen, Maier, Zabel and Kirch1996), or a seven-day period (e.g., TNF-α; O’Brien et al., Reference O’Brien, Fitzgerald, Scully, Landers, Scott and Dinan2007). These challenges all need to be considered in the design of studies involving the measurement of cytokines.

Vitamin D

Vitamin D is best known for its role in skeletal health. More recently, vitamin D has also been implicated in non-skeletal health such as cancers, immunology, and psychiatric disease (Cantorna, Reference Cantorna2012; Holick, Reference Holick2007; Yin & Agrawal, Reference Yin and Agrawal2014). Activation of cells of the immune system results in upregulation of the vitamin D receptor (Veldman et al., Reference Veldman, Cantorna and DeLuca2000). Furthermore, vitamin D is a direct inhibitor of the pro-inflammatory cytokine IL-17 (Bruce et al., Reference Bruce, Yu, Ooi and Cantorna2011). With regard to psychiatric disease, an increased risk of depression has been associated with low vitamin D in cross-sectional studies (Hoang et al., Reference Hoang, DeFina, Willis, Leonard, Weiner and Brown2011), yet this may reflect individuals with depression spending less time outdoors with less sun exposure. However, a prospective study of 2,759 individuals found a significant association between low vitamin D measured at 9 years of age, and higher scores on depressive symptoms at 11 and 14 years of age (Tolppanen et al., Reference Tolppanen, Sayers, Fraser, Lewis, Zammit and Lawlor2012). With regard to schizophrenia, an association has been observed with increased risk of this syndrome later in life in neonates who had either low levels or high levels of vitamin D (McGrath et al., Reference McGrath, Eyles, Pedersen, Anderson, Ko, Burne and Mortensen2010).

Heritability estimates for vitamin D show much variation and some also seem to vary across season of measurement and sex. Heritability of vitamin D ranges from 0.43 in European adult twins (98.3% of these twins were female; Hunter et al., Reference Hunter, Lange, Snieder, MacGregor, Swaminathan, Thakker and Spector2001) to as high as 0.80 in the German Asthma Family Study Group (Wjst et al., Reference Wjst, Altmueller, Braig, Bahnweg and Andre2007). A study of male twins found vitamin D levels to be highly heritable during winter, but not heritable in summer (Karohl et al., Reference Karohl, Su, Kumari, Tangpricha, Veledar, Vaccarino and Raggi2010), while a study of male and female twins found vitamin D to be heritable in summer, but not during winter (Snellman et al., Reference Snellman, Melhus, Gedeborg, Olofsson, Wolk, Pedersen and Michaelsson2009). Sex differences have been observed with a study of vitamin D in rural Chinese adolescent twins estimating heritability at 0.86 for males and 0.17 for females (Arguelles et al., Reference Arguelles, Langman, Ariza, Ali, Dilley, Price and Wang2009).

With the clinical diagnosis of both MDD and schizophrenia likely to represent a biological heterogeneous group of disorders, identification of biomarkers that stratify patients for application of ‘stratified medicine’ is a direction worthy of further research (Kapur et al., Reference Kapur, Phillips and Insel2012). The study reported here represents preliminary research towards the goal of understanding the role of potential blood biomarkers (specifically plasma cytokine and vitamin D measures) of depression and psychosis. We could not find prior published heritability estimates for some of these cytokines. We used a population-based sample of healthy adolescent twins to assess the genetic and environmental contributions to variation in circulating levels of these potential biomarkers.

Methods

Samples

Participants were 16-year-old twins (mean 16.2 years, SD 0.25 years) from the Brisbane adolescent twin study (Wright & Martin, Reference Wright and Martin2004). In this sample, both plasma cytokine and dried blood spots (DBS) vitamin D measures were collected as part of a study focusing on health and well-being in an adolescent population sample. Plasma cytokine measures were available for 400 individuals (85 MZ twin pairs and 115 DZ twin pairs), DBS vitamin D measures were available for 378 individuals (70 MZ twin pairs and 118 DZ twin pairs, two twin pairs were incomplete). Of these twin pairs, 49 MZ twin pairs and 74 DZ twin pairs had data available for both plasma cytokine and vitamin D measures.

Blood was collected when twins came in for testing as close as possible to their 16th birthday. To explore impact of age of biological sample in this pilot study we selected individuals who participated either between the years 1997–2000 (wave 1) or between the years 2006–2009 (wave 2). Blood samples were available from these years both as plasma (for measurement of cytokines) and DBS (for measurement of vitamin D). DBS for the measurement of vitamin D were stored on Whatman 903 filter paper for wave 1, and on Whatman FTA cards impregnated with antibacterial agents to preserve DNA for wave 2. Blood of two members of a twin pair (i.e., co-twins) was always collected within the same wave.

Assay of Plasma Cytokine and Vitamin D Measures

Plasma cytokine measures

A total of 25 plasma cytokines and inflammatory markers were measured at the James Cook University, Townsville, Australia. Of these 25 markers, TGF-β1 and TNFR1 were assayed successfully. Specifically, plasma cytokines and inflammatory markers were divided into four separate groups, based on multiplexing compatibility with other cytokines and inflammatory markers with the groups as follows: Group 1: TGF-β1; Group 2: interleukin-2 (IL-2), IL-4, IL-7, IL-11, IL-12, IL-13, TNF-α, IL-17A, IL-21, Exotaxin, Granulocyte Macrophage Colony-Stimulating Factor (GM-CSF); Group 3: IL-1α, IL-1β, IL-3, IL-5, IL-6, IL-8, IL-9, IL-10, IFN-γ-inducible protein 10 (IP-10), Monocyte Chemo-attractant protein-1 (MCP-1), Macrophage inflammatory protein-1a (Mip-1a), IFN-γ; Group 4: TNFR1.

TGF-β1 and TNFR1 were measured individually (not part of the multiplex) due to not being compatible with other cytokines. For TGF-β1 (560429) we used the human TGF-β1Duoset ELISA kit (R&D). We used BD biosciences flex set multiplex assays at half strength (allowing double the number of samples) compared to the manufacturer's recommendations, supported by pilot analyses. Plasma samples were diluted four times before testing, consistent with observations from the kit manufacturer (and our own pre-experiment measurements) that undiluted plasma causes high background signal that interferes significantly with specific signals. Standard curves were generated using technical controls of lyophilized standard protein at a known concentration. In addition, for all cytokines and inflammatory markers an intra-assay experiment (to evaluate accuracy of the method) was run on 20 samples created from tissue culture medium spiked with standards. The experimental design for the plasma samples ensured that co-twins (two members of a twin pair) were randomized across plates.

Out of the cytokines measured in plasma, we found that only the two assays conducted for individual cytokines (TGF-β1 and TNFR1) not included in the multiplex generated meaningful results. For the multiplexed cytokines (groups 2 and 3), we found that although the technical controls (the intra-assay experiment) were measured accurately, the assay was not sufficiently sensitive to the low circulating levels in healthy adolescents following the recommended dilution of sample.

Given the poor outcome of cytokine assays from plasma samples, we also attempted to assay cytokines from DBS (Skogstrand et al., Reference Skogstrand, Ekelund, Thorsen, Vogel, Jacobsson, Norgaard-Pedersen and Hougaard2008). Inflammatory markers are more stable in DBS, with measurable concentrations of cytokines found to be stable in DBS stored at different temperatures for many days when compared to DBS frozen immediately after preparation (although long-term storage at –20 °C is considered optimal; Skogstrand et al., Reference Skogstrand, Ekelund, Thorsen, Vogel, Jacobsson, Norgaard-Pedersen and Hougaard2008). While measurable amounts of most cytokines have been found to be nearly constant in DBS stored up to 23 years, a marked decrease over time has been noted in measurable concentrations of IL-1β, IL-8, sIL-6ra, matrix metallopeptidase-9 (MMP-9), triggering receptor expressed on myeloid cells 1 (TREM-1), CRP, brain-derived neurotrophic factor (BDNF), and neurotrophin-4 (NT-4) in stored DBS (Skogstrand et al., Reference Skogstrand, Thorsen, Norgaard-Pedersen, Schendel, Sorensen and Hougaard2005). We found that the cytokine measures were sensitive to paper type (often generating null reads for one or other paper) and were subject to plate effects that could not be adjusted appropriately in an experimental design in which co-twins within a twin pair were present on the same plate. We also attempted to measure antibodies to infectious agents (Yolken et al., Reference Yolken, Torrey, Lieberman, Yang and Dickerson2011), another potential biomarker for MDD, but also found the assays to be highly sensitive to paper type and plate effects, and few individuals had non-null measures.

Vitamin D measures

The main circulating form of vitamin D is 25 hydroxyvitamin D3 (25(OH)D3) (Holick, Reference Holick2007). In our study, 25(OH)D3 was measured from DBS by liquid chromatography tandem mass spectroscopy (Eyles et al., Reference Eyles, Anderson, Ko, Jones, Thomas, Burne and McGrath2009; McGrath et al., Reference McGrath, Eyles, Pedersen, Anderson, Ko, Burne and Mortensen2010) at the University of Queensland, Brisbane, Australia. The assay method is highly sensitive, and can measure 25(OH)D3 in DBS stored for between 8 and 22 years (Eyles et al., Reference Eyles, Anderson, Ko, Jones, Thomas, Burne and McGrath2009). With this method, assay calibrants are extracted and derived in the same way as clinical samples, using multi-point calibration curves (Eyles et al., Reference Eyles, Anderson, Ko, Jones, Thomas, Burne and McGrath2009). Co-twins were plated in adjacent wells on the same plate. As Whatman FTA paper is thicker than 903 and therefore absorbs more blood, standards were prepared on both paper types in accordance with previous studies (Kvaskoff et al., Reference Kvaskoff, Ko, Simila and Eyles2012).

For the measurement of 25(OH)D3, the experimental design for the DBS was not ideal for partitioning of variance as co-twins of the same pair were plated in neighboring wells of the same plate. Under this design, batch effects are common to the twin pair so will be partitioned into the common environmental component. In contrast, if co-twins of a twin pair are plated randomly, batch effects will partition into the unique environment variance component. The DBS plating layout had been established for a different study interested in differences between twin pairs in blood markers. The static associated with tiny blood spots meant that replating was not practical. However, the extensive technical controls implemented in the 25(OH)D3 assay eliminated plate effects and so confounding of plate and twin pair was not an issue.

Statistical Analyses

To account for non-normality of the data, a square root transformation was applied to TGF-β1. Subsequently, TGF-β1 and TNFR1 were standardized and effects of plate and year of blood sampling were regressed out. For 25(OH)D3, which is largely affected by seasonal differences in ultra violet exposure, a cosinor regression model was fitted to the data to adjust for seasonality; additionally, possible effects of sex, year of blood sampling, and paper type (Barnett & Dobson, Reference Barnett and Dobson2010) were regressed out. Year of blood sampling did not have a significant effect on any measure.

A saturated model was fitted to the residuals to estimate MZ and DZ twin correlations for cytokines TGF-β1 and TNFR1 and for 25(OH)D3. A saturated model does not hold any assumptions regarding the underlying variance components model. Means and variances were constrained to be equal across zygosity groups, and twin correlations were constrained to be equal for same-sex DZ and opposite-sex DZ twin pairs to improve stability of the genetic model. Within the saturated model, differences in means and variances between first- and second-born twins and between zygosity and sex (and BMI for 25(OH)D3) were tested using likelihood ratio tests.

To investigate the relative contributions of genetic and environmental factors to the observed variation in TGF-β1, TNFR1, and 25(OH)D3, univariate variance components models were specified. The analysis of 25(OH)D3 was done in the full sample as well as separately, including individuals who had their blood collected in summer or winter (where the months, May to October inclusive were considered winter, and November to April inclusive were considered summer in the southern hemisphere). Within these models, the variance was partitioned into additive genetic (A), common environmental (C), and unique environmental (E) variance components. ‘A’ represents the additive genetic effects of alleles summed up over all genetic loci in the genome, ‘C’ represents shared or common environmental factors that render offspring of the same family more alike, and ‘E’ represents environmental factors that result in differences between family members. ‘E’ also includes measurement error.

To examine the significance of estimated variance components, the fit of a nested (increasingly more restricted) model was compared to the fit of the full model. Two submodels were considered: (1) a model including A and E, and (2) a model including C and E. Goodness-of-fit of these submodels was assessed using likelihood ratio tests. The difference in log-likelihoods between the full (ACE) model and the reduced (AE or CE) model follows a χ2-distribution and was evaluated using a χ2-difference test. If the χ2-difference test is significant, the estimate of the variance component that is removed from the model (e.g., C in an AE model) is considered significantly larger than zero. If the χ2-difference test is not significant, the estimate of the variance component that is removed from the model is not significantly larger than zero. Twin correlations and variance components were estimated in the statistical software package Mx (Neale et al., Reference Neale, Boker, Xie and Maes2006).

Results

Means and variances of raw values for TGF-β1, TNFR1, and 25(OH)D3 are shown in Table 1. For TGF-β1 and TNFR1 we were not able to find an agreed normal reference range to which we could compare our results, vitamin D levels were within the normal range (Paxton et al., Reference Paxton, Teale, Nowson, Mason, McGrath, Thompson and Munns2013). For TNFR1, we observed a significant difference in means between males and females, with males having higher levels than females (p < .001). For 25(OH)D3, we observed significant differences in variances (p = .001) between MZ and DZ twins (with MZ twins having on average higher levels and larger variance compared with DZ twins) and a birth order effect in both means (p < .05) and variances (p < .01) (with first-born twins having on average lower levels of vitamin D and smaller variance). We expect the effects of zygosity and birth order to be a result of the sampling variance. The phenotypic correlations between the vitamin D and the two cytokine measures were not significantly different from zero.

TABLE 1 Means, Variances (of Raw Values), and Twin Correlations (with 95% Confidence Intervals) for Transformed Values of TGF-β1, TNFR1, and 25(OH)D3

rMZ = monozygotic twin pair correlation; rDZ = dizygotic twin pair correlation; A = males and females combined; M = males; F = females. TGF-β1 and TNFR1: Measured in ng/ml; Number twin pairs = 85 MZ, 115 DZ. 25(OH)D3: Measured in nmol/L; Number twin pairs = 70 MZ, 118 DZ.

MZ correlations were significantly higher than DZ correlations for TGF-β1 and 25(OH)D3, and approached significance for TNFR1 (Table 1), suggesting a genetic component in the variance decomposition. Given the small sample size, we did not estimate heritability separately for males and females. Twin correlations, however, were very similar for males and females, suggesting no differences in heritability estimates across sex in our data (Table 1).

Sex was included as a covariate in the means model in the genetic analyses. We did not include sex as a covariate in the variance model, nor did we consider birth order effects in our genetic models. Including those effects in our genetic models would greatly reduce power given the current sample size, which in turn would probably lead to spurious results.

Within the genetic model, the two cytokines were found to be moderately heritable (Table 2), with heritabilities estimated at 0.57 (95% CI 0.26–0.80, χ2 = 12.49, p = <.001) and 0.50 (95% CI 0.11–0.63, χ2 = 5.9, p = .008) for TGF-β1 and TNFR1, respectively. Heritability of 25(OH)D3 (all months combined) was estimated to be high (0.86, 95% CI 0.61 – 0.94, χ2 = 55.98, p = <.001) (Table 2). Heritability of 25(OH)D3 for individuals who had blood collected in the summer months was also high (0.90, 95% CI 0.60 – 0.94, χ2 = 25.43, p = <.001), while heritability for individuals who had blood collected in winter was moderate (0.56, 95% CI 0.31–0.92, χ2 = 23.023, p = .001). For the cytokines TGF-β1 and TNFR1, any plate or batch effects would tend to increase the unique environment variance component.

TABLE 2 Heritabilities of TGF-β1, TNFR1, and 25(OH)D3 (with 95% Confidence Intervals)

A = standardized additive genetic variance; C = standardized common environmental variance; E = standardized unique environmental variance.

Discussion

We set out to determine if potential biomarkers for MDD and schizophrenia were heritable in a community cohort of healthy adolescent twins. Mean levels of circulating vitamin D, measured as 25(OH)D3, were in the normal range for healthy Australian adolescents (Paxton et al., Reference Paxton, Teale, Nowson, Mason, McGrath, Thompson and Munns2013). The differences in variances observed for 25(OH)D3 may have been due to chance. The heritability estimates of the two cytokines that could be measured in plasma were found to be moderate (57% and 50% for TGF-β1 and TNFR1, respectively) while the heritability of vitamin D was found to be high (86%).

The heritability estimate for the standardized values of vitamin D was similar to the heritability of 0.80 found for vitamin D — specifically also 25(OH)D3 in the German Asthma Family Study Group (Wjst et al., Reference Wjst, Altmueller, Braig, Bahnweg and Andre2007), and 0.86 found for 25(OH)D (as 25(OH)D3) in male rural Chinese adolescent twins (Arguelles et al., Reference Arguelles, Langman, Ariza, Ali, Dilley, Price and Wang2009) — but greater than the estimate of 0.43 estimated in adult twins from the St Thomas UK Adult Twin Registry (Hunter et al., Reference Hunter, Lange, Snieder, MacGregor, Swaminathan, Thakker and Spector2001). Similar to Snellman et al. (Reference Snellman, Melhus, Gedeborg, Olofsson, Wolk, Pedersen and Michaelsson2009), we found the heritability estimate of vitamin D to be higher in the summer months. This was in contrast to another study, which observed heritability of vitamin D to be higher in winter months (Karohl et al., Reference Karohl, Su, Kumari, Tangpricha, Veledar, Vaccarino and Raggi2010). The only previous published report we could find estimating the heritability of TGF-β1 found a heritability of 0.28; however, the levels of this cytokine were estimated in an antigen-stimulated whole-blood assay (Stein et al., Reference Stein, Guwatudde, Nakakeeto, Peters, Elston, Tiwari and Whalen2003). We could not find published reports of heritabilities of TNFR1 to which to compare our results.

A genetic contribution to variation in circulating levels of cytokines TGF-β1 and TNFR1 and vitamin D is potentially relevant in the etiology of MDD and schizophrenia, as each of these biomarkers may contribute to a role in the etiology of these disorders. Here we show the variance of these biomarkers is largely genetic, while changes in environmental factors appear to have less influence. Variants in the major histocompatibility complex (MHC) region have been associated with schizophrenia (Ripke et al., Reference Ripke, Sanders, Kendler, Levinson, Sklar and Holmans2011; Reference Ripke, Neale, Corvin, Walters, Farh and Holmans2014), and many of the genes of this region code for cytokines (Shiina et al., Reference Shiina, Hosomichi, Inoko and Kulski2009). This association does not appear to be driven by the high linkage disequilibrium in the extended MHC (Ripke et al., Reference Ripke, Neale, Corvin, Walters, Farh and Holmans2014). With the complexity of the MHC region presenting challenges in understanding its role in schizophrenia (Lehner, Reference Lehner2012), further study of shared genetic factors between these biomarkers and schizophrenia is warranted. The possibility of shared genetic factors between these biomarkers and MDD could also be investigated in future studies.

It should also be noted that although we did not find a strong positive phenotypic association between cytokines and vitamin D measures, this was to be expected. Stimulation of human CD4+CD25-T lymphocytes in the presence of 1, 25(OH)2D3 has been shown to inhibit production of pro-inflammatory cytokines, including IFN-γ and IL-17 (Jeffery et al., Reference Jeffery, Burke, Mura, Zheng, Qureshi, Hewison and Sansom2009). Low levels of plasma 25(OH)D3 have been associated with chronic disease where inflammation has been found to play an important role, such as type 2 diabetes (Ozfirat & Chowdhury, Reference Ozfirat and Chowdhury2010). This finding may not diminish the potential usefulness of these blood biomarkers, rather it suggests that the role of vitamin D deficiency in inflammation may be an area where further research is warranted (Yin & Agrawal, Reference Yin and Agrawal2014).

A limitation of our study is that healthy adolescents are expected to have very low levels of circulating inflammatory cytokines (Miller et al., Reference Miller, Buckley, Seabolt, Mellor and Kirkpatrick2011). This may explain why our initial ELISA multiplex assay performed on plasma samples was not sufficiently sensitive (i.e., did not generate usable results) to the circulating levels of cytokines in our healthy community cohort of adolescents. This was despite the assay being calibrated to standardized adult samples (McAfoose et al., Reference McAfoose, Koerner and Baune2009). To address the limitation of assay sensitivity, high-sensitivity assays (such as ELISA single assays or high sensitivity kits based on the Luminex 200 system) can be used. ELISA assays utilize undiluted samples, but they usually need high volume of sample (up to 500μL per sample). A limitation of the TGF-β1 assay was the volume of sample required. The human TGF-β1 Duoset ELISA used required 100 μl of sample. This was higher than the volume of aliquots available, so we decreased the sample volume used to 50 μl. In addition, the release of TGF-β1 from platelet granules upon platelet activation also needs to be considered. Our protocol should remove platelets from the plasma sample but incomplete removal of platelets, which can cause variable and irreproducible results (Flislak et al., Reference Flislak, Jaroszewicz, Lapinski, Flislak, Rogalska and Prokopowicz2005), would serve to reduce estimates of heritability.

Recommendations for future studies could include extending this research to adolescents with MDD or schizophrenia (or psychotic symptoms) and conducting both univariate and bivariate analyses to investigate to what extent genetic impact on circulating levels of cytokines and vitamin D are heritable and whether the same genes affect these measures in people with psychiatric disorders such as MDD and schizophrenia. However, high sensitivity assays (such as ELISA single assays), with larger sample sizes would be required. This could be followed by investigating the role of other potential blood biomarkers (such as CRP and antibodies to infectious agents) in adolescents with MDD or psychosis.

Conclusion

This study reports heritability estimates of cytokines/inflammatory markers and vitamin D in a community-based cohort of adolescent twins. The heritability estimate for vitamin D was high, whereas the two cytokines that could be measured in plasma showed moderate heritabilities. As presented in the published literature, we found measurement of cytokines at the levels circulating in healthy adolescents to be difficult, perhaps limiting their utility. Further research (which takes into account the limitations of our present study) is warranted to explore the potential uses of these biomarkers, in particular in adolescents with mental health disorders.

Ethical Standards

The authors assert that all procedures contributing to this work comply with the ethical standards of the relevant national and institutional committees on human experimentation and with the Helsinki Declaration of 1975, as revised in 2008.

Acknowledgments

We thank the Brisbane twins and siblings for their participation; Marlene Grace and Ann Eldridge for sample collection; Kerrie McAloney for study coordination; Anthony Conciatore for IT support, Leanne Wallace and the Molecular Genetics Laboratory for sample preparation. The research was supported by Rotary Mental Health, the Australian Research Council (A7960034, A79906588, A79801419, DP0212016, DP0343921) and by the National Health and Medical Research Council (389891, 1049911, 1069141).

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Figure 0

TABLE 1 Means, Variances (of Raw Values), and Twin Correlations (with 95% Confidence Intervals) for Transformed Values of TGF-β1, TNFR1, and 25(OH)D3

Figure 1

TABLE 2 Heritabilities of TGF-β1, TNFR1, and 25(OH)D3 (with 95% Confidence Intervals)