ABSTRACT
Trisomy 21 (T21) causes the condition known as Down syndrome (DS), with clear impacts on brain development and function. In a previous paper (Sullivan, 2016) we showed that T21 consistently activates the interferon (IFN) response, but the contribution of IFN hyperactivity to DS phenotypes awaits elucidation. Here, we report the results of a large plasma metabolomics study, showing that T21 disrupts tryptophan catabolism toward increased production of kynurenine (KYN) and its neurotoxic derivative quinolinic acid. We also show that stimulation of IFN signaling leads to tryptophan depletion, over-production of KYN, and super-induction of IDO1, the rate-limiting enzyme in the KYN pathway, in human cells with T21 and a mouse model of DS. Finally, cytokine profiling revealed a positive correlation between circulating levels of IFNα and KYN dysregulation in people with DS. Altogether, these results reveal a mechanism by which IFN hyperactivity could drive cognitive deficits and neurodegeneration in DS.
INTRODUCTION
Down syndrome (DS) is caused by triplication of chromosome 21 (trisomy 21, T21), which occurs in approximately 1 in 700 live births, representing the most common chromosomal abnormality in the human population (1). T21 impacts multiple organ systems during development and causes an altered disease spectrum in people with DS, significantly increasing their risk of developing Alzheimer’s disease (AD), leukemia, and numerous autoimmune conditions (1-7), while protecting them from solid malignancies (8, 9). However, DS-associated phenotypes are highly variable among individuals with DS, even for conserved phenotypes such as cognitive impairment and predisposition to early onset AD (2, 10). Therefore, a deeper understanding of the mechanisms driving such phenotypic variation could illuminate not only mechanisms of pathology, but also opportunities for diagnostics and therapeutic strategies to serve this special population.
In order to identify molecular pathways that could contribute to both the altered disease spectrum experienced by the population with DS as well as the inter-individual variation among phenotypes, our group previously analyzed transcriptomes (11) and circulating proteomes (12) from several cohorts of individuals with DS compared to euploid individuals (D21, controls). These efforts revealed that multiple cell types from people with T21 show transcriptional signatures indicative of constitutive activation of the interferon (IFN) response (11), which could be explained by the fact that four of the six IFN receptors are encoded on chr21 (13). Furthermore, plasma proteomics analyses demonstrated that people with DS show signs of chronic autoinflammation (12), including elevated levels of potent inflammatory cytokines with known ties to IFN signaling (e.g. IL-6, TNF-α). However, it remains to be defined how this obvious immune dysregulation contributes to highly variable DS-associated phenotypes, including the diverse neurological manifestations of T21. To gain further insight into this area, we investigated metabolic changes caused by T21 in the plasma of people with DS.
Here, we report the results of the largest plasma metabolomics study of individuals with DS to date using untargeted, highly sensitive liquid chromatography mass spectrometry (LC-MS) technology. We discovered dysregulation of a number of inflammation-associated metabolites, such as succinate and 2-hydroxyglutarate (14, 15), in individuals with DS. However, most prominent among the dysregulated metabolites were those related to tryptophan catabolism. Specifically, people with DS showed highly statistically significant upregulation of kynurenine (KYN) and its neurotoxic derivative quinolinic acid (QA) (16). Using an unbiased, machine learning approach to build a predictive metabolic signature of T21, we found that select metabolites in the tryptophan pathway, along with other inflammation-associated metabolites, can accurately distinguish plasma from individuals with DS from euploid controls. Using cell-based metabolic flux assays, we found that IFN-α stimulation leads to profound depletion of tryptophan in T21 cells, along with markedly increased production of KYN, which could be explained by overexpression of IDO1, the rate-limiting enzyme in the KYN pathway and a known interferon stimulated gene (17). We found that a mouse model of DS that includes triplication of the IFN receptor gene cluster, Dp(16)1/Yey, has increased levels of KYN relative to wild type littermates, and produces more KYN when injected with the IFN-stimulating molecule poly(I:C). Given the well-established roles of KYN dysregulation on a wide range of neurological conditions (18-20), our results suggest that IFN-dependent activation of the KYN pathway could contribute to key neurological phenotypes in DS.
RESULTS
Trisomy 21 causes consistent changes in plasma metabolite abundance
In order to identify metabolic pathways that are consistently dysregulated by T21, we collected plasma samples from two fully independent cohorts: the Translational Nexus Clinical Data Registry and Biobank (referred hereto as Cohort 1), and the Crnic Institute’s Human Trisome Project (www.trisome.org, NCT02864108, referred hereto as the Cohort 2). Cohort 1 included 49 individuals with T21 and 49 euploid (D21) individuals, while Cohort 2 consisted of 30 T21 and 41 D21. The breakdown of patients according to age and sex are reported in Table 1. While the Cohort 1 is balanced for karyotype but imbalanced for age, Cohort 2 is more age-balanced, with a bias towards females in both D21 and T21 groups. When the two cohorts are combined, age, sex, and karyotype are more evenly distributed, which prompted us to analyze the cohorts both individually and in combination. Because the variables of age, sex, and cohort-specific features (e.g. protocol for sample collection, processing and storage), can influence metabolite abundance and/or detection, we accounted for these variables when determining the impact of karyotype as described below.
To determine metabolite abundance, we performed untargeted, LC-MS metabolomics on plasma from each cohort. The combined analysis workflow is outlined in Figure 1 – figure supplement 1A with details available in the Materials and Methods. This approach led to the identification of 91 high-confidence metabolites detected in both cohorts. To identify those that are consistently differentially abundant between people with and without DS, we employed a robust linear model-fitting approach that accounted for age, sex, and cohort (21). We arrived at this model after evaluating each of these variables in the cohorts individually, as well as in combination. Using the 91-metabolite panel, we first evaluated the impact of age and sex within each cohort. We fit linear models and compared the results within Cohort 1, where we included or excluded the variables age and sex directly in the model (Figure 1 – figure supplement 1B). We found that taking age and sex into account directly impacted the differential abundance statistics when comparing T21 to D21 individuals; this result was expected given the differences in age and sex seen in Cohort 1. We performed the same comparison within Cohort 2 (Figure 1 – figure supplement 1C) and found similar results, although age and sex had less of an impact as Cohort 2 is more balanced. The differences observed between cohorts motivated us to evaluate the impact of a combined cohort analysis, with the goal of mitigating the biases within each of the individual cohorts and increasing our statistical power with a greater number of individuals.
Integrating data across cohorts required us to evaluate the impact of each cohort as a batch effect. Indeed, we observed strong differences in the distributions of metabolite abundances between cohorts (Figure 1 – figure supplement 2A). By using the same linear model fit, while additionally including the cohort as the batch covariate in the model, thus accounting for age, sex, and cohort, the distributions of metabolite abundance became overlapping and comparable (Figure 1 – figure supplement 2B). We confirmed the impact of the cohorts as a model covariate using principal components analysis (PCA), showing that the first principal component can explain the variation seen between cohorts (Figure 1 – figure supplement 2C). After accounting for patient cohort, along with age and sex in the model, the first two principal components no longer account for variation that can be attributed to the modeled covariates (Figure 1 – figure supplement 2D), indicating that the two cohorts can be combined to find metabolite changes that are attributable to karyotype rather than systematic effects associated with age, sex, and cohort-specific variables.
When the combined total of samples in the two cohorts were analyzed for the 91 metabolites using the linear model fit including age, sex, and cohort covariate, we identified 16 metabolites that are significantly differentially abundant according to a Benjamini-Hochberg adjusted p-value cut-off of 0.01 (Figure 1A, Supplemental File 1A). Of these, seven were less abundant in the plasma of individuals with T21 and nine were more abundant.
Among the significantly depleted metabolites are the amino acids L-serine and L-tyrosine, consistent with earlier reports (22, 23) (Figure 1A-B). Depletion of L-homocysteine (Figure 1A-B), which has also been previously observed in people with DS (24), could be attributed to the localization of the cystathionine-beta-synthase gene (CBS) on chr21. Among upregulated metabolites we observed succinate and 2-hydroxyglutarate, two metabolites related to the TCA cycle (Figure 1A-B). Elevated succinate levels have been previously reported in people with DS and interpreted as a sign of mitochondrial dysfunction (23), but succinate upregulation is also an established marker of inflammation (14). Other upregulated metabolites include the antioxidant molecules dehydroascorbate and mannitol (Figure 1A-B) (25, 26). In order to identify metabolic pathways that were systematically dysregulated in individuals with T21, we performed an unbiased pathway enrichment analysis. We tested a total of 52 KEGG pathways (27) that had at least 5 metabolites included in our 91 metabolites (Supplemental File 1B). Using a hypergeometric test, the most significantly enriched pathway was Tryptophan Metabolism (p-value = 0.002, adj. p = 0.096). In fact, of the 11 tryptophan catabolic metabolites annotated in this pathway and detected in our analysis, five are differentially abundant: KYN, QA and 5-hydroxyindoleacetate are upregulated, while indole and indole-3-acetaldehyde are downregulated (Figure 1C). As noted later, depletion of L-serine could also be related to dysregulated tryptophan metabolism (Figure 1A-B, see later Figure 3 – figure supplement 2).
A signature of tryptophan catabolites and inflammatory metabolites accurately stratifies plasma samples from individuals with trisomy 21
Next, we employed a machine-learning approach to investigate whether metabolites identified with our platform could be used to stratify plasma samples provided from individuals with or without DS (see Materials and Methods for details). As a baseline for comparison, we established the predictive power of each of the 16 differentially abundant metabolites (Figure 2A). To achieve this, we used metabolite abundance as a predictor of T21 that we evaluated using receiver operatic characteristic curves (ROC), which compares the true positive rates (TPR) to false positive rate (FPR). Interestingly, QA had the most predictive value (AUC = 0.73) (Figure 2A). Next, to determine the predictive potential of multivariate plasma metabolic profiles to distinguish T21 from D21, we prioritized metabolites based on their predictive value using a lasso regression feature selection approach (28). To achieve this, we trained 10,000 independent, 5-fold cross-validated lasso regression models on the combined data set of both cohorts to identify metabolites that were consistently selected in models with high predictive value. The coefficients of an individual metabolite reflect the metabolite’s weight in that model, thus we selected the metabolites with the greatest average coefficient weights that were consistently selected in over 80% of the trained models with an accuracy > 0.9. This analysis yielded 11 metabolites, of which eight had positive model coefficients and three had negative model coefficients (Figure 2B). These 11 metabolites included seven of the 16 most differentially abundant metabolites and an additional four from the remaining 75 metabolites in our analysis, demonstrating that this approach is not simply selecting the most differentially abundant metabolites, but rather the model is selecting the groups of metabolites that together provide the strongest predictive power. The most frequently selected metabolites included three members of the tryptophan metabolism pathway: QA, KYN, and 3-indole-acetaldehyde (Figure 2B). Of note, these three metabolites were selected in 100% of models with > 90% accuracy, while acyl-C5:1 had the largest median positive model coefficient. Next, we evaluated the predictive power across the combined Nexus and HTP cohort using the selected most predictive 11 metabolites. We performed a bootstrapped analysis using a lasso regression to benchmark model performance. We split the combined cohort to train the model on 80% of the participants (randomly selected) and tested performance using the held-out 20%. We repeated this process for 10,000 iterations and found an average model performance of AUC=0.88 with a 95% confidence interval of [0.76, 0.97] (Figure 2C).
These results demonstrate that there is strong predictive power within a small group of plasma metabolites for stratifying T21 individuals from D21 individuals. Also, using an independent methodology, these results confirm that differential tryptophan metabolism is a major contributor to the distinguishing metabolic profile of people with DS, which prompted us to investigate this result in more depth.
Trisomy 21 induces the kynurenine pathway
In vertebrate cells, there are three major catabolic pathways for tryptophan, leading to the production of serotonin, KYN, or indole (Figure 3). There is a 10% decrease in L-tryptophan levels in individuals with T21, though it does not rise to the level of significance (p = 0.05, adjusted p = 0.12) (Figure 3, Supplemental File 1A). There is also an approximately 10% decrease in serotonin, which is not significantly different between T21 and D21. However, 5-hydroxyindoleacetate (5-HIA), a breakdown product of serotonin, is significantly elevated in the group with T21 (adjusted p = 3e-3) (Figure 3). Conversion of tryptophan to KYN represents a major pathway for catabolism of ingested tryptophan, accounting for removal of up to 99% of this amino acid that is not used in protein synthesis (29). Remarkably, KYN itself and the neurotoxic downstream product QA, are significantly elevated in people with DS (Figure 3). In contrast, picolinic acid (PA), a neuroprotective derivative of KYN, is not different between the two groups (Figure 3). Kynurenic acid (KA), another neuroprotective metabolite in the pathway, was detected only in Cohort 2 and was not affected by karyotype (Figure 3 – figure supplement 1A). Accordingly, the KYN/tryptophan, QA/PA, and QA/KA ratios are all significantly higher in people with DS (Figure 3 – figure supplement 1B-D). Notably, indole and its derivative indole-3-acetaldehyde, both of which are significantly decreased in the T21 group (Figure 3), are metabolites produced from tryptophan by tryptophanase-expressing gastrointestinal microbiota (30, 31). Interestingly, indole can also be employed by the gut microbiota to synthesize tryptophan in a reaction that consumes L-serine (31), an amino acid that is significantly depleted in the plasma of people with DS (Figure 3 – figure supplement 2). Thus, lower levels of indole and L-serine could be interpreted as a sign of increased tryptophan biosynthesis by the gut microbiome to sustain levels of this essential amino acid when it is shunted into the KYN pathway in people with DS.
Altogether, our results indicate that a major metabolic impact of trisomy 21 is a dysregulation of tryptophan catabolism toward increased production of the neurotoxic metabolites in the KYN pathway. This is an important result, because activation of the KYN pathway has been implicated in myriad neurological and neurodegenerative disorders. Repeatedly, elevations in the KYN/tryptophan ratio, QA/PA, and/or QA/KA ratios have been linked to the development of neurological conditions such as Alzheimer’s disease (32-35), Huntington’s disease (36, 37), AIDS/HIV-associated neurocognitive disorder (38-40), Parkinson’s disease (41), amyotrophic lateral sclerosis (42, 43), and multiple sclerosis (44, 45).
Trisomy 21 sensitizes cells to super-induction of the KYN pathway upon IFN stimulation
In order to further investigate the mechanism of KYN dysregulation in DS, we employed cell-based metabolic flux experiments using isotope-labelled tryptophan on a panel of age-and sex-matched skin fibroblasts with and without T21. Of note, the rate-limiting step in the KYN pathway is the conversion of L-tryptophan into N-formyl-kynurenine, a reaction catalyzed by the tryptophan 2,3 dioxygenase 2 (TDO2) enzyme in the liver or the indoleamine 2,3 dioxygenases 1 and 2 (IDO1-2) enzymes elsewhere (17). Importantly, IDO1 is a well-recognized IFN-stimulated gene (ISG) whose expression can be induced by Type I (α/ β) and Type II (γ) IFN ligands (46-50). Given our previous finding that T21 fibroblasts are hypersensitive to IFN-α, β, and γ stimulation (11), we performed these experiments before and after IFN-α stimulation. Remarkably, IFN-α stimulation produced a significant, time-dependent depletion of tryptophan in T21 cells, but not supernatant (Figure 4A, Figure 4-figure supplement 1A, Supplemental File 1C), concurrent with a significant increase in KYN levels in the supernatant, but not cells (Figure 4B, Figure 4 - figure supplement 1B). The restriction of isotope-labeled tryptophan depletion to the cells is likely due to isotope-labeled tryptophan being far in excess in the supernatant. Accordingly, the KYN/tryptophan ratio was significantly elevated upon IFN-α stimulation only in T21 supernatants and cells (Figure 4 - figure supplement 1C,D), and most prominent between KYN in the supernatant and tryptophan in the cells, consistent with consumption of intracellular tryptophan and subsequent secretion of KYN (Figure 4C). Matched Western blot analysis showed that T21 fibroblasts display stronger induction of STAT1 phosphorylation (a transcription factor driving IDO1 transcription) and subsequent IDO1 expression at the protein level, than in D21 cells (Figure 4D). In fact, after 24 hours of IFN-α treatment, all three T21 cell lines employed in the metabolic flux assay expressed much higher levels of IDO1 relative to their diploid counterparts (Figure 4E).
Together, these results provide a mechanistic explanation for the observed dysregulated levels of tryptophan catabolites in plasma of people with DS, whereby T21, likely via overexpression of the four IFNRs encoded on chr21, would provoke a systemic hyper-sensitivity to IDO1 induction in response to IFN signaling.
Tryptophan catabolism is selectively disrupted in the Dp(16)1/Yey mouse model of DS
To test the impact of various groups of genes encoded on human chr21 on tryptophan metabolism, we employed three cytogenetically distinct mouse strains carrying segmental duplications syntenic to human chr21 (51): Dp(10)1/Yey (Dp10), Dp(16)1/Yey (Dp16), and Dp(17)1/Yey (Dp17), which have triplication of ∼35 genes from mouse chr10, ∼120 genes from chr16, and ∼20 genes from chr17, respectively, and compared them to wild type C5Bl/6 mice (WT). We prepared plasma samples from age-and sex-matched cohorts comprised of these strains and measured kynurenine using LC-MS. Interestingly, we found that the only strain with significantly increased plasma KYN levels relative to WT mice was the Dp16 model, which is not only the largest segmental duplication, but the one harboring the four IFN receptors homologous to those found on human chr21: Ifnar1, Ifnar2, Ifngr2, and, Il10rb (Figure 5A). Furthermore, we and others have previously shown that not only are the IFN receptors overexpressed in this model, but downstream IFN signaling is chronically activated on numerous tissues including blood and brain (11, 52). Therefore, we focused exclusively on this model in subsequent studies. To determine the impact of further stimulation of IFN signaling on altered tryptophan catabolism in Dp16 mice, we chronically injected age and sex-matched Dp16 and WT mice with the synthetic dsRNA polyinosinic:policytidylic acid (poly(I:C)) or a sham control using an established protocol (53), and collected plasma samples. Poly(I:C) activates pattern recognition receptors including TLR3, RIG-I/MDA5, and PKR, with subsequent upregulation of Type I IFN production and concomitant downstream signaling (54). Metabolomic analysis of WT mice revealed modestly increased levels of KYN in poly(I:C)-treated-group relative to the Sham-injected control group; however, only the Dp16 mice displayed statistically significantly higher levels of KYN when injected with poly(I:C) (Figure 5B).
These results are consistent with a gene-specific component to dysregulation of the KYN pathway and further implicate triplication of the IFN receptor locus as a key contributor. Moreover, they demonstrate the heightened sensitivity of an IFN receptor-triplicated model to KYN production in response to IFN stimulation at the organismal level.
Kynurenine dysregulation positively correlates with circulating levels of IFNα and downstream cytokines
Recently, we reported the results of the largest plasma proteomics study of people with DS to date (12), which revealed that T21 causes changes in the circulating proteome indicative of chronic autoinflammation, including elevated levels of many cytokines acting downstream of IFN signaling. Hence, we decided to test whether there was a correlation between inflammatory markers and KYN dysregulation. Toward this end, we measured a panel of 38 cytokines using a Mesoscale Discovery (MSD) assay in 37 participants in Cohort 2, 18 of them with DS, the other 19 being mostly age-and sex-matched typical controls. We calculated Spearman’s correlation between specific metabolites of interest versus all cytokines measured. Strikingly, the top cytokine positively correlated with KYN levels among those with DS was IFN-α2a (ρ = 0.67, Figure 6A). In fact, most of the cytokines positively correlated with KYN levels (ρ > 0.3) are known to be induced by IFN signaling in various settings, such as MCP-1, IL-33, IL-31, IP-10, IL-8, MIP-1α, MCP-4, IL-27, and TNF-α (55-69). In most cases, the positive correlation was unique to people with DS (see for example IFN-α2a, MCP-1, Figure 6B, C). A similar result was obtained for the QA correlation analysis, with the top positively correlated markers being MCP-1 (CCL2) and MCP-4 (CCL13), two known IFN-inducible monocyte chemotactic proteins (61, 65) (Figure 6D). Once again, most positively correlated cytokines (ρ > 0.3) are known to act downstream of IFN signaling (55-69). As for KYN, the correlations were unique to or more pronounced in people with DS (see for example MCP1 and MCP4 (Figure 6E,F)).
Altogether, the combination of correlative studies in plasma samples and cause-effect relationships using cell-based assays support the notion that dysregulation of tryptophan metabolism in DS is driven by hyperactive IFN signaling downstream of T21.
DISCUSSION
The developmental and clinical impacts of T21 in the population with DS are highly variable, with a large number of co-morbidities showing increased prevalence in this population relative to typical people. Despite many research efforts in this area, little is known about the molecular pathways that drive the various co-morbidities common in DS. Clearly, identification of these pathways would facilitate the design of diagnostic and therapeutic strategies to serve this at-risk population via precision medicine approaches. An obvious impact of these approaches would be in the management of diverse neurological conditions showing increased prevalence in this population, including, but not restricted to, early onset AD (3, 10, 70, 71), epilepsy (72), depression (73), and autism (74, 75). Our results point to dysregulation of the KYN pathway as a potential contributing factor to the development of these conditions in people with DS, with obvious diagnostics and therapeutic implications as described below.
People with DS constitute the largest population with a strong predisposition to AD, which is attributed to the fact that the APP gene is located on chr21 (3, 70, 71, 76), and that APP duplication causes familial early onset AD in the typical population (77). By age 40, virtually all individuals with DS present the brain pathology of AD; however, the age of dementia diagnoses is highly variable, with some individuals being diagnosed in their 30’s, while others remain dementia-free in their 70’s (78, 79). Therefore, the population with T21 provides a unique opportunity to identify mechanisms that either accelerate or delay AD development. The results in this report, when integrated with a significant body of literature, support the existence of an IFN?IDO1?KYN signaling pathway that could accelerate AD onset and progression in people with DS. First, it is clear that people with DS display chronic immune dysregulation with clear ties to IFN signaling. We recently reported a comprehensive analysis of the circulating proteome of people with DS (12), which revealed clear signs of immune dysregulation across the lifespan. These, and other efforts in the field (80), have identified a core set of inflammatory markers elevated in people with DS, including MCP-1, IL-6, TNF-α and IL-1β, all of which are known to be induced by IFN signaling and whose levels are both elevated in typical people with AD and positively associated with AD progression (55, 81-83). Here, we show that circulating levels of IFN-α2a and MCP-1 positively correlate with dysregulation of the KYN pathway (Figure 5), which has been repeatedly associated with AD development (see below) (32, 35, 84, 85). Second, T21 consistently activates the IFN transcriptional response across diverse cell types, including circulating immune cells (11), which is likely due to the fact that four of the six IFNRs are encoded on chr21 (86). Accordingly, T21 cells are hypersensitive to IFN ligands and show significant overexpression of ISGs (11, 86-88), including IDO1, the rate limiting enzyme in the KYN pathway. Pioneering work by Dr. Leonard Maroun and colleagues showed that reduction of IFN signaling in the early Ts16 mouse model of DS, with either anti-IFN antibodies or by crossbreeding with a strain lacking two IFNRs, improved embryonic development and increased survival of cortical neurons in vitro (89-91). Additionally, connections between IFN signaling and T21 were established as early as in the 1970s (13, 92-94), but never explored fully. Third, IFN signaling is likely to promote neuropathology and AD progression both upstream and downstream of amyloid deposition. IFN signaling was shown to enhance APP expression and processing into the pathological amyloid peptide, Aβ 1-42, leading to increased amyloid plaque formation (95, 96). Furthermore, in mouse models of AD, IFN signaling was shown to mediate neuroinflammation, neuronal cell death, and cognitive decline downstream of amyloid plaque formation (96-99). Finally, the KYN pathway has been consistently implicated in AD progression. Multiple studies have reported elevated levels of metabolites in the KYN pathway in people with AD, and, in many of these studies, KYN dysregulation has been positively correlated with AD progression (35, 84, 85, 100-105). Furthermore, IDO1 inhibition reverses AD pathology driven by injection of Aβ1-42 in mice (106) and in an early transgenic mouse model of AD (107). Based on these observations, we hypothesize here that those individuals with DS showing the strongest degree of dysregulation in the IFN→IDO1→KYN pathway will also display earlier onset and faster progression of AD. Clearly, testing this hypothesis will require a significant effort, including a multi-dimensional, longitudinal analysis of IFN signaling, KYN dysregulation, and various metrics of the AD pathological cascade.
Beyond AD, it is possible that KYN dysregulation is a driver of other neuropathologies more prevalent in DS, such as epilepsy/infantile spasms/seizures, depression, and autism (72-75). KYN and QA were shown to promote seizures in mice, rats, and frogs (108-111), and QA was found to be elevated in mouse models of epilepsy (112), leading to the characterization of QA as an ‘endogenous convulsant’ with a pathogenic role in seizure disorders (113). The role of tryptophan catabolism in depression is undisputed (114), with a prominent role for serotonin depletion as a causative event, leading to the widespread therapeutic use of selective serotonin reuptake inhibitors (SSRIs). Importantly, activation of the KYN pathway shunts tryptophan away from serotonin synthesis, causing serotonin depletion, which led Lapin and others to propose the ‘kynurenine hypothesis’ of depression (115). The discovery of the neurotropic activities of KYN and its derivatives indicated that induction of the KYN pathway could not only drive serotonin deficiency, but also promote depression-associated anxiety, psychosis, and cognitive decline (116). Notably, it has been amply documented that therapeutic administration of IFN-α can induce depression (117-119). During therapeutic use of IFN-α for the treatment of hepatitis C, high tryptophan breakdown was associated with depression-like symptoms during the course of treatment, leading Wichers et al. to propose that IDO1 induction (and consequent neurotoxicity) was the principal pathophysiological mechanism (50, 120). Regarding autism, independent cohort studies have documented dysregulation of KYN metabolism in patients diagnosed with autism spectrum disorder (ASD) (121, 122), as demonstrated by increased KYN/KA ratios (122) and elevated levels of QA (121), adding further evidence to the growing notion of neuroinflammatory processes in the etiology of ASD (123).
In addition to the recognized neurological conditions discussed above, KYN dysregulation could contribute to the cognitive deficits associated with DS. The acute effects of KYN metabolites, QA in particular, on cognitive function are well documented (16, 124). QA is a potent neurotoxin that acts as an excitotoxic agonist of NMDA receptors, and which may also exert toxicity via oxidative stress (9). Importantly, dysregulation of the KYN pathway in DS could explain a large body of work showing beneficial effects of memantine, an NMDA antagonist that protects from QA-mediated neurotoxicity (10-13), as well as anti-oxidants such as vitamin E, in various animal models of DS (125-129). Of note, memantine is an approved drug for the treatment of AD, which is currently being tested in a follow-up Phase II clinical trial to improve cognition in young adults with DS (NCT02304302). The initial pilot trial showed benefits on a subset of neurocognitive measures (130). A second independent trial, which focused on adults 40 years and older, showed no effects in any of the endpoints (131). However, we posit here that the limited therapeutic effect of this drug is due to its action at a very downstream step in the pathway, and that inhibitors of IDO1 (107, 132), kynurenine-3-monooxygenase (KMO) (133), and IFN signaling (e.g. JAK inhibitors, decoy IFNR receptors) (134, 135) should be considered. Even if memantine is pursued further, we suggest that its use should be accompanied by an assessment of the degree of KYN dysregulation in those receiving the drug. In principle, memantine should have no benefits for individuals with DS who display normal levels of QA.
Finally, it is important to note that the KYN pathway plays major roles in immune control. KYN is a potent immunosuppressive metabolite promoting ‘immune privilege’ in tissues such as the brain, testes, and gut, but which is also exploited by some tumor types to evade immune surveillance (17, 136). KYN upregulation in people with DS may affect key cell types involved in autoimmunity, such as regulatory T cells (17, 136), and it may represent an immunosuppressive negative feedback mechanism downstream of chronic IFN signaling (46-49, 137). Given that people with DS are highly predisposed to myriad autoimmune disorders, and that Pneumonia lung infections are the top cause of death in people with DS (138), our results justify future investigations to define the role of KYN dysregulation in multiple common co-morbidities in DS.
Materials and Methods
Human cohorts and sample collection
All human subjects in this study were consented according to Colorado Multiple Institutional Review Board (COMIRB)-approved protocols. Written informed consent was obtained from parents or guardians of participants under the age of 18, and assent was obtained from participants over the age of 7 who were cognitively able to assent. Deidentified plasma samples were obtained from the Translational Nexus Clinical Data Registry and Biobank (University of Colorado Anschutz Medical Campus, COMIRB #08-1276) for 49 individuals with DS and 49 controls without DS. Additionally, plasma samples for 31 individuals with DS and 42 controls were obtained through the Human Trisome Project (University of Colorado Anschutz Medical Campus, COMIRB #15-2170, www.trisome.org). Plasma was collected in Vacutainer tubes (EDTA – purple capped or Lithium heparin – light green capped) and stored at −80°C. Participant medical history was collected by the respective biobanks.
Sample preparation
For plasma analyses (human and mouse plasma), a volume of 50 µl of was extracted in 450 µl of ice cold lysis buffer (methanol:acetonitrile:water 5:3:2). For cell experiments, 1×106 cells were extracted in 1 ml of lysis buffer. In both protocols, incubation with lysis buffer was followed by vortexing for 30 minutes at 4ºC. Separate extraction for hydrophobic metabolites (including oxylipids) were performed in ice cold methanol with similar ratios and workflows. Insoluble proteins were pelleted by centrifugation (10 minutes at 4ºC and 10,000 x g) and supernatants were collected and stored at −80°C until analysis. UHPLC-MS metabolomics analyses were performed using a Vanquish UHPLC system coupled online to a Q Exactive mass spectrometer (Thermo Fisher, Bremen, Germany). Samples were resolved over a Kinetex C18 column (2.1 × 150 mm, 1.7 µm; Phenomenex, Torrance, CA, USA) at 25ºC using a three minute isocratic condition of 5% acetonitrile, 95% water, and 0.1% formic acid flowing at 250 µl/min,48 or using a 5 min gradient at 400 µl/min from 5-95% B (A: water/0.1% formic acid; B: acetonitrile/0.1% formic acid) and a 17 min gradient ((A) water/acetonitrile (75/25, vol/vol) with 5 mmol/L ammonium acetate and (B) 2-propanol/acetonitrile/water (50/45/5, vol/vol/vol) with 5 mmol/L ammonium acetate). Compounds of interest were monitored and quantified in negative ion mode against deuterium-labeled internal standards. MS analysis and data elaboration were performed as described (139, 140). To monitor possible technical variability, technical replicates were run for both cohorts. Briefly, for the plasma samples from each cohort, aliquots of each of the individual samples were combined to make technical replicates, which were run as described above. Additionally, in each experiment, several buffer aliquots were run as blanks for artifact identification.
Metabolomics data processing
Metabolite assignments and isotopologue distributions in tracing experiments with 13C15N-tryptophan were performed using MAVEN (Princeton, NJ, USA) and Compound Discoverer (Thermo Fisher, Bremen, Germany), on the basis of accurate intact mass, retention time and MS/MS (141, 142). Peak areas were exported for further statistical analysis with R (R Foundation for Statistical Computing, Vienna, Austria). Data sets from each of the two studies were log2-transformed. To perform differential expression analysis, the limma R package was used to fit a linear model to the data, including age, sex, and cohort as covariates (21). Log fold change, p-value and adjusted p-value were calculated for the T21-D21 comparison using the empirical Bayes function and Benjamini-Hochberg adjustment procedure for multiple testing correction in limma (143). Adjusted p-values shown in the volcano plots and reported on the box plots were generated with this limma moderated t-test. For displaying data per sample on the boxplots, we plotted the residuals from the model fit.
For pathway enrichment, we first mapped the 91 metabolites to KEGG pathways using the KEGGREST R package (144). Of the 91 metabolites, 79 were annotated to at least one KEGG pathway. In total, this resulted in 116 unique pathway annotations which had at least 1 metabolite in them from the set of 79. We excluded pathways with less than 5 metabolites in them, leaving 52 pathways to investigate. Using this set of pathways, we performed a hypergeometric test in which the 16 differentially abundant metabolites were selected from the 79. For each pathway, we tested the number of metabolites that were both in the pathway and differentially abundant.
Predictive modeling
To select metabolites to be used as features for predictive modeling, we used the age-, sex-, and cohort-adjusted metabolomics data. Missing values made up less than 1% of the data and were imputed with the k-nearest neighbors algorithm using k = 5. Imputation was performed within the karyotype group using the impute package in R (145). We trained 10,000 independent, 5-fold cross-validated lasso regression models on combined set of Nexus and HTP samples using the R, glmnet package (146). For each independently trained model, metabolite coefficients and model accuracy was recorded. For models which reached 90% accuracy or greater, we recorded which metabolites had non-zero coefficients (i.e. features selected in the model). To select our final set of biomarkers to test, we used metabolites which had been selected by at least 80% of the models reaching 90% accuracy or greater, resulting in 11 total metabolites. We then evaluated the performance of building a predictor using the lasso model with the top 11 identified metabolites. To estimate performance, we ran a bootstrapped analysis over 10,000 independently trained models. We randomly separated the 169 patient samples into 80% training and 20% testing sets. Using the 11 metabolites, we used 5-fold cross-validation on the training set to identify the optimal value, then tested the trained model on the held-out testing set. We reported the average model performance over the 10,000 models and provide an empirically determined (from the bootstrapped analysis) 95% confidence intervals. Area under the receiver operating characteristic curve (AUC) is reported.
Data and code availability
All data and R code developed for the full set of statistical and machine learning analyses is available at: https://github.com/CostelloLab/Trisomy21_KYN_metabolomics. To ensure reproducibility, this code can be run to generate all figures for this manuscript.
Cell culture
Human fibroblasts were described previously (11). For the metabolic flux experiment, cells were cultured in 5 mg/L 13C11 15N2 L-tryptophan (Sigma-Aldrich Cat #574597) for 72 hr prior to stimulation with 10 ng/mL IFN-α (R&D Systems Cat# 11101-2). Media was prepared by adding 120 uL of 10 mg/mL stock 13C11 15N2 L-tryptophan in 1x PBS to 240 mL of RPMI (Corning Cat# 10-040) in 10% Dialyzed FBS (Sigma Cat# F0392) and 1x Anti-Anti (Gibco Cat# 15240-062). Cells were treated with 10 ng/mL IFN-α or vehicle by adding 6 uL of 0.2 mg/mL IFN-α or 1x PBS to 120 mL of heavy labeled media. Cell lysates and media were collected at 0, 1, 6, and 24 hours following initial application of the heavy tryptophan and IFN-α. LC-MS metabolomics profiling was performed as described above, and tryptophan catabolites were identified by their C13 and/or N15 peaks.
Western blots
Cells were plated at equal densities (∼33,000/cm2) and allowed to attach overnight. The next day, IFN-α (R&D Systems Cat# 11101-2) was added at 10 ng/mL in RPMI (Corning Cat# 10-040) and cells were harvested by 0.25% trypsin (Gibco Cat# 25200-056) at 0, 1, 6, and 24 hours. Trypsin was quenched by adding RPMI with 10% Dialyzed FBS (Sigma Cat# F0392). Cells were pelleted at 200g for 5 minutes. Cell pellets were washed with 1x PBS, then resuspended in RIPA buffer containing 1 μg/mL pepstatin, 2 μg/mL aprotonin, 20 μg/mL trypsin inhibitor, 10 nM leupeptin, 200 nM Na3VO4, 500 nM phenylmethylsulfonyl fluoride (PMSF), and 10 μM NaF. Suspensions were sonicated at six watts for 15 s two times and clarified by centrifugation at 21,000?g for 10 min at 4°C. Supernatants were quantified in a Pierce BCA Protein Assay and diluted in complete RIPA with 4x Laemmli sample buffer. Tris-glycine SDS-polyacrylamide gel electrophoresis was used to separate 20–40 μg protein lysate, which was transferred to a 0.45 μm polyvinylidene fluoride (PVDF) membrane. Membranes were blocked in 5% non-fat dried milk or 2.5% bovine serum albumin (BSA) in Tris-buffered saline containing 0.1% TWEEN (TBS-T) at room temperature for 30 min. Immunoblotting was done using primary antibodies against Stat1 (Santa Cruz Biotechnology Cat# 346), pStat1 (Cell Signaling Technology Cat# 7649), IDO1 (Cell Signaling Technology Cat# 86630), and GAPDH (Santa Cruz Biotechnology Cat# 365062) overnight in 5% non-fat dried milk or 2.5% BSA in TBS-T at 4°C while shaking. Membranes were washed 3x in TBS-T for 5–15 min before probing with a horseradish peroxidase (HRP) conjugated secondary antibody in 5% non-fat dried milk at room temperature for one hour. Membranes were again washed 3x in TBS-T for 5–15 min before applying enhanced chemiluminescence (ECL) solution. Chemiluminensence signal was captured using a GE (Pittsburgh, PA) ImageQuant LAS4000.
Mouse strains
Dp(10)1Yey/+, Dp(16)1(Yey)/+ and Dp(17)1(Yey)/+ have been previously described (51). Dp(16) mice were purchased from Jackson Laboratories or provided by Drs. Faycal Guedj and Diana Bianchi at the National Institutes of Health. Dp(10)Yey/+, and Dp(17)1(Yey)/+ mice were provided by Drs. Katheleen Gardiner and Santos Franco, respectively. Animals were used between 6 and 30 weeks of age. All mice were maintained on a C57Bl/6 background and housed in specific-pathogen-free conditions. All experiments were approved by the Institutional Animal Care and Use Committee at the University of Colorado Anschutz Medical Campus.
Poly(I:C) treatment
Mice were allocated into control and poly(I:C) groups according to age, sex, and genotype. VacciGradeTM high molecular weight poly(I:C) (InvivoGen Cat# vac-pic) was diluted to 1 mg/mL, according to manufacturer’s instructions. For induction of chronic inflammation, mice received intraperitoneal injections of 10 μg/g poly(I:C) at two-day intervals for a total of nine injections. Blood was either collected prior to the final injection, via the submandibular vein into 0.5 mL of 18 u/mL sodium heparin (Sigma Cat# H3393) or after sacrifice via cardiac puncture into 1.3 mL lithium heparin tubes (Fisher Cat #41-12-17-02). Blood samples were centrifuged (700 x g, 15 mins, 21°C) to separate the plasma. Plasma was collected into a fresh tube and centrifuged (2200 x g, 15 mins, 21°C) to pellet any remaining cells; cell-free plasma was aliquoted and stored at −80°C.
ADDITIONAL INFORMATION
Competing interests
JME: Reviewing Editor, eLife. The other authors declare no competing interests.
Funding
This work was supported primarily by the Linda Crnic Institute for Down Syndrome, the Global Down Syndrome Foundation, the Anna and John J. Sie Foundation, the Boettcher Foundation, and the University of Colorado School of Medicine. RKP is supported by NIH training grant T15LM009451.
Author Contributions
RKP, KDS, JME, and JCC, conception and design, acquisition of data, analysis and interpretation of data, drafting or revising the article; AD, conception and design, acquisition of data, analysis and interpretation of data; RCH, MPL, KPS, KAW, RM, KDT, ALR, REG, RBW, acquisition of data, analysis and interpretation of data.
Acknowledgements
This work was supported primarily by the Linda Crnic Institute for Down Syndrome, the Global Down Syndrome Foundation, the Anna and John J. Sie Foundation, the Boettcher Foundation, and the University of Colorado School of Medicine. We thank the individuals with Down syndrome that donated the biological samples that enabled these studies.
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