Abstract
Gut microbiome differences between people with Parkinson’s disease (PD) and control subjects without Parkinsonism are widely reported, but potential alterations related to PD with mild cognitive impairment (MCI) have yet to be comprehensively explored. We compared gut microbial features of PD with MCI (n = 58) to cognitively unimpaired PD (n = 60) and control subjects (n = 90) with normal cognition. Our results did not support a specific microbiome signature related to MCI in PD.
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Mild cognitive impairment (MCI) is a non-motor symptom of Parkinson’s disease (PD) that represents a risk factor for developing dementia, and can significantly impact quality of life.1 While gut microbial community differences between people with PD and individuals without parkinsonism are well established2,3,4,5,6,7, only a single publication has investigated the gut microbiome in PD with MCI, suggesting significant differences in several taxa when contrasting PD with MCI to PD with unimpaired cognition or to control subjects.8 To investigate whether these results could be replicated in a larger, geographically distinct cohort, we performed similar comparisons using data from the Luxembourg Parkinson’s Study4.
Our dataset comprised 58 people with PD and MCI (PD-MCI), 60 people with PD without cognitive impairment (PD-NC), and 90 cognitively normal control subjects. While there were differences in demographic and clinical variables between the control and PD groups, including that controls were younger and had lower frequency of constipation, the PD-MCI and PD-NC groups had similar profiles (Table 1).
We did not observe any difference between the PD-MCI, PD-NC, and control groups in microbial community richness and evenness (alpha diversity) when tested without confounders (Fig. 1a, b, Supplementary Table 1a). In a linear regression model for the inverse Simpson index, including the three groups and potential confounding variables, both PD groups tended to have lower diversity than controls (0.1 > p > 0.05; Supplementary Table 1b). In a within-PD model with confounders, there was no difference between PD with or without MCI (Supplementary Table 1c).
In comparisons of community composition (beta diversity), there was a difference between the three groups when tested with or without confounding variables (p < 0.001 for both) (Fig. 1c, Supplementary Tables 2a, b). Pairwise tests between controls and each of the PD groups also showed a significant group effect, but a within-PD test indicated no difference in relation to MCI status (Supplementary Tables 2c–e). In tests of sample dispersions between the groups, the difference was significant between PD-MCI and controls (p < 0.05), close to significant between PD-NC and controls (0.1 > p > 0.05) and not significant between PD-MCI and PD-NC (Fig. 1d; Supplementary Tables 2f, g).
We performed differential abundance comparisons with three tools: DESeq29 and ANCOM-BC210, commonly used methods with different statistical backgrounds, and DA.lic from the DAtest11 package, selected based on its performance compared to other tests (Supplementary Fig 1a–c, Supplementary Table 3a). Comparing controls to the PD groups resulted in many significant taxonomic clades when comparing either PD-MCI or PD-NC to controls (Fig. 1e, Supplementary Fig 1d, Supplementary Table 3b–d). Taxa which were significant with more than one test included, among others, decreased abundances of the family Lachnospiraceae, Clostridiaceae and Butyricicoccaceae in PD, and increases in Enterobacteriaceae and the genera Hungatella and DTU089 (family Ruminococcaceae). DESeq2 indicated increases in many additional taxa, such as the genera Escherichia/Shigella and Methanobrevibacter. However, when comparing PD-MCI to PD-NC, two out of three tests detected no significant taxa (Fig. 1e). DESeq2 highlighted 10 significant taxa for this comparison, notably less than in comparisons between other groups (Supplementary Fig 2a). Among the most significant taxa were genus Streptococcus (increased in PD-MCI) and an Amplicon Sequence Variant (ASV) classified as Akkermansia muciniphila (decreased in PD-MCI) (Supplementary Fig 2b–e).
Many of the taxa detected as differentially abundant between the PD and control groups were in line with previous publications, including the increased abundances of Enterobacteriaceae7, Hungatella5,6 and Methanobrevibacter6, and decreased abundances of Lachnospiraceae5,6,7 and Butyricicoccaceae6,7 in PD. The differences in beta diversity between control and PD subjects were also in line with the literature.2,3,4,6,7 As for comparisons related to PD with MCI, the previous publication on the topic reported a significant difference in beta diversity between PD-NC and PD-MCI, higher abundances of two families and four genera in PD-MCI compared to either PD-NC or controls, and decreases in two genera when contrasting PD-MCI and PD-NC.8 In our study, there was no difference in beta diversity between PD with and without MCI. When comparing specific taxa, only one of three tests indicated any differences between PD with and without MCI, and none of those taxa overlapped with the previous publication8. Considering the lack of overlap, the two studies do not suggest a consistent microbial signature representative of MCI in PD. The most compelling taxon detected in the present study was an A. muciniphila ASV, which was almost entirely absent in PD-MCI. A. muciniphila is typically increased in PD3,4,5,6,7, and more research regarding the significance of this taxon in PD and its subtypes is warranted.
To conclude, our comparisons reproduced previously detected differences between PD and control subjects but did not lend support to microbial community patterns specific to PD with MCI.
Methods
Subject recruitment, faecal sample collection and processing as well as amplification and sequencing of the 16 S rRNA gene (regions V3–V4) have been described previously4. Participants were included in the present study if they matched UK Parkinson’s Disease Society Brain Bank clinical diagnostic criteria12 for typical PD; subjects with atypical or not yet specified parkinsonism were excluded. Control subjects genetically related to participants with PD were also excluded. The Luxembourg Parkinson’s Study13 was conducted according to the Declaration of Helsinki, with approval from the National Ethics Board (CNER Ref: 201407/13) and Data Protection Committee (CNPD Ref: 446/2017). All participants signed written informed consent.
MCI was defined according to Movement Disorder Society (MDS) taskforce criteria14, using a validated scale for cognitive assessment in PD (Montreal Cognitive Assessment15; MoCA), and information about the impact of cognitive impairment on daily living. For MoCA, the cutoffs used were <26 and >20. The impact of cognitive impairment was evaluated by MDS-UPDRS (Unified Parkinson’s Disease Rating Scale) question 1.1., assessed by a study physician, neuropsychologist, or PD specialized nurse during a semi-structured interview with the participant, together in discussion with family members, where possible. Constipation was defined based on Rome III criteria16. Levodopa equivalent daily dosage (LEDD) was calculated based on published conversion factors17.
Sequence data was processed with dadasnake18. Primers were removed using cutadapt19 allowing 20% mismatches and no indels. Quality filtering, ASV (Amplicon Sequence Variant) generation and chimera removal were performed using DADA220. Reads were truncated at positions with Phred score < 10, or at 240 bp. Quality filtering was set to keep sequences with a maximum expected error of 2 and length of 240 bp. Downsampling was performed to 25,000 reads using seqtk21; samples with fewer reads were removed. ASVs were generated in pooled mode using default parameters. A minimum overlap of 12 bp was required for merging forward and reverse ASVs. Chimeric sequences were removed based on the consensus algorithm. Taxonomic classification was performed against SILVA v. 13822 using the naïve Bayesian classifier implemented in mothur23.
After excluding subjects that did not match diagnostic criteria, control subjects related to PD subjects, and subjects lacking microbiome data, the data contained results from 468 individuals. Additional exclusions were implemented as follows:
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236 subjects with age <= 64 years due to overrepresentation of younger individuals in the control group,
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3 subjects due to missing information on education or body mass index (BMI),
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5 subjects due to having <10,000 sequence reads left after removing rare ASVs (present in <10% of samples) and ASVs classified as chloroplasts or mitochondria,
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16 subjects due to reported use of corticosteroids or immunosuppressants in the past 6 months.
After these exclusions, the final data set used for analyses consisted of data from 208 individuals.
Statistical comparisons and visualizations were performed in R24 (version 4.3.2), using renv25 (1.0.3) for package management and knitr26 (1.43) for reporting. Comparisons of demographic and clinical variables were performed using Pearson’s Chi-squared test or Fisher’s exact test (categorical variables), Welch two sample t-tests (PD-only continuous variables), and one-way ANOVA with post-hoc two-tailed pairwise t-tests and “holm” multiple comparison correction (continuous variables).
Alpha diversity indices were calculated with phyloseq27 (1.42.0) and compared with Wilcoxon rank sum tests (variables with two categories), Kruskal-Wallis tests (variables with more than two categories) or Pearson correlations (continuous variables) as well as linear regression to model multiple variables together. Beta diversity was explored using phyloseq and vegan28 (2.6–4), with data subsampled to the lowest sequence read count in a sample. Bray-Curtis dissimilarity was used as the dissimilarity measure, visualizations were performed with Non-Metric Multidimensional Scaling (NMDS), and statistical comparisons with PERMANOVA (function: adonis2) using 9999 permutations. Confounder-corrected adonis2 models were run with the option ‘by = “margin”’ to calculate marginal effects. Additional tests for beta diversity included ANOVA and Tukey-HSD for multivariate homogeneity of group dispersions.
Differential abundance comparisons were performed with DESeq29 (1.38.3), ANCOM-BC2 from ANCOMBC10 (2.1.4), and DA.lic, which implements LIMMA29 with CLR transformed data, from DAtest11 (2.8.0). DA.lic was selected based on the results of testDA from DAtest, which was run 50 times for each method, contrasting PD-NC to PD-MCI with a confounder-corrected model, using PD-only genus and ASV level data (ASVs trimmed to those present in > 30 samples). The final choice was based on test score > 0, false discovery rate < 0.25, and higher power than other similarly performing tests.
The model used for all differential abundance tests was taxon ~ Group (control/PD-NC/PD-MCI)+Sex+Age+BMI+Antibiotic use in past 6 months (yes / no)+Constipation (yes / no) + Education (categorical, split by median). DESeq2 was run with default parameters except for ‘sfType = “poscounts”’, and results were retrieved for all pairwise comparisons between the three subject groups. DA.lic and ANCOM-BC2 were run twice for each taxonomic level:
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with full data and all three groups, for which these tests only provide results in relation to the reference level (only PD-NC vs. control and PD-MCI vs. control, not PD-MCI vs. PD-NC),
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with PD-only data for the PD-MCI vs. PD-NC comparison.
DA.lic was performed using default settings. With ANCOM-BC2, the full data comparison (1) was additionally performed using the pairwise approach, which provides results for all three pairwise comparisons, but is more stringent. Additional parameters included setting ‘prv_cut’ to 0 and multiple comparison correction to “fdr” for both the default test and the pairwise test.
Reporting summary
Further information on research design is available in the Nature Research Reporting Summary linked to this article.
Data availability
Patient data used in the preparation of this manuscript were obtained from the National Centre of Excellence in Research on Parkinson’s Disease (NCER-PD). NCER-PD datasets are not publicly available, as they are linked to the Luxembourg Parkinson’s Study and its internal regulations. The NCER-PD Consortium is willing to share its available data. Its access policy was devised based on the study ethics documents, including the informed consent form, as approved by the national ethics committee. Requests to access datasets should be directed to the Data and Sample Access Committee via email: request.ncer-pd@uni.lu.
Code availability
The R code for this study is available at https://gitlab.lcsb.uni.lu/ESB/ncer-mci-microbiome.
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Acknowledgements
We would like to thank all participants of the Luxembourg Parkinson’s Study for their important support of our research. Furthermore, we acknowledge the joint effort of the National Centre of Excellence in Research on Parkinson’s Disease (NCER-PD) Consortium members from the partner institutions Luxembourg Centre for Systems Biomedicine, Luxembourg Institute of Health, Centre Hospitalier de Luxembourg, and Laboratoire National de Santé generally contributing to the Luxembourg Parkinson’s Study. Data used in the preparation of this manuscript were obtained from the National Centre of Excellence in Research on Parkinson’s Disease (NCER-PD). The National Centre of Excellence in Research on Parkinson’s Disease (NCER-PD) is funded by the Luxembourg National Research Fund (FNR/NCER13/BM/11264123). The work was supported by the PEARL program (FNR/P13/6682797 to R.K.), MotaSYN (12719684 to R.K.), MAMaSyn (to R.K.), the FNR/DFG Core INTER (ProtectMove, FNR11250962 to P.M.). P.W. acknowledges funding from the European Research Council under the European Union’s Horizon 2020 research and innovation program (no. 863664). A.K.L., R.K., and P.W. acknowledge the financial support of the Institute for Advanced Studies of the University of Luxembourg through an AUDACITY grant (ref. no. MCI-BIOME_2019). The funders played no role in the study design, data collection, analysis and interpretation of data, or the writing of this manuscript. For the purpose of open access, and in fulfillment of the obligations arising from the grant agreement of the Luxembourg National Research Fund, the authors have applied a Creative Commons Attribution 4.0 International (CC BY 4.0) license to any Author Accepted Manuscript version arising from this submission. The sequence data analyses for this study were carried out using the HPC facilities of the University of Luxembourg.
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Conceptualization: V.T.E.A., R.K., P.M., P.W.; Data curation: V.T.E.A., Z.L., L.P., and NCER-PD; Formal analysis: V.T.E.A., P.M., A.H.B., M.K.; Writing –original draft: V.T.E.A., Writing –review & editing: all authors; Funding acquisition: P.M., A.K.L., R.K., P.W.; Project administration: V.T.E.A., P.M., A.K.L., R.K., P.W.; Supervision: P.M., A.K.L., R.K., P.W. All authors read and approved the final manuscript. A.K.L., R.K., P.M., and P.W. share last authorship.
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A.K.L. has served on advisory boards and as speaker for Roche. The other authors declare no competing interests.
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Aho, V.T.E., Klee, M., Landoulsi, Z. et al. Gut microbiome is not associated with mild cognitive impairment in Parkinson’s disease. npj Parkinsons Dis. 10, 78 (2024). https://doi.org/10.1038/s41531-024-00687-1
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DOI: https://doi.org/10.1038/s41531-024-00687-1
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