Large-scale identification of clinical and genetic predictors of motor progression in patients with newly diagnosed Parkinson's disease: a longitudinal cohort study and validation

Jeanne C Latourelle, Michael T Beste, Tiffany C Hadzi, Robert E Miller, Jacob N Oppenheim, Matthew P Valko, Diane M Wuest, Bruce W Church, Iya G Khalil, Boris Hayete, Charles S Venuto, Jeanne C Latourelle, Michael T Beste, Tiffany C Hadzi, Robert E Miller, Jacob N Oppenheim, Matthew P Valko, Diane M Wuest, Bruce W Church, Iya G Khalil, Boris Hayete, Charles S Venuto

Abstract

Background: Better understanding and prediction of progression of Parkinson's disease could improve disease management and clinical trial design. We aimed to use longitudinal clinical, molecular, and genetic data to develop predictive models, compare potential biomarkers, and identify novel predictors for motor progression in Parkinson's disease. We also sought to assess the use of these models in the design of treatment trials in Parkinson's disease.

Methods: A Bayesian multivariate predictive inference platform was applied to data from the Parkinson's Progression Markers Initiative (PPMI) study (NCT01141023). We used genetic data and baseline molecular and clinical variables from patients with Parkinson's disease and healthy controls to construct an ensemble of models to predict the annual rate of change in combined scores from the Movement Disorder Society-Unified Parkinson's Disease Rating Scale (MDS-UPDRS) parts II and III. We tested our overall explanatory power, as assessed by the coefficient of determination (R2), and replicated novel findings in an independent clinical cohort from the Longitudinal and Biomarker Study in Parkinson's disease (LABS-PD; NCT00605163). The potential utility of these models for clinical trial design was quantified by comparing simulated randomised placebo-controlled trials within the out-of-sample LABS-PD cohort.

Findings: 117 healthy controls and 312 patients with Parkinson's disease from the PPMI study were available for analysis, and 317 patients with Parkinson's disease from LABS-PD were available for validation. Our model ensemble showed strong performance within the PPMI cohort (five-fold cross-validated R2 41%, 95% CI 35-47) and significant-albeit reduced-performance in the LABS-PD cohort (R2 9%, 95% CI 4-16). Individual predictive features identified from PPMI data were confirmed in the LABS-PD cohort. These included significant replication of higher baseline MDS-UPDRS motor score, male sex, and increased age, as well as a novel Parkinson's disease-specific epistatic interaction, all indicative of faster motor progression. Genetic variation was the most useful predictive marker of motor progression (2·9%, 95% CI 1·5-4·3). CSF biomarkers at baseline showed a more modest (0·3%, 95% CI 0·1-0·5) but still significant effect on prediction of motor progression. The simulations (n=5000) showed that incorporating the predicted rates of motor progression (as assessed by the annual change in MDS-UPDRS score) into the final models of treatment effect reduced the variability in the study outcome, allowing significant differences to be detected at sample sizes up to 20% smaller than in naive trials.

Interpretation: Our model ensemble confirmed established and identified novel predictors of Parkinson's disease motor progression. Improvement of existing prognostic models through machine-learning approaches should benefit trial design and evaluation, as well as clinical disease monitoring and treatment.

Funding: Michael J Fox Foundation for Parkinson's Research and National Institute of Neurological Disorders and Stroke.

Conflict of interest statement

Competing interests: JCL, MTB, TCH, REM, JNO, MPV, DMW, IGK, BH, are currently (JCL, TCH, REM, DMW, IGK, BH) or were at time of study (MTB, JNO, MPV) employees of GNS Healthcare.

Copyright © 2017 Elsevier Ltd. All rights reserved.

Figures

Fig. 1. Variable importance of model predictors…
Fig. 1. Variable importance of model predictors in motor progression
The relative contribution to the overall explanatory power for individual and/or sets of features is shown. The variable importance of the feature(s) is expressed as a percent increase in the mean squared error in leave-one-out cross-validation with each feature plotted in descending order of importance. Mean and 95% confidence intervals are indicated. The dashed blue line represents the full model without excluding any features.
Fig. 2. Replication of PD-specific SNP interaction…
Fig. 2. Replication of PD-specific SNP interaction affecting motor progression rates
Stratified plots of Motor progression rates vs. rs17710829 and rs9298897 genotypes for PD cases in PPMI (upper panels) and LABS-PD (lower panels). Note, dominant genetic modeling (combing the TC and CC genotypes) was used for rs17710829 due to its low minor allele frequency (C allele frequency=6%) while the more common rs9298897 (G allele frequency =35%) was modeled additively.
Fig. 3
Fig. 3
LABS-PD Motor Scores by Predicted Progression Group. Median (95% CI) MDS-UPDRS motor scores parts II and III, beginning with the first follow-up exam (starting at either 3 or 4 years after baseline) are shown for cases predicted to be slow, moderate or fast progressors at study baseline.

References

    1. Kalia LV, Lang AE. Parkinson’s disease. Lancet Lond Engl. 2015;386:896–912.
    1. Sieber B-A, Landis S, Koroshetz W, et al. Prioritized research recommendations from the National Institute of Neurological Disorders and Stroke Parkinson’s Disease 2014 conference. Ann Neurol. 2014;76:469–72.
    1. Post B, Merkus MP, de Haan RJ, Speelman JD CARPA Study Group. Prognostic factors for the progression of Parkinson’s disease: a systematic review. Mov Disord Off J Mov Disord Soc. 2007;22:1839–51. quiz 1988.
    1. Reinoso G, Allen JC, Au W-L, Seah S-H, Tay K-Y, Tan LCS. Clinical evolution of Parkinson’s disease and prognostic factors affecting motor progression: 9-year follow-up study. Eur J Neurol. 2015;22:457–63.
    1. Terrelonge M, Marder KS, Weintraub D, Alcalay RN. CSF β-Amyloid 1–42 Predicts Progression to Cognitive Impairment in Newly Diagnosed Parkinson Disease. J Mol Neurosci MN. 2016;58:88–92.
    1. Morales DA, Vives-Gilabert Y, Gómez-Ansón B, et al. Predicting dementia development in Parkinson’s disease using Bayesian network classifiers. Psychiatry Res. 2013;213:92–8.
    1. Schrag A, Siddiqui UF, Anastasiou Z, Weintraub D, Schott JM. Clinical variables and biomarkers in prediction of cognitive impairment in patients with newly diagnosed Parkinson’s disease: a cohort study. Lancet Neurol. 2017;16:66–75.
    1. Velseboer DC, de Bie RMA, Wieske L, et al. Development and external validation of a prognostic model in newly diagnosed Parkinson disease. Neurology. 2016;86:986–93.
    1. Simuni T, Long JD, Caspell-Garcia C, et al. Predictors of time to initiation of symptomatic therapy in early Parkinson’s disease. Ann Clin Transl Neurol. 2016;3:482–94.
    1. Bhattaram VA, Siddiqui O, Kapcala LP, Gobburu JVS. Endpoints and Analyses to Discern Disease-Modifying Drug Effects in Early Parkinson’s Disease. AAPS J. 2009:11. doi: 10.1208/s12248-009-9123-2.
    1. Friedman N, Koller D. Being Bayesian About Network Structure. A Bayesian Approach to Structure Discovery in Bayesian Networks. Mach Learn. 2003;50:95–125.
    1. Xing H, McDonagh PD, Bienkowska J, et al. Causal modeling using network ensemble simulations of genetic and gene expression data predicts genes involved in rheumatoid arthritis. PLoS Comput Biol. 2011;7:e1001105.
    1. Anderson JP, Parikh JR, Shenfeld DK, et al. Reverse Engineering and Evaluation of Prediction Models for Progression to Type 2 Diabetes: An Application of Machine Learning Using Electronic Health Records. J Diabetes Sci Technol. 2016;10:6–18.
    1. Steinberg GB, Church BW, McCall CJ, Scott AB, Kalis BP. Novel predictive models for metabolic syndrome risk: a ‘big data’ analytic approach. Am J Manag Care. 2014;20:e221–8.
    1. Marek K, Jennings D, Lasch S, et al. The Parkinson Progression Marker Initiative (PPMI) Prog Neurobiol. 2011;95:629–35.
    1. Goetz CG, Tilley BC, Shaftman SR, et al. Movement Disorder Society-sponsored revision of the Unified Parkinson’s Disease Rating Scale (MDS-UPDRS): scale presentation and clinimetric testing results. Mov Disord Off J Mov Disord Soc. 2008;23:2129–70.
    1. Pahwa R, Lyons KE, Hauser RA, et al. Randomized trial of IPX066, carbidopa/levodopa extended release, in early Parkinson’s disease. Parkinsonism Relat Disord. 2014;20:142–8.
    1. Hauser RA, Panisset M, Abbruzzese G, et al. Double-blind trial of levodopa/carbidopa/entacapone versus levodopa/carbidopa in early Parkinson’s disease. Mov Disord Off J Mov Disord Soc. 2009;24:541–50.
    1. Storch A, Jost WH, Vieregge P, et al. Randomized, double-blind, placebo-controlled trial on symptomatic effects of coenzyme Q(10) in Parkinson disease. Arch Neurol. 2007;64:938–44.
    1. Parashos SA, Luo S, Biglan KM, et al. Measuring disease progression in early Parkinson disease: the National Institutes of Health Exploratory Trials in Parkinson Disease (NET-PD) experience. JAMA Neurol. 2014;71:710–6.
    1. Bates DM. lme4: Mixed-effects modeling with R. [accessed March 17, 2014];URL Httplme4 R-Forge R-Proj Orgbook. 2010 .
    1. Hindorff LA, Sethupathy P, Junkins HA, et al. Potential etiologic and functional implications of genome-wide association loci for human diseases and traits. Proc Natl Acad Sci U S A. 2009;106:9362–7.
    1. Piñero J, Queralt-Rosinach N, Bravo À, et al. DisGeNET: a discovery platform for the dynamical exploration of human diseases and their genes. Database J Biol Databases Curation. 2015;2015:bav028.
    1. Donoho D, Tanner J. Observed universality of phase transitions in high-dimensional geometry, with implications for modern data analysis and signal processing. Philos Trans R Soc Lond Math Phys Eng Sci. 2009;367:4273–93.
    1. Ravina B, Tanner C, Dieuliis D, et al. A longitudinal program for biomarker development in Parkinson’s disease: a feasibility study. Mov Disord Off J Mov Disord Soc. 2009;24:2081–90.
    1. Hayete B, Valko M, Greenfield A, Yan R. MDL-motivated compression of GLM ensembles increases interpretability and retains predictive power. [accessed Dec 21, 2016];ArXiv161106800 Stat. 2016 published online Nov 21. .
    1. Nutt JG, Holford NH. The response to levodopa in Parkinson’s disease: imposing pharmacological law and order. Ann Neurol. 1996;39:561–73.
    1. Venuto CS, Potter NB, Ray Dorsey E, Kieburtz K. A review of disease progression models of Parkinson’s disease and applications in clinical trials. Mov Disord Off J Mov Disord Soc. 2016;31:947–56.
    1. Ravina B, Marek K, Eberly S, et al. Dopamine transporter imaging is associated with long-term outcomes in Parkinson’s disease. Mov Disord Off J Mov Disord Soc. 2012;27:1392–7.
    1. Kang J-H, Irwin DJ, Chen-Plotkin AS, et al. Association of cerebrospinal fluid β-amyloid 1-42, T-tau, P-tau181, and α-synuclein levels with clinical features of drug-naive patients with early Parkinson disease. JAMA Neurol. 2013;70:1277–87.
    1. Gillies GE, Pienaar IS, Vohra S, Qamhawi Z. Sex differences in Parkinson’s disease. Front Neuroendocrinol. 2014;35:370–84.
    1. Carim-Todd L, Escarceller M, Estivill X, Sumoy L. LRRN6A/LERN1 (leucine-rich repeat neuronal protein 1), a novel gene with enriched expression in limbic system and neocortex. Eur J Neurosci. 2003;18:3167–82.
    1. Laurén J, Airaksinen MS, Saarma M, Timmusk T. A novel gene family encoding leucine-rich repeat transmembrane proteins differentially expressed in the nervous system. Genomics. 2003;81:411–21.
    1. MacLeod D, Dowman J, Hammond R, Leete T, Inoue K, Abeliovich A. The familial Parkinsonism gene LRRK2 regulates neurite process morphology. Neuron. 2006;52:587–93.
    1. Inoue H, Lin L, Lee X, et al. Inhibition of the leucine-rich repeat protein LINGO-1 enhances survival, structure, and function of dopaminergic neurons in Parkinson’s disease models. Proc Natl Acad Sci U S A. 2007;104:14430–5.
    1. Mi S, Miller RH, Lee X, et al. LINGO-1 negatively regulates myelination by oligodendrocytes. Nat Neurosci. 2005;8:745–51.
    1. Li W, Walus L, Rabacchi SA, et al. A neutralizing anti-Nogo66 receptor monoclonal antibody reverses inhibition of neurite outgrowth by central nervous system myelin. J Biol Chem. 2004;279:43780–8.
    1. Vilariño-Güell C, Wider C, Ross OA, et al. LINGO1 and LINGO2 variants are associated with essential tremor and Parkinson disease. Neurogenetics. 2010;11:401–8.
    1. Nalls MA, Pankratz N, Lill CM, et al. Large-scale meta-analysis of genome-wide association data identifies six new risk loci for Parkinson’s disease. Nat Genet. 2014;46:989–93.
    1. Chen T, Gai W-P, Abbott CA. Dipeptidyl peptidase 10 (DPP10(789)): a voltage gated potassium channel associated protein is abnormally expressed in Alzheimer’s and other neurodegenerative diseases. BioMed Res Int. 2014;2014:209398.
    1. Luo S, Wang J. Bayesian hierarchical model for multiple repeated measures and survival data: an application to Parkinson’s disease. Stat Med. 2014;33:4279–91.
    1. van den Hout A, Matthews FE. Estimating dementia-free life expectancy for Parkinson’s patients using Bayesian inference and microsimulation. Biostat Oxf Engl. 2009;10:729–43.
    1. Lee JY, Gobburu JVS. Bayesian quantitative disease-drug-trial models for Parkinson’s disease to guide early drug development. AAPS J. 2011;13:508–18.

Source: PubMed

Sponsors and Collaborators

Medical Conditions

Drug Interventions

3
Subscribe