Forecasting Pathogen Dynamics with Bayesian Model-Averaging: Application to Xylella fastidiosa.
Bayesian model-averaging
Importance sampling
Outbreak prediction
Partial differential equations
Xylella fastidiosa
Journal
Bulletin of mathematical biology
ISSN: 1522-9602
Titre abrégé: Bull Math Biol
Pays: United States
ID NLM: 0401404
Informations de publication
Date de publication:
10 06 2023
10 06 2023
Historique:
received:
26
08
2022
accepted:
15
05
2023
medline:
12
6
2023
pubmed:
10
6
2023
entrez:
10
6
2023
Statut:
epublish
Résumé
Forecasting invasive-pathogen dynamics is paramount to anticipate eradication and containment strategies. Such predictions can be obtained using a model grounded on partial differential equations (PDE; often exploited to model invasions) and fitted to surveillance data. This framework allows the construction of phenomenological but concise models relying on mechanistic hypotheses and real observations. However, it may lead to models with overly rigid behavior and possible data-model mismatches. Hence, to avoid drawing a forecast grounded on a single PDE-based model that would be prone to errors, we propose to apply Bayesian model averaging (BMA), which allows us to account for both parameter and model uncertainties. Thus, we propose a set of different competing PDE-based models for representing the pathogen dynamics, we use an adaptive multiple importance sampling algorithm (AMIS) to estimate parameters of each competing model from surveillance data in a mechanistic-statistical framework, we evaluate the posterior probabilities of models by comparing different approaches proposed in the literature, and we apply BMA to draw posterior distributions of parameters and a posterior forecast of the pathogen dynamics. This approach is applied to predict the extent of Xylella fastidiosa in South Corsica, France, a phytopathogenic bacterium detected in situ in Europe less than 10 years ago (Italy 2013, France 2015). Separating data into training and validation sets, we show that the BMA forecast outperforms competing forecast approaches.
Identifiants
pubmed: 37300801
doi: 10.1007/s11538-023-01169-w
pii: 10.1007/s11538-023-01169-w
pmc: PMC10257384
doi:
Types de publication
Journal Article
Research Support, Non-U.S. Gov't
Langues
eng
Sous-ensembles de citation
IM
Pagination
67Informations de copyright
© 2023. The Author(s), under exclusive licence to Society for Mathematical Biology.
Références
Abboud C, Bonnefon O, Parent E, Soubeyrand S (2019) Dating and localizing an invasion from post-introduction data and a coupled reaction-diffusion-absorption model. J Math Biol 79:765–789
doi: 10.1007/s00285-019-01376-x
Anas O, Harrison UJ, Brannen PM, Sutton TB (2008) The effect of warming winter temperature on the severity of Pierce’s disease in the Appalachian mountains and Piedmont of the southeastern United States. Plant Health Progress 101094:450–459
Bartoš F, Gronau QF, Timmers B, Otte WM, Ly A, Wagenmakers E-J (2021) Bayesian model-averaged meta-analysis in medicine. Stat Med 40:6743–6761
doi: 10.1002/sim.9170
Berliner LM (2003) Physical-statistical modeling in geophysics. J Geophys Res Atmos 108:8776
doi: 10.1029/2002JD002865
Bertozzi A, Franco E, Mohler G, Short M, Sledge D (2020) The challenges of modeling and forecasting the spread of COVID-19. Proc Natl Acad Sci 117:16732–16738
doi: 10.1073/pnas.2006520117
Botella C, Bonnet P, Hui C, Joly A, Richardson DM (2022) Dynamic species distribution modeling reveals the pivotal role of human-mediated long-distance dispersal in plant invasion. Biology 11:1293
doi: 10.3390/biology11091293
Boys RJ, Wilkinson DJ, Kirkwood TBL (2008) Bayesian inference for a discretely observed stochastic kinetic model. Stat Comput 18:125–135
doi: 10.1007/s11222-007-9043-x
Bugallo MF, Martino L, Corander J (2015) Adaptive importance sampling in signal processing. Digit Signal Process 47:36–49
doi: 10.1016/j.dsp.2015.05.014
Burnham KP, White GC, Anderson DR (1995) Model selection strategy in the analysis of capture-recapture data. Biometrics 51:888–898
doi: 10.2307/2532990
Cendoya M, Martínez-Minaya J, Dalmau V, Ferrer A, Saponari M, Conesa D, López-Quílez A, Vicent A (2020) Spatial Bayesian modeling applied to the surveys of Xylella fastidiosa in Alicante (Spain) and Apulia (Italy). Front Plant Sci 11:1204
doi: 10.3389/fpls.2020.01204
Chapman DS, White SM, Hooftman DA, Bullock JM (2015) Inventory and review of quantitative models for spread of plant pests for use in pest risk assessment for the EU territory. EFSA Supporting Publications, 12:EN–795
Cornuet J, Marin J-M, Mira A, Robert CP (2012) Adaptive multiple importance sampling. Scand J Stat 39:798–812
doi: 10.1111/j.1467-9469.2011.00756.x
Denancé N, Cesbron S, Briand M, Rieux A, Jacques M-A (2017) Is Xylella fastidiosa really emerging in France? In: Costa J, Koebnik R (eds) 1st Annual Conference of the EuroXanth - COST Action Integrating Science on Xanthomonadaceae for integrated plant disease management in Europe, vol 7. EuroXanth, Portugal
Denancé N, Legendre B, Briand M, Olivier V, Boisseson C, Poliakoff F, Jacques M-A (2017) Several subspecies and sequence types are associated with the emergence of Xylella fastidiosa in natural settings in France. Plant Pathol 66:1054–1064
doi: 10.1111/ppa.12695
Dupas E, Durand K, Rieux A, Briand M, Pruvost O, Cunty A, Denancé N, Donnadieu C, Legendre B, Lopez-Roques C, Cesbron S, Ravigné V, Jacques M-A (2023) Suspicions of two bridgehead invasions of xylella fastidiosa subsp. multiplex in France. Commun Biol 6:103
doi: 10.1038/s42003-023-04499-6
ESV P (2022) Données de surveillance sur végétaux de Xylella fastidiosa
Evans LC (1998) Partial differential equations, volume 19 of Graduate studies in mathematics. Am Math Soc
Faria NR, Rambaut A, Suchard MA, Baele G, Bedford T, Ward MJ, Tatem AJ, Sousa JD, Arinaminpathy N, Pépin J, Posada D, Peeters M, Pybus OG, Lemey P (2014) The early spread and epidemic ignition of HIV-1 in human populations. Science 346:56–61
doi: 10.1126/science.1256739
Fletcher D (2018) Model averaging. Springer, Berlin
doi: 10.1007/978-3-662-58541-2
Ford EB, Gregory PC (2007) Bayesian model selection and extrasolar planet detection. In: Statistical Challenges in Modern Astronomy IV, ASP Conference Series, vol 371, p 189
Gelfand AE, Dey DK (1994) Bayesian model choice: asymptotics and exact calculations. J R Stat Soc B 56:501–514
Gelfand AE, Smith AFM (1990) Sampling-based approaches to calculating marginal densities. J Am Stat Assoc 85:398–409
doi: 10.1080/01621459.1990.10476213
Gelman A, Roberts GO, Gilks WR et al (1996) Efficient metropolis jumping rules. Bayesian Stat 5:599–608
George EI, McCulloch RE (1993) Variable selection via Gibbs sampling. J Am Stat Assoc 88:881–889
doi: 10.1080/01621459.1993.10476353
Godefroid M, Cruaud A, Streito J-C, Rasplus J-Y, Rossi J-P (2019) Xylella fastidiosa: climate suitability of European continent. Sci Rep 9:8844
doi: 10.1038/s41598-019-45365-y
Hoeting JA, Madigan D, Raftery AE, Volinsky CT (1999) Bayesian model-averaging: a tutorial. Stat Sci 14:382–417
Huld TA, Šúri M, Dunlop ED, Micale F (2006) Estimating average daytime and daily temperature profiles within Europe. Environ Modell Softw 21:1650–1661
doi: 10.1016/j.envsoft.2005.07.010
Jeanmonod D, Natali A (1997) Les xénophytes de Corse: un danger pour la flore indigène. Lagascalia 19:783–792
Jones DR, Baker RHA (2004) Introductions of non-native plant pathogens into Great Britain, 1970–2004. Plant Pathol 56:891–910
doi: 10.1111/j.1365-3059.2007.01619.x
Kissler SM, Tedijanto C, Goldstein E, Grad YH, Lipsitch M (2020) Projecting the transmission dynamics of SARS-CoV-2 through the postpandemic period. Science 368:860–868
doi: 10.1126/science.abb5793
Kottelenberg D, Hemerik L, Saponari M, Van Der Werf W (2021) Shape and rate of movement of the invasion front of Xylella fastidiosa spp. pauca in Puglia. Sci Rep 11:1–14
doi: 10.1038/s41598-020-79279-x
Lamon EC, Clyde MA (2000) Accounting for model uncertainty in prediction of chlorophyll a in lake okeechobee. J Agric Biol Environ Stat 5:297–322
doi: 10.2307/1400456
Lanzarone E, Pasquali S, Gilioli G, Marchesini E (2017) A Bayesian estimation approach for the mortality in a stage-structured demographic model. J Math Biol 75:759–779
doi: 10.1007/s00285-017-1099-4
Leamer E (1978) Specification searches: Ad hoc inference with nonexperimental data. vol 53. Wiley
Leitner M, Kühn I (2018) Dispersal in plants and animals. In: Bunde A, Caro J, Kärger J, Vogl G (eds) Diffusive spreading in nature, technology and society. Springer International Publishing, Cham, pp 29–47
doi: 10.1007/978-3-319-67798-9_3
Louvrier J, Papaix J, Duchamp C, Gimenez O (2020) A mechanistic-statistical species distribution model to explain and forecast wolf (Canis lupus) colonization in South-Eastern France. Spatial Stat 36:100428
doi: 10.1016/j.spasta.2020.100428
Madigan D, Gavrin J, Raftery AE (1995) Enhancing the predictive performance of Bayesian graphical models. Commun Stat Theory Methods 24:2271–2292
doi: 10.1080/03610929508831616
Madigan D, Raftery AE (1994) Model selection and accounting for model uncertainty in graphical models using Occam’s window. J Am Stat Assoc 89:1535–1546
doi: 10.1080/01621459.1994.10476894
Marin J-M, Pudlo P, Sedki M (2019) Consistency of adaptive importance sampling and recycling schemes. Bernoulli 25:1977–1998
doi: 10.3150/18-BEJ1042
Martinetti D, Soubeyrand S (2019) Identifying lookouts for epidemio-surveillance: application to the emergence of Xylella fastidiosa in France. Phytopathology 109:265–276
doi: 10.1094/PHYTO-07-18-0237-FI
Mason SJ (2004) On using “climatology’’ as a reference strategy in the Brier and ranked probability skill scores. Mon Weather Rev 132:1891–1895
doi: 10.1175/1520-0493(2004)132<1891:OUCAAR>2.0.CO;2
McElreath R (2018) Overfitting, regularization, and information criteria. In: Statistical rethinking: a Bayesian course with examples in R and Stan. Chapman and Hall/CRC
Newton MA, Raftery AE (1994) Approximate Bayesian inference with the weighted likelihood bootstrap. J R Stat Soc B 56:3–26
Oehler VG, Yeung KY, Choi YE, Bumgarner RE, Raftery AE, Radich JP (2009) The derivation of diagnostic markers of chronic myeloid leukemia progression from microarray data. Blood 114:3292–3298
doi: 10.1182/blood-2009-03-212969
Okubo A, Levin S (2002) Diffusion and ecological problems: modern perspectives. Springer Science & Business Media, New York
Ovaskainen O, Rekola H, Meyke E, Arjas E (2008) Bayesian methods for analyzing movements in heterogeneous landscapes from mark-recapture data. Ecology 89:542–554
doi: 10.1890/07-0443.1
Parkinson D, Liddle AR (2013) Bayesian model averaging in astrophysics: a review. Stat Anal Data Min ASA Data Sci J 6:3–14
doi: 10.1002/sam.11179
Peterson RO, Vucetich JA, Page RE, Chouinard A et al (2003) Temporal and spatial aspects of predator-prey dynamics. Alces 39:215–232
Protter MH, Weinberger HF (1967) Maximum principles in differential equations. Prentice-Hall, Englewood Cliffs, New Jersey
Pyšek P, Hulme PE (2005) Spatio-temporal dynamics of plant invasions: linking pattern to process. Ecoscience 12:302–315
doi: 10.2980/i1195-6860-12-3-302.1
Raffini F, Bertorelle G, Biello R, D’Urso G, Russo D, Bosso L (2020) From nucleotides to satellite imagery: approaches to identify and manage the invasive pathogen Xylella fastidiosa and its insect vectors in Europe. Sustainability 12:4508
doi: 10.3390/su12114508
Raftery AE (1996) Approximate Bayes factors and accounting for model uncertainty in generalised linear models. Biometrika 83:251–266
doi: 10.1093/biomet/83.2.251
Raftery AE, Gneiting T, Balabdaoui F, Polakowski M (2005) Using Bayesian model averaging to calibrate forecast ensembles. Mon Weather Rev 133:1155–1174
doi: 10.1175/MWR2906.1
Roques L (2013) Modèles de réaction-diffusion pour l’écologie spatiale. Editions Quae, Paris
Roques L, Bonnefon O, Baudrot V, Soubeyrand S, Berestycki H (2020) A parsimonious approach for spatial transmission and heterogeneity in the COVID-19 propagation. R Soc Open Sci 7:201382
doi: 10.1098/rsos.201382
Roques L, Soubeyrand S (2023) Les invasions biologiques à la lumière des modèles. In: Lannou C, Rasplus J-Y, Soubeyrand S, Gautier M, Rossi J-P (eds) Crises sanitaires en agriculture: Les espèces invasives sous surveillance. Editions Quae, Versailles, pp 167–185
Roques L, Soubeyrand S, Rousselet J (2011) A statistical-reaction-diffusion approach for analyzing expansion processes. J Theor Biol 274:43–51
doi: 10.1016/j.jtbi.2011.01.006
Roques L, Walker E, Franck P, Soubeyrand S, Klein E (2016) Using genetic data to estimate diffusion rates in heterogeneous landscapes. J Math Biol 73:397–422
doi: 10.1007/s00285-015-0954-4
Rubin DB, Schenker N (1986) Efficiently simulating the coverage properties of interval estimates. J R Stat Soc C 35:159–167
Schurr FM, Pagel J, Cabral JS, Groeneveld J, Bykova O, O’Hara RB, Hartig F, Kissling WD, Linder HP, Midgley GF, Schröder B, Singer A, Zimmermann NE (2012) How to understand species’ niches and range dynamics: a demographic research agenda for biogeography. J Biogeogr 39:2146–2162
doi: 10.1111/j.1365-2699.2012.02737.x
Shigesada N, Kawasaki K, Takeda Y (1995) Modeling stratified diffusion in biological invasions. Am Nat 146:229–251
doi: 10.1086/285796
Sidman AH, Mak M, Lebo MJ (2008) Forecasting non-incumbent presidential elections: Lessons learned from the 2000 election. Int J Forecast 24:237–258
doi: 10.1016/j.ijforecast.2008.03.003
Skellam JG (1951) Random dispersal in theoretical populations. Biometrika 38:196–218
doi: 10.1093/biomet/38.1-2.196
Soubeyrand S, Abboud C (2022). Data set: average daily minimum temperature in January and February in Corsica
Soubeyrand S, de Jerphanion P, Martin O, Saussac M, Manceau C, Hendrikx P, Lannou C (2018) What dynamics underly temporal observations? Application to the emergence of Xylella fastidiosa in France: probably not a recent story. New Phytol 219:824–836
doi: 10.1111/nph.15177
Soubeyrand S, Roques L (2014) Parameter estimation for reaction-diffusion models of biological invasions. Popul Ecol 56:427–434
doi: 10.1007/s10144-013-0415-0
Turchin P (1998) Quantitative analysis of movement: measuring and modeling population redistribution in plants and animals. Sinauer, Sunderland, Massachusetts
Viallefont V, Raftery AE, Richardson S (2001) Variable selection and bayesian model averaging in case-control studies. Stat Med 20:3215–3230
doi: 10.1002/sim.976
White SM, Bullock JM, Hooftman DAP, Chapman DS (2017) Modelling the spread and control of Xylella fastidiosa in the early stages of invasion in Apulia, Italy. Biol Invasions 19:1825–1837
doi: 10.1007/s10530-017-1393-5
White SM, Navas-Cortés JA, Bullock JM, Boscia D, Chapman DS (2020) Estimating the epidemiology of emerging Xylella fastidiosa outbreaks in olives. Plant Pathol 69:1403–1413
doi: 10.1111/ppa.13238
Wikle CK (2003) Hierarchical Bayesian models for predicting the spread of ecological processes. Ecology 84:1382–1394
doi: 10.1890/0012-9658(2003)084[1382:HBMFPT]2.0.CO;2
Williams PJ, Hooten MB, Womble JN, Esslinger GG, Bower MR (2018) Monitoring dynamic spatio-temporal ecological processes optimally. Ecology 99:524–535
doi: 10.1002/ecy.2120
Wintle BA, McCarthy MA, Volinsky CT, Kavanagh RP (2003) The use of Bayesian model averaging to better represent uncertainty in ecological models. Conserv Biol 17:1579–1590
doi: 10.1111/j.1523-1739.2003.00614.x
Yeung KY, Bumgarner RE, Raftery AE (2005) Bayesian model averaging: development of an improved multi-class, gene selection and classification tool for microarray data. Bioinformatics 21:2394–2402
doi: 10.1093/bioinformatics/bti319