Association of Long-Term Habitual Dietary Fiber Intake since Infancy with Gut Microbiota Composition in Young Adulthood

Dietary fiber is an important health-promoting component of the diet, which is fermented by the gut microbes that produce metabolites beneficial for the host’s health. We studied the associations of habitual long-term fiber intake from infancy with gut microbiota composition in young adulthood by le...

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Veröffentlicht in:The Journal of nutrition 2024-02, Vol.154 (2), p.744-754
Hauptverfasser: Heiskanen, Marja A, Aatsinki, Anna, Hakonen, Petra, Kartiosuo, Noora, Munukka, Eveliina, Lahti, Leo, Keskitalo, Anniina, Huovinen, Pentti, Niinikoski, Harri, Viikari, Jorma, Rönnemaa, Tapani, Lagström, Hanna, Jula, Antti, Raitakari, Olli, Rovio, Suvi P, Pahkala, Katja
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Sprache:eng
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Zusammenfassung:Dietary fiber is an important health-promoting component of the diet, which is fermented by the gut microbes that produce metabolites beneficial for the host’s health. We studied the associations of habitual long-term fiber intake from infancy with gut microbiota composition in young adulthood by leveraging data from the Special Turku Coronary Risk Factor Intervention Project, an infancy-onset 20-y dietary counseling study. Fiber intake was assessed annually using food diaries from infancy ≤ age 20 y. At age 26 y, the first postintervention follow-up study was conducted including food diaries and fecal sample collection (N = 357). Cumulative dietary fiber intake was assessed as the area under the curve for energy-adjusted fiber intake throughout the study (age 0–26 y). Gut microbiota was profiled using 16S ribosomal ribonucleic acid amplicon sequencing. The primary outcomes were 1) α diversity expressed as the observed richness and Shannon index, 2) β diversity using Bray-Curtis dissimilarity scores, and 3) differential abundance of each microbial taxa with respect to the cumulative energy-adjusted dietary fiber intake. Higher cumulative dietary fiber intake was associated with decreased Shannon index (β = –0.019 per unit change in cumulative fiber intake, P = 0.008). Overall microbial community composition was related to the amount of fiber consumed (permutational analysis of variation R2 = 0.005, P = 0.024). The only genus that was increased with higher cumulative fiber intake was butyrate-producing Butyrivibrio (log2 fold-change per unit change in cumulative fiber intake 0.40, adjusted P = 0.023), whereas some other known butyrate producers such as Faecalibacterium and Subdoligranulum were decreased with higher cumulative fiber intake. As early-life nutritional exposures may affect the lifetime microbiota composition and disease risk, this study adds novel information on the associations of long-term dietary fiber intake with the gut microbiota. This trial was registered at clinicaltrials.gov as NCT00223600.
ISSN:0022-3166
1541-6100
1541-6100
DOI:10.1016/j.tjnut.2024.01.008