Unveiling the genetic landscape and motility-associated functions of Type IV pili in the Bifidobacterium genus

Gabriele Andrea Lugli; Emanuele Selleri; Chiara Tarracchini; Aryanna Muscò; Silvia Petraro; Giulia Longhi; Leonardo Mancabelli; Christian Milani; Francesca Turroni; Marco Ventura

doi:10.20517/mrr.2025.119

Microbiome Research Reports ›› 2026, Vol. 5 ›› Issue (1) -6. DOI: 10.20517/mrr.2025.119

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Unveiling the genetic landscape and motility-associated functions of Type IV pili in the Bifidobacterium genus

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Abstract

Background: Bifidobacteria are recognized as one of the most influential bacterial groups inhabiting the human gut, capable of modulating the host’s health. To understand how these bacteria interact with their hosts, it is essential to investigate their extracellular structures, such as pili. While the presence of sortase-dependent pili has already been investigated in the Bifidobacterium genus, limited information is available on Type IV pili (T4P), which have previously been identified in a few species as tight adherence (Tad) loci.

Methods: Here, we explored the T4P distribution across the currently 117 (sub)species representing all described taxa of the Bifidobacterium genus, revealing two distinct loci unevenly distributed within the genus through in silico genomic analyses supported by in vitro validation.

Results: Our analysis identified a conserved Type IVc pili (T4cP) structure across all bifidobacterial taxa, with minor predicted structural variations in members of the Bifidobacterium longum and Bifidobacterium boum phylogenetic groups. This T4cP structure, also known as Tad, exhibited an ancestral, non-retractile architecture typically associated with stable colonization and long-term persistence. In addition, a secondary Type IVa pili (T4aP) structure was detected in 13 bifidobacterial species. These species are associated with specific ecological niches, including primate, bovine, and porcine hosts, suggesting a link between this locus and host-associated adaptation.

Conclusion: Notably, twitching motility assays demonstrated that Bifidobacterium adolescentis strains harboring the T4aP locus exhibit motility in response to specific environmental signals, observed upon starch supplementation of the growth medium, thereby challenging the traditional view of bifidobacteria as a strictly non-motile bacterial genus.

Keywords

Bifidobacteria / genomics / phylogenetics / extracellular structures / T4P

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Gabriele Andrea Lugli, Emanuele Selleri, Chiara Tarracchini, Aryanna Muscò, Silvia Petraro, Giulia Longhi, Leonardo Mancabelli, Christian Milani, Francesca Turroni, Marco Ventura. Unveiling the genetic landscape and motility-associated functions of Type IV pili in the Bifidobacterium genus. Microbiome Research Reports, 2026, 5(1): -6 DOI:10.20517/mrr.2025.119

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