Gene-Trait Matching and Prevalence of Nisin Tolerance Systems in Lactococus lactis

Gijtenbeek, Lieke A van; Eckhardt, Thomas; Herrera-Dominguez, Lucía; Brockmann, Elke; Jensen, Kristian; Geppel, Asger; Nielsen, Kristian Fog; Vindeloev, Jannik; Neves, Ana Rute; Øregaard, Gunnar

doi:10.3389/fbioe.2021.622835

Cited by 6 publications

(5 citation statements)

References 95 publications

(142 reference statements)

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“…Previous comparative genome analysis of 43 L. lactis genomes identified a subset of four strains retaining nisFEG/nisI genes, without biosynthesis genes, but did not determine if these strains retained full immune capacity to nisin [ 62 ]. A gene-trait matching study of 710 individual L. lactis strains identified 59 strains that encoded nisRKFEG , without other biosynthetic machinery, and found that nisFEG always co-occurred with nisRK and imparted the ability to survive and acidify milk in the presence a 1.5 µg·mL −1 level of nisin, but was not as effective as the presence of nsr [ 63 ]. The same study identified the presence of the nisin immunity protein-encoding gene nisI co-localised with nisP in 16/710 genomes, which conferred some degree of nisin resistance [ 63 ].…”

Section: Discussionmentioning

confidence: 99%

“…A gene-trait matching study of 710 individual L. lactis strains identified 59 strains that encoded nisRKFEG , without other biosynthetic machinery, and found that nisFEG always co-occurred with nisRK and imparted the ability to survive and acidify milk in the presence a 1.5 µg·mL −1 level of nisin, but was not as effective as the presence of nsr [ 63 ]. The same study identified the presence of the nisin immunity protein-encoding gene nisI co-localised with nisP in 16/710 genomes, which conferred some degree of nisin resistance [ 63 ]. The nisIP sub-gene cluster was not detected among S. equinus genomes, which could result from the fact that the two genes are at opposing ends of the nisin E gene cluster, rather than co-localised, as they are in the nisin A gene cluster, which would more easily facilitate co-retention after the loss of other genes ( Figure 2 a).…”

Section: Discussionmentioning

confidence: 99%

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Nisin E Is a Novel Nisin Variant Produced by Multiple Streptococcus equinus Strains

et al. 2023

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Nisin A, the prototypical lantibiotic, is an antimicrobial peptide currently utilised as a food preservative, with potential for therapeutic applications. Here, we describe nisin E, a novel nisin variant produced by two Streptococcus equinus strains, APC4007 and APC4008, isolated from sheep milk. Shotgun whole genome sequencing and analysis revealed biosynthetic gene clusters similar to nisin U, with a unique rearrangement of the core peptide encoding gene within the cluster. The 3100.8 Da peptide by MALDI-TOF mass spectrometry, is 75% identical to nisin A, with 10 differences, including 2 deletions: Ser29 and Ile30, and 8 substitutions: Ile4Lys, Gly18Thr, Asn20Pro, Met21Ile, His27Gly, Val32Phe, Ser33Gly, and Lys34Asn. Nisin E producing strains inhibited species of Lactobacillus, Bacillus, and Clostridiodes and were immune to nisin U. Sequence alignment identified putative promoter sequences across the nisin producer genera, allowing for the prediction of genes in Streptococcus to be potentially regulated by nisin. S. equinus pangenome BLAST analyses detected 6 nisin E operons across 44 publicly available genomes. An additional 20 genomes contained a subset of nisin E transport/immunity and regulatory genes (nseFEGRK), without adjacent peptide production genes. These genes suggest that nisin E response mechanisms, distinct from the canonical nisin immunity and resistance operons, are widespread across the S. equinus species. The discovery of this new nisin variant and its immunity determinants in S. equinus suggests a central role for nisin in the competitive nature of the species.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Nisin E Is a Novel Nisin Variant Produced by Multiple Streptococcus equinus Strains

et al. 2023

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“…It is worth noting that these genes are often positioned on transmissible elements such as plasmids (Froseth and McKay 1991 , Liu et al 1997 ), highlighting the potential for NSR-associated resistance transfer to other microbes. Indeed, the prevalence of NSR amongst lactococci was recently emphasized when whole genome sequencing of 710 dairy-associated L. lactis strains found that an impressive 270 (38%) harboured an nsr gene (van Gijtenbeek et al 2021 ). Furthermore, a singular nis I immunity gene located on a 50-kb plasmid was shown to provide nisin resistance to the non-nisin producer L. lactis NCDO712 (Tarazanova et al 2016 ).…”

Section: Nisin Resistance and Immunity Mechanismsmentioning

confidence: 99%

After a century of nisin research - where are we now?

Ullivarri

Ross

Field

2023

FEMS Microbiology Reviews

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It is almost a century since nisin was discovered in fermented milk cultures, coincidentally in the same year that penicillin was first described. Over the last 100 years this small, highly modified pentacyclic peptide has not only found success in the food industry as a preservative but has also served as the paradigm for our understanding of the genetic organization, expression and regulation of genes involved in lantibiotic biosynthesis – one of the few cases of extensive post-translation modification in prokaryotes. Recent developments in understanding the complex biosynthesis of nisin have shed light on the cellular location of the modification and transport machinery and the co-ordinated series of spatio-temporal events required to produce active nisin and provide resistance and immunity. The continued unearthing of new natural variants from within human and animal gastrointestinal tracts has sparked interest in the potential application of nisin to influence the microbiome, given the growing recognition of the role the gastrointestinal microbiota plays in health and disease. Moreover, interdisciplinary approaches have taken advantage of biotechnological advancements to bioengineer nisin to produce novel variants and expand nisin functionality for applications in the biomedical field. This review will discuss the latest progress in these aspects of nisin research.

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“…For instance, the MntH manganese transporter in Lacticaseibacillus rhamnosus and Lacticaseibacillus paracasei was established as a major factor responsible for the phenotype of yeast and mold inhibition (Siedler et al 2020 ), and BLAST -based identification of the encoding gene in other related species could subsequently be correlated with the inhibitory phenotype. Similarly, phenotypes such as nisin resistance (van Gijtenbeek et al 2021 ) or the ability to catabolize plant sugars in Lactococcus lactis (Siezen et al 2008 ) and polysaccharide synthesis in Oenococcus oeni (Dimopoulou et al 2016 ) were predicted through BLAST -based homology search.…”

Section: Knowledge-driven Approachesmentioning

confidence: 99%

From genotype to phenotype: computational approaches for inferring microbial traits relevant to the food industry

Karlsen

Rau

Sánchez

et al. 2023

FEMS Microbiology Reviews

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When selecting microbial strains for the production of fermented foods, various microbial phenotypes need to be taken into account to achieve target product characteristics, such as biosafety, flavor, texture, and health-promoting effects. Through continuous advances in sequencing technologies, microbial whole-genome sequences of increasing quality can now be obtained both cheaper and faster, which increases the relevance of genome-based characterization of microbial phenotypes. Prediction of microbial phenotypes from genome sequences makes it possible to quickly screen large strain collections in silico to identify candidates with desirable traits. Several microbial phenotypes relevant to the production of fermented foods can be predicted using knowledge-based approaches, leveraging our existing understanding of the genetic and molecular mechanisms underlying those phenotypes. In the absence of this knowledge, data-driven approaches can be applied to estimate genotype-phenotype relationships based on large experimental datasets. Here, we review computational methods that implement knowledge- and data-driven approaches for phenotype prediction, as well as methods that combine elements from both approaches. Furthermore, we provide examples of how these methods have been applied in industrial biotechnology, with special focus on the fermented food industry.

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Gene-Trait Matching and Prevalence of Nisin Tolerance Systems in Lactococus lactis

Cited by 6 publications

References 95 publications

Nisin E Is a Novel Nisin Variant Produced by Multiple Streptococcus equinus Strains

Nisin E Is a Novel Nisin Variant Produced by Multiple Streptococcus equinus Strains

After a century of nisin research - where are we now?

From genotype to phenotype: computational approaches for inferring microbial traits relevant to the food industry

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