Identification of two archaeal GDGT lipid–modifying proteins reveals diverse microbes capable of GMGT biosynthesis and modification

SummaryBacterial membrane lipids have been traditionally defined as fatty acids (FAs) bilayers linked through ester bonds, while those of Archaea as ether-linked isoprenoids forming bilayers or monolayers of membrane spanning lipids (MSLs) known as isoprenoidal glycerol dialkyl glycerol tetraethers (isoGDGTs). This paradigm has been challenged with the discovery of branched GDGTs (brGDGTs), membrane spanning ether-bound branched alkyl FAs, that are of bacterial origin but whose specific producers in the environment are often unknown. The limited number of available microbial cultures restricts the knowledge of the biological sources of membrane lipids, which in turn limits their potential applicability as biomarkers. To address this limitation, we detected membrane lipids in the Black Sea using high resolution accurate mass/mass spectrometry and inferred their potential producers by targeting lipid biosynthetic pathways encoded on the metagenome, in metagenome-assembled genomes and unbinned scaffolds. We also detected brGDGTs and overly branched GDGTs in the suboxic and euxinic waters, which are potentially attributed, to members of the Planctomycetota, Cloacimonadota, Desulfobacterota, Chloroflexota, Actinobacteria and Myxococcota—all anaerobic microorganisms. These results open a new chapter in the use of specific brGDGTs as biomarkers of anoxic conditions in marine settings and of the role of these membrane lipids in microbial adaptation.

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Decoding the chemical language of RiPPs from the untapped Archaea domain

Song,

Cai,

Gao

et al. 2024

Preprint

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Chemical communication is crucial in ecosystems with complex microbial assemblages. However, due to archaeal cultivation challenges, our understanding of the structure diversity and function of secondary metabolites (SMs) within archaeal communities is limited compared to the extensively studied and well-documented bacterial counterparts. Our comprehensive investigation into the biosynthetic potential of archaea, combined with metabolic analyses and heterologous expression, has unveiled the previously unexplored biosynthetic capabilities and chemical diversity of Archaeal SMs. This represents the first reported instance of heterologous expression of archaeal SMs. We have identified twenty-four new lanthipeptides of RiPPs exhibiting unique chemical characteristics, including a novel subfamily featuring an unexplored type with diamino-dicarboxylic (DADC) termini, largely expanding the chemical landscape of Archaeal SMs. The maturation process of this noncanonical DADC lanthipeptide deviates from classical ones by cleaving amino acids within the thioether rings. This sheds light on the biosynthetic novelty of archaeal metabolites and emphasizes their potential as an untapped resource for SMs. Interestingly, archaeal lanthipeptides exhibit haloarchaea-specific antagonistic activity and enhance the host's motility, facilitating the archaeal interaction with biotic and abiotic environments. Our discoveries broaden our understanding of archaeal chemical language and provide promising prospects for future exploration of SM-mediated interactions in this domain.

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Identification of two archaeal GDGT lipid–modifying proteins reveals diverse microbes capable of GMGT biosynthesis and modification

Cited by 3 publications

References 74 publications

Structural insights linking H-bridging of archaeal GDGTs to high temperature

Structural insights linking H-bridging of archaeal GDGTs to high temperature

Unraveling an unknown diversity of archaeal and bacterial tetraether membrane lipid producers in a euxinic marine system

Decoding the chemical language of RiPPs from the untapped Archaea domain

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