Differential Expression of Paraburkholderia phymatum Type VI Secretion Systems (T6SS) Suggests a Role of T6SS-b in Early Symbiotic Interaction

Hug, Sebastian; Liu, Yilei; Heiniger, Benjamin; Bailly, Aurélien; Ahrens, Christian H.; Eberl, Leo; Pessi, Gabriella

doi:10.3389/fpls.2021.699590

Cited by 13 publications

(16 citation statements)

References 111 publications

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“…Accordingly, Osedax ’s Oceanospirillales endosymbiont is metabolically versatile ( 24, 38 ), encoding a significantly larger repertoire of genes involved in sugar and lipid transport as well as carbohydrate, amino acid, and vitamin synthesis compared to the chemolithoautotrophic endosymbionts of Vestimentifera (Figure 3D). An enrichment of secretion systems likely allows the endosymbiont of Osedax to outcompete other microbes to occupy the bacteriocytes, as has been shown in other symbiotic systems such as Vibrio fischeri -bobtail squid and in the Rhizobia symbionts of legumes ( 64, 65 ). After the Osedax-Oceanospirillales symbiosis is established, the bacteria may transform the bone-derived nutrients acquired by the host into a more diverse set of macronutrients that may be either directly exported to the host or acquired through symbiont digestion ( 26 ) (Figure 9A).…”

Section: Discussionmentioning

confidence: 91%

The hologenome of Osedax frankpressi reveals the genetic interplay for the symbiotic digestion of vertebrate bone

Moggioli

Panossian

Sun

et al. 2022

Preprint

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The marine annelid Osedax has evolved a unique heterotrophic symbiosis that allows it to feed exclusively on sunken bones. Yet, the genetic and physiological principles sustaining this symbiosis are poorly understood. Here we show that Osedax frankpressi has a small, AT-rich genome shaped by extensive gene loss. While the Oceanospirillales endosymbiont of Osedax is enriched in genes for carbohydrate and nitrogen metabolism, O. frankpressi has undergone genetic changes to accommodate bone digestion, including the expansion of matrix metalloproteases, and a loss of pathways to synthesize amino acids that are abundant in collagen. Unlike other symbioses, however, innate immunity genes required to acquire and control the endosymbionts are reduced in O. frankpressi. These findings reveal Osedax has evolved an alternative genomic toolkit to bacterial symbiosis where host-symbiont co-dependence has favoured genome simplicity in the host to exploit the nutritionally unbalanced diet of bones.

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Section: Discussionmentioning

confidence: 91%

The hologenome of Osedax frankpressi reveals the genetic interplay for the symbiotic digestion of vertebrate bone

Moggioli

Panossian

Sun

et al. 2022

Preprint

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“…P. phymatum wild-type containing the empty pPROBE vector (WT-pPROBE) was used as negative control. As a positive control, the P. phymatum reporter strain p nodB , containing the promotor of the nodB gene (Bphy_7722) fused to gfp , was employed (WT- p nodB ) ( Hug et al, 2021 ). The gene nodB is involved in the synthesis of the backbone of NFs, and its expression is known to be induced by flavonoids secreted by the host plant ( Guerreiro et al, 1997 ).…”

Section: Resultsmentioning

confidence: 99%

A novel function of the key nitrogen-fixation activator NifA in beta-rhizobia: Repression of bacterial auxin synthesis during symbiosis

Bellés-Sancho

Liu²,

Heiniger³

et al. 2022

Front. Plant Sci.

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Rhizobia fix nitrogen within root nodules of host plants where nitrogenase expression is strictly controlled by its key regulator NifA. We recently discovered that in nodules infected by the beta-rhizobial strain Paraburkholderia phymatum STM815, NifA controls expression of two bacterial auxin synthesis genes. Both the iaaM and iaaH transcripts, as well as the metabolites indole-acetamide (IAM) and indole-3-acetic acid (IAA) showed increased abundance in nodules occupied by a nifA mutant compared to wild-type nodules. Here, we document the structural changes that a P. phymatum nifA mutant induces in common bean (Phaseolus vulgaris) nodules, eventually leading to hypernodulation. To investigate the role of the P. phymatum iaaMH genes during symbiosis, we monitored their expression in presence and absence of NifA over different stages of the symbiosis. The iaaMH genes were found to be under negative control of NifA in all symbiotic stages. While a P. phymatum iaaMH mutant produced the same number of nodules and nitrogenase activity as the wild-type strain, the nifA mutant produced more nodules than the wild-type that clustered into regularly-patterned root zones. Mutation of the iaaMH genes in a nifA mutant background reduced the presence of these nodule clusters on the root. We further show that the P. phymatum iaaMH genes are located in a region of the symbiotic plasmid with a significantly lower GC content and exhibit high similarity to two genes of the IAM pathway often used by bacterial phytopathogens to deploy IAA as a virulence factor. Overall, our data suggest that the increased abundance of rhizobial auxin in the non-fixing nifA mutant strain enables greater root infection rates and a role for bacterial auxin production in the control of early stage symbiotic interactions.

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“…Accordingly, Osedax's Oceanospirillales endosymbiont is metabolically versatile 24,38 , encoding a significantly larger repertoire of genes involved in sugar and lipid transport as well as carbohydrate, amino acid, and vitamin synthesis compared to the chemolithoautotrophic endosymbionts of Vestimentifera (Figure 3D). An enrichment of secretion systems compared to Vestimentiferan symbionts likely allows the endosymbiont of Osedax to outcompete other microbes as it continually colonize new bacteriocytes, as has been shown in other symbiotic systems such as Vibrio fischeri-bobtail squid and in the Rhizobia symbionts of legumes 64,65 . After the Osedax-Oceanospirillales symbiosis is established, the bacteria may transform the bone-derived nutrients acquired by the host into a more diverse set of macronutrients that may be either directly exported to the host or acquired through symbiont digestion 26 (Figure 9A).…”

Section: Discussionmentioning

confidence: 97%

Distinct genomic routes underlie transitions to specialised symbiotic lifestyles in deep sea annelid worms

Martín-Durán

Moggioli

Panossian

et al. 2022

Preprint

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Annelids have repeatedly evolved symbioses that allow them to colonise extreme ecological niches, like hydrothermal vents and whale falls. Yet, the genetic principles sustaining these symbiotic lifestyles remain unclear. Here we show that different genomic adaptations underpin the symbioses of phylogenetically related annelids with distinct nutritional strategies. While genome compaction and extensive gene losses distinguish the heterotrophic symbiosis of the bone-eating worm Osedax frankpressi, gene gains define the chemoautotrophic symbiosis of deep-sea Vestimentifera. Endosymbionts ultimately compensate most metabolic deficiencies of the host, which include the loss of pathways to recycle nitrogen and synthesise carbohydrates and amino acids enriched in bones in O. frankpressi. Unlike in chemoautotrophic symbioses, innate immunity genes to acquire and control endosymbionts are reduced in O. frankpressi, which, however, has a unique expansion of matrix metalloproteases to digest collagen. Altogether, our study supports that the type of nutritional interaction influences host genome evolution in highly specialized symbioses.

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Differential Expression of Paraburkholderia phymatum Type VI Secretion Systems (T6SS) Suggests a Role of T6SS-b in Early Symbiotic Interaction

Cited by 13 publications

References 111 publications

The hologenome of Osedax frankpressi reveals the genetic interplay for the symbiotic digestion of vertebrate bone

The hologenome of Osedax frankpressi reveals the genetic interplay for the symbiotic digestion of vertebrate bone

A novel function of the key nitrogen-fixation activator NifA in beta-rhizobia: Repression of bacterial auxin synthesis during symbiosis

Distinct genomic routes underlie transitions to specialised symbiotic lifestyles in deep sea annelid worms

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