Functional Symbionts
2682 recordsRecords of insect symbionts with verified function from literatures.
Search by:
- • Host species (e.g., "Drosophila")
- • Symbiont name (e.g., "Wolbachia")
- • Function (e.g., "B vitamins")
- • Function Tag (e.g., "Nitrogen fixation")
- • Phylum (e.g., "Proteobacteria")
| Host Insect | Classification | Localization | Function | Function Tags | Year | Edit | |
|---|---|---|---|---|---|---|---|
|
Serratia sp. PF-27
Pseudomonadota |
Bacteria
|
Extracellular
|
Serratia sp. PF-27 is a strain possessing a siderophore biosynthetic pathway (e.g., desferrioxamine B), which is hypothesized to help the host (Pharaxonotha floridana) tolerate cycad toxins. |
2023 |
|||
|
Serratia
Pseudomonadota |
Bacteria
|
Extracellular
|
Serratia might play a role in detoxifying cycad toxins (e.g., azoxyglycosides and BMAA) in Rhopalotria slossonae. |
2023 |
|||
|
Serratia
Pseudomonadota |
Bacteria
|
Extracellular
|
Serratia might play a role in detoxifying cycad toxins (e.g., azoxyglycosides and BMAA) in Pharaxonotha floridana. |
2023 |
|||
|
Serratia
Pseudomonadota |
Eumaeus atalaUSA |
Bacteria
|
Extracellular
|
Serratia might play a role in detoxifying cycad toxins (e.g., azoxyglycosides and BMAA) in Eumaeus atala. |
2023 |
||
|
Stenotrophomonas sp. St-PFmG
Pseudomonadota |
Bacteria
|
Extracellular
|
Stenotrophomonas sp. St-PFmG is a strain possessing a siderophore biosynthetic pathway (e.g., desferrioxamine B), which is hypothesized to help the host (Pharaxonotha floridana) tolerate cycad toxins. |
2023 |
|||
|
Stenotrophomonas sp. St-PFBMAAmG
Pseudomonadota |
Bacteria
|
Extracellular
|
Stenotrophomonas sp. St-PFBMAAmG is a strain possessing a siderophore biosynthetic pathway (e.g., desferrioxamine B), which is hypothesized to help the host (Pharaxonotha floridana) tolerate cycad toxins. |
2023 |
|||
|
Stenotrophomonas sp. St-RSmG
Pseudomonadota |
Bacteria
|
Extracellular
|
Stenotrophomonas sp. St-RSmG is a strain possessing a siderophore biosynthetic pathway (e.g., desferrioxamine B), which is hypothesized to help the host (Rhopalotria slossonae) tolerate cycad toxins. |
2023 |
|||
|
Stenotrophomonas sp. St-RSBMAAmG
Pseudomonadota |
Bacteria
|
Extracellular
|
Stenotrophomonas sp. St-RSBMAAmG is a strain possessing a siderophore biosynthetic pathway (e.g., desferrioxamine B), which is hypothesized to help the host (Rhopalotria slossonae) tolerate cycad toxins. |
2023 |
|||
|
Stenotrophomonas sp. PFBMAA-4
Pseudomonadota |
Bacteria
|
Extracellular
|
Stenotrophomonas sp. PFBMAA-4 is a strain possessing a siderophore biosynthetic pathway (e.g., desferrioxamine B), which is hypothesized to help the host (Pharaxonotha floridana) tolerate cycad toxins. |
2023 |
|||
|
Stenotrophomonas sp. RS-48
Pseudomonadota |
Bacteria
|
Extracellular
|
Stenotrophomonas sp. RS-48 is a strain possessing a siderophore biosynthetic pathway (e.g., desferrioxamine B), which is hypothesized to help the host (Rhopalotria slossonae) tolerate cycad toxins. |
2023 |
|||
|
Stenotrophomonas
Pseudomonadota |
Bacteria
|
Extracellular
|
Stenotrophomonas might play a role in detoxifying cycad toxins (e.g., azoxyglycosides and BMAA) in Rhopalotria slossonae. |
2023 |
|||
|
Stenotrophomonas
Pseudomonadota |
Bacteria
|
Extracellular
|
Stenotrophomonas might play a role in detoxifying cycad toxins (e.g., azoxyglycosides and BMAA) in Pharaxonotha floridana. |
2023 |
|||
|
Stenotrophomonas
Pseudomonadota |
Eumaeus atalaUSA |
Bacteria
|
Extracellular
|
Stenotrophomonas might play a role in detoxifying cycad toxins (e.g., azoxyglycosides and BMAA) in Eumaeus atala. |
2023 |
||
|
Streptomyces philanthi
Actinomycetota |
Philanthus triangulumGermany |
Bacteria
|
Streptomyces philanthi protects the offspring of Philanthus triangulum from opportunistic pathogens by producing antibiotics. The host, in turn, protects the symbiont from oxidative and nitrosative damage. |
2023 |
|||
|
Buchnera aphidicola
Pseudomonadota |
Acyrthosiphon pisumChina |
Bacteria
|
Extracellular
|
Buchnera aphidicola (an endosymbiont) can synthesize and provide essential nutrients (e.g., amino acids) for its host, Acyrthosiphon pisum. |
2023 |
||
|
Enterococcus faecalis
Bacillota |
Riptortus pedestrisSouth Korea |
Bacteria
|
Extracellular
|
Enterococcus faecalis (a gut strain) can be utilized as a probiotic to increase the survival rate of the host, Riptortus pedestris. |
2023 |
||
|
Lactococcus lactis B1None3
Bacillota |
Riptortus pedestrisSouth Korea |
Bacteria
|
Extracellular
|
Lactococcus lactis B1None3 (a gut strain) can be utilized as a probiotic to increase the survival rate of the host, Riptortus pedestris. |
2023 |
||
|
Lactococcus lactis B1None3
Bacillota |
Riptortus pedestrisSouth Korea |
Bacteria
|
Extracellular
|
Lactococcus lactis B1None3 (a gut strain) can be utilized as a probiotic to increase the survival rate of the host, Riptortus pedestris. |
2023 |
||
Agrotis ipsilonEgypt |
Bacteria
|
Extracellular
|
Gut bacterial communities (Amplicon data) in Agrotis ipsilon larvae are capable of degrading various polysaccharides (including cellulose, xylan, pectin, and starch) and producing lipolytic and protease enzymes to aid host metabolism. |
2023 |
|||
Spodoptera littoralisEgypt |
Bacteria
|
Extracellular
|
2023 |