Functional Symbionts
227 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 | |
|---|---|---|---|---|---|---|---|
Epibolus pulchripesCzechia |
Bacteria
|
2024 |
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Glomeris connexaCzech |
Bacteria
|
2024 |
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|
Bacteroides
Bacteroidota |
Hyphantria cuneaChina |
Bacteria
|
Extracellular
|
The presence of Bacteroides is part of the gut microbiota that enhances the compatibility of the invasive pest (Hyphantria cunea) to new host plants, facilitating rapid adaptation. |
2024 |
||
|
Blautia
Bacillota |
Hyphantria cuneaChina |
Bacteria
|
Extracellular
|
The presence of Blautia is part of the gut microbiota that enhances the compatibility of the invasive pest (Hyphantria cunea) to new host plants, facilitating rapid adaptation. |
2024 |
||
|
Coprococcus
Bacillota |
Hyphantria cuneaChina |
Bacteria
|
Extracellular
|
The presence of Coprococcus is part of the gut microbiota that enhances the compatibility of the invasive pest (Hyphantria cunea) to new host plants, facilitating rapid adaptation. |
2024 |
||
|
Blattabacterium cuenoti
Bacteroidota |
Blattella germanicaSpain |
Bacteria
|
Intracellular
|
Blattabacterium cuenoti serves as the obligate endosymbiont and primary nutritional provider, contributing to amino acid provision and affecting uric acid storage in Blattella germanica. |
2024 |
||
Blattella germanicaSpain |
Bacteria
|
Extracellular
|
The gut bacteria are not essential for Blattella germanica's survival and development but may complement host nutrition by assisting with food digestion and nutrient absorption. |
2024 |
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|
Enterococcus faecalis
Bacillota |
Bactrocera minaxChina |
Bacteria
|
Extracellular
|
Enterococcus faecalis degrades phenols found in unripe citrus within Bactrocera minax larvae, functioning as a key detoxification enzyme provider. |
2024 |
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|
Serratia marcescens
Pseudomonadota |
Bactrocera minaxChina |
Bacteria
|
Extracellular
|
Serratia marcescens degrades phenols found in unripe citrus within Bactrocera minax larvae, functioning as a key detoxification enzyme provider. |
2024 |
||
Apis melliferaSouth Korea, |
Bacteria
|
Extracellular
|
2024 |
||||
Harmonia axyridisChina |
Bacteria
|
Extracellular
|
2024 |
||||
|
Staphylococcus
Bacillota |
Harmonia axyridisChina |
Bacteria
|
Extracellular
|
2024 |
|||
|
Staphylococcus
Bacillota |
Harmonia axyridisChina |
Bacteria
|
Extracellular
|
2024 |
|||
Harmonia axyridisChina |
Bacteria
|
Extracellular
|
2024 |
||||
Dorcus hopei hopeiChina |
Bacteria
|
Extracellular
|
2024 |
||||
Zeuzera coffeaeChina |
Bacteria
|
2024 |
|||||
|
Enterobacter
Pseudomonadota |
Ceratitis capitataTunisian |
Bacteria
|
Extracellular
|
Enterobacter (as part of a probiotic consortium) significantly influences the intestinal microbiota structure, leading to improved functional potential and increased carbohydrate-active enzymes (CAZymes) in Ceratitis capitata. |
2024 |
||
|
Klebsiella oxytoca
Pseudomonadota |
Ceratitis capitataTunisian |
Bacteria
|
Extracellular
|
Klebsiella oxytoca (as part of a probiotic consortium) significantly influences the intestinal microbiota structure, leading to improved functional potential and increased carbohydrate-active enzymes (CAZymes) in Ceratitis capitata. |
2024 |
||
|
Lactococcus lactis
Bacillota |
Ceratitis capitataTunisian |
Bacteria
|
Extracellular
|
Lactococcus lactis (as part of a probiotic consortium) significantly influences the intestinal microbiota structure, leading to improved functional potential and increased carbohydrate-active enzymes (CAZymes) in Ceratitis capitata. |
2024 |
||
Riptortus pedestrisChina |
Bacteria
|
Extracellular
|
2024 |