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 | |
|---|---|---|---|---|---|---|---|
|
Acetobacter malorum
Pseudomonadota |
Bacteria
|
Extracellular
|
Acetobacter malorum results in the development of larger ovaries and increased egg numbers in Drosophila melanogaster. |
2019 |
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|
Saccharomyces cerevisiae
Ascomycota |
Fungi
|
Extracellular
|
Saccharomyces cerevisiae results in the development of larger ovaries and increased egg numbers in Drosophila melanogaster. |
2019 |
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|
Regiella insecticola
Pseudomonadota |
Sitobion avenaeChile |
Bacteria
|
Intracellular
|
Regiella insecticola infection in aphids results in increased predation by the ladybird Hippodamia variegata, and does not improve defenses against coccinellid predators or metabolic rates. |
2019 |
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|
Pantoea sp.
Pseudomonadota |
Bacteria
|
Extracellular
|
Pantoea sp. improves the fitness of Brachynema germari, as symbiont-free insects exhibit retarded growth, lower longevity, and reduced adult body weight. |
2019 |
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|
Bacteria
|
Extracellular
|
Gut bacteria (microbiome) includes the suppression and detoxification of plant defenses. |
2019 |
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Helicoverpa zeaUSA |
Bacteria
|
Extracellular
|
Gut bacteria (microbiome) includes the suppression and detoxification of plant defenses. |
2019 |
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|
Bacteria
|
Extracellular
|
2019 |
|||||
|
Burkholderia
Pseudomonadota |
Riptortus pedestrisJapan |
Bacteria
|
Burkholderia recycles host metabolic wastes into essential amino acids and B vitamins within the M4 crypts of the host insect. |
2019 |
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|
Serratia marcescens
Pseudomonadota |
Rhodnius prolixusBrazil |
Bacteria
|
Extracellular
|
2019 |
|||
|
Candidatus Regiella insecticola
Pseudomonadota |
Sitobion avenaeChina |
Bacteria
|
Intracellular
|
Candidatus Regiella insecticola infection decreases the intrinsic rate of increase ($\text{r}_\text{m}$) of aphids at $25^{\circ}\text{C}$ and $28^{\circ}\text{C}$; this negative effect is environmentally dependent, with the effect at $31^{\circ}\text{C}$ varying by aphid genotype and density. |
2019 |
||
|
Arsenophonus
Pseudomonadota |
Aphis gossypiiChina |
Bacteria
|
Intracellular
|
Arsenophonus facultative endosymbiont infections alter the performance of Aphis gossypii on an amino-acid-deficient diet. |
2019 |
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|
Xenorhabdus rhabduscin
Pseudomonadota |
Spodoptera frugiperdaFrance |
Bacteria
|
Xenorhabdus rhabduscin gene cluster products inhibit Spodoptera frugiperda phenoloxidase activity. |
2019 |
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|
Arsenophonus
Pseudomonadota |
Bemisia tabaciChina, India, Queen… |
Bacteria
|
Intracellular
|
2019 |
|||
|
Halomonas
Pseudomonadota |
Bemisia tabaciChina, India, Queen… |
Bacteria
|
Intracellular
|
2019 |
|||
|
Rickettsia
Pseudomonadota |
Bemisia tabaciChina, India, Queen… |
Bacteria
|
Intracellular
|
2019 |
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|
Aureobasidium
Ascomycota |
ThitarodesChina |
Fungi
|
Aureobasidium produces useful enzymes, such as amylases, cellulases, lipases, proteases, xylanases, and mannanases. |
2019 |
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|
Aureobasidium
Ascomycota |
Thitarodes puiChina |
Fungi
|
Aureobasidium plays important roles in helping the host larva to digest foods, adapt to extreme environments, or resist pathogens. |
2019 |
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|
Carnobacterium
Bacillota |
Thitarodes puiChina |
Bacteria
|
Carnobacterium promotes the growth of Thitarodes larvae, elevates bacterial diversity, maintains a better balance of intestinal flora, and acts as a probiotic in the host. |
2019 |
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|
Malassezia
Basidiomycota |
Thitarodes puiChina |
Fungi
|
2019 |
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|
Phoma
Ascomycota |
Thitarodes puiChina |
Fungi
|
Phoma plays important roles in helping the host larva to digest foods, adapt to extreme environments, or resist pathogens. |
2019 |