SRR26926464 - Clanis bilineata

Basic Information

Run: SRR26926464

Assay Type: WGS

Bioproject: PRJNA1043846

Biosample: SAMN37523168

Bytes: 2138412837

Center Name: JIANGSU ACADEMY OF AGRICULTURAL SCIENCES

Sequencing Information

Instrument: Illumina NovaSeq 6000

Library Layout: SINGLE

Library Selection: RANDOM

Platform: ILLUMINA

Geographic Information

Country: China

Continent: Asia

Location Name: China: Nanjing

Latitude/Longitude: 32.04 N 118.88 E

Sample Information

Host: Clanis bilineata

Isolation: edible insects

Biosample Model: Metagenome or environmental

Collection Date: 2021-10-07

Taxonomic Classification

Potential Symbionts

About Potential Symbionts

This table shows potential symbiont identified in the metagenome sample. Matches are scored based on:

Relative abundance in the sample
Species-level matches with known symbionts
Host insect order matches with reference records
Completeness and richness of functional records

Note: only the three highest scoring comparison records were retained for each symbiont species or genus in the sample

Based on our current records database, this section aims to identify potential functional symbionts in this metagenome sample, with scoring based on:

Relative abundance in sample
Species-level matches with known symbionts
Host insect order matches
Functional record completeness

Note: Showing top 3 highest scoring records for each species/genus

Symbiont Name	Record	Host Species	Function	Abundance	Score Score Composition: Symbiont Abundance Species match bonus Host match bonus Function richness Higher scores indicate stronger symbiotic relationship potential
Enterococcus mundtii Species-level Match Host Order Match	RISB1733	Spodoptera littoralis Order: Lepidoptera	actively secretes a stable class IIa bacteriocin (mundticin KS) against invading bacteria, including the opportunistic pathogens E. faecalis and E. casseliflavus, but not against other gut residents, facilitating the normal development of host gut microbiota	47.50%	67.5
Enterococcus mundtii Species-level Match Host Order Match	RISB0476	Spodoptera litura Order: Lepidoptera	The ingestion of bacteria negatively affected the development and nutritional physiology of insect. The bacteria after successful establishment started degrading the gut wall and invaded the haemocoel thereby causing the death of the host.	47.50%	67.3
Enterococcus mundtii Species-level Match Host Order Match	RISB2494	Anticarsia gemmatalis Order: Lepidoptera	allow the adaptation of this insect to plants rich in protease inhibitors, minimizing the potentially harmful consequences of protease inhibitors from some of this insect host plants, such as soybean	47.50%	66.5
Klebsiella pneumoniae Species-level Match Host Order Match	RISB2185	Scirpophaga incertulas Order: Lepidoptera	The ability of these arthropods to feed on wood, foliage and detritus is likely to involve catalysis by different types of cellulases/hemicellulases that are secreted by gut microbiota to digest the structural and recalcitrant lignocellulosic residues in their foods.	0.02%	20.0
Microbacterium oleivorans Species-level Match Host Order Match	RISB2194	Scirpophaga incertulas Order: Lepidoptera	The ability of these arthropods to feed on wood, foliage and detritus is likely to involve catalysis by different types of cellulases/hemicellulases that are secreted by gut microbiota to digest the structural and recalcitrant lignocellulosic residues in their foods.	0.01%	20.0
Microbacterium arborescens Species-level Match Host Order Match	RISB2191	Scirpophaga incertulas Order: Lepidoptera	The ability of these arthropods to feed on wood, foliage and detritus is likely to involve catalysis by different types of cellulases/hemicellulases that are secreted by gut microbiota to digest the structural and recalcitrant lignocellulosic residues in their foods.	0.00%	20.0
Bacillus sp. FSL M7-0307 Species-level Match Host Order Match	RISB2181	Scirpophaga incertulas Order: Lepidoptera	The ability of these arthropods to feed on wood, foliage and detritus is likely to involve catalysis by different types of cellulases/hemicellulases that are secreted by gut microbiota to digest the structural and recalcitrant lignocellulosic residues in their foods.	0.00%	20.0
Pantoea agglomerans Species-level Match Host Order Match	RISB2198	Scirpophaga incertulas Order: Lepidoptera	The ability of these arthropods to feed on wood, foliage and detritus is likely to involve catalysis by different types of cellulases/hemicellulases that are secreted by gut microbiota to digest the structural and recalcitrant lignocellulosic residues in their foods.	0.00%	20.0
Serratia marcescens Species-level Match Host Order Match	RISB2200	Scirpophaga incertulas Order: Lepidoptera	The ability of these arthropods to feed on wood, foliage and detritus is likely to involve catalysis by different types of cellulases/hemicellulases that are secreted by gut microbiota to digest the structural and recalcitrant lignocellulosic residues in their foods.	0.00%	20.0
Pseudomonas fulva Species-level Match Host Order Match	RISB0088	Bombyx mori Order: Lepidoptera	Pseudomonas fulva ZJU1 can degrade and utilize the mulberry-derived secondary metabolite, 1-deoxynojirimycin (DNJ) as the sole energy source, and after inoculation into nonspecialists, P. fulva ZJU1 increased host resistance to DNJ and significantly promoted growth	0.00%	20.0
Serratia marcescens Species-level Match Host Order Match	RISB0477	Spodoptera litura Order: Lepidoptera	The ingestion of bacteria negatively affected the development and nutritional physiology of insect. The bacteria after successful establishment started degrading the gut wall and invaded the haemocoel thereby causing the death of the host.	0.00%	19.8
Bacillus thuringiensis Species-level Match Host Order Match	RISB0109	Tuta absoluta Order: Lepidoptera	Individual exposure of B. thuringiensis isolates to P. absoluta revealed high susceptibility of the pest and could potentially be used to develop effective, safe and affordable microbial pesticides for the management of P. absoluta.	0.01%	19.7
Escherichia coli Species-level Match Host Order Match	RISB1339	Manduca sexta Order: Lepidoptera	modulate immunity-related gene expression in the infected F0 larvae, and also in their offspring, triggered immune responses in the infected host associated with shifts in both DNA methylation and histone acetylation	0.02%	19.3
Stenotrophomonas maltophilia Species-level Match Host Order Match	RISB1122	Bombyx mori Order: Lepidoptera	facilitate host resistance against organophosphate insecticides, provides essential amino acids that increase host fitness and allow the larvae to better tolerate the toxic effects of the insecticide.	0.07%	19.1
Bacillus cereus Species-level Match Host Order Match	RISB2489	Anticarsia gemmatalis Order: Lepidoptera	allow the adaptation of this insect to plants rich in protease inhibitors, minimizing the potentially harmful consequences of protease inhibitors from some of this insect host plants, such as soybean	0.02%	19.0
Mammaliicoccus sciuri Species-level Match Host Order Match	RISB0075	Bombyx mori Order: Lepidoptera	could produce a secreted chitinolytic lysozyme (termed Msp1) to damage fungal cell walls，completely inhibit the spore germination of fungal entomopathogens Metarhizium robertsii and Beauveria bassiana	0.00%	19.0
Klebsiella oxytoca Species-level Match Host Order Match	RISB2565	Acrolepiopsis assectella Order: Lepidoptera	Klebsiella oxytoca and Bacillus spp. produce the volatile alkyl disulfides present in the fecal pellets, which serve as kairomones to attract the parasitoid Diadromus pulchellus to the moth host	0.00%	18.9
Serratia marcescens Species-level Match Host Order Match	RISB1426	Maculinea alcon Order: Lepidoptera	been associated with growth-promoting activity, is capable of producing volatile pyrazines, including 2,5-dimethylpyrazine and 3-ethyl-2,5-dimethylpyrazine, which are used as pheromones by ants	0.00%	18.9
Enterobacter ludwigii Species-level Match Host Order Match	RISB1543	Helicoverpa zea Order: Lepidoptera	two immunity-related genes glucose oxidase (GOX) and lysozyme (LYZ) were more highly expressed in both salivary glands and midguts compared with MgCl2 solution-treated caterpillars	0.00%	18.6
Bifidobacterium asteroides Species-level Match Host Order Match	RISB0616	Spodoptera frugiperda Order: Lepidoptera	Strain wkB204 grew in the presence of amygdalin as the sole carbon source, suggesting that this strain degrades amygdalin and is not susceptible to the potential byproducts	0.00%	18.4
Klebsiella oxytoca Species-level Match Host Order Match	RISB1508	Walshia miscecolorella Order: Lepidoptera	Antibiotic-treated larvae suffered growth retardation on a diet containing plant extract or swainsonine. Gut bacteria showed toxin-degradation activities in vitro	0.00%	18.2
Enterobacter sp. BIDMC 29 Species-level Match Host Order Match	RISB1392	Spodoptera frugiperda Order: Lepidoptera	microbe-mediated assaults by maize defenses on the fall armyworm on the insect digestive and immune system reduced growth and elevated mortality in these insects	0.01%	18.2
Enterobacter sp. RHBSTW-00994 Species-level Match Host Order Match	RISB1392	Spodoptera frugiperda Order: Lepidoptera	microbe-mediated assaults by maize defenses on the fall armyworm on the insect digestive and immune system reduced growth and elevated mortality in these insects	0.00%	18.2
Acinetobacter sp. Tol 5 Species-level Match Host Order Match	RISB1500	Lymantria dispar Order: Lepidoptera	Bacteria isolated from a host plant had a glycoside-degrading activity, which enhanced growth of the moth when larvae were fed on a toxin-containing diet	0.00%	18.1
Carnobacterium maltaromaticum Species-level Match Host Order Match	RISB1693	Plutella xylostella Order: Lepidoptera	play an important role in the breakdown of plant cell walls, detoxification of plant phenolics, and synthesis of amino acids.	0.00%	17.5
Pantoea dispersa Species-level Match Host Order Match	RISB0182	Spodoptera frugiperda Order: Lepidoptera	detoxify benzoxazinoids (secondary metabolites produced by maize) and promote caterpillar growth	0.00%	16.9
Acinetobacter sp. Tol 5 Species-level Match Host Order Match	RISB0731	Lymantria dispar Order: Lepidoptera	Condensed tannins improved growth of Acinetobacter sp. by 15% (by measuring the optical density)	0.00%	16.9
Micrococcus sp. 2A Species-level Match Host Order Match	RISB2276	Ostrinia nubilalis Order: Lepidoptera	extreme cellulolytic enzymes, at extreme (pH 12) conditions, exhibited cellulolytic properties	0.00%	16.9
Microbacterium arborescens Species-level Match Host Order Match	RISB1759	Spodoptera frugiperda Order: Lepidoptera	degradation of lambda-cyhalothrin, deltamethrin, chlorpyrifos ethyl, lufenuron and spinosyn	0.00%	16.8
Leclercia adecarboxylata Species-level Match Host Order Match	RISB1757	Spodoptera frugiperda Order: Lepidoptera	degradation of lambda-cyhalothrin, deltamethrin, chlorpyrifos ethyl, lufenuron and spinosyn	0.00%	16.8
Sphingomonas sp. J315 Species-level Match Host Order Match	RISB0134	Spodoptera frugiperda Order: Lepidoptera	provide a protective effect to against chlorantraniliprole stress to S. frugiperda	0.01%	16.7
Sphingomonas sp. LY29 Species-level Match Host Order Match	RISB0134	Spodoptera frugiperda Order: Lepidoptera	provide a protective effect to against chlorantraniliprole stress to S. frugiperda	0.00%	16.6
Stenotrophomonas maltophilia Species-level Match Host Order Match	RISB1123	Bombyx mori Order: Lepidoptera	confer a significant fitness advantage via nutritional (amino acids) upgrading	0.07%	16.6
Carnobacterium maltaromaticum Species-level Match Host Order Match	RISB1692	Plutella xylostella Order: Lepidoptera	participate in the synthesis of host lacking amino acids histidine and threonine	0.00%	16.6
Glutamicibacter halophytocola Species-level Match Host Order Match	RISB0606	Phthorimaea operculella Order: Lepidoptera	could degrade the major toxic α-solanine and α-chaconine in potatoes	0.01%	16.4
Leclercia adecarboxylata Species-level Match Host Order Match	RISB1758	Spodoptera frugiperda Order: Lepidoptera	may influence the metabolization of pesticides in insects	0.00%	16.1
Delftia lacustris Species-level Match Host Order Match	RISB1754	Spodoptera frugiperda Order: Lepidoptera	may influence the metabolization of pesticides in insects	0.00%	16.1
Stenotrophomonas sp. SXG-1 Species-level Match Host Order Match	RISB0031	Sesamia inferens Order: Lepidoptera	degrade Chlorpyrifos and Chlorantraniliprole in vitro	0.02%	16.1
Acinetobacter calcoaceticus Species-level Match Host Order Match	RISB0017	Scirpophaga incertulas Order: Lepidoptera	degrade Chlorpyrifos and Chlorantraniliprole in vitro	0.00%	16.1
Citrobacter freundii Species-level Match Host Order Match	RISB2458	Bombyx mori Order: Lepidoptera	degradation of cellulose, xylan, pectin and starch	0.00%	16.0
Escherichia coli Species-level Match Host Order Match	RISB2120	Galleria mellonella Order: Lepidoptera	mediate trans-generational immune priming	0.02%	15.8
Carnobacterium maltaromaticum Species-level Match Host Order Match	RISB1691	Plutella xylostella Order: Lepidoptera	activity of cellulose and hemicellulose	0.00%	15.8
Pseudomonas sp. St29 Species-level Match Host Order Match	RISB0286	Diatraea saccharalis Order: Lepidoptera	associated with cellulose degradation	0.01%	15.8
Pseudomonas sp. AN-1 Species-level Match Host Order Match	RISB0286	Diatraea saccharalis Order: Lepidoptera	associated with cellulose degradation	0.00%	15.7
Erwinia sp. E602 Species-level Match Host Order Match	RISB1986	Bombyx mori Order: Lepidoptera	producing cellulase and amylase	0.00%	15.6
Nocardioides Host Order Match	RISB1914	Hyles euphorbiae Order: Lepidoptera	able to degrade alkaloids and/or latex	4.53%	15.3
Staphylococcus Host Order Match	RISB1545	Bombyx mori Order: Lepidoptera	Staphyloxanthin pigment from gut symbiont presented considerable biological properties including in vitro antimicrobial activity against pathogens Staphylococcus aureus, Escherichia coli and Candida albicans; in vitro antioxidant activity by % DPPH free radical scavenging activity	0.01%	15.0
Citrobacter freundii Species-level Match Host Order Match	RISB0506	Plutella xylostella Order: Lepidoptera	None	0.00%	15.0
Buchnera aphidicola Species-level Match Host Order Match	RISB0290	Helicoverpa armigera Order: Lepidoptera	None	0.00%	15.0
Staphylococcus Host Order Match	RISB2497	Anticarsia gemmatalis Order: Lepidoptera	allow the adaptation of this insect to plants rich in protease inhibitors, minimizing the potentially harmful consequences of protease inhibitors from some of this insect host plants, such as soybean	0.01%	14.0
Lactobacillus Host Order Match	RISB0292	Lymantria dispar asiatica Order: Lepidoptera	Beauveria bassiana infection-based assays showed that the mortality of non-axenic L. dispar asiatica larvae was significantly higher than that of axenic larvae at 72 h.	0.00%	13.4
Lactobacillus Host Order Match	RISB0715	Spodoptera frugiperda Order: Lepidoptera	Have the function of nutrient absorption, energy metabolism, the plant’s secondary metabolites degradation, insect immunity regulation, and so on	0.00%	12.9
Bacteroides Host Order Match	RISB0090	Hyphantria cunea Order: Lepidoptera	enhance the compatibility of invasive pests to new hosts and enable more rapid adaptation to new habitats.	0.00%	12.1
Streptococcus Host Order Match	RISB2625	Galleria mellonella Order: Lepidoptera	suppress bacteria ingested with food by producing bacteriocin and by releasing a lysozyme like enzyme	0.01%	12.0
Staphylococcus Host Order Match	RISB2247	Anticarsia gemmatalis Order: Lepidoptera	mitigation of the negative effects of proteinase inhibitors produced by the host plant	0.01%	11.7
Raoultella Host Order Match	RISB1672	Spodoptera frugiperda Order: Lepidoptera	downregulated POX but upregulated trypsin PI in this plant species	0.02%	11.3
Streptococcus Host Order Match	RISB2604	Homona magnanima Order: Lepidoptera	influence the growth of Bacillus thuringiensis in the larvae	0.01%	11.2
Clostridium Host Order Match	RISB0028	Sesamia inferens Order: Lepidoptera	degrade Chlorpyrifos and Chlorantraniliprole in vitro	0.03%	11.1
Gordonia Host Order Match	RISB1912	Hyles euphorbiae Order: Lepidoptera	able to degrade alkaloids and/or latex	0.29%	11.1
Aeromonas Host Order Match	RISB2456	Bombyx mori Order: Lepidoptera	able to utilize the CMcellulose and xylan	0.01%	10.8
Curtobacterium Host Order Match	RISB1910	Hyles euphorbiae Order: Lepidoptera	able to degrade alkaloids and/or latex	0.05%	10.8
Brevibacterium Host Order Match	RISB2359	Bombyx mori Order: Lepidoptera	producing lipase in a gut environment	0.02%	10.8
Aeromonas Host Order Match	RISB2563	Samia cynthia Order: Lepidoptera	producing xylanase	0.01%	10.4
Lactobacillus Host Order Match	RISB0617	Spodoptera frugiperda Order: Lepidoptera	degrade amygdalin	0.00%	10.3
Bombilactobacillus Host Order Match	RISB0617	Spodoptera frugiperda Order: Lepidoptera	degrade amygdalin	0.00%	10.3
Methylobacter Host Order Match	RISB2340	Saturniidae Order: Lepidoptera	Nitrogen fixation	0.00%	10.3
Ralstonia Host Order Match	RISB0243	Spodoptera frugiperda Order: Lepidoptera	None	0.01%	10.0
Pantoea agglomerans Species-level Match	RISB2197	Termitidae Order: Blattodea	The ability of these arthropods to feed on wood, foliage and detritus is likely to involve catalysis by different types of cellulases/hemicellulases that are secreted by gut microbiota to digest the structural and recalcitrant lignocellulosic residues in their foods.	0.00%	10.0
Bifidobacterium asteroides Species-level Match	RISB0174	Apis mellifera Order: Hymenoptera	Bifidobacterium provides complementary demethylation service to promote Gilliamella growth on methylated homogalacturonan, an enriched polysaccharide of pectin. In exchange, Gilliamella shares digestive products with Bifidobacterium, through which a positive interaction is established	0.00%	10.0
Buchnera aphidicola Species-level Match	RISB0236	Acyrthosiphon pisum Order: Hemiptera	Buchnera the nutritional endosymbiont of A. pisum is located inside of bacteriocytes and requires aspartate from the aphid host, because it cannot make it de novo. Further Buchnera needs aspartate for the biosynthesis of the essential amino acids lysine and threonine, which the aphid and Buchnera require for survival	0.00%	10.0
Listeria monocytogenes Species-level Match	RISB2308	Drosophila melanogaster Order: Diptera	L. monocytogenes infection disrupts host energy metabolism by depleting energy stores (triglycerides and glycogen) and reducing metabolic pathway activity (beta-oxidation and glycolysis). The infection affects antioxidant defense by reducing uric acid levels and alters amino acid metabolism. These metabolic changes are accompanied by melanization, potentially linked to decreased tyrosine levels.	0.00%	10.0
Cellulosimicrobium sp. ES-005 Species-level Match	RISB2182	Armadillidae Order: Isopoda	The ability of these arthropods to feed on wood, foliage and detritus is likely to involve catalysis by different types of cellulases/hemicellulases that are secreted by gut microbiota to digest the structural and recalcitrant lignocellulosic residues in their foods.	0.00%	10.0
Wolbachia pipientis Species-level Match	RISB0766	Aedes fluviatilis Order: Diptera	The presence of Wolbachia pipientis improves energy performance in A. fluviatilis cells; it affects the regulation of key energy sources such as lipids, proteins, and carbohydrates, making the distribution of actin more peripheral and with extensions that come into contact with neighboring cells.	0.00%	10.0
Burkholderia gladioli Species-level Match	RISB1172	Lagria villosa Order: Coleoptera	process a cryptic gene cluster that codes for the biosynthesis of a novel antifungal polyketide with a glutarimide pharmacophore, which led to the discovery of the gladiofungins as previously-overlooked components of the antimicrobial armory of the beetle symbiont	0.00%	10.0
Kaistia Host Order Match	RISB0829	Spodoptera frugiperda Order: Lepidoptera	None	0.00%	10.0
Cedecea Host Order Match	RISB0504	Plutella xylostella Order: Lepidoptera	None	0.00%	10.0
Deinococcus sp. AB2017081 Species-level Match	RISB1649	Camponotus japonicus Order: Hymenoptera	Four new aminoglycolipids, deinococcucins A–D, were discovered from a Deinococcus sp. strain isolated from the gut of queen carpenter ants, Camponotus japonicus, showed functional ability of inducing the quinone reductase production in host cells	0.00%	9.9
Buchnera aphidicola Species-level Match	RISB2485	Macrosiphum euphorbiae Order: Hemiptera	symbiont expression patterns differ between aphid clones with differing levels of virulence, and are influenced by the aphids' host plant. Potentially, symbionts may contribute to differential adaptation of aphids to host plant resistance	0.00%	9.8
Burkholderia gladioli Species-level Match	RISB1729	Lagria hirta Order: Coleoptera	the symbionts inhibit the growth of antagonistic fungi on the eggs of the insect host, indicating that the Lagria-associated Burkholderia have evolved from plant pathogenic ancestors into insect defensive mutualists	0.00%	9.3
Streptomyces globisporus Species-level Match	RISB0456	Messor structor Order: Hymenoptera	secretes albomycin to inhibit the growth of entomopathogens suggests that Streptomyces globisporus subsp. globisporus may be involved in defensive symbiosis with the Messor structor ant against infections	0.00%	9.1
Streptomyces sp. RTd22 Species-level Match	RISB0943	Polybia plebeja Order: Hymenoptera	this bacterium produces antimicrobial compounds that are active against Hirsutella citriformis, a natural fungal enemy of its host, and the human pathogens Staphylococcus aureus and Candida albicans	0.04%	9.0
Streptomyces sp. CB01881 Species-level Match	RISB0943	Polybia plebeja Order: Hymenoptera	this bacterium produces antimicrobial compounds that are active against Hirsutella citriformis, a natural fungal enemy of its host, and the human pathogens Staphylococcus aureus and Candida albicans	0.01%	9.0
Burkholderia gladioli Species-level Match	RISB1604	Lagria villosa Order: Coleoptera	Bacteria produce icosalide, an unusual two-tailed lipocyclopeptide antibiotic,which is active against entomopathogenic bacteria, thus adding to the chemical armory protecting beetle offspring	0.00%	8.8
Xanthomonas sp. AM6 Species-level Match	RISB0498	Xylocopa appendiculata Order: Hymenoptera	Xanthomonas strain from Japanese carpenter bee is effective PU-degradable bacterium and is able to use polyacryl-based PU as a nutritional source, as well as other types of PS-PU and PE-PU	0.01%	8.8
Xanthomonas sp. CFBP 8443 Species-level Match	RISB0498	Xylocopa appendiculata Order: Hymenoptera	Xanthomonas strain from Japanese carpenter bee is effective PU-degradable bacterium and is able to use polyacryl-based PU as a nutritional source, as well as other types of PS-PU and PE-PU	0.00%	8.8
Arthrobacter sp. NEB 688 Species-level Match	RISB0769	Delia antiqua Order: Diptera	showed significant volatile inhibition activity against fungal entomopathogen Fusarium moniliforme, Botryosphaeria dothidea and both Fusarium oxysporum respectively	0.01%	8.3
Arthrobacter sp. FW306-2-2C-D06B Species-level Match	RISB0769	Delia antiqua Order: Diptera	showed significant volatile inhibition activity against fungal entomopathogen Fusarium moniliforme, Botryosphaeria dothidea and both Fusarium oxysporum respectively	0.00%	8.3
Paenibacillus sp. FSL K6-2441 Species-level Match	RISB0774	Delia antiqua Order: Diptera	showed significant contact inhibition activity against fungal entomopathogen Fusarium moniliforme, Botryosphaeria dothidea and both Fusarium oxysporum respectively	0.00%	8.3
Leucobacter aridicollis Species-level Match	RISB0771	Delia antiqua Order: Diptera	showed significant contact inhibition activity against fungal entomopathogen Fusarium moniliforme, Botryosphaeria dothidea and both Fusarium oxysporum respectively	0.00%	8.3
Blattabacterium cuenoti Species-level Match	RISB0133	Panesthiinae Order: Blattodea	enables hosts to subsist on a nutrient-poor diet; endosymbiont genome erosions are associated with repeated host transitions to an underground life	0.00%	7.9
Citrobacter freundii Species-level Match	RISB0517	Leptinotarsa decemlineata Order: Coleoptera	affect the cellular and humoral immunity of the insect, increasing its susceptibility to Bacillus thuringiensis var. tenebrionis (morrisoni) (Bt)	0.00%	7.9
Caballeronia insecticola Species-level Match	RISB0276	Riptortus pedestris Order: Hemiptera	Gut symbiont resulted in increase in the body size and weight of male adults;increased dispersal capacity of male adults especially for flight	0.00%	7.8
Escherichia coli Species-level Match	RISB0128	Tribolium castaneum Order: Coleoptera	may produce 4,8-dimethyldecanal (DMD) production that is strongly associated with attraction to females and host pheromone communication	0.02%	7.7
Wolbachia pipientis Species-level Match	RISB1515	Drosophila melanogaster Order: Diptera	increases the recombination rate observed across two genomic intervals and increases the efficacy of natural selection in hosts	0.00%	7.5
Chromobacterium sp. ATCC 53434 Species-level Match	RISB1453	Aedes aegypti Order: Diptera	aminopeptidase secreted by a Chromobacterium species suppresses DENV infection by directly degrading the DENV envelope protein	0.00%	7.5
Comamonas terrigena Species-level Match	RISB2021	Bactrocera dorsalis Order: Diptera	This group in the immature stages may be helping the insects to cope with oxidative stress by supplementing available oxygen.	0.00%	7.5
Wolbachia pipientis Species-level Match	RISB1354	Drosophila melanogaster Order: Diptera	Wolbachia influence octopamine metabolism in the Drosophila females, which is by the symbiont genotype	0.00%	7.0
Xanthomonas sp. AM6 Species-level Match	RISB0217	Xylocopa appendiculata Order: Hymenoptera	strains biodegraded polyethylene terephthalate PET powder, broke it into its degradation products	0.01%	7.0
Micrococcus sp. 2A Species-level Match	RISB2277	Leptinotarsa decemlineata Order: Coleoptera	extreme cellulolytic enzymes, at extreme (pH 12) conditions, exhibited cellulolytic properties	0.00%	6.9
Corynebacterium variabile Species-level Match	RISB0363	Pagiophloeus tsushimanus Order: Coleoptera	terpenoid-degrading: the highest degradation rates of D-camphor, linalool, and eucalyptol	0.00%	6.8
Erwinia sp. E602 Species-level Match	RISB0808	Hypothenemus hampei Order: Coleoptera	might contribute to caffeine breakdown using the C-12 oxidation pathway	0.00%	6.4
Paenibacillus sp. FSL K6-2441 Species-level Match	RISB0813	Hypothenemus hampei Order: Coleoptera	might contribute to caffeine breakdown using the C-9 oxidation pathway	0.00%	6.4
Lactiplantibacillus plantarum Species-level Match	RISB0674	Drosophila melanogaster Order: Diptera	could effectively inhibit fungal spore germinations	0.00%	6.0
Methylobacterium sp. WL1 Species-level Match	RISB2053	Atractomorpha sinensis Order: Orthoptera	associated with cellulolytic enzymes	0.00%	5.7
Blattabacterium cuenoti Species-level Match	RISB0518	Cryptocercus punctulatus Order: Blattodea	collaborative arginine biosynthesis	0.00%	5.7
Chryseobacterium sp. C-71 Species-level Match	RISB2092	Aedes aegypti Order: Diptera	axenic larvae cannot develop	0.01%	5.6
Paenibacillus sp. FSL K6-2441 Species-level Match	RISB2098	Aedes aegypti Order: Diptera	axenic larvae cannot develop	0.00%	5.6
Blattabacterium cuenoti Species-level Match	RISB0093	Blattella germanica Order: Blattodea	obligate endosymbiont	0.00%	5.4
Rhodococcus ruber Species-level Match	RISB1157	Tenebrio molitor Order: Coleoptera	degrading plastics	0.01%	5.4
Comamonas testosteroni Species-level Match	RISB1875	Aedes aegypti Order: Diptera	gut microbiome	0.00%	5.3
Diaphorobacter aerolatus Species-level Match	RISB1062	Oryctes rhinoceros Order: Coleoptera	gut microbe	0.00%	5.2
Bosea sp. Tri-49 Species-level Match	RISB1702	Phlebotomus papatasi Order: Diptera	None	0.07%	5.1
Agrobacterium tumefaciens Species-level Match	RISB0650	Melanaphis bambusae Order: Hemiptera	None	0.03%	5.0
Bosea sp. ANAM02 Species-level Match	RISB1702	Phlebotomus papatasi Order: Diptera	None	0.01%	5.0
Brevundimonas sp. M20 Species-level Match	RISB1703	Phlebotomus papatasi Order: Diptera	None	0.01%	5.0
Delftia lacustris Species-level Match	RISB0657	Melanaphis bambusae Order: Hemiptera	None	0.00%	5.0
Caballeronia zhejiangensis Species-level Match	RISB0688	Anasa tristis Order: Hemiptera	None	0.00%	5.0
Lactiplantibacillus plantarum Species-level Match	RISB0608	Drosophila melanogaster Order: Diptera	None	0.00%	5.0
Brevundimonas sp. NIBR11 Species-level Match	RISB1703	Phlebotomus papatasi Order: Diptera	None	0.00%	5.0
Micromonospora harpali Species-level Match	RISB2034	Harpalus sinicus Order: Coleoptera	None	0.00%	5.0
Zymomonas mobilis Species-level Match	RISB1326	Vespa mandarinia Order: Hymenoptera	None	0.00%	5.0
Cupriavidus pauculus Species-level Match	RISB0694	Alydus tomentosus Order: Hemiptera	None	0.00%	5.0
Variovorax sp. HW608 Species-level Match	RISB1712	Phlebotomus papatasi Order: Diptera	None	0.00%	5.0
Thauera sp. JM12B12 Species-level Match	RISB1711	Phlebotomus papatasi Order: Diptera	None	0.00%	5.0
Salmonella enterica Species-level Match	RISB0413	Melanaphis sacchari Order: Hemiptera	None	0.00%	5.0
Ereboglobus luteus Species-level Match	RISB1523	Shelfordella lateralis Order: Blattodea	None	0.00%	5.0
Lactococcus	RISB0131	Ceratitis capitata Order: Diptera	The intestinal microbiota structure was significantly influenced by the probiotic treatment while still maintaining a stable core dominant community of Enterobacteriacea. The colony with these microbiome had the most improved potential functions in terms of gut microbes as well as the carbohydrates active enzymes most improved potential functions.	0.00%	5.0
Methylovirgula	RISB0137	Coccinella septempunctata Order: Coleoptera	Methylovirgula is ubiquitous in soil and has been found in many soil samples as a major species producing carbon activity, scholars have found that the microorganism has the highest content in mixed peat swamp forest systems and has the effect of harnessing and reducing methane	0.00%	5.0
Rhodobacter	RISB0138	Coccinella septempunctata Order: Coleoptera	Rhodanobacter genera can utilize various carbon sources, including cellobiose. In larvae of longhorned beetles that feed on plants rich in carbohydrates (cellulose and hemicellulose) and lignin, Rhodanobacter can help the larvae digest more carbon nutrients through carbon sequestration	0.00%	5.0
Acetobacter	RISB1865	Drosophila melanogaster Order: Diptera	The bacterial cells may thus be able to ameliorate the pH of the acidic region, by the release of weak bases.Additionally, the bacteria have a complex relationship with physiological processes which may affect ionic homeostasis in the gut, such as nutrition and immune function	0.00%	5.0
Clostridium	RISB2301	Pyrrhocoris apterus Order: Hemiptera	could play an important role for the insect by degrading complex dietary components, providing nutrient supplementation, or detoxifying noxious chemicals (e.g. cyclopropenoic fatty acids or gossypol) in the diet	0.03%	4.3
Lactococcus	RISB2305	Pyrrhocoris apterus Order: Hemiptera	could play an important role for the insect by degrading complex dietary components, providing nutrient supplementation, or detoxifying noxious chemicals (e.g. cyclopropenoic fatty acids or gossypol) in the diet	0.00%	4.2
Gordonibacter	RISB2303	Pyrrhocoris apterus Order: Hemiptera	could play an important role for the insect by degrading complex dietary components, providing nutrient supplementation, or detoxifying noxious chemicals (e.g. cyclopropenoic fatty acids or gossypol) in the diet	0.00%	4.2
Gordonibacter	RISB2126	Dysdercus fasciatus Order: Hemiptera	Elimination of symbionts by egg-surface sterilization resulted in significantly higher mortality and reduced growth rates, indicating that the microbial community plays an important role for host nutrition	0.00%	4.1
Sphingobium	RISB1837	Dendroctonus valens Order: Coleoptera	It can trongly degrade naringenin, and pinitol, the main soluble carbohydrate of P. tabuliformis, is retained in L. procerum-infected phloem and facilitate naringenin biodegradation by the microbiotas.	0.02%	4.0
Novosphingobium	RISB1837	Dendroctonus valens Order: Coleoptera	It can trongly degrade naringenin, and pinitol, the main soluble carbohydrate of P. tabuliformis, is retained in L. procerum-infected phloem and facilitate naringenin biodegradation by the microbiotas.	0.02%	4.0
Acetobacter	RISB0961	Drosophila melanogaster Order: Diptera	The exist of Acetobacter had a balancing effect on food ingestion when carbohydrate levels were high in the warmer months, stabilizing fitness components of flies across the year.	0.00%	3.6
Lactococcus	RISB0967	Oulema melanopus Order: Coleoptera	contribute to the decomposition of complex carbohydrates, fatty acids, or polysaccharides in the insect gut. It might also contribute to the improvement of nutrient availability.	0.00%	3.6
Amycolatopsis	RISB0483	Trachymyrmex smithi Order: Hymenoptera	inhibited the growth of Pseudonocardia symbionts under laboratory conditions. The novel analog nocamycin V from the strain was identified as the antibacterial compound	0.16%	3.5
Raoultella	RISB2226	Leptinotarsa decemlineata Order: Coleoptera	Colorado potato beetle (Leptinotarsa decemlineata) larvae exploit bacteria in their oral secretions to suppress antiherbivore defenses in tomato (Solanum lycopersicum)	0.02%	3.4
Methylobacter	RISB1440	Lutzomyia evansi Order: Diptera	Methylobacterium can be important in several physiological and metabolic processes in Lu. evansi, which suggests that interactions could occur with Leishmania parasite	0.00%	3.3
Sphingobacterium	RISB2227	Leptinotarsa decemlineata Order: Coleoptera	Colorado potato beetle (Leptinotarsa decemlineata) larvae exploit bacteria in their oral secretions to suppress antiherbivore defenses in tomato (Solanum lycopersicum)	0.00%	3.3
Amycolatopsis	RISB0199	Trachymyrmex Order: Hymenoptera	produce antibiotic EC0-0501 that has strong activity against ant-associated Actinobacteria and may also play a role in bacterial competition in this niche	0.16%	3.2
Candidatus Blochmanniella	RISB2542	Camponotus Order: Hymenoptera	Blochmannia provide essential amino acids to its host,Camponotus floridanus, and that it may also play a role in nitrogen recycling via its functional urease	0.00%	3.1
Tsukamurella	RISB1531	Hoplothrips carpathicus Order: Thysanoptera	This genus was identified as dominant in intensively feeding second-stage larvae and suggests a mechanism by which L2 larvae might process cellulose.	0.11%	3.1
Candidatus Blochmanniella	RISB1827	Camponotus floridanus Order: Hymenoptera	a modulation of immune gene expression which may facilitate tolerance towards the endosymbionts and thus may contribute to their transovarial transmission	0.00%	3.1
Nocardia	RISB0947	Acromyrmex Order: Hymenoptera	Pseudonocardia in the Acromyrmex leaf-cutter ants as a protective partner against the entomopathogenic fungus Metarhizium	0.60%	3.0
Candidatus Blochmanniella	RISB2448	Camponotus floridanus Order: Hymenoptera	nutritional contribution of the bacteria to host metabolism by production of essential amino acids and urease-mediated nitrogen recycling	0.00%	2.7
Sphingobacterium	RISB1226	Delia antiqua Order: Diptera	six bacteria protect larvae from infection with the entomopathogen Beauveria bassiana through symbiotic bacterium-derived organic acids	0.00%	2.7
Nocardia	RISB1218	Mycocepurus smithii Order: Hymenoptera	produce secondary metabolites with antibiotic activity that protects the fungus garden against pathogens	0.60%	2.7
Bartonella	RISB1673	Apis mellifera Order: Hymenoptera	a gut symbiont of insects and that the adaptation to blood-feeding insects facilitated colonization of the mammalian bloodstream	0.00%	2.6
Azospira	RISB1918	Anopheles gambiae Order: Diptera	may be related with mediating adaptation to different ecological niches or in shaping specific adult behaviors including mating	0.00%	2.5
Pseudonocardia	RISB0947	Acromyrmex Order: Hymenoptera	Pseudonocardia in the Acromyrmex leaf-cutter ants as a protective partner against the entomopathogenic fungus Metarhizium	0.06%	2.5
Yersinia	RISB0492	Cimex hemipterus Order: Hemiptera	the disruption of the abundant Yersinia possibly could be related to the enhanced susceptibility towards the insecticides	0.00%	2.4
Bacteroides	RISB0256	Leptocybe invasa Order: Hymenoptera	Differences in Male-Killing Rickettsia Bacteria between Lineages of the Invasive Gall-Causing Pest Leptocybe invasa	0.00%	2.3
Acetobacter	RISB0184	Drosophila melanogaster Order: Diptera	enhancing the brain levels of tyrosine decarboxylase 2 (Tdc2), which is an enzyme that synthesizes octopamine (OA)	0.00%	2.3
Pseudonocardia	RISB1218	Mycocepurus smithii Order: Hymenoptera	produce secondary metabolites with antibiotic activity that protects the fungus garden against pathogens	0.06%	2.1
Nitrosospira	RISB0869	Sirex noctilio Order: Hymenoptera	might be involved in degrading organic matter and fixing nitrogen occurred exclusively in the larval gut	0.00%	2.1
Bacteroides	RISB1183	Oryzaephilus surinamensis Order: Coleoptera	supplement precursors for the cuticle synthesis and thereby enhance desiccation resistance of its host	0.00%	2.0
Bradyrhizobium	RISB0135	Coccinella septempunctata Order: Coleoptera	be commonly found in plant roots and they all have nitrogen fixation abilities	0.16%	1.7
Rhizobium	RISB0135	Coccinella septempunctata Order: Coleoptera	be commonly found in plant roots and they all have nitrogen fixation abilities	0.12%	1.7
Streptococcus	RISB2624	Reticulitermes flavipes Order: Blattodea	can be broken down into substances such as carbon dioxide, ammonia and acetic acid	0.01%	1.7
Gluconobacter	RISB0016	Aedes aegypti Order: Diptera	Gluconobacter might increase the susceptibility of Ae. aegypti to CHIKV infection.	0.00%	1.6
Mycobacterium	RISB1156	Nicrophorus concolor Order: Coleoptera	produces Antimicrobial compounds	0.86%	1.5
Nostoc	RISB0812	Hypothenemus hampei Order: Coleoptera	might contribute to caffeine breakdown using the C-18 oxidation pathway	0.00%	1.4
Kosakonia	RISB0810	Hypothenemus hampei Order: Coleoptera	might contribute to caffeine breakdown using the C-16 oxidation pathway	0.00%	1.4
Sphingobacterium	RISB1400	Delia antiqua Order: Diptera	suppressed Beauveria bassiana conidia germination and hyphal growth	0.00%	1.3
Halomonas	RISB1808	Monochamus galloprovincialis Order: Coleoptera	Have the ability for degradation of cellulose, proteins and starch	0.02%	1.3
Vibrio	RISB1810	Monochamus galloprovincialis Order: Coleoptera	Have the ability for degradation of cellulose, proteins and starch	0.01%	1.3
Massilia	RISB2151	Osmia bicornis Order: Hymenoptera	may be essential to support Osmia larvae in their nutrient uptake	0.02%	1.3
Duganella	RISB2152	Osmia bicornis Order: Hymenoptera	may be essential to support Osmia larvae in their nutrient uptake	0.00%	1.3
Actinomyces	RISB1234	Hermetia illucens Order: Diptera	provides the tools for degrading of a broad range of substrates	0.02%	1.3
Gluconobacter	RISB1882	Drosophila suzukii Order: Diptera	produce volatile substances that attract female D. suzukii	0.00%	1.2
Komagataeibacter	RISB1883	Drosophila suzukii Order: Diptera	produce volatile substances that attract female D. suzukii	0.00%	1.2
Raoultella	RISB1007	Monochamus alternatus Order: Coleoptera	may help M. alternatus degrade cellulose and pinene	0.02%	1.0
Lysinibacillus	RISB1416	Psammotermes hypostoma Order: Blattodea	isolates showed significant cellulolytic activity	0.00%	1.0
Cronobacter	RISB0247	Tenebrio molitor Order: Coleoptera	may be indirectly involved in the digestion of PE	0.00%	1.0
Brevibacterium	RISB0464	Acrida cinerea Order: Orthoptera	correlated with the hemicellulose digestibility	0.02%	1.0
Clavibacter	RISB0465	Trilophidia annulata Order: Orthoptera	correlated with the hemicellulose digestibility	0.02%	1.0
Methylobacter	RISB2053	Atractomorpha sinensis Order: Orthoptera	associated with cellulolytic enzymes	0.00%	0.7
Cedecea	RISB1570	Bactrocera tau Order: Diptera	could attract male and female B. tau	0.00%	0.7
Aeromonas	RISB2086	Aedes aegypti Order: Diptera	axenic larvae cannot develop	0.01%	0.6
Kosakonia	RISB1155	Tenebrio molitor Order: Coleoptera	degrading plastics	0.00%	0.4
Achromobacter	RISB1869	Aedes aegypti Order: Diptera	gut microbiome	0.03%	0.3
Sphingobium	RISB1880	Aedes aegypti Order: Diptera	gut microbiome	0.02%	0.3
Peribacillus	RISB1877	Aedes aegypti Order: Diptera	gut microbiome	0.01%	0.3
Alcaligenes	RISB1871	Aedes aegypti Order: Diptera	gut microbiome	0.00%	0.3
Lysinibacillus	RISB1066	Oryctes rhinoceros Order: Coleoptera	gut microbe	0.00%	0.2
Curtobacterium	RISB0900	Myzus persicae Order: Hemiptera	None	0.05%	0.1
Clostridium	RISB1959	Pyrrhocoridae Order: Hemiptera	None	0.03%	0.0
Achromobacter	RISB0383	Aphis gossypii Order: Hemiptera	None	0.03%	0.0
Paraburkholderia	RISB0125	Physopelta gutta Order: Hemiptera	None	0.03%	0.0
Brevibacterium	RISB0897	Myzus persicae Order: Hemiptera	None	0.02%	0.0
Halomonas	RISB1374	Bemisia tabaci Order: Hemiptera	None	0.02%	0.0
Vagococcus	RISB0042	Aldrichina grahami Order: Diptera	None	0.01%	0.0
Methylorubrum	RISB0903	Myzus persicae Order: Hemiptera	None	0.01%	0.0
Legionella	RISB1687	Polyplax serrata Order: Phthiraptera	None	0.01%	0.0
Flavobacterium	RISB0659	Melanaphis bambusae Order: Hemiptera	None	0.01%	0.0
Gordonibacter	RISB1960	Pyrrhocoridae Order: Hemiptera	None	0.00%	0.0
Yersinia	RISB0407	Anaphes nitens Order: Hymenoptera	None	0.00%	0.0
Gluconobacter	RISB0876	Drosophila suzukii Order: Diptera	None	0.00%	0.0
Propionibacterium	RISB0490	Ceratitis capitata Order: Diptera	None	0.00%	0.0
Tistrella	RISB0270	Recilia dorsalis Order: Hemiptera	None	0.00%	0.0
Gibbsiella	RISB1320	Vespa mandarinia Order: Hymenoptera	None	0.00%	0.0
Myroides	RISB0626	Musca altica Order: Diptera	None	0.00%	0.0