SRR23622349 - Cetonia aurata

Basic Information

Run: SRR23622349

Assay Type: WGS

Bioproject: PRJNA938905

Biosample: SAMN33449284

Bytes: 3602770143

Center Name: MAX PLANCK INSTITUTE FOR BIOLOGY

Sequencing Information

Instrument: Illumina HiSeq 4000

Library Layout: PAIRED

Library Selection: RANDOM

Platform: ILLUMINA

Geographic Information

Country: Germany

Continent: Europe

Location Name: Germany: Baden-Wuerttemberg\, Tuebingen

Latitude/Longitude: 48.53 N 9.05 E

Sample Information

Host: Cetonia aurata

Isolation: decomposed grub time point 2

Biosample Model: Metagenome or environmental

Collection Date: 2021-10

Taxonomic Classification

Potential Symbionts

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
Serratia marcescens
RISB1295
Nicrophorus vespilloides
Order: Coleoptera
producing antibacterial compound Serrawettin W2, which has antibacterial and nematode-inhibiting effects
6.74%
23.8
Serratia marcescens
RISB0365
Pagiophloeus tsushimanus
Order: Coleoptera
terpenoid-degrading: the highest degradation rates of D-camphor, linalool, and eucalyptol
6.74%
23.5
Serratia marcescens
RISB1158
Nicrophorus vespilloides
Order: Coleoptera
produces an antibacterial cyclic lipopeptide called serrawettin W2
6.74%
23.1
Stenotrophomonas sp. 610A2
RISB0325
Pharaxonotha floridana
Order: Coleoptera
suggesting the occurrence of an unprecedented desferrioxamine-like biosynthetic pathway,including desferrioxamine B, which may help tolerating diets rich in azoxyglycosides, BMAA, and other cycad toxins, including a possible role for bacterial siderophores
1.47%
21.5
Stenotrophomonas sp. BIO128-Bstrain
RISB0325
Pharaxonotha floridana
Order: Coleoptera
suggesting the occurrence of an unprecedented desferrioxamine-like biosynthetic pathway,including desferrioxamine B, which may help tolerating diets rich in azoxyglycosides, BMAA, and other cycad toxins, including a possible role for bacterial siderophores
0.16%
20.2
Stenotrophomonas sp. 169
RISB0325
Pharaxonotha floridana
Order: Coleoptera
suggesting the occurrence of an unprecedented desferrioxamine-like biosynthetic pathway,including desferrioxamine B, which may help tolerating diets rich in azoxyglycosides, BMAA, and other cycad toxins, including a possible role for bacterial siderophores
0.14%
20.1
Burkholderia gladioli
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
0.01%
20.0
Pseudomonas sp. SD17-1
RISB1622
Dendroctonus valens
Order: Coleoptera
volatiles from predominant bacteria regulate the consumption sequence of carbon sources d-pinitol and d-glucose in the fungal symbiont Leptographium procerum, and appear to alleviate the antagonistic effect from the fungus against RTB larvae
0.08%
19.9
Pseudomonas sp. B21-036
RISB1622
Dendroctonus valens
Order: Coleoptera
volatiles from predominant bacteria regulate the consumption sequence of carbon sources d-pinitol and d-glucose in the fungal symbiont Leptographium procerum, and appear to alleviate the antagonistic effect from the fungus against RTB larvae
0.06%
19.9
Pseudomonas sp. AE27
RISB1622
Dendroctonus valens
Order: Coleoptera
volatiles from predominant bacteria regulate the consumption sequence of carbon sources d-pinitol and d-glucose in the fungal symbiont Leptographium procerum, and appear to alleviate the antagonistic effect from the fungus against RTB larvae
0.05%
19.9
Sphingobacterium sp. WM
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)
1.41%
19.8
Acinetobacter sp. NyZ410
RISB0730
Curculio chinensis
Order: Coleoptera
Acinetobacter sp. in C. chinensis enriched after treating with saponin, and when incubating bacteria with saponin for 72 h, saponin content significantly decreased from 4.054 to 1.867 mg/mL (by 16S rRNA metagenome sequencing and HPLC)
0.02%
19.7
Acinetobacter sp. MYb10
RISB0730
Curculio chinensis
Order: Coleoptera
Acinetobacter sp. in C. chinensis enriched after treating with saponin, and when incubating bacteria with saponin for 72 h, saponin content significantly decreased from 4.054 to 1.867 mg/mL (by 16S rRNA metagenome sequencing and HPLC)
0.01%
19.7
Acinetobacter sp. A1-4-2
RISB0730
Curculio chinensis
Order: Coleoptera
Acinetobacter sp. in C. chinensis enriched after treating with saponin, and when incubating bacteria with saponin for 72 h, saponin content significantly decreased from 4.054 to 1.867 mg/mL (by 16S rRNA metagenome sequencing and HPLC)
0.00%
19.7
Burkholderia gladioli
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
0.01%
19.3
Burkholderia gladioli
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
0.01%
18.8
Sphingobacterium sp. LZ7M1
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)
0.25%
18.6
Sphingobacterium sp. DR205
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)
0.24%
18.6
Enterobacter sp. T2
RISB2221
Leptinotarsa decemlineata
Order: Coleoptera
Colorado potato beetle (Leptinotarsa decemlineata) larvae exploit bacteria in their oral secretions to suppress antiherbivore defenses in tomato (Solanum lycopersicum)
0.01%
18.4
Raoultella sp. HC6
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)
0.00%
18.3
Citrobacter koseri
RISB1060
Oryctes rhinoceros
Order: Coleoptera
associated with insect digestive tracts
2.55%
18.3
Klebsiella oxytoca
RISB1506
Cleonus trivittatus
Order: Coleoptera
Antibiotic-treated larvae suffered growth retardation on a diet containing plant extract or swainsonine. Gut bacteria showed toxin-degradation activities in vitro
0.02%
18.3
Citrobacter freundii complex sp. CFNIH2
RISB0517
Leptinotarsa decemlineata
Order: Coleoptera
affect the cellular and humoral immunity of the insect, increasing its susceptibility to Bacillus thuringiensis var. tenebrionis (morrisoni) (Bt)
0.11%
18.0
Citrobacter freundii
RISB0517
Leptinotarsa decemlineata
Order: Coleoptera
affect the cellular and humoral immunity of the insect, increasing its susceptibility to Bacillus thuringiensis var. tenebrionis (morrisoni) (Bt)
0.04%
17.9
Morganella morganii
RISB1867
Costelytra zealandica
Order: Coleoptera
Female beetles were previously shown to use phenol as their sex pheromone produced by symbiotic bacteria in the accessory or colleterial gland
0.00%
17.8
Escherichia coli
RISB0128
Tribolium castaneum
Order: Coleoptera
may produce 4,8-dimethyldecanal (DMD) production that is strongly associated with attraction to females and host pheromone communication
0.09%
17.8
Bacillus sp. FJAT-52991
RISB1645
Osphranteria coerulescens
Order: Coleoptera
The isolate has cellulolytic activity and can hydrolyze CMC, avicel, cellulose and sawdust with broad temperature and pH stability
0.00%
17.6
Enterobacter sp. T2
RISB0496
Sitophilus oryzae
Order: Coleoptera
bacteria can degrade malathion, pirimiphos-methyl, and deltamethrin and utilize these insecticides as the carbon source in vitro.
0.01%
17.6
Enterococcus faecalis
RISB0497
Cryptolestes ferrugineus
Order: Coleoptera
bacteria can degrade malathion, pirimiphos-methyl, and deltamethrin and utilize these insecticides as the carbon source in vitro.
0.01%
17.6
Enterococcus faecalis
RISB2042
Harpalus pensylvanicus
Order: Coleoptera
E. faecalis facilitate seed consumption by H. pensylvanicus, possibly by contributing digestive enzymes to their host
0.01%
17.4
Enterobacter cloacae
RISB1428
Rhynchophorus ferrugineus
Order: Coleoptera
promote the development and body mass gain of RPW larvae by improving their nutrition metabolism
0.01%
16.9
Paludibacter propionicigenes
RISB2055
Odontotaenius disjunctus
Order: Coleoptera
microbial fixation of nitrogen that is important for this beetle to subsist on woody biomass
0.00%
16.8
Morganella morganii
RISB1548
Costelytra zealandica
Order: Coleoptera
symbionts residing in the colleterial glands produce phenol 1 as the female sex pheromone
0.00%
16.8
Morganella morganii
RISB1868
Costelytra zealandica
Order: Coleoptera
produces phenol as the sex pheromone of the host from tyrosine in the colleterial gland
0.00%
16.7
Streptomyces sp. T12
RISB0777
Copris tripartitus
Order: Coleoptera
contribute brood ball hygiene by inhibiting fungal parasites in the environment
0.13%
16.7
Streptomyces sp. WAC00303
RISB0777
Copris tripartitus
Order: Coleoptera
contribute brood ball hygiene by inhibiting fungal parasites in the environment
0.11%
16.7
Streptomyces sp. NBC_01324
RISB0777
Copris tripartitus
Order: Coleoptera
contribute brood ball hygiene by inhibiting fungal parasites in the environment
0.02%
16.6
Enterococcus faecalis
RISB0374
Tribolium castaneum
Order: Coleoptera
modulates host phosphine resistance by interfering with the redox system
0.01%
16.5
Paenibacillus sp. PAMC21692
RISB0813
Hypothenemus hampei
Order: Coleoptera
might contribute to caffeine breakdown using the C-9 oxidation pathway
0.04%
16.4
Klebsiella sp. FDAARGOS_511
RISB0809
Hypothenemus hampei
Order: Coleoptera
might contribute to caffeine breakdown using the C-17 oxidation pathway
0.01%
16.4
Delftia sp. DS1230
RISB0806
Hypothenemus hampei
Order: Coleoptera
might contribute to caffeine breakdown using the C-19 oxidation pathway
0.01%
16.4
Klebsiella sp. PL-2018
RISB0809
Hypothenemus hampei
Order: Coleoptera
might contribute to caffeine breakdown using the C-17 oxidation pathway
0.00%
16.4
Delftia sp. Cs1-4
RISB0806
Hypothenemus hampei
Order: Coleoptera
might contribute to caffeine breakdown using the C-19 oxidation pathway
0.00%
16.4
Erwinia sp. E602
RISB0808
Hypothenemus hampei
Order: Coleoptera
might contribute to caffeine breakdown using the C-12 oxidation pathway
0.00%
16.4
Paenibacillus sp. FSL R5-0912
RISB0813
Hypothenemus hampei
Order: Coleoptera
might contribute to caffeine breakdown using the C-9 oxidation pathway
0.01%
16.4
Bacillus sp. FJAT-52991
RISB0805
Hypothenemus hampei
Order: Coleoptera
might contribute to caffeine breakdown using the C-8 oxidation pathway
0.00%
16.4
Paenibacillus sp. FSL H8-0548
RISB0813
Hypothenemus hampei
Order: Coleoptera
might contribute to caffeine breakdown using the C-9 oxidation pathway
0.00%
16.4
Bacillus cereus
RISB1056
Oryctes rhinoceros
Order: Coleoptera
provide symbiotic digestive functions to Oryctes
0.26%
16.2
Paludibacter propionicigenes
RISB2056
Odontotaenius disjunctus
Order: Coleoptera
plays an important role in nitrogen fixation
0.00%
15.9
Diaphorobacter aerolatus
RISB1062
Oryctes rhinoceros
Order: Coleoptera
gut microbe
0.11%
15.3
Lysinibacillus fusiformis
RISB1066
Oryctes rhinoceros
Order: Coleoptera
gut microbe
0.02%
15.2
Staphylococcus epidermidis
RISB1070
Oryctes rhinoceros
Order: Coleoptera
gut microbe
0.00%
15.2
Pantoea agglomerans
RISB1858
Lissorhoptrus oryzophilus
Order: Coleoptera
None
0.01%
15.0
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
0.01%
15.0
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
0.01%
15.0
Rahnella
RISB1623
Dendroctonus valens
Order: Coleoptera
volatiles from predominant bacteria regulate the consumption sequence of carbon sources d-pinitol and d-glucose in the fungal symbiont Leptographium procerum, and appear to alleviate the antagonistic effect from the fungus against RTB larvae
0.00%
14.8
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.
0.17%
14.2
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.
0.07%
14.1
Spiroplasma
RISB0343
Harmonia axyridis
Order: Coleoptera
female ladybirds co-infected with Hesperomyces harmoniae and Spiroplasma had a significantly lower fecundity and hatchability compared to females with only one or no symbiont
0.00%
13.5
Sodalis
RISB2035
Sitophilus oryzae
Order: Coleoptera
endosymbiont dynamics parallels numerous transcriptional changes in weevil developing adults and affects several biological processes, including metabolism and development
0.00%
13.4
Sodalis
RISB2607
Sitophilus oryzae
Order: Coleoptera
induces the specific differentiation of the bacteriocytes, increases mitochondrial oxidative phosphorylation through the supply of pantothenic acid and riboflavin
0.00%
13.2
Sodalis
RISB1718
Sitophilus zeamais
Order: Coleoptera
we investigated the role of a quorum sensing(QS ) system in S. praecaptivus and found that it negatively regulates a potent insect-killing phenotype
0.00%
13.0
Proteus
RISB0001
Leptinotarsa decemlineata
Order: Coleoptera
produces toxic hydrogen cyanide (HCN) and a mandelonitrile-producing cyanoglucoside, amygdalin, which protect the insect from predation
0.00%
12.7
Spiroplasma
RISB1483
Brachinus elongatulus
Order: Coleoptera
may manipulate host reproduction (e.g., cause male-killing) or provide resistance to nematodes and/or parasitoid wasps
0.00%
12.4
Bacteroides
RISB1183
Oryzaephilus surinamensis
Order: Coleoptera
supplement precursors for the cuticle synthesis and thereby enhance desiccation resistance of its host
0.17%
12.2
Rahnella
RISB1800
Dendroctonus valens
Order: Coleoptera
could alleviate or compromise the antagonistic effects of fungi O. minus and L. procerum on RTB larval growth
0.00%
12.2
Rahnella
RISB0741
Dendroctonus ponderosae
Order: Coleoptera
R. aquatilis decreased (−)-α-pinene (38%) and (+)-α-pinene (46%) by 40% and 45% (by GC-MS), respectively
0.00%
12.1
Bradyrhizobium
RISB0135
Coccinella septempunctata
Order: Coleoptera
be commonly found in plant roots and they all have nitrogen fixation abilities
0.46%
12.0
Rhizobium
RISB0135
Coccinella septempunctata
Order: Coleoptera
be commonly found in plant roots and they all have nitrogen fixation abilities
0.40%
12.0
Micrococcus
RISB2277
Leptinotarsa decemlineata
Order: Coleoptera
extreme cellulolytic enzymes, at extreme (pH 12) conditions, exhibited cellulolytic properties
0.01%
11.9
Corynebacterium
RISB0363
Pagiophloeus tsushimanus
Order: Coleoptera
terpenoid-degrading: the highest degradation rates of D-camphor, linalool, and eucalyptol
0.03%
11.8
Halomonas
RISB1808
Monochamus galloprovincialis
Order: Coleoptera
Have the ability for degradation of cellulose, proteins and starch
0.12%
11.4
Kosakonia
RISB0810
Hypothenemus hampei
Order: Coleoptera
might contribute to caffeine breakdown using the C-16 oxidation pathway
0.00%
11.4
Vibrio
RISB1810
Monochamus galloprovincialis
Order: Coleoptera
Have the ability for degradation of cellulose, proteins and starch
0.03%
11.4
Cronobacter
RISB0247
Tenebrio molitor
Order: Coleoptera
may be indirectly involved in the digestion of PE
0.00%
11.0
Mycobacterium
RISB1156
Nicrophorus concolor
Order: Coleoptera
produces Antimicrobial compounds
0.04%
10.7
Spiroplasma
RISB0250
Tenebrio molitor
Order: Coleoptera
associated with PE biodegradation
0.00%
10.7
Rhodococcus
RISB1157
Tenebrio molitor
Order: Coleoptera
degrading plastics
0.11%
10.5
Aeromonas
RISB1145
Tenebrio molitor
Order: Coleoptera
degrading plastics
0.04%
10.4
Kosakonia
RISB1155
Tenebrio molitor
Order: Coleoptera
degrading plastics
0.00%
10.4
Micromonospora
RISB2034
Harpalus sinicus
Order: Coleoptera
None
0.05%
10.1
Dysgonomonas
RISB1481
Brachinus elongatulus
Order: Coleoptera
None
0.02%
10.0
Pantoea agglomerans
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.
0.01%
10.0
Buchnera aphidicola
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
0.01%
10.0
Microbacterium oleivorans
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%
10.0
Microbacterium arborescens
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%
10.0
Francisella tularensis
RISB1907
Bombyx mori
Order: Lepidoptera
After infection with F. tularensis, the induction of melanization and nodulation, which are immune responses to bacterial infection, were inhibited in silkworms. Pre-inoculation of silkworms with F. tularensis enhanced the expression of antimicrobial peptides and resistance to infection by pathogenic bacteria.
0.00%
10.0
Cellulosimicrobium sp. ES-005
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
Listeria monocytogenes
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
Deinococcus sp. AJ005
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
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
0.01%
9.8
Escherichia coli
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
0.09%
9.4
Clostridium sp. MB40-C1
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
0.00%
9.2
Pantoea ananatis
RISB1671
Spodoptera frugiperda
Order: Lepidoptera
modulate plant defense, downregulated the activity of the plant defensive proteins polyphenol oxidase and trypsin proteinase inhibitors (trypsin PI) but upregulated peroxidase (POX) activity in tomatoresponses
0.00%
9.2
Mammaliicoccus sciuri
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%
9.0
Staphylococcus xylosus
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
0.00%
9.0
Weissella cibaria
RISB1982
Blattella germanica
Order: Blattodea
gut microbiota contributes to production of VCAs that act as fecal aggregation agents and that cockroaches discriminate among the complex odors that emanate from a diverse microbial community
0.00%
8.8
Buchnera aphidicola
RISB0685
Acyrthosiphon pisum
Order: Hemiptera
It supplies the host with vitamins and essential amino acids, such as arginine and methionine that aphids cannot synthesize or derive insufficiently from their diet, the phloem sap of plants
0.01%
8.8
Xanthomonas sp. CFBP 8443
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
0.03%
8.8
Xanthomonas sp. 10-10
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
0.02%
8.8
Xanthomonas sp. CFBP 8445
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
Arthrobacter sp. KBS0702
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
Leucobacter aridicollis
RISB0771
Delia antiqua
Order: Diptera
showed significant contact inhibition activity against fungal entomopathogen Fusarium moniliforme, Botryosphaeria dothidea and both Fusarium oxysporum respectively
0.01%
8.3
Blattabacterium cuenoti
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
0.02%
8.0
Caballeronia insecticola
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
Weissella cibaria
RISB0641
Formica
Order: Hymenoptera
exhibited abilities in catabolizing sugars (sucrose, trehalose, melezitose and raffinose) known to be constituents of hemipteran honeydew
0.00%
7.7
Comamonas terrigena
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.
0.02%
7.5
Chromobacterium sp. IIBBL 290-4
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
Carnobacterium maltaromaticum
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%
7.5
Snodgrassella alvi
RISB1423
Bombus spp.
Order: Hymenoptera
The bumble bee microbiome slightly increases survivorship when the host is exposed to selenate
0.00%
6.9
Leclercia adecarboxylata
RISB1757
Spodoptera frugiperda
Order: Lepidoptera
degradation of lambda-cyhalothrin, deltamethrin, chlorpyrifos ethyl, lufenuron and spinosyn
0.01%
6.8
Microbacterium arborescens
RISB1759
Spodoptera frugiperda
Order: Lepidoptera
degradation of lambda-cyhalothrin, deltamethrin, chlorpyrifos ethyl, lufenuron and spinosyn
0.00%
6.8
Staphylococcus xylosus
RISB2247
Anticarsia gemmatalis
Order: Lepidoptera
mitigation of the negative effects of proteinase inhibitors produced by the host plant
0.00%
6.7
Sphingomonas sp. MM-1
RISB0134
Spodoptera frugiperda
Order: Lepidoptera
provide a protective effect to against chlorantraniliprole stress to S. frugiperda
0.01%
6.7
Blattabacterium sp. (Mastotermes darwiniensis)
RISB1534
Periplaneta fuliginosa
Order: Blattodea
involved in uric acid degradation, nitrogen assimilation and nutrient provisioning
0.00%
6.6
Sphingomonas sp. C3-2
RISB0134
Spodoptera frugiperda
Order: Lepidoptera
provide a protective effect to against chlorantraniliprole stress to S. frugiperda
0.00%
6.6
Carnobacterium maltaromaticum
RISB1692
Plutella xylostella
Order: Lepidoptera
participate in the synthesis of host lacking amino acids histidine and threonine
0.00%
6.6
Frischella perrara
RISB2028
Diceroprocta semicincta
Order: Hemiptera
causes the formation of a scab-like structure on the gut epithelium of its host
0.00%
6.6
Delftia lacustris
RISB1754
Spodoptera frugiperda
Order: Lepidoptera
may influence the metabolization of pesticides in insects
0.10%
6.2
Leclercia adecarboxylata
RISB1758
Spodoptera frugiperda
Order: Lepidoptera
may influence the metabolization of pesticides in insects
0.01%
6.2
Lactiplantibacillus plantarum
RISB0674
Drosophila melanogaster
Order: Diptera
could effectively inhibit fungal spore germinations
0.00%
6.0
Lysinibacillus fusiformis
RISB1417
Psammotermes hypostoma
Order: Blattodea
isolates showed significant cellulolytic activity
0.02%
6.0
Escherichia coli
RISB2120
Galleria mellonella
Order: Lepidoptera
mediate trans-generational immune priming
0.09%
5.9
Providencia rettgeri
RISB1001
Anastrepha obliqua
Order: Diptera
improve the sexual competitiveness of males
0.00%
5.9
Carnobacterium maltaromaticum
RISB1691
Plutella xylostella
Order: Lepidoptera
activity of cellulose and hemicellulose
0.00%
5.8
Methylobacterium sp. NMS14P
RISB2053
Atractomorpha sinensis
Order: Orthoptera
associated with cellulolytic enzymes
0.01%
5.7
Raoultella sp. HC6
RISB1575
Bactrocera tau
Order: Diptera
could attract male and female B. tau
0.00%
5.7
Blattabacterium cuenoti
RISB0518
Cryptocercus punctulatus
Order: Blattodea
collaborative arginine biosynthesis
0.02%
5.7
Methylobacterium sp. FF17
RISB2053
Atractomorpha sinensis
Order: Orthoptera
associated with cellulolytic enzymes
0.00%
5.7
Erwinia sp. E602
RISB1986
Bombyx mori
Order: Lepidoptera
producing cellulase and amylase
0.00%
5.6
Chryseobacterium sp. POL2
RISB2092
Aedes aegypti
Order: Diptera
axenic larvae cannot develop
0.03%
5.6
Chryseobacterium sp. Y16C
RISB2092
Aedes aegypti
Order: Diptera
axenic larvae cannot develop
0.02%
5.6
Chryseobacterium sp. 6424
RISB2092
Aedes aegypti
Order: Diptera
axenic larvae cannot develop
0.01%
5.6
Providencia rettgeri
RISB1169
Bactrocera dorsalis
Order: Diptera
Promote the growth of larvae
0.00%
5.6
Aquitalea sp. USM4
RISB2089
Aedes aegypti
Order: Diptera
axenic larvae cannot develop
0.00%
5.6
Achromobacter
RISB1869
Aedes aegypti
Order: Diptera
gut microbiome
5.16%
5.4
Comamonas testosteroni
RISB1875
Aedes aegypti
Order: Diptera
gut microbiome
0.08%
5.4
Bosea sp. ANAM02
RISB1702
Phlebotomus papatasi
Order: Diptera
None
0.29%
5.3
Achromobacter
RISB0383
Aphis gossypii
Order: Hemiptera
None
5.16%
5.2
Agrobacterium tumefaciens
RISB0650
Melanaphis bambusae
Order: Hemiptera
None
0.16%
5.2
Salmonella enterica
RISB0413
Melanaphis sacchari
Order: Hemiptera
None
0.15%
5.2
Bosea sp. F3-2
RISB1702
Phlebotomus papatasi
Order: Diptera
None
0.14%
5.1
Bosea sp. AS-1
RISB1702
Phlebotomus papatasi
Order: Diptera
None
0.13%
5.1
Brevundimonas sp. NCCP 15609
RISB1703
Phlebotomus papatasi
Order: Diptera
None
0.13%
5.1
Flavobacterium johnsoniae
RISB0659
Melanaphis bambusae
Order: Hemiptera
None
0.04%
5.0
Brevundimonas sp. M20
RISB1703
Phlebotomus papatasi
Order: Diptera
None
0.03%
5.0
Brevundimonas sp. MF30-B
RISB1703
Phlebotomus papatasi
Order: Diptera
None
0.02%
5.0
Variovorax sp. HW608
RISB1712
Phlebotomus papatasi
Order: Diptera
None
0.02%
5.0
Variovorax sp. PBS-H4
RISB1712
Phlebotomus papatasi
Order: Diptera
None
0.01%
5.0
Cupriavidus pauculus
RISB0694
Alydus tomentosus
Order: Hemiptera
None
0.01%
5.0
Thauera sp. K11
RISB1711
Phlebotomus papatasi
Order: Diptera
None
0.01%
5.0
Lactobacillus
RISB1866
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
0.01%
5.0
Caballeronia zhejiangensis
RISB0688
Anasa tristis
Order: Hemiptera
None
0.00%
5.0
Snodgrassella alvi
RISB1947
Apis cerana
Order: Hymenoptera
None
0.00%
5.0
Lactiplantibacillus plantarum
RISB0608
Drosophila melanogaster
Order: Diptera
None
0.00%
5.0
Providencia rettgeri
RISB1352
Nasonia vitripennis
Order: Hymenoptera
None
0.00%
5.0
Thauera sp. GDN1
RISB1711
Phlebotomus papatasi
Order: Diptera
None
0.00%
5.0
Zymomonas mobilis
RISB1326
Vespa mandarinia
Order: Hymenoptera
None
0.00%
5.0
Candidatus Karelsulcia muelleri
RISB1591
Philaenus spumarius
Order: Hemiptera
None
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
Gilliamella
RISB0102
Apis mellifera
Order: Hymenoptera
Gilliamella apicola carries the gene for the desaturase FADS2, which is able to metabolize polyunsaturated fatty acids from pollen and synthesize endocannabinoid, a lipogenic neuroactive substance, thereby modulating reward learning and memory in honeybees.
0.00%
5.0
Bifidobacterium
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%
5.0
Treponema
RISB2377
termite
Order: Blattodea
when grown together, two termite-gut Treponema species influence each other's gene expression in a far more comprehensive and nuanced manner than might have been predicted based on the results of previous studies on the respective pure cultures
0.00%
4.9
Apibacter
RISB0603
Apis cerana
Order: Hymenoptera
The acquisition of genes for the degradation of the toxic monosaccharides potentiates Apibacter with the ability to utilize the pollen hydrolysis products, at the same time enabling monosaccharide detoxification for the host
0.02%
4.5
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
Ochrobactrum
RISB0773
Delia antiqua
Order: Diptera
showed significant volatile inhibition activity against fungal entomopathogen Fusarium moniliforme, Botryosphaeria dothidea and both Fusarium oxysporum respectively
0.21%
3.5
Bifidobacterium
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%
3.4
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
0.07%
3.4
Rhodococcus
RISB0775
Delia antiqua
Order: Diptera
showed significant contact inhibition activity against fungal entomopathogen Fusarium moniliforme, Botryosphaeria dothidea and both Fusarium oxysporum respectively
0.11%
3.4
Lactobacillus
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.
0.01%
3.4
Pectobacterium
RISB1889
Pseudococcus longispinus
Order: Hemiptera
a nested symbiotic arrangement, where one bacterium lives inside another bacterium,occurred in building the mosaic metabolic pathways seen in mitochondria and plastids
0.01%
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
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
0.07%
3.2
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.
0.05%
3.0
Lactobacillus
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
0.01%
2.9
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
0.01%
2.6
Shewanella
RISB1924
Anopheles gambiae
Order: Diptera
may be related with mediating adaptation to different ecological niches or in shaping specific adult behaviors including mating
0.02%
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
Nocardia
RISB0947
Acromyrmex
Order: Hymenoptera
Pseudonocardia in the Acromyrmex leaf-cutter ants as a protective partner against the entomopathogenic fungus Metarhizium
0.06%
2.5
Bacteroides
RISB0256
Leptocybe invasa
Order: Hymenoptera
Differences in Male-Killing Rickettsia Bacteria between Lineages of the Invasive Gall-Causing Pest Leptocybe invasa
0.17%
2.5
Pseudonocardia
RISB0947
Acromyrmex
Order: Hymenoptera
Pseudonocardia in the Acromyrmex leaf-cutter ants as a protective partner against the entomopathogenic fungus Metarhizium
0.02%
2.4
Yersinia
RISB0492
Cimex hemipterus
Order: Hemiptera
the disruption of the abundant Yersinia possibly could be related to the enhanced susceptibility towards the insecticides
0.01%
2.4
Bacteroides
RISB0090
Hyphantria cunea
Order: Lepidoptera
enhance the compatibility of invasive pests to new hosts and enable more rapid adaptation to new habitats.
0.17%
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
Ochrobactrum
RISB1707
Phlebotomus papatasi
Order: Diptera
Ochrobactrum sp. is one of the transstadial bacteria, which is also known to be pathogenic to humans
0.21%
2.2
Nocardia
RISB1218
Mycocepurus smithii
Order: Hymenoptera
produce secondary metabolites with antibiotic activity that protects the fungus garden against pathogens
0.06%
2.1
Blautia
RISB0091
Hyphantria cunea
Order: Lepidoptera
enhance the compatibility of invasive pests to new hosts and enable more rapid adaptation to new habitats.
0.01%
2.1
Proteus
RISB2315
Aedes aegypti
Order: Diptera
upregulates AMP gene expression, resulting in suppression of DENV infection in the mosquito gut epithelium
0.00%
2.1
Pseudonocardia
RISB1218
Mycocepurus smithii
Order: Hymenoptera
produce secondary metabolites with antibiotic activity that protects the fungus garden against pathogens
0.02%
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
Apilactobacillus
RISB0475
Apis mellifera
Order: Hymenoptera
A. kunkeei alleviated acetamiprid-induced symbiotic microbiota dysregulation and mortality in honeybees
0.00%
2.1
Rhodococcus
RISB0430
Rhodnius prolixus
Order: Hemiptera
Rhodnius prolixus harbouring R. rhodnii developed faster, had higher survival, and laid more eggs
0.11%
2.1
Streptococcus
RISB2625
Galleria mellonella
Order: Lepidoptera
suppress bacteria ingested with food by producing bacteriocin and by releasing a lysozyme like enzyme
0.02%
2.0
Micrococcus
RISB2276
Ostrinia nubilalis
Order: Lepidoptera
extreme cellulolytic enzymes, at extreme (pH 12) conditions, exhibited cellulolytic properties
0.01%
1.9
Corynebacterium
RISB0531
Helicoverpa armigera
Order: Lepidoptera
Corynebacterium sp. 2-TD, mediates the toxicity of the 2-tridecanone to H. armigera
0.03%
1.7
Streptococcus
RISB2624
Reticulitermes flavipes
Order: Blattodea
can be broken down into substances such as carbon dioxide, ammonia and acetic acid
0.02%
1.7
Gluconobacter
RISB0016
Aedes aegypti
Order: Diptera
Gluconobacter might increase the susceptibility of Ae. aegypti to CHIKV infection.
0.00%
1.6
Glutamicibacter
RISB0606
Phthorimaea operculella
Order: Lepidoptera
could degrade the major toxic α-solanine and α-chaconine in potatoes
0.01%
1.4
Massilia
RISB2151
Osmia bicornis
Order: Hymenoptera
may be essential to support Osmia larvae in their nutrient uptake
0.06%
1.4
Duganella
RISB2152
Osmia bicornis
Order: Hymenoptera
may be essential to support Osmia larvae in their nutrient uptake
0.01%
1.3
Dysgonomonas
RISB1235
Hermetia illucens
Order: Diptera
provides the tools for degrading of a broad range of substrates
0.02%
1.3
Actinomyces
RISB1234
Hermetia illucens
Order: Diptera
provides the tools for degrading of a broad range of substrates
0.02%
1.3
Streptococcus
RISB2604
Homona magnanima
Order: Lepidoptera
influence the growth of Bacillus thuringiensis in the larvae
0.02%
1.2
Komagataeibacter
RISB1883
Drosophila suzukii
Order: Diptera
produce volatile substances that attract female D. suzukii
0.01%
1.2
Gluconobacter
RISB1882
Drosophila suzukii
Order: Diptera
produce volatile substances that attract female D. suzukii
0.00%
1.2
Ochrobactrum
RISB2002
Trichogramma chilonis
Order: Hymenoptera
could significantly increase both female count
0.21%
1.1
Paraclostridium
RISB0028
Sesamia inferens
Order: Lepidoptera
degrade Chlorpyrifos and Chlorantraniliprole in vitro
0.00%
1.1
Pectobacterium
RISB0798
Pseudoregma bambucicola
Order: Hemiptera
may help P. bambucicola feed on the stalks of bamboo
0.01%
1.1
Dickeya
RISB1086
Rhodnius prolixus
Order: Hemiptera
supply enzymatic biosynthesis of B-complex vitamins
0.01%
1.0
Proteus
RISB2460
Bombyx mori
Order: Lepidoptera
degradation of cellulose, xylan, pectin and starch
0.00%
1.0
Clavibacter
RISB0465
Trilophidia annulata
Order: Orthoptera
correlated with the hemicellulose digestibility
0.01%
1.0
Brevibacterium
RISB0464
Acrida cinerea
Order: Orthoptera
correlated with the hemicellulose digestibility
0.01%
1.0
Aeromonas
RISB2456
Bombyx mori
Order: Lepidoptera
able to utilize the CMcellulose and xylan
0.04%
0.9
Nocardioides
RISB1914
Hyles euphorbiae
Order: Lepidoptera
able to degrade alkaloids and/or latex
0.09%
0.9
Alcaligenes
RISB1871
Aedes aegypti
Order: Diptera
gut microbiome
0.54%
0.8
Gordonia
RISB1912
Hyles euphorbiae
Order: Lepidoptera
able to degrade alkaloids and/or latex
0.05%
0.8
Corynebacterium
RISB2360
Bombyx mori
Order: Lepidoptera
producing lipase in a gut environment
0.03%
0.8
Curtobacterium
RISB1910
Hyles euphorbiae
Order: Lepidoptera
able to degrade alkaloids and/or latex
0.02%
0.8
Brevibacterium
RISB2359
Bombyx mori
Order: Lepidoptera
producing lipase in a gut environment
0.01%
0.8
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
0.04%
0.6
Sphingobium
RISB1880
Aedes aegypti
Order: Diptera
gut microbiome
0.17%
0.5
Priestia
RISB0839
Helicoverpa armigera
Order: Lepidoptera
producing amylase
0.01%
0.4
Gilliamella
RISB0620
Spodoptera frugiperda
Order: Lepidoptera
degrade amygdalin
0.00%
0.3
Methylobacter
RISB2340
Saturniidae
Order: Lepidoptera
Nitrogen fixation
0.00%
0.3
Peribacillus
RISB1877
Aedes aegypti
Order: Diptera
gut microbiome
0.01%
0.3
Kaistia
RISB0829
Spodoptera frugiperda
Order: Lepidoptera
None
0.19%
0.2
Halomonas
RISB1374
Bemisia tabaci
Order: Hemiptera
None
0.12%
0.1
Paraburkholderia
RISB0125
Physopelta gutta
Order: Hemiptera
None
0.12%
0.1
Myroides
RISB0626
Musca altica
Order: Diptera
None
0.10%
0.1
Micromonospora
RISB2033
Palomena viridissima
Order: Hemiptera
None
0.05%
0.1
Ralstonia
RISB0243
Spodoptera frugiperda
Order: Lepidoptera
None
0.04%
0.0
Weeksella
RISB1265
Rheumatobates bergrothi
Order: Hemiptera
None
0.03%
0.0
Sediminibacterium
RISB0244
Spodoptera frugiperda
Order: Lepidoptera
None
0.03%
0.0
Apibacter
RISB0604
Apis cerana
Order: Hymenoptera
None
0.02%
0.0
Curtobacterium
RISB0900
Myzus persicae
Order: Hemiptera
None
0.02%
0.0
Methylorubrum
RISB0903
Myzus persicae
Order: Hemiptera
None
0.02%
0.0
Pectobacterium
RISB1772
Muscidae
Order: Diptera
None
0.01%
0.0
Yersinia
RISB0407
Anaphes nitens
Order: Hymenoptera
None
0.01%
0.0
Glutamicibacter
RISB0438
Helicoverpa armigera
Order: Lepidoptera
None
0.01%
0.0
Brevibacterium
RISB0897
Myzus persicae
Order: Hemiptera
None
0.01%
0.0
Tistrella
RISB0270
Recilia dorsalis
Order: Hemiptera
None
0.01%
0.0
Legionella
RISB1687
Polyplax serrata
Order: Phthiraptera
None
0.01%
0.0
Neisseria
RISB0512
Plutella xylostella
Order: Lepidoptera
None
0.01%
0.0
Metabacillus
RISB0902
Myzus persicae
Order: Hemiptera
None
0.01%
0.0
Helicobacter
RISB0662
Melanaphis bambusae
Order: Hemiptera
None
0.01%
0.0
Gilliamella
RISB1945
Apis cerana
Order: Hymenoptera
None
0.00%
0.0
Bifidobacterium
RISB1944
Apis cerana
Order: Hymenoptera
None
0.00%
0.0
Treponema
RISB0169
Reticulitermes flaviceps
Order: Blattodea
None
0.00%
0.0
Gluconobacter
RISB0876
Drosophila suzukii
Order: Diptera
None
0.00%
0.0
Cedecea
RISB0504
Plutella xylostella
Order: Lepidoptera
None
0.00%
0.0
Gibbsiella
RISB1320
Vespa mandarinia
Order: Hymenoptera
None
0.00%
0.0
Selenomonas
RISB1305
Aphis gossypii
Order: Hemiptera
None
0.00%
0.0

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Taxonomic Analysis Files

Kraken Report

Detailed taxonomic classification

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Krona HTML

Interactive taxonomic visualization

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Bracken Results

Species abundance estimation

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Assembly & Gene Prediction

Assembled Contigs

MEGAHIT assembly results

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Predicted Genes

Gene sequences (FASTA)

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Gene Annotation

GFF format annotation

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Genome Binning

MetaBAT2 Bins

Compressed genome bins

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Bin Information

Quality metrics and statistics

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Raw Sequencing Files

Direct download from NCBI SRA
Run ID File Size
SRR23622349
3.4 GB Download

Raw sequencing files are hosted on NCBI SRA. Click the download button to start downloading directly from NCBI servers.

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