SRR5342666 - Cycloneda sanguinea
Basic Information
Run: SRR5342666
Assay Type: WGS
Bioproject: PRJNA377641
Biosample: SAMN25047055
Bytes: 1589267352
Center Name: EMBRAPA
Sequencing Information
Instrument: Illumina HiSeq 2500
Library Layout: PAIRED
Library Selection: RANDOM
Platform: ILLUMINA
Geographic Information
Country: Brazil
Continent: South America
Location Name: Brazil: Distrito Federal
Latitude/Longitude: 15.73 S 47.9002 W
Sample Information
Host: Cycloneda sanguinea
Isolation: -
Biosample Model: Metagenome or environmental
Collection Date: 2015
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
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:
Higher scores indicate stronger symbiotic relationship potential |
|---|---|---|---|---|---|
|
Vibrio
Host Order Match
|
RISB1810 |
Monochamus galloprovincialis
Order: Coleoptera
|
Have the ability for degradation of cellulose, proteins and starch
|
23.42% |
34.7
|
|
Escherichia coli
Species-level Match
Host Order 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
|
6.50% |
24.2
|
|
Bacillus cereus
Species-level Match
Host Order Match
|
RISB1056 |
Oryctes rhinoceros
Order: Coleoptera
|
provide symbiotic digestive functions to Oryctes
|
5.89% |
21.9
|
|
Bacillus cereus
Species-level Match
Host Order Match
|
RISB1778 |
Lissorhoptrus oryzophilus
Order: Coleoptera
|
might be promising paratransgenesis candidates
|
5.89% |
21.8
|
|
Pseudomonas sp. CIP-10
Species-level Match
Host Order Match
|
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
|
1.29% |
21.1
|
|
Pseudomonas sp. CIP-10
Species-level Match
Host Order Match
|
RISB2224 |
Leptinotarsa decemlineata
Order: Coleoptera
|
Colorado potato beetle (Leptinotarsa decemlineata) larvae exploit bacteria in their oral secretions to suppress antiherbivore defenses in tomato (Solanum lycopersicum)
|
1.29% |
19.6
|
|
Lactococcus lactis
Species-level Match
Host Order Match
|
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.
|
0.71% |
19.3
|
|
Wolbachia
Host Order Match
|
RISB1452 |
Octodonta nipae
Order: Coleoptera
|
Wolbachia harbored dominantly in a female than the male adult, while, no significant differences were observed between male and female body parts and tissues
|
5.53% |
18.7
|
|
Klebsiella pneumoniae
Species-level Match
Host Order Match
|
RISB1153 |
Tenebrio molitor
Order: Coleoptera
|
degrading plastics
|
3.01% |
18.4
|
|
Enterococcus faecalis
Species-level Match
Host Order Match
|
RISB0497 |
Cryptolestes ferrugineus
Order: Coleoptera
|
bacteria can degrade malathion, pirimiphos-methyl, and deltamethrin and utilize these insecticides as the carbon source in vitro.
|
0.50% |
18.1
|
|
Wolbachia
Host Order Match
|
RISB2107 |
Sitophilus zeamais
Order: Coleoptera
|
Wolbachia directly favored weevil fertility and exhibited only mild indirect effects, usually enhancing the SZPE effect
|
5.53% |
17.9
|
|
Enterococcus faecalis
Species-level Match
Host Order Match
|
RISB2042 |
Harpalus pensylvanicus
Order: Coleoptera
|
E. faecalis facilitate seed consumption by H. pensylvanicus, possibly by contributing digestive enzymes to their host
|
0.50% |
17.8
|
|
Pseudomonas sp. CIP-10
Species-level Match
Host Order Match
|
RISB0815 |
Hypothenemus hampei
Order: Coleoptera
|
might contribute to caffeine breakdown using the C-15 oxidation pathway
|
1.29% |
17.7
|
|
Lactococcus lactis
Species-level Match
Host Order Match
|
RISB1430 |
Rhynchophorus ferrugineus
Order: Coleoptera
|
promote the development and body mass gain of RPW larvae by improving their nutrition metabolism
|
0.71% |
17.6
|
|
Streptomyces sp. T12
Species-level Match
Host Order Match
|
RISB0777 |
Copris tripartitus
Order: Coleoptera
|
contribute brood ball hygiene by inhibiting fungal parasites in the environment
|
0.82% |
17.4
|
|
Wolbachia
Host Order Match
|
RISB1282 |
Ips sp.
Order: Coleoptera
|
inducing cytoplasmic incompatibility, resulting in reproductive distortions and hence
|
5.53% |
17.2
|
|
Stenotrophomonas maltophilia
Species-level Match
Host Order Match
|
RISB0139 |
Tenebrio molitor
Order: Coleoptera
|
correlated with polyvinyl chloride PVC degradation
|
1.08% |
17.1
|
|
Enterococcus faecalis
Species-level Match
Host Order Match
|
RISB0374 |
Tribolium castaneum
Order: Coleoptera
|
modulates host phosphine resistance by interfering with the redox system
|
0.50% |
16.9
|
|
Paenibacillus sp. IHB B 3084
Species-level Match
Host Order Match
|
RISB0813 |
Hypothenemus hampei
Order: Coleoptera
|
might contribute to caffeine breakdown using the C-9 oxidation pathway
|
0.22% |
16.6
|
|
Lactococcus lactis
Species-level Match
Host Order Match
|
RISB1065 |
Oryctes rhinoceros
Order: Coleoptera
|
gut microbe
|
0.71% |
15.9
|
|
Bacillus cereus
Species-level Match
|
RISB2161 |
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.
|
5.89% |
15.9
|
|
Escherichia coli
Species-level 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
|
6.50% |
15.8
|
|
Burkholderia
Host Order 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
|
0.56% |
15.6
|
|
Staphylococcus epidermidis
Species-level Match
Host Order Match
|
RISB1070 |
Oryctes rhinoceros
Order: Coleoptera
|
gut microbe
|
0.24% |
15.5
|
|
Staphylococcus hominis
Species-level Match
Host Order Match
|
RISB1071 |
Oryctes rhinoceros
Order: Coleoptera
|
gut microbe
|
0.09% |
15.3
|
|
Burkholderia
Host Order 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
|
0.56% |
14.9
|
|
Burkholderia
Host Order Match
|
RISB1836 |
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.
|
0.56% |
14.6
|
|
Klebsiella pneumoniae
Species-level 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.
|
3.01% |
13.0
|
|
Proteus
Host Order Match
|
RISB0001 |
Leptinotarsa decemlineata
Order: Coleoptera
|
produces toxic hydrogen cyanide (HCN) and a mandelonitrile-producing cyanoglucoside, amygdalin, which protect the insect from predation
|
0.21% |
12.9
|
|
Bacteroides
Host Order Match
|
RISB1183 |
Oryzaephilus surinamensis
Order: Coleoptera
|
supplement precursors for the cuticle synthesis and thereby enhance desiccation resistance of its host
|
0.54% |
12.6
|
|
Escherichia coli
Species-level Match
|
RISB2120 |
Galleria mellonella
Order: Lepidoptera
|
mediate trans-generational immune priming
|
6.50% |
12.3
|
|
Leuconostoc
Host Order Match
|
RISB0812 |
Hypothenemus hampei
Order: Coleoptera
|
might contribute to caffeine breakdown using the C-18 oxidation pathway
|
0.15% |
11.6
|
|
Halomonas
Host Order Match
|
RISB1808 |
Monochamus galloprovincialis
Order: Coleoptera
|
Have the ability for degradation of cellulose, proteins and starch
|
0.08% |
11.4
|
|
Mycobacterium
Host Order Match
|
RISB1156 |
Nicrophorus concolor
Order: Coleoptera
|
produces Antimicrobial compounds
|
0.22% |
10.9
|
|
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
|
0.73% |
10.7
|
|
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
|
0.73% |
10.5
|
|
Paenibacillus polymyxa
Species-level Match
|
RISB2195 |
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.
|
0.25% |
10.3
|
|
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.
|
0.14% |
10.1
|
|
Stenotrophomonas maltophilia
Species-level 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.
|
1.08% |
10.1
|
|
Streptomyces sp. T12
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
|
0.82% |
9.8
|
|
Buchnera aphidicola
Species-level Match
|
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
|
0.73% |
9.5
|
|
Streptomyces sp. T12
Species-level Match
|
RISB2334 |
Sirex noctilio
Order: Hymenoptera
|
degrading woody substrates and that such degradation may assist in nutrient acquisition by S. noctilio, thus contributing to its ability to be established in forested habitats worldwide
|
0.82% |
9.5
|
|
Clostridium sp. 'deep sea'
Species-level Match
|
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
|
0.26% |
9.5
|
|
Clostridium sp. MB40-C1
Species-level Match
|
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
|
0.08% |
9.3
|
|
Mammaliicoccus sciuri
Species-level 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
|
0.15% |
9.2
|
|
Klebsiella pneumoniae
Species-level Match
|
RISB2459 |
Bombyx mori
Order: Lepidoptera
|
degradation of cellulose, xylan, pectin and starch
|
3.01% |
9.0
|
|
Acinetobacter pittii
Species-level Match
|
RISB1977 |
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
|
0.15% |
9.0
|
|
Stenotrophomonas maltophilia
Species-level Match
|
RISB1227 |
Delia antiqua
Order: Diptera
|
six bacteria protect larvae from infection with the entomopathogen Beauveria bassiana through symbiotic bacterium-derived organic acids
|
1.08% |
8.8
|
|
Paenibacillus sp. IHB B 3084
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
|
0.22% |
8.5
|
|
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
|
0.42% |
8.4
|
|
Salmonella enterica
Species-level Match
|
RISB0413 |
Melanaphis sacchari
Order: Hemiptera
|
None
|
1.94% |
6.9
|
|
Acinetobacter soli
Species-level Match
|
RISB1118 |
Spodoptera frugiperda
Order: Lepidoptera
|
degradation of flubendiamide and chlorantraniliprole
|
0.34% |
6.4
|
|
Blattabacterium cuenoti
Species-level Match
|
RISB0518 |
Cryptocercus punctulatus
Order: Blattodea
|
collaborative arginine biosynthesis
|
0.42% |
6.1
|
|
Blattabacterium cuenoti
Species-level Match
|
RISB0093 |
Blattella germanica
Order: Blattodea
|
obligate endosymbiont
|
0.42% |
5.8
|
|
Staphylococcus hominis
Species-level Match
|
RISB1881 |
Aedes aegypti
Order: Diptera
|
gut microbiome
|
0.09% |
5.4
|
|
Acinetobacter soli
Species-level Match
|
RISB0500 |
Plutella xylostella
Order: Lepidoptera
|
None
|
0.34% |
5.3
|
|
Candidatus Erwinia haradaeae
Species-level Match
|
RISB1632 |
Lachninae
Order: Hemiptera
|
None
|
0.11% |
5.1
|
|
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
|
0.11% |
5.0
|
|
Xanthomonas
|
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
|
0.26% |
4.0
|
|
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
|
0.12% |
3.3
|
|
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
|
0.12% |
3.2
|
|
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
|
0.12% |
2.9
|
|
Bacteroides
|
RISB0256 |
Leptocybe invasa
Order: Hymenoptera
|
Differences in Male-Killing Rickettsia Bacteria between Lineages of the Invasive Gall-Causing Pest Leptocybe invasa
|
0.54% |
2.8
|
|
Bacteroides
|
RISB0090 |
Hyphantria cunea
Order: Lepidoptera
|
enhance the compatibility of invasive pests to new hosts and enable more rapid adaptation to new habitats.
|
0.54% |
2.7
|
|
Yersinia
|
RISB0492 |
Cimex hemipterus
Order: Hemiptera
|
the disruption of the abundant Yersinia possibly could be related to the enhanced susceptibility towards the insecticides
|
0.13% |
2.6
|
|
Proteus
|
RISB2315 |
Aedes aegypti
Order: Diptera
|
upregulates AMP gene expression, resulting in suppression of DENV infection in the mosquito gut epithelium
|
0.21% |
2.3
|
|
Streptococcus
|
RISB2625 |
Galleria mellonella
Order: Lepidoptera
|
suppress bacteria ingested with food by producing bacteriocin and by releasing a lysozyme like enzyme
|
0.27% |
2.3
|
|
Xanthomonas
|
RISB0217 |
Xylocopa appendiculata
Order: Hymenoptera
|
strains biodegraded polyethylene terephthalate PET powder, broke it into its degradation products
|
0.26% |
2.2
|
|
Streptococcus
|
RISB2624 |
Reticulitermes flavipes
Order: Blattodea
|
can be broken down into substances such as carbon dioxide, ammonia and acetic acid
|
0.27% |
1.9
|
|
Chryseobacterium
|
RISB2092 |
Aedes aegypti
Order: Diptera
|
axenic larvae cannot develop
|
0.98% |
1.5
|
|
Streptococcus
|
RISB2604 |
Homona magnanima
Order: Lepidoptera
|
influence the growth of Bacillus thuringiensis in the larvae
|
0.27% |
1.5
|
|
Paraclostridium
|
RISB0028 |
Sesamia inferens
Order: Lepidoptera
|
degrade Chlorpyrifos and Chlorantraniliprole in vitro
|
0.23% |
1.3
|
|
Chryseobacterium
|
RISB1874 |
Aedes aegypti
Order: Diptera
|
gut microbiome
|
0.98% |
1.3
|
|
Proteus
|
RISB2460 |
Bombyx mori
Order: Lepidoptera
|
degradation of cellulose, xylan, pectin and starch
|
0.21% |
1.2
|
|
Flavobacterium
|
RISB0659 |
Melanaphis bambusae
Order: Hemiptera
|
None
|
1.02% |
1.0
|
|
Chryseobacterium
|
RISB0015 |
Aedes aegypti
Order: Diptera
|
None
|
0.98% |
1.0
|
|
Cupriavidus
|
RISB0694 |
Alydus tomentosus
Order: Hemiptera
|
None
|
0.88% |
0.9
|
|
Priestia
|
RISB0839 |
Helicoverpa armigera
Order: Lepidoptera
|
producing amylase
|
0.50% |
0.8
|
|
Legionella
|
RISB1687 |
Polyplax serrata
Order: Phthiraptera
|
None
|
0.45% |
0.5
|
|
Peribacillus
|
RISB1877 |
Aedes aegypti
Order: Diptera
|
gut microbiome
|
0.17% |
0.5
|
|
Helicobacter
|
RISB0662 |
Melanaphis bambusae
Order: Hemiptera
|
None
|
0.16% |
0.2
|
|
Yersinia
|
RISB0407 |
Anaphes nitens
Order: Hymenoptera
|
None
|
0.13% |
0.1
|
|
Treponema
|
RISB0169 |
Reticulitermes flaviceps
Order: Blattodea
|
None
|
0.11% |
0.1
|
|
Halomonas
|
RISB1374 |
Bemisia tabaci
Order: Hemiptera
|
None
|
0.08% |
0.1
|
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Assembly & Gene Prediction
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SRR5342666
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