SRR5342618 - Hippodamia convergens

Basic Information

Run: SRR5342618

Assay Type: WGS

Bioproject: PRJNA377711

Biosample: SAMN25047087

Bytes: 699460959

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: Hippodamia convergens

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

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
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	2.50%	22.3
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)	2.50%	20.8
Bacillus cereus Species-level Match Host Order Match	RISB1056	Oryctes rhinoceros Order: Coleoptera	provide symbiotic digestive functions to Oryctes	4.25%	20.2
Bacillus cereus Species-level Match Host Order Match	RISB1778	Lissorhoptrus oryzophilus Order: Coleoptera	might be promising paratransgenesis candidates	4.25%	20.2
Staphylococcus gallinarum Species-level Match Host Order Match	RISB0945	Callosobruchus maculatus Order: Coleoptera	The strain encodes complete biosynthetic pathways for the production of B vitamins and amino acids, including tyrosine; A carbohydrate-active enzyme search revealed that the genome codes for a number of digestive enzymes, reflecting the nutritional ecology of C. maculatus	0.15%	20.2
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	1.61%	19.3
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.	0.66%	19.2
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	2.50%	18.9
Sphingobacterium sp. R2 Species-level Match Host Order Match	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)	0.40%	18.7
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	1.24%	17.8
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	4.66%	17.8
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	0.66%	17.6
Serratia marcescens Species-level Match Host Order Match	RISB1295	Nicrophorus vespilloides Order: Coleoptera	producing antibacterial compound Serrawettin W2, which has antibacterial and nematode-inhibiting effects	0.47%	17.6
Staphylococcus gallinarum Species-level Match Host Order Match	RISB0946	Callosobruchus maculatus Order: Coleoptera	The strain encodes complete biosynthetic pathways for the production of B vitamins and amino acids, including tyrosine	0.15%	17.5
Klebsiella pneumoniae Species-level Match Host Order Match	RISB1153	Tenebrio molitor Order: Coleoptera	degrading plastics	2.12%	17.5
Serratia marcescens Species-level Match Host Order Match	RISB0365	Pagiophloeus tsushimanus Order: Coleoptera	terpenoid-degrading: the highest degradation rates of D-camphor, linalool, and eucalyptol	0.47%	17.3
Stenotrophomonas maltophilia Species-level Match Host Order Match	RISB0139	Tenebrio molitor Order: Coleoptera	correlated with polyvinyl chloride PVC degradation	1.10%	17.1
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	4.66%	17.0
Serratia marcescens Species-level Match Host Order Match	RISB1158	Nicrophorus vespilloides Order: Coleoptera	produces an antibacterial cyclic lipopeptide called serrawettin W2	0.47%	16.8
Wolbachia Host Order Match	RISB1282	Ips sp. Order: Coleoptera	inducing cytoplasmic incompatibility, resulting in reproductive distortions and hence	4.66%	16.4
Acinetobacter Host Order Match	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)	1.39%	16.1
Lactococcus lactis Species-level Match Host Order Match	RISB1065	Oryctes rhinoceros Order: Coleoptera	gut microbe	0.66%	15.9
Staphylococcus epidermidis Species-level Match Host Order Match	RISB1070	Oryctes rhinoceros Order: Coleoptera	gut microbe	0.18%	15.4
Acinetobacter Host Order Match	RISB1356	Callosobruchus maculatus Order: Coleoptera	These bacterial phyla may allow the adults C. maculatus to survive on DDVP treated grains, thereby making it inappropriate to control the beetle populations in the field.	1.39%	14.8
Vibrio Host Order Match	RISB1810	Monochamus galloprovincialis Order: Coleoptera	Have the ability for degradation of cellulose, proteins and starch	3.19%	14.5
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.	4.25%	14.3
Spiroplasma Host Order Match	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	0.43%	13.9
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	1.09%	13.8
Acinetobacter Host Order Match	RISB0520	Leptinotarsa decemlineata Order: Coleoptera	inhibited the expression of genes associated with the JA-mediated defense signaling pathway and SGA biosynthesis	1.39%	13.6
Bacteroides Host Order Match	RISB1183	Oryzaephilus surinamensis Order: Coleoptera	supplement precursors for the cuticle synthesis and thereby enhance desiccation resistance of its host	0.90%	12.9
Spiroplasma Host Order Match	RISB1483	Brachinus elongatulus Order: Coleoptera	may manipulate host reproduction (e.g., cause male-killing) or provide resistance to nematodes and/or parasitoid wasps	0.43%	12.8
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.	2.12%	12.1
Leuconostoc Host Order Match	RISB0812	Hypothenemus hampei Order: Coleoptera	might contribute to caffeine breakdown using the C-18 oxidation pathway	0.60%	12.0
Paenibacillus Host Order Match	RISB0813	Hypothenemus hampei Order: Coleoptera	might contribute to caffeine breakdown using the C-9 oxidation pathway	0.53%	11.9
Nostoc Host Order Match	RISB0812	Hypothenemus hampei Order: Coleoptera	might contribute to caffeine breakdown using the C-18 oxidation pathway	0.29%	11.7
Lysinibacillus Host Order Match	RISB1066	Oryctes rhinoceros Order: Coleoptera	gut microbe	1.17%	11.4
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	1.37%	11.4
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	1.37%	11.1
Spiroplasma Host Order Match	RISB0250	Tenebrio molitor Order: Coleoptera	associated with PE biodegradation	0.43%	11.1
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	1.61%	10.9
Exiguobacterium Host Order Match	RISB1152	Tenebrio molitor Order: Coleoptera	degrading plastics	0.47%	10.8
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	1.24%	10.2
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	1.37%	10.2
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.	1.10%	10.1
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	1.24%	9.9
Clostridium sp. AWRP 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	0.25%	9.5
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	0.24%	9.2
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	0.97%	8.9
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	1.10%	8.8
Enterococcus casseliflavus Species-level Match	RISB0112	Bactrocera dorsalis Order: Diptera	increase the resistance of B. dorsalis to β-cypermethrin by regulating cytochrome P450 (P450) enzymes and α-glutathione S-transferase (GST) activities	0.46%	8.5
Klebsiella pneumoniae Species-level Match	RISB2459	Bombyx mori Order: Lepidoptera	degradation of cellulose, xylan, pectin and starch	2.12%	8.1
Providencia sp. PROV040 Species-level Match	RISB1574	Bactrocera tau Order: Diptera	could attract male and female B. tau	2.05%	7.8
Providencia sp. PROV040 Species-level Match	RISB0984	Nasonia vitripennis Order: Hymenoptera	may highly associated with diapause	2.05%	7.8
Escherichia coli Species-level Match	RISB2120	Galleria mellonella Order: Lepidoptera	mediate trans-generational immune priming	1.61%	7.4
Blattabacterium sp. (Blattella germanica) Species-level Match	RISB1534	Periplaneta fuliginosa Order: Blattodea	involved in uric acid degradation, nitrogen assimilation and nutrient provisioning	0.58%	7.2
Blattabacterium cuenoti Species-level Match	RISB0518	Cryptocercus punctulatus Order: Blattodea	collaborative arginine biosynthesis	0.97%	6.7
Enterococcus casseliflavus Species-level Match	RISB1755	Spodoptera frugiperda Order: Lepidoptera	may influence the metabolization of pesticides in insects	0.46%	6.6
Enterococcus casseliflavus Species-level Match	RISB1991	Diatraea saccharalis Order: Lepidoptera	possess cellulose degrading activity	0.46%	6.2
Salmonella enterica Species-level Match	RISB0413	Melanaphis sacchari Order: Hemiptera	None	1.01%	6.0
Paenibacillus	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.	0.53%	5.5
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	0.40%	5.4
Pantoea vagans Species-level Match	RISB1842	Macrotermes natalensis Order: Blattodea	None	0.38%	5.4
Candidatus Erwinia haradaeae Species-level Match	RISB1632	Lachninae Order: Hemiptera	None	0.19%	5.2
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	0.26%	4.7
Paenibacillus	RISB0774	Delia antiqua Order: Diptera	showed significant contact inhibition activity against fungal entomopathogen Fusarium moniliforme, Botryosphaeria dothidea and both Fusarium oxysporum respectively	0.53%	3.8
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.	0.40%	3.8
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	0.40%	3.3
Proteus	RISB2315	Aedes aegypti Order: Diptera	upregulates AMP gene expression, resulting in suppression of DENV infection in the mosquito gut epithelium	1.09%	3.2
Bacteroides	RISB0256	Leptocybe invasa Order: Hymenoptera	Differences in Male-Killing Rickettsia Bacteria between Lineages of the Invasive Gall-Causing Pest Leptocybe invasa	0.90%	3.2
Exiguobacterium	RISB0007	Phormia regina Order: Diptera	prompted oviposition by flies; The flies' oviposition decisions appear to be guided by bacteria-derived semiochemicals as the bacteria	0.47%	3.2
Bacteroides	RISB0090	Hyphantria cunea Order: Lepidoptera	enhance the compatibility of invasive pests to new hosts and enable more rapid adaptation to new habitats.	0.90%	3.0
Streptococcus	RISB2625	Galleria mellonella Order: Lepidoptera	suppress bacteria ingested with food by producing bacteriocin and by releasing a lysozyme like enzyme	0.90%	2.9
Psychrobacter	RISB1773	Calliphoridae Order: Diptera	it shows physiological adaptation to survival in warmer temperatures and has been previously associated with food spoilage	0.18%	2.6
Sphingomonas	RISB0420	Aphis gossypii Order: Hemiptera	Sphingomonas could mediate A. gossypii resistance to imidacloprid by hydroxylation and nitroreduction	0.56%	2.6
Streptococcus	RISB2624	Reticulitermes flavipes Order: Blattodea	can be broken down into substances such as carbon dioxide, ammonia and acetic acid	0.90%	2.5
Sphingomonas	RISB1307	Aphis gossypii Order: Hemiptera	have been previously described in associations with phloem-feeding insects, in low abundances	0.56%	2.4
Sphingomonas	RISB0134	Spodoptera frugiperda Order: Lepidoptera	provide a protective effect to against chlorantraniliprole stress to S. frugiperda	0.56%	2.2
Lysinibacillus	RISB1416	Psammotermes hypostoma Order: Blattodea	isolates showed significant cellulolytic activity	1.17%	2.2
Flavobacterium	RISB0659	Melanaphis bambusae Order: Hemiptera	None	2.15%	2.2
Streptococcus	RISB2604	Homona magnanima Order: Lepidoptera	influence the growth of Bacillus thuringiensis in the larvae	0.90%	2.1
Proteus	RISB2460	Bombyx mori Order: Lepidoptera	degradation of cellulose, xylan, pectin and starch	1.09%	2.1
Chryseobacterium	RISB2092	Aedes aegypti Order: Diptera	axenic larvae cannot develop	1.31%	1.9
Chryseobacterium	RISB1874	Aedes aegypti Order: Diptera	gut microbiome	1.31%	1.6
Paraclostridium	RISB0028	Sesamia inferens Order: Lepidoptera	degrade Chlorpyrifos and Chlorantraniliprole in vitro	0.41%	1.5
Peribacillus	RISB1877	Aedes aegypti Order: Diptera	gut microbiome	1.18%	1.5
Exiguobacterium	RISB0582	Aleurodicus rugioperculatus Order: Hemiptera	may indirectly affect whitefly oviposition	0.47%	1.3
Chryseobacterium	RISB0015	Aedes aegypti Order: Diptera	None	1.31%	1.3
Priestia	RISB0839	Helicoverpa armigera Order: Lepidoptera	producing amylase	0.65%	1.0
Legionella	RISB1687	Polyplax serrata Order: Phthiraptera	None	0.96%	1.0
Helicobacter	RISB0662	Melanaphis bambusae Order: Hemiptera	None	0.46%	0.5
Myroides	RISB0626	Musca altica Order: Diptera	None	0.29%	0.3
Apibacter	RISB0604	Apis cerana Order: Hymenoptera	None	0.26%	0.3