Homologs in group_2432

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6 homologs were identified in 6 genomes with OrthoFinder.
The following table displays the locus tag of each homolog, the organism to which it belongs, the gene name and product.

	Locus tag	Identity	Source	Gene	Product
FBDBKF_19655	FBDBKF_19655	86.3	Morganella morganii S1	narZ	nitrate reductase subunit alpha
EHELCC_16945	EHELCC_16945	86.3	Morganella morganii S2	narZ	nitrate reductase subunit alpha
NLDBIP_17505	NLDBIP_17505	86.3	Morganella morganii S4	narZ	nitrate reductase subunit alpha
LHKJJB_17425	LHKJJB_17425	86.3	Morganella morganii S3	narZ	nitrate reductase subunit alpha
HKOGLL_17240	HKOGLL_17240	86.3	Morganella morganii S5	narZ	nitrate reductase subunit alpha
F4V73_RS10450	F4V73_RS10450	86.4	Morganella psychrotolerans	-	nitrate reductase subunit alpha

Distribution of the homologs in the orthogroup group_2432

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Number of homologs in each genome (first column) and amino-acid identity of the closest homolog (second column).

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Phylogeny of group_2432

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Phylogeny of the RefSeq best hits of group_2432

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Swissprot accession	Eval	Score	ID (%)	N gaps	Alignment length	Annot score	Gene	Description	Organism
P09152	0.0	2130	79	2	1241	1	narG	Respiratory nitrate reductase 1 alpha chain	Escherichia coli (strain K12)
P19319	0.0	2028	75	2	1240	1	narZ	Respiratory nitrate reductase 2 alpha chain	Escherichia coli (strain K12)
P42175	0.0	1356	52	16	1245	3	narG	Nitrate reductase alpha chain	Bacillus subtilis (strain 168)
P9WJQ3	0.0	1158	46	15	1240	1	narG	Nitrate reductase alpha subunit	Mycobacterium tuberculosis (strain ATCC 25618 / H37Rv)
P9WJQ2	0.0	1158	46	15	1240	3	narG	Nitrate reductase alpha subunit	Mycobacterium tuberculosis (strain CDC 1551 / Oshkosh)
P85097	0.0	1029	48	34	1234	1	narG	Respiratory nitrate reductase alpha chain (Fragments)	Bradyrhizobium sp.
Q47CW6	3.97e-89	313	29	20	804	1	pcrA	Perchlorate reductase subunit alpha	Dechloromonas aromatica (strain RCB)
Q47CW6	7.9e-31	135	37	4	215	1	pcrA	Perchlorate reductase subunit alpha	Dechloromonas aromatica (strain RCB)
P9WJQ1	3.07e-87	300	62	0	218	1	narX	Nitrate reductase-like protein NarX	Mycobacterium tuberculosis (strain ATCC 25618 / H37Rv)
P9WJQ0	3.07e-87	300	62	0	218	2	narX	Nitrate reductase-like protein NarX	Mycobacterium tuberculosis (strain CDC 1551 / Oshkosh)
I3R9M9	8.79e-81	290	43	4	367	1	narG	Respiratory nitrate reductase subunit alpha	Haloferax mediterranei (strain ATCC 33500 / DSM 1411 / JCM 8866 / NBRC 14739 / NCIMB 2177 / R-4)
I3R9M9	6.98e-34	145	30	13	382	1	narG	Respiratory nitrate reductase subunit alpha	Haloferax mediterranei (strain ATCC 33500 / DSM 1411 / JCM 8866 / NBRC 14739 / NCIMB 2177 / R-4)
I3R9M9	2.15e-23	111	32	5	241	1	narG	Respiratory nitrate reductase subunit alpha	Haloferax mediterranei (strain ATCC 33500 / DSM 1411 / JCM 8866 / NBRC 14739 / NCIMB 2177 / R-4)
Q8GPG4	1.01e-48	192	30	5	384	1	ddhA	Dimethylsulfide dehydrogenase subunit alpha	Rhodovulum sulfidophilum
Q8GPG4	2.98e-11	72	26	4	187	1	ddhA	Dimethylsulfide dehydrogenase subunit alpha	Rhodovulum sulfidophilum
Q8GPG4	6.77e-05	51	32	1	87	1	ddhA	Dimethylsulfide dehydrogenase subunit alpha	Rhodovulum sulfidophilum
Q9S1H0	1.3e-35	150	29	7	399	1	serA	Selenate reductase subunit alpha	Thauera selenatis
Q9S1H0	6.7e-15	84	29	4	186	1	serA	Selenate reductase subunit alpha	Thauera selenatis
Q9S1H0	7.4e-08	60	38	0	68	1	serA	Selenate reductase subunit alpha	Thauera selenatis
P60068	2.37e-31	137	27	6	365	1	clrA	Chlorate reductase subunit alpha	Ideonella dechloratans
P60068	7.52e-12	73	29	5	186	1	clrA	Chlorate reductase subunit alpha	Ideonella dechloratans
P60068	3e-07	58	40	0	67	1	clrA	Chlorate reductase subunit alpha	Ideonella dechloratans
Q9HR74	1.35e-16	89	24	8	308	2	dmsA	Putative dimethyl sulfoxide reductase catalytic subunit A	Halobacterium salinarum (strain ATCC 700922 / JCM 11081 / NRC-1)
Q9HR74	3.08e-06	55	28	2	118	2	dmsA	Putative dimethyl sulfoxide reductase catalytic subunit A	Halobacterium salinarum (strain ATCC 700922 / JCM 11081 / NRC-1)
P77374	3.15e-13	78	27	13	290	1	ynfE	Putative dimethyl sulfoxide reductase chain YnfE	Escherichia coli (strain K12)
P77374	1.13e-05	53	27	6	179	1	ynfE	Putative dimethyl sulfoxide reductase chain YnfE	Escherichia coli (strain K12)
P18775	9.24e-11	70	24	8	290	1	dmsA	Dimethyl sulfoxide reductase DmsA	Escherichia coli (strain K12)
P45004	6.67e-08	60	25	9	295	3	dmsA	Dimethyl sulfoxide reductase DmsA	Haemophilus influenzae (strain ATCC 51907 / DSM 11121 / KW20 / Rd)
P37519	1.87e-07	59	21	5	283	3	yyaE	Probable oxidoreductase YyaE	Bacillus subtilis (strain 168)
Q9KRF0	1.1e-06	57	36	1	74	3	torA	Trimethylamine-N-oxide reductase	Vibrio cholerae serotype O1 (strain ATCC 39315 / El Tor Inaba N16961)
Q9CK41	1.42e-06	56	32	1	74	3	torA	Trimethylamine-N-oxide reductase	Pasteurella multocida (strain Pm70)
Q57366	4.33e-06	55	22	17	382	1	dmsA	Dimethyl sulfoxide/trimethylamine N-oxide reductase	Cereibacter sphaeroides
Q57366	0.000702	47	29	1	74	1	dmsA	Dimethyl sulfoxide/trimethylamine N-oxide reductase	Cereibacter sphaeroides
Q8D8S3	5.18e-06	54	36	1	74	3	torA	Trimethylamine-N-oxide reductase	Vibrio vulnificus (strain CMCP6)
Q7MLQ2	5.31e-06	54	36	1	74	3	torA	Trimethylamine-N-oxide reductase	Vibrio vulnificus (strain YJ016)
Q8ZKZ7	6.37e-06	54	31	1	74	3	torA	Trimethylamine-N-oxide reductase	Salmonella typhimurium (strain LT2 / SGSC1412 / ATCC 700720)
Q8Z2M4	6.54e-06	54	31	1	74	3	torA	Trimethylamine-N-oxide reductase	Salmonella typhi
Q8EHI9	7.24e-06	54	36	1	74	3	torA	Trimethylamine-N-oxide reductase	Shewanella oneidensis (strain ATCC 700550 / JCM 31522 / CIP 106686 / LMG 19005 / NCIMB 14063 / MR-1)
P33225	7.74e-06	54	31	1	77	1	torA	Trimethylamine-N-oxide reductase 1	Escherichia coli (strain K12)
O87948	9.18e-06	53	36	1	74	1	torA	Trimethylamine-N-oxide reductase	Shewanella massilia
Q8CW73	9.25e-06	53	31	1	74	3	torA	Trimethylamine-N-oxide reductase 1	Escherichia coli O6:H1 (strain CFT073 / ATCC 700928 / UPEC)
Q52675	9.39e-06	53	23	10	247	1	dorA	Dimethyl sulfoxide/trimethylamine N-oxide reductase	Rhodobacter capsulatus
P58360	9.65e-06	53	31	1	74	3	torA	Trimethylamine-N-oxide reductase 1	Escherichia coli O157:H7
Q87QI7	3.33e-05	52	35	1	74	3	torA	Trimethylamine-N-oxide reductase	Vibrio parahaemolyticus serotype O3:K6 (strain RIMD 2210633)
P20099	9.29e-05	50	22	8	232	1	bisC	Biotin sulfoxide reductase	Escherichia coli (strain K12)
P06131	0.000572	48	38	1	67	1	fdhA	Formate dehydrogenase subunit alpha	Methanobacterium formicicum
P07658	0.000853	47	34	1	66	1	fdhF	Formate dehydrogenase H	Escherichia coli (strain K12)

Number of RefSeq hits:

General

Source	Proteus mirabilis HI4320
Locus tag	PMI_RS17765
Feature type	CDS
Gene	-
Product	nitrate reductase subunit alpha
Location	3899261 - 3903022 (strand: 1)
Length	3762 (nucleotides) / 1253 (amino acids)

Contig

Accession	NC_010554
Length	4063606 nucleotides
Topology	circular
Plasmid	False

Orthology

Orthogroup	group_2432
Orthogroup size	7
N. genomes	7

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Genomic region

Domains

PF00384	Molybdopterin oxidoreductase
PF01568	Molydopterin dinucleotide binding domain
PF14710	Respiratory nitrate reductase alpha N-terminal

COG entry Annotation(s)

ID	Function(s) descr.	Function(s) cat.	Description
COG5013	Energy production and conversion (C) Inorganic ion transport and metabolism (P)	CP	Nitrate reductase alpha subunit

Kegg Ortholog Annotation(s)

KO	Description	Pathways	Modules
K00370	nitrate reductase / nitrite oxidoreductase, alpha subunit [EC:1.7.5.1 1.7.99.-]	Nitrogen metabolism Metabolic pathways Microbial metabolism in diverse environments Two-component system	Denitrification, nitrate => nitrogen Dissimilatory nitrate reduction, nitrate => ammonia Complete nitrification, comammox, ammonia => nitrite => nitrate

Protein Sequence

MSKFLDRFRYFKQLGDTFSQDHGQELNVNRDWENSYRSRWQHDKIVRSTHGVNCTGSCSWKIYVKNGLVTWETQQTDYPRTRPDLPDHEPRGCPRGASYSWYLYSANRVKYPMVRKRLIKLWREAKAQHADPVDAWASIVNAPEKTKSYKQARGRGGFVRSSWSEVNEIIAASNVYTAKTFGPDRIIGFSPIPAMSMVSYAAGARYLSLIGGACLSFYDWYCDLPPASPMTWGEQTDVPESADWYNSSYLIAWGSNVPQTRTPDAHFFTEVRYKGTKTVAVTPDYAEIAKLCDQWLNPKQGTDSAMAMAMGHVILNEFHVKRQTEYFSNYVRIYTDMPMLVMLDKHDSGKLVAGRMLRAADLVNNLDQEKNPEWKTIAIDEKTQQLVAPQGSMGFRWEGAAKWNLEPKDGKSGEEVTLQLGLLENHDDVVDVAFPYFGGIKSEYFEGVALDDVLVHRLPAKRITLANGEEKYVTTVYDLLLANYGVDRGLNDENCATNYDEIKAYSPAWAEQVTGVSRQDIIRIAREFADNAEKTHGRSMVIVGAGINHWYHMDMTYRGIINMLIFCGCIGQSGGGWAHYVGQEKLRPQTGWLPLAFGLDWQRPPRHMNSTSFFYNHSSQWRYETVSPTELLSPLADKSRFSGSLIDMNVRSERMGWLPSAPQLNVNPLSITKKAQQAGVSATDYTINALKSGEIRFASEQPDNPQNFPRNLFIWRSNLLGSAGKGHEYLLKYLLGTENGLQGKDLGEQGQVKPQEVEWQDKGGEGKVDLVVTLDFRMSSTCLFSDIVLPTATWYEKDDMNTSDMHPFIHPLTAAVDPAWESKTDWEIYKGIAKTFSKLCVGHLGVETDLVTQPIQHDSAAEMAQPFDVKDWKKGECDLIPGKTAPHLIPVERDYPNTYARFTSLGPLMDKLGNGGKGIGWNTQTEVDFLKKLNRVRHDGVAKGRPAIETAIDAAEVILSLAPETNGQVAVKAWDALSKVTGRDHTHLAKVKEDEKIRFRDIVAQPRKIISSPTWSGLEDEHVSYNACYTNVHEMIPWRTLSGRQQLYQDHEWMRAYGESLVVYRPPIDTKAIEAVKGKKPNGFPEKALNFLTPHQKWGIHSTYSDNLLMLTLGRGGPVVWLSEDDAKEMGISDNDWVEAYNSNGALTARAIVSQRIPDGMIYMYHAQERQINLPGSEITGMRGGIHNSVTRVCPKPTHMIGGYAQLAYSFNYYGTVGSNRDEFVVVRKMKQIDWLDGEGDAYQQTLNGQEKA

Flanking regions ( +/- flanking 50bp)

ACGAATTATACGCAATGTGAGCGCGCTAACGCGCATTGGGAGAGTATCTGATGAGTAAATTTCTCGATAGATTCCGCTATTTTAAACAGCTTGGTGATACGTTTTCACAAGATCACGGGCAAGAGTTAAATGTTAATCGCGACTGGGAAAATAGTTATCGTAGCCGTTGGCAGCATGACAAAATCGTGCGTTCTACACATGGTGTTAACTGCACCGGATCATGTAGCTGGAAAATTTATGTTAAAAACGGCTTAGTAACATGGGAAACCCAGCAAACAGACTATCCACGAACTCGTCCTGATCTGCCTGATCATGAACCCCGTGGTTGTCCGCGTGGTGCGAGCTATTCATGGTATTTATATAGCGCTAACCGCGTTAAATACCCAATGGTACGTAAACGTCTGATCAAATTATGGCGTGAAGCCAAAGCGCAACACGCTGATCCAGTTGATGCATGGGCATCGATTGTTAATGCTCCCGAAAAAACGAAAAGTTATAAACAAGCTCGTGGTCGTGGTGGTTTCGTTCGCTCTTCATGGTCTGAAGTGAATGAAATTATTGCTGCCTCTAACGTCTATACCGCTAAAACTTTTGGCCCAGATCGTATTATTGGTTTCTCACCTATTCCGGCAATGTCAATGGTGTCTTACGCCGCCGGTGCCCGCTATTTATCTCTTATTGGTGGTGCTTGCTTAAGTTTTTACGATTGGTATTGTGATTTACCACCTGCCTCACCAATGACTTGGGGGGAGCAAACAGATGTGCCAGAGTCAGCTGACTGGTATAACTCTTCTTATCTGATTGCATGGGGTTCAAACGTACCTCAAACCCGTACGCCAGATGCTCACTTTTTTACCGAAGTTCGTTATAAAGGCACCAAAACGGTAGCAGTAACACCTGATTATGCTGAAATTGCTAAACTGTGTGACCAGTGGTTAAACCCAAAACAAGGTACAGATAGCGCCATGGCAATGGCGATGGGACACGTTATTCTTAACGAATTCCACGTTAAACGCCAAACTGAATACTTTAGTAACTATGTGCGCATTTACACTGACATGCCAATGTTAGTGATGTTAGATAAGCATGATTCTGGCAAATTAGTTGCGGGTCGCATGCTACGTGCCGCTGATTTAGTGAACAATCTCGATCAGGAGAAAAATCCAGAATGGAAAACCATTGCTATTGATGAGAAAACACAGCAATTGGTCGCTCCTCAAGGTTCAATGGGTTTTCGTTGGGAAGGCGCTGCCAAATGGAATCTAGAGCCTAAAGACGGTAAGAGTGGCGAAGAAGTCACTTTACAATTGGGTCTTTTAGAAAATCATGATGATGTGGTTGACGTTGCATTTCCTTACTTTGGTGGCATCAAGAGTGAATACTTTGAAGGTGTTGCCCTTGATGATGTTCTCGTTCATAGACTGCCAGCAAAACGCATTACTCTTGCCAATGGCGAAGAAAAATATGTCACTACCGTTTATGACTTATTACTGGCTAACTATGGTGTCGATCGTGGTTTAAATGATGAAAACTGTGCGACAAACTATGATGAGATCAAAGCCTATTCACCCGCATGGGCTGAACAAGTAACAGGGGTTAGCCGTCAAGATATTATCCGCATTGCACGTGAATTTGCTGATAATGCAGAAAAAACACATGGTCGTTCAATGGTGATTGTCGGTGCGGGCATTAACCATTGGTATCACATGGATATGACCTACCGTGGCATTATCAATATGCTTATCTTCTGTGGTTGTATTGGCCAAAGTGGTGGGGGGTGGGCTCACTATGTGGGACAAGAAAAACTGCGTCCACAAACAGGTTGGTTGCCATTAGCTTTTGGTCTGGATTGGCAGCGTCCACCTCGTCATATGAATAGCACGTCATTTTTCTATAATCATTCAAGTCAATGGCGCTATGAAACGGTATCACCGACAGAATTACTATCACCTTTAGCAGATAAATCACGCTTTAGCGGTAGCTTAATTGATATGAATGTGCGTTCGGAGCGTATGGGGTGGTTACCGTCAGCACCGCAATTAAACGTTAACCCATTGTCTATTACCAAGAAAGCTCAACAAGCTGGCGTCAGTGCAACGGATTATACCATTAATGCTCTGAAATCAGGTGAGATCCGTTTTGCATCAGAGCAACCGGATAATCCGCAAAACTTCCCTCGTAACTTATTTATCTGGCGTTCTAATTTATTGGGATCTGCAGGTAAAGGGCATGAATATTTACTGAAATATCTATTAGGGACGGAAAATGGATTACAAGGTAAAGATTTAGGTGAACAAGGCCAAGTTAAGCCACAAGAAGTGGAATGGCAAGATAAAGGCGGTGAGGGTAAGGTCGATTTAGTGGTGACTTTAGACTTTCGTATGTCAAGTACCTGTCTGTTCTCCGATATCGTGTTACCAACCGCCACATGGTATGAAAAAGATGATATGAATACCTCGGATATGCATCCATTTATTCATCCATTAACCGCCGCGGTAGATCCCGCTTGGGAGTCTAAAACCGATTGGGAAATTTATAAAGGTATTGCTAAAACCTTCTCTAAATTGTGTGTCGGTCATTTAGGGGTTGAAACCGATTTAGTGACACAGCCAATACAACATGACTCCGCGGCTGAAATGGCACAACCATTTGATGTCAAAGATTGGAAAAAAGGTGAATGTGACCTTATCCCGGGGAAAACTGCACCGCATCTTATTCCTGTGGAGCGTGATTATCCAAATACCTATGCTCGTTTTACCTCACTTGGGCCGTTAATGGATAAATTAGGTAATGGCGGTAAAGGGATCGGTTGGAATACACAGACAGAAGTTGATTTCCTGAAAAAACTTAATCGCGTTCGTCATGACGGTGTGGCAAAAGGGCGCCCGGCGATTGAAACCGCAATTGATGCAGCCGAAGTTATCCTCTCTTTAGCACCTGAAACGAATGGTCAAGTGGCGGTAAAAGCGTGGGATGCACTAAGTAAAGTAACAGGACGCGATCACACTCATTTAGCTAAAGTAAAAGAAGATGAGAAAATTCGTTTCCGCGATATCGTTGCTCAACCTCGTAAAATCATTTCAAGTCCTACATGGTCTGGTCTGGAAGATGAGCATGTCTCTTATAACGCTTGTTATACCAATGTTCACGAGATGATCCCTTGGCGTACTTTAAGTGGCCGTCAGCAGTTATATCAAGATCATGAGTGGATGCGTGCTTATGGCGAAAGTTTAGTGGTTTATCGTCCACCTATTGATACTAAGGCAATCGAAGCCGTGAAAGGTAAAAAACCGAACGGCTTCCCAGAAAAAGCGCTGAACTTCCTGACGCCTCACCAAAAATGGGGTATTCACTCAACGTATAGCGATAACTTACTGATGTTAACCCTCGGTCGTGGTGGCCCTGTGGTTTGGCTGAGTGAAGATGATGCTAAAGAGATGGGTATTAGTGATAACGATTGGGTTGAAGCATACAACAGTAATGGTGCGTTAACCGCAAGAGCGATTGTGAGCCAACGTATTCCTGATGGCATGATTTATATGTATCACGCACAAGAGCGCCAAATAAACCTACCAGGCTCTGAAATAACTGGAATGCGTGGCGGTATTCATAATTCCGTGACGCGTGTTTGCCCTAAACCGACCCATATGATTGGTGGATACGCTCAGTTGGCTTATAGCTTTAACTACTATGGAACTGTGGGCTCTAACCGCGATGAATTTGTTGTGGTACGTAAGATGAAACAGATTGATTGGCTTGATGGTGAAGGCGATGCTTATCAACAAACCCTGAATGGACAGGAGAAGGCATAATGAAAATTCGTTCACAAGTCGGTATGGTACTGAACCTCGACAAATGTATC