CRISPRimmunity

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Overview of predicted results

Overview of the results

Contig_ID	Contig_def	CRISPR array number	Contig Signature genes	Self targeting spacer number	Target MGE spacer number	Prophage number	Anti-CRISPR protein number
NZ_CP024949	Helicobacter pylori strain B136A chromosome, complete genome	4 crisprs	cas2,c2c9_V-U4,cas3,cas14j,DEDDh	0	1	0	0

Cas Category Instructions

Results visualization

1. NZ_CP024949

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CRISPR-Cas detection and classification

Crispr_ID: NZ_CP024949_1

CRISPR_ID

CRISPR_location

CRISPR_type

Repeat_type

Spacer_info

Cas_protein_info

CRISPR-Cas_info

NZ_CP024949_1

269537-269634

Unclear

Consensus_repeat	Method
AAATTTTGGGCTAGAATGTGTAAAAAGGTAAAAT	CRISPRCasFinder

1 spacers

cas2

The CRISPR arrays of NZ_CP024949_1

>merge|NZ_CP024949|1|269537-269634|CRISPRCasFinder
AAATTTTGGGCTAGAATGTGTAAAAAGGTAAAATTTGAAAAGCTTAAAAAGCCTCTCTTACTGAAAATTTTGGGCTAGAATGTGTAAAAAGGTAAAAT

>NZ_CP024949|1|1|269537-269634|CRISPRCasFinder
AAATTTTGGGCTAGAATGTGTAAAAAGGTAAAAT	TTGAAAAGCTTAAAAAGCCTCTCTTACTGA
AAATTTTGGGCTAGAATGTGTAAAAAGGTAAAAT

Protein	Signature genes	Signature genes Name	Protein_function
NZ_CP024949.1\|WP_145819984.1\|283813_285037_-\|2-oxoacid:ferredoxin-oxidoreductase-subunit-alpha	unknown	unknown	gnl\|CDD\|181999
NZ_CP024949.1\|WP_145819962.1\|261680_261935_+\|YafQ-family-addiction-module-toxin	unknown	unknown	gnl\|CDD\|379750
NZ_CP024949.1\|WP_015644167.1\|274465_275017_+\|Holliday-junction-branch-migration-protein-RuvA	unknown	unknown	gnl\|CDD\|129193
NZ_CP024949.1\|WP_000242349.1\|264553_265321_+\|ABC-transporter-ATP-binding-protein	unknown	unknown	gnl\|CDD\|224045
NZ_CP024949.1\|WP_001135623.1\|262055_262580_-\|acyl-CoA-thioesterase	unknown	unknown	gnl\|CDD\|224523
NZ_CP024949.1\|WP_000921461.1\|263573_264554_+\|iron-ABC-transporter-permease	unknown	unknown	gnl\|CDD\|376439
NZ_CP024949.1\|WP_145819960.1\|261376_261667_+\|hypothetical-protein	unknown	unknown	unknown
NZ_CP024949.1\|WP_000271050.1\|260924_261209_+\|endoribonuclease-VapD	cas2	pfam09827_cas2_CAS-I:CAS-II:CAS-III	gnl\|CDD\|225846
NZ_CP024949.1\|WP_145819972.1\|272594_274439_+\|DUF342-domain-containing-protein	unknown	unknown	unknown
NZ_CP024949.1\|WP_145819956.1\|257987_260156_+\|Hop-family-adhesin-BabA	unknown	unknown	gnl\|CDD\|375731
NZ_CP024949.1\|WP_145819982.1\|282856_283801_-\|pyruvate-ferredoxin-oxidoreductase	unknown	unknown	gnl\|CDD\|239471
NZ_CP024949.1\|WP_145819970.1\|271041_272502_-\|murein-biosynthesis-integral-membrane-protein-MurJ	unknown	unknown	gnl\|CDD\|367301
NZ_CP024949.1\|WP_145819968.1\|269643_271041_-\|cysteine--tRNA-ligase	unknown	unknown	gnl\|CDD\|234705
NZ_CP024949.1\|WP_145819978.1\|280527_281361_-\|outer-membrane-beta-barrel-protein	unknown	unknown	gnl\|CDD\|280099
NZ_CP024949.1\|WP_121098477.1\|278546_280523_+\|excinuclease-ABC-subunit-B	unknown	unknown	gnl\|CDD\|235395
NZ_CP024949.1\|WP_145819964.1\|262738_263581_+\|SDR-family-NAD(P)-dependent-oxidoreductase	unknown	unknown	gnl\|CDD\|187632
NZ_CP024949.1\|WP_145819980.1\|281426_282749_-\|adenylosuccinate-lyase	unknown	unknown	gnl\|CDD\|181437
NZ_CP024949.1\|WP_145819958.1\|260551_260944_+\|hypothetical-protein	unknown	unknown	unknown
NZ_CP024949.1\|WP_145819966.1\|265394_269357_-\|autotransporter-domain-containing-protein	unknown	unknown	gnl\|CDD\|111576
NZ_CP024949.1\|WP_145819976.1\|277856_278477_+\|DUF1542-domain-containing-protein	unknown	unknown	unknown

Protein	Function_ID	Function_description	E-value
NZ_CP024949.1\|WP_145819984.1\|283813_285037_-\|2-oxoacid:ferredoxin-oxidoreductase-subunit-alpha	gnl\|CDD\|181999	PRK09622, porA, 2-oxoacid:ferredoxin oxidoreductase subunit alpha.	0
NZ_CP024949.1\|WP_145819962.1\|261680_261935_+\|YafQ-family-addiction-module-toxin	gnl\|CDD\|379750	pfam15738, YafQ_toxin, Bacterial toxin of type II toxin-antitoxin system, YafQ. YafQ is a family of bacterial toxin ribonucleases of type II toxin-antitoxin systems. The E.coli gene is expressed from the dinB operon. The cognate antitoxin for the E. coli protein is DinJ, in family RelB_antitoxin, pfam02604.	8.18432e-32
NZ_CP024949.1\|WP_015644167.1\|274465_275017_+\|Holliday-junction-branch-migration-protein-RuvA	gnl\|CDD\|129193	TIGR00084, Holliday_junction_ATP-dependent_DNA_helicase_RuvA, Holliday junction DNA helicase, RuvA subunit. RuvA specifically binds Holliday junctions as a sandwich of two tetramers and maintains the configuration of the junction. It forms a complex with two hexameric rings of RuvB, the subunit that contains helicase activity. The complex drives ATP-dependent branch migration of the Holliday junction recombination intermediate. The endonuclease RuvC resolves junctions. [DNA metabolism, DNA replication, recombination, and repair].	1.11068e-67
NZ_CP024949.1\|WP_000242349.1\|264553_265321_+\|ABC-transporter-ATP-binding-protein	gnl\|CDD\|224045	COG1120, FepC, ABC-type cobalamin/Fe3+-siderophores transport systems, ATPase components [Inorganic ion transport and metabolism / Coenzyme metabolism].	9.28427e-100
NZ_CP024949.1\|WP_001135623.1\|262055_262580_-\|acyl-CoA-thioesterase	gnl\|CDD\|224523	COG1607, COG1607, Acyl-CoA hydrolase [Lipid metabolism].	3.69539e-64
NZ_CP024949.1\|WP_000921461.1\|263573_264554_+\|iron-ABC-transporter-permease	gnl\|CDD\|376439	pfam01032, FecCD, FecCD transport family. This is a sub-family of bacterial binding protein-dependent transport systems family. This Pfam entry contains the inner components of this multicomponent transport system.	1.59229e-66
NZ_CP024949.1\|WP_000271050.1\|260924_261209_+\|endoribonuclease-VapD	gnl\|CDD\|225846	COG3309, VapD, Uncharacterized virulence-associated protein D [Function unknown].	1.44851e-45
NZ_CP024949.1\|WP_145819956.1\|257987_260156_+\|Hop-family-adhesin-BabA	gnl\|CDD\|375731	pfam18304, SabA_adhesion, SabA N-terminal extracellular adhesion domain. This is the N-terminal extracellular adhesion domain of Sialic acid binding adhesin (SabA) present in Helicobacter pylori. The N-terminal domain of SabA functions as a sugar-binding adhesion domain with conserved disulfide bonds. Notably, these amino acid residues are not only conserved among SabA orthologs but also between SabA and BabA.	9.4948e-72
NZ_CP024949.1\|WP_145819982.1\|282856_283801_-\|pyruvate-ferredoxin-oxidoreductase	gnl\|CDD\|239471	cd03376, TPP_PFOR_porB_like, Thiamine pyrophosphate (TPP family), PFOR porB-like subfamily, TPP-binding module; composed of proteins similar to the beta subunit (porB) of the Helicobacter pylori four-subunit pyruvate ferredoxin oxidoreductase (PFOR), which are also found in archaea and some hyperthermophilic bacteria. PFOR catalyzes the oxidative decarboxylation of pyruvate to form acetyl-CoA, a crucial step in many metabolic pathways. Archaea, anaerobic bacteria and eukaryotes that lack mitochondria (and therefore pyruvate dehydrogenase) use PFOR to oxidatively decarboxylate pyruvate, with ferredoxin or flavodoxin as the electron acceptor. The 36-kDa porB subunit contains the binding sites for the cofactors, TPP and a divalent metal cation, which are required for activity.	5.0765e-135
NZ_CP024949.1\|WP_145819970.1\|271041_272502_-\|murein-biosynthesis-integral-membrane-protein-MurJ	gnl\|CDD\|367301	pfam03023, MVIN, MviN-like protein. Deletion of the mviN virulence gene in Salmonella enterica serovar. Typhimurium greatly reduces virulence in a mouse model of typhoid-like disease. Open reading frames encoding homologs of MviN have since been identified in a variety of bacteria, including pathogens and non-pathogens and plant-symbionts. In the nitrogen-fixing symbiont Rhizobium tropici, mviN is required for motility. The MviM protein is predicted to be membrane-associated.	1.14155e-115
NZ_CP024949.1\|WP_145819968.1\|269643_271041_-\|cysteine--tRNA-ligase	gnl\|CDD\|234705	PRK00260, cysS, cysteinyl-tRNA synthetase; Validated.	0
NZ_CP024949.1\|WP_145819978.1\|280527_281361_-\|outer-membrane-beta-barrel-protein	gnl\|CDD\|280099	pfam01856, HP_OMP, Helicobacter outer membrane protein. This family seems confined to Helicobacter. It is predicted to be an outer membrane protein based on its pattern of alternating hydrophobic amino acids similar to porins.	6.56886e-33
NZ_CP024949.1\|WP_121098477.1\|278546_280523_+\|excinuclease-ABC-subunit-B	gnl\|CDD\|235395	PRK05298, PRK05298, excinuclease ABC subunit UvrB.	0
NZ_CP024949.1\|WP_145819964.1\|262738_263581_+\|SDR-family-NAD(P)-dependent-oxidoreductase	gnl\|CDD\|187632	cd05374, 17beta-HSD-like_SDR_c, 17beta hydroxysteroid dehydrogenase-like, classical (c) SDRs. 17beta-hydroxysteroid dehydrogenases are a group of isozymes that catalyze activation and inactivation of estrogen and androgens. SDRs are a functionally diverse family of oxidoreductases that have a single domain with a structurally conserved Rossmann fold (alpha/beta folding pattern with a central beta-sheet), an NAD(P)(H)-binding region, and a structurally diverse C-terminal region. Classical SDRs are typically about 250 residues long, while extended SDRs are approximately 350 residues. Sequence identity between different SDR enzymes are typically in the 15-30% range, but the enzymes share the Rossmann fold NAD-binding motif and characteristic NAD-binding and catalytic sequence patterns. These enzymes catalyze a wide range of activities including the metabolism of steroids, cofactors, carbohydrates, lipids, aromatic compounds, and amino acids, and act in redox sensing. Classical SDRs have an TGXXX[AG]XG cofactor binding motif and a YXXXK active site motif, with the Tyr residue of the active site motif serving as a critical catalytic residue (Tyr-151, human 15-hydroxyprostaglandin dehydrogenase (15-PGDH) numbering). In addition to the Tyr and Lys, there is often an upstream Ser (Ser-138, 15-PGDH numbering) and/or an Asn (Asn-107, 15-PGDH numbering) contributing to the active site; while substrate binding is in the C-terminal region, which determines specificity. The standard reaction mechanism is a 4-pro-S hydride transfer and proton relay involving the conserved Tyr and Lys, a water molecule stabilized by Asn, and nicotinamide. Extended SDRs have additional elements in the C-terminal region, and typically have a TGXXGXXG cofactor binding motif. Complex (multidomain) SDRs such as ketoreductase domains of fatty acid synthase have a GGXGXXG NAD(P)-binding motif and an altered active site motif (YXXXN). Fungal type ketoacyl reductases have a TGXXXGX(1-2)G NAD(P)-binding motif. Some atypical SDRs have lost catalytic activity and/or have an unusual NAD(P)-binding motif and missing or unusual active site residues. Reactions catalyzed within the SDR family include isomerization, decarboxylation, epimerization, C=N bond reduction, dehydratase activity, dehalogenation, Enoyl-CoA reduction, and carbonyl-alcohol oxidoreduction.	9.50829e-91
NZ_CP024949.1\|WP_145819980.1\|281426_282749_-\|adenylosuccinate-lyase	gnl\|CDD\|181437	PRK08470, PRK08470, adenylosuccinate lyase; Provisional.	0
NZ_CP024949.1\|WP_145819966.1\|265394_269357_-\|autotransporter-domain-containing-protein	gnl\|CDD\|111576	pfam02691, VacA, Vacuolating cyotoxin. This family consists of Vacuolating cyotoxin proteins form Proteobacteria. These proteins are an important virulence determinate in H. pylori and induce cytoplasmic vacuolation in a variety of mammalian cell lines.	0

>NZ_CP024949.1|WP_145819966.1|265394_269357_-|autotransporter-domain-containing-protein
MEIQQTHRKINRPLVSLVLAGALISTIPQESHAAFFTTVIIPAIVGGIATGTAVGTVSGLLSWGLKQAEEANKTPDKPDKVWRIQAGKGFNEFPNKEYDLYKSLLSSKIDGGWDWGNAARHYWVKGGQWNKLEVDMKDAVGTYKLSGLRNFTGGDLDVNMQKATLRLGQFNGNSFTSYKDSADRTTRVNFNAKNISIDNFVEINNRVGSGAGRKASSTVLTLQASEGITSSKNAEISLYDGATLNLASSSVKLMGNVWMGRLQYVGAYLAPSYSTINTSKVTGEVDFNHLTVGDHNAAQAGIIASNKTHIGTLDLWQSAGLNIIAPPEGGYKDKPNSTTSQSGAKNDKQEISQNNNSNTEVINPPNNTQKTETEPTQVIDGPFAGGKDTVVNIDRINTKADGTIKVGGFKASLTTNAAHLNIGKGGVNLSNQASGRTLLVENLTGNITVEGTLRVNNQVGGAAVAGSSANFEFKAGEDTNNATATFNNDIHLGKAVNLRVDAHTAYFNGNIYLGKSTNLRVNGHSAHFKNIDASKSDNGLNTSALDFSGVTDKVNINKLTTSATNVNIKNFDIKELVVTTRVQSFGQYTIFGENIGDKSRIGVVSLQTGYSPAYSGGVTFKGGKKLVIDEIYHAPWNYFDARNVTDVEINKRILFGAPGNIAGKTGLMFNNLTLNSNASMDYGKDLDLTIQGHFTNNQGTMNLFVQDGRVATLNAGHQASMIFNNLVDSSTGFYKPLIKVNNAQNLTKNKEHVLVKARNIDYNLVGVQGASYDNISASNTNLQDQFKERLALYNNNNRMDICVVRKNNTDDIKACGMAIGNQAMVNNPENYKYLEGKAWKNTGINKTANNTTIAVNLGNNSAPTSSESNTTNLPTNTTNNARFASYALIKNAPFARYSATPNLVAINQHDFGTIESVFELADRSKDIDTLYTHSGTQGRDLLQTLLIDSHDAGYARTMIDATSANEITKQLNAATTTLNNIASLEYKTSGLQTLSLSNAMILNSRLVNLSRRHTNNIDSFAKRLQALKDQRFASLESAAEVLYQFAPKYEKPTNVWANAIGGTSLNNGSNASLYGTSAGVDAYLNGEVEAIVGGFGSYGYSSFSNQANSLNSGANNTNFGVYSRIFANQHEFDFEAQGALGSDQSSLNFKSALLQDLNQSYHYLAYSATTRASYGYDFAFFRNALVLKPSVGVSYNHLGSTNFKSNSNQVALSNGSSSQHLFNANANVEARYYYGDTSYFYMNAGVLQEFARFGSNNAVSLNTFKVNATRNPLNTHARVMMGGELQLAKEVFLNLGVVYLHNLISNASHFASNLGMRYSF
>NZ_CP024949.1|WP_000242349.1|264553_265321_+|ABC-transporter-ATP-binding-protein
MVLEVKNLSFKYSQKLILDKLSFSVPKNSITSILAPNGSGKTTLLKCLLGLLKPLEETEIKACNKDILPLKPYEKAKLIAYIPQVEYYAFNFSVLDFVLMGKATHLNLFAMPKAKHIKEATSVLERLDLESLKDQGINDLSGGQRQMVLLARSLLQRTPLLLLDEPTSALDLKNQALFFDAIKDEMKKRELSVLVNIHDPNLVARHSTHVVMLKDKKLFLQASTPIAMTSHNLSALYDTPLEAIWHDNKLVVYAL
>NZ_CP024949.1|WP_000921461.1|263573_264554_+|iron-ABC-transporter-permease
MLKTYHIALACVILAVVVLLFGGESLSLEEWQEVCLNVKNHFLHNEELSSLSVIILEIRLPRVILALLVGASLSGSGVVMQTIFRNPLVDPFLLGISSGAMLGVAMAIAVVESNIAILAFFGAILASLAVLAMNRVLGNSVLSLVLSGVVLSAFLSALAGAIKFFVIPQKAQAIVVWLLGSLSLSSYKDCLIAFIGLSLGFIPLFLLRWRINLLSLSDAQSLSLGINPVLLRSLCLVCVSVASALAVSVSGTIGWIGLVIPHVARLFFGANLQKLLLSSLLMGAFFLLLADVVAKTITPYDLPVGIATSVLGAPFFLWLLFRTRGV
>NZ_CP024949.1|WP_145819964.1|262738_263581_+|SDR-family-NAD(P)-dependent-oxidoreductase
MGEKKESQKVAIITGASSGIGLECALMLLDQGYKVYALSRHATLCVALNHALCESVDIDVSDSNALKEAFSNISAKEDHCDVLINSAGYGVFGSVEDTPIEEVKKQFSVNFFALCEVVQFCLPLLKNKPYSKIFNLSSIAGRVSMLFLGHYSASKHALEAYSDALRLELKPFNVQVCLIEPGPVKSNWEKTAFENDERKDSVYALEVNAAKSFYSGVYQKALNAKAVAQKIVFLSMSQKIKARYLIGLKTQLLLALYRILPSSWYDSLFRLVVLGRKRDA
>NZ_CP024949.1|WP_001135623.1|262055_262580_-|acyl-CoA-thioesterase
MPQIQSSHSSHFDFTIDTADRTKLLMSYLVVPTTANFNNVMHGGELLNLLDKVAYVCSTRYCAKGTVTLSVDGVTFKYPIPVGNLLTFLASINYVGNTSCEVGIKVLSEDIKTREITHTNSCYFTMVAVENGKPTPMPKYEPKTEVEIRRYEGALKRKEMRTRGYLKSGKHEGV
>NZ_CP024949.1|WP_145819962.1|261680_261935_+|YafQ-family-addiction-module-toxin
MLTIETSKKFDKDLKILVKNGFDLKLLYKVVGNLAKEQPLEPKYKDHPLKGALKDFRECHIKPDVLPVYRVKDNVLTLVRLGQS
>NZ_CP024949.1|WP_145819960.1|261376_261667_+|hypothetical-protein
MPNPTAKKDYTQYSEKQLFNFLNSIKTKQKRALEKLKEIQAQKQRIKKALQFKALHLTENGYTLEEEREILARAKDTKNHLCFKSIEDFKKHCENL
>NZ_CP024949.1|WP_000271050.1|260924_261209_+|endoribonuclease-VapD
MYALAFDLKIEILKKEYGEPYNKAYDDLRQELELLGFEWTQGSVYVNYSKENTLAQVYKAINKLSQIEWFKKSVRDIRAFKVEDFSDFTEIVKS
>NZ_CP024949.1|WP_145819958.1|260551_260944_+|hypothetical-protein
MPNTTAKKDYTKYSEKQLFNLIHRLERKIKKMQNDRVSFKEKMAKELEKRDQNFRDKIDALNELLQKISQAFDDKRDCCLGRKIPNIQTQQAMKDAVNGVNLTQIDSLDDLTNELKRENNKGFENVCSSV
>NZ_CP024949.1|WP_145819956.1|257987_260156_+|Hop-family-adhesin-BabA
MLHAEDDGFYTSVGYQIGEAAQMVTNTKGIQELSDNYEKLNNLLTRYSTLNTLIKLSADPSAVNAARENLGASAKNLIGDTKNSPAYQAVLLAINAAVGFWNVLGYATQCGGNANGTKSISSTTVFNNEPGYRNTSITCSLNGYKPGYYSPMSIENFKKLNEAYQILQTALKKGLPALKENNGTVNVTYTYTCSGEGNNNCSPQTTGVEQNGTKTKTQTIDGKTVTTTISSKVVNDGKETNKGSSYTEITNKLESVPDSAQALLAQASTLINTINTACPYFSVTNKHDGPQMEPTRGKLCGFTEEISAIQKMITDAQELVNQTSTINSNKQSTPVGNNNGKPFNPFTDASFAQGMLANASAQAKMLNLAHQVGQTINPENLTGNFQNFVKNFLATCTNKSTAHTDGEQGSPPGTVTTQTFASGCAYVGETITALTNSIAHFGTQAEQIQQAENIADTLVNFKSRYNELGNTYNSITTALSKVPNAQSLQNVVSKKNNPYSPQGIETNYYLNQNSYNQIQTINQELGRNPFRKVGIVSSQTNNGAMNGIGIQVGYKQFFGQKRKWGARYYGFFDYNHAFIKSSFFNSASDVWTYGFGADALYNFINDKATNFLGKNNKLSVGLFGGIALAGTSWLNSEYVNLATVNNVYNAKMNVANFQFLFNMGVRMNLARPKKKDSDHAAQHGIELGLKIPTINTNYYSFMGAELKYRRLYSVYLNYVFAY
>NZ_CP024949.1|WP_145819968.1|269643_271041_-|cysteine--tRNA-ligase
MFIYDTKLKQKVPFEPLVQNKANIYVCGPTVYDDAHLGHARSAIAFDLLRRTLEWSGYEVMLVRNFTDIDDKIINKAFKENKSIQELSSIYIESYTRDLNALNVKKPSLEPKASEYLDAMVRMIETLLEKNIAYRVSNGDIYLDTSKDKDYGSLSVHNSSMEFSRIGLVQEKRLEQDFVLWKSYKGDNDVGFDSPLGKGRPGWHIECSSMVFETLALANAPYQIDIHAGGADLLFPHHENEACQTRCAFGVELAKYWMHNGFVNINNEKMSKSLGNSFFIKDALKNYDGEILRNYLLGVHYRSVLNFNEEDLLVSKKRLDKIYRLKQRVLGTLGGINPNFKKEILECMQDDLNVSKALSILESMLSSTNEKLDQNPKNKALKGEILANLKFIEELLGIGFKDPSAYFQLGVSESEKQEIEKKIEERKRAKEQKDFLKADSIREELLNHKIALMDTPQGTIWEKLF
>NZ_CP024949.1|WP_145819970.1|271041_272502_-|murein-biosynthesis-integral-membrane-protein-MurJ
MLKKIFLTNSLGILCSRIFGFLRDLMMANILGAGVYSDIFFVAFKLPNLFRRIFAEGSFSQSFLPSFIRSSIKGSFASLVGLIFCGVLLVWCLLVALNPLWLTKLLAYGFNEETLKLCAPIVAINFWYLLLVFITTFLGTLLQYKHSFFASAYSASLLNLCMILALLISKEKTHLEALYYLSYGVLLGGVAQILLHFYPLVKLGLLNLLFKGFLSFKTKNAAKKKYRSKKVKKDLKGFFKQFLPSVLGNSSAQIASFLDTTIASFLASGSVSYLYYANRVFQLPLALFAIAISTALFPSIAIAIKNNQQDLILQRLQKAWFFLVGVLLLCSIGGIMLSKEITELLFERGQFSPKDTLITSQVFSLYLLGLLPFGLTKLFSLWLYAKLEQKKAAKISLISLFLGLAASLSLMPLLGVLGLALANSLSGLFLFVLTIKAFGFQLFLGIIKNLKSWLVILFLACVEILLLLAFKSWVTHLYLFYYFQGF
>NZ_CP024949.1|WP_145819972.1|272594_274439_+|DUF342-domain-containing-protein
MSLEHFAPIKVERCKDIQKELKKAAAENKLQTEDLWFEILKTSIFIKNSAKDDFSEAFGGELQQLEEDEYYEKKELALYQTHDIKIKSNAYKRFFEVQVDEDLSKIEIILDECFIVLDTEEHYQEMFAYIKECLAFEGVVFRHLSQMYENLKTELRKYQKEAQNKRFILYASLTFIPNTEEKSHFLLEEEYLPTHTIFLSDQEESFVKENDYIAKENQKVACVNYPKQGRDGRNLKGLYIELPKVAHSPTPIGHDKNAFEEREENNALVYYSKALQGVKMEKGRLVSKQNFIFKNGIKSIETPNLLGGVESGLALEIQAKDELSDAIDSNLILEASAINIKGNVGKNVILVAKEITIEGQIHPESYVYANKARITNHKGVCYAKEFECKYLERAKVYANSVKVEASAGSVVYAKEIALEKLKSDNKLYFSKQCLIDEVDGNGNRFIFYAFGGRENQEELKTAKQKLNALGLKSKKIIAQHQSLNHLVKNHQAIMEKLKNATEEIKRSLMQQESVKDAYSEFMFALKRLKILKAQMLELQKINNECYAKLISIENSFQHASITTKNPFKQENIVIYHRNYPKVSNSTAMLSHNESVNVIYEDHKIKKIPKSAIKG
>NZ_CP024949.1|WP_015644167.1|274465_275017_+|Holliday-junction-branch-migration-protein-RuvA
MIVGLIGVVEKISALEAHIEVQGVVYGVQVSMRTAALLQAGQKARLKILQVIKEDAHLLYGFLEESEKILFERLLKINGVGGRIALAILSSFSPNEFENIIATKEVKRLQQVPGIGKKLADKIMVDLIGFFIQDENKPARNEVFLALESLGFKSAEINQVLKTLKPNLSIEAAIKEALQQLRS
>NZ_CP024949.1|WP_145819976.1|277856_278477_+|DUF1542-domain-containing-protein
MINYPNLPNSDLEITEQPEVKEITNELLKQLQNALHSNALFTDQIKLSLKGIVRILEVLLSLDFFKNANEIDSSLRNSIEWLSNAGESLKLKMKEYEGFFSDFNTSMKANEQEVTSILNANTENIKSEIKKLENQLIETTTRLLTSYQIFLNKARENANNEITANKTESLEAIAQAKTSANNEINTKQTQAITNINEAKNLSLSKH
>NZ_CP024949.1|WP_121098477.1|278546_280523_+|excinuclease-ABC-subunit-B
MPLFDLKSPYPPAGDQPQAIEALTKSLKNNNHYQTLVGVTGSGKTYTMANIIAQTNKPALIMSHNKTLCAQLYSEFKAFFPHNRVEYFISHFDYYQPESYIPRRDLFIEKDSSINDDLERLRLSATTSLLGYDDVIVIASVSANYGLGNPEEYLKVMEKIKVGEKRAYKSFLLKLVEMGYSRNEVVFDRGSFRATGECVDIFPAYNDAEFIRIEFFGDEIERIAVFDALERNEIKRLDSVMLYAASQFAVGSERLNLAIKSIEDELALRLKFFKEQDKMLEYNRLKQRTEHDLEMISATGVCKGIENYARHFTGKAPNETPFCLFDYLGIFEREFLVIVDESHVSLPQFGGMYAGDMSRKSVLVEYGFRLPSALDNRPLKFDEFIHKNCQFLFVSATPNKLELELSKKNVAEQIIRPTGLLDPKFEVRDSDKQVQDLFDEIKLVVARDERVLITTLTKKMAEELCKYYAEWGLKARYMHSEIDAIERNHIIRSLRLKEFDILIGINLLREGLDLPEVSLVAIMDADKEGFLRSETSLIQTMGRAARNANGKVLLYAKKITQSMQKAFEITSYRRAKQEEFNKIHNITPKTVTRALEEELKLRDDEIRIAKALKKDKMPKSEREKIIKELDKKMRECAKNLDFEEAMRLRDEIAKLRTL
>NZ_CP024949.1|WP_145819978.1|280527_281361_-|outer-membrane-beta-barrel-protein
MKRALCLVLGLFCALNAKGFKDVLTKGDYTFFNKKVVSPIKRYADRSAFYLGLGYQLGSIQHNSSNLNLSQQFNKSQIVFSDGLSPVFKNSYVSNGLGVQVGYKWVGKHEETKWFGFRWGLFYDLSASLYGLKESQSVIISTYGTYMDLLLNAYNGDKFFAGFNLGIAFAGVHDKVSDELLYQTLLLDTFGGKVNLNGFQFLVDLGVRLGSKHNQFGFGIKVPTYYFNHYYSMNNISNNSGDVLKVLRFLEYGINSLLYQVDFRHNYSVYFNYTYSF
>NZ_CP024949.1|WP_145819980.1|281426_282749_-|adenylosuccinate-lyase
MLERYANEEMKALWNEQTKFETYLEVEKAVVRAWNKLGQIQDSDCEKICSKAAFNLEHIKEIEKTTKHDLIAFTTCVAESLGEESRFFHYGITSSDCIDTAMALLMTKSLKLIQKGVQNLYETLKNRALEHKDTLMVGRSHGVFGEPITFGLVLALFADEIKRHLKALDLTMEFISVGAISGAMGNFAHAPLELEELACEFLGLKTANINNQVIQRDRYARLACDLALLASSCEKIAVNIRHLQRSEVYEVEEAFSTGQKGSSAMPHKRNPILSENITGLCRVIRSFTTPMLENVALWHERDMSHSSVERFALPDLFITSDFMLSRLNSVIKNLVVYPKNMLKNLALSGGLVFSQRVLLELPKKGLSREESYSIVQENAMKIWEVLQQGAFKNADENLFLNALLNDERLKKYLSEDEIKACFDYSYYTKNVGAIFKRVFE
>NZ_CP024949.1|WP_145819982.1|282856_283801_-|pyruvate-ferredoxin-oxidoreductase
MIKEVKTLKGFSQSAEKFQGSHLLCPGCGHGIIVREVLNAVDGPIVLGNSTGCLEVCSAVYPHTSWDVPWIHIGFENGSTAISGVEAMYKALANKGRYQGQKPKFVAFGGDGASYDIGLQFISGCMERGHDMTYICLDNENYANTGGQRSGSTPLGASTSTTPAGSVSFGKKEKKKDIVNIMASHGVPYVAQLSPNKWKDMNKKIKTALDTEGPCFINALSPCTTEWKFESNKTIELADMAVDSLMFPLFEIFNGMELKITYRPRNIIPVRDYLGAQKRFKHLFKKENEHIIEELQKDVNERWEYLQRREEAKV
>NZ_CP024949.1|WP_145819984.1|283813_285037_-|2-oxoacid:ferredoxin-oxidoreductase-subunit-alpha
MAKSIELQEIEVWDGNTASSNALRQAQIDVIAAYPITPSTPIVQNYGSFKDNGYIDGEFVLVESEHAAMSACVGAAAAGGRVSTATSSQGLALMVEVLYQASGMRLPIVLNLVNRALAAPLNIHGDHSDMYLSRDSGWISLCTCNPQEAYDFTLMAFRIAEHQKVRVPTIVNQDGFLCSHTVQNVRPLSDAVAYQFVGEYQTKHSLLDFDKPVSYGAQAEEEWHYEHKAQLHHAIMSASSVIEEVFNDFAKLTGRQYYLTKTFQLEDAEIAIFALGTTYESAIVAAKEMRKKGIKAGVATIHSLRPFPYERLGQDLKNLKALAILDKSSPAGAMGAMFNEVTSAVYQTQGTKHPVVSNYIYGLGERDMTIAHLCEIFEEINEDALKGTLTHPTQQFVGLRGPKMSFF

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Crispr_ID: NZ_CP024949_2

CRISPR_ID

CRISPR_location

CRISPR_type

Repeat_type

Spacer_info

Cas_protein_info

CRISPR-Cas_info

NZ_CP024949_2

289502-289587

Orphan

Consensus_repeat	Method
GTTCTTGAACCACTACTTCTCGCATG	CRISPRCasFinder

1 spacers

The CRISPR arrays of NZ_CP024949_2

>merge|NZ_CP024949|2|289502-289587|CRISPRCasFinder
GTTCTTGAACCACTACTTCTCGCATGCCCATGCAGAGATCAAAGAAAACTCCCTTGAAGCGTTCTTGAACCACTACTTCTCGCATG

>NZ_CP024949|2|2|289502-289587|CRISPRCasFinder
GTTCTTGAACCACTACTTCTCGCATG	CCCATGCAGAGATCAAAGAAAACTCCCTTGAAGC
GTTCTTGAACCACTACTTCTCGCATG

Protein	Signature genes	Signature genes Name	Protein_function
NZ_CP024949.1\|WP_145819996.1\|295849_296470_+\|bifunctional-4-hydroxy-2-oxoglutarate-aldolase/2-dehydro-3-deoxy-phosphogluconate-aldolase	unknown	unknown	gnl\|CDD\|273490
NZ_CP024949.1\|WP_145820002.1\|298399_299935_-\|hypothetical-protein	unknown	unknown	unknown
NZ_CP024949.1\|WP_145819984.1\|283813_285037_-\|2-oxoacid:ferredoxin-oxidoreductase-subunit-alpha	unknown	unknown	gnl\|CDD\|181999
NZ_CP024949.1\|WP_145819992.1\|292661_293939_-\|glucose-6-phosphate-dehydrogenase	unknown	unknown	gnl\|CDD\|223441
NZ_CP024949.1\|WP_145819986.1\|286962_288270_-\|hypothetical-protein	unknown	unknown	unknown
NZ_CP024949.1\|WP_145819976.1\|277856_278477_+\|DUF1542-domain-containing-protein	unknown	unknown	unknown
NZ_CP024949.1\|WP_145819982.1\|282856_283801_-\|pyruvate-ferredoxin-oxidoreductase	unknown	unknown	gnl\|CDD\|239471
NZ_CP024949.1\|WP_145820000.1\|297629_298382_-\|SDR-family-NAD(P)-dependent-oxidoreductase	unknown	unknown	gnl\|CDD\|187604
NZ_CP024949.1\|WP_145819990.1\|291967_292651_-\|6-phosphogluconolactonase	unknown	unknown	gnl\|CDD\|273494
NZ_CP024949.1\|WP_145819994.1\|294004_295831_+\|phosphogluconate-dehydratase	unknown	unknown	gnl\|CDD\|130264
NZ_CP024949.1\|WP_000486466.1\|285454_286015_-\|pyruvate-flavodoxin-oxidoreductase-subunit-gamma	unknown	unknown	gnl\|CDD\|180284
NZ_CP024949.1\|WP_000656174.1\|285046_285439_-\|4Fe-4S-dicluster-domain-containing-protein	unknown	unknown	gnl\|CDD\|236596
NZ_CP024949.1\|WP_145820004.1\|300668_301703_+\|UDP-glucose-4-epimerase-GalE	unknown	unknown	gnl\|CDD\|273487
NZ_CP024949.1\|WP_145819978.1\|280527_281361_-\|outer-membrane-beta-barrel-protein	unknown	unknown	gnl\|CDD\|280099
NZ_CP024949.1\|WP_145819998.1\|296544_297417_+\|Sel1-like-repeat-protein-HcpC	unknown	unknown	gnl\|CDD\|223861
NZ_CP024949.1\|WP_121098477.1\|278546_280523_+\|excinuclease-ABC-subunit-B	unknown	unknown	gnl\|CDD\|235395
NZ_CP024949.1\|WP_001126912.1\|290970_291981_-\|glucokinase	unknown	unknown	gnl\|CDD\|129832
NZ_CP024949.1\|WP_145819980.1\|281426_282749_-\|adenylosuccinate-lyase	unknown	unknown	gnl\|CDD\|181437
NZ_CP024949.1\|WP_145819989.1\|289763_290810_-\|alcohol-dehydrogenase-catalytic-domain-containing-protein	unknown	unknown	gnl\|CDD\|176186
NZ_CP024949.1\|WP_021174749.1\|286293_286956_+\|outer-membrane-protein	unknown	unknown	gnl\|CDD\|280099

Protein	Function_ID	Function_description	E-value
NZ_CP024949.1\|WP_145819996.1\|295849_296470_+\|bifunctional-4-hydroxy-2-oxoglutarate-aldolase/2-dehydro-3-deoxy-phosphogluconate-aldolase	gnl\|CDD\|273490	TIGR01182, KHG/KDPG_aldolase_., Entner-Doudoroff aldolase. 2-deydro-3-deoxyphosphogluconate aldolase (EC 4.1.2.14) is an enzyme of the Entner-Doudoroff pathway. This aldolase has another function, 4-hydroxy-2-oxoglutarate aldolase (EC 4.1.3.16) shown experimentally in Escherichia coli and Pseudomonas putida [Amino acid biosynthesis, Glutamate family, Energy metabolism, Entner-Doudoroff].	7.82184e-111
NZ_CP024949.1\|WP_145819984.1\|283813_285037_-\|2-oxoacid:ferredoxin-oxidoreductase-subunit-alpha	gnl\|CDD\|181999	PRK09622, porA, 2-oxoacid:ferredoxin oxidoreductase subunit alpha.	0
NZ_CP024949.1\|WP_145819992.1\|292661_293939_-\|glucose-6-phosphate-dehydrogenase	gnl\|CDD\|223441	COG0364, Zwf, Glucose-6-phosphate 1-dehydrogenase [Carbohydrate transport and metabolism].	0
NZ_CP024949.1\|WP_145820004.1\|300668_301703_+\|UDP-glucose-4-epimerase-GalE	gnl\|CDD\|273487	TIGR01179, UDP-glucose_4-epimerase, UDP-glucose-4-epimerase GalE. Alternate name: UDPgalactose 4-epimerase This enzyme interconverts UDP-glucose and UDP-galactose. A set of related proteins, some of which are tentatively identified as UDP-glucose-4-epimerase in Thermotoga maritima, Bacillus halodurans, and several archaea, but deeply branched from this set and lacking experimental evidence, are excluded from this model and described by a separate model. [Energy metabolism, Sugars].	0
NZ_CP024949.1\|WP_145819982.1\|282856_283801_-\|pyruvate-ferredoxin-oxidoreductase	gnl\|CDD\|239471	cd03376, TPP_PFOR_porB_like, Thiamine pyrophosphate (TPP family), PFOR porB-like subfamily, TPP-binding module; composed of proteins similar to the beta subunit (porB) of the Helicobacter pylori four-subunit pyruvate ferredoxin oxidoreductase (PFOR), which are also found in archaea and some hyperthermophilic bacteria. PFOR catalyzes the oxidative decarboxylation of pyruvate to form acetyl-CoA, a crucial step in many metabolic pathways. Archaea, anaerobic bacteria and eukaryotes that lack mitochondria (and therefore pyruvate dehydrogenase) use PFOR to oxidatively decarboxylate pyruvate, with ferredoxin or flavodoxin as the electron acceptor. The 36-kDa porB subunit contains the binding sites for the cofactors, TPP and a divalent metal cation, which are required for activity.	5.0765e-135
NZ_CP024949.1\|WP_145820000.1\|297629_298382_-\|SDR-family-NAD(P)-dependent-oxidoreductase	gnl\|CDD\|187604	cd05346, SDR_c5, classical (c) SDR, subgroup 5. These proteins are members of the classical SDR family, with a canonical active site tetrad and a typical Gly-rich NAD-binding motif. SDRs are a functionally diverse family of oxidoreductases that have a single domain with a structurally conserved Rossmann fold (alpha/beta folding pattern with a central beta-sheet), an NAD(P)(H)-binding region, and a structurally diverse C-terminal region. Classical SDRs are typically about 250 residues long, while extended SDRs are approximately 350 residues. Sequence identity between different SDR enzymes are typically in the 15-30% range, but the enzymes share the Rossmann fold NAD-binding motif and characteristic NAD-binding and catalytic sequence patterns. These enzymes catalyze a wide range of activities including the metabolism of steroids, cofactors, carbohydrates, lipids, aromatic compounds, and amino acids, and act in redox sensing. Classical SDRs have an TGXXX[AG]XG cofactor binding motif and a YXXXK active site motif, with the Tyr residue of the active site motif serving as a critical catalytic residue (Tyr-151, human 15-hydroxyprostaglandin dehydrogenase (15-PGDH) numbering). In addition to the Tyr and Lys, there is often an upstream Ser (Ser-138, 15-PGDH numbering) and/or an Asn (Asn-107, 15-PGDH numbering) contributing to the active site; while substrate binding is in the C-terminal region, which determines specificity. The standard reaction mechanism is a 4-pro-S hydride transfer and proton relay involving the conserved Tyr and Lys, a water molecule stabilized by Asn, and nicotinamide. Extended SDRs have additional elements in the C-terminal region, and typically have a TGXXGXXG cofactor binding motif. Complex (multidomain) SDRs such as ketoreductase domains of fatty acid synthase have a GGXGXXG NAD(P)-binding motif and an altered active site motif (YXXXN). Fungal type ketoacyl reductases have a TGXXXGX(1-2)G NAD(P)-binding motif. Some atypical SDRs have lost catalytic activity and/or have an unusual NAD(P)-binding motif and missing or unusual active site residues. Reactions catalyzed within the SDR family include isomerization, decarboxylation, epimerization, C=N bond reduction, dehydratase activity, dehalogenation, Enoyl-CoA reduction, and carbonyl-alcohol oxidoreduction.	6.04339e-145
NZ_CP024949.1\|WP_145819990.1\|291967_292651_-\|6-phosphogluconolactonase	gnl\|CDD\|273494	TIGR01198, 6-phosphogluconolactonase_6PGL., 6-phosphogluconolactonase. This enzyme of the pentose phosphate pathway is often found as a part of a multifunctional protein with [Energy metabolism, Pentose phosphate pathway].	4.78113e-93
NZ_CP024949.1\|WP_145819994.1\|294004_295831_+\|phosphogluconate-dehydratase	gnl\|CDD\|130264	TIGR01196, Phosphogluconate_dehydratase, 6-phosphogluconate dehydratase. A close homolog, designated MocB (mannityl opine catabolism), is found in a mannopine catabolism region of a plasmid of Agrobacterium tumefaciens. However, it is not essential for mannopine catabolism, branches within the cluster of 6-phosphogluconate dehydratases (with a short branch length) in a tree rooted by the presence of other dehydyatases. It may represent an authentic 6-phosphogluconate dehydratase, redundant with the chromosomal copy shown to exist in plasmid-cured strains. This model includes mocB above the trusted cutoff, although the designation is somewhat tenuous. [Energy metabolism, Entner-Doudoroff].	0
NZ_CP024949.1\|WP_000486466.1\|285454_286015_-\|pyruvate-flavodoxin-oxidoreductase-subunit-gamma	gnl\|CDD\|180284	PRK05844, PRK05844, pyruvate flavodoxin oxidoreductase subunit gamma; Validated.	3.48516e-128
NZ_CP024949.1\|WP_000656174.1\|285046_285439_-\|4Fe-4S-dicluster-domain-containing-protein	gnl\|CDD\|236596	PRK09625, porD, pyruvate flavodoxin oxidoreductase subunit delta; Reviewed.	5.72644e-84
NZ_CP024949.1\|WP_145819978.1\|280527_281361_-\|outer-membrane-beta-barrel-protein	gnl\|CDD\|280099	pfam01856, HP_OMP, Helicobacter outer membrane protein. This family seems confined to Helicobacter. It is predicted to be an outer membrane protein based on its pattern of alternating hydrophobic amino acids similar to porins.	6.56886e-33
NZ_CP024949.1\|WP_145819998.1\|296544_297417_+\|Sel1-like-repeat-protein-HcpC	gnl\|CDD\|223861	COG0790, COG0790, FOG: TPR repeat, SEL1 subfamily [General function prediction only].	1.07699e-46
NZ_CP024949.1\|WP_121098477.1\|278546_280523_+\|excinuclease-ABC-subunit-B	gnl\|CDD\|235395	PRK05298, PRK05298, excinuclease ABC subunit UvrB.	0
NZ_CP024949.1\|WP_001126912.1\|290970_291981_-\|glucokinase	gnl\|CDD\|129832	TIGR00749, Glucokinase_Glucose_kinase., glucokinase, proteobacterial type. This model represents glucokinase of E. coli and close homologs, mostly from other proteobacteria, presumed to have equivalent function. This glucokinase is more closely related to a number of uncharacterized paralogs than to the glucokinase glcK (fromerly yqgR) of Bacillus subtilis and its closest homologs, so the two sets are represented by separate models. [Energy metabolism, Glycolysis/gluconeogenesis].	0
NZ_CP024949.1\|WP_145819980.1\|281426_282749_-\|adenylosuccinate-lyase	gnl\|CDD\|181437	PRK08470, PRK08470, adenylosuccinate lyase; Provisional.	0
NZ_CP024949.1\|WP_145819989.1\|289763_290810_-\|alcohol-dehydrogenase-catalytic-domain-containing-protein	gnl\|CDD\|176186	cd05283, CAD1, Cinnamyl alcohol dehydrogenases (CAD). Cinnamyl alcohol dehydrogenases (CAD), members of the medium chain dehydrogenase/reductase family, reduce cinnamaldehydes to cinnamyl alcohols in the last step of monolignal metabolism in plant cells walls. CAD binds 2 zinc ions and is NADPH- dependent. CAD family members are also found in non-plant species, e.g. in yeast where they have an aldehyde reductase activity. The medium chain dehydrogenases/reductase (MDR)/zinc-dependent alcohol dehydrogenase-like family, which contains the zinc-dependent alcohol dehydrogenase (ADH-Zn) and related proteins, is a diverse group of proteins related to the first identified member, class I mammalian ADH. MDRs display a broad range of activities and are distinguished from the smaller short chain dehydrogenases (~ 250 amino acids vs. the ~ 350 amino acids of the MDR). The MDR proteins have 2 domains: a C-terminal NAD(P) binding-Rossmann fold domain of a beta-alpha form and an N-terminal catalytic domain with distant homology to GroES. The MDR group contains a host of activities, including the founding alcohol dehydrogenase (ADH), quinone reductase, sorbitol dehydrogenase, formaldehyde dehydrogenase, butanediol DH, ketose reductase, cinnamyl reductase, and numerous others. The zinc-dependent alcohol dehydrogenases (ADHs) catalyze the NAD(P)(H)-dependent interconversion of alcohols to aldehydes or ketones. Active site zinc has a catalytic role, while structural zinc aids in stability. ADH-like proteins typically form dimers (typically higher plants, mammals) or tetramers (yeast, bacteria), and generally have 2 tightly bound zinc atoms per subunit. The active site zinc is coordinated by a histidine, two cysteines, and a water molecule. The second zinc seems to play a structural role, affects subunit interactions, and is typically coordinated by 4 cysteines.	9.74826e-163
NZ_CP024949.1\|WP_021174749.1\|286293_286956_+\|outer-membrane-protein	gnl\|CDD\|280099	pfam01856, HP_OMP, Helicobacter outer membrane protein. This family seems confined to Helicobacter. It is predicted to be an outer membrane protein based on its pattern of alternating hydrophobic amino acids similar to porins.	7.25063e-36

>NZ_CP024949.1|WP_145819986.1|286962_288270_-|hypothetical-protein
MIFLKKSLCALLFSGFFIPPLIKAASFVYDLKFMSFNFNLVAPNNNPYWNSLTKMQGRLMPQIGVQLDKRQALMFGAWFIQNLHTHYSYFPYSWGVTMYYQYIGKNLRFFLGIVPRSYQIGHYPLSAFKKLFWFIDPTFRGGAFQFKPAYDPNRWWNGWFEGVVDWYGGRNWNNQPKKKNYDFDQFLYFVSSEFQFLKGYLGLGGQLVIFHNASPHSMGDNYPYGGNSYLKPGDATPQWPNGYPYFSQKNNPQGGEIGKYSNPTILDRVYYHAYLKADFKNLMPYMDNIFMTFGTQSSQTHYCVRHASECKNARFYNSFGGEFYAQAQYKGFGIFNRYYFSNKPQMHFYATYGQSLYTGLPWYRAPNFDMIGLYYVYKNKWVSVRADAFFNFLGGGDGYHLYGKGGKWITTYQQFLTLTIDTRELIDFVKSKTSK
>NZ_CP024949.1|WP_021174749.1|286293_286956_+|outer-membrane-protein
MNKTTVKILMGMALLSSLQAAEAELDEKSKKPKFADRNTFYLGVGYQLSAINTSFSTESVDKSYFMTGNGFGVVLGGKFVAKTQAVEHVGFRYGLFYDQTFSSHKSYISTYGLEFSGLWDAFNSPKMFLGLEFGLGIAGATYMPGGAMHGIIAQNLGKENSLFQLLVKVGFRFGFLHNEITFGLKFPFIPNKRTEIIDGLSATTLWHRLPVAYFNYIYNF
>NZ_CP024949.1|WP_000486466.1|285454_286015_-|pyruvate-flavodoxin-oxidoreductase-subunit-gamma
MFQIRWHARAGQGAITGAKGLADVISKTGKEVQAFASYGSAKRGAAMMAYNRVDDEPILNHERFMQPDYVLVIDPGLVFIENIFANEKEDTTYIITSYLNKEELFEKKPELKTRKVFLVDCLKISMETLKRPIPNTPMLGALMKVSGMLEIEAFKEAFKKVLGKKLTQEVIDANMLAIQRAYEEVQ
>NZ_CP024949.1|WP_000656174.1|285046_285439_-|4Fe-4S-dicluster-domain-containing-protein
MKDWNEFEMGAVLFPFEKNAQSEMEKHNDERHYTEQSYFTTSVAHWRVAKPVHNNNICINCFNCWVYCPDAAILSREGKLKGVDYSHCKGCGVCVDVCPTNPKSLWMFEEQIEPATALTQWPQKQEKKKS
>NZ_CP024949.1|WP_145819984.1|283813_285037_-|2-oxoacid:ferredoxin-oxidoreductase-subunit-alpha
MAKSIELQEIEVWDGNTASSNALRQAQIDVIAAYPITPSTPIVQNYGSFKDNGYIDGEFVLVESEHAAMSACVGAAAAGGRVSTATSSQGLALMVEVLYQASGMRLPIVLNLVNRALAAPLNIHGDHSDMYLSRDSGWISLCTCNPQEAYDFTLMAFRIAEHQKVRVPTIVNQDGFLCSHTVQNVRPLSDAVAYQFVGEYQTKHSLLDFDKPVSYGAQAEEEWHYEHKAQLHHAIMSASSVIEEVFNDFAKLTGRQYYLTKTFQLEDAEIAIFALGTTYESAIVAAKEMRKKGIKAGVATIHSLRPFPYERLGQDLKNLKALAILDKSSPAGAMGAMFNEVTSAVYQTQGTKHPVVSNYIYGLGERDMTIAHLCEIFEEINEDALKGTLTHPTQQFVGLRGPKMSFF
>NZ_CP024949.1|WP_145819982.1|282856_283801_-|pyruvate-ferredoxin-oxidoreductase
MIKEVKTLKGFSQSAEKFQGSHLLCPGCGHGIIVREVLNAVDGPIVLGNSTGCLEVCSAVYPHTSWDVPWIHIGFENGSTAISGVEAMYKALANKGRYQGQKPKFVAFGGDGASYDIGLQFISGCMERGHDMTYICLDNENYANTGGQRSGSTPLGASTSTTPAGSVSFGKKEKKKDIVNIMASHGVPYVAQLSPNKWKDMNKKIKTALDTEGPCFINALSPCTTEWKFESNKTIELADMAVDSLMFPLFEIFNGMELKITYRPRNIIPVRDYLGAQKRFKHLFKKENEHIIEELQKDVNERWEYLQRREEAKV
>NZ_CP024949.1|WP_145819980.1|281426_282749_-|adenylosuccinate-lyase
MLERYANEEMKALWNEQTKFETYLEVEKAVVRAWNKLGQIQDSDCEKICSKAAFNLEHIKEIEKTTKHDLIAFTTCVAESLGEESRFFHYGITSSDCIDTAMALLMTKSLKLIQKGVQNLYETLKNRALEHKDTLMVGRSHGVFGEPITFGLVLALFADEIKRHLKALDLTMEFISVGAISGAMGNFAHAPLELEELACEFLGLKTANINNQVIQRDRYARLACDLALLASSCEKIAVNIRHLQRSEVYEVEEAFSTGQKGSSAMPHKRNPILSENITGLCRVIRSFTTPMLENVALWHERDMSHSSVERFALPDLFITSDFMLSRLNSVIKNLVVYPKNMLKNLALSGGLVFSQRVLLELPKKGLSREESYSIVQENAMKIWEVLQQGAFKNADENLFLNALLNDERLKKYLSEDEIKACFDYSYYTKNVGAIFKRVFE
>NZ_CP024949.1|WP_145819978.1|280527_281361_-|outer-membrane-beta-barrel-protein
MKRALCLVLGLFCALNAKGFKDVLTKGDYTFFNKKVVSPIKRYADRSAFYLGLGYQLGSIQHNSSNLNLSQQFNKSQIVFSDGLSPVFKNSYVSNGLGVQVGYKWVGKHEETKWFGFRWGLFYDLSASLYGLKESQSVIISTYGTYMDLLLNAYNGDKFFAGFNLGIAFAGVHDKVSDELLYQTLLLDTFGGKVNLNGFQFLVDLGVRLGSKHNQFGFGIKVPTYYFNHYYSMNNISNNSGDVLKVLRFLEYGINSLLYQVDFRHNYSVYFNYTYSF
>NZ_CP024949.1|WP_121098477.1|278546_280523_+|excinuclease-ABC-subunit-B
MPLFDLKSPYPPAGDQPQAIEALTKSLKNNNHYQTLVGVTGSGKTYTMANIIAQTNKPALIMSHNKTLCAQLYSEFKAFFPHNRVEYFISHFDYYQPESYIPRRDLFIEKDSSINDDLERLRLSATTSLLGYDDVIVIASVSANYGLGNPEEYLKVMEKIKVGEKRAYKSFLLKLVEMGYSRNEVVFDRGSFRATGECVDIFPAYNDAEFIRIEFFGDEIERIAVFDALERNEIKRLDSVMLYAASQFAVGSERLNLAIKSIEDELALRLKFFKEQDKMLEYNRLKQRTEHDLEMISATGVCKGIENYARHFTGKAPNETPFCLFDYLGIFEREFLVIVDESHVSLPQFGGMYAGDMSRKSVLVEYGFRLPSALDNRPLKFDEFIHKNCQFLFVSATPNKLELELSKKNVAEQIIRPTGLLDPKFEVRDSDKQVQDLFDEIKLVVARDERVLITTLTKKMAEELCKYYAEWGLKARYMHSEIDAIERNHIIRSLRLKEFDILIGINLLREGLDLPEVSLVAIMDADKEGFLRSETSLIQTMGRAARNANGKVLLYAKKITQSMQKAFEITSYRRAKQEEFNKIHNITPKTVTRALEEELKLRDDEIRIAKALKKDKMPKSEREKIIKELDKKMRECAKNLDFEEAMRLRDEIAKLRTL
>NZ_CP024949.1|WP_145819976.1|277856_278477_+|DUF1542-domain-containing-protein
MINYPNLPNSDLEITEQPEVKEITNELLKQLQNALHSNALFTDQIKLSLKGIVRILEVLLSLDFFKNANEIDSSLRNSIEWLSNAGESLKLKMKEYEGFFSDFNTSMKANEQEVTSILNANTENIKSEIKKLENQLIETTTRLLTSYQIFLNKARENANNEITANKTESLEAIAQAKTSANNEINTKQTQAITNINEAKNLSLSKH
>NZ_CP024949.1|WP_145819989.1|289763_290810_-|alcohol-dehydrogenase-catalytic-domain-containing-protein
MRVPSKGFAIFSKDGHFKPHDFSRHAVGPKDVLIDILYAGICHSDVHSAYSEWKEGIYPMVPGHEIAGVIKEVGKEVKKFKVGDVVGVGCFVNSCKTCKPCKEHQEQFCTKVVFTYDCLDSFHDNEPHMGGYSNNIVVDENYVISVDKNAPLEKVAPLLCAGITTYSPLKFSKVTKGTKVGVAGFGGLGSMAVKYAVAMGAEVSVFARNEHKKQDALSIGVKHFYTDPKQCKEELDFIISTIPTHYDLKDYLKLLTYNGDLALVGLPPVEVAPALNVFEFIHLGNRKVYGSLIGGIKETQEMMDFSIKHNIYPEVDLILGKDIDTAYHNLTHGKAKFRYVIDMKKSFD
>NZ_CP024949.1|WP_001126912.1|290970_291981_-|glucokinase
MPKTETYPRLLADIGGTNARFGLEVAPRQIECVEVLRCEDFESLSDAVRFYLSKCKESLKLHPIYGSFAVATPIMGDFVQMTNNHWTFSIETTRQCLNLKKLLVINDFVAQAYAISAMQENDLAQIGGIKCEINAPKAILGPGTGLGVSTLIQNSDGSLKVLPGEGGHVSFAPFDDLEILVWQYARSKFNHVSAERFLSGSGLVLIYEALSKRKGLEKVAKLSKAELTPQIISERALNGDYPICRLTLDTFCSMLGTLAADVALTLGARGGVYLCGGIIPRFIDYFKTSPFRARFETKGRMGAFLASIPVHVVMKKTPGLDGAGIALENYLLHDKI
>NZ_CP024949.1|WP_145819990.1|291967_292651_-|6-phosphogluconolactonase
MGYQLFEFESLKDCHKALIDRFKEFFNNALKKHHQVSIAFSGGRSPISLLQKLSVLDLKWHECSISLVDERIIDTSHKDSNTKLLHDYLLQNNALKASFIPLLPKKISSDTNALFHFANQHFKQPHLAILGMGTDGHTASLFPETSAFLNEEKENIVLTKPINAPYERLSMSVNALENCEKLFLSISGAEKRGVLEKALKENAPYSLPIARILHSQKVTTEVFYAKN
>NZ_CP024949.1|WP_145819992.1|292661_293939_-|glucose-6-phosphate-dehydrogenase
MLDFGLVLFGATGDLAMRKLFVSLYEIYTHYGFKNDSRIIASGRKELSNEEFLTLLCEKTQLHSREKGREFLAHISYFCVRLDNPKDFEELSKIATKNKPLIFYFSISPSFFATTAQHLAKNALNHANTRLILEKPLGHDLKTCKEIFQSISAFFKEEQIFRIDHYLGKKGVQNILELRLNNPILNILWDQISAVEICVYETLGVEERGEFYDKIGALRDMVQNHLLQVLSLIATDLPNDLKDLRQEKIKVLKTLQPPKDFKKQVIRAQYQGYRDENKVHKESQTETFVAIKAFLDTPKFKGVPFYLKHAKKMPHNQASVKIHFNAVNTLEFFLSQDKITLTLKDNQNPLILETHNKQEFLQPYAKLLYDAIQNNHNNFAHQLELEASWVFIDTLIEGFINNATPLYSYESHNLNESEFLKPLYQ
>NZ_CP024949.1|WP_145819994.1|294004_295831_+|phosphogluconate-dehydratase
MPKHSLEQIKEKITERSKKTRELYLENIFNPKNQPKIESLGCANIAHVTASMPEHLKMPLGSHKRKHFAIITAYNDMLSAHQPFKNYPDLIKKELQEHNAYASVASGVPAMCDGITQGYDGMELSLFSRDVIALSTAVGLSHNVFDGAFFLGVCDKIVPGLLIGALSFGNLASVFVPSGPMVSGIENYKKAKARQDFAMGKINREELLKVEMQSYHDVGTCTFYGTANSNQMMMEFMGLHVANSSFINPNNPLRKVLVEESAKRLASGKVLPLAKLIDEKSILNALIGLMATGGSTNHTLHLIAIARSCGVILNWDDFDAVSNLIPLLAKVYPNGSADVNAFEACGGLAFVIKELLKEGLLFEDTHTIMDTETQKGMQNYTKTPFLENDHLVYKDAINHSLNTDILRPVSEPFAANGGLKILKGNLGRAVIKISAIKDEHRKVKARAIVFKTQSEFLERFKNKELERDFVAVLPFQGPKSNGMPELHKLTTNLGALQDMGYKVALVTDGRMSGASGKVPSAIHLSPEGALNGAIIKIKDGDLIELDAPNNALNVLEKDFEKRGINPLFLETLENLEKPSFGLGRELFTSLRLNANTAEEGGMSFGIKV
>NZ_CP024949.1|WP_145819996.1|295849_296470_+|bifunctional-4-hydroxy-2-oxoglutarate-aldolase/2-dehydro-3-deoxy-phosphogluconate-aldolase
MQDKIIEVLQISPIVPVVVVEDIKDAVPLAQSLIEGGIPIIEVTLRSSCALEAIELIAKNVPKMRVGAGTILNLTQLEQAQNRGAEFLISPGLTITLLEHAKKKGMPLIPGVSSSSEVMQALELGYSALKFFPAEYCGGVKLLNAFNGPFKGVKFCPTGGISADNMRSYLNLENVLCVGGSWLTPKDLIQNKEWDKITEICKRALA
>NZ_CP024949.1|WP_145819998.1|296544_297417_+|Sel1-like-repeat-protein-HcpC
MLENVKKSLFRVLCLGALCLGGLMAEQDPKELVGLGAKSYKEQDFTQAKKYFEKACDLKENSGCFNLGVLYYQGQGVEKNLKKAASFYAKACDLNYSNGCHLLGNLYYSGQGVSQNTNKALQYYSKACDLKYAEGCASLGGIYHDGKVVTRDFKKAVEYFAKACDLNDGDGCTILGSLYDAGRGTPKDLKKALASYDKACGLKDSPGCFNAGNMYHHGDGVVKNFKEALARYSKACELENGGGCFNLGAMQYNGEGVTRNEKQAIENFKKGCNLGAKGACDILKQLKIKV
>NZ_CP024949.1|WP_145820000.1|297629_298382_-|SDR-family-NAD(P)-dependent-oxidoreductase
MAHILVSGATSGFGLEIAKAFLQKNHVVFGTGRRKENLQKLQLAYPKHFIPLCFDLQKKLEMKRAIEAIFSMTDRIDALINNAGLALGLNKAYECELDDWEIMIDTNIKGLLYLTRLILPSMIEHDQGTIINLGSIAGTYPYPGGNVYGASKAFVKQFSLNLRADLAGTNIRVSNVEPGLCGETEFSMVRFKGDKIKAQSVYENTIYLKPQDIANIVLWIYEQPLHVNINRIEIMPISQTFAPLPTHKSP
>NZ_CP024949.1|WP_145820002.1|298399_299935_-|hypothetical-protein
MKKLLYTLLALLLIGLLTTYLILFTEWGNKIIASYIEKKINPNEHYLSVKTFKLGFNSLDFKAQANDDSTLILKGDFSLLKQSVNLNYHIDIKNLYSFKEWIPYPLRGAVMTSGNIKGHRKALVIQGVSNVAQSHTTYNALLDDFKLSHLSLNAKDANLEDLLYLINRPAYANAKVSLQADFNSLKPLEGHLILTANNALINNALINQIFHLNLKDTLVFNLSHSSDFKENKAISDTTLTSPLVNFTALKSEYLFSVLKLNAPYTLEIPSLAKLQSITNHPLKGSLTLKGDIEQSPKLLKVSGHSNLLDGTLDFTLLNKDLKARFSNISTLKALDLFNYPKFFQSIADANLDYDLSAKQGVLKARLKNARFLKNAFSDFLYSISKFDIMKEVYNDANLVSQINQQRLLSDLSLKSPKTQLKIRNGLLDLNTKQMDMLMDAEILKFIFKMKLQGNMHQPKFSLILNEKAIQQNLQQGLKKILKNDTLKKGLDHLLKDDKLKEKLEKGLKGLF
>NZ_CP024949.1|WP_145820004.1|300668_301703_+|UDP-glucose-4-epimerase-GalE
MALLFTGACGYIGSHTARAFLEKTKENIIIVDDLSTGFLEHIKALEHYYPNRVTFIQANLNETHKLDAFLNKQQLKDPIEAVLHFGAKISVEESTRLPLEYYTNNTLNTLELVKLCLKHAIKRFIFSSTAVVYGESGSSLSEESPLNPINPYGASKMMSERILLDTSKIADFKCVILRYFNVAGACMHNDYSTPYTLGQRTLNATHLIKIACECAVGKRKKMGIFGTNYPTRDGTCIRDYIHVDDLANAHLASYHTLLEKNKSEIYNVGYNQGYSVKEVIEKVKEISNKDFLVEILDKRQGDPASLIANNSKILQNTPFKPLYNNLDTIIKSALSWEEHLLKFQ

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Crispr_ID: NZ_CP024949_3

CRISPR_ID

CRISPR_location

CRISPR_type

Repeat_type

Spacer_info

Cas_protein_info

CRISPR-Cas_info

NZ_CP024949_3

459716-459849

Orphan

I-B

Consensus_repeat	Method
TTAAAATTATAAGTGCCTTGATT	CRISPRCasFinder

2 spacers

The CRISPR arrays of NZ_CP024949_3

>merge|NZ_CP024949|3|459716-459849|CRISPRCasFinder
TTAAAGTGATAAGTCCCTTGATTGAAGGTGTCGTTATTAAAGCTAACATTGTCATTAAAATTATAAGTGCCTTGATTGAAAGCGCTGTTTTGAAAAGCAGATTGAGCGCTGTTAAAATTATAAGTCCCTTGATT

>NZ_CP024949|3|3|459716-459849|CRISPRCasFinder
TTAAAGTGATAAGTCCCTTGATT	GAAGGTGTCGTTATTAAAGCTAACATTGTCA
TTAAAATTATAAGTGCCTTGATT	GAAAGCGCTGTTTTGAAAAGCAGATTGAGCGCTG
TTAAAATTATAAGTCCCTTGATT

Protein	Signature genes	Signature genes Name	Protein_function
NZ_CP024949.1\|WP_145820164.1\|477575_478715_-\|N-6-DNA-methylase	unknown	unknown	gnl\|CDD\|223897
NZ_CP024949.1\|WP_000236817.1\|445765_446368_-\|6-pyruvoyl-tetrahydropterin-synthase-family-protein	unknown	unknown	gnl\|CDD\|223792
NZ_CP024949.1\|WP_145820156.1\|469213_470758_+\|outer-membrane-beta-barrel-protein-HofG	unknown	unknown	gnl\|CDD\|334957
NZ_CP024949.1\|WP_001099598.1\|451358_451940_-\|recombination-protein-RecR	unknown	unknown	gnl\|CDD\|273176
NZ_CP024949.1\|WP_000037493.1\|446371_447031_-\|hypothetical-protein	unknown	unknown	unknown
NZ_CP024949.1\|WP_145820144.1\|450216_451362_-\|tRNA-pseudouridine(13)-synthase-TruD	unknown	unknown	gnl\|CDD\|272903
NZ_CP024949.1\|WP_108551423.1\|461856_462549_+\|Bax-inhibitor-1/YccA-family-protein	unknown	unknown	gnl\|CDD\|198414
NZ_CP024949.1\|WP_001115888.1\|452086_452293_+\|4-oxalocrotonate-tautomerase-family-protein	unknown	unknown	gnl\|CDD\|129125
NZ_CP024949.1\|WP_145820158.1\|471541_473137_-\|Hop-family-adhesin-AlpB	unknown	unknown	gnl\|CDD\|280099
NZ_CP024949.1\|WP_000426995.1\|448754_449297_-\|GTP-cyclohydrolase-I-FolE	unknown	unknown	gnl\|CDD\|129173
NZ_CP024949.1\|WP_145820146.1\|452360_453461_-\|Hop-family-outer-membrane-protein-HopJ/HopK	unknown	unknown	gnl\|CDD\|280099
NZ_CP024949.1\|WP_000098056.1\|447827_448739_-\|polyprenyl-synthetase-family-protein	unknown	unknown	gnl\|CDD\|223220
NZ_CP024949.1\|WP_145820159.1\|473158_474709_-\|Hop-family-adhesin-AlpA	unknown	unknown	gnl\|CDD\|280099
NZ_CP024949.1\|WP_145820151.1\|462646_465904_+\|carbamoyl-phosphate-synthase-large-subunit	unknown	unknown	gnl\|CDD\|235393
NZ_CP024949.1\|WP_145820162.1\|475544_477572_-\|UvrD-helicase-domain-containing-protein	unknown	unknown	gnl\|CDD\|223288
NZ_CP024949.1\|WP_145820153.1\|466523_468965_+\|TonB-dependent-receptor	unknown	unknown	gnl\|CDD\|224544
NZ_CP024949.1\|WP_145820150.1\|460714_461713_-\|type-I-glyceraldehyde-3-phosphate-dehydrogenase	unknown	unknown	gnl\|CDD\|273675
NZ_CP024949.1\|WP_080015819.1\|449297_450278_-\|zinc-metalloprotease-HtpX	unknown	unknown	gnl\|CDD\|235081
NZ_CP024949.1\|WP_001229994.1\|465908_466340_+\|hypothetical-protein	unknown	unknown	gnl\|CDD\|376519
NZ_CP024949.1\|WP_145820142.1\|447027_447831_-\|5'/3'-nucleotidase-SurE	unknown	unknown	gnl\|CDD\|223570

Protein	Function_ID	Function_description	E-value
NZ_CP024949.1\|WP_145820164.1\|477575_478715_-\|N-6-DNA-methylase	gnl\|CDD\|223897	COG0827, COG0827, Adenine-specific DNA methylase [DNA replication, recombination, and repair].	5.96287e-53
NZ_CP024949.1\|WP_000236817.1\|445765_446368_-\|6-pyruvoyl-tetrahydropterin-synthase-family-protein	gnl\|CDD\|223792	COG0720, COG0720, 6-pyruvoyl-tetrahydropterin synthase [Coenzyme metabolism].	3.2004e-21
NZ_CP024949.1\|WP_145820156.1\|469213_470758_+\|outer-membrane-beta-barrel-protein-HofG	gnl\|CDD\|334957	pfam02521, HP_OMP_2, Putative outer membrane protein. This family consists of putative outer membrane proteins from Helicobacter pylori (campylobacter pylori).	1.49381e-179
NZ_CP024949.1\|WP_001099598.1\|451358_451940_-\|recombination-protein-RecR	gnl\|CDD\|273176	TIGR00615, Recombination_protein_RecR, recombination protein RecR. All proteins in this family for which functions are known are involved in the initiation of recombination and recombinational repair. RecF is also required. This family is based on the phylogenomic analysis of JA Eisen (1999, Ph.D. Thesis, Stanford University). [DNA metabolism, DNA replication, recombination, and repair].	4.16127e-98
NZ_CP024949.1\|WP_145820144.1\|450216_451362_-\|tRNA-pseudouridine(13)-synthase-TruD	gnl\|CDD\|272903	TIGR00094, tRNA_pseudouridine_synthase_D, tRNA pseudouridine synthase, TruD family. an EGAD loading error caused one member to be called surE, but that's an adjacent gene. MJ11364 is a strong partial match from 50 to 230 aa. [Protein synthesis, tRNA and rRNA base modification].	8.61366e-139
NZ_CP024949.1\|WP_080015819.1\|449297_450278_-\|zinc-metalloprotease-HtpX	gnl\|CDD\|235081	PRK02870, PRK02870, heat shock protein HtpX; Provisional.	0
NZ_CP024949.1\|WP_001115888.1\|452086_452293_+\|4-oxalocrotonate-tautomerase-family-protein	gnl\|CDD\|129125	TIGR00013, Probable_tautomerase_K2, 4-oxalocrotonate tautomerase family enzyme. 4-oxalocrotonate tautomerase is a homohexamer in which each monomer is very small, at about 62 amino acids. Pro-1 of the mature protein serves as a general base. The enzyme functions in meta-cleavage pathways of aromatic hydrocarbon catabolism. Because several Arg residues located near the active site in the crystal structure of Pseudomonas putida are not conserved among all members of this family, because the literature describes a general role in the isomerization of beta,gamma-unsaturated enones to their alpha,beta-isomers, and because of the presence of fairly distantly related paralogs in Campylobacter jejuni, the family is regarded as not necessarily uniform in function. [Energy metabolism, Other].	4.5194e-26
NZ_CP024949.1\|WP_145820158.1\|471541_473137_-\|Hop-family-adhesin-AlpB	gnl\|CDD\|280099	pfam01856, HP_OMP, Helicobacter outer membrane protein. This family seems confined to Helicobacter. It is predicted to be an outer membrane protein based on its pattern of alternating hydrophobic amino acids similar to porins.	1.05529e-53
NZ_CP024949.1\|WP_000426995.1\|448754_449297_-\|GTP-cyclohydrolase-I-FolE	gnl\|CDD\|129173	TIGR00063, GTP_cyclohydrolase_1, GTP cyclohydrolase I. alternate names: Punch (Drosophila),GTP cyclohydrolase I (EC 3.5.4.16) catalyzes the biosynthesis of formic acid and dihydroneopterin triphosphate from GTP. This reaction is the first step in the biosynthesis of tetrahydrofolate in prokaryotes, of tetrahydrobiopterin in vertebrates, and of pteridine-containing pigments in insects. [Biosynthesis of cofactors, prosthetic groups, and carriers, Folic acid].	2.47966e-105
NZ_CP024949.1\|WP_145820146.1\|452360_453461_-\|Hop-family-outer-membrane-protein-HopJ/HopK	gnl\|CDD\|280099	pfam01856, HP_OMP, Helicobacter outer membrane protein. This family seems confined to Helicobacter. It is predicted to be an outer membrane protein based on its pattern of alternating hydrophobic amino acids similar to porins.	2.85621e-47
NZ_CP024949.1\|WP_000098056.1\|447827_448739_-\|polyprenyl-synthetase-family-protein	gnl\|CDD\|223220	COG0142, IspA, Geranylgeranyl pyrophosphate synthase [Coenzyme metabolism].	7.13916e-76
NZ_CP024949.1\|WP_145820159.1\|473158_474709_-\|Hop-family-adhesin-AlpA	gnl\|CDD\|280099	pfam01856, HP_OMP, Helicobacter outer membrane protein. This family seems confined to Helicobacter. It is predicted to be an outer membrane protein based on its pattern of alternating hydrophobic amino acids similar to porins.	1.87699e-54
NZ_CP024949.1\|WP_145820151.1\|462646_465904_+\|carbamoyl-phosphate-synthase-large-subunit	gnl\|CDD\|235393	PRK05294, carB, carbamoyl-phosphate synthase large subunit.	0
NZ_CP024949.1\|WP_145820162.1\|475544_477572_-\|UvrD-helicase-domain-containing-protein	gnl\|CDD\|223288	COG0210, UvrD, Superfamily I DNA and RNA helicases [DNA replication, recombination, and repair].	1.44763e-135
NZ_CP024949.1\|WP_145820153.1\|466523_468965_+\|TonB-dependent-receptor	gnl\|CDD\|224544	COG1629, CirA, Outer membrane receptor proteins, mostly Fe transport [Inorganic ion transport and metabolism].	1.97966e-35
NZ_CP024949.1\|WP_145820150.1\|460714_461713_-\|type-I-glyceraldehyde-3-phosphate-dehydrogenase	gnl\|CDD\|273675	TIGR01534, Glyceraldehyde-3-phosphate_dehydrogenase, glyceraldehyde-3-phosphate dehydrogenase, type I. This model represents glyceraldehyde-3-phosphate dehydrogenase (GAPDH), the enzyme responsible for the interconversion of 1,3-diphosphoglycerate and glyceraldehyde-3-phosphate, a central step in glycolysis and gluconeogenesis. Forms exist which utilize NAD (EC 1.2.1.12), NADP (EC 1.2.1.13) or either (1.2.1.59). In some species, NAD- and NADP- utilizing forms exist, generally being responsible for reactions in the anabolic and catabolic directions respectively. Two Pfam models cover the two functional domains of this protein; pfam00044 represents the N-terminal NAD(P)-binding domain and pfam02800 represents the C-terminal catalytic domain. An additional form of gap gene is found in gamma proteobacteria and is responsible for the conversion of erythrose-4-phosphate (E4P) to 4-phospho-erythronate in the biosynthesis of pyridoxine. This pathway of pyridoxine biosynthesis appears to be limited, however, to a relatively small number of bacterial species although it is prevalent among the gamma-proteobacteria. This enzyme is described by TIGR001532. These sequences generally score between trusted and noise to this GAPDH model due to the close evolutionary relationship. There exists the possiblity that some forms of GAPDH may be bifunctional and act on E4P in species which make pyridoxine and via hydroxythreonine and lack a separate E4PDH enzyme (for instance, the GAPDH from Bacillus stearothermophilus has been shown to posess a limited E4PD activity as well as a robust GAPDH activity). There are a great number of sequences in the databases which score between trusted and noise to this model, nearly all of them due to fragmentary sequences. It seems that study of this gene has been carried out in many species utilizing PCR probes which exclude the extreme ends of the consenses used to define this model. The noise level is set relative not to E4PD, but the next closest outliers, the class II GAPDH's (found in archaea, TIGR01546) and aspartate semialdehyde dehydrogenase (ASADH, TIGR01296) both of which have highest-scoring hits around -225 to the prior model. [Energy metabolism, Glycolysis/gluconeogenesis].	1.40001e-158
NZ_CP024949.1\|WP_108551423.1\|461856_462549_+\|Bax-inhibitor-1/YccA-family-protein	gnl\|CDD\|198414	cd10432, BI-1-like_bacterial, Bacterial BAX inhibitor (BI)-1/YccA-like proteins. This family is comprised of bacterial relatives of the mammalian members of the BAX inhibitor (BI)-1 like family of small transmembrane proteins, which have been shown to have an antiapoptotic effect either by stimulating the antiapoptotic function of Bcl-2, a well-characterized oncogene, or by inhibiting the proapoptotic effect of Bax, another member of the Bcl-2 family. In plants, BI-1 like proteins play a role in pathogen resistance. A characterized prokaryotic member, Escherichia coli YccA, has been shown to interact with ATP-dependent protease FtsH, which degrades abnormal membrane proteins as part of a quality control mechanism to keep the integrity of biological membranes.	3.23593e-52
NZ_CP024949.1\|WP_001229994.1\|465908_466340_+\|hypothetical-protein	gnl\|CDD\|376519	pfam01300, Sua5_yciO_yrdC, Telomere recombination. This domain has been shown to bind preferentially to dsRNA. The domain is found in SUA5 as well as HypF and YrdC. It has also been shown to be required for telomere recombniation in yeast.	0.000215832
NZ_CP024949.1\|WP_145820142.1\|447027_447831_-\|5'/3'-nucleotidase-SurE	gnl\|CDD\|223570	COG0496, SurE, Predicted acid phosphatase [General function prediction only].	1.23034e-125

>NZ_CP024949.1|WP_145820146.1|452360_453461_-|Hop-family-outer-membrane-protein-HopJ/HopK
MQFPKTLFSLSLLFLSFCIAEENGAYASVGFEYSISHAIQHNDPFLNQERIQIISNAQNKIYKLNQVKNEITSMPKTFAYINNALKNHSKLTPTEKQAETYYLQSTLQNIEKIVTLSGGVASNPQLAQALEKMQEPITNPLEFEENLKNLESQFTQSQNRMLSSLSSQIAAISNSLNALDPNSYSKNISSMYGVSLSVGYKHFFTKKKNQGFRYYLFYDYGYTNFGFVGNGFDGLGKMNNHLYGLGIDYLYNFIDNAKKHSSVGFYVGFALAGSSWVGSGLGMWVSQGDFINNYLTGYQAKMHTSFFQIPLNFGVRVNVNRHNGFEMGLKIPLAVNSFYETHGKGLNTSLFFKRLVVFNVSYVYSF
>NZ_CP024949.1|WP_001115888.1|452086_452293_+|4-oxalocrotonate-tautomerase-family-protein
MPFINIKLVPENGGPTNEQKQQLIEGVSDLMVKVLNKNKASVVVIIDEVDSNNYGLGGESVHHLRQKN
>NZ_CP024949.1|WP_001099598.1|451358_451940_-|recombination-protein-RecR
MNTYKNSLNHFLNLVDCLEKIPNVGKKSAFKMAYHLGLENPYLALKITHALENALENLKTCASCNALSESEVCEICSDESRQNSQLCMVLHPRDVFILEDLKDFLGRYYVLNSIEEVDFNALEKRLIEENIKEIIFAFPPTLANDSLMLYIEDKLQHFHLTFTKIAQGVPTGVNFENIDSVSLSRAFNSRIKA
>NZ_CP024949.1|WP_145820144.1|450216_451362_-|tRNA-pseudouridine(13)-synthase-TruD
MNLNFMPLLHAYNHASIDFHFNSSARDFCVHEVPLYEFSNTGEHAVIQVRKSGLSTLEMLQIFSQILGVKIAELGYAGLKDKNALTTQFISLPKKYAPLLEKNTHNLQERNLKILSLNYHHNKIKLGHLKGNRFFMRFKKMTPLNAHKTEQVLEQIAQFGMPNYFGSQRFGKFNDNHKEGLKILQNQTKFAHQKLNAFLISSYQSYLFNALLSKRLEISKIISDFSIKENLEFFKQKNLSVDSNTLKALKNQAHPFKILEGDVMCHYPYGKFFDALELEKESERFLNKEAVPTGLLDGKKALYAKNLSLEIEKEFQHNLLNSHAKTLGSRRFFWVFLENVTSQYIKEKAQFELGFYLPKGSYASALLKEIKHEKGENNDEF
>NZ_CP024949.1|WP_080015819.1|449297_450278_-|zinc-metalloprotease-HtpX
MRARCSKKSSMRKEKIMTNFEKIIVQNRLKTNAVLATYCTIFAFIGLLVDAIRINANDLGIALFKLITFQIFPTITIIMFLAAFVVIVVCIQNFSSIMLSGDEYKLIDPSKVLSSKENQIHRLLLELLEEAKLHFEPKLYIINAPYMNAFASGWDESNSLIALTSALIERLDRDELKAVIAHELSHIRHNDIRLTMCVGILSNIMLLVANFSVYFFMGNRKNSGANLARMILLLLQIILPFLTLILQMYLSRTREYMADSGAAFLMHDNKPMIRALQKISNDYANNDYKGIDQNSTRSAAYLFNAEMFSTHPSIKNRIQSLSRRVI
>NZ_CP024949.1|WP_000426995.1|448754_449297_-|GTP-cyclohydrolase-I-FolE
MENFFNQFFENIGENKNREGLKETPKRVQELWKFLYKGYKEDPRVALKSAYFQGVCDEMIVAQNIEFYSTCEHHLLPFLGNISLGYIPKEKIVGISAIAKLIEIYSKRLQIQERLTTQIAETFDEIIEPRGVIVVCEAKHLCMSMQGVQKQNAIIKTSVLRGLFKKDPKTRAEFMQLLKS
>NZ_CP024949.1|WP_000098056.1|447827_448739_-|polyprenyl-synthetase-family-protein
MSSPNLSFYYNECERFESFLNHHHLHLESFHPYLEKAFFEMVLNGGKRFRPKLFLAVLCALVGQKDYSSQQTEYFKIALSIECLHTYSLIHDDLPCMDNAALRRNHPTLHAKYDETTAVLIGDALNTYSFELLSNSLLESHIIVELVKILSVNGGIKGMVLGQALDCYFENTPLNLEQLTFLHEHKTAKLISASLMMGLVASGIKDEELFKWLQAFGLKTGLCFQVLDDIIDVTQDEEESGKTTHLDGAKNSFVNLLGLEKASGYAQTLKTEVLNDLNLLKSAYPSLQENLNALLNTLFKGKT
>NZ_CP024949.1|WP_145820142.1|447027_447831_-|5'/3'-nucleotidase-SurE
MKKILLTNDDGYHAKGIKALEQALEEMAEIYVVAPKHEKSACSQCITISAPLRAEKIKGKEGRHYRIDDGTPSDCVYLAINELFKHVCFDLVISGINLGSNMGEDTIYSGTVAGAIEGTIQGVPSIAISQILSNKNKNTPLSFDLAQKIIQDLVQNIFTNGYPLKGRKLLNVNVPNCSLQEYKGECITPKGYRLYKKEVHKRTDPKNESYFWLGLHPLEWQKRENEDRLSDFDAIASNHVSITPLNLDLTSYDDLKSLESWHEGMLK
>NZ_CP024949.1|WP_000037493.1|446371_447031_-|hypothetical-protein
MSKKHRLAFLGLIVGVFFFFNACQHRLHMGYYSEVTGDYLFNYNSTIVVAYDRSDAMTSYYINVIVYELQKLGFYNVFTQAEFPLDKAKNVIYARIVRNISAVPFYQYNYQLIDQVNKPCYFLGGQFYCSQTPTDYYAINGFSEQILMSANSHFILDWYDVVLQKRVLYVDGSVSGRTCGYQMLYRDLIKSTIKRIDFNRPERYYYNLRLPLYQPCYRQ
>NZ_CP024949.1|WP_000236817.1|445765_446368_-|6-pyruvoyl-tetrahydropterin-synthase-family-protein
MVIRRLYKFCASHVVRNCSSLKCAQNIHGHNYEVEVFIETNRLDSANMALDFGLMQQEMQVFIESFDHAHHFWDKESDEFQRFIENHCVRYVKCSFNLSAESYALMFLYYLTKILQKSVFSNNEGELKVSSVRVHETKNGYAESFLNDLENSHFKSLVHDHCVSFSQGIQNLWHDKDFFNKIISDEKQCFFHAKPLHQIP
>NZ_CP024949.1|WP_145820150.1|460714_461713_-|type-I-glyceraldehyde-3-phosphate-dehydrogenase
MKIFINGFGRIGRCVLRAILERNDTNPKLEVIGINDPANWEILAYLLEHDSAHGLLNKEAHYSNHKLIIGSLEIPVFNSIKDLKGVDVILECSGKFLEPKTLENYLLLGAKKVLLSAPFMGEYDEKQYPTLVYGVNHFCYQNQAIVSNASCTTNAIAPICTILDKAFNIKEGMLTTIHSYTSDQKLIDLAHPLDKRRSRAAASNIIPTTTKAALALHKVLPNLKNKMHGHSVRVPSLDVSMIDLSLFLEKKVPKDPINDLLIEASKGVLKGVLEIDLKERVSSDFISNPSSVIIAPDLTFTLENMVKIMGWYDNEWGYSNRLVDMAQFVYHY
>NZ_CP024949.1|WP_108551423.1|461856_462549_+|Bax-inhibitor-1/YccA-family-protein
MALYDRANSRNAYAEDSLLHESELVGFVKTTYKFFAGSLLLATIGALLGLMNFQAVVQYKWVFFIAEIAAFFGLMFSKSKPGLNLFMLFAFTSLSGVTLVPLLGMVIAKAGLGAVWQALGMTTIVFGLMSVYALKTKNDLANMGKMLFIALIVVVVCSLINLFLGSPMFQVVIAGASAILFSLYIAYDTQNIVKGMYDSPIDAAVSLYLDFLNVFISILQIIGIFSDRDK
>NZ_CP024949.1|WP_145820151.1|462646_465904_+|carbamoyl-phosphate-synthase-large-subunit
MPKRTDISNILLIGSGPIVIGQACEFDYSGTQSCKTLKSLGYRVILINSNPATVMTDPEFSHQTYIQPITGENIAAIIEKEKIDAILPTMGGQTALNAVMQMHQKGMLEGVELLGAKIEAIKKGEDRQAFKEAMLKIGMDLPKGRYAYNELEALEAINEIGFPAIIRASFTLAGGGSGVAYNIEEFQELAKNALDASPINEILIEESLLGWKEYEMEVIRDSKDNCIIVCCIENIDPMGVHTGDSITIAPSLTLTDKEYQRMRDASFAILREIGVDTGGSNVQFAIHPETLRMVVIEMNPRVSRSSALASKATGFPIAKVATMLAVGFSLDEIKNDITNTPASFEPSLDYIVVKIPRFAFEKFAGVSSTLGTSMKSIGEVMAIGGNFLEALQKALCSLENNWLGFESLSKDLEAIKKEIRRPNPKRLLYIADAFRLGVSVDEVFELCQIDRWFLSQIQKLVKAEESINSSVLTDAKKLRGLKNLGFSDARIAAKIKENENLEVSPFEVELARSNLQIAPNFEEVDTCAAEFLSLTPYLYSTYAPNPLPPIGNKQEKQEKKILIIGSGPNRIGQGIEFDYCCVHASFALKDLNIKSVMLNCNPETVSTDYDTSDTLYFEPIHFECVKSIIQRERVDGIIVHFGGQTPLKLAKDLAKMQAPIIGTPFKVIDIAEDREKFSLFLKELDIKQPKNGMAKSIDEAYSIANVIGFPIIVRPSYVLGGQHMQILENIEELHHYLESVTHALEVSPKNPLLIDKFLEKAVELDVDVICDKKEVYIAGILQHIEEAGIHSGDSACFIPSTLSPEILDEIERVSAKIALHLGVVGLLNIQFAVYENSLYLIEVNPRASRTVPFLSKALGVPLAKVATRVMVLEDLKEALKFYDKKNIVEYSKGVYKPKMPHFVALKEAVFPFNKLYGSDLILGPEMKSTGEVMGIARSLGLAFFKAQTACFNPIKNKGLIFVSIKDKDKEEACVLMKRLVQLGFELCATEGTHKALEKAGVKSLKVLKISEGRPNIMDLMMNGEISMAINTSDHKSQDDAKLIRASVLKNHVSYFTTLSAIEVLLLALEESSQQDELLALQDYLK
>NZ_CP024949.1|WP_001229994.1|465908_466340_+|hypothetical-protein
MALVYLVQSDTTIGLLSKDSEKLNALKGRPKNQSVLIESADFSTLKSLVRAPNAFKNLIRRSAKTTFIYPNSKAVRVIKGRHGDFLKRFKTLYSTSANLTQCAYDKEIASNLADVIVSDERGLFESASSKIFRIYKDKKVRIR
>NZ_CP024949.1|WP_145820153.1|466523_468965_+|TonB-dependent-receptor
MNDKRFRKYCSFSIFLSLLGMFELEAKEEEKEEKKTERKKEKKENAQHTLGKVTTQAAKIFNYNNQTTISSKELERRQANQISDMFRRNPNINVGGGAVIAQKIYVRGIEDRLARVTVDGAAQMGASYGHQGNTIIDPGMLKSVVVTKGAAQASAGPMALIGAIKMETRSASDFIPKGKDYAMSGAATFLTNFGDRETVMGAYRNHHFDMLLYYTHQNIFYYRDGDNAMKNLFDPKAENKVTASPSEQNNVMAKINGYLSERDILTLSYNMTRDNANRPLRANFTGTFLPYSCGDFNAFPNDQNPDDCLFENDASLFKTYSVNLVHNVSLNYEREGGSRFGDPKLKINGYTSIRNVQIDPLFKPSDIAAIIPFTPNPKLGEENECVAQGGIYDATKQTCSITFKSLGGGSVVANKNLFIINSGFNANVIHTIDHKNDNLFEYGLNYQNLTTFDKAIPNSELVKPGDAPDACLRVMGPNDPNMNGRCQRNGATANVIGVYAQANYTLHPMVTLGAGTRYDVYTLVDKDWQLHITQGFSPSAALNVSPLENLNFRLSYAYVTRGPMPGGLVWMRQDNLRYNRNLKPEIGQNAEFNTEYSSQYFDFRAAGFVQLISNYINQFSSTLFVTNLPAQDIIYVPGYEVSGTAKYKGFSLGLSVARSWPSLKGRLIADVYELAATTGNVFILTASYTIPRTGLSITWLSRFVTDLSYCSYSPYRNGPTDIDRRPSHCPKTPGIFHVHKPGYGVSSFFITYKPTYKKLKGLSLNAVFNNVFNQQYIDQASPVMSPDEPNQDKYARGMAEPGFNARFEISYKF
>NZ_CP024949.1|WP_145820156.1|469213_470758_+|outer-membrane-beta-barrel-protein-HofG
MRQEKYFLTSSLSLLSFLLCPVEAFDYRFSGRVENFSKIGFNNSQINTKKGIYPTESFIDIVTLAQVKVNLLPKGIENHRLSVSLGGAIAAIPYDKTKYDINQANGKIFGSIVENFIGGYHGYFFNKYLGPAYAGTSQSASYHARPYVVDTAFLRYDYKDVFGFKAGRYEANIDFMSGSNQGWEVYYQPYKTETQRLRFWWWSSFGRGLAFNSWIYEFFATVPYLKKGGNPNNSNDFINYGWHGITTTYSYKGLDAQFFYYFAPKTYNAPGFKLVYDTNRNFENVGFRSQSMIMTTFPLYYRGWYNPETNTYSLEDSTPHGSLLGRNGVTLNIRQVFWWDNFNWSIGFYNTFGNSDAFLGSHTMPRGNNTSYIGSEISITTRHAGMIGYDFWDNTAYDGLADAITNANTFTFYTSVGGIHKRFAWHVFGRVSHANKNALGQVGRANEYSLQFNASYAFTESILLNFRITYYGARINKGYQAGYFGAPKFNNPDGDFSANYQDRSYMMTNLTLKF
>NZ_CP024949.1|WP_145820158.1|471541_473137_-|Hop-family-adhesin-AlpB
MKQNLKPFKMIKENLMTQSQKVRFLAPLSLALSLSFNPVGAEEDGGFMTFGYELGQVVQQVKNPGKIKAEELAGLLNSNTTNNTNINIAGTGGNVAGTLGNLFMNQLGNLIDLYPTLNTSNISQCGATNSGGSGSGATTAAATTSNNPCFQGNLALYNEMVGSIKTLSQNISKNIFQGDNNTTSQNLSNQLSELNTASVYLTYMNSFLNANNQAGGIFQNHTNQTYGSGVTAQQIAYILKQASITMGPSGDSGAAAAFLDAALAQHVFNSANAGNDLSAKEFTSLVQNIVNNSQNALTLANNANISNSTGYQVSYGGNIDQARSTQLLNNTTNTLAKVTALNNELKANPWLGNFAAGNSSQVNAFNGFITKIGYKQFFGENKNVGLRYYGFFSYNGAGVGNGPTYNQVNLLTYGVGTDVLYNVFSRSFGSRSLNAGFFGGIQLAGDTYISTLRNSPQLANRPTATKFQFLFDVGLRMNFGILKKDLKSHNQHSIEIGVQIPTIYNTYYKAGGAEVKYFRPYSVYWVYGYAF
>NZ_CP024949.1|WP_145820159.1|473158_474709_-|Hop-family-adhesin-AlpA
MIKKNRTLFLSLALCASISYAEDDGGFFTVGYQLGQVMQDVQNPGGAKSDELARELNADVTNNILNNNTGGNVAGALSNAFSQYLYSLLGAYPTKLNSNDVSANALLSGAVGSGTCAAAGTAGGTSLNTQSACTAAGYYWLPSLTDRILSTIGSQTNYGTNTNFPNMQQQLTYLNAGNVFFNAMNKALENKNGTSNSANGATDSDGQTYSQQAIQYLQGQQNILNNAANLLKQDELLLEAFNSAVAANIGNKEFNSAAFTGLVQGIIDQSQLVYNELTKNTISGSAVNSAGINSNQANAVQGRASQLPNALYNAQVTLDKINALNNQVRSMPYLPQFRAGNSRSTNILNGFYTKIGYKQFFGKKRNIGLRYYGFFSYNGASVGFRSTQNNVGLYTYGVGTDVLYNIFSRSYQNRSVDMGFFSGIQLAGETFQSTLRDDPNVKLHGKINNTHFQFLFDFGMRMNFGKLDGKSNRHNQHTVEFGVVVPTIYNTYYKSAGTTVKYFRPYSVYWSYGYSF
>NZ_CP024949.1|WP_145820162.1|475544_477572_-|UvrD-helicase-domain-containing-protein
MLETLQLNPEQLKAACALKGHNLVIASAGTGKTSTIVGRILYLLDNGIKPEEILLLTFTNKASNEMIARVAKYFKSSSKIEAGTFHAVAYRYLKEHYPNLSLKQPKELRKLLESIVDTKNAIDDDKKPYTSQHLYALYSLYTNALKQEDFSTWLSTKNPEHTPYAAFYENILEEFENTKKKHNYIDYNDLLLLFKKAMLERPSPYREVLCDEFQDTNPLQESILDAINPPSLFCVGDYDQSIYAFNGADISIISNFTQKYKNAQVFTLTKNYRSSKEILDLANQVIQRNERIYPKNLEVVKSGKFNKPTLLNYNDNIAQCQDIAKRIVMRKGFKEVAVIFRNNASADQLEAALRSYNVPSKRKGSASFFESKEVALALDICALIFNPKDIMAAIHILSYISDIGSNTAKDIHEALMLLGNGDLKSALIQPNKEAKIYTKKKEITSMGLFEEIFALENSSRFNSVIDKAFYSHPVLMHPKISLNGAKMLSDFFILYTKAPTHSPSALIKHILESVFFQTFKTRLLKERSKNKDGSYNEFKKLQAQKRFNEKMDLLSSLAKNYQNLGRFLNGTLIGSSEATQGEGVNLLSVHASKGLEFKDVYIIDLMEGRFPNHKLMNTGGGIEEERRLFYVAITRAKENLWLSYAKNELRENAKPKEHKPSVFLYEAGLLKPDLK
>NZ_CP024949.1|WP_145820164.1|477575_478715_-|N-6-DNA-methylase
MYQLDIKTLGQVFTPKKIVDFMLTLKHNQGSVLEPSAGDGSFLKRLKKAVGIEIDPKICPKNALCMDFFDYPLENQFDTIIGNPPYVKHKDIAPSAKEKLHYSLFDERSNLYLFFIEKAIKHLKPKGELIFITTRDFLKSTSSVKLNEWIYKEGTITHFFELGDQKVFPNAMPNCVIFRFCKGNFSRIANDGLQFLCKKGILYFLNQSYTQKLSEVFKVKVGAVSGCDKIFKNEKYGNLEFVTSITKRTNVLEKMVFVNEPNDYLLQHKDSLMQRKIKKFNENNWYQWGRMHHISPKKRIYVNTKTRQKNPFFIHQCPNYDGSILALFPYNQNLDLQNLCDKLNAINWQELGFVCDGRFLFSQRSLENALLPKDFLNLG

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Crispr_ID: NZ_CP024949_4

CRISPR_ID

CRISPR_location

CRISPR_type

Repeat_type

Spacer_info

Cas_protein_info

CRISPR-Cas_info

NZ_CP024949_4

1215306-1215429

Orphan

Consensus_repeat	Method
AATTCTTCTAGTTTTTTTGAAATGATTTCTTCAG	CRISPRCasFinder

1 spacers

The CRISPR arrays of NZ_CP024949_4

>merge|NZ_CP024949|4|1215306-1215429|CRISPRCasFinder
AATTCTTCTAGTTTTTTTGAAATGATTTCTTCAGTAACGCTAGAGAGTCTTTCTCCATCATGCTTACCCTCTGGGGTTTCTTGGCTCTGTAATTCTTCTTGTTTTTTTGAAATGATTTCTTCAG

>NZ_CP024949|4|4|1215306-1215429|CRISPRCasFinder
AATTCTTCTAGTTTTTTTGAAATGATTTCTTCAG	TAACGCTAGAGAGTCTTTCTCCATCATGCTTACCCTCTGGGGTTTCTTGGCTCTGT
AATTCTTCTTGTTTTTTTGAAATGATTTCTTCAG

Protein	Signature genes	Signature genes Name	Protein_function
NZ_CP024949.1\|WP_001019055.1\|1218267_1219074_-\|septum-site-determining-protein-MinD	unknown	unknown	gnl\|CDD\|225447
NZ_CP024949.1\|WP_145820926.1\|1213295_1214081_-\|hypothetical-protein	unknown	unknown	unknown
NZ_CP024949.1\|WP_145821537.1\|1215014_1215221_-\|lysozyme	unknown	unknown	gnl\|CDD\|381599
NZ_CP024949.1\|WP_145820924.1\|1211187_1212069_+\|RluA-family-pseudouridine-synthase	unknown	unknown	gnl\|CDD\|223638
NZ_CP024949.1\|WP_145821539.1\|1219097_1220090_-\|ketol-acid-reductoisomerase	unknown	unknown	gnl\|CDD\|235491
NZ_CP024949.1\|WP_145820936.1\|1216344_1216698_-\|sel1-repeat-family-protein	unknown	unknown	gnl\|CDD\|276807
NZ_CP024949.1\|WP_145820922.1\|1209637_1211188_+\|single-stranded-DNA-specific-exonuclease-RecJ	unknown	unknown	gnl\|CDD\|273193
NZ_CP024949.1\|WP_145820920.1\|1208011_1209628_+\|CTP-synthase-(glutamine-hydrolyzing)	unknown	unknown	gnl\|CDD\|235437
NZ_CP024949.1\|WP_145820937.1\|1216829_1217234_-\|Holliday-junction-resolvase-RuvX	unknown	unknown	gnl\|CDD\|234639
NZ_CP024949.1\|WP_000201859.1\|1204300_1205332_-\|flagellar-motor-switch-protein-FliG	unknown	unknown	gnl\|CDD\|272961
NZ_CP024949.1\|WP_000056261.1\|1203537_1204314_-\|flagellar-assembly-protein-FliH	unknown	unknown	gnl\|CDD\|235850
NZ_CP024949.1\|WP_145820930.1\|1214760_1215021_-\|lysozyme	unknown	unknown	unknown
NZ_CP024949.1\|WP_145820945.1\|1221989_1222532_-\|UDP-4-amino-4,-6-dideoxy-N-acetyl-beta-L-altrosamine-N-acetyltransferase	unknown	unknown	gnl\|CDD\|274661
NZ_CP024949.1\|WP_145820939.1\|1217230_1218031_-\|DNA-protecting-protein-DprA	unknown	unknown	gnl\|CDD\|273238
NZ_CP024949.1\|WP_000829865.1\|1207090_1207753_-\|hypothetical-protein	unknown	unknown	gnl\|CDD\|239486
NZ_CP024949.1\|WP_145820943.1\|1221118_1222057_+\|tetraacyldisaccharide-4'-kinase	unknown	unknown	gnl\|CDD\|224577
NZ_CP024949.1\|WP_145820928.1\|1214653_1214749_-\|hypothetical-protein	unknown	unknown	unknown
NZ_CP024949.1\|WP_145820941.1\|1220339_1221122_+\|NAD+-synthase	unknown	unknown	gnl\|CDD\|184435
NZ_CP024949.1\|WP_000051414.1\|1218037_1218271_-\|cell-division-topological-specificity-factor-MinE	unknown	unknown	gnl\|CDD\|188120
NZ_CP024949.1\|WP_145820934.1\|1215821_1216160_-\|hypothetical-protein	unknown	unknown	unknown

Protein	Function_ID	Function_description	E-value
NZ_CP024949.1\|WP_001019055.1\|1218267_1219074_-\|septum-site-determining-protein-MinD	gnl\|CDD\|225447	COG2894, MinD, Septum formation inhibitor-activating ATPase [Cell division and chromosome partitioning].	1.14895e-150
NZ_CP024949.1\|WP_145821537.1\|1215014_1215221_-\|lysozyme	gnl\|CDD\|381599	cd00737, lyz_endolysin_autolysin, endolysin and autolysin. The dsDNA phages of eubacteria use endolysins or muralytic enzymes in conjunction with hollin, a small membrane protein, to degrade the peptidoglycan found in bacterial cell walls. Similarly, bacteria produce autolysins to facilitate the biosynthesis of its cell wall heteropolymer peptidoglycan and cell division. Endolysins and autolysins are found in viruses and bacteria, respectively. Both endolysin and autolysin enzymes cleave the glycosidic beta 1,4-bonds between the N-acetylmuramic acid and the N-acetylglucosamine of the peptidoglycan.	0.00249574
NZ_CP024949.1\|WP_145820924.1\|1211187_1212069_+\|RluA-family-pseudouridine-synthase	gnl\|CDD\|223638	COG0564, RluA, Pseudouridylate synthases, 23S RNA-specific [Translation, ribosomal structure and biogenesis].	7.80102e-65
NZ_CP024949.1\|WP_145821539.1\|1219097_1220090_-\|ketol-acid-reductoisomerase	gnl\|CDD\|235491	PRK05479, PRK05479, ketol-acid reductoisomerase; Provisional.	7.91367e-180
NZ_CP024949.1\|WP_145820936.1\|1216344_1216698_-\|sel1-repeat-family-protein	gnl\|CDD\|276807	sd00010, SLR, Sel1-like repeat. Sel1-like repeats (SLRs) share similar alpha-helical conformations with Tetratricopeptide repeats (TPRs), but with different consensus sequence lengths and superhelical topologies. SLRs contain 36 to 44 amino acids and are present in bacteria and eukaryotes but not in archaea. SLR proteins are involved in a variety of functions, and many serve as adaptor proteins for the assembly of macromolecular complexes. The SLR family was named after the Caenorhabditis elegans Sel1 protein which is predicted to fold into 11 SLRs, a transmembrane domain, and an N-terminal signal sequence. The human Sel1L protein contains an additional fibronectin type-II domain and an N-terminal PEST sequence. Its downregulation is associated with the development of breast and pancreatic carcinomas.	1.44337e-22
NZ_CP024949.1\|WP_145820922.1\|1209637_1211188_+\|single-stranded-DNA-specific-exonuclease-RecJ	gnl\|CDD\|273193	TIGR00644, recJ, single-stranded-DNA-specific exonuclease RecJ. All proteins in this family are 5'-3' single-strand DNA exonucleases. These proteins are used in some aspects of mismatch repair, recombination, and recombinational repair. [DNA metabolism, DNA replication, recombination, and repair].	0
NZ_CP024949.1\|WP_000829865.1\|1207090_1207753_-\|hypothetical-protein	gnl\|CDD\|239486	cd03392, PAP2_like_2, PAP2_like_2 proteins. PAP2 is a super-family of phosphatases and haloperoxidases. This subgroup, which is specific to bacteria, lacks functional characterization and may act as a membrane-associated lipid phosphatase.	9.98042e-15
NZ_CP024949.1\|WP_000201859.1\|1204300_1205332_-\|flagellar-motor-switch-protein-FliG	gnl\|CDD\|272961	TIGR00207, Flagellar_motor_switch_protein_FliG, flagellar motor switch protein FliG. The fliG protein along with fliM and fliN interact to form the switch complex of the bacterial flagellar motor located at the base of the basal body. This complex interacts with chemotaxis proteins (eg CHEY). In addition the complex interacts with other components of the motor that determine the direction of flagellar rotation. The model contains putative members of the fliG family at scores of less than 100 from Agrobacterium radiobacter and Sinorhizobium meliloti as well as fliG-like genes from treponema pallidum and Borrelia burgdorferi. That is why the suggested cutoff is set at 20 but was set at 100 to construct the family. [Cellular processes, Chemotaxis and motility].	1.07e-164
NZ_CP024949.1\|WP_000056261.1\|1203537_1204314_-\|flagellar-assembly-protein-FliH	gnl\|CDD\|235850	PRK06669, fliH, flagellar assembly protein H; Validated.	2.24935e-65
NZ_CP024949.1\|WP_145820945.1\|1221989_1222532_-\|UDP-4-amino-4,-6-dideoxy-N-acetyl-beta-L-altrosamine-N-acetyltransferase	gnl\|CDD\|274661	TIGR03585, PseH, UDP-4-amino-4,6-dideoxy-N-acetyl-beta-L-altrosamine N-acetyltransferase. Sequences in this family are members of the pfam00583 (GNAT) superfamily of acetyltransferases and are proposed to perform a N-acetylation step in the process of pseudaminic acid biosynthesis in Campylobacter species. This gene is commonly observed in apparent operons with other genes responsible for the biosynthesis of pseudaminic acid and as a component of flagellar and exopolysaccharide biosynthesis loci. Significantly, many genomes containing other components of this pathway lack this gene, indicating that some other N-acetyl transferases may be incolved and/or the step is optional, resulting in a non-acetylated pseudaminic acid variant sugar.	1.39564e-58
NZ_CP024949.1\|WP_145820939.1\|1217230_1218031_-\|DNA-protecting-protein-DprA	gnl\|CDD\|273238	TIGR00732, Protein_smf, DNA protecting protein DprA. Disruption of this gene in both Haemophilus influenzae and Helicobacter pylori drastically reduces the efficiency of transformation with exogenous DNA, but with different levels of effect on chromosomal (linear) and plasmid (circular) DNA. This difference suggests the DprA is not active in recombination, and it has been shown not to affect DNA binding, leaving the intermediate step in natural transformation, DNA processing. In Strep. pneumoniae, inactivation of dprA had no effect on the uptake of DNA. All of these data indicated that DprA is required at a later stage in transformation. Subsequently DprA and RecA were both shown in S. pneumoniae to be required to protect incoming ssDNA from immediate degradation. Role of DprA in non-transformable species is not known. The gene symbol smf was assigned in E. coli, but without assignment of function. [Cellular processes, DNA transformation].	2.30224e-94
NZ_CP024949.1\|WP_145820920.1\|1208011_1209628_+\|CTP-synthase-(glutamine-hydrolyzing)	gnl\|CDD\|235437	PRK05380, pyrG, CTP synthetase; Validated.	0
NZ_CP024949.1\|WP_145820943.1\|1221118_1222057_+\|tetraacyldisaccharide-4'-kinase	gnl\|CDD\|224577	COG1663, LpxK, Tetraacyldisaccharide-1-P 4'-kinase [Cell envelope biogenesis, outer membrane].	3.69259e-90
NZ_CP024949.1\|WP_145820941.1\|1220339_1221122_+\|NAD+-synthase	gnl\|CDD\|184435	PRK13980, PRK13980, NAD synthetase; Provisional.	1.02601e-125
NZ_CP024949.1\|WP_000051414.1\|1218037_1218271_-\|cell-division-topological-specificity-factor-MinE	gnl\|CDD\|188120	TIGR01215, Cell_division_topological_specificity_factor, cell division topological specificity factor MinE. This protein is involved in the process of cell division. This protein prevents the proteins MinC and MinD to inhibit cell division at internal sites, but allows inhibiton at polar sites. This allows for correct cell division at the proper sites. [Cellular processes, Cell division].	1.07135e-25
NZ_CP024949.1\|WP_145820937.1\|1216829_1217234_-\|Holliday-junction-resolvase-RuvX	gnl\|CDD\|234639	PRK00109, PRK00109, Holliday junction resolvase RuvX.	9.94891e-38

>NZ_CP024949.1|WP_145821537.1|1215014_1215221_-|lysozyme
MDSERFSLSIYTDKTRHPTIGYGYNLSVYSYESKRITKAYGLLTDILKKNHKALLSYEWYKNLDAMRF
>NZ_CP024949.1|WP_145820930.1|1214760_1215021_-|lysozyme
MLKLGGCEKHCKKKYTIEKVIKEVGLELKSKSVMPYFFNEYDLTKNANREEPERLRRQVISILMRTPKGREILKEYLNEGCILLGE
>NZ_CP024949.1|WP_145820928.1|1214653_1214749_-|hypothetical-protein
MLKNFKKAFFRALCLGAWCLLGEWCNNLGRL
>NZ_CP024949.1|WP_145820926.1|1213295_1214081_-|hypothetical-protein
MSYFFKIILGTSVIVGALLDLWRWIYDKFCFSLVFVLLILGIVAYSYISLKMHQRKCFAKCFVNSESFLSKMLHSPIMVSCFYFIFSIFTSISIAYSVLDYNWMMWGIVFCTIVVCAVVFGALEKMLKNIIKEDYLMLISREVSAFVGTLFFIGLSCYVIYHGNMPDYLRPALIDTIKAASDSAYSNCDYTSYVLEFKKMLERVTWWGMHKAESMGLNKGFMVAGWVAFIIYNALSGIAISRLSAQIIYWLSKYFRGECGK
>NZ_CP024949.1|WP_145820924.1|1211187_1212069_+|RluA-family-pseudouridine-synthase
MPFVEEEFEILKPTKALFLVRDVLKCSLKEAQRHLDKQRLKQNQQAVRKSQMIQGVVRLIYFKPNEKTQALVFETKDFGVFDKPAQVYTHPKGYFYHESLLDCIQSHLGKNAHPAHRLDYETSGLVLAGKTLQSTKDLKALFMQKKVKKTYLALAHGLVEKSMKIDKPILTPQNIQKDLRIRSKISPLGKLSITLVDPLSYNPFLDISLLKITPITGRTHQIRLHLSSVGHRIVGEGLYGVADEEAREYLQLKRENHAPLLMLHAASLEFEFKKAIYKITSQMPQRFMPFLKD
>NZ_CP024949.1|WP_145820922.1|1209637_1211188_+|single-stranded-DNA-specific-exonuclease-RecJ
MKQKLKAQIKERVASIAYNEKGFPSPFLFKDLKKAALKIIEAMRANTEILVVGDYDADGVISSTIMAKFFKSLDYKHVRVAIPNRFMDGYGISKKFLEKHHAPLIITVDNGINAFEAAQFCKEKNYTLIITDHHCLHHDKIPDAYAVINPKQPDCDFIQKEVCGALVAFYLCYGIHKLLGKEKSHSSELLCLAGVATIADMMPLTFFNRFLVSKALYFLQKESLGAMGFLRQREVFRKRSLKASDISFNIAPLINSAGRMQDAKMALDFLSTNNFQDGYSLYERLKACNTKRKMIQQQVFEEAFKHAMVGEKIIVAFKDNWHEGVLGIVASKLVEATQKPSLVFTFKEGVYKGSARSSPNIDLIDALNGVSSLLLGYGGHRQACGLSVGKNNIVSLFETLENFDFKVLPFYETEPPLTLNLKDIDRELLEIIEMGEPYGQENPEPLFQAQNLEVIEEKIIKESHQVLRFKDKECVKEAIYFNAERFLKAGEKVSAIFSVELDECSNEPKMFVKSLL
>NZ_CP024949.1|WP_145820920.1|1208011_1209628_+|CTP-synthase-(glutamine-hydrolyzing)
MDRAKFIFVTGGVLSSLGKGISSSSIATLLQHCNYQVSILKIDPYINIDPGTMSPLEHGEVFVTSDGAETDLDIGHYERFLNRNLTRLNNFTTGQIFSSVIENERKGEYLGKTIQIVPHVTDEIKRRIRSAAKGLDFLIVEVGGTVGDMEGMFYLEAIRQLKLELGNEKVINVHVTLIPYIQTTNELKTKPTQHSVQELRRLGVTPQIILARSPKPLDKELKNKIALSCDVEQDSVIVATDTKSIYACPILFLQEGILTPIARRFNLNKLHPKMAAWNTLVEKIIAPKHKVKIGFVGKYLSLKESYKSLIEALIHAGAHLDVQVNIEWLDSENFNEKTDLEGVDAILVPGGFGERGIEGKICAIQRARLEKLPFLGICLGMQLAIVEFCRNVLGLKRANSTEFNQRCEYPVVYLIEDFMDQNHQKQVRTYNSPLGGTMRLGEYECEIMPNSLLEKAYKKPSIKERHRHRYEINPKYRQEWENKGLKVVGFGANHLIEAIELEDHPFFVGVQFHPEFTSRLQSPNPIILDFIKSALSKS
>NZ_CP024949.1|WP_000829865.1|1207090_1207753_-|hypothetical-protein
MAENSFKNVSTQPKAFFLLPVKTLFLLGSVFSAFFILIAGLVFFDYANSMDHAIFSLMRSNSSNPILDQTLRRVVFLGSSQFVLPLSLLVGVFLSLYRRNLALGVWFVLSVILFEALLESLKHLLAHSIQWLSHSANFPSAIALSLTLFYGLLVLLIPHLITHQIFQNILSYSLLGLIFLIGLALIVLGVSFSSVLGGVCLGALGACFSIGIYLSVFQKI
>NZ_CP024949.1|WP_000201859.1|1204300_1205332_-|flagellar-motor-switch-protein-FliG
MATKLTPKQKAQLDELSMSEKIAILLIQVGEDTTGEILRHLDIDSITEISKQIVQLNGTDKQIGAAVLEEFFAIFQSNQYINTGGLEYARELLTRTLGSEEARKVMDKLTKSLQTQKNFAYLGKIKPQQLADFIINEHPQTIALILAHMEAPNAAETLSYFPDEMKAEISIRMANLGEISPQVVKRVSTVLENKLESLTSYKIEVGGLRAVAEIFNRLGQKSAKTTLARIESVDNKLAGAIKEMMFTFEDIAKLDNFAIREILKVADKKDLSLALKTSTQDLTDKFLNNMSSRAAEQFVEEMQYLGAVKIKDVDVAQRKIIEIVQSLQEKGVIQTGEEEDVIE
>NZ_CP024949.1|WP_000056261.1|1203537_1204314_-|flagellar-assembly-protein-FliH
MSLNSRKNLIQKDHLNKHDIQKYEFKSMANLPPKTNPNGASLETPNPQEPLEKKAIENDLIDCLLKKTDELSSHLVKLQMQFEKAQEESKALIENAKNDGYKIGFKEGEEKMRNELTHSVNEEKNQLLHAITALDEKMKKSQDHLMALEKELSAIAIDIAKEVILKEVEDNSQKVALALAEELLKNVLDATDIHLKVNPLDYPYLNERLQNASKIKLESNEAISKGGVMITSSNGSLDGNLMERFKTLKESVLENFKV
>NZ_CP024949.1|WP_145820934.1|1215821_1216160_-|hypothetical-protein
MKIMHQVRDFLDSCKQTIQKNSSEVFQKTKRALFKEESQKIREQAVKIVEKRLKKESMKLSDFNEEELKIMFEAEEKRLLEQIHAKELKEKQEKTTKHFKEIWEKGDNEQGK
>NZ_CP024949.1|WP_145820936.1|1216344_1216698_-|sel1-repeat-family-protein
MASQTPEELFDLGVKSIEARDYIQAKKYFEKACDLKYGGGCGALGDLYDDVEKNLIKAAQLYSKACDLNNSVGCGALGMLYEFGQGVEKNLTKATQLYSKACKLGFQKTCEILKELK
>NZ_CP024949.1|WP_145820937.1|1216829_1217234_-|Holliday-junction-resolvase-RuvX
MILACDVGLKRIGIAVLLNGVILPLEAILRHNRNQASRDLSDLLREKNIQVLVVGKPNESYADTNARIEYFIKLLDFKGEIVFINEDRSSIEAYENLEHLGKKNKRLATKDGRLDSLSACKILERYCQQVLKNH
>NZ_CP024949.1|WP_145820939.1|1217230_1218031_-|DNA-protecting-protein-DprA
MKSNFQYGALENIPKAFDILKDPPKKLYCVGDTKLLEAPLKVAIIGTRRPTPYSKQHTITLARELAKNGAVIVSGGALGVDIIAQENALPKTIMLSPCSLDFIYPTNNHKVIQEIAQNGLILSEYEKDFMPVKGSFLARNRLVIALSDAVIIPQADLKSGSMSSARLAQKYQKPLFVLPQRLNESDGTNELLEKGQAQGIFNIQNFINTLLKDHHLKEMPEMKDEFLEYCAKNPSYEEAYLKFGDKLLEYELLGKIKRINHIVVLA
>NZ_CP024949.1|WP_000051414.1|1218037_1218271_-|cell-division-topological-specificity-factor-MinE
MSLFDFFKNKGSAATATDRLKLILAKERTLNLPYMEEMRKEIIAVIQKYTKSSDIHFKTLDSNQSVETIEVEIILPK
>NZ_CP024949.1|WP_001019055.1|1218267_1219074_-|septum-site-determining-protein-MinD
MAIVVTITSGKGGVGKSTTTANLAIGLAESGKKVVAVDFDIGLRNLDMILGLENRIVYDVVDVMEKNCNLSQALITDKKTKNLSFLAASQSKDKNILDKEKVAILINALRADFDYILIDSPAGIESGFEHAILHADMALVVVTPEVSSLRDSDRVIGIIDAKSNRAKRGEEVHKHLIINRLKPELVANGEMISIEEVLKILCLPLIGIIPEDSHIISATNKGEPVIRTDCESAKAYQRITRRILGEEVEYVEFKAKKGFFSALKGIFS
>NZ_CP024949.1|WP_145821539.1|1219097_1220090_-|ketol-acid-reductoisomerase
MALPVYYDKDIDLGVIQSLQVGIIGYGAQGEAQALNLRDSKVRVRIGLYQGSLSVSKAKKEGFEVLEVKELVQQSDVIMALLPDELHKEVLEKEVIPFLKEGQIVGFAHGFSVHFNQVVLPKGVGAILVAPKGPGSALREEYLKNRGLYHLIAIEQESSKYNAKAVALSYAKAMGGGRMGVLETSFKEECESDLFGEQAVLCGGLEAIVRMGFETLIKAGYPEELAYFECVHEVKLVADLLHHKGVEGLRKHISNTAEFGAIKHREPMGNLLKKRMQKILKKIQNGSFAKDFLLEKSLNYPRLNTERKALKGTKIEQIGEILRAPFNHKK
>NZ_CP024949.1|WP_145820941.1|1220339_1221122_+|NAD+-synthase
MQKDYQKLIVYLCDFLEKEVQKKGFKKVVYGLSGGLDSAVVGVLCQKVFKENAHALLMPSSVSMPESKTDALNLCETFSIPYTEYSIAPYDAIFGSHFKDASLTRKGNFCARLRMAFLYDYSLKSDSLVIGTSNKSERMLGYGTLFGDLACAINPIGELFKTEVYELARRLNIPKKILNKPPSADLFVGQSDEKDLGYPYSVIDPLLKDIEALFKNKPIDAETLTQLGYDEILVKNITSRIQKNAFKLELPTIAQKFNPK
>NZ_CP024949.1|WP_145820943.1|1221118_1222057_+|tetraacyldisaccharide-4'-kinase
MKSDKPFLERYFYDPTLLQKGLIFALYPFSLIYQGIATLKRKMAKKHDFKIPLISIGNLIAGGSGKTPFILEIAPRYQEVAVVSRGYQRDSQGLVVVSVKGNILVSQQTAGDEAYLLALNLKQASVIVSEKRELGVLKALELGAKIVFLDDGFRFNFNQFNLLLKPKVPPYYPFCLPSGLYRESIKSYKEAHLVVTEDKDYKRITSIAHPTKHMLLVTAIANPSRLDAFLPKEVVKKLYFRDHAPFNLELLEKEFYQNSATSLLVTSKDLVKLQDCNLPLSVLNLKLEICPKVLEEIDRYILSYPCNTKERL
>NZ_CP024949.1|WP_145820945.1|1221989_1222532_-|UDP-4-amino-4,-6-dideoxy-N-acetyl-beta-L-altrosamine-N-acetyltransferase
MKKNYSYGNIQAIDFIHLNDEEKLLVLEFRNHPNTALWMYSAFISLKTHLQFIEDLKNSPNHRYFLFKEGGVYLGVGSITKINFFHKHGYLGIYKNPFLKNGGEAILKALECIAFEEFQLNSLHLEVMENNFKAIAFYEKNHYELEGRLKGFISKDKEFIDVLLYYKDKKGYNDQSPLKL

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Self-targeting detection

CRISPR_ID	Spacer_Info	Spacer_region	Spacer_length	Hit_ID	Protospacer_location	Mismatch	Identity

MGE targeting detection<

CRISPR_ID	Spacer_Info	Spacer_region	Spacer_length	Hit_phage_ID	Hit_phage_def	Protospacer_location	Mismatch	Identity
NZ_CP024949_3	3.2\|459793\|34\|NZ_CP024949\|CRISPRCasFinder	459793-459826	34	MG945382	UNVERIFIED: Microviridae sp. isolate 3159-1801, complete genome	824-857	8	0.765

1. spacer 3.2|459793|34|NZ_CP024949|CRISPRCasFinder matches to MG945382 (UNVERIFIED: Microviridae sp. isolate 3159-1801, complete genome) position: , mismatch: 8, identity: 0.765

gaaagcgctgttttgaaaagcagattgagcgctg-	CRISPR spacer
taccgcgctattttgaaaagcagatggaa-gcaga	Protospacer
 *  *****.*************** **. ** *

Prophage detection

Region	Region Position	Protein_number	Hit_taxonomy	Key_proteins	Att_site	Prophage annotation

Anti-CRISPR protein detection

Acr ID	Acr position	Acr size	Homology with known anti	Neighbor HTH/AcRanker	Neighbor Aca	In prophage	Protospacer in prophage