CGDB: Circadian Gene DataBase

Circadian Info
PTMs
Sequence
Orthology
Keyword
GO
TOP

CGDB Gene Information

Tag

Content

CGDB ID

CGD-RaN-021797

Uniprot Accession

Q8CJE2; Q8CJE2; PER3_RAT

Protein Name

Period circadian protein homolog 3

Gene Name

Per3

Genbank Protein ID

NP_076468.2

Genbank Nucleotide ID

NM_023978.2

EMBL (Genbank) ID

BAC16806.1

Organism

Rattus norvegicus

NCBI Taxa ID

10116

Circadian Information

Evidence	Phase			Amplitude (FOLD)	Sentence	Tissue/Cell	Data type	PMID
Evidence	Peak	Trough	External condition	Amplitude (FOLD)	Sentence	Tissue/Cell	Data type	PMID
Small-scale	ZT 12	ZT 0	LD	25.00	Pertranscription factors Per1, Per2, and Per3 peaked during the early dark period in abdominal adipose tissue of rats.	abdominal adipose tissue	Small-scale	[1]
Small-scale	ZT 0	ZT 12	LD	6.00	The mRNA level of PER3 is under circadian control in SCN of Sprague-Dawley rats.	SCN	Small-scale	[1]
Small-scale	ZT 0	ZT 12	LD	2.30	The mRNA level of PER3 is under circadian control in basolateral nucleus of the amygdala of Sprague-Dawley rats.	basolateral nucleus of the amygdala	Small-scale	[1]
Small-scale	ZT 12	ZT 0	LD	5.00	The mRNA level of PER3 is under circadian control in entral nucleus of the amygdala of Sprague-Dawley rats.	entral nucleus of the amygdala	Small-scale	[1]
Small-scale	ZT 0	ZT 12	LD	4.50	The mRNA level of PER3 is under circadian control in hippocampus of Sprague-Dawley rats.	hippocampus	Small-scale	[1]
Small-scale	ZT 4	ZT 16	LD	14.00	The mRNA level of PER3 is under circadian control in nucleus accumbens cores of Sprague-Dawley rats.	nucleus accumbens core	Small-scale	[1]
Small-scale	ZT 0	ZT 12	LD	5.00	The mRNA level of PER3 is under circadian control in nucleus accumbens shell of Sprague-Dawley rats.	nucleus accumbens shell	Small-scale	[1]
Small-scale	ZT 4	ZT 16	LD	8.00	The mRNA level of PER3 is under circadian control in prefrontal cortex of Sprague-Dawley rats.	prefrontal cortex	Small-scale	[1]
Small-scale	ZT 4	ZT 16	LD	2.00	The mRNA level of PER3 is under circadian control in ventral tegmental area of Sprague-Dawley rats.	ventral tegmental area	Small-scale	[1]

Description

Functional Description

Originally described as a core component of the circadian clock. The circadian clock, an internal time-keeping system, regulates various physiological processes through the generation of approximately 24 hour circadian rhythms in gene expression, which are translated into rhythms in metabolism and behavior. It is derived from the Latin roots ''circa'' (about) and ''diem'' (day) and acts as an important regulator of a wide array of physiological functions including metabolism, sleep, body temperature, blood pressure, endocrine, immune, cardiovascular, and renal function. Consists of two major components: the central clock, residing in the suprachiasmatic nucleus (SCN) of the brain, and the peripheral clocks that are present in nearly every tissue and organ system. Both the central and peripheral clocks can be reset by environmental cues, also known as Zeitgebers (German for ''timegivers''). The predominant Zeitgeber for the central clock is light, which is sensed by retina and signals directly to the SCN. The central clock entrains the peripheral clocks through neuronal and hormonal signals, body temperature and feeding-related cues, aligning all clocks with the external light/dark cycle. Circadian rhythms allow an organism to achieve temporal homeostasis with its environment at the molecular level by regulating gene expression to create a peak of protein expression once every 24 hours to control when a particular physiological process is most active with respect to the solar day. Transcription and translation of core clock components (CLOCK, NPAS2, ARNTL/BMAL1, ARNTL2/BMAL2, PER1, PER2, PER3, CRY1 and CRY2) plays a critical role in rhythm generation, whereas delays imposed by post-translational modifications (PTMs) are important for determining the period (tau) of the rhythms (tau refers to the period of a rhythm and is the length, in time, of one complete cycle). A diurnal rhythm is synchronized with the day/night cycle, while the ultradian and infradian rhythms have a period shorter and longer than 24 hours, respectively. Disruptions in the circadian rhythms contribute to the pathology of cardiovascular diseases, cancer, metabolic syndromes and aging. A transcription/translation feedback loop (TTFL) forms the core of the molecular circadian clock mechanism. Transcription factors, CLOCK or NPAS2 and ARNTL/BMAL1 or ARNTL2/BMAL2, form the positive limb of the feedback loop, act in the form of a heterodimer and activate the transcription of core clock genes and clock-controlled genes (involved in key metabolic processes), harboring E-box elements (5''-CACGTG-3'') within their promoters. The core clock genes: PER1/2/3 and CRY1/2 which are transcriptional repressors form the negative limb of the feedback loop and interact with the CLOCK|NPAS2-ARNTL/BMAL1|ARNTL2/BMAL2 heterodimer inhibiting its activity and thereby negatively regulating their own expression. This heterodimer also activates nuclear receptors NR1D1, NR1D2, RORA, RORB and RORG, which form a second feedback loop and which activate and repress ARNTL/BMAL1 transcription, respectively. Has a redundant role with the other PER proteins PER1 and PER2 and is not essential for the circadian rhythms maintenance. In contrast, plays an important role in sleep-wake timing and sleep homeostasis probably through the transcriptional regulation of sleep homeostasis-related genes, without influencing circadian parameters. Can bind heme (By similarity).

Protein Sequence
(Fasta)

MDPCGNPAVP GGDCPQTRGP GLQGSSGQEG PLQGICVDSS HSEHEDRNRM SEELIMVVQE 60
MKKYFPAERH TKPSTLDALN YALRCVHSVQ ANSEFFQSLS PRGARQAEAT VYNLEELTSL 120
ASEHTSKNTD TFVAVFSFLS GRLVHISEQA AWILNSKKGF LKSLHFVDLL APRDVRVFYA 180
HTAPTQLPFW NTWTQRASQY ECAPVKPFFC RICGGGDREQ KRHYSPFRIL PYLVHVHSPA 240
QPEPEPCCLT LVEKIHSGYE APRIPVDKRV FTTTHTPGCV FLEVDERAVP LLGFLPQDLI 300
GTSILTYLHP EDRPLMVAVH QKVLKYVGHP PFEHSPIRFC TQNGDYVILD SSWSSFVNPW 360
SRKVSFIIGR HKVRTSPLNE DVFATRIKKA TSHDEDITEL QEQIHRLLLQ PVHASASSGY 420
GSLGSSGSQE QHISVTSSSE SSGHCVEEAQ QEQMTLQQVY ASVNKIKNVG QQLYIESMAR 480
SSVKPVMETC TEPQGSDEQK DFSSSQTLKN KSTDTGSGGD LRPEQHSSSY QQMNCIDSVI 540
RYLTSYSFPA LKRKCISCTN TSSSSEEAKP NPEADGSLRD TEQLLDIPEQ ETTTPSADAE 600
GGVARTLSTA ALSMASGVSQ CSCSSTTDHV PPLQSESVAG ACEPWALRTK AHVTAEGFKP 660
VGLTAAVLSA HTQKEEQNYV DRFREKILTS PYGCYLQQEG RNHAKYACVV GAGATPKHSR 720
CAGSERRKHK RKKLPTPVDS SSSSAHLCPH VRGLLPDVQH WSASVTSPCA TGLALPSALV 780
VPNQTPYLLS SFPLQDMAPH GVGDSAPWGA AAECPPLSAG PHPVSTFPSA YMGTFMTVLL 840
HNSPLFPLWP ASFSPYPFLG ATGPSQMAPL VPAMAPDLEP TPSDHGPRRV EENWETHSEE 900
EHPFISSRSS SPLQLNLLQE EMPAPSEYAD ALRRGACPDA KQLCVTGNSG SRSPPCATGE 960
LATASVQQES PSAAASGSSA SSVHGSGSDY TSEVSENGQR SQDTHRDRAF SGAAEESIWR 1020
MIERTPQCVL MTYQVPERGR DTVLREDLEK LHSMERQRPQ FSSAQKEELA KVRSWIHSHP 1080
APEERQLQRA MSPVKTEVQL VTLQRPVNSV QQKTPVEQL 1119

Nucleotide Sequence
(Fasta)

ATGGATCCCT GTGGAAACCC GGCAGTGCCT GGTGGCGACT GTCCCCAAAC TAGGGGACCG 60
GGGCTCCAAG GGTCGTCTGG CCAGGAGGGT CCTCTGCAGG GCATTTGCGT GGACAGCAGC 120
CACAGTGAAC ATGAAGACCG AAACAGAATG TCTGAAGAGC TTATAATGGT TGTCCAAGAA 180
ATGAAAAAGT ATTTCCCAGC CGAGAGACAC ACTAAACCCA GCACCCTAGA TGCCCTTAAC 240
TATGCCCTAC GCTGTGTACA TAGTGTGCAA GCAAACAGTG AATTTTTCCA GAGTCTCAGT 300
CCACGTGGAG CACGTCAGGC AGAAGCGACT GTATATAATC TCGAGGAGCT GACCTCTCTG 360
GCTTCTGAAC ATACTTCCAA GAACACAGAT ACCTTCGTGG CAGTGTTTTC GTTTCTGTCT 420
GGAAGGCTGG TGCACATTTC TGAACAGGCT GCTTGGATCC TGAATTCTAA GAAAGGTTTC 480
CTCAAGAGCT TGCACTTCGT CGACCTGCTT GCCCCTCGGG ACGTGAGGGT GTTCTACGCT 540
CACACCGCTC CAACTCAACT CCCTTTCTGG AACACCTGGA CCCAAAGAGC CTCGCAGTAT 600
GAATGCGCAC CAGTGAAGCC CTTTTTCTGC AGAATCTGTG GCGGTGGAGA CAGGGAGCAG 660
AAGAGACATT ACTCCCCATT CCGGATCCTC CCCTACTTGG TTCATGTACA CAGCCCTGCC 720
CAGCCAGAGC CAGAGCCTTG CTGTCTAACA CTGGTTGAAA AGATTCACTC TGGTTATGAA 780
GCTCCTCGAA TCCCTGTAGA TAAAAGAGTT TTTACCACAA CACACACGCC GGGATGTGTG 840
TTTCTTGAAG TAGATGAAAG AGCAGTGCCT TTGCTGGGTT TCCTACCTCA GGATCTGATT 900
GGAACGTCGA TCTTAACGTA CTTGCACCCA GAAGATCGGC CTCTGATGGT TGCAGTACAC 960
CAAAAAGTTT TAAAGTACGT GGGCCACCCT CCATTTGAAC ACTCACCCAT AAGATTCTGC 1020
ACGCAGAATG GAGATTATGT CATTCTGGAT TCCAGCTGGT CCAGCTTTGT GAACCCCTGG 1080
AGCCGGAAGG TCTCCTTCAT CATTGGTCGA CATAAAGTCC GAACGAGCCC GTTAAATGAA 1140
GATGTTTTTG CCACCAGAAT AAAAAAGGCA ACCAGTCATG ACGAAGACAT AACAGAATTA 1200
CAAGAACAAA TTCACAGACT TCTCTTGCAG CCGGTTCATG CCAGTGCTTC CAGTGGCTAC 1260
GGGAGCCTGG GCAGCAGTGG CTCGCAGGAG CAGCACATCA GCGTCACCTC TTCCAGTGAG 1320
TCAAGCGGAC ACTGTGTGGA GGAAGCCCAG CAGGAGCAGA TGACCCTGCA GCAGGTCTAT 1380
GCCAGTGTAA ACAAAATTAA GAATGTGGGC CAACAGCTCT ACATCGAGTC GATGGCCAGA 1440
TCGTCGGTGA AGCCAGTGAT GGAGACGTGC ACGGAACCGC AGGGTAGTGA TGAGCAGAAG 1500
GACTTTTCTT CCTCTCAGAC ACTGAAAAAT AAAAGCACAG ATACCGGCTC TGGAGGCGAT 1560
CTGCGGCCAG AACAGCATAG CTCGTCCTAT CAGCAGATGA ACTGCATCGA CAGTGTCATC 1620
AGGTACCTGA CAAGCTACAG TTTCCCAGCC TTGAAAAGAA AGTGCATCTC CTGCACAAAC 1680
ACGTCTTCAT CCTCAGAGGA AGCCAAGCCA AACCCAGAGG CAGACGGCAG CCTGCGAGAC 1740
ACCGAACAGC TCCTGGACAT TCCAGAACAG GAAACAACCA CACCATCCGC AGACGCCGAG 1800
GGAGGTGTTG CACGGACCCT GTCCACTGCC GCACTGAGCA TGGCGTCTGG CGTAAGCCAG 1860
TGCAGCTGCA GCAGCACCAC GGACCATGTC CCCCCCCTAC AGTCAGAAAG TGTTGCCGGA 1920
GCGTGTGAGC CCTGGGCCCT GAGAACGAAG GCTCACGTGA CCGCAGAAGG ATTCAAGCCC 1980
GTGGGGCTCA CAGCGGCCGT CCTCTCCGCG CACACGCAGA AGGAAGAGCA GAACTATGTT 2040
GACAGGTTCC GGGAGAAGAT CCTGACCTCG CCCTACGGCT GTTATCTTCA GCAAGAAGGC 2100
AGGAACCATG CCAAGTACGC CTGCGTCGTC GGAGCAGGGG CCACCCCTAA GCACAGCAGA 2160
TGTGCTGGAA GTGAGAGACG GAAGCACAAA CGGAAGAAGC TGCCGACGCC TGTGGACAGC 2220
AGCAGCTCCA GTGCCCACCT CTGTCCCCAT GTCAGAGGAC TCCTTCCAGA TGTGCAGCAC 2280
TGGAGCGCTT CCGTTACCTC TCCCTGTGCT ACAGGCCTAG CTCTCCCCTC AGCCCTGGTG 2340
GTTCCCAACC AGACCCCGTA TCTCCTCTCC TCTTTTCCCC TTCAAGACAT GGCCCCTCAC 2400
GGAGTAGGGG ACTCCGCACC CTGGGGTGCT GCAGCCGAAT GTCCACCTCT GTCCGCTGGT 2460
CCCCACCCTG TTTCCACGTT CCCTTCTGCT TACATGGGTA CTTTCATGAC CGTCCTCCTG 2520
CACAACAGCC CTCTCTTTCC TCTGTGGCCG GCATCATTCT CTCCATATCC ATTCCTGGGG 2580
GCCACAGGTC CTTCTCAAAT GGCACCCTTA GTACCAGCAA TGGCTCCAGA CCTGGAACCA 2640
ACCCCTTCAG ACCACGGCCC AAGGAGAGTG GAGGAGAACT GGGAGACACA CAGCGAAGAA 2700
GAGCATCCGT TTATTAGCTC ACGGAGCAGT TCACCATTGC AGTTAAATTT ACTCCAGGAA 2760
GAAATGCCTG CACCATCAGA GTATGCAGAT GCACTGAGAA GAGGCGCCTG CCCAGACGCT 2820
AAGCAACTCT GTGTTACAGG TAACAGTGGC AGTAGGAGCC CTCCCTGTGC CACAGGTGAG 2880
CTGGCCACAG CATCAGTACA GCAAGAATCT CCATCCGCAG CTGCCTCAGG AAGCAGTGCC 2940
AGCAGTGTAC ACGGCAGTGG CAGTGACTAC ACTTCTGAAG TCTCTGAAAA TGGACAGAGG 3000
TCACAGGATA CACACAGAGA CAGAGCCTTT TCCGGGGCGG CTGAAGAATC TATCTGGAGA 3060
ATGATAGAAC GGACGCCACA GTGTGTTCTC ATGACATACC AGGTGCCGGA GAGGGGTAGA 3120
GACACCGTGC TGAGGGAAGA CCTGGAAAAA CTTCACAGCA TGGAGCGGCA GCGGCCCCAG 3180
TTCTCTTCTG CGCAGAAGGA GGAGCTGGCC AAGGTGCGGT CCTGGATCCA CAGCCACCCT 3240
GCCCCTGAGG AAAGACAGCT CCAAAGAGCT ATGTCACCTG TGAAAACAGA GGTTCAGTTG 3300
GTGACACTGC AGAGGCCTGT GAACAGTGTC CAGCAGAAGA CACCAGTTGA GCAGCTGTGA 3360

Fasta Sequence

>CGD-RaN-021797|BAC16806.1|Per3|Rattus norvegicus
ATGGATCCCTGTGGAAACCCGGCAGTGCCTGGTGGCGACTGTCCCCAAACTAGGGGACCGGGGCTCCAAGGGTCGTCTGGCCAGGAGGGTCCTCTGCAGGGCATTTGCGTGGACAGCAGCCACAGTGAACATGAAGACCGAAACAGAATGTCTGAAGAGCTTATAATGGTTGTCCAAGAAATGAAAAAGTATTTCCCAGCCGAGAGACACACTAAACCCAGCACCCTAGATGCCCTTAACTATGCCCTACGCTGTGTACATAGTGTGCAAGCAAACAGTGAATTTTTCCAGAGTCTCAGTCCACGTGGAGCACGTCAGGCAGAAGCGACTGTATATAATCTCGAGGAGCTGACCTCTCTGGCTTCTGAACATACTTCCAAGAACACAGATACCTTCGTGGCAGTGTTTTCGTTTCTGTCTGGAAGGCTGGTGCACATTTCTGAACAGGCTGCTTGGATCCTGAATTCTAAGAAAGGTTTCCTCAAGAGCTTGCACTTCGTCGACCTGCTTGCCCCTCGGGACGTGAGGGTGTTCTACGCTCACACCGCTCCAACTCAACTCCCTTTCTGGAACACCTGGACCCAAAGAGCCTCGCAGTATGAATGCGCACCAGTGAAGCCCTTTTTCTGCAGAATCTGTGGCGGTGGAGACAGGGAGCAGAAGAGACATTACTCCCCATTCCGGATCCTCCCCTACTTGGTTCATGTACACAGCCCTGCCCAGCCAGAGCCAGAGCCTTGCTGTCTAACACTGGTTGAAAAGATTCACTCTGGTTATGAAGCTCCTCGAATCCCTGTAGATAAAAGAGTTTTTACCACAACACACACGCCGGGATGTGTGTTTCTTGAAGTAGATGAAAGAGCAGTGCCTTTGCTGGGTTTCCTACCTCAGGATCTGATTGGAACGTCGATCTTAACGTACTTGCACCCAGAAGATCGGCCTCTGATGGTTGCAGTACACCAAAAAGTTTTAAAGTACGTGGGCCACCCTCCATTTGAACACTCACCCATAAGATTCTGCACGCAGAATGGAGATTATGTCATTCTGGATTCCAGCTGGTCCAGCTTTGTGAACCCCTGGAGCCGGAAGGTCTCCTTCATCATTGGTCGACATAAAGTCCGAACGAGCCCGTTAAATGAAGATGTTTTTGCCACCAGAATAAAAAAGGCAACCAGTCATGACGAAGACATAACAGAATTACAAGAACAAATTCACAGACTTCTCTTGCAGCCGGTTCATGCCAGTGCTTCCAGTGGCTACGGGAGCCTGGGCAGCAGTGGCTCGCAGGAGCAGCACATCAGCGTCACCTCTTCCAGTGAGTCAAGCGGACACTGTGTGGAGGAAGCCCAGCAGGAGCAGATGACCCTGCAGCAGGTCTATGCCAGTGTAAACAAAATTAAGAATGTGGGCCAACAGCTCTACATCGAGTCGATGGCCAGATCGTCGGTGAAGCCAGTGATGGAGACGTGCACGGAACCGCAGGGTAGTGATGAGCAGAAGGACTTTTCTTCCTCTCAGACACTGAAAAATAAAAGCACAGATACCGGCTCTGGAGGCGATCTGCGGCCAGAACAGCATAGCTCGTCCTATCAGCAGATGAACTGCATCGACAGTGTCATCAGGTACCTGACAAGCTACAGTTTCCCAGCCTTGAAAAGAAAGTGCATCTCCTGCACAAACACGTCTTCATCCTCAGAGGAAGCCAAGCCAAACCCAGAGGCAGACGGCAGCCTGCGAGACACCGAACAGCTCCTGGACATTCCAGAACAGGAAACAACCACACCATCCGCAGACGCCGAGGGAGGTGTTGCACGGACCCTGTCCACTGCCGCACTGAGCATGGCGTCTGGCGTAAGCCAGTGCAGCTGCAGCAGCACCACGGACCATGTCCCCCCCCTACAGTCAGAAAGTGTTGCCGGAGCGTGTGAGCCCTGGGCCCTGAGAACGAAGGCTCACGTGACCGCAGAAGGATTCAAGCCCGTGGGGCTCACAGCGGCCGTCCTCTCCGCGCACACGCAGAAGGAAGAGCAGAACTATGTTGACAGGTTCCGGGAGAAGATCCTGACCTCGCCCTACGGCTGTTATCTTCAGCAAGAAGGCAGGAACCATGCCAAGTACGCCTGCGTCGTCGGAGCAGGGGCCACCCCTAAGCACAGCAGATGTGCTGGAAGTGAGAGACGGAAGCACAAACGGAAGAAGCTGCCGACGCCTGTGGACAGCAGCAGCTCCAGTGCCCACCTCTGTCCCCATGTCAGAGGACTCCTTCCAGATGTGCAGCACTGGAGCGCTTCCGTTACCTCTCCCTGTGCTACAGGCCTAGCTCTCCCCTCAGCCCTGGTGGTTCCCAACCAGACCCCGTATCTCCTCTCCTCTTTTCCCCTTCAAGACATGGCCCCTCACGGAGTAGGGGACTCCGCACCCTGGGGTGCTGCAGCCGAATGTCCACCTCTGTCCGCTGGTCCCCACCCTGTTTCCACGTTCCCTTCTGCTTACATGGGTACTTTCATGACCGTCCTCCTGCACAACAGCCCTCTCTTTCCTCTGTGGCCGGCATCATTCTCTCCATATCCATTCCTGGGGGCCACAGGTCCTTCTCAAATGGCACCCTTAGTACCAGCAATGGCTCCAGACCTGGAACCAACCCCTTCAGACCACGGCCCAAGGAGAGTGGAGGAGAACTGGGAGACACACAGCGAAGAAGAGCATCCGTTTATTAGCTCACGGAGCAGTTCACCATTGCAGTTAAATTTACTCCAGGAAGAAATGCCTGCACCATCAGAGTATGCAGATGCACTGAGAAGAGGCGCCTGCCCAGACGCTAAGCAACTCTGTGTTACAGGTAACAGTGGCAGTAGGAGCCCTCCCTGTGCCACAGGTGAGCTGGCCACAGCATCAGTACAGCAAGAATCTCCATCCGCAGCTGCCTCAGGAAGCAGTGCCAGCAGTGTACACGGCAGTGGCAGTGACTACACTTCTGAAGTCTCTGAAAATGGACAGAGGTCACAGGATACACACAGAGACAGAGCCTTTTCCGGGGCGGCTGAAGAATCTATCTGGAGAATGATAGAACGGACGCCACAGTGTGTTCTCATGACATACCAGGTGCCGGAGAGGGGTAGAGACACCGTGCTGAGGGAAGACCTGGAAAAACTTCACAGCATGGAGCGGCAGCGGCCCCAGTTCTCTTCTGCGCAGAAGGAGGAGCTGGCCAAGGTGCGGTCCTGGATCCACAGCCACCCTGCCCCTGAGGAAAGACAGCTCCAAAGAGCTATGTCACCTGTGAAAACAGAGGTTCAGTTGGTGACACTGCAGAGGCCTGTGAACAGTGTCCAGCAGAAGACACCAGTTGAGCAGCTGTGA

Sequence Source

Uniprot/ENA

Orthology

CGDB ID	Spieces	Identity	E-Value	Score
CGD-AiM-028497	Ailuropoda melanoleuca	65.51	1.00e-153	539.7
CGD-AnP-057114	Anas platyrhynchos	45.57	0.00e+00	660.6
CGD-AsM-051238	Astyanax mexicanus	46	1.00e-160	564.7
CGD-CaJ-041907	Callithrix jacchus	54.7	0.00e+00	1088.9
CGD-CaF-038549	Canis familiaris	55.55	0.00e+00	1127.1
CGD-CaP-050028	Cavia porcellus	48.16	0.00e+00	872.1
CGD-ChS-042175	Chlorocebus sabaeus	57.28	0.00e+00	1176.4
CGD-ChH-060322	Choloepus hoffmanni	49.85	1.00e-162	571.2
CGD-DaR-072762	Danio rerio	39.44	0.00e+00	687.2
CGD-DaN-060659	Dasypus novemcinctus	64.78	0.00e+00	817.4
CGD-DiO-049550	Dipodomys ordii	57.35	0.00e+00	860.1
CGD-EqC-051045	Equus caballus	60.35	0.00e+00	1245.3
CGD-FeC-041831	Felis catus	45.79	0.00e+00	810.1
CGD-FiA-032827	Ficedula albicollis	53.37	0.00e+00	683.3
CGD-GaG-020965	Gallus gallus	48.56	0.00e+00	696.4
CGD-GoG-059542	Gorilla gorilla	53.03	0.00e+00	1045.8
CGD-HoS-062136	Homo sapiens (Human)	56.11	0.00e+00	1149
CGD-IcT-051943	Ictidomys tridecemlineatus	56.56	0.00e+00	1176
CGD-LaC-038253	Latimeria chalumnae	45.99	1.00e-179	628.2
CGD-LeO-053510	Lepisosteus oculatus	41.58	6.00e-144	509.2
CGD-LoA-064706	Loxodonta africana	52.03	0.00e+00	964.5
CGD-MaM-036963	Macaca mulatta	82.66	1.00e-170	596.3
CGD-MaE-031352	Macropus eugenii	60.08	3.00e-167	586.6
CGD-MeL-053407	Melampsora laricipopulina	25.74	3.68e-01	33.5
CGD-MeG-072597	Meleagris gallopavo	54.09	0.00e+00	673.7
CGD-MiM-058960	Microcebus murinus	54.8	0.00e+00	914.1
CGD-MoD-067747	Monodelphis domestica	49.51	0.00e+00	965.3
CGD-MuM-021078	Mus musculus (Mouse)	78.98	0.00e+00	1752.6
CGD-MuP-062621	Mustela putorius furo	49.68	0.00e+00	964.9
CGD-MyL-055612	Myotis lucifugus	54.93	0.00e+00	900.6
CGD-NoL-069268	Nomascus leucogenys	57.6	0.00e+00	1164.4
CGD-OrN-041249	Oreochromis niloticus	46.01	5.00e-158	556.2
CGD-OrL-069692	Oryzias latipes	45.39	4.00e-165	579.7
CGD-OtG-043281	Otolemur garnettii	60.19	0.00e+00	1275
CGD-OvA-022195	Ovis aries	50.92	0.00e+00	1004.2
CGD-PaT-063745	Pan troglodytes	58.48	0.00e+00	1213.4
CGD-PaA-041667	Papio anubis	57.95	0.00e+00	1192.9
CGD-PoA-060690	Pongo abelii	57.12	0.00e+00	1157.9
CGD-PrC-048229	Procavia capensis	46.66	0.00e+00	732.3
CGD-PtV-052486	Pteropus vampyrus	65.16	0.00e+00	898.7
CGD-PyT-071611	Pyrenophora teres	27.49	2.00e-03	41.2
CGD-SaH-047243	Sarcophilus harrisii	51.13	0.00e+00	959.1
CGD-SuS-028663	Sus scrofa	50.62	0.00e+00	971.1
CGD-TaG-047964	Taeniopygia guttata	48.97	0.00e+00	704.9
CGD-TaS-050246	Tarsius syrichta	65.01	0.00e+00	869.8
CGD-TeN-064311	Tetraodon nigroviridis	42.82	2.00e-165	580.5
CGD-TuB-071016	Tupaia belangeri	51.68	0.00e+00	1009.6
CGD-TuT-040951	Tursiops truncatus	54.57	0.00e+00	1062
CGD-ViV-067018	Vitis vinifera	25.96	1.08e-01	35.04
CGD-XeT-062261	Xenopus tropicalis	42.63	0.00e+00	745.7

Keyword

KW-0090--Biological rhythms
KW-0181--Complete proteome
KW-0963--Cytoplasm
KW-0539--Nucleus
KW-0597--Phosphoprotein
KW-1185--Reference proteome
KW-0677--Repeat
KW-0804--Transcription
KW-0805--Transcription regulation
KW-0832--Ubl conjugation

Gene Ontology

GO:0005737--C:cytoplasm
GO:0005634--C:nucleus
GO:0045187--P:regulation of circadian sleep/wake cycle, sleep
GO:0006355--P:regulation of transcription, DNA-templated
GO:0048511--P:rhythmic process
GO:0006351--P:transcription, DNA-templated

Interpro

IPR000014--PAS
IPR013655--PAS_fold_3
IPR022728--Period_circadian-like_C

PROSITE

PS50112--PAS

Pfam

PF08447--PAS_3
PF12114--Period_C

SMART

SM00091--PAS