Fungal Genomics

at Utrecht University

General Properties

Protein IDPro_DTO377G3_2|g2285.t1
Gene name
Locationscaffold_02:2146139..2147318
Strand-
Gene length (bp)1179
Transcript length (bp)918
Coding sequence length (bp)918
Protein length (aa) 306

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PFAM Domains

PFAM Domain ID Short name Long name E-value Start End
PF01634 HisG ATP phosphoribosyltransferase 2.0E-55 58 225
PF08029 HisG_C HisG, C-terminal domain 5.8E-28 229 301

GO

GO Term Description Terminal node
GO:0005737 cytoplasm Yes
GO:0003879 ATP phosphoribosyltransferase activity Yes
GO:0000105 histidine biosynthetic process Yes
GO:0000287 magnesium ion binding Yes
GO:0046394 carboxylic acid biosynthetic process No
GO:1901566 organonitrogen compound biosynthetic process No
GO:0009987 cellular process No
GO:0034641 cellular nitrogen compound metabolic process No
GO:0044238 primary metabolic process No
GO:0044283 small molecule biosynthetic process No
GO:0046872 metal ion binding No
GO:1901605 alpha-amino acid metabolic process No
GO:0003824 catalytic activity No
GO:1901360 organic cyclic compound metabolic process No
GO:0071704 organic substance metabolic process No
GO:0009073 aromatic amino acid family biosynthetic process No
GO:0044464 cell part No
GO:0016740 transferase activity No
GO:0016763 transferase activity, transferring pentosyl groups No
GO:0019752 carboxylic acid metabolic process No
GO:0006547 histidine metabolic process No
GO:0009072 aromatic amino acid family metabolic process No
GO:0046483 heterocycle metabolic process No
GO:1901362 organic cyclic compound biosynthetic process No
GO:1901564 organonitrogen compound metabolic process No
GO:0044281 small molecule metabolic process No
GO:0043169 cation binding No
GO:0005488 binding No
GO:0044424 intracellular part No
GO:0016053 organic acid biosynthetic process No
GO:0006725 cellular aromatic compound metabolic process No
GO:0009058 biosynthetic process No
GO:0019438 aromatic compound biosynthetic process No
GO:0043167 ion binding No
GO:0006807 nitrogen compound metabolic process No
GO:0003674 molecular_function No
GO:1901576 organic substance biosynthetic process No
GO:0008150 biological_process No
GO:0044237 cellular metabolic process No
GO:0016757 transferase activity, transferring glycosyl groups No
GO:0052803 imidazole-containing compound metabolic process No
GO:0008152 metabolic process No
GO:0044249 cellular biosynthetic process No
GO:0006082 organic acid metabolic process No
GO:0006520 cellular amino acid metabolic process No
GO:0005575 cellular_component No
GO:0018130 heterocycle biosynthetic process No
GO:1901607 alpha-amino acid biosynthetic process No
GO:0043436 oxoacid metabolic process No
GO:0008652 cellular amino acid biosynthetic process No

SignalP

[Help with interpreting these statistics]
SignalP signal predicted Location
(based on Ymax)
D score
(significance: > 0.45)
No 1 - 22 0.5

Transmembrane Domains

(None)

Transcription Factor Class

(None)

Expression data

Analysis 1: Genome-wide gene expression in conidia of Penicillium roqueforti during growth at various temperatures and for various amounts of time. Published in Punt et al., 2020.

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Sequences

Type of sequenceSequence
Locus Download genbank file of locus
The gene with 5 kb flanks (if sufficient flanking sequence is available). For use in cloning design programs. NOTE: features (genes or exons) that are only partially contained within the sequence are completely excluded.
Protein >Pro_DTO377G3_2|g2285.t1
MDLVNHLEGRLLFAVPKKGRLQQATLDLLAGCDVQFRRETRLDIALVKNLPIALIFLPAADIPTFVGEGRVDLGI
TGRDQVAEHDATLPTGEASNVEEILDLGFGACKLQVQVPEKGDIKEAKDLVGRNVVTSFTALTESFFRNLEGAEV
GQKLSTNIKYVGGSVEAACALGVADGIVDLVESGETMKAAGLKAIDTVVSSTAVLVKSRKTNSEMLTILSSRLRG
VITAQKFVLCQYNIPREQLAIASKITPGKRAPTITALEEEGWVAVSSMVEKKHIATVMDELIKVGASDILVMNIA
NSRTD*
Coding >Pro_DTO377G3_2|g2285.t1
ATGGATCTCGTCAACCACCTCGAAGGCCGTCTCCTCTTCGCCGTGCCCAAAAAAGGACGTCTGCAACAAGCAACC
CTCGACCTCCTCGCCGGCTGTGACGTCCAGTTCCGCCGCGAAACCCGCCTCGATATCGCACTGGTCAAGAATTTG
CCCATTGCGCTGATCTTCCTGCCCGCTGCCGATATCCCGACATTCGTCGGCGAAGGCCGCGTTGATTTGGGAATC
ACCGGCCGCGACCAGGTCGCCGAGCACGATGCCACCCTGCCCACCGGCGAGGCCTCCAACGTCGAGGAGATCCTC
GACCTGGGCTTCGGCGCCTGCAAGCTGCAAGTGCAGGTGCCTGAGAAGGGCGATATCAAAGAGGCCAAGGATCTC
GTTGGCCGCAACGTCGTGACCAGCTTCACTGCCCTCACTGAATCTTTCTTCCGTAACCTCGAGGGCGCCGAAGTT
GGCCAGAAACTCTCCACGAATATCAAGTATGTTGGCGGTAGTGTTGAGGCTGCCTGCGCTCTCGGCGTTGCGGAT
GGTATTGTTGATCTTGTTGAGTCTGGTGAGACTATGAAGGCCGCTGGCCTGAAGGCAATTGACACTGTTGTCTCC
AGCACCGCTGTGCTGGTCAAGTCCCGCAAGACCAACTCCGAAATGCTCACTATACTCAGCTCCCGTCTGCGTGGT
GTCATCACCGCCCAGAAGTTCGTCCTGTGCCAATACAACATCCCGCGTGAGCAGCTGGCAATCGCGTCCAAGATC
ACCCCCGGCAAGCGTGCGCCTACTATCACCGCGCTCGAGGAGGAGGGCTGGGTTGCTGTCAGCTCCATGGTGGAG
AAGAAGCACATTGCCACGGTAATGGATGAGCTGATTAAGGTCGGCGCGAGTGATATCTTGGTCATGAACATTGCC
AACTCGCGCACGGATTAA
Transcript >Pro_DTO377G3_2|g2285.t1
ATGGATCTCGTCAACCACCTCGAAGGCCGTCTCCTCTTCGCCGTGCCCAAAAAAGGACGTCTGCAACAAGCAACC
CTCGACCTCCTCGCCGGCTGTGACGTCCAGTTCCGCCGCGAAACCCGCCTCGATATCGCACTGGTCAAGAATTTG
CCCATTGCGCTGATCTTCCTGCCCGCTGCCGATATCCCGACATTCGTCGGCGAAGGCCGCGTTGATTTGGGAATC
ACCGGCCGCGACCAGGTCGCCGAGCACGATGCCACCCTGCCCACCGGCGAGGCCTCCAACGTCGAGGAGATCCTC
GACCTGGGCTTCGGCGCCTGCAAGCTGCAAGTGCAGGTGCCTGAGAAGGGCGATATCAAAGAGGCCAAGGATCTC
GTTGGCCGCAACGTCGTGACCAGCTTCACTGCCCTCACTGAATCTTTCTTCCGTAACCTCGAGGGCGCCGAAGTT
GGCCAGAAACTCTCCACGAATATCAAGTATGTTGGCGGTAGTGTTGAGGCTGCCTGCGCTCTCGGCGTTGCGGAT
GGTATTGTTGATCTTGTTGAGTCTGGTGAGACTATGAAGGCCGCTGGCCTGAAGGCAATTGACACTGTTGTCTCC
AGCACCGCTGTGCTGGTCAAGTCCCGCAAGACCAACTCCGAAATGCTCACTATACTCAGCTCCCGTCTGCGTGGT
GTCATCACCGCCCAGAAGTTCGTCCTGTGCCAATACAACATCCCGCGTGAGCAGCTGGCAATCGCGTCCAAGATC
ACCCCCGGCAAGCGTGCGCCTACTATCACCGCGCTCGAGGAGGAGGGCTGGGTTGCTGTCAGCTCCATGGTGGAG
AAGAAGCACATTGCCACGGTAATGGATGAGCTGATTAAGGTCGGCGCGAGTGATATCTTGGTCATGAACATTGCC
AACTCGCGCACGGATTAA
Gene >Pro_DTO377G3_2|g2285.t1
ATGGATCTCGTCAACCAGTGAGTCAATTTCAATTACAAACCGCATGGGGATTTCTGCTAATATAACGATTCTAAA
CAGCCTCGAAGGCCGTCTCCTCTTCGCCGTGCCCAAAAGCAAGTGCTCTCCCAAATCGTGACTCATAGATGCGAG
CAGCGATACCCACATGAACAAGAAACAAACACAAAGAAACCAAGACTGACGGCGCAAACTCCACTATACAGAAGG
ACGTCTGCAACAAGCAACCCTCGACCTCCTCGCCGGCTGTGACGTCCAGTTCCGCCGCGAAACCCGCCTCGATAT
CGCACTGGTCAAGAATTTGCCCATTGCGCTGATCTTCCTGCCCGCTGCCGATATCCCGACATTCGTCGGCGAAGG
CCGCGTTGATTTGGGAATCACCGGCCGCGACCAGGTCGCCGAGCACGATGCCACCCTGCCCACCGGCGAGGCCTC
CAACGTCGAGGAGATCCTCGACCTGGGCTTCGGCGCCTGCAAGCTGCAAGTGCAGGTGCCTGAGAAGGGCGATAT
CAAAGAGGCCAAGGATCTCGTTGGCCGCAACGTCGTGACCAGCTTCACTGCCCTCACTGAATCTTTCTTCCGTAA
CCTCGAGGGCGCCGAAGTTGGCCAGAAACTCTCCACGAATATCAAGTATGTTGGCGGTAGTGTTGAGGCTGCCTG
CGCTCTCGGCGTTGCGGATGGTATTGTTGATCTTGTTGGTATGTTGTGATATGCCAGTCTACTGAAATACTGTCC
TGTGGAATACGGAACAGGGAACCGGAACCCGTTGCTAACACTCAAATCTGTTCAGAGTCTGGTGAGACTATGAAG
GCCGCTGGCCTGAAGGCAATTGACACTGTTGTCTCCAGCACCGCTGTGCTGGTCAAGTCCCGCAAGACCAACTCC
GAAATGCTCACTATACTCAGCTCCCGTCTGCGTGGTGTCATCACCGCCCAGAAGTTCGTCCTGTGCCAATACAAC
ATCCCGCGTGAGCAGCTGGCAATCGCGTCCAAGATCACCCCCGGCAAGCGTGCGCCTACTATCACCGCGCTCGAG
GAGGAGGGCTGGGTTGCTGTCAGCTCCATGGTGGAGAAGAAGCACATTGCCACGGTAATGGATGAGCTGATTAAG
GTCGGCGCGAGTGATATCTTGGTCATGAACATTGCCAACTCGCGCACGGATTAA

© 2022 - Robin Ohm - Utrecht University - The Netherlands

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