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protein coding gene - ies6 (SPAC222.04c) - Ino80 complex subunit Ies6

Gene summary

Standard name
ies6
Systematic ID
SPAC222.04c
Product
Ino80 complex subunit Ies6
Organism
Schizosaccharomyces pombe (fission yeast)
UniProt ID
Q9UTE8
ORFeome ID
02/02C07
Characterisation status
biological role published
Feature type
mRNA gene
Genomic location
chromosome I: 950120..950813 reverse strand

Annotation

GO biological process

GO:0034080 - CENP-A containing chromatin assembly

References:

GO:0140861 - DNA repair-dependent chromatin remodeling

References:

GO:0045815 - transcription initiation-coupled chromatin remodeling

References:

GO cellular component

GO:0000785 - chromatin

References:

GO:0005737 - cytoplasm

References:

GO:0031011 - Ino80 complex

References:

Multi-locus phenotype

FYPO:0001355 - decreased vegetative cell population growth

References:

Genotypes:

FYPO:0002061 - inviable vegetative cell population

References:

Genotypes:

Quantitative gene expression

PBO:0006310 - protein level

References:

PBO:0011963 - RNA level

References:

Single locus phenotype

FYPO:0000427 - abnormal G1 to G0 transition

References:

Genotypes:

FYPO:0000059 - abnormal mitotic cell cycle

References:

Genotypes:

FYPO:0006201 - abnormal regulation of adenine biosynthetic process

References:

Genotypes:

FYPO:0000080 - decreased cell population growth at low temperature

References:

Genotypes:

FYPO:0001407 - decreased cell population growth on glucose carbon source

References:

Genotypes:

FYPO:0009053 - decreased cell population growth on glutamate nitrogen source

References:

Genotypes:

FYPO:0009092 - decreased cell population growth on lysine and serine nitrogen source

References:

Genotypes:

FYPO:0009073 - decreased cell population growth on lysine nitrogen source

References:

Genotypes:

FYPO:0002924 - decreased cell population growth on maltose carbon source

References:

Genotypes:

FYPO:0000250 - decreased cell population growth on proline nitrogen source

References:

Genotypes:

FYPO:0001176 - decreased cell population growth on sucrose carbon source

References:

Genotypes:

FYPO:0003740 - decreased CENP-A containing chromatin assembly

References:

Genotypes:

FYPO:0003217 - decreased chromatin silencing at centromere central core

References:

Genotypes:

FYPO:0000708 - decreased mating efficiency

References:

Genotypes:

FYPO:0005948 - decreased protein localization to chromatin at highly transcribed RNA polymerase II genes during vegetative growth

References:

Genotypes:

FYPO:0005314 - decreased protein localization to chromatin at MCB promoters during vegetative growth

References:

Genotypes:

FYPO:0001117 - decreased RNA level during vegetative growth

References:

Genotypes:

FYPO:0005318 - decreased transcription from MCB promoter

References:

Genotypes:

FYPO:0001122 - elongated vegetative cell

References:

Genotypes:

FYPO:0003938 - increased cell population growth during glucose starvation

References:

Genotypes:

FYPO:0009077 - increased cell population growth on ethanol carbon source

References:

Genotypes:

FYPO:0005261 - increased cell population growth on galactose carbon source

References:

Genotypes:

FYPO:0009101 - increased cell population growth on glycerol and galactose carbon source

References:

Genotypes:

FYPO:0009094 - increased cell population growth on lysine and proline nitrogen source

References:

Genotypes:

FYPO:0009098 - increased cell population growth on mannitol carbon source

References:

Genotypes:

FYPO:0009096 - increased cell population growth on xylose carbon source

References:

Genotypes:

FYPO:0006843 - increased histone H3 localization to chromatin

References:

Genotypes:

FYPO:0001840 - increased minichromosome loss during vegetative growth

References:

Genotypes:

FYPO:0004557 - increased vegetative cell population growth

References:

Genotypes:

FYPO:0002061 - inviable vegetative cell population

References:

Genotypes:

FYPO:0006518 - loss of viability in G0

References:

Genotypes:

FYPO:0007035 - normal growth on 5-fluorouracil

References:

Genotypes:

FYPO:0006844 - normal H2A.Z level at centromere

References:

Genotypes:

FYPO:0005079 - normal protein localization to chromatin at centromere central core

References:

Genotypes:

FYPO:0006842 - normal spatial extent of CENP-A containing nucleosome assembly

References:

Genotypes:

FYPO:0009036 - resistance to benzamidine

References:

Genotypes:

FYPO:0009031 - resistance to bleomycin

References:

Genotypes:

FYPO:0000764 - resistance to cycloheximide

References:

Genotypes:

FYPO:0009034 - resistance to ethylenediaminetetraacetic acid

References:

Genotypes:

FYPO:0000725 - resistance to methyl methanesulfonate

References:

Genotypes:

FYPO:0000077 - resistance to rapamycin

References:

Genotypes:

FYPO:0005193 - resistance to torin1

References:

Genotypes:

FYPO:0009065 - resistance to X-rays and rapamycin during vegetative growth

References:

Genotypes:

FYPO:0007933 - sensitive to 2,2′-dipyridyl

References:

Genotypes:

FYPO:0004325 - sensitive to 5-fluorouracil

References:

Genotypes:

FYPO:0001097 - sensitive to amitrole

References:

Genotypes:

FYPO:0009067 - sensitive to amorolfine

References:

Genotypes:

FYPO:0000095 - sensitive to bleomycin

References:

Genotypes:

FYPO:0001701 - sensitive to bortezomib

References:

Genotypes:

FYPO:0000096 - sensitive to cadmium

References:

Genotypes:

FYPO:0001188 - sensitive to Calcofluor White

References:

Genotypes:

FYPO:0009069 - sensitive to ciclopirox olamine

References:

Genotypes:

FYPO:0000102 - sensitive to cisplatin

References:

Genotypes:

FYPO:0000104 - sensitive to cycloheximide

References:

Genotypes:

FYPO:0000799 - sensitive to diamide

References:

Genotypes:

FYPO:0003559 - sensitive to doxorubicin

References:

Genotypes:

FYPO:0007931 - sensitive to egtazic acid

References:

Genotypes:

FYPO:0000842 - sensitive to ethanol during vegetative growth

References:

Genotypes:

FYPO:0000785 - sensitive to formamide

References:

Genotypes:

FYPO:0000087 - sensitive to hydrogen peroxide

References:

Genotypes:

FYPO:0000088 - sensitive to hydroxyurea

References:

Genotypes:

FYPO:0001719 - sensitive to lithium

References:

Genotypes:

FYPO:0009084 - sensitive to lithium chloride and methyl methanesulfonate

References:

Genotypes:

FYPO:0009086 - sensitive to lithium chloride and sodium dodecyl sulfate

References:

Genotypes:

FYPO:0006836 - sensitive to magnesium chloride

References:

Genotypes:

FYPO:0009088 - sensitive to magnesium chloride and sodium dodecyl sulfate

References:

Genotypes:

FYPO:0000089 - sensitive to methyl methanesulfonate

References:

Genotypes:

FYPO:0006200 - sensitive to phosphate starvation

References:

Genotypes:

FYPO:0001214 - sensitive to potassium chloride

References:

Genotypes:

FYPO:0009082 - sensitive to potassium chloride and methyl methanesulfonate

References:

Genotypes:

FYPO:0007924 - sensitive to potassium chloride and sodium dodecyl sulfate

References:

Genotypes:

FYPO:0005889 - sensitive to sodium chloride

References:

Genotypes:

FYPO:0009090 - sensitive to sodium chloride and sodium dodecyl sulfate

References:

Genotypes:

FYPO:0000841 - sensitive to sodium dodecyl sulfate

References:

Genotypes:

FYPO:0007938 - sensitive to tea tree oil

References:

Genotypes:

FYPO:0002328 - sensitive to terbinafine

References:

Genotypes:

FYPO:0000797 - sensitive to tert-butyl hydroperoxide

References:

Genotypes:

FYPO:0000091 - sensitive to thiabendazole

References:

Genotypes:

FYPO:0002546 - sensitive to trichostatin A

References:

Genotypes:

FYPO:0001457 - sensitive to tunicamycin

References:

Genotypes:

FYPO:0000268 - sensitive to UV during vegetative growth

References:

Genotypes:

FYPO:0000115 - sensitive to valproic acid

References:

Genotypes:

FYPO:0003656 - sensitive to vanadate

References:

Genotypes:

FYPO:0004983 - sensitive to vorinostat

References:

Genotypes:

FYPO:0003612 - viable spore population

References:

Genotypes:

FYPO:0002060 - viable vegetative cell population

References:

Genotypes:

FYPO:0001510 - viable vegetative cell, abnormal cell shape, normal cell size

References:

Genotypes:

Taxonomic conservation

PBO:0011065 - conserved in eukaryotes

PBO:0011071 - conserved in eukaryotes only

PBO:0011064 - conserved in fungi

PBO:0011069 - conserved in metazoa

PBO:0011070 - conserved in vertebrates

PBO:0006222 - predominantly single copy (one to one)

Protein features

IDNameInterPro nameDB name
PF08265YL1_CVps72/YL1_CPFAM
SM00993YL1_C_2Vps72/YL1_CSMART
PTHR31200INO80 COMPLEX SUBUNIT CINO80C/Ies6PANTHER

Orthologs

References / Literature

PMID:22540037 - Predicting the fission yeast protein interaction network.
Pancaldi V et al. G3 (Bethesda) 2012 Apr;2(4):453-67
PMID:30134042 - The INO80 complex activates the transcription of S-phase genes in a cell cycle-regulated manner.
Knezevic I et al. FEBS J 2018 Oct;285(20):3870-3881
PMID:23950735 - Global analysis of fission yeast mating genes reveals new autophagy factors.
Sun LL et al. PLoS Genet 2013;9(8):e1003715
PMID:25483073 - Chromosome segregation and organization are targets of 5'-Fluorouracil in eukaryotic cells.
Mojardín L et al. Cell Cycle 2015;14(2):206-18
PMID:28904333 - The Ino80 complex mediates epigenetic centromere propagation via active removal of histone H3.
Choi ES et al. Nat Commun 2017 Sep 13;8(1):529
PMID:33378674 - The INO80 Complex Regulates Epigenetic Inheritance of Heterochromatin.
Shan CM et al. Cell Rep 2020 Dec 29;33(13):108561
PMID:20473289 - Analysis of a genome-wide set of gene deletions in the fission yeast Schizosaccharomyces pombe.
Kim DU et al. Nat Biotechnol 2010 Jun;28(6):617-623
PMID:37787768 - Broad functional profiling of fission yeast proteins using phenomics and machine learning.
Rodríguez-López M et al. Elife 2023 Oct 03;12
PMID:26791325 - Predicting chemotherapeutic drug combinations through gene network profiling.
Nguyen TT et al. Sci Rep 2016 Jan 21;6:18658
PMID:23101633 - Quantitative analysis of fission yeast transcriptomes and proteomes in proliferating and quiescent cells.
Marguerat S et al. Cell 2012 Oct 26;151(3):671-83
PMID:16823372 - ORFeome cloning and global analysis of protein localization in the fission yeast Schizosaccharomyces pombe.
Matsuyama A et al. Nat Biotechnol 2006 Jul;24(7):841-7
PMID:28218250 - Chromatin remodeller Fun30 Fft3 induces nucleosome disassembly to facilitate RNA polymerase II elongation.
Lee J et al. Nat Commun 2017 Feb 20;8:14527
PMID:33260998 - High-Throughput Flow Cytometry Combined with Genetic Analysis Brings New Insights into the Understanding of Chromatin Regulation of Cellular Quiescence.
Zahedi Y et al. Int J Mol Sci 2020 Nov 27;21(23)
PMID:19040720 - Chromatin Central: towards the comparative proteome by accurate mapping of the yeast proteomic environment.
Shevchenko A et al. Genome Biol 2008;9(11):R167
PMID:36793083 - The SAGA histone acetyltransferase module targets SMC5/6 to specific genes.
Mahrik L et al. Epigenetics Chromatin 2023 Feb 16;16(1):6
PMID:37445861 - Resistance to Chemotherapeutic 5-Fluorouracil Conferred by Modulation of Heterochromatic Integrity through Ino80 Function in Fission Yeast.
Lim KK et al. Int J Mol Sci 2023 Jun 26;24(13)
PMID:23365689 - Cellular robustness conferred by genetic crosstalk underlies resistance against chemotherapeutic drug doxorubicin in fission yeast.
Tay Z et al. PLoS One 2013;8(1):e55041
PMID:24763107 - Absolute proteome and phosphoproteome dynamics during the cell cycle of Schizosaccharomyces pombe (Fission Yeast).
Carpy A et al. Mol Cell Proteomics 2014 Aug;13(8):1925-36
PMID:39747188 - PhpC NF-Y transcription factor infiltrates heterochromatin to generate cryptic intron-containing transcripts crucial for small RNA production.
Srivastav MK et al. Nat Commun 2025 Jan 02;16(1):268
PMID:23697806 - A genome-wide resource of cell cycle and cell shape genes of fission yeast.
Hayles J et al. Open Biol 2013 May 22;3(5):130053
PMID:21511999 - Comparative functional genomics of the fission yeasts.
Rhind N et al. Science 2011 May 20;332(6032):930-6
PMID:19933844 - Fission yeast Iec1-ino80-mediated nucleosome eviction regulates nucleotide and phosphate metabolism.
Hogan CJ et al. Mol Cell Biol 2010 Feb;30(3):657-74