Saccharomyces cerevisiae

20 known processes

QRI5 (YLR204W)

Qri5p

(Aliases: COX24)

QRI5 biological process predictions


Filter by process size:
Biological process GO term ID Process size Probability Func Analog Org
translation GO:0006412 230 0.244
mitochondrion organization GO:0007005 261 0.163
cellular protein complex assembly GO:0043623 209 0.123
mitochondrial respiratory chain complex assembly GO:0033108 36 0.122
mitochondrial translation GO:0032543 52 0.076
negative regulation of gene expression GO:0010629 312 0.059
regulation of biological quality GO:0065008 391 0.059
negative regulation of cellular metabolic process GO:0031324 407 0.046
positive regulation of biosynthetic process GO:0009891 336 0.044
protein complex biogenesis GO:0070271 314 0.041
cytochrome complex assembly GO:0017004 29 0.041
protein complex assembly GO:0006461 302 0.037
positive regulation of nitrogen compound metabolic process GO:0051173 412 0.035
developmental process GO:0032502 261 0.034
positive regulation of nucleobase containing compound metabolic process GO:0045935 409 0.032
negative regulation of cellular component organization GO:0051129 109 0.030
single organism developmental process GO:0044767 258 0.030
anatomical structure development GO:0048856 160 0.029
regulation of cellular component organization GO:0051128 334 0.028
ion transport GO:0006811 274 0.026
cytoplasmic translation GO:0002181 65 0.026
positive regulation of cellular biosynthetic process GO:0031328 336 0.025
sexual reproduction GO:0019953 216 0.024
meiotic cell cycle process GO:1903046 229 0.023
positive regulation of gene expression GO:0010628 321 0.023
negative regulation of biosynthetic process GO:0009890 312 0.022
regulation of protein metabolic process GO:0051246 237 0.022
response to chemical GO:0042221 390 0.021
meiotic cell cycle GO:0051321 272 0.020
negative regulation of cellular macromolecule biosynthetic process GO:2000113 289 0.020
organonitrogen compound biosynthetic process GO:1901566 314 0.019
positive regulation of macromolecule metabolic process GO:0010604 394 0.019
regulation of organelle organization GO:0033043 243 0.019
carbohydrate derivative metabolic process GO:1901135 549 0.018
negative regulation of protein metabolic process GO:0051248 85 0.018
posttranscriptional regulation of gene expression GO:0010608 115 0.018
single organism catabolic process GO:0044712 619 0.018
anatomical structure morphogenesis GO:0009653 160 0.017
ribosome biogenesis GO:0042254 335 0.017
transmembrane transport GO:0055085 349 0.017
negative regulation of macromolecule biosynthetic process GO:0010558 291 0.017
sporulation GO:0043934 132 0.016
cellular developmental process GO:0048869 191 0.016
cell differentiation GO:0030154 161 0.016
negative regulation of cellular biosynthetic process GO:0031327 312 0.015
carboxylic acid metabolic process GO:0019752 338 0.015
negative regulation of cellular protein metabolic process GO:0032269 85 0.015
cation transport GO:0006812 166 0.015
reproductive process in single celled organism GO:0022413 145 0.015
regulation of dna replication GO:0006275 51 0.015
single organism membrane organization GO:0044802 275 0.013
regulation of cellular protein metabolic process GO:0032268 232 0.013
heterocycle catabolic process GO:0046700 494 0.013
reproductive process GO:0022414 248 0.012
positive regulation of macromolecule biosynthetic process GO:0010557 325 0.012
protein transport GO:0015031 345 0.012
reproduction of a single celled organism GO:0032505 191 0.012
establishment of protein localization GO:0045184 367 0.012
membrane organization GO:0061024 276 0.012
intracellular protein transport GO:0006886 319 0.012
organic acid metabolic process GO:0006082 352 0.011
regulation of catabolic process GO:0009894 199 0.011
regulation of translation GO:0006417 89 0.011
cell development GO:0048468 107 0.011
regulation of mitochondrion organization GO:0010821 20 0.011
negative regulation of macromolecule metabolic process GO:0010605 375 0.011
nuclear division GO:0000280 263 0.010

QRI5 disease predictions

Disease predictions are made from cross-annotation of human disease genes to the identified functional analogs in yeast and predicted with the yeast functional network.

Disease DO term ID Size Probability Func Analog Org