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View Protein Complex Details

Complex Overview

From Publication: Krogan N. J. et al. (2006) Global landscape of protein complexes in the yeast Saccharomyces cerevisiae. Nature. 2006 Mar 30;440(7084):637-43. Epub 2006 Mar 22.
Notes: From the published set of core protein complex predictions.
Complex Size: 8 proteins

Complex Member Proteins

Protein

 GO Cellular Component GO Biological Process GO Molecular Function
FYV10
  • nucleus
  • cytoplasm
    		•
  • negative regulation of gluconeogenesis
    		•
  • molecular_function
    		•
    GID7
  • nucleus
  • cytoplasm
    		•
  • negative regulation of gluconeogenesis
    		•
  • molecular_function
    		•
    GID8
  • nucleus
  • cytoplasm
    		•
  • negative regulation of gluconeogenesis
  • traversing start control point of mitotic cell cycle
    		•
  • molecular_function
    		•
    RMD5
  • cytosol
    		•
  • negative regulation of gluconeogenesis
    		•
  • molecular_function
    		•
    VID24
  • cytoplasmic membrane-bounded vesicle
  • extrinsic to membrane
    		•
  • vesicle-mediated transport
  • negative regulation of gluconeogenesis
    		•
  • molecular_function
    		•
    VID28
  • nucleus
  • cytoplasm
    		•
  • ascospore formation
  • proteasomal ubiquitin-dependent protein catabolic process
  • response to drug
  • negative regulation of gluconeogenesis
  • positive regulation of transcription from RNA polymerase II promoter
  • vacuolar protein catabolic process
    		•
  • molecular_function
    		•
    VID30
  • nucleus
  • cytoplasm
    		•
  • proteasomal ubiquitin-dependent protein catabolic process
  • negative regulation of gluconeogenesis
  • regulation of nitrogen utilization
  • vacuolar protein catabolic process
    		•
  • molecular_function
    		•
    YDL176W
  • cellular_component
    		•
  • biological_process
    		•
  • molecular_function
    		•

    Cellular Component Analysis

    Given the number of proteins in the complex (A), total proteins annotated with a given GO term (B), and the total number of annotated proteins (T); the p-value represents the chances of randomly having the number of proteins in the complex annotated with a specific GO term (I).

    Only showing terms with a p-value less than or equal to 0.01.

    GO Term

    		 P-value

    		 A

    		 B

    		 I

    		 T

    Biological Process Analysis

    Given the number of proteins in the complex (A), total proteins annotated with a given GO term (B), and the total number of annotated proteins (T); the p-value represents the chances of randomly having the number of proteins in the complex annotated with a specific GO term (I).

    Only showing terms with a p-value less than or equal to 0.01.

    GO Term

    		 P-value

    		 A

    		 B

    		 I

    		 T
    negative regulation of gluconeogenesis 8.2011E-20 8 12 7 6292
    negative regulation of cellular carbohydrate metabolic process 8.2011E-20 8 12 7 6292
    negative regulation of carbohydrate metabolic process 8.2011E-20 8 12 7 6292
    regulation of gluconeogenesis 1.1839E-18 8 16 7 6292
    regulation of cellular ketone metabolic process 3.2926E-18 8 18 7 6292
    regulation of carbohydrate biosynthetic process 1.7635E-17 8 22 7 6292
    regulation of glucose metabolic process 1.6123E-16 8 29 7 6292
    regulation of cellular carbohydrate metabolic process 1.6123E-16 8 29 7 6292
    gluconeogenesis 4.4107E-16 8 33 7 6292
    hexose biosynthetic process 6.9409E-16 8 35 7 6292
    regulation of carbohydrate metabolic process 8.6151E-16 8 36 7 6292
    monosaccharide biosynthetic process 1.3021E-15 8 38 7 6292
    pyruvate metabolic process 3.9504E-15 8 44 7 6292
    alcohol biosynthetic process 6.4806E-15 8 47 7 6292
    cellular carbohydrate biosynthetic process 2.7105E-13 8 78 7 6292
    carbohydrate biosynthetic process 8.289E-13 8 91 7 6292
    glucose metabolic process 3.0437E-12 8 109 7 6292
    hexose metabolic process 7.6731E-12 8 124 7 6292
    monocarboxylic acid metabolic process 1.336E-11 8 134 7 6292
    monosaccharide metabolic process 1.4089E-11 8 135 7 6292
    negative regulation of biosynthetic process 1.5427E-10 8 189 7 6292
    negative regulation of cellular biosynthetic process 1.5427E-10 8 189 7 6292
    negative regulation of cellular metabolic process 3.1445E-10 8 209 7 6292
    negative regulation of metabolic process 3.2525E-10 8 210 7 6292
    alcohol metabolic process 4.5189E-10 8 220 7 6292
    negative regulation of cellular process 1.1139E-9 8 250 7 6292
    negative regulation of biological process 1.2116E-9 8 253 7 6292
    cellular carbohydrate metabolic process 1.55E-9 8 262 7 6292
    carbohydrate metabolic process 2.5372E-9 8 281 7 6292
    small molecule biosynthetic process 5.0606E-9 8 310 7 6292
    carboxylic acid metabolic process 8.3635E-9 8 333 7 6292
    organic acid metabolic process 8.3635E-9 8 333 7 6292
    oxoacid metabolic process 8.3635E-9 8 333 7 6292
    cellular ketone metabolic process 1.094E-8 8 346 7 6292
    regulation of cellular biosynthetic process 9.597E-8 8 472 7 6292
    regulation of biosynthetic process 9.7397E-8 8 473 7 6292
    regulation of primary metabolic process 1.7384E-7 8 514 7 6292
    regulation of cellular metabolic process 2.3274E-7 8 536 7 6292
    regulation of metabolic process 2.6807E-7 8 547 7 6292
    small molecule metabolic process 2.6217E-6 8 760 7 6292
    regulation of cellular process 3.609E-6 8 796 7 6292
    regulation of biological process 4.5811E-6 8 824 7 6292
    biological regulation 6.4966E-5 8 1213 7 6292
    vacuolar protein catabolic process 1.2776E-4 8 14 2 6292
    cellular biosynthetic process 3.6841E-4 8 1567 7 6292
    biosynthetic process 4.2747E-4 8 1602 7 6292
    proteasomal protein catabolic process 3.1803E-3 8 69 2 6292
    proteasomal ubiquitin-dependent protein catabolic process 3.1803E-3 8 69 2 6292
    traversing start control point of mitotic cell cycle 7.6075E-3 8 6 1 6292

    Molecular Function Analysis

    Given the number of proteins in the complex (A), total proteins annotated with a given GO term (B), and the total number of annotated proteins (T); the p-value represents the chances of randomly having the number of proteins in the complex annotated with a specific GO term (I).

    Only showing terms with a p-value less than or equal to 0.01.

    GO Term

    		 P-value

    		 A

    		 B

    		 I

    		 T
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