YRC Logo
PROTEIN SEARCH:
Descriptions Names[Advanced Search]

View Protein Complex Details

Complex Overview

From Publication: Riffle <i>et al</i>. (2010) (Unpublished Data)
Notes: Complex predicted from the combined set of Gavin (2002), Gavin (2006), Ho (2002) and Krogan (2006); at p-value cutoff of 1E-7
Complex Size: 12 proteins

Complex Member Proteins

Protein

 GO Cellular Component GO Biological Process GO Molecular Function
BUD31
  • nucleus
    		•
  • RNA splicing
  • cellular bud site selection
    		•
  • molecular_function
    		•
    CEF1
  • spliceosomal complex
    		•
  • nuclear mRNA splicing, via spliceosome
    		•
  • DNA binding
  • first spliceosomal transesterification activity
    		•
    CLF1
  • chromatin
    		•
  • DNA replication
  • cell cycle
  • cis assembly of pre-catalytic spliceosome
  • nuclear mRNA splicing, via spliceosome
    		•
  • protein binding
    		•
    CWC2
  • spliceosomal complex
    		•
  • nuclear mRNA splicing, via spliceosome
    		•
  • molecular_function
    		•
    CWC22
  • spliceosomal complex
    		•
  • nuclear mRNA splicing, via spliceosome
    		•
  • molecular_function
    		•
    PRP19
  • nucleus
  • cytoplasm
  • mitochondrion
  • spliceosomal complex
    		•
  • nuclear mRNA splicing, via spliceosome
  • ubiquitin-dependent protein catabolic process
    		•
  • ubiquitin-protein ligase activity
  • first spliceosomal transesterification activity
  • RNA binding
    		•
    PRP45
  • nucleus
  • spliceosomal complex
    		•
  • positive regulation of transcription from RNA polymerase II promoter
  • nuclear mRNA splicing, via spliceosome
    		•
  • transcription activator activity
    		•
    PRP46
  • spliceosomal complex
    		•
  • nuclear mRNA splicing, via spliceosome
    		•
  • molecular_function
    		•
    RSE1
  • U2 snRNP
    		•
  • spliceosome assembly
  • nuclear mRNA splicing, via spliceosome
    		•
  • U2 snRNA binding
    		•
    SNT309
  • spliceosomal complex
    		•
  • nuclear mRNA splicing, via spliceosome
    		•
  • protein binding
    		•
    SNU114
  • U4/U6 x U5 tri-snRNP complex
  • U5 snRNP
    		•
  • generation of catalytic spliceosome for first transesterification step
  • nuclear mRNA splicing, via spliceosome
    		•
  • GTP binding
  • U5 snRNA binding
  • GTPase activity
    		•
    SYF1
  • spliceosomal complex
    		•
  • cell cycle
  • nuclear mRNA splicing, via spliceosome
    		•
  • 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
    spliceosomal complex 1.7226E-15 12 45 8 6292
    ribonucleoprotein complex 6.9243E-10 12 514 10 6292
    nuclear part 1.2397E-6 12 1103 10 6292
    nucleus 3.4695E-5 12 2041 11 6292
    macromolecular complex 5.3141E-5 12 1635 10 6292
    organelle part 1.1283E-4 12 2282 11 6292
    intracellular organelle part 1.1283E-4 12 2282 11 6292
    intracellular organelle 5.3355E-3 12 4070 12 6292
    organelle 5.3513E-3 12 4071 12 6292
    small nuclear ribonucleoprotein complex 6.105E-3 12 63 2 6292

    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
    RNA splicing 4.3877E-21 12 132 12 6292
    nuclear mRNA splicing, via spliceosome 9.8263E-20 12 99 11 6292
    RNA splicing, via transesterification reactions with bulged adenosine as nucleophile 1.1039E-19 12 100 11 6292
    RNA splicing, via transesterification reactions 2.4126E-19 12 107 11 6292
    mRNA processing 1.7977E-17 12 156 11 6292
    mRNA metabolic process 6.0458E-16 12 213 11 6292
    RNA processing 1.9966E-15 12 380 12 6292
    RNA metabolic process 1.3916E-10 12 954 12 6292
    gene expression 4.9591E-9 12 1283 12 6292
    nucleic acid metabolic process 1.6138E-8 12 1415 12 6292
    nucleobase, nucleoside, nucleotide and nucleic acid metabolic process 5.4733E-8 12 1566 12 6292
    cellular nitrogen compound metabolic process 2.3908E-7 12 1770 12 6292
    nitrogen compound metabolic process 2.7555E-7 12 1791 12 6292
    cellular macromolecule metabolic process 5.1661E-6 12 2285 12 6292
    macromolecule metabolic process 7.2022E-6 12 2349 12 6292
    primary metabolic process 8.9282E-5 12 2896 12 6292
    cellular metabolic process 1.5563E-4 12 3033 12 6292
    metabolic process 2.5194E-4 12 3157 12 6292
    spliceosome assembly 5.0164E-4 12 18 2 6292
    ribonucleoprotein complex assembly 6.0496E-4 12 92 3 6292
    cis assembly of pre-catalytic spliceosome 3.811E-3 12 2 1 6292
    cellular macromolecular complex assembly 4.3192E-3 12 182 3 6292
    generation of catalytic spliceosome for first transesterification step 5.7116E-3 12 3 1 6292
    nuclear mRNA cis splicing, via spliceosome 5.7116E-3 12 3 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
    snRNA binding 3.3242E-5 12 5 2 6292
    first spliceosomal transesterification activity 4.981E-5 12 6 2 6292
    U2 snRNA binding 1.9072E-3 12 1 1 6292
    U5 snRNA binding 3.811E-3 12 2 1 6292
    YRC Informatics Platform - Version 3.0
    Created and Maintained by: Michael Riffle