All terms in GO

Label Id Description
peroxisome inheritance GO_0045033 [The acquisition of peroxisomes by daughter cells from the mother cell after replication. In Saccharomyces cerevisiae, the number of peroxisomes cells is fairly constant; a subset of the organelles are targeted and segregated to the bud in a highly ordered, vectorial process. Efficient segregation of peroxisomes from mother to bud is dependent on the actin cytoskeleton, and active movement of peroxisomes along actin filaments is driven by the class V myosin motor protein, Myo2p.]
obsolete neuroblast division GO_0045034 [OBSOLETE. The asymmetrical division of a neuroblast, the neural precursor in the central nervous system, giving rise to another neuroblast and a ganglion mother cell.]
sensory organ precursor cell division GO_0045035 [The series of four asymmetric divisions undergone by the sensory organ precursor cells to generate cells that have distinct cell fates. For example, in the external sensory organ, the precursor cells give rise to one multidendritic neuron and four additional cells (the socket, shaft, sheath cells and the external sense neuron).]
glutamic-type peptidase activity GO_0070002 [Catalysis of the hydrolysis of peptide bonds in a polypeptide chain by a mechanism involving a glutamate/glutamine catalytic dyad.]
protein targeting to chloroplast GO_0045036 [The process of directing proteins towards the chloroplast, usually using signals contained within the protein. Imported proteins are synthesized as cytosolic precursors containing N-terminal uptake-targeting sequences that direct each protein to its correct subcompartment and are subsequently cleaved.]
establishment of protein localization to chloroplast GO_0072596 [The directed movement of a protein to a specific location in a chloroplast.]
protein import into chloroplast stroma GO_0045037 [The targeting and import of proteins into the chloroplast stroma. Import depends on ATP hydrolysis catalyzed by stromal chaperones. Chloroplast stromal proteins, such as the S subunit of rubisco, have a N-terminal stromal-import sequence of about 44 amino acids which is cleaved from the protein precursor after import.]
cysteine-type exopeptidase activity GO_0070004 [Catalysis of the hydrolysis of C- or N-terminal peptide bonds in a polypeptide chain by a mechanism in which the sulfhydryl group of a cysteine residue at the active center acts as a nucleophile.]
protein import into chloroplast thylakoid membrane GO_0045038 [The import of proteins into the chloroplast thylakoid membranes. Proteins that are destined for the thylakoid lumen require two uptake-targeting sequences: the first targets the protein to the stroma, and the second targets the protein from the stroma to the thylakoid lumen. Four separate thylakoid-import systems deal with the proteins once they are in the stroma.]
protein import GO_0017038 [The targeting and directed movement of proteins into a cell or organelle. Not all import involves an initial targeting event.]
cysteine-type aminopeptidase activity GO_0070005 [Catalysis of the hydrolysis of a single N-terminal amino acid residue from a polypeptide chain by a mechanism in which the sulfhydryl group of a cysteine residue at the active center acts as a nucleophile.]
protein insertion into mitochondrial inner membrane GO_0045039 [The processes mediating the insertion of proteins into the mitochondrial inner membrane. Mitochondrial inner membrane proteins can get inserted from the cytosol, by crossing the outer membrane and being guided by an inner membrane translocase complex into their final destination in the inner membrane. Some proteins present in the intermembrane space can get inserted into the inner mitochondrial membrane. Finally, some proteins are inserted into the inner membrane from the matrix side of the membrane.]
metalloaminopeptidase activity GO_0070006 [Catalysis of the hydrolysis of a single N-terminal amino acid residue from a polypeptide chain by a mechanism in which water acts as a nucleophile, one or two metal ions hold the water molecule in place, and charged amino acid side chains are ligands for the metal ions.]
glutamic-type endopeptidase activity GO_0070007 [Catalysis of the hydrolysis of internal peptide bonds in a polypeptide chain by a mechanism involving a glutamate/glutamine catalytic dyad.]
serine-type aminopeptidase activity GO_0070009 [Catalysis of the hydrolysis of a single N-terminal amino acid residue from a polypeptide chain by a catalytic mechanism that involves a catalytic triad consisting of a serine nucleophile that is activated by a proton relay involving an acidic residue (e.g. aspartate or glutamate) and a basic residue (usually histidine).]
mesenchymal cell differentiation involved in salivary gland development GO_0060692 [The process in which a relatively unspecialized cell acquires specialized features of a mesenchymal cell of the salivary gland. A mesenchymal cell is a loosely associated cell that is part of the connective tissue in an organism. Mesenchymal cells give rise to more mature connective tissue cell types.]
G protein-coupled UTP receptor activity GO_0045030 [Combining with a nucleotide and transmitting the signal to a heterotrimeric G-protein complex to initiate a change in cell activity, activated by UTP.]
G protein-coupled ATP receptor activity GO_0045031 [Combining with ATP and transmitting the signal across the membrane by activating an associated G-protein; promotes the exchange of GDP for GTP on the alpha subunit of a heterotrimeric G-protein complex.]
GO_0045032 GO_0045032
epithelial cell maturation involved in salivary gland development GO_0060691 [The developmental process, independent of morphogenetic (shape) change, that is required for an epithelial cell of the salivary gland to attain its fully functional state.]