All terms in GO

Label Id Description
ubiquitin-independent protein catabolic process via the multivesicular body sorting pathway GO_0090611 [The chemical reactions and pathways resulting in the breakdown of a protein or peptide, via the multivesicular body (MVB) sorting pathway; proteins are sorted into MVBs, and delivered to a lysosome/vacuole for degradation. This process is independent of ubiquitination.]
5'-methylthioadenosine deaminase activity GO_0090614 [Catalysis of the reaction: 5'methyl thioadenosine + H2O = 5'methyl thioinosine + NH3.]
5'-deoxyadenosine deaminase activity GO_0090613 [Catalysis of the reaction: 5'deoxyadenosine + H2O = 5'deoxyinosine + NH3.]
microtubule minus-end binding GO_0051011 [Binding to the minus end of a microtubule.]
microtubule plus-end binding GO_0051010 [Binding to the plus end of a microtubule.]
microtubule severing GO_0051013 [The process in which a microtubule is broken down into smaller segments. Severing enzymes remove dimers from the middle of the filament to create new ends, unlike depolymerizing kinesins that use ATP to uncap microtubules at their ends.]
bundle sheath cell fate specification GO_0090610 [The process in which a cell becomes capable of differentiating autonomously into a bundle sheath cell in an environment that is neutral with respect to the developmental pathway; upon specification, the cell fate can be reversed.]
actin filament binding GO_0051015 [Binding to an actin filament, also known as F-actin, a helical filamentous polymer of globular G-actin subunits.]
actin binding GO_0003779 [Binding to monomeric or multimeric forms of actin, including actin filaments.]
inner acrosomal membrane GO_0002079 [The acrosomal membrane region that underlies the acrosomal vesicle and is located toward the sperm nucleus. This region is responsible for molecular interactions allowing the sperm to penetrate the zona pellucida and fuses with the egg plasma membrane.]
membrane fusion involved in acrosome reaction GO_0002078 [The fusion of the plasma membrane of the sperm with the outer acrosomal membrane.]
barbed-end actin filament capping GO_0051016 [The binding of a protein or protein complex to the barbed (or plus) end of an actin filament, thus preventing the addition, exchange or removal of further actin subunits.]
acrosome matrix dispersal GO_0002077 [The proteolytic digestion of components in the acrosomal matrix that occurs as part of the acrosome reaction. The process can occur either in the cumulus oophorous facilitating the penetration of it by the sperm, or at the zona pellucida allowing the sperm to reach the plasma membrane of the egg where the inner acrosomal membrane of the sperm can interact with the egg plasma membrane.]
osteoblast development GO_0002076 [The process whose specific outcome is the progression of an osteoblast over time, from its formation to the mature structure. Osteoblast development does not include the steps involved in committing a cranial neural crest cell or an osteoprogenitor cell to an osteoblast fate. An osteoblast is a cell that gives rise to bone.]
somitomeric trunk muscle development GO_0002075 [The process whose specific outcome is the progression of the somitomeric trunk muscle over time, from its formation to the mature structure. The somitomeric trunk muscle is derived from somitomeric mesoderm. The muscle begins its development with the differentiation of the muscle cells and ends with the mature muscle. An example of this process is found in Mus musculus.]
extraocular skeletal muscle development GO_0002074 [The process whose specific outcome is the progression of the extraocular skeletal muscle over time, from its formation to the mature structure. The extraocular muscle is derived from cranial mesoderm and controls eye movements. The muscle begins its development with the differentiation of the muscle cells and ends with the mature muscle. An example of this process is found in Mus musculus.]
GO_0002073 GO_0002073
submerged biofilm formation GO_0090605 [A process in which planktonically growing microorganisms aggregate and grow on solid substrates under the flow of a liquid and produce extracellular polymers that facilitate attachment and matrix formation, resulting in a change in the organisms' growth rate and gene transcription.]
optic cup morphogenesis involved in camera-type eye development GO_0002072 [The invagination of the optic vesicle to form two-walled indentations, the optic cups, that will go on to form the retina. This process begins with the optic vesicle becoming a two-walled structure and its subsequent shape changes. It does not include the fate commitment of cells to become the pigmented retina and the neural retina. An example of this process is found in Mus musculus.]
GO_0090608 GO_0090608