All terms in GO

Label Id Description
regulation of skeletal muscle contraction by modulation of calcium ion sensitivity of myofibril GO_0014723 [Any process that modulates the frequency, rate or extent of skeletal muscle contraction by changing calcium ion binding affinity of the myofibril.]
regulation of twitch skeletal muscle contraction GO_0014724 [Any process that modulates the frequency, rate or extent of twitch skeletal muscle contraction.]
twitch skeletal muscle contraction GO_0014721 [A process in which force is generated within twitch skeletal muscle tissue, resulting in a change in muscle geometry. Force generation involves a chemo-mechanical energy conversion step that is carried out by the actin/myosin complex activity, which generates force through ATP hydrolysis. The twitch skeletal muscle responds to neurostimulations with a contraction followed by a relaxation.]
ductus arteriosus closure GO_0097070 [The morphogenesis process in which the ductus arteriosus changes to no longer permit blood flow after birth. The ductus arteriosus is the shunt between the aorta and the pulmonary artery which allows blood to bypass the fetus' lungs.]
tonic skeletal muscle contraction GO_0014720 [A process in which force is generated within tonic skeletal muscle tissue, resulting in a change in muscle geometry. Force generation involves a chemo-mechanical energy conversion step that is carried out by the actin/myosin complex activity, which generates force through ATP hydrolysis. The tonic skeletal muscle is characterized by long lasting contractile responses and high resistance to fatigue.]
interferon regulatory factor complex GO_0097071 [A protein complex that consists of two interferon regulatory proteins (IRFs); may be homodimeric or heterodimeric. The activation of a latent closed conformation of IRF in the cytoplasm is triggered by phosphorylation of Ser/Thr residues in a C-terminal region. Phosphorylation stimulates the C-terminal autoinhibitory domain to attain a highly extended conformation triggering dimerization through extensive contacts to a second subunit.]
interferon regulatory factor 3 complex GO_0097072 [An interferon regulatory factor complex that consists of a homodimer of interferon regulatory factor 3.]
interferon regulatory factor 5 complex GO_0097073 [An interferon regulatory factor complex that consists of a homodimer of interferon regulatory factor 5.]
interferon regulatory factor 7 complex GO_0097074 [An interferon regulatory factor complex that consists of a homodimer of interferon regulatory factor 7.]
interferon regulatory factor 3-interferon regulatory factor 7 complex GO_0097075 [An interferon regulatory factor complex that consists of a heterodimer of interferon regulatory factor 3 and interferon regulatory factor 7.]
transforming growth factor beta activated kinase 1 complex GO_0097076 [A protein complex that possesses protein kinase activity and activates the I-kappa B kinase complex (IKK) and mitogen-activated protein (MAP) kinases in response to TRAF6 signaling. It comprises the catalytic subunit TAK1 complexed to the regulatory subunits, termed TABs (TAK1-binding subunits).]
copper ion sensor activity GO_0097077 [Binding to and responding, e.g. by conformational change, to changes in the cellular level of copper(I) (Cu+).]
FAL1-SGD1 complex GO_0097078 [A protein complex involved in the 18S rRNA biogenesis. In S. cerevisiae this complex consists of Fal1p and Sgd1p and in humans this complex consists of NOM1 and eIF4AIII subunits.]
selenite:proton symporter activity GO_0097079 [Enables the transfer of a solute or solutes from one side of a membrane to the other according to the reaction: selenite(out) + H+(out) = selenite(in) + H+(in).]
regulation of the velocity of shortening of skeletal muscle modulating contraction GO_0014729 [Any process that modulates velocity of shortening of a skeletal muscle contraction. The shortening leads to reduction of the length of muscle fibers and sarcomeres.]
positive regulation of extraocular skeletal muscle development GO_0014727 [Any process that activates, maintains or increases the frequency, rate or extent of extraocular skeletal muscle development. Extraocular skeletal muscle development is 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.]
regulation of extraocular skeletal muscle development GO_0014725 [Any process that modulates the frequency, rate or extent of extraocular skeletal muscle development. Extraocular skeletal muscle development is 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.]
regulation of the force of skeletal muscle contraction GO_0014728 [Any process that modulates the frequency, rate or extent of the force of skeletal muscle contraction. The force of skeletal muscle contraction is produced by acto-myosin interaction processes through the formation of cross bridges.]
negative regulation of extraocular skeletal muscle development GO_0014726 [Any process that stops, prevents, or reduces the frequency, rate or extent of extraocular skeletal muscle development. Extraocular skeletal muscle development is 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.]
skeletal muscle hypertrophy GO_0014734 [The enlargement or overgrowth of all or part of an organ due to an increase in size (not length) of individual muscle fibers without cell division. In the case of skeletal muscle cells this happens due to the additional synthesis of sarcomeric proteins and assembly of myofibrils.]