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fungal-type vacuole
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GO_0000324 |
[A vacuole that has both lytic and storage functions. The fungal vacuole is a large, membrane-bounded organelle that functions as a reservoir for the storage of small molecules (including polyphosphate, amino acids, several divalent cations (e.g. calcium), other ions, and other small molecules) as well as being the primary compartment for degradation. It is an acidic compartment, containing an ensemble of acid hydrolases. At least in S. cerevisiae, there are indications that the morphology of the vacuole is variable and correlated with the cell cycle, with logarithmically growing cells having a multilobed, reticulated vacuole, while stationary phase cells contain a single large structure.] |
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re-entry into mitotic cell cycle
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GO_0000320 |
[The resumption of the mitotic cell division cycle by cells that were in a quiescent or other non-dividing state.] |
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re-entry into mitotic cell cycle after pheromone arrest
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GO_0000321 |
[The resumption of the mitotic cell division cycle by pheromone-arrested cells that have not mated. An example of this process is found in Saccharomyces cerevisiae.] |
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detection of electrical stimulus involved in regulation of muscle adaptation
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GO_0014879 |
[The series of events by which an electrical stimulus is received and converted into a molecular signal. This occurs as part of the regulation of muscle adaptation.] |
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detection of electrical stimulus
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GO_0050981 |
[The series of events by which an electrical stimulus is received and converted into a molecular signal.] |
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striated muscle adaptation
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GO_0014888 |
[Any process in which striated muscle adapts, with consequent modifications to structural and/or functional phenotypes, in response to a stimulus. Stimuli include contractile activity, loading conditions, substrate supply, and environmental factors. These adaptive events occur in both muscle fibers and associated structures (motoneurons and capillaries), and they involve alterations in regulatory mechanisms, contractile properties and metabolic capacities.] |
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muscle atrophy
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GO_0014889 |
[A process, occurring in the muscle, that is characterized by a decrease in protein content, fiber diameter, force production and fatigue resistance in response to different conditions such as starvation, aging and disuse.] |
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transition between slow and fast fiber
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GO_0014886 |
[The process of conversion of slow-contracting muscle fibers to a faster character. This may involve increasing of contractile rate, fast myosin gene induction, increase in glycolytic metabolic properties, altered electrophysiology and altered innervation. This process also regulates skeletal muscle adapatation.] |
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regulation of skeletal muscle adaptation
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GO_0014733 |
[Any process in which skeletal muscle adapts, with consequent modifications to structural and/or functional phenotypes, in response to a stimulus. Stimuli include contractile activity, loading conditions, substrate supply, and environmental factors. These adaptive events occur in both muscle fibers and associated structures (motoneurons and capillaries), and they involve alterations in regulatory mechanisms, contractile properties and metabolic capacities.] |
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cardiac muscle adaptation
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GO_0014887 |
[The process in which cardiac muscle adapts, with consequent modifications to structural and/or functional phenotypes, in response to a stimulus. Stimuli include contractile activity, loading conditions, substrate supply, and environmental factors.] |
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detection of muscle inactivity involved in regulation of muscle adaptation
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GO_0014884 |
[The series of events in which a muscle inactivity stimulus is received by a cell and converted into a molecular signal. This occurs as part of the regulation of muscle adaptation.] |
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detection of injury involved in regulation of muscle adaptation
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GO_0014885 |
[The series of events by which an injury stimulus is received and converted into a molecular signal. This occurs as part of the regulation of muscle adaptation.] |
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detection of wounding
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GO_0014822 |
[The series of events by which an injury stimulus is received and converted into a molecular signal.] |
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regulation of myofibril number
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GO_0014882 |
[Any process that modulates the number of myofibrils. A myofibril is the contractile element of skeletal and cardiac muscle. It is a long, highly organized bundle of actin, myosin, and other proteins that contracts by a sliding filament mechanism.] |
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regulation of muscle hyperplasia
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GO_0014738 |
[Any process that modulates the frequency, rate or extent of muscle hyperplasia.] |
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transition between fast and slow fiber
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GO_0014883 |
[The process of conversion of fast-contracting muscle fibers to a slower character. This may involve slowing of contractile rate, slow myosin gene induction, increase in oxidative metabolic properties, altered electrophysiology and altered innervation. This process also regulates skeletal muscle adapatation.] |
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regulation of muscle filament sliding
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GO_0032971 |
[Any process that modulates the frequency, rate or extent of muscle filament sliding.] |
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regulation of myofibril size
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GO_0014881 |
[Any process that modulates the size of myofibrils. A myofibril is the contractile element of skeletal and cardiac muscle. It is a long, highly organized bundle of actin, myosin, and other proteins that contracts by a sliding filament mechanism.] |
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sulfite transmembrane transporter activity
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GO_0000319 |
[Enables the transfer of sulfite ions from one side of a membrane to the other.] |
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inorganic anion transmembrane transporter activity
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GO_0015103 |
[Enables the transfer of inorganic anions from one side of a membrane to the other. Inorganic anions are atoms or small molecules with a negative charge which do not contain carbon in covalent linkage.] |
