|
Lugaro cell differentiation
|
GO_0021708 |
[The process in which neuroblasts acquire specialized structural and/or functional features that characterize the mature Lugaro cell. Differentiation includes the processes involved in commitment of a neuroblast to a Lugaro cell fate. A Lugaro cell is an inhibitory GABAergic interneuron found in the cerebellar cortex.] |
|
cerebellar Golgi cell differentiation
|
GO_0021701 |
[The process in which neuroblasts acquire specialized structural and/or functional features that characterize the mature cerebellar Golgi cell. Differentiation includes the processes involved in commitment of a neuroblast to a Golgi cell fate. A cerebellar Golgi cell is an inhibitory GABAergic interneuron found in the cerebellar cortex.] |
|
cerebellar Purkinje cell differentiation
|
GO_0021702 |
[The process in which neuroblasts acquire specialized structural and/or functional features that characterize the mature cerebellar Purkinje cell. Differentiation includes the processes involved in commitment of a neuroblast to a Purkinje cell fate. A Purkinje cell is an inhibitory GABAergic neuron found in the cerebellar cortex that projects to the deep cerebellar nuclei and brain stem.] |
|
locus ceruleus formation
|
GO_0021705 |
[The process that gives rise to the locus ceruleus. This process pertains to the initial formation of a structure from unspecified parts. In mice, the locus ceruleus is a dense cluster of neurons within the dorsorostral pons. This nucleus is the major location of neurons that release norepinephrine throughout the brain, and is responsible for physiological responses to stress and panic.] |
|
locus ceruleus maturation
|
GO_0021706 |
[A developmental process, independent of morphogenetic (shape) change, that is required for the locus ceruleus to attain its fully functional state. The locus ceruleus is a dense cluster of neurons within the dorsorostral pons. This nucleus is the major location of neurons that release norepinephrine throughout the brain, and is responsible for physiological responses to stress and panic.] |
|
locus ceruleus development
|
GO_0021703 |
[The process whose specific outcome is the progression of the locus ceruleus over time, from its formation to the mature structure. The locus ceruleus is a dense cluster of neurons within the dorsorostral pons. This nucleus is the major location of neurons that release norepinephrine throughout the brain, and is responsible for physiological responses to stress and panic.] |
|
locus ceruleus morphogenesis
|
GO_0021704 |
[The process in which the anatomical structure of the locus ceruleus is generated and organized. In mice, the locus ceruleus is a dense cluster of neurons within the dorsorostral pons. This nucleus is the major location of neurons that release norepinephrine throughout the brain, and is responsible for physiological responses to stress and panic.] |
|
accessory nerve formation
|
GO_0021608 |
[The process that gives rise to the accessory nerve. This process pertains to the initial formation of a structure from unspecified parts. The spinal branch of this motor nerve innervates the trapezius and the sternocleidomastoid muscles. The cranial branch joins the vagus nerve and innervates the same targets as the vagus nerve.] |
|
cranial nerve formation
|
GO_0021603 |
[The process that gives rise to the cranial nerves. This process pertains to the initial formation of a structure from unspecified parts. The cranial nerves are composed of twelve pairs of nerves that emanate from the nervous tissue of the hindbrain. These nerves are sensory, motor, or mixed in nature, and provide the motor and general sensory innervation of the head, neck and viscera. They mediate vision, hearing, olfaction and taste and carry the parasympathetic innervation of the autonomic ganglia that control visceral functions.] |
|
accessory nerve structural organization
|
GO_0021609 |
[The process that contributes to the act of creating the structural organization of the accessory nerve This process pertains to the physical shaping of a rudimentary structure. The spinal branch of this motor nerve innervates the trapezius and the sternocleidomastoid muscles. The cranial branch joins the vagus nerve and innervates the same targets as the vagus nerve.] |
|
cranial nerve structural organization
|
GO_0021604 |
[The process that contributes to the act of creating the structural organization of the cranial nerves. This process pertains to the physical shaping of a rudimentary structure. The cranial nerves are composed of twelve pairs of nerves that emanate from the nervous tissue of the hindbrain. These nerves are sensory, motor, or mixed in nature, and provide the motor and general sensory innervation of the head, neck and viscera. They mediate vision, hearing, olfaction and taste and carry the parasympathetic innervation of the autonomic ganglia that control visceral functions.] |
|
cranial nerve morphogenesis
|
GO_0021602 |
[The process in which the anatomical structure of the cranial nerves are generated and organized. The cranial nerves are composed of twelve pairs of nerves that emanate from the nervous tissue of the hindbrain. These nerves are sensory, motor, or mixed in nature, and provide the motor and general sensory innervation of the head, neck and viscera. They mediate vision, hearing, olfaction and taste and carry the parasympathetic innervation of the autonomic ganglia that control visceral functions.] |
|
abducens nerve structural organization
|
GO_0021600 |
[The process that contributes to the act of creating the structural organization of the abducens nerve. This process pertains to the physical shaping of a rudimentary structure. The motor function of the abducens nerve is to contract the lateral rectus which results in abduction of the eye.] |
|
abducens nerve maturation
|
GO_0021601 |
[A developmental process, independent of morphogenetic (shape) change, that is required for the abducens nerve to attain its fully functional state. The motor function of the abducens nerve is to contract the lateral rectus which results in abduction of the eye.] |
|
cranial nerve maturation
|
GO_0021605 |
[A developmental process, independent of morphogenetic (shape) change, that is required for a cranial nerve to attain its fully functional state. The cranial nerves are composed of twelve pairs of nerves that emanate from the nervous tissue of the hindbrain. These nerves are sensory, motor, or mixed in nature, and provide the motor and general sensory innervation of the head, neck and viscera. They mediate vision, hearing, olfaction and taste and carry the parasympathetic innervation of the autonomic ganglia that control visceral functions.] |
|
accessory nerve maturation
|
GO_0021606 |
[A developmental process, independent of morphogenetic (shape) change, that is required for the accessory nerve to attain its fully functional state. The spinal branch of this motor nerve innervates the trapezius and the sternocleidomastoid muscles. The cranial branch joins the vagus nerve and innervates the same targets as the vagus nerve.] |
|
accessory nerve morphogenesis
|
GO_0021607 |
[The process in which the anatomical structure of the accessory nerve is generated and organized. The spinal branch of this motor nerve innervates the trapezius and the sternocleidomastoid muscles. The cranial branch joins the vagus nerve and innervates the same targets as the vagus nerve.] |
|
nerve maturation
|
GO_0021682 |
[A developmental process, independent of morphogenetic (shape) change, that is required for a nerve to attain its fully functional state.] |
|
gibberellic acid transmembrane transport
|
GO_1905200 |
[The directed movement of gibberellic acid across a membrane.] |
|
gibberellin transmembrane transporter activity
|
GO_1905201 |
[Enables the transfer of gibberellin from one side of a membrane to the other.] |
