Active transport neurons

Enterochromaffin cells are interspersed with mucosal cells mainly in the stomach and small intestine. In the blood, serotonin is present at high concentrations in platelets, which take up serotonin from the plasma by an active transport process. Serotonin is released on platelet activation. In the central nervous system, serotonin serves as a transmitter. The main serotonin-containing neurons are those clustered in form of the Raphe nuclei. Serotonin exerts its biological effects through the activation of specific receptors. Most of them are G-protein coupled receptors (GPCRs) and belong to the 5-HTr, 5-HT2-, 5-HT4-, 5-HTs-, 5-HT6-, 5-HT7-receptor subfamilies. The 5-HT3-receptor is a ligand-operated ion channel. 

Acetylcholine synthesis and neurotransmission requires normal functioning of two active transport mechanisms. Choline acetyltransferase (ChAT) is the enzyme responsible for ACh synthesis from the precursor molecules acetyl coenzyme A and choline. ChAT is the neurochemical phenotype used to define cholinergic neurons although ChAT is present in cell bodies, it is concentrated in cholinergic terminals. The ability of ChAT to produce ACh is critically dependent on an adequate level of choline. Cholinergic neurons possess a high-affinity choline uptake mechanism referred to as the choline transporter (ChT in Fig. 5.1). The choline transporter can be blocked by the molecule hemicholinium-3. Blockade of the choline transporter by hemicholinium-3 decreases ACh release,... 

Many neurotransmitters are inactivated by a combination of enzymic and non-enzymic methods. The monoamines - dopamine, noradrenaline and serotonin (5-HT) - are actively transported back from the synaptic cleft into the cytoplasm of the presynaptic neuron. This process utilises specialised proteins called transporters, or carriers. The monoamine binds to the transporter and is then carried across the plasma membrane it is thus transported back into the cellular cytoplasm. A number of psychotropic drugs selectively or non-selectively inhibit this reuptake process. They compete with the monoamines for the available binding sites on the transporter, so slowing the removal of the neurotransmitter from the synaptic cleft. The overall result is prolonged stimulation of the receptor. The tricyclic antidepressant imipramine inhibits the transport of both noradrenaline and 5-HT. While the selective noradrenaline reuptake inhibitor reboxetine and the selective serotonin reuptake inhibitor fluoxetine block the noradrenaline transporter (NAT) and serotonin transporter (SERT), respectively. Cocaine non-selectively blocks both the NAT and dopamine transporter (DAT) whereas the smoking cessation facilitator and antidepressant bupropion is a more selective DAT inhibitor. 

The answers are 333-c, 334-a, 335-d. (Katzung, pp 77-80. Hardman, pp 116, 132, 147—148.) Acetylcholine is synthesized from acetyl-CoA and choline. Choline is taken up into the neurons by an active transport system. Ilemicholinium blocks this uptake, depleting cellular choline, so that synthesis of ACh no longer occurs. 

Secretory cells, including neurons, also possess a specialized regulated secretory pathway. Vesicles in this pathway have soluble proteins, peptides or neurotransmitters stored and concentrated within secretory vesicles. At that point, these vesicles are actively transported to a site for extracellular delivery in response to a specific extracellular signal. Exocytosis through regulated secretion accomplishes different functions, including the... 

Details of the mechanisms by which endocytosed material moves from the early to the late and lysosomal compartment are still poorly understood. However, portions of the EEs tubulovesicular structures may be actively transported along microtubules towards the perinuclear region of the cell in both neurons and non-neuronal cells. These endosomes on the move may enclose invaginated membranes and also internally bud off vesicles. For that reason, these complex structures are called multivesicular bodies (MVBs) [76]. Material returning by retrograde axonal transport to the neuronal cell body includes many MVBs [67]. The eventual fate of these structures may vary. Some MVBs may fuse with LEs or they may fuse with each... 

This results in the extrusion of three positive charges for every two that enter the cell, resulting in a transmembrane potential of 50-70 mV, and has enormous physiological significance. More than one-third of the ATP utilized by resting mammalian cells is used to maintain the intracellular Na+-K+ gradient (in nerve cells this can rise up to 70%), which controls cell volume, allows neurons and muscle cells to be electrically excitable, and also drives the active transport of sugars and amino acids (see later). 

In sum, the natural tendency will be for sodium, calcium, and chloride ions to flow into the neuron and for potassium ions to flow out, and in so doing to reduce the membrane potential to zero. In reality, this is not so easy. The plasma membrane of the neuron is not very permeable to these ions. If it were, it would be impossible to sustain concentration gradients across it. The rate of passive diffusion of these ions across this membrane is very slow, though not zero, and different for each ion. So how do ions get across the neuronal plasma membrane rapidly There are two ways gated channels and active transport by pumps. 

The effect of released norepinephrine wanes quickly, because approx. 90% is actively transported back into the axoplasm, then into storage vesicles (neuronal re-uptake). Small portions of norepinephrine are inactivated by the enzyme catechol-0-methyltransferase (COMT, present in the cytoplasm of postjunctional cells, to yield normeta-nephrine), and monoamine oxidase (MAO, present in mitochondria of nerve cells and postjunctional cells, to yield 3,4-dihydroxymandelic acid). 

The brain and other areas of the central nervous system (CNS) have high ATP requirements. Although the brain only represents about 2% of the body s mass, it consumes around 20% of the metabolized oxygen and ca. 60% of the glucose. The neurons high energy requirements are mainly due to ATP-de-pendent ion pumps (particularly Na7K " AT-Pase) and other active transport processes that are needed for nerve conduction (see p. 350). 

In the CNS, glial cells aid in the communication between the densely packed neurons of the CNS. These cells also play a big part in forming the blood-brain barrier. The blood-brain barrier keeps some classes of chemicals from entering the brain, which can make it very difficult to treat diseases of the brain. However, some chemicals, such as caffeine, readily enter the brain, as do many other neuroactive compounds. Compounds essential for function are actively transported across this barrier. 

Neurotrophic factors play a central role in development and maintenance of neuronal cells. After release from the target cells, they bind specific receptors on the nerve termini, are internalized and carried up the axon to the perikaryon by retrograde transport. This process helps guide the direction of neurite growth (i.e. a chemoattractant activity) during neuronal development, and also serves to nourish the developing cell. Once established, the process of retrograde transport must continue if the cell is to survive and remain differentiated. 

Synthesis of norepinephrine begins with the amino acid tyrosine, which enters the neuron by active transport, perhaps facilitated by a permease. In the neuronal cytosol, tyrosine is converted by the enzyme tyrosine hydroxylase to dihydroxyphenylalanine (dopa), which is converted to dopamine by the enzyme aromatic L-amino acid decarboxylase, sometimes termed dopa-decarboxylase. The dopamine is actively transported into storage vesicles, where it is converted to norepinephrine (the transmitter) by dopamine (3-hydroxylase, an enzyme within the storage vesicle. 

Figure 7.44 The metabolism and toxicity of MPTP. Diffusion into the brain is followed by metabolism in the astrocyte. The metabolite MPP+ is actively transported into the dopaminergic neuron by DAT. It is accumulated there and is actively taken into mitochondria by another uptake system. Here, it inhibits mitochondrial electron transport between NADH dehydrogenase (NADH DHase) and coenzyme Q (Q10). Consequently, it blocks the electron transport system, depletes ATP, and destroys the neuron. Abbreviations MPTP, 1-methyl-4-phenyl 1,2,3,6-tetrahydropyridine DAT, dopamine transporter uptake system.

FIGURE 11-36 Na+K+ ATPase. In animal cells, this active transport system is primarily responsible for setting and maintaining the intracellular concentrations of Na+ and K+ and for generating the transmembrane electrical potential. It does this by moving three Na+ out of the cell for every two K+ it moves in. The electrical potential is central to electrical signaling in neurons, and the gradient of Na+ is used to drive the uphill cotransport of solutes in many cell types. 

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