Chapter 8 (exam 3)

Question 1

Neuro Subdivisions

Answer 1

• CNS - brain and spinal cord
• Peripheral nervous system - carries motor and sensory info

–somatic - voluntary muscle movement

–autonomic - involuntary control of organs and endocrine glands

Question 2

Neuro Anatomy

Answer 2

neurons - conduct info

–dendrite, soma, cytoplasm, myelin sheath, node of ranvier, schwann cells, axon terminal

-glial cells - suporting cells do not directly conduct info

Question 3

Neuron Function

Answer 3

(-70mV) resting, influx of calcium, open sodium gated channels, depolarization to (+30mV), repolarization using sodium potassium pump

-many targets to prevent full cycle (inhbit na/k pump, voltage gated channels, k channels

Question 4

Voltage gated sodium channels

Answer 4

• open when E increases
• flood into axon, sequentially open the channels
• depolarization
• repolarization using the Na/K ATPase pump (active transport)

–antiporter enzyme

–3 na out and 2 k in

–k channel is passive so k flows out (recycled)

Question 5

Terminus of neuron

Answer 5

• vesicles carry the neurotransmitters (NT)
• NT - chemical signaling, stored in vesicles, lipid membrane
• lipid membrane of the vesicle merges witht the terminus membrane to release the NT
• Ca2+ ions through voltage gated calcium channels in the terminus following an action potential, divalent and bond to protein in vesicle membrane and to terminus membrane
• NT into synapse, diffusion gradient, post synaptic receptor

Question 6

NT in Synapse

Answer 6

• move to post synaptic receptor via random diffusion
• geometry of the terminus and post synaptic cell favors contact
• reuptake the NT into the terminus, or degrade the NT
• tox target the terminus and synapse (prevent docking, bind to post syn receptor)

–antagonist - bind to hypostimulate

–agonist - bind to hyperstimulate (spasms)

Question 7

Tetrodotoxin (TTX)

Answer 7

• produced by puffer fish, may also be used in sushi
• bind to voltage gated sodium channels
• hypostimulation - paralysis
• slow transport of sodium into the axon
• slow action potential (half)
• LD50 - 11-532 micro/kilo dependent on exposure, in mice

1-4mg in human fatal

(+) charge on TTX binds to sodium channel to prevent depolarization

Question 8

Saxitoxin

Answer 8

• produced by dinoflagellates marine algae
• paralytic shellfish poisoning
• accumulate in shellfish due ot feeding mechanism, filtering water
• same mechanism as TTX
• lethal in humans as low as 0.5mg
• amino nitrogen protonated and have (+) charge pka = 8.24, 11.6

Question 9

Batrachotoxin

Answer 9

• poison dart frogs
• obtained by diet - captive frogs are not poisonous
• bind to voltage gated sodium channels

–liphilic and can act on either side of the membrane (unlike TTX and STX)

• more likely to bind to interior because harder to diffuse
• lethal dose (200micrograms)

Question 10

domoic nad kainic acid

Answer 10

• produced by algae in harmful algal blooms
• resemble NT glutamate

–hyderstimulation, excitotoxicity

–excess calcium in the cell

–release ROS and RNS

–lipid peroxidation

–similar to methamphetamine

• nonpolar section may increase time on the receptor
• effect memory - cross clood brain barrier in CNS

Question 11

Eutrophication

Answer 11

• increase N and P
• increase algal growth
• more dead algal blooms
• decay via bacteria
• bacteria uses oxygen
• also, less solar penetration and less macrophytes which habitat larvae

Question 12

Toxicants of Myelin

Answer 12

• lead and tin - damage mydlinating cells and decrease conduction velocity
• splits myelin and leave water fillef vacuoles and damage ion gradient control
• organo tin species
• tributyl tin more nonpolar, used to paint ships and decrease barnicles

Question 13

Acetylcholinesterase (AcChase)

Answer 13

• remove NT AcCh from synapse, stops signal
• located on post synaptic membrane
• AcCh + R = AcChR
• decreases the conc in the synapse, equation shift left and the receptor releases the AcCh
• active site requires “catalytic triad”

–serine, histidine, aspartic acid

-overall mechanism stabalizes the O in serine in order to be deprotonated, histidine removes the H, O as a nucleophile for AcCh

Question 14

AcChase mechanism

Answer 14

Question 15

Organophosphates

Answer 15

• chemical warfare agents and pesticides
• unlike ATP because it is organic
• aging of OP makes it permanently stable, stable to hydrolysis
• hyperstimulation - spasms, uncontrolled muscle contractions

SLUDGE - salivation, lacrimation (tears), urination, defecation, GI emesis (vomit)

Question 16

Aging CWA

Answer 16

• if leavign group hydrolyzes off of an OP (similar to choline group in AcCh), the remaining residue will be permanently bound to AcChase
• OP does not bond to the receptor, but to the AcChase

Question 17

Carbamates

Answer 17

• similar to OPs
• no aging
• pesticises, no CWA
• product is more stable than when AcCh binds to the AcChase
• stable to hydrolysis

Question 18

Atropine

Answer 18

-binds to AcCh receptor and blocks signal transmission

–antagonist

• greater affinity for the receptor than AcCh
• from plant
• alone results in hypostimulation, buys time and prevents hyperstimulation
• DOES NOT interact with the OP
• functional antagonist

Question 19

Botulinum Toxin

Answer 19

• produced by clostridium botulinum
• anaerobe present in soils
• improperly canned food
• 250 kD protein
• temperature stable and cooking does not degrade
• inhibits the release of vesicles contraining AcCh

–cleaves SNARE proteins that dock vesicle with the terminus membrane

Question 20

Honey in Infants

Answer 20

• low gut acidity, Clostridium botulinum can grow
• human gut normally prevents growth
• inhibit release of vesicles containing NT (AcCh)
• cleave protein that dock vesicles with terminus
• LD50 on order fo ng/kg