Lecture 8 Light regulation of the circadian system Flashcards
phase response curve in hamsters and light intensity.
dim light little effect, strong big.
Circadian photoentrainment relies upon accurate quantitative measurement of environmental light.
rods and cones and light entrainment
Sensitivity of established retinal photoreceptors (rods cones) can not fully explain light measurement by the circadian system.
rods - starlight/moonlight.
cones - relative light intensity/contrast, so not a reliable indicator of brightness.
extra retinal birds photoentrainment?
still entrain to LD without eyes.
DD period delays, LD normal again.
so photoreceptors capable of entraining clock can’t be in eyes.
injected black dye under scalp, if the photoreceptors are in the brain it will block, if in skin it won’t.
lost entrainment so in the brain.
true for all non mammalian vertabrates, vary between species though
rodless coneless mice?
cyclic GMP phosphodiesterase mutation which fucks rods, also no cones (why?)
still show normal entrainment response to DD, LD.
SCN input from?
how do we know?
RHT retinohypothalamic tract
therefore either RGC themselves are photoreceptive or they relay a signal.
injected fluourescent beads into SCN of rats, taken up by axon terminals of retinal ganglion cells and transported back to retina and into cell body.
can identify retinal cells projecting to SCN
RGC showed to be what?
intrinsically photosensitive, removed cell so isolated and still show response.
red/cone phototransduction.
rods:
outer segment has stacked rows of membranous discs, full of light sensitive proteins, allow rods to pack photopigment into small space, increases absorbtion of photons.
ret gang cells don’t have this.
membranous discs contain rhodopsin in rods, codopsin in cones. all animal use opsin proteins
opsins - GPCRs, ligand is 11-cis retinal.
binding of ligand keeps it in an inactive state, it’s an inverse agonist.
when light hits the retinal/ligand, it causes it to isomerise, changes to trans, released and opsin then signals
new type of opsin?
rods and cones in h0omans?
1 rod, 3 cones RBY, melanopsin
melanopsin found how?
micey mice.
made transgenic mice expressing tau::lacZ melanopsin (motor region normal, add taulac coding seq)
LacZ encodes beta-galactosidase,
digests X-gal a colourless sugar –> blue precipitate.
Tau targets proteins to microtubules.
therefore if a cell expresses blue that cell expresses melanopsin.
then saw melanopsin expressing retinal ganglion cells fromed the retinohypothalamic tract.
axons of cell bodies towards optic disk.
underside of the brain showed blue optic nerves towards the chiasm, SCN has a dark blue stain.
melanopsin KO mice
don’t respond anymore. no depolarisation in response to light.
adding melanopsin to cells to make light sensitive.
Neuro2A cells from mouse neuroblastoma not light sensitive, make express melanopsin, light sensitive only if also given 11-cis retinal cofactor.
melanopsin is therefore sufficient for photosensitivity, and light detection in melanopsin is consistent with that of other known opsins.
rodless coneless humans
disease that causes degeneration.
look at their melatonin production - still normal and synced to LD.
humans with lost eyes or damage to RHT
maintain normal sleep wake cycles with alarm clocks etc but melatonin free runs.
therefore a non rod/cone photoreceptor in eyes of humans regulates melatonin similar to melanopsin
melanopsin KO mice
more severe free running but retain photoentrainment.
DD followed by light pulse, show robust phase delay.
where do ganglion cells get info from?
rods and cones through other cells
