Transcript Chapter 5bF
Biology 484 – Ethology
Chapter 5b – Neurohormones
5.4 Nervous system and digestive system of a blowfly
The recurrent nerve is a sensory nerve that receives sensory input from
the foregut. As we saw in our video, when this nerve is severed, it will
keep the fly from receiving these signals and the blowfly will eat beyond
capacity.
This is an inhibitory
behavioral response
that is guided neurally
but leads to the
release of hormones in
the brain that will
promote satiety.
5.7 The cricket nervous system
If the optic lobe region of the brain is separated from the
subesophageal ganglion, the fly will lose its clock rhythm… its ability
to maintain a circadian rhythm.
A circadian rhythm is an
endogenously driven cycle
in biochemical,
physiological, and/or
behavioral processes.
Typically close to a 24 hour
time frame, circadian
rhythms have been
observed in plants, animals,
and even fungi.
5.8 A master clock may regulate mechanisms controlling circadian rhythms within individuals
The master “clock” (the pacemaker) will regulate the response of many
other timed rhythms in the body. This pacemaker will in tern be
regulated by sensory information it receives.
5.10 Mutations of the per gene affect the circadian rhythms of fruit flies
The per gene is a
regulatory gene that has
been shown to affect
circadian rhythms in fruit
flies. The bars indicate
periods of activity.
Notice how each point
mutation affects the genes
regulation of the “clock”
differently.
5.11 Expression of the gene that codes for PK2 in the SCN
PK2 is the equivalent of
per in mammals. Here we
see differences in
expression of PK2
dependant upon the hour
of the day.
LD = 12:12 Light/dark
cycle
2DD = two days of
darkness
8DD = eight days of
darkness
5.12 Circadian control of wheel-running by white rats changes when the rats are injected with PK2
Behaviorally, we see
that that infusions of the
products of PK2 in the
suprachiasmatic
nucleus (SCN) alter
wheel running behavior.
In this instance, the
control group shows
high activity at night,
whereas the PK2 group
shows high daytime
activity.
5.13 Naked mole-rats lack a circadian rhythm
Logically, the naked molerat’s lack of rhythm can be
understood when we think
of it living its entire life
underground.
5.14 Circannual rhythm of the golden-mantled ground squirrel
Circannual rhythms are produced when the internal biological clock also
operates on an annual basis.
5.16 Lunar cycle of banner-tailed kangaroo rats
5.17 A cycle of photosensitivity
White-crowned sparrows exhibit a clock mechanism that is highly light
sensitive between a specific two hour patch (hours 17-19 in a 24 hour
clock). The read peaks show these sensitivities. When the bird receives
light stimulus at those times, testicular growth is seen. Other light cycles
failed.
5.18 A hormonal response to light
Leutenizing hormone is a pituitary
hormone that will stimulate the
activity of the gonads.
The birds were held in darkness for
varying lengths of time, and THEN
exposed to an 8 hour period of
light. (Upper graph)
After the 8 hour exposure, the
typical cycling rate in LH was
maintained for the five days shown.
5.20 Photoperiod affects testis size in the red crossbill
Question to Ponder: How would you explain
this seasonal rhythm?
5.21 Regulation of infanticide by male house mice (Part 1)
Infanticide can be affected by manipulation of the circadian rhythm.
5.21 Regulation of infanticide by male house mice (Part 2)
Fast Day males (those in the teal color) halted the display of infanticidal
behavior within 20 days of real time (their perceived days were 22).
By contrast, Slow Day males (those in the purple) did not show a decline in
infanticde until 25 days of real time (their perceived day 22).
5.22 A hormonal effect on infanticidal behavior in laboratory mice
Progesterone surges
appear to be the key to
inducing infanticide.
Males lacking this
gene, do not display
infanticide.
The PRKO mouse is a
knockout mouse that
lacks the ability to
detect its own
circulating
progesterone.
Pup Morphology as a Measure of Development
Measurements:
•
•
•
•
Anogenital Distance
Interoccular Distance
Body Length
Weight
Reproductive
Behaviors in Rats
Reproductive
Behaviors
Reproductive Behaviors - Data
Male Reproductive Behaviors:
• Mounts
• Intromissions
• Ejaculations
Reproductive Behaviors - Data
Female Reproductive Behavior:
Lordosis
Lordosis Score of “0”
Lordosis Score of “1”
Lordosis Score of “2”
Lordosis Score of “3”
Results of Male Reproductive Behavior Tests Following Developmental
Exposure to PFOA
Reproductive Behaviors - Results
Average Mounts vs. Average
Intromissions
Percentage of Animals
Displaying Sex Behavior
120.00%
8
7
100.00%
6
80.00%
5
4
60.00%
3
40.00%
2
20.00%
1
0.00%
0
Avg. Mounts
Avg. Intromissions
CM TM
Pre-Ejaculatory Behaviors
Ejaculation
CM TM
5.23 Testosterone and progesterone levels in two categories of male California mice
NS
Significant
5.24 Testosterone and the control of sexual motivation in male Japanese quail (Part 1)
5.24 Testosterone and the control of sexual motivation in male Japanese quail (Part 2)
Therefore…. Even though testosterone is produced by the gonads,
the motivation to behave sexually is controlled by estradiol.
Estradiol is therefore the hormone that is associated with male
sexual motivation. Notice the red line with the aromatase inhibitor.
5.32 Testosterone and territorial behavior (Part 1)
Notice how
elevated
testosterone is
associated with
territorial behavior.