Homeostasis Part 2 Lecture PDF

Summary

This document is a lecture on homeostasis, part 2, covering organ systems, biological communication, and control mechanisms in the human body. It outlines objectives, control systems, homeostasis, control pathways, and different types of feedback loops. The document also details how these mechanisms influence various biological processes within the body.

Full Transcript

Introduction to
Organ Systems,
Homeostasis, Biological
Communication and
Control - Part 2
Prof Stefan du Plessis
Objectives
Control Systems and Homeostasis:
Define Physiological control systems
Explain the difference between Local control and Reflex control
Describe the properties of Homeostatic Reflex Pathways
Define the primary components of a reflex pathway response loop
Discuss Feedback loops and distinguish between, Negative feedback
(Homeostatic), Positive Feedback (Non-homeostatic) and Feedforward
Biological Rhythms and setpoints
Control Systems and Homeostasis
The important concept to remember is that the body monitors its internal state
and try to keep it stable.
i.e. certain key functions must stay within a particular operating range (not too far from
its setpoint)
and the body takes action to correct disruptions that threaten its normal function
through physiological control mechanisms
Control Systems
All control systems have 3 components (in its simplest form)

Integrate information
and initiates an
appropriate response
Homeostasis and Controls
Control Pathways
Maintain homeostasis via Control Pathways

There are 2 basic patterns of control mechanisms:

Local control (Simplest form)
Paracrines & autocrines
Long-distance / reflex control
Nervous
Endocrine
Cytokines
 Control Pathways
Local Control Reflex Control
Simplest form of control More complex system
Restricted to the Changes are
cell/tissue involved widespread/systemic
Nearby cell(s) sense the
change in vicinity and Any long-distance pathway
respond by usually that uses the nervous
releasing a chemical. and/or endocrine system
Response is restricted to Expand on the three
area where the change components of response
took place loop

e.g. Tissue O2 decrease - cells secrete chemical – diffuses e.g. Baroreceptors sense blood pressure is to low – relay
to vascular smooth muscle cells - leading to vasodilation information to brain via afferent neurons – respond via
ANS and increase HR and peripheral resistance
Example: Steps in a reflex Pathway
Reflex Control Response Loop
Stimulus – disturbance that sets
the pathway in motion
Sensor/receptor – continuously
monitor environment for specific
parameter
Integrating centers are
Afferent path – when activated by usually part of the
change the sensor sends input signal nervous or endocrine
system
to integrating center
Integration center – compares
input signal with the setpoint or
desired value
Efferent path - output signal that Output signals may be
chemical, electrical or
travels to target combination of both
Effector - target cell/tissue that
carries out the appropriate response
to bring variable back within limits
Types of Receptors
Feedback Loops
Feedback loops modulate the response
Negative: are homeostatic
Response slows stimulation
Return to optimal range
Responds to an altered output by restoring itself towards a predetermined set
point
Positive: are NOT homeostatic
Stimulation drives more stimulation
Responds to a disturbance by moving variables farther away from the initial set
point
Feedforward control prepares body for change
Can anticipate changes and prompt the system to act before the alterations
begin to affect it
Setpoint
Homeostatic range oscillates around setpoint
Each regulated variable has a normal range within which it can vary without
triggering correction
Setpoint
Setpoints vary between individuals and can change over time
Setpoints can be changed to accommodate different physiological
requirements
Inheritance
Acclimatization – adaptation to a given set of environmental conditions
Biorhythms – regulated variables that change predictably and create repeating cycles
e.g. circadian rhythm for blood pressure, body temperature, metabolic processes
Negative Feedback
Opposes or removes the signal
Designed to keep the system
at or near a setpoint
Can restore the normal state,
but cannot prevent the original
stimulus
Negative Feedback
Positive Feedback
Reflex pathway that is not homeostatic
Response reinforces stimulus, rather
than decreasing or removing it
The response sends the regulated value
even farther away from its normal value
(out of control/ballistic)
Requires intervention outside the loop
to stop the response
Positive Feedback
Feedforward Control
Reflexes that predict a change is about to occur and starts the response loop in
anticipation of the change

e.g.
Salivation reflex
Cephalic phase
Cannon’s Postulates – Properties of
Homeostatic Control Systems
The role of the nervous system in preserving the fitness of the internal
environment.
The concept of tonic level of activity (e.g. volume button).
The concept of antagonistic controls - different signals that have opposing effect.
(systems that are not under tonic control are usually under antagonistic control)
The concept that chemical signals have different effects in different tissues of
the body.
Tonic Control
Antagonistic
One Ligand - Different Effects
The target cell response depends on its receptors (isoforms) or its associated
intracellular pathways, not on the ligand.
Objectives
Biological Communication:
Outline and compare the different mechanisms of biological communication in
the body by referring to:
Short distance communication -- Cell-Cell Communication, Contact
dependent, Gap junctions, Paracrine, Autocrine, Juxtacrine, Intracrine
Long distance communication -- Electrical or Chemical/Neural Hormonal
Short- or Long-distance communication -- Cytokines
Cell-to-Cell Communication
Human body compose of 75 trillion cells
Cells may be only 1m up to meters apart
Need to communicate rapidly and convey huge amount of
information to each other
Only two types of physiological signals:
Electrical = changes in RMP
Chemical = molecules secreted into ECF
Cells receiving these signals = Target cells
Cell-to-Cell Communication
Our bodies use various basic methods of cell-to-cell
communication:
Short Distance
Gap junctions
Juxtacrine or Contact-dependant signals
Intracrine
Local communication (autocrine and paracrine)
Long-distance communication
Cell-to-Cell Communication
Gap junctions
Direct cell-to-cell communication
Union of membrane-spanning proteins (connexins)
Transfer chemical & electrical signals
>20 Isoforms – allowing movement of various ions and small molecules (AA, ATP, cAMP)
Cell-to-Cell Communication
Contact-dependent signals/Juxtacrine
Requires cell-to-cell contact (surface molecule on one cell
bind to membrane protein on another)
Immune system, growth and development
Cell adhesion molecules acts as receptors in cell-to-
cell signaling and is linked to cytoskeleton and
intracellular enzymes
CAMs transfer signals in both directions across cell
membrane
Cell-to-Cell Communication
Intracrine
Refers to a hormone that acts inside a cell, regulating intracellular events.
The cell stimulates itself by cellular production of a factor that acts within the cell.
Cell-to-Cell Communication
Local cell-to-cell communication
Chemical signals distributed by diffusion in
Interstitial fluid
Restricted to adjacent cells as diffusion is
limiting factor
Two types:
Autocrine signals – chemical signal that
acts on cell that secreted it
Paracrine signals – chemical signal that acts
on cells in immediate vicinity

e.g. cytokines – regulatory peptides,
eicosanoids - lipid derived signal molecules
Cell-to-Cell Communication
Long distance communication: Hormones
Signal Chemicals
Made in endocrine cells
Transported via blood all over body
Only cells with receptors can react
(Target cells)
Cell-to-Cell Communication
Long distance communication: Neurotransmitter
Electrical signal travels down axon - then translated into chemical signal
Chemical signal then secreted by neuron = neurocrine
Neurotransmitter = diffuse to target cell across narrow extracellular space and have
rapid response
Neuromodulator = if neurocrine acts more slowly as a paracrine or autocrine signal
Cell-to-Cell Communication
Long distance communication: Neurohormone
Electrical signal travels down axon - then translated into chemical signal
Chemical signal then secreted by neuron = neurocrine
Neurohormone = if neurocrine diffuse into blood for distribution.
Cell-to-Cell Communication
Cytokines
Variety of regulatory peptides
All nucleated cells secrete cytokines in response
to stimuli
Control cell development, cell differentiation
and immune response
Mode of action
During development and differentiation they act
as autocrine/paracrine
During stress and inflammation they may act on
distant targets (transported through circulation)
Cytokines Hormones

Act on broad spectrum of cells Specific target cells

Not produced by specialized cells Produced by specialized cells (glands)

Most peptide/protein hormones are
Made on demand
made in advance and stored
Intracellular Communication
(Signal Transduction)
Signal pathway

First
messenger

Second
messenger
Concept Checks: Extended Matching
Communication Communication Communication Property
Method Property ? Electrical signal
Autocrine ? Chemical signal
? Both electrical and chemical signal
Cytokine

Gap Junction You see a car speeding towards you and jump out of
the way. Do you think the internal signal to jump have
Hormone been transmitted by a paracrine signal? Provide 2
reasons to explain why or why not.
Neurohormone

Neurotransmitter

Paracrine
Concept Checks
What is a synonym for a reflex control pathway? Provide an example of a variable that is controlled by
local control?

Give 7 basic steps of reflex control pathway

Provide an example of a variable that is controlled by
Compare local control to reflex (long distance) control long distance control?

Homeostasis tries to maintain variables within a range
and if variable moves out of range, there is a response.
Describe this response.
Concept Checks
What is the drawback of having only a single control What is acclimatization?
system (a heater) for maintaining aquarium water
temperature in some desired range?

What is a feedback loop?

What is tonic control?

What is a positive feedback loop?

What is antagonistic control?
Concept Checks
What is negative feedback control? What is feedforward control?

Is positive feedback a common method for maintaining
Give an example of Negative feedback. homeostasis?

What is the difference between tonic control and
antagonistic control?

Define Set Point.
Concept Checks
What is the pathway of a simple neural reflex? What is an example of a simple neural reflex?

What is the pathway of a simple endocrine reflex? What is an example of a simple endocrine reflex?

What is the pathway of a neurohormone reflex? What is an example of a neurohormone reflex?