Neurons & Glia Chapter 2 PDF

Summary

This document provides an overview of neurons and glia, covering topics such as historical context, histological methods, basic cell biology of neurons, and the roles of glial cells in the CNS and PNS. It also details different types of stains used, such as Nissl and Golgi stains.

Full Transcript

Neurons & Glia

Chapter 2
 – Discuss the historical context & histological
methods that lead to the neuron doctrine
Learning – Learn about the basic cell biology of neurons and
their classifications
objectives – Understand the role of glial cells in the central
nervous system (CNS) and peripheral nervous
system (PNS)
 – Neurons
– Process information
– Sense environmental changes
– Communicate changes to other neurons
– Command body response
– Glia insulate, support, and nourish neurons.
– A bit analogous to the relationship between football players and fans
Role of glia
and neurons
 – Histology (histos, tissue) is the
microscopic study of tissue structure.
– Two types of histology techniques (stains)
paved the way for our modern
understanding of neuroscience:
– Nissl stain / Cresyl Violet (named after
Histology Franz Nissl)
– Facilitates the study of cytoarchitecture in
Nissl stain of ventral horn

the CNS
– Golgi stain (named after Camillo Golgi)
– Allows differentiation of soma and
perikaryon
– Neurites: axons and dendrites

Golgi stain of subiculum
 – Histology (histos, tissue) is the
microscopic study of tissue structure.
– Two types of histology techniques (stains)
paved the way for our modern
understanding of neuroscience:
– Nissl stain / Cresyl Violet (named after
Histology Franz Nissl)
– Facilitates the study of cytoarchitecture in
the CNS
– Golgi stain (named after Camillo Golgi)
– Allows differentiation of soma and
perikaryon
– Neurites: axons and dendrites

Basic parts of a neuron
 – Various dyes (such as cresyl violet) target
negatively-charged molecules – namely,
DNA & RNA
– Accumulation of DNA & RNA molecules in
ribosomes & endoplasmic reticulum of
neuronal cell bodies are called “Nissl
Nissl stains bodies”
Nissl stain of ventral horn – 40x
magnification vs. 5x

– Nissl bodies therefore “drink up” lots of dye
and are easily visualized with this staining
technique
– Good for figuring out anatomical neuronal
cell body distribution / density
 – Silver nitrate + potassium dichromate are applied to
preserved (“fixed”) tissue
– Random cells in the area will pick up the chemicals and get
completely filled with micro-crystalized silver chromate (think
of wax mold)
– Good for figuring out detailed cell morphology
(shape/structure)
Golgi stains

From Dr. Zhou’s 2020 paper: https://elifesciences.org/articles/55569
 – Neuron doctrine – fundamental ”doctrine” of neuroscience
– Neurons adhere to cell theory: individual neurons are the smallest
anatomical building blocks of the nervous system
– Neural circuitry
– Neurons communicate by contact, not continuity (in contrast to
Golgi’s ideology)
– Santiago Ramon y Cajal figured this out after using Golgi staining to study
neuroanatomy
The Neuron
Doctrine

Basic parts of a neuron
 – Discuss the historical context & histological
methods that lead to the neuron doctrine
Learning – Learn about the basic cell biology of neurons and
their classifications
objectives – Understand the role of glial cells in the central
nervous system (CNS) and peripheral nervous
system (PNS)
 – Neurons (nerve cells) are structural units of
nervous system
– Large, highly specialized cells that conduct
impulses
– Special characteristics
Cells of the – Extreme longevity (lasts a person’s lifetime)
– Amitotic, with few exceptions
nervous – High metabolic rate: requires continuous supply of
oxygen and glucose
system – All have cell body (soma) and one or more
processes
 – Also called the perikaryon or soma
– Biosynthetic center of neuron
– Contains spherical nucleus with nucleolus
– In most, plasma membrane is part of receptive
The neuron region that receives input info from other neurons
cell body – Most neuron cell bodies are located in CNS
(soma) – Nuclei: clusters of neuron cell bodies in CNS
– Ganglia: clusters of neuron cell bodies in PNS
 – The soma or cell body contains:
– Cytosol: watery fluid inside the
Components cell

of the – Organelles: membrane-enclosed
structures within the soma
neuronal – Cytoplasm: contents within a cell
membrane (e.g., organelles,
soma excluding the nucleus)

Internal structure of a typical neuron
 – Inside the soma we have the
nucleus which is responsible for:
– Gene expression
– Transcription
– RNA processing

Components – Neuronal genes are special due to
genetic variation and genetic
of the engineering
neuronal – Neurons differ from other cells
because of specific genes.
soma – Sequencing of human genome
– Genetic basis of many diseases
of the nervous system
– Role of genetic engineering and
gene targeting

Internal structure of a typical neuron
 – We also have
ribosomes in the soma:
– Major site of protein
Components synthesis

of the – Studded on rough
endoplasmic reticulum
neuronal (ER)
– Protein synthesis also
soma on free ribosomes;
polyribosomes
 – Smooth ER and Golgi apparatus are also in the soma
– Sites for preparing/sorting proteins for delivery to
different cell regions (trafficking) and regulating
substances
Components
of the
neuronal
soma
Components – ~Mitochondria is the powerhouse of the cell
of the (soma)~
– Site of cellular respiration (energy generation)
neuronal – Krebs cycle / electron transport chain

soma – ATP is cell’s energy source
 – Central component of electrical
functioning in the nervous system
– Barrier that encloses the entire neuron

The neuronal – ~5 nm thick
– Protein concentration in membrane
membrane varies.
– Structure of discrete membrane
regions influences neuronal function.

Neuronal membrane channels &
their role in electrical activity
 – The cytoskeleton
– Not static (squirming structures!)
– Internal scaffolding of neuronal
membrane
– Made up of three structures:
– Microtubules
– Thick hollow-walled pipes made of
tubulin “beads” that can polymerize
The together to form various shapes
– Microtuble-associated proteins
cytoskeleton (MAPs) implicated in dementia
– Microfilaments
– Tiny tubes of actin protein that
constantly change shape as needed
– Neurofilaments
– Like the bones & ligaments of the
neuronal skeleton – the strongest &
most rigid
 – The cytoskeleton
– Not static (squirming structures!)
– Internal scaffolding of neuronal
membrane
– Made up of three structures:
– Microtubules
– Thick hollow-walled pipes made of
tubulin “beads” that can polymerize
The together to form various shapes
– Microtuble-associated proteins
cytoskeleton (MAPs) implicated in dementia
– Microfilaments
– Tiny tubes of actin protein that
constantly change shape as needed
– Neurofilaments
– Like the bones & ligaments of the
neuronal skeleton – the strongest &
most rigid
Also from Dr. Zhou’s 2020 paper:
https://elifesciences.org/articles/55569
 – Armlike processes that extend from cell body
– CNS contains both neuron cell bodies and their
processes
– PNS contains chiefly neuron processes
– Tracts
Parts of the – Bundles of neuron processes in CNS

neuron – – Nerves
– Bundles of neuron processes in PNS
neuron – Two types of processes
processes – Dendrites
– Axon
 – Dendrites
– Motor neurons can contain 100s of these short,
tapering, diffusely branched processes
– Contain same organelles as in cell body
– Receptive (input) region of neuron
Parts of the – Convey incoming messages toward cell body as
graded potentials (short distance signals)
neuron – – In many brain areas, finer dendrites are highly
specialized to collect information
dendrites – Contain dendritic spines, appendages with
bulbous or spiky ends
Parts of the
neuron –
dendrites

Structure of a motor neuron digitally reconstructed at 1000x magnification
 – The axon: structure
– Each neuron has one axon that starts at cone-shaped
area called axon hillock
– In some neurons, axons are short or absent; in others,
axon comprises almost entire length of cell
– Some axons can be over 1 meter long
– Long axons are called nerve fibers
Parts of the – Axons have occasional branches called axon
collaterals
neuron – the – Axons branch profusely at their end (terminus)

axon – Can number as many as 10,000 terminal branches
– Distal endings are called axon terminals or terminal
boutons
 – The axon: functional characteristics
– Axon is the conducting region of neuron
– Generates nerve impulses and transmits them along
axolemma (neuron cell membrane) to axon terminal
– Terminal: region that secretes neurotransmitters, which
are released into extracellular space
– Can excite or inhibit neurons it contacts
Parts of the – Carries on many conversations with different neurons
neuron – the at same time
– Axons rely on cell bodies to renew proteins and
axon membranes
– Quickly decay if cut or damaged
 – The axon: functional characteristics (cont.)
– Axons have efficient internal transport mechanisms
– Molecules and organelles are moved along axons by
motor proteins and cytoskeletal elements
– Movement occurs in both directions

Parts of the – Anterograde: away from cell body
– Examples: mitochondria, cytoskeletal elements, membrane
components, enzymes
neuron – the – Retrograde: toward cell body

axon – Examples: organelles to be degraded, signal molecules,
viruses, and bacterial toxins
 – The axon: functional characteristics (cont.)
– Axons have efficient internal transport mechanisms
– Molecules and organelles are moved along axons by
motor proteins and cytoskeletal elements
– Movement occurs in both directions

Parts of the – Anterograde: away from cell body
– Examples: mitochondria, cytoskeletal elements, membrane
components, enzymes
neuron – the – Retrograde: toward cell body

axon – Examples: organelles to be degraded, signal molecules,
viruses, and bacterial toxins
 – Certain viruses and bacterial toxins
damage neural tissues by using
retrograde axonal transport
– Example: polio, rabies, and herpes
Axoplasmic simplex viruses, and tetanus toxin

– Research is under way to investigate
transport using retrograde transport to treat genetic
diseases
– Viruses containing “corrected” genes or
microRNA to suppress defective genes
can enter cell through retrograde transport
Rabies virus labeled neurons
 – Synaptic transmission is the
fundamental way in which neurons
communicate with each other
– Usually occurs between an axon à
subsequent dendrite of next neuron,
but other types of synapses exist
which we’ll learn about later
The synapse
– Electrical-to-chemical-to-electrical
transformation
– Synaptic transmission dysfunction
leads to mental disorders.
 – Structural classification
– Three types grouped by number of processes
1. Multipolar: three or more processes (1 axon, others dendrites)
– Most common and major neuron type in CNS
2. Bipolar: two processes (one axon, 1one dendrite)
– Rare (ex: retina and olfactory mucosa)
3. Unipolar: one T-like process (two axons)
– Also called pseudounipolar
Classifications – Peripheral (distal) process: associated with sensory receptor

of neurons – Proximal (central) process: enters CNS
Classifications
of neurons
Classifications
of neurons
 – Functional classification of neurons
– Three types of neurons grouped by direction in which nerve impulse
travels relative to CNS
1. Sensory
– Transmit impulses from sensory receptors toward CNS
– Almost all are unipolar

Functional 2.
– Cell bodies are located in ganglia in PNS
Motor
classifications – Carry impulses from CNS to effectors
– Multipolar
of neurons – Most cell bodiesC are located in CNS (except some autonomic neurons)
3. Interneurons
– Also called association neurons
– Lie between motor and sensory neurons
– Shuttle signals through CNS pathways
– Most are entirely within CNS
– 99% of body’s neurons are interneurons
Functional
classifications
of neurons
 – Classification of neurons based on gene expression is one of
the “newest” ways we can categorize them
– Creation of transgenic mice
– Transgenic = genes inserted into the organism’s genome that weren’t
originally there, often used to genetically “tag” cells
– Green fluorescent protein

Genetic – Classification based on
classifications neurotransmitter type
– “Cholinergic”
of neurons – ”Serotonergic”
– ”Dopaminergic”

Also from Dr. Zhou’s 2020 paper: https://elifesciences.org/articles/55569
 – Discuss the historical context & histological
methods that lead to the neuron doctrine
Learning – Learn about the basic cell biology of neurons and
their classifications
objectives – Understand the role of glial cells in the central
nervous system (CNS) and peripheral nervous
system (PNS)
 – Four main neuroglia support CNS neurons
– Astrocytes
– Microglial cells
– Ependymal cells
Glia are the – Oligodendrocytes

“support” cells
of the
nervous
system
 – Astrocytes
– Most abundant, versatile,
and highly branched of glial
cells
– Cling to neurons, synaptic
endings, and capillaries
– Functions include:
– Support and brace neurons
– Play role in exchanges
between capillaries and

CNS Glia neurons
– Guide migration of young
neurons
– Control chemical
environment around
neurons
– Respond to nerve impulses
and neurotransmitters
– Influence neuronal
functioning
– Participate in information
processing in brain
 – Microglial cells
– Small, ovoid cells with
thorny processes that
touch and monitor
neurons
CNS Glia – Migrate toward injured
neurons
– Can transform to
phagocytize
microorganisms and
neuronal debris
 – Ependymal cells
– Range in shape from squamous to columnar
– May be ciliated
– Cilia beat to circulate CSF
– Line the central cavities of the brain and spinal column
– Form permeable barrier between cerebrospinal fluid (CSF) in cavities
and tissue fluid bathing CNS cells

CNS Glia
 – Oligodendrocytes
– Branched cells
– Processes wrap CNS nerve fibers, forming insulating myelin
sheaths in thicker nerve fibers

CNS Glia
 – Composed of myelin, a whitish, protein-
lipid substance
– Function of myelin
– Protect and electrically insulate axon
– Increase speed of nerve impulse
transmission
Myelin sheath – Myelinated fibers: segmented sheath
surrounds most long or large-diameter
axons
– Nonmyelinated fibers: do not contain
sheath
– Conduct impulses more slowly
 – Myelin sheaths in the CNS
– Formed by processes of oligodendrocytes, not whole cells
– Each cell can wrap up to 60 axons at once
– Myelin sheath gap is present
– No outer collar of perinuclear cytoplasm
– Thinnest fibers are unmyelinated, but covered by long extensions of adjacent neuroglia

– White matter: regions of brain and spinal cord with dense collections of myelinated
fibers
– Usually fiber tracts

– Gray matter: mostly neuron cell bodies and nonmyelinated fibers

Myelin sheath
 – Two major neuroglia seen in PNS
– Satellite cells
– Surround neuron cell bodies in PNS
– Function similar to astrocytes of CNS
– Schwann cells (neurolemmocytes)
– Surround all peripheral nerve fibers and form myelin sheaths in thicker nerve
fibers
– Similar function as oligodendrocytes
– Vital to regeneration of damaged peripheral nerve fibers

PNS Glia
 – Myelination in the PNS
– Formed by Schwann cells
– Wraps around axon in jelly roll fashion
– One cell forms one segment of myelin
sheath

Myelin sheath – Outer collar of perinuclear cytoplasm
(formerly called neurilemma): peripheral
in the PNS bulge containing nucleus and most of
cytoplasm
– Plasma membranes have less protein
– No channels or carriers, so good electrical
insulators
– Interlocking proteins bind adjacent myelin
membranes
Myelin sheath
in the PNS
 – Myelination in the PNS (cont.)
– Myelin sheath gaps
– Gaps between adjacent Schwann cells
– Sites where axon collaterals can emerge
– Formerly called nodes of Ranvier
Myelin sheath – Nonmyelinated fibers
– Thin fibers not wrapped in myelin; surrounded
in the PNS by Schwann cells but no coiling; one cell may
surround 15 different fibers
Quiz hint! – Types of glia & their general functions
Questions?