Wiring diagram of C. elegans (302 neurons total, 279 neurons shown here. 20 pharyngeal (of or relating to the pharynx) nervous system neurons not shown as well as 3 that do not make synapses with other neurons)
red: sensory neurons
blue: interneurons
green: motor neurons
number of possible node pairs is N*(N-1)/2
for c. elegans: > (302*301)/2
[1] 45451
> (279*278)/2
[1] 38781
6393 chemical synapses, 890 electrical junctions, and 1410 neuromuscular junctions
horizontal axis represents closeness of connectivity (spring embedded graph layout)
vertical aix represents signal flow from top to bottom
from D. Chklovskii. White et al, Phil Trans R Soc Lond B 1986
crispr: clustered reguarly interspaced short palindromic repeat
cas: crispr associated
any eukaryotic dna that contains a PAM sequence can be a target.
PAM sequence: protospacer associated motif, usually two or three nucleotides. Occurs frequently.
* -canonical PAM is the sequence 5'-NGG-3' where "N" is any nucleobase followed by two guanine ("G") nucleobases
* -Guide RNAs (gRNAs) can transport Cas9 to anywhere in the genome for gene editing, but no editing can occur at any site other than one at which Cas9 recognizes PAM.
A guide RNA that contains sequences complementary to a piece of DNA from the target gene of interest brings the Cas9 enzyme to the target site on the chromosome through DNA-RNA base pairing (purple and red)
Two nuclease domains of Cas9 create a double strand break in the genomic DNA. The double strand break can be repaired by the nonhomologous end joining system, through which small deletions or insertions may be created at the repair site.
The ds break can also be repaird by the homologous recombination system with a donor DNA as a template, through which specific modifications such as insertion of a transgene can result.
clarity based tissue clearing for fluorescene imaging.
Intact tissue is fixed in prescence of hydrogel monomers that covalently link DNA RNA, and proteins into a mesh during subsequent polymerization. Lipids (which are a major cause of opacity for fluorescence imaging) are not covalently linked and are removed during subsequent clearing process by passive diffusion or electrophoresis in presence of detergent. Tissue is then transparent for better and deeper imaging. This example is from a Thy1-gfp transgenic mouse imaged with a confocal microscope. Shows neocortex, hippocampus, and thalamus.
<figure><img src="figs/2016-03-0913.07.50_Fig13-21_573d5fd_copy_737a840.jpg" height="400px"><figcaption>Principles of Neurobiology, Garland Science Fig. 13-21; Johnson et al., J Neurosci 2000</figcaption></figure>
Intracellular dye filling to trace axonal projections of a single neuron. Rat posterior piriform cortex pyramidal neuron. Injected in vivo followed by several days. Johnson et al., J Neurosci 2000.
Mapping synaptic protein organization with super res fluorescence microscopy.
double labeling with basson (presynaptic scaffold protein, red) and postsynaptic scaffold protein (homer1, green) in mouse olfactory bulb glomerular layer.
Imaged using stochastic optical reconstruction microscopy (STORM), a super resolution technique. Gets you beyond the diffraction limit for light microscopy, typically 100-150 nm with the highest resolution objectives and shortest wavelengths of visible light.
Third image is higher magnification view.
Right shows distribution of different antibody, STORM imaging resolved proteins around the synaptic cleft.
Mix of phytohemagglutnin (PHA-L, green) an anterograde trace and cholera toxin subunit b (CTb, magenta) a retrograde tracer injected into right insular cortex of a mouse brain. Stained in blue with fluorescent nissl stain. Projections from and to insular cortex.
On right show adeno-assoc viruses expressing Cre-dependent GFP. Injected into motor cortex of mice expressing Cre recombinase in layer 6 or 2/3. Notice different projection patterns of neurons from these two layers in the rendered 3D views.
Gene encoding rabies virus glycoprotein is essential for viral recognition of host cells and for viral spread is replace with GFP in the rabies genome. This mutant rabies virus can no longer recognize and transduce normal mammalian neurons.
Mutant rabies assembled in a cell line that helps assemble the virus with a coat protein from a different virus, the EnvA coat protein (blue). This makes it able to transfect mammalian cells that express the EnvA receptor TVA (cyan) from a transgene.
<figure><img src="figs/2016-03-0913.12.01_Fig13-33_49ce44c_copy_f3994f3.jpg" height="400px"><figcaption>Principles of Neurobiology, Garland Science Fig. 13-33; Campbell et al., IEEE Trans Biomed Eng 1991</figcaption></figure>
multielectrode arrays (like this 10x10 silicon based prototype) are widely used now for recordings from multiple cortical neurons simultaneously and for usages with neural prosthetics. from Campbell et al., IEEE Trans Biomed Eng 1991
chemical and genetically encoded calcium indicators.
fura2 is a fluorophore with a calcium chelating site from calcium buffer EGTA. With low calcium, excitation at 380nm produces stronger fluorescence emission than excitation at 350 nm. Ratiometric imaging at 350/380 gives sensitive measure of [Ca2+]
first genetic calcium reporter based on FRET (fluorescene resonance energy transfer).
Gcamp. permutated gfp is restored to its native 3D structure with an associated increase in fluorescene after calcium triggered binding of the calmodulin binding peptide M13 to calmodulin. Fluorescent intensity thus gives readout of Ca2+. Single APs reliably induce fluorescent intensity changes in GCaMP6 in mouse visual cortical neurons in vivo.
Head fixed preparation on left during 2P imaging. The thirsty mouse can be trained to extend its tongue only when odor A, but not odor B is presented in order to receive a water reward. Motor cortical area controling tongue extension can be imaged during the learning process.
Virtual reality preparation to test the neuronal correlates of memory dependent spatial navigation. Floating styrofoam ball that the mouse is trained to run on, head fixed with electrodes or 2P imaging. Screens providing continuous first person VR experience— in fact this was done by coding a VR environment based on the quake 2 game engine (if any of you have played the classic quake first person shooter games by id software).
The right shows a miniaturized microscope weighing just over a gram that an adult mouse can carry on its head to image brain activity as it freely moves and navigates.
* Multimodal sensory activation, focuses attention, object tracking and stereoscopic vision/depth perception, salience of object, defensive/self preservation, limbic loop, decision making, movement selection, proximal and distal motor pool recruitment, reflex activation— but all from a previously unexperienced activity!
[^Schmolesky-1998]: Schmolesky, M. T., Wang, Y., Hanes, D. P., Thompson, K. G., Leutgeb, S., Schall, J. D., and Leventhal, A. G. (1998). Signal timing across the macaque visual system, J Neurophysiol, 79(6), 3272-8. PMID 9636126
* cell body (soma)– metabolic center of the cell, contains the nucleus.
* dendrites– receive incoming signals from other nerve cells
* axon– carries signals to other neurons
* axon hillock– initiates action potentials
* synapse– site at which two neurons communicate
* synaptic cleft– area between pre and post-synaptic cell
Note:
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## Ways to measure neural activity
* Extracellular recording– an electrode is placed near a neuron. Measures action potentials. Useful for detecting patterns of activity.
* Intracellular recording– an electrode is placed inside a neuron-can measure smaller graded potential changes. Useful for isolating responses to single inputs.
* Voltage clamping– can make the membrane potential of a cell at a desired point and determine the current flow across the membrane.
* Patch Clamping– can measure ion flow across a single channel.
* fMRI– infer activity indirectly in a living brain based on brain oxygenation patterns
Note:
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## General rules of spinal cord organization
* Neurons and axons that process and relay sensory information (afferents) are in dorsal spinal cord.
* Preganglionic visceral motor neurons (innervate glands) are found in the intermediate/lateral region.
* Interneurons are in intermediate zone.
* Motor neurons and axons are found in the ventral portion of the cord.
* Distal muscles are innervated by lateral motor neurons.
* Proximal muscles by medial motor neurons.
Note:
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## Compare and contrast sensory systems
* What are the peripheral receptors? What is their receptive field? What neurotransmitters are used?
* How is the information translated into changes in cell potential?
* What are the circuits, how do they get to the cortex?
* What types of perception defects are associated with damage to different components of the system?
