JoVE Logo
Autorzy
Skontaktuj Się z Nami

Zaloguj się

Aby wyświetlić tę treść, wymagana jest subskrypcja JoVE. Zaloguj się lub rozpocznij bezpłatny okres próbny.

W tym Artykule

  • Podsumowanie
  • Streszczenie
  • Wprowadzenie
  • Protokół
  • Wyniki
  • Dyskusje
  • Ujawnienia
  • Podziękowania
  • Materiały
  • Odniesienia
  • Przedruki i uprawnienia

Podsumowanie

Visualizing myelination is an important goal for many researchers studying the nervous system. CARS is a technique that is compatible with immunofluorescence that can natively image lipids within tissue such as the brain illuminating specialized structures such as myelin.

Streszczenie

Coherent anti-Stokes Raman spectroscopy (CARS) is a technique classically employed by chemists and physicists to produce a coherent signal of signature vibrations of molecules. However, these vibrational signatures are also characteristic of molecules within anatomical tissue such as the brain, making it increasingly useful and applicable for Neuroscience applications. For example, CARS can measure lipids by specifically exciting chemical bonds within these molecules, allowing for quantification of different aspects of tissue, such as myelin involved in neurotransmission. In addition, compared to other techniques typically used to quantify myelin, CARS can also be set up to be compatible with immunofluorescent techniques, allowing for co-labeling with other markers such as sodium channels or other components of synaptic transmission. Myelination changes are an inherently important mechanism in demyelinating diseases such as multiple sclerosis or other neurological conditions such as Fragile X Syndrome or autism spectrum disorders is an emerging area of research. In conclusion, CARS can be utilized in innovative ways to answer pressing questions in Neuroscience and provide evidence for underlying mechanisms related to many different neurological conditions.

Wprowadzenie

Action potentials are the basic unit of information in the brain, and action potential propagation through axons forms one pillar of information processing1,2,3. Neurons typically receive afferent inputs from multiple other neurons and integrate these inputs within a given narrow time window4,5. Therefore, the mechanisms of action potential propagation in axons have received a significant amount of attention from investigators.

When propagating through an axon, an action potential is regenerated repeatedly along the axon to ensure reliable propagation6. In most neurons of jawed vertebrates (gnathostomes) axons are surrounded by a sheath of myelin, which is a lipid-rich substance produced by nearby oligodendrocytes or Schwann cells, which are types of glial cells (reviewed in7,8). This myelin sheath electrically insulates the axon, reducing its capacitance and allowing action potential propagation efficiently, quickly, and with lower energy consumption. Myelin does not cover the axon uniformly, but it sheaths the axon in segments that have short gaps in between them, called the nodes of Ranvier (reviewed in9,10). Both myelination thickness, which controls the level of electrical insulation of an axon, and the spacing of the nodes of Ranvier, which control the frequency with which action potentials are regenerated along an axon, influence the speed of action potential propagation (reviewed in11).

There is a large body of literature suggesting that myelination thickness affects the speed of action potential propagation in axons12,13,14. Moreover, alterations in axon myelination can result in a number of CNS deficits15,16,17,18,19,20,21. It is therefore not surprising that the focus of many research efforts involves the measurement and characterization of axon myelination. Measurements of myelin thickness have most commonly been done with electron microscopy, a technique that requires a significant amount of tissue preparation and is challenging to use in combination with immunohistochemistry. However, there is also a faster and simpler technique to measure axon myelination that is based on Coherent Anti-Stokes Raman Spectroscopy (CARS). A CARS laser can be tuned to various frequencies and when tuned to frequencies that are suitable to excite lipids, myelin can be imaged without the need for any additional labels22. The lipid imaging can be combined with standard immunohistochemistry such that lipids can be imaged together with several fluorescent channels23. Imaging myelination with CARS is significantly faster than electron microscopy and has a resolution that is, albeit lower than EM, sufficient to detect even small differences in myelination in the same type of axons.

Access restricted. Please log in or start a trial to view this content.

Protokół

All experiments complied with all applicable laws, National Institutes of Health guidelines, and were approved by the University of Colorado Anschutz Institutional Animal Care and Use Committee.

1. Animals

  1. Use C57BL/6J (stock #000664) mice (Mus musculus) obtained from The Jackson Laboratory or Mongolian gerbils (Meriones unguiculatus) originally obtained from Charles River.

2. Tissue preparation

  1. For transcardial perfusion, overdose rodent species of interest with pentobarbital (120 mg/kg body weight) and transcardially perfuse them with phosphate-buffered saline (PBS; 137 mM NaCl, 2.7 mM KCl, 1.76 mM KH2PO4, 10 mM Na2HPO4) followed by 4% paraformaldehyde (PFA)24.
    1. Specifically, open the abdomen and the rib cage using scissors and hold the rib cage in place with Kelly hemostatic forceps to expose the heart.
    2. Insert a 23 GA needle connected to a perfusion pump into the left ventricle and quickly cut the right atrium using fine scissors.
    3. Administer PBS through the perfusion pump and the needle in the heart for 10 min to clear the brain and body of blood.
    4. Switch the perfusion pump to 4% PFA for 10 min and check for rigidity of limbs and tail to confirm successful perfusion.
  2. After perfusion, decapitate the animals and remove their brain from the skull. Keep the brains overnight in 4% PFA before transferring to PBS. Embed brainstems in 4% agarose (in PBS) and slice coronally using a vibratome at 200 µm thickness.

3. Staining

  1. Stain free floating sections for Nissl, to visualize cell bodies (1:100), in antibody media (AB media: 0.1 M phosphate buffer (PB: 50 mM KH2PO4, 150 mM Na2HPO4), 150 mM NaCl, 3 mM Triton-X, 1% bovine serum albumin (BSA)) for 30 min at room temperature on a standard laboratory shaker25.
    1. Protect sections from light using aluminum foil and/or a cover. 550 nm or below wavelengths are compatible with CARS imaging (Figure 1).
      NOTE: While we do not expect that Triton-X or other reagents have an impact on CARS imaging of lipids, additional controls with specific antibody media may be warranted.
  2. PAUSE POINT: Store free floating sections (while protected from light) in PBS until imaging. Once sectioned, image brain sections within 2 weeks.

figure-protocol-2771
Figure 1: CARS imaging can be combined with immunofluorescent imaging. The graphs shows that CARS imaging occurs at 660/640 nm red signal spectrum26. This wavelength is sufficiently far removed from the green, blue, or UV range, allowing for combination of the CARS signal with immunofluorescence in these ranges. Specifically, the graph also indicates the excitation and emission for Nissl tagged with blue fluorophore, which was combined with CARS during the collection of representative results for this publication. Please click here to view a larger version of this figure.

4. Imaging

NOTE: The CARS laser set up contains a fiber laser that provides the 80 MHz clock, and an OPO (Optical Parametric Oscillator) laser with a tunable range of 770-990 nm with the Stokes beam fixed at 1031 nm, which are needed for collecting the CARS signal. There is one aperture for both beams.

  1. Before bringing samples to the microscope, turn on and warm up CARS laser for at least 1 h, align the CARS laser, and Koehler the condenser optics and the diaphragm of the microscope for forward CARS imaging.
    NOTE: This step is critical for proper function of CARS microscopy.
    1. For spatial alignment of the two laser beams (pump and stokes), access the two internal PSDs (position sensitive detectors) via the CARS laser GUI.
    2. Achieve temporal alignment by using the delay function in the CARS laser GUI, which can help overlap the pulses of the two lasers (pump and stokes) that have different dispersions because of their different wavelengths. Therefore, both the temporal and spatial overlapping of the pump and stokes beams are done with the user input through the GUI.
    3. Adjust the external periscope (last two mirrors of the setup) to center the spatially overlapped two lasers onto the scanning head mirrors of the microscope.
    4. For best forward CARS non-descanned detection, make sure the condenser is Koehler-ed (meaning the condenser is centered and focused onto the diaphragm to achieve uniform illumination)
  2. For immunofluorescence confocal imaging and CARS imaging, fit the CARS laser, with both forward and epi CARS non-descanned detectors (NDDs), by incorporating a confocal microscope equipped with visible lasers for fluorescence imaging (Figure 2).
  3. Place sections in a culture dish with coverslip (for inverted microscopy), PBS to avoid the tissue drying out, and a glass weight to keep tissue near coverslip.
  4. Take z-stacks or single images with a 60X, 1.2 NA infrared corrected water objective, which serves for collection of the CARS signal in the epi direction and through a 0.55 NA condenser in the forward direction for imaging brain areas such as the medial nucleus of the trapezoid body (MNTB).
    1. Take the CARS images at approximately 600 mW pump/probe and 300 mW Stokes, by using the CARS laser GUI. These laser power values are measured internally by the system. Both lasers' powers at the sample location are less than 25 mW and safe for the tissue sample.
    2. Overlap the pump and Stokes beams spatially and temporally. Tune the OPO to 797.2 nm. This yields a CARS wavelength of 650 nm. Because of the higher energy level, the resulting return to the ground state is anti-Stokes (blue shifted) to the excitation.
    3. Capture the CARS signal in epi or forward non-descanned detectors using bandpass filters (640-680 nm) followed by sequential detection of the immunofluorescence label (in this instance fluorescently labeled Nissl).
      NOTE: The Nissl neuronal soma marker is not caught in the CARS 640-680 nm bandpass filter, allowing the combination of fluorescence and CARS imaging in the images presented below.
    4. The CARS and fluorescence do not share PMTs. Use these settings for optimal lipid signal to selectively image myelination in the brain area.
      CAUTION: Shield the user from the laser beam
  5. Save the images as .oib files, which can be imported into an image analysis program for further quantification (Figure 3).

figure-protocol-7351
Figure 2: CARS instrument diagram showing CARS lasers (red arrows) and non-descanned (NDD) epi and forward detection incorporated onto a laser scanning confocal. In forward NDD we acquire CARS for C-H bonds (dark red arrows) and SHG (second harmonic generatioin) at 515 nm (orange arrow). In epi NDD, we acquire CARS for C-H bonds (dark red arrows) and 2PE (two-photon emission) autofluorescence (light blue arrow). Sequentially, fluorescence confocal images can be acquired (green arrows for visible laser, blue arrows for confocal detection). Please click here to view a larger version of this figure.

figure-protocol-8257
Figure 3: CARS can illuminate myelin (magenta) in brain tissue (brainstem) while also imaging Nissl (cyan) or fluorescent markers. The two panels show representative results from a Mongolian gerbil (single image M. unguiculatus, Figure 3A,C,E) and mouse (z-stack max projection M. musculus, Figure 2B,D,F) brain, indicating that this technique can be used across species. Figure 3A,B showing Nissl in cyan, C,D show the CARS signal in magenta, E,F combine the Nissl and CARS signals with each panel for gerbil or mouse, respectively. Both sets of images show a section of the medial nucleus of the trapezoid body (MNTB) in the brain stem. Neurons in the MNTB receive inputs from heavily myelinated axons, which terminate in the calyx of held, a type of giant synapse27. Scale bar is 20 µm. Please click here to view a larger version of this figure.

Access restricted. Please log in or start a trial to view this content.

Wyniki

One of the biggest advantages of CARS microscopy over other techniques is the compatibility with fluorescent imaging23. Figure 1 shows the CARS spectra compared to Nissl tagged with immunofluorescent marker showing little/no overlap in spectra. Figure 2 illustrates the laser set up for CARS in combination with confocal microscopy. Figure 3 demonstrates two representative images, one as a single stack and one ...

Access restricted. Please log in or start a trial to view this content.

Dyskusje

A growing body of literature emphasizes the role of myelin in brain function13,16,21,28. Moreover, we know that myelination thickness and myelination pattern can change in several neurological conditions such as multiple sclerosis (reviewed in29), aging (reviewed in30), autism20,31, and ma...

Access restricted. Please log in or start a trial to view this content.

Ujawnienia

The authors declare no conflicts of interest.

Podziękowania

Supported by NIH R01 DC 17924, R01 DC 18401 (Klug), and NIH 1R15HD105231-01, T32DC012280, and FRAXA (McCullagh). The CARS imaging was performed in the Advanced Light Microscopy Core part of the NeuroTechnology Center at the University of Colorado Anschutz Medical Campus supported in part by NIH P30 NS048154 and NIH P30 DK116073.

Access restricted. Please log in or start a trial to view this content.

Materiały

NameCompanyCatalog NumberComments
Anesthetic:
1 mL disposable syringe with needle 27 GA x 0.5"Exel int260040
Fatal +Vortech
Surgery:
Spring Scissors - 8mm Cutting EdgeFine Science Tools15024-10
Standard tweezersFine Science Tools11027-12
Perfusion:
4% ParaformaldehydeFisher ChemicalSF994 (CS)
Fine Scissors - SharpFine Science Tools14063-11
Kelly hemostatsFine Science Tools13019-14
Millipore H2O
Needle tip, 23 GA x 1"BD precision glide305193
Phosphate buffered saline (PBS):
Potassium chlorideSigmaP9333
Potassium phosphate monobaseSigmaP5655
pump with variable flow or equivalent
Sodium chlorideFisher Chemicals271-1
Sodiumphosphate dibasicSigmaS7907
Dissection:
50 mL vial with 4% PFA
Bochem Chemical Spoon 180mmBochem230331000
Fine Scissors - SharpFine Science Tools14063-11
Noyes Spring ScissorsFine Science Tools15011-12
Pair of fine (Graefe) tweezersFine Science Tools11050-10
Shallow glass or plastic tray, approximately 10" x 10"
Standard tweezersFine Science Tools11027-12
Surgical Scissors - BluntFine Science Tools14000-20
Slicing:
Agar, plantRPI9002-18-0
VibratomeLeicaVT1000s
well plateAlkali Sci.TPN1048-NT
Staining:
AB Media:1n 1,000 mL of Millipore H2O
Phosphate buffered (PB):
Potassium Phosphate MonobaseSigmaP5655
Sodium Phosohate DibasicSigmaS7907
BSA (Bovine serum albumin)Sigma life scienceA2153-100g
Sodium ChlorideFisher Chemicals271-1
Triton X-100Sigma - Aldrichx100-500ml
Nissl 435/455InvitrogenN21479
CARS:
APE picoemerald laserAngewandte Physik & Elektronik GmbH
bandpass filter (420-520 nm)Chroma TechnologyHQ470/100m-2P
bandpass filter (500-530 nm)Chroma TechnologyHQ515/30m-2P
bandpass filters (640-680 nm)Chroma TechnologyHQ660/40m-2P
Confocal microscopeOlympusFV1000
Cut Transfer pipetFisher13-711-7M
dichroic longpass 565 nmChroma Technology565dcxr
dichroic longpass 585 nmChroma Technology585dcxr
dichroic shortpass 750 nmChroma TechnologyT750spxrxt
glass bottom culture dishMatTekP35G-0-10-C
glass weight (10 mm x 10 mm boro rod)Allen Scientific Glass Inc
multiphoton shortpass emission filter 680 nmChroma TechnologyET680sp-2p8
PBS

Odniesienia

  1. Cole, K., Curtis, H. Electric impedance of the squid giant axon during activity. The Journal of General Physiology. 22 (5), 649-670 (1939).
  2. Cole, K. S., Curtis, H. J. Membrane potential of the squid giant axon during current flow. Journal of General Physiology. 24 (4), 551-563 (1941).
  3. Alcami, P., El Hady, A. Axonal computations. Frontiers in Cellular Neuroscience. 13, 413(2019).
  4. Neumann, E., Nachmansohn, D. Nerve excitability-Toward an integrating concept. Aharon Katzir Memorial Volume. , 99-166 (1975).
  5. Waxman, S. G. Integrative properties and design principles of axons. International Review of Neurobiology. 18, 1-40 (1975).
  6. Fitzhugh, R. Computation of impulse initiation and saltatory conduction in a myelinated nerve fiber. Biophysical Journal. 2 (1), 11-21 (1962).
  7. Zalc, B. The acquisition of myelin: a success story. Novartis Foundation Symposium. 276, 275-281 (2006).
  8. Salzer, J. L., Zalc, B. Myelination. Current Biology. 26 (20), 971-975 (2016).
  9. Boullerne, A. I. The history of myelin. Experimental Neurology. 283, 431-445 (2016).
  10. Kuhn, S., Gritti, L., Crooks, D., Dombrowski, Y. Oligodendrocytes in development, myelin generation and beyond. Cells. 8 (11), 1424(2019).
  11. Saab, A. S., Nave, K. -A. Myelin dynamics: protecting and shaping neuronal functions. Current Opinion in Neurobiology. 47, 104-112 (2017).
  12. Chomiak, T., Hu, B. What is the optimal value of the g-Ratio for myelinated fibers in the rat CNS? A theoretical approach. PLOS ONE. 4 (11), 7754(2009).
  13. Ford, M. C., et al. Tuning of Ranvier node and internode properties in myelinated axons to adjust action potential timing. Nature Communications. 6, 8073(2015).
  14. Stange-Marten, A., et al. Input timing for spatial processing is precisely tuned via constant synaptic delays and myelination patterns in the auditory brainstem. Proceedings of the National Academy of Sciences of the United States of America. 114 (24), 4851-4858 (2017).
  15. Bu, J., Banki, A., Wu, Q., Nishiyama, A. Increased NG2+ glial cell proliferation and oligodendrocyte generation in the hypomyelinating mutant shiverer. Glia. 48 (1), 51-63 (2004).
  16. Pacey, L. K. K., et al. Delayed myelination in a mouse model of fragile X syndrome. Human Molecular Genetics. 22 (19), 3920-3930 (2013).
  17. Green, A. J., et al. Clemastine fumarate as a remyelinating therapy for multiple sclerosis (ReBUILD): a randomised, controlled, double-blind, crossover trial. Lancet. 390 (10111), London, England. 2481-2489 (2017).
  18. Jeon, S. J., Ryu, J. H., Bahn, G. H. Altered translational control of fragile X mental retardation protein on myelin proteins in neuropsychiatric disorders. Biomolecules & Therapeutics. 25 (3), 231-238 (2017).
  19. Barak, B., et al. Neuronal deletion of Gtf2i, associated with Williams syndrome, causes behavioral and myelin alterations rescuable by a remyelinating drug. Nature Neuroscience. 22 (5), 700-708 (2019).
  20. Phan, B. N., et al. A myelin-related transcriptomic profile is shared by Pitt-Hopkins syndrome models and human autism spectrum disorder. Nature Neuroscience. 23 (3), 375-385 (2020).
  21. Lucas, A., Poleg, S., Klug, A., McCullagh, E. A. Myelination deficits in the auditory brainstem of a mouse model of fragile X syndrome. Frontiers in Neuroscience. 15, 1536(2021).
  22. Wang, H., Fu, Y., Zickmund, P., Shi, R., Cheng, J. -X. Coherent anti-stokes raman scattering imaging of axonal myelin in live spinal ttissues. Biophysical Journal. 89 (1), 581-591 (2005).
  23. Kim, S. -H., et al. Multiplex coherent anti-stokes raman spectroscopy images intact atheromatous lesions and concomitantly identifies distinct chemical profiles of atherosclerotic lipids. Circulation Research. 106 (8), 1332-1341 (2010).
  24. Gage, G. J., Kipke, D. R., Shain, W. Whole animal perfusion fixation for rodents. Journal of Visualized Experiments. (65), e3564(2012).
  25. Tu, L., et al. Free-floating Immunostaining of Mouse Brains. Journal of Visualized Experiments. (176), e62876(2021).
  26. Fluorescence SpectraViewer. , Available from: https://www.thermofisher.com/order/fluorescence-spectraviewer (2022).
  27. Held, H. Die centrale gehörleitung. Arch Anat Physiol Anat Abt. 17, 201-248 (1893).
  28. Sherman, D. L., Brophy, P. J. Mechanisms of axon ensheathment and myelin growth. Nature Reviews Neuroscience. 6 (9), 683-690 (2005).
  29. Gruchot, J., et al. The molecular basis for remyelination failure in multiple sclerosis. Cells. 8 (8), 825(2019).
  30. Rivera, A. D., et al. Epidermal growth factor pathway in the age-related decline of oligodendrocyte regeneration. Frontiers in Cellular Neuroscience. 16, 838007(2022).
  31. Kútna, V., O'Leary, V. B., Hoschl, C., Ovsepian, S. V. Cerebellar demyelination and neurodegeneration associated with mTORC1 hyperactivity may contribute to the developmental onset of autism-like neurobehavioral phenotype in a rat model. Autism Research: Official Journal of the International Society for Autism Research. 15 (5), 791-805 (2022).
  32. Ozsvár, A., et al. Quantitative analysis of lipid debris accumulation caused by cuprizone induced myelin degradation in different CNS areas. Brain Research Bulletin. 137, 277-284 (2018).
  33. Prineas, J. W., Graham, J. S. Multiple sclerosis: capping of surface immunoglobulin G on macrophages engaged in myelin breakdown. Annals of Neurology. 10 (2), 149-158 (1981).
  34. Bégin, S., et al. Automated method for the segmentation and morphometry of nerve fibers in large-scale CARS images of spinal cord tissue. Biomedical Optics Express. 5 (12), 4145-4161 (2014).

Access restricted. Please log in or start a trial to view this content.

Przedruki i uprawnienia

Zapytaj o uprawnienia na użycie tekstu lub obrazów z tego artykułu JoVE

Zapytaj o uprawnienia

Przeglądaj więcej artyków

Coherent Anti Stokes Raman SpectroscopyCARSMyelinationBrain ImagingAction PotentialsBrain FunctionLight MicroscopyFluorescence ImagingImmunohistochemistryMultiple SclerosisAgingAutismLipid ImagingCH2 BondsTissue PreparationLaser AlignmentConfocal ImagingImage Acquisition Parameters

This article has been published

Video Coming Soon

JoVE Logo

Prywatność

Warunki Korzystania

Zasady

Skontaktuj Się z Nami

Poleć Bibliotece

BIULETYNY JoVE

Badania

Edukacja

Autorzy

Bibliotekarze

O JoVE

Copyright © 2025 MyJoVE Corporation. Wszelkie prawa zastrzeżone