Nissl body

Last updated August 23, 2023

Drawing of a motor neuron from the ventral horn of the medulla spinals of a rabbit. The angular and spindle-shaped Nissl bodies in the cytoplasm are well shown. Gray626.png — Drawing of a motor neuron from the ventral horn of the medulla spinals of a rabbit. The angular and spindle-shaped Nissl bodies in the cytoplasm are well shown.

In cellular neuroscience, Nissl bodies (also called Nissl granules, Nissl substance or tigroid substance) are discrete granular structures in neurons that consist of rough endoplasmic reticulum, a collection of parallel, membrane-bound cisternae studded with ribosomes on the cytosolic surface of the membranes.^[1] Nissl bodies were named after Franz Nissl, a German neuropathologist who invented the staining method bearing his name (Nissl staining).^[2]^[3] The term "Nissl bodies" generally refers to discrete clumps of rough endoplasmic reticulum and free ribosomes in nerve cells. Masses of rough endoplasmic reticulum also occur in some non-neuronal cells, where they are referred to as ergastoplasm, basophilic bodies,^[1] or chromophilic substance.^[4] While these organelles differ in some ways from Nissl bodies in neurons,^[5] large amounts of rough endoplasmic reticulum are generally linked to the copious production of proteins.^[1]

Staining

"Nissl stains" refers to various basic dyes that selectively label negatively charged molecules such as DNA and RNA. Because ribosomes are rich in ribosomal RNA, they are strongly basophilic ("base-loving"). The dense accumulation of membrane-bound and free ribosomes in Nissl bodies results in their intense coloration by Nissl stains, allowing them to be seen with a light microscope.^[1]

Size and distribution

Nissl bodies occur in the somata and dendrites of neurons, though not in the axon or axon hillock.^[6] They vary in size, shape, and intracellular location; they are most conspicuous in the motor neurons of the spinal cord and brainstem, where they appear as large, blocky assemblies.^[5] In other neurons, they may be smaller, and in some (such as the granule neurons of the cerebellar cortex) very little rough endoplasmic reticulum is present.^[5] The pattern of coloration with Nissl stains once was used to classify neurons.^[5] For various reasons, this practice has largely ceased, but specific neuronal types do manifest characteristic types of Nissl bodies.^[5]

Functional role

The functions of Nissl bodies are thought to be the same as those of the rough endoplasmic reticulum in general, primarily the synthesis and segregation of proteins.^[1]^[2] Similar to the ergastoplasm of glandular cells, Nissl bodies are the main site of protein synthesis in the neuronal cytoplasm.^[5] The ultrastructure of Nissl bodies suggests they are primarily concerned with the synthesis of proteins for intracellular use.^[7]

Pathology

Nissl bodies show changes under various physiological conditions and in pathological conditions such as axonotmesis, during which they may dissolve and largely disappear (chromatolysis). If the neuron is successful in repairing the damage, the Nissl bodies gradually reappear and return to their characteristic distribution within the cell.^[5]

Related Research Articles

The endoplasmic reticulum (ER) is, in essence, the transportation system of the eukaryotic cell, and has many other important functions such as protein folding. It is a type of organelle made up of two subunits – rough endoplasmic reticulum (RER), and smooth endoplasmic reticulum (SER). The endoplasmic reticulum is found in most eukaryotic cells and forms an interconnected network of flattened, membrane-enclosed sacs known as cisternae, and tubular structures in the SER. The membranes of the ER are continuous with the outer nuclear membrane. The endoplasmic reticulum is not found in red blood cells, or spermatozoa.

The endomembrane system is composed of the different membranes (endomembranes) that are suspended in the cytoplasm within a eukaryotic cell. These membranes divide the cell into functional and structural compartments, or organelles. In eukaryotes the organelles of the endomembrane system include: the nuclear membrane, the endoplasmic reticulum, the Golgi apparatus, lysosomes, vesicles, endosomes, and plasma (cell) membrane among others. The system is defined more accurately as the set of membranes that forms a single functional and developmental unit, either being connected directly, or exchanging material through vesicle transport. Importantly, the endomembrane system does not include the membranes of plastids or mitochondria, but might have evolved partially from the actions of the latter.

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Franz Alexander Nissl was a German psychiatrist and medical researcher. He was a noted neuropathologist.

Endoplasm generally refers to the inner, dense part of a cell's cytoplasm. This is opposed to the ectoplasm which is the outer (non-granulated) layer of the cytoplasm, which is typically watery and immediately adjacent to the plasma membrane. The nucleus is separated from the endoplasm by the nuclear envelope. The different makeups/viscosities of the endoplasm and ectoplasm contribute to the amoeba's locomotion through the formation of a pseudopod. However, other types of cells have cytoplasm divided into endo- and ectoplasm. The endoplasm, along with its granules, contains water, nucleic acids, amino acids, carbohydrates, inorganic ions, lipids, enzymes, and other molecular compounds. It is the site of most cellular processes as it houses the organelles that make up the endomembrane system, as well as those that stand alone. The endoplasm is necessary for most metabolic activities, including cell division.

Cytoarchitecture, also known as cytoarchitectonics, is the study of the cellular composition of the central nervous system's tissues under the microscope. Cytoarchitectonics is one of the ways to parse the brain, by obtaining sections of the brain using a microtome and staining them with chemical agents which reveal where different neurons are located.

<span class="mw-page-title-main">Cellular compartment</span> Closed part in cytosol

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In cellular neuroscience, chromatolysis is the dissolution of the Nissl bodies in the cell body of a neuron. It is an induced response of the cell usually triggered by axotomy, ischemia, toxicity to the cell, cell exhaustion, virus infections, and hibernation in lower vertebrates. Neuronal recovery through regeneration can occur after chromatolysis, but most often it is a precursor of apoptosis. The event of chromatolysis is also characterized by a prominent migration of the nucleus towards the periphery of the cell and an increase in the size of the nucleolus, nucleus, and cell body. The term "chromatolysis" was initially used in the 1940s to describe the observed form of cell death characterized by the gradual disintegration of nuclear components; a process which is now called apoptosis. Chromatolysis is still used as a term to distinguish the particular apoptotic process in the neuronal cells, where Nissl substance disintegrates.

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<span class="mw-page-title-main">Jean Vance</span> British-Canadian biochemist

Jean Vance is a British-Canadian biochemist. She is known for her pioneering work on subcellular organelles and for her discovery of a connection between the endoplasmic reticulum and the mitochondrial membrane. She is a Professor of Medicine at the University of Alberta, Canada and a Fellow of the Royal Society of Canada.

Ribosome-associated Vesicles, as known as RAVs, are a novel subcompartment of the rough endoplasmic reticulum, a membranous cellular network that is important for the synthesis and transport of proteins. RAVs have been observed via multiple imaging techniques and appear as discrete spherical vesicles that are associated with actively translated ribosomes. It is hypothesized that RAVs may arise from structural and/or functional changes in local membrane curvature along the rough endoplasmic reticulum tubular membrane network.

References

1 2 3 4 5 Junqueira LC, Carniero J, Kelley RO (1995). Basic Histology. Appleton & Lange. ISBN 0-8385-0567-8.
1 2 Richard H. Thompson (29 March 2000). The Brain: A Neuroscience Primer. Macmillan. pp. 35–. ISBN 978-0-7167-3226-6 . Retrieved 4 January 2013.
↑ Da Mota Gomes M (2019). "Franz Nissl (1860-1919), noted neuropsychiatrist and neuropathologist, staining the neuron, but not limiting it". Dementia & Neuropsychologia. 13 (3): 352–355. doi:10.1590/1980-57642018dn13-030014. PMC 6753910 .
↑ Fawcett, Don W. (1966). The Cell: Its Organelles and Inclusions. W.B. Saunders Company. ISBN 0-7216-3585-7.
1 2 3 4 5 6 7 Peters A, Palay SL, Webster Hd (1991). The Fine Structure of the Nervous System. Oxford University Press. ISBN 0-19-506571-9.
↑ Wolfgang Kühnel (2003). Color Atlas of Cytology, Histology, and Microscopic Anatomy. Thieme. pp. 182–. ISBN 978-3-13-562404-4 . Retrieved 4 January 2013.
↑ T. Herdegen; J. Delgado-Garcia (25 May 2005). Brain Damage and Repair: From Molecular Research to Clinical Therapy. Springer. pp. 37–. ISBN 978-1-4020-1892-3 . Retrieved 4 January 2013.

External links

Media related to Nissl stain at Wikimedia Commons
Nissl+Bodies at the U.S. National Library of Medicine Medical Subject Headings (MeSH)
Histology image: 04103loa – Histology Learning System at Boston University - "Nervous Tissue and Neuromuscular Junction: spinal cord, cell bodies of anterior horn cells"
Histology at anhb.uwa.edu.au
Tissues containing Nissl bodies at harvard.edu

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[Junqueira-1] 1 2 3 4 5 Junqueira LC, Carniero J, Kelley RO (1995). Basic Histology. Appleton & Lange. ISBN 0-8385-0567-8.

[Thompson2000-2] 1 2 Richard H. Thompson (29 March 2000). The Brain: A Neuroscience Primer. Macmillan. pp. 35–. ISBN 978-0-7167-3226-6 . Retrieved 4 January 2013.

[Da_Mota_Gomes-3] Da Mota Gomes M (2019). "Franz Nissl (1860-1919), noted neuropsychiatrist and neuropathologist, staining the neuron, but not limiting it". Dementia & Neuropsychologia. 13 (3): 352–355. doi:10.1590/1980-57642018dn13-030014. PMC 6753910 .

[Fawcett-4] Fawcett, Don W. (1966). The Cell: Its Organelles and Inclusions. W.B. Saunders Company. ISBN 0-7216-3585-7.

[PetersPalayWebster-5] 1 2 3 4 5 6 7 Peters A, Palay SL, Webster Hd (1991). The Fine Structure of the Nervous System. Oxford University Press. ISBN 0-19-506571-9.

[Kühnel2003-6] Wolfgang Kühnel (2003). Color Atlas of Cytology, Histology, and Microscopic Anatomy. Thieme. pp. 182–. ISBN 978-3-13-562404-4 . Retrieved 4 January 2013.

[HerdegenDelgado-Garcia2005-7] T. Herdegen; J. Delgado-Garcia (25 May 2005). Brain Damage and Repair: From Molecular Research to Clinical Therapy. Springer. pp. 37–. ISBN 978-1-4020-1892-3 . Retrieved 4 January 2013.

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