Enrichment of Glutamate‐like Immunoreactivity in Primary Afferent Terminals Throughout the Spinal Cord Dorsal Horn

Broman, Jonas; Anderson, Sonya; Ottersen, Ole Petter

doi:10.1111/j.1460-9568.1993.tb00958.x

Cited by 106 publications

(81 citation statements)

References 55 publications

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“…There is now abundant evidence that VGLUT1 is present in large diameter low threshold skin and muscle primary afferent terminals in the spinal cord, corroborating extensive electrophysiological/pharmacological and glutamate immunogold labeling data supporting a transmitter role of glutamate in such terminals (e.g. Salt and Hill, 1983;Jahr and Yoshioka, 1986;Schouenborg and Sjölund, 1986;Gerber and Randic, 1989;Walmsley and Nicol, 1991;Maxwell et al, 1990a;Broman et al, 1993;Maxwell et al, 1993;Broman and Ådahl, 1994;Valtschanoff et al, 1994;Örnung et al, 1995;Larsson et al, 2001;Ragnarson et al, 2003). Dorsal rhizotomy results in significant depletion of large VGLUT1 immunolabeled varicosities in the ventral horn and deep dorsal horn (Li et al, 2003;Oliveira et al, 2003;Alvarez et al, 2004;Wu et al, 2004), and essentially all primary afferent terminals in these VGLUT1 and VGLUT2 co-localize in a proportion of varicosities in laminae III-IV and lamina IX, further support the notion that some primary afferent terminals in both the deep dorsal horn and the ventral horn express VGLUT2 in addition to VGLUT1.…”

Section: Origin Of Immunolabeled Terminalsmentioning

confidence: 74%

“…This presumably explains why their disappearance is usually undetected following dorsal rhizotomy. Primary afferent terminals in lamina II contain high levels of glutamate (DeBiasi and Rustioni, 1988;Maxwell et al, 1990b;Broman et al, 1993;Broman and Ådahl, 1994;Valtschanoff et al, 1994;Larsson et al, 2001) and there is abundant physiological/pharmacological evidence that support glutamate as a fast primary afferent neurotransmitter in such terminals (e.g. Weinberg, 1989, Aanonsen et al, 1990;Broman et al, 2000).…”

Section: Origin Of Immunolabeled Terminalsmentioning

confidence: 99%

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Distribution of vesicular glutamate transporters 1 and 2 in the rat spinal cord, with a note on the spinocervical tract

et al. 2006

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Section: Origin Of Immunolabeled Terminalsmentioning

confidence: 74%

Section: Origin Of Immunolabeled Terminalsmentioning

confidence: 99%

Distribution of vesicular glutamate transporters 1 and 2 in the rat spinal cord, with a note on the spinocervical tract

et al. 2006

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“…286, Amiry-Moghaddam et al, 1994;no. 607, Ericson et al, 1995 andBroman et al, 1993;no. 34, Laake et al, 1986).…”

Section: Methodsunclassified

Synaptic Vesicular Localization and Exocytosis ofl-Aspartate in Excitatory Nerve Terminals: A Quantitative Immunogold Analysis in Rat Hippocampus

et al. 1998

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To elucidate the role of aspartate as a signal molecule in the brain, its localization and those of related amino acids were examined by light and electron microscopic quantitative immunocytochemistry using antibodies specifically recognizing the aldehyde-fixed amino acids. Rat hippocampal slices were incubated at physiological and depolarizing [K ϩ ] before glutaraldehyde fixation. At normal [K ϩ ], aspartate-like and glutamatelike immunoreactivities were colocalized in nerve terminals forming asymmetrical synapses on spines in stratum radiatum of CA1 and the inner molecular layer of fascia dentata (i.e., excitatory afferents from CA3 and hilus, respectively). During K ϩ depolarization there was a loss of aspartate and glutamate from these terminals. Simultaneously the immunoreactivities strongly increased in glial cells. These changes were Ca 2ϩ -dependent and tetanus toxin-sensitive and did not comprise taurine-like immunoreactivity. Adding glutamine at CSF concentration prevented the loss of aspartate and glutamate and revealed an enhancement of aspartate in the terminals at moderate depolarization.In hippocampi from animals perfused with glutaraldehyde during insulin-induced hypoglycemia (to combine a strong aspartate signal with good ultrastructure) aspartate was colocalized with glutamate in excitatory terminals in stratum radiatum of CA1. The synaptic vesicle-to-cytoplasmic matrix ratios of immunogold particle density were similar for aspartate and glutamate, significantly higher than those observed for glutamine or taurine. Similar results were obtained in normoglycemic animals, although the nerve terminal contents of aspartate were lower. The results indicate that aspartate can be concentrated in synaptic vesicles and subject to sustained exocytotic release from the same nerve endings that contain and release glutamate.

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“…The sections, collected on nickel mesh grids and dried overnight at 50°C were immersed sequentially in the following solutions: (1) 1% periodic acid (HIO,) in doubledistilled water (ddW) for 7 min; (2) 8% sodium m-periodate (NaIO,) in ddW for 15 min; (3) 1% human serum albumin (HSA) in ddW for 10 min; (4) 1% HSA in Tris phosphate-buffered saline (TPBS, 0.4 gm KCl, 0.2 gm NaN,, 7.0 gm NaCl per liter of 0.01 M PB + 0.01 M Tris/ HCl) for 10 min; (5) glutamate antiserum (#607; diluted 1: lOO-1:900 in TPBS containing 2% HSA and preadsorbed with 100 pM aspartateglutaraldehyde complex, 200 FM glutamine-glutaraldehyde complex, and 200 PM P-alanine-glutaraldehyde complex) for 2 hr Broman et al, 1993); (6) 1% HSA in TPBS for 10 min; (7) 0.05 M Tris and 0.5 mg/liter polyethyleneglycol in ddW ("Tris buffer") for 3 min; and (8) colloidal gold (20 nm) coupled to anti-rabbit IgG (diluted 1:20 in Tris buffer) for 2 hr. All steps were followed with thorough rinses in either ddW or TPBS.…”

Section: Localization Of Glutamate Using Postembedding Techniquesmentioning

confidence: 99%

3-Hydroxyanthranilic acid oxygenase-containing astrocytic processes surround glutamate-containing axon terminals in the rat striatum

Roberts

McCarthy

et al. 1995

J. Neurosci.

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Glutamate, the major transmitter of the corticostriatal pathway, is present in abundance in the striatum. 3-Hydroxyanthranilic acid oxygenase (3HAO) is the biosynthetic enzyme for quinolinic acid, an endogenous agonist of the NMDA glutamate receptor subtype and a potent neurotoxin. In order to explore the anatomical basis of possible functional interactions between glutamate and quinolinic acid in the rat striatum, pre- and postembedding immunocytochemical methods were used to localize 3HAO immunoreactivity (-i) and glutamate-i at the electron microscopic level. In accordance with previous light microscopic and biochemical studies, 3HAO-i was detected exclusively in astrocytes throughout the striatum. Notably, 3HAO-i was present in fine- caliber glial processes that often surrounded or abutted synaptic profiles, both asymmetric and symmetric. Glutamate-i was heavily deposited (3–13-fold higher gold particle density than tissue average) in axon terminals forming asymmetric synapses with spines and, occasionally, dendrites. In contrast, terminals forming symmetric synapses, dendrites, neuronal somata, and glial cells contained significantly less labeling than terminals forming asymmetric synapses. In double-labeled material, 3HAO-i was observed in glial processes that partially surrounded or were adjacent to glutamate-labeled terminals forming asymmetric synapses. 3HAO-labeled glial processes were also adjacent to unlabeled terminals forming symmetric synapses. Since quinolinic acid is known to enter the extracellular compartment readily, these results suggest that astrocytic quinolinic acid may participate in the regulation of glutamatergic neurotransmission in the rat striatum.

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Enrichment of Glutamate‐like Immunoreactivity in Primary Afferent Terminals Throughout the Spinal Cord Dorsal Horn

Cited by 106 publications

References 55 publications

Distribution of vesicular glutamate transporters 1 and 2 in the rat spinal cord, with a note on the spinocervical tract

Distribution of vesicular glutamate transporters 1 and 2 in the rat spinal cord, with a note on the spinocervical tract

Synaptic Vesicular Localization and Exocytosis ofl-Aspartate in Excitatory Nerve Terminals: A Quantitative Immunogold Analysis in Rat Hippocampus

3-Hydroxyanthranilic acid oxygenase-containing astrocytic processes surround glutamate-containing axon terminals in the rat striatum

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