acid-phosphatase and Peripheral-Nerve-Injuries

This paper reviews light- and electron microscopic, histochemical and physiological evidence which demonstrate that peripheral nerve injury in mammals is followed by profound structural and functional changes in the central terminals of the affected primary sensory neurons. Available evidence indicates that at least some of these so-called transganglionic changes are the result of ganglion cell degeneration and death, although other mechanisms are probably in effect as well. Existing data suggest that this ganglion cell death does not effect all types of ganglion cells equally, but do not permit a clearcut answer to the question of which kinds of ganglion cells are affected more than others. Results from studies with microtubule inhibitors and antibodies to nerve growth factor are compatible with the notion that depletion of retrogradely transported trophic factors is involved in the production of certain transganglionic changes. This issue needs further examination, however. Physiological studies indicate marked alterations in certain primary afferent synaptic connections after peripheral nerve lesions. So far, these changes have not been satisfactorily correlated with the structural changes induced by similar lesions. Further studies on the structural and functional response of primary sensory neurons to peripheral nerve injury are likely to contribute to the understanding of the frequent failure to regain normal sensory functions after peripheral nerve lesions in man, as well as of the basic aspects of lesion-induced changes in general in the peripheral and central nervous system.

Topics: Acid Phosphatase; Afferent Pathways; Animals; Axonal Transport; Cats; Guinea Pigs; Microscopy, Electron; Nerve Growth Factors; Nerve Tissue Proteins; Nervous System; Neuronal Plasticity; Neurons, Afferent; Peripheral Nerve Injuries; Rats; Spinal Cord; Trigeminal Nerve Injuries; Trigeminal Nuclei

Topics: Acid Phosphatase; Amino Acids; Animals; Axons; Basophils; Botulinum Toxins; Cell Nucleolus; Cell Nucleus; Cholinesterases; Cytoplasm; Endoplasmic Reticulum; Golgi Apparatus; Lysosomes; Microscopy, Electron; Mitochondria; Motor Neurons; Nerve Degeneration; Nerve Regeneration; Nerve Tissue Proteins; Peripheral Nerve Injuries; Ribosomes; RNA; Sex Chromatin

Although electroacupuncture is widely used in chronic pain management, it is quite controversial due to its unclear mechanism. We hypothesised that EA alleviates pain by inhibiting degradation of the ecto-nucleotidase prostatic acid phosphatase (PAP) and facilitating ATP dephosphorylation in dorsal root ganglions (DRGs).. We applied EA in male C57 mice subjected to chronic constriction injury (CCI) and assessed extracellular ATP and 5'-nucleotidease expression in DRGs. Specifically, we used a luminescence assay, quantitative reverse transcriptase-polymerase chain reaction, Western blotting, immunohistochemistry and nociceptive-related behavioural changes to gather data, and we tested for effects after PAP expression was inhibited with an adeno-associated virus (AAV). Moreover, membrane PAP degradation was investigated in cultured DRG neurons and the inhibitory effects of EA on this degradation were assessed using immunoprecipitation.. EA treatment alleviated CCI surgery-induced mechanical pain hypersensitivity. Furthermore, extracellular ATP decreased significantly in both the DRGs and dorsal horn of EA-treated mice. PAP protein but not mRNA increased in L4-L5 DRGs, and inhibition of PAP expression via AAV microinjection reversed the analgesic effect of EA. Membrane PAP degradation occurred through a clathrin-mediated endocytosis pathway in cultured DRG neurons; EA treatment inhibited the phosphorylation of adaptor protein complex 2, which subsequently reduced the endocytosis of membrane PAP.. EA treatment alleviated peripheral nerve injury-induced mechanical pain hypersensitivity in mice by inhibiting membrane PAP degradation via reduced endocytosis and subsequently promote ATP dephosphorylation in DRGs.. In a mouse model of chronic pain, electroacupuncture treatment increased levels of prostatic acid phosphatase (PAP: an ecto-nucleotidase known to relieve pain hypersensitivity) by inhibiting PAP degradation in dorsal root ganglions. This promoted extracellular ATP dephosphorylation, inhibited glia activation and eventually alleviated peripheral nerve injury-induced mechanical pain hypersensitivity in mice. Our findings represent an important step forward in clarifying the mechanisms of pain relief afforded by acupuncture treatment.

Topics: Acid Phosphatase; Adenosine Triphosphatases; Adenosine Triphosphate; Animals; Electroacupuncture; Ganglia, Spinal; Male; Mice; Neuralgia; Peripheral Nerve Injuries; Rats; Rats, Sprague-Dawley

Prostatic acid phosphatase (PAP) is expressed in nociceptive dorsal root ganglion (DRG) neurons and functions as an ectonucleotidase that dephosphorylates extracellular adenosine monophosphate (AMP) to adenosine to suppress pain via activating A1-adenosine receptor (A1R) in dorsal spinal cord. However, the effect of peripheral nerve injury on the expression of PAP has not been reported until now. In the present study we found that PAP expression in DRG neurons is significantly decreased from the 2nd day after peripheral nerve injury and reaches the bottom at the 14th. In addition, intrathecal PAP injection can reduce mechanical allodynia induced by spared nerve injury. Our findings suggest that the decrease of PAP is involved in pathophysiological mechanisms of neuropathic pain.

Topics: Acid Phosphatase; Animals; Down-Regulation; Ganglia, Spinal; Hyperalgesia; Immunohistochemistry; In Situ Hybridization; Male; Neuralgia; Peripheral Nerve Injuries; Rats; Rats, Sprague-Dawley; Real-Time Polymerase Chain Reaction; Sensory Receptor Cells

Reversal of direction (turnaround) of axonal transport of particle-specific enzyme activities was studied at a ligature placed on rat sciatic nerve. In the principal experiment, the ligature remained on the nerve in vivo several hours, allowing enzyme activities (acetylcholinesterase, acid phosphatase, and monoamine oxidase) to accumulate immediately proximal to the tie. The nerve was then tied a second time, proximal to the first tie, and incubated in vitro for several more hours. Accumulation of enzyme activities just distal to the second tie was measured. This second accumulation, of activities traveling in the retrograde direction, was shown to be the result of turnaround in several ways. (1) The increase in activity distal to the second tie was equal to the decrease in activity proximal to the first. (2) The increase in enzyme activities distal to the second tie was greatly reduced when the accumulation proximal to the first tie was trapped by placing a third tie between the first and second ties. (3) It was shown that the activity that accumulated distal to the second tie could not have been in retrograde motion at the time of the first tie. (4) Accumulation distal to the second tie was not a function of the length of nerve segment included between the two ties. In contrast to the consistent occurrence of turnaround of orthograde flow, turnaround of retrograde flow could not be demonstrated. Turnaround transport was blocked by incubation in the cold and in the presence of NaCN or vinblastine. The turnaround process operated on all three enzymes studied, suggesting that it operates on lysosomes and mitochondria, as well as on the endoplasmic reticulum-like material bearing acetylcholinesterase. Evidence for the participation of the transport process in the renewal of AChE in the distal portions of the axon was obtained in experiments using diisopropylphosphorofluoridate and cycloheximide.

Topics: Acetylcholinesterase; Acid Phosphatase; Animals; Axonal Transport; In Vitro Techniques; Isoflurophate; Male; Monoamine Oxidase; Peripheral Nerve Injuries; Peripheral Nerves; Rats; Sciatic Nerve