Selective expression of Narp in primary nociceptive neurons: role in microglia/macrophage activation following nerve injury.

Neuronal activity regulated pentraxin (Narp) is a secreted protein implicated in regulating synaptic plasticity via its association with the extracellular surface of AMPA receptors. We found robust Narp immunostaining in dorsal root ganglia (DRG) that is largely restricted to small diameter neurons, and in the superficial layers of the dorsal horn of the spinal cord. In double staining studies of DRG, we found that Narp is expressed in both IB4- and CGRP-positive neurons, markers of distinct populations of nociceptive neurons. Although a panel of standard pain behavioral assays were unaffected by Narp deletion, we found that Narp knockout mice displayed an exaggerated microglia/macrophage response in the dorsal horn of the spinal cord to sciatic nerve transection 3days after surgery compared with wild type mice. As other members of the pentraxin family have been implicated in regulating innate immunity, these findings suggest that Narp, and perhaps other neuronal pentraxins, also regulate inflammation in the nervous system.

Decreased peripheral nerve damage after ischemia-reperfusion injury in mice lacking TNF-alpha.

We sought to explore the role of tumor necrosis factor-alpha (TNF-alpha) in the pathogenesis of peripheral nerve ischemia-reperfusion (IR) injury. We established an ischemia-reperfusion model in wild type (WT) and TNF-alpha knockout (KO) mice. Electrophysiology, behavioral score and morphological indices (edema and ischemic fiber degeneration [IFD]) were examined to determine the influence of TNF-alpha on peripheral nerve structure and function following ischemia followed by reperfusion. TNF-alpha and nuclear factor-kappa B (NF-kappaB) expression were evaluated using immunohistochemistry. TNF-alpha KO mice, compared to WT had, in sciatic nerve, marked improvement in nerve pathology. This is a region subject to moderate ischemia-reperfusion injury. There was also a significant improvement in electrophysiological and some behavioral indices. TNF-alpha and NF-kappaB expression were abundant in sciatic-tibial nerves of WT mice subjected to IR, but there was less, or complete lack of, expression in ischemic nerve of TNF-alpha KO mice. We conclude that TNF-alpha plays an essential role in the pathogenesis of peripheral nerve ischemia-reperfusion injury, possibly partly through the activation of NF-kappaB.

Orchestration of the inflammatory response in ischemia-reperfusion injury.

Ischemia to nerve can cause fiber degeneration and reperfusion following ischemia [ischemia-reperfusion (IR)] adds the additional insult of an inflammatory response and oxidative injury. Limited information is available on the molecular mediators and their endoneurial targets. In this study, using a highly reproducible animal model of IR injury to nerve and selective immunolabeling methods [for nuclear factor kappa B (NF-kappaB), intercellular adhesion molecule-1 (ICAM-1), cytokines, and inflammatory cells] over an expanded time frame, we evaluated the temporal pattern and localization of mediators of the inflammatory response. Sixty rats were used. Nine groups (N=6 each) underwent complete hind limb ischemia for 4 h, followed by reperfusion durations of 0, 3, 12, 24, and 48 h, and 7, 14, 28, and 42 days. One group underwent sham operation (N=6). The earliest change was ICAM-1 expression in the microvessel (endothelial cell) followed almost immediately by NF-kappaB activation with axonal expression (24 and 48 h), followed by endoneurial edema and ischemic fiber degeneration (7 and 14 days). Granulocytic infiltration was followed by endoneurial infiltration of mononuclear phagocytes (14 days), expression of interleukin 6 (IL-6) (microvessels), and subsequent Schwann cell NF-kappaB expression. Granulocytes, tumor necrosis factor alpha, and IL-6-positive cells were observed primarily within the epineurium. IR results in changes in a number of interacting networks of targets and inflammatory mediators. NF-kappaB activation has a central orchestrating role involving both the axon and the Schwann cell in effecting the inflammatory response.

Pretreatment with portal venous ultraviolet B-irradiated donor alloantigen promotes donor-specific tolerance to rat nerve allografts.

OBJECTIVE: To determine if a single intraportal inoculation of ultraviolet B-irradiated (UVB) donor splenocytes can prevent nerve allograft rejection and confer donor-specific immunotolerance to rat nerve allograft segments. METHODS: Age-matched, class I and class II major histocompatibility complex (MHC) mismatched Buffalo (RT1b) rats were transplanted with a syngeneic nerve isograft, a Lewis (RT1l) nerve allograft, or a Brown-Norway (RT1n) rat nerve allograft segment. Control Buffalo rats in group I received a 3.0-cm Lewis (RT11) sciatic-posterior tibial interposition nerve allograft without pretreatment; group II Buffalo rats received a syngeneic Buffalo nerve isograft without pretreatment. Group III Buffalo recipients were inoculated with 2.5 x 107 UVB-irradiated Lewis donor splenocyte cells by portal venous administration 7 days before transplantation with a 3.0-cm sciatic-posterior tibial nerve allograft from a Lewis (RT11) or a third party Brown-Norway rat (RT1n) donor (group IV). Nerve graft regeneration was assessed with walking track analysis, nerve conduction studies, retrograde neural tracing, nerve graft histology, and morphometry. Recipient immune tolerance was assessed through in vitro immunological assessment. RESULTS: Pretreatment with UVB-irradiated donor splenocytes 7 days before transplantation prevented nerve allograft rejection. Pretreated animals receiving a nerve allograft recovered limb function, and demonstrated morphological, histological, and electrophysiologic parameters of nerve regeneration similar to that measured in rats receiving a nerve isograft. In vitro immunological assessment by mixed lymphocyte culture (MLC), cytotoxic T lymphocyte (CTL) assay, limiting dilution analysis (LDA) of helper (pTH) and cytotoxic (pCTL) precursor frequencies, and IL-2 production demonstrated a marked donor-specific suppression in allografted animals pretreated with intraportal UVB-irradiated donor splenocytes. These assessments correlated with indefinite acceptance of donor nerve allografts. CONCLUSIONS: A single pretreatment with a single intraportal dose of UVB-modified donor antigen specifically induces tolerance to peripheral nerve allografts in rats.

Non-neural-specific T lymphocytes can orchestrate inflammatory peripheral neuropathy.

Neural-specific T lymphocytes are held to play a pathological role in inflammatory peripheral nerve disorders such as the Guillain-Barré syndrome (GBS) and chronic inflammatory demyelinating polyneuropathy (CIDP). Here, non-neural-specific T-cell-mediated inflammation was studied in peripheral nerves in Lewis rats by systemic transfer of ovalbumin-specific activated T cells followed by intraneural injection of ovalbumin. Rapid endoneurial perivenular infiltration of alpha beta T cells and ED1+ macrophages occurred with ovalbumin injection following transfer of 2 x 10(6) T cells. This cellular infiltration and accumulation produced marked increases in blood-nerve barrier (BNB) permeability. In contrast, control casein injections produced neither significant cell accumulation nor BNB permeability changes. Transfer of a higher number of T cells (5 x 10(6)) induced severe Wallerian degeneration and nerve conduction failure in ovalbumin injected nerves. Fewer T cells (5 x 10(5)) induced conduction block and mild demyelination which were markedly augmented by systemic cotransfer of anti-myelin immunoglobulin. This study demonstrates that activated T cells of non-neural specificity can accumulate in peripheral nerve, produce dramatic changes in BNB permeability and with intravenous anti-myelin antibody orchestrate primary demyelination or axonal degeneration in a dose-dependent fashion.

[Myelopathy associated with HTLV-1: clinical electrophysiologic study]. / Mielopatía asociada al HTLV-1: estudio clinicoelectrofisiológico.

Clinical and electrophysiological studies have been performed in 9 cases of HTLV-I associated myelopathy (7 female, 2 male). Spastic paraparesis and neurogenic bladder were present in 8; sensory disturbances were detected only in 4. The conduction velocities of the posterior tibial and sural nerves were reduced in 2 cases. Median nerve SSEP revealed a delay of N11, N13, N14, N20 peak latencies and an increase of N9-N20, N13-N14 and N13-N20 interpeak latencies. The electrophysiological studies are the most accurate indicators of the diffuse involvement not only of central motor and sensory pathways but also of the peripheral nervous system.

Role of macrophages in onion-bulb formation in localized hypertrophic mononeuritis (LHM).

A unique pathogenetic process for onion-bulb (Ob) formation is disclosed with disclosed with immunohistochemistry and electron microscopy. Biopsy of a swollen segment of tibial nerve from a 42 year-old white female histologically demonstrated diffuse and angiocentric lymphocytic infiltrate in both endo- and perineurium with occasional lymphofollicular formation. Extensive Ob formation of nerve fibers was most striking with or without associated lymphocytes. Axis-cylinders were intact in the majority of Ob. Immunocytochemically, Ob are composed of alternately laminated leaflets of Schwann cells (S100+) and mononuclear macrophage (HAM56+/LeuMl+/Muramidase+) processes but no perineurial (EMA+) cells. Immunohistochemical evidence of antigen presentation (HLA-DR/LN3+/Ia+) was confined to macrophages. Electron microscopy insinuates that intricate interactions between macrophages and Schwann cells exists. Putative inhibition of remyelination along with proliferation of Schwann cells most probably is secondary to the effects of macrophages secretory products. No direct participation of B or T lymphocytes was detected in Ob. Thus, modified macrophages may emit a factor for concomitantly promoting proliferation of Schwann cells and an enzyme for myelin breakdown. In addition, only a few macrophages could be detected in some Ob and could be easily overlooked or misinterpreted as "vacuolated fibroblasts", if no immunohistochemical correlation is made, as modified macrophages making the external leaflets of Ob are more vacuolated.

[Velocity of nerve conduction in children and adolescents with type I diabetes mellitus: clinical, metabolic and immunologic correlations]. / La velocità di conduzione nervosa in bambini ed adolescenti diabetici di I tipo: correlazioni cliniche, metaboliche ed immunologiche.

Clinical, metabolic, neurophysiologic and immunological data were obtained in a group of 50 patients with type I diabetes mellitus Results were compared with those obtained in 30 healthy subjects of comparable age. M.N.C. (median nerve conduction) velocities and sensitive latency were observed to be significant lower in the diabetic patients rather than in the controls. These abnormalities were correlated with the duration of diabetes rather than with the glucose control. The positivity for circulating immune complexes was found to be associated with a significant reduction of median sensory nerve conduction velocity. There results suggest that in addition to metabolic, genetic, vascular and hormonal abnormalities also immunologic factors may play a role in the pathogenesis of diabetic neuropathy.

Acute conduction block associated with experimental antiserum-mediated demyelination of peripheral nerve.

Intraneural injection of antisera from rabbits with high antigalactocerebroside antibody levels into rat sciatic nerve produced acute nerve conduction block. This was first apparent in some motor axons between 30 and 60 minutes after injection and progressed to completion within 2 to 4 hours. Concurrent morphological evidence of demyelination was present, but structural changes at the time of onset of block were mild and were restricted to the myelin and Schwann cell, particularly at the paranodal areas and Schmidt-Lanterman clefts. It is suggested that paranodal lesions could account for the observed conduction block.