Antimicrobial responses of peripheral and central nervous system glia against Staphylococcus aureus.

Staphylococcus aureus infections of the central nervous system are serious and can be fatal. S. aureus is commonly present in the nasal cavity, and after injury to the nasal epithelium it can rapidly invade the brain via the olfactory nerve. The trigeminal nerve constitutes another potential route of brain infection. The glia of these nerves, olfactory ensheathing cells (OECs) and trigeminal nerve Schwann cells (TgSCs), as well as astrocytes populating the glia limitans layer, can phagocytose bacteria. Whilst some glial responses to S. aureus have been studied, the specific responses of different glial types are unknown. Here, we compared how primary mouse OECs, TgSCs, astrocytes and microglia responded to S. aureus. All glial types internalized the bacteria within phagolysosomes, and S. aureus-conjugated BioParticles could be tracked with subtle but significant differences in time-course of phagocytosis between glial types. Live bacteria could be isolated from all glia after 24 h in culture, and microglia, OECs and TgSCs exhibited better protection against intracellular S. aureus survival than astrocytes. All glial types responded to the bacteria by cytokine secretion. Overall, OECs secreted the lowest level of cytokines, suggesting that these cells, despite showing strong capacity for phagocytosis, have immunomodulatory functions that can be relevant for neural repair.

A Budding Relationship: Bacterial Extracellular Vesicles in the Microbiota-Gut-Brain Axis.

The discovery of the microbiota-gut-brain axis has revolutionized our understanding of systemic influences on brain function and may lead to novel therapeutic approaches to neurodevelopmental and mood disorders. A parallel revolution has occurred in the field of intercellular communication, with the realization that endosomes, and other extracellular vesicles, rival the endocrine system as regulators of distant tissues. These two paradigms shifting developments come together in recent observations that bacterial membrane vesicles contribute to inter-kingdom signaling and may be an integral component of gut microbe communication with the brain. In this short review we address the current understanding of the biogenesis of bacterial membrane vesicles and the roles they play in the survival of microbes and in intra and inter-kingdom communication. We identify recent observations indicating that bacterial membrane vesicles, particularly those derived from probiotic organisms, regulate brain function. We discuss mechanisms by which bacterial membrane vesicles may influence the brain including interaction with the peripheral nervous system, and modulation of immune activity. We also review evidence suggesting that, unlike the parent organism, gut bacteria derived membrane vesicles are able to deliver cargo, including neurotransmitters, directly to the central nervous system and may thus constitute key components of the microbiota-gut-brain axis.

Cell Biology of Intracellular Adaptation of Mycobacterium leprae in the Peripheral Nervous System.

The mammalian nervous system is invaded by a number of intracellular bacterial pathogens which can establish and progress infection in susceptible individuals. Subsequent clinical manifestation is apparent with the impairment of the functional units of the nervous system, i.e., the neurons and the supporting glial cells that produce myelin sheaths around axons and provide trophic support to axons and neurons. Most of these neurotrophic bacteria display unique features, have coevolved with the functional sophistication of the nervous system cells, and have adapted remarkably to manipulate neural cell functions for their own advantage. Understanding how these bacterial pathogens establish intracellular adaptation by hijacking endogenous pathways in the nervous system, initiating myelin damage and axonal degeneration, and interfering with myelin maintenance provides new knowledge not only for developing strategies to combat neurodegenerative conditions induced by these pathogens but also for gaining novel insights into cellular and molecular pathways that regulate nervous system functions. Since the pathways hijacked by bacterial pathogens may also be associated with other neurodegenerative diseases, it is anticipated that detailing the mechanisms of bacterial manipulation of neural systems may shed light on common mechanisms, particularly of early disease events. This chapter details a classic example of neurodegeneration, that caused by Mycobacterium leprae, which primarily infects glial cells of the peripheral nervous system (Schwann cells), and how it targets and adapts intracellularly by reprogramming Schwann cells to stem cells/progenitor cells. We also discuss implications of this host cell reprogramming by leprosy bacilli as a model in a wider context.

Infection Rates of Electrical Leads Used for Percutaneous Neurostimulation of the Peripheral Nervous System.

BACKGROUND: Percutaneous neurostimulation of the peripheral nervous system involves the insertion of a wire "lead" through an introducing needle to target a nerve/plexus or a motor point within a muscle. Electrical current may then be passed from an external generator through the skin via the lead for various therapeutic goals, including providing analgesia. With extended use of percutaneous leads sometimes greater than a month, infection is a concern. It was hypothesized that the infection rate of leads with a coiled design is lower than for leads with a noncoiled cylindrical design. METHODS: The literature was retrospectively reviewed for clinical studies of percutaneous neurostimulation of the peripheral nervous system of greater than 2 days that included explicit information on adverse events. The primary endpoint was the number of infections per 1,000 indwelling days. RESULTS: Forty-three studies were identified that met inclusion criteria involving coiled (n = 21) and noncoiled (n = 25) leads (3 studies involved both). The risk of infection with noncoiled leads was estimated to be 25 times greater than with coiled leads (95% confidence interval [CI] 2 to 407, P = 0.006). The infection rates were estimated to be 0.03 (95% CI 0.01 to 0.13) infections per 1,000 indwelling days for coiled leads and 0.83 (95% CI 0.16 to 4.33) infections per 1,000 indwelling days for noncoiled leads (P = 0.006). CONCLUSIONS: Percutaneous leads used for neurostimulation of the peripheral nervous system have a much lower risk of infection with a coiled design compared with noncoiled leads: approximately 1 infection for every 30,000 vs. 1,200 indwelling days, respectively.

Mycobacterium leprae and leprosy: a compendium.

Leprosy is a chronic infectious disease caused by Mycobacterium leprae, which was discovered by G.H.A. Hansen in 1873. M. leprae is an exceptional bacterium because of its long generation time and no growth in artificial media. Entire sequencing of the bacterial genome revealed numerous pseudogenes (inactive reading frames with functional counterparts in M. tuberculosis) which might be responsible for the very limited metabolic activity of M. leprae. The clinical demonstration of the disease is determined by the quality of host immune response. Th1-type immune response helps to kill the bacteria, but hosts are encroached upon when Th2-type response is predominant. The bacteria have affinity to the peripheral nerves and are likely to cause neuropathy. M. leprae/laminin-alpha2 complexes bind to alpha/beta dystroglycan complexes expressed on the Schwann cell surface. WHO recommends a chemotherapy protocol [multidrug therapy (MDT)] which effectively controls the disease and contributes to the global elimination program. Leprosy has been stigmatized throughout history, and recent topics regarding the disease in Japan are also discussed.

A 21-kDa surface protein of Mycobacterium leprae binds peripheral nerve laminin-2 and mediates Schwann cell invasion.

Nerve damage is the hallmark of Mycobacterium leprae infection, which results from M. leprae invasion of the Schwann cell of the peripheral nervous system. We have recently shown that the laminin-2 isoform, specially the G domain of laminin alpha2 chain, on the Schwann cell-axon unit serves as an initial neural target for M. leprae. However, M. leprae surface molecules that mediate bacterial invasion of peripheral nerves are entirely unknown. By using human alpha2 laminins as a probe, a major 28-kDa protein in the M. leprae cell wall fraction that binds alpha2 laminins was identified. After N-terminal amino acid sequence analysis, PCR-based strategy was used to clone the gene that encodes this protein. Deduced amino acid sequence of this M. leprae laminin-binding protein predicts a 21-kDa molecule (ML-LBP21), which is smaller than the observed molecular size in SDS/PAGE. Immunofluorescence and immunoelectron microscopy on intact M. leprae with mAbs against recombinant (r) ML-LBP21 revealed that the protein is surface exposed. rML-LBP21 avidly bound to alpha2 laminins, the rG domain of the laminin-alpha2 chain, and the native peripheral nerve laminin-2. The role of ML-LBP21 in Schwann cell adhesion and invasion was investigated by using fluorescent polystyrene beads coated with rML-LBP21. Although beads coated with rML-LBP21 alone specifically adhered to and were ingested by primary Schwann cells, these functions were significantly enhanced when beads were preincubated with exogenous alpha2 laminins. Taken together, the present data suggest that ML-LBP21 may function as a critical surface adhesin that facilitates the entry of M. leprae into Schwann cells.

Pathogenesis of Lyme neuroborreliosis in the rhesus monkey: the early disseminated and chronic phases of disease in the peripheral nervous system.

The histopathologic and immunohistochemical features of early and late neuroborreliosis of the peripheral nervous system were investigated in rhesus macaques infected with the JD1 strain of Borrelia burgdorferi. Infection was proven by culture or polymerase chain reaction analysis of skin biopsies and indirectly by Western blot analysis. Three months after infection, neuritis involving multiple nerves was the most consistent neurologic manifestation. Both macrophages and B lymphocytes but not T lymphocytes were present in the cellular infiltrates. Axonal structures surrounding infiltrates had changes consisting of demyelination and axonal phagocytosis. Some of the Schwann cells in lesions stained with anti-nitrotyrosine and anti-tumor necrosis factor-alpha antibodies. B. burgdorferi, or antigens thereof, were visualized immunohistochemically within macrophages. Forty-six months after infection, the most common changes were regenerative, whereas neuritis was infrequent. Aberrant axonal regeneration, irregularly sized myelinated fibers, and fibrosis were frequently observed. Possible mechanisms to explain the appearance and subsidence of Lyme neuritis are discussed.

Evidence that the herpes simplex virus type 1 uracil DNA glycosylase is required for efficient viral replication and latency in the murine nervous system.

Herpes simplex virus (HSV) encodes a uracil DNA glycosylase (UNG; UL2), which has been shown to be dispensable for normal replication of HSV-1 in cultured cells (J. Mullaney, H.W. Moss, and D.J. McGeoch, J. Gen. Virol. 70:449-454, 1989). In adult neurons, UNG activity is undetectable (F. Focher, P. Mazzarello, A. Verri, U. Hubscher, and S. Spadari, Mutat. Res. 237:65-73, 1990), suggesting that the HSV-1 UNG may play an important role in viral replication in neurons acutely and/or following reactivation. To examine the contribution of the HSV-1 UNG in vivo, two independent strain 17 Syn+ Ung- mutants, designated uB1 and uB2, were examined in a mouse model of herpetic disease. Following direct intracranial inoculation, both mutants exhibited a 10-fold reduction in neurovirulence compared with the parental strain 17 Syn+. Inoculations by a peripheral route demonstrated that the Ung- mutants were at least 100,000-fold less neuroinvasive than 17 Syn+. Replication kinetics in vivo demonstrated that uB1 and uB2 replicated less well in both the mouse peripheral and central nervous systems. Latency was established by both of the mutants in 100% of the animals examined. Following transient hyperthermia, however, the frequency of reactivation of the mutants in vivo was dramatically reduced. Restoration of the UNG locus resulted in full neurovirulence, neuroinvasiveness, and the ability to reactivate in vivo. These findings suggest that the HSV-1 UNG plays an important role during acute viral replication in vivo and possibly in the reactivation process.

Temporal central and peripheral nervous system changes induced by a paralytogenic mutant of Moloney murine leukemia virus TB.

BACKGROUND: The temporal localization of cellular targets for viral replication and the morphopathogenesis of neurodegeneration in the central nervous system (CNS) and peripheral nervous system induced by ts1, a neuropathogenic and lymphocytopathic mutant of Moloney murine leukemia virus-TB, were studied in the highly susceptible FVB/N mouse strain in order to better understand the mechanisms of this neurodegenerative disease. EXPERIMENTAL DESIGN: Newborn FVB/N mice were inoculated intraperitoneally with 0.1 ml of viral suspension containing 10(6) to 10(7) infectious units/ml. The mice were observed daily for clinical signs of disease and killed at specific time points. Their nervous system tissues were collected and processed for light and electron microscopy and for immunohistochemical viral-antigen detection. RESULTS: ts1-Infected FVB/N mice developed a rapidly progressive wasting disease that culminated in hindleg paralysis or paraplegia 30 to 35 days postinoculation (pi). CONCLUSIONS: Clear evidence of CNS lesions involving the cerebellar ventricular system, the grey and white matter of the brain stem and the spinal cord were seen as early as 5 to 10 days pi. These lesions, which began as mild perivascular and paraventricular neuropil spongiform changes and cytoplasmic vacuolation of neuronal and glial cell processes, progressed in severity with time and culminated in almost complete destruction of the white and gray matter in the brain stem and the cervical and lumbar spinal cord. Viruses were detected as early as 5 to 10 days pi in the fourth ventricle choroid plexus and ventricular lumen and budding from endothelial cells within the brain stem and cerebellum. Endothelial, ependymal, microglial, astroglial, and oligodendroglial cells were positive for gp70env. Astroglial and microglial cell proliferation with microglial syncytia formation was detected only within the areas showing spongiform degeneration. Viral replication was consistently high in the capillary endothelial cells of those areas showing spongiform degeneration, whereas in the glial cells, relatively few budding viruses were present. Neurodegeneration was accompanied by demyelinization within the CNS and peripheral nervous system and by hindleg muscle degeneration and necrosis. Multiple cellular targets for ts1 viral infection and replication were detected within the nervous system. The presence of budding virus and the immunodetection of viral antigen in the choroid plexus and ependymal cells of the fourth ventricle and the central canal of the spinal cord demonstrated that cerebrospinal fluid as well as blood can disseminate virus within the CNS. Pathologic and functional changes within the blood-brain barrier and glial system probably account for the neuronal necrosis and spongiform changes that result in paralysis induced by ts1 infection.