Modeling neuropathogenesis of B virus infection in the macaque ganglia

LeCher, Julia

09 May 2016

B virus is an alphaherpesvirus, endemic to macaque monkeys, capable of deadly human zoonosis with an 80% mortality rate in untreated cases. The macaque monkey is widely used in biomedical research and the threat of B virus poses an occupational hazard to researchers, veterinarians, and animal handlers. B virus establishes a life-long latent infection in sensory neurons of the peripheral nervous system (PNS) in the natural host. In human infections, B virus readily transits to the central nervous system (CNS) and destroys brain tissues. Identifying immune correlates of B virus infection in the PNS of the natural host is critical in understanding viral lethality in the human host. The lack of an accurate animal model and restrictions on handling potentially infected nervous tissue previously limited studies of B virus infection in macaque ganglia. To address this barrier, a long-lived mixed neuron/glia cell culture model was established from macaque DRG explants using a novel methodology that relied on cellular migration from whole tissues. Utilizing this model, the hypothesis tested was that acute B virus infection of macaque ganglia triggers cellular defense networks to promote leukocyte recruitment and impact leukocyte activation. Chemokines were upregulated in B virus-infected cultures and infected cell media induced leukocyte chemotaxis. Leukocytes were less effectively activated by media from infected cells when compared to media from mock-infected cells. To identify factors responsible for this, focused microarrays were performed and cytokine profiles were quantified from B virus and mock-infected culture supernatants. IL-6 protein levels were significantly reduced in B virus infected cultures. This observation led to the hypothesis that IL-6 downregulation impairs leukocyte activation and, indeed, when IL-6 was added to B virus-infected culture supernatants to control levels, these cultures were far more effective at eliciting leukocyte activation when compared with mock-infected cultures. Collectively, these data support the hypothesis that acute B virus infection of macaque ganglia triggers cellular defense networks to promote leukocyte recruitment and impact leukocyte activation and identifies a potential viral mechanism to impair leukocyte functionality. Additionally, this work presents a novel methodology for establishing long-lived mixed neuron/glia cultures from postnatal/adult macaque DRGs.

Herpes B virus

Macaque monkey

Neurovirology

DRG

Neuron/glia cell culture

IL-6

Avaliação do efeito neuroprotetor de compostos obtidos da peçonha da aranha Parawixia bistriata, em cultura primária mista de células do tecido nervoso, de ratos Wistar / Evaluation of the neuroprotective effect of compounds from Parawixia bistriata spider venom, in primary mixed cells culture from cerebral tissue of newborn Wistar rats.

Primini, Eduardo Octaviano

20 December 2016

O L-glutamato (L-Glu) é o principal neurotransmissor excitatório em vertebrados e é fundamental para funções primordiais do sistema nervoso central (SNC), tais como aprendizagem e memória. Entretanto, quando este neurotransmissor está em excesso na fenda sináptica, pode provocar uma série de eventos excitotóxicos, que por sua vez, estão associados a muitas neuropatologias. A terapia da maioria dessas doenças é ineficiente e provoca sérios efeitos colaterais. Portanto, é necessário desenvolver fármacos mais efetivos e com menos efeitos colaterais. Assim, peçonhas de artrópodes como a da aranha P. bistriata, se apresentam como fontes alternativas de compostos neuroativos, pois já demonstraram efeitos neuroprotetores in vitro e in vivo, bem como anticonvulsivos. Destarte, o objetivo deste estudo foi investigar um possível efeito neuroprotetor da fração RT10, isolada da peçonha de P.bistriata, em cultura primária de neurônios e glia (CPNGs), do tecido nervoso de ratos recém-nascidos, expostos a concentrações tóxicas de L-Glu (5 mM). As CPNGs foram tratadas durante 3 horas, previamente à lesão, que foi feita por um período de 12h. Ambas as exposições (tratamento e lesão) foram conduzidas no 7.º dia in vitro (DIV). Para analisar quantitativamente e qualitativamente os efeitos dos tratamentos, bem como demonstrar a composição das CPNGs foram realizados ensaios de viabilidade celular, com o sal sódico de resazurina (SSR) e, imunomarcações com anticorpos primários para MAP2, NeuN e GFAP. A fração RT10 foi neuroprotetora, pois diminuiu a perda celular nos testes com o SSR em 10%, nas CPNGs, expostas ao L-Glu, além de apresentarem efeito maior (5%), que o do fármaco Riluzol (RIL). A neuroproteção da RT10 também foi observada nos ensaios de imunocitoquimica. Os neurônios tratados com RT10 e RIL, que foram marcados com anti-MAP2 tiveram maior prolongamentos dos dendritos em relação aos neurônios não tratados. Portanto, a intensidade da fluorescência de anti-MAP2 para os neurônios tratados com esta fração foi 38% maior em relação aos não tratados; e 21% maior quando comparados ao grupo RIL. Deste modo, podemos considerar a RT10, como uma ferramenta para a prospecção de novos fármacos contra neurodegenerações, in vitro e principalmente estudos de mecanismo de ação, cujas variáveis podem ser mais bem controladas. / L-Glutamate (L-Glu), the major excitatory neurotransmitter in the central nervous system of vertebrates, is essential to the occurrence of cognitive functions. However, when L-Glu is over-accumulated in a synaptic cleft it can provoke excitotoxicity (EXT), which has been implicated in many neurological disorders (NDs). The current therapies against NDs are undereffective and can provoke side effects, so it is necessary to develop new treatments. In this regard, neuroactive compounds obtained from Parawixia bistriata spider venom are an alternative source of neuroactive compounds, because they showed neuroprotective effects in vitro and in vivo. Thus, the main aim of this work was to evaluate a possible neuroprotective effect of RT10 fraction obtained from P. bistriata venom in primary culture of neuron and glial cells (PCNGCs) from cerebral tissue of newborn Wistar rats, after the exposition to L-glu toxic concentration (5mM). The PCNGCs were submitted to the neuroprotection treatments for 3 hours and previously to the neurotoxic treatment, which the L-glu stayed for 12h in the PNGCs. The both expositions were conducted on the 7th day in vitro (DIV). The Resazurin sodium salt (RSS) and immunocytochemistry (MAP2, NeuN e GFAP primary antibodies) trials were utilized to measure quantitatively and qualitatively the treatments, as well as to prove the culture composition. In the RSS trial, the RT10 was neuroprotector, since avoided the cell death in 10%, under the PCNGCs which were exposed to L-Glu. in addition, RT10 demonstrated higher effect than rilozole (5%). RT10 attenuated the toxic effects of L-Glu under the neuromorphology, consequently the fluorescence intensity of MAP2 at PCNGC treated with RT10 was 38% higher than untreated group and it was 21% higher than riluzole group. Thus, we can consider that RT10 compounds are valuable tools to the prospection of new drugs against NDs.

excitotoxicidade

excitotoxicity

glia

glia cell

L-Glu

L-Glu

Neuron

Neurônio

neuroproteção

neuroprotection

neurotransmissão

neurotransmission

Parawixia bistriata

Parawixia bistriata

Parawixinas

Parawixins

RT10

RT10

Avaliação do efeito neuroprotetor de compostos obtidos da peçonha da aranha Parawixia bistriata, em cultura primária mista de células do tecido nervoso, de ratos Wistar / Evaluation of the neuroprotective effect of compounds from Parawixia bistriata spider venom, in primary mixed cells culture from cerebral tissue of newborn Wistar rats.

Eduardo Octaviano Primini

20 December 2016

O L-glutamato (L-Glu) é o principal neurotransmissor excitatório em vertebrados e é fundamental para funções primordiais do sistema nervoso central (SNC), tais como aprendizagem e memória. Entretanto, quando este neurotransmissor está em excesso na fenda sináptica, pode provocar uma série de eventos excitotóxicos, que por sua vez, estão associados a muitas neuropatologias. A terapia da maioria dessas doenças é ineficiente e provoca sérios efeitos colaterais. Portanto, é necessário desenvolver fármacos mais efetivos e com menos efeitos colaterais. Assim, peçonhas de artrópodes como a da aranha P. bistriata, se apresentam como fontes alternativas de compostos neuroativos, pois já demonstraram efeitos neuroprotetores in vitro e in vivo, bem como anticonvulsivos. Destarte, o objetivo deste estudo foi investigar um possível efeito neuroprotetor da fração RT10, isolada da peçonha de P.bistriata, em cultura primária de neurônios e glia (CPNGs), do tecido nervoso de ratos recém-nascidos, expostos a concentrações tóxicas de L-Glu (5 mM). As CPNGs foram tratadas durante 3 horas, previamente à lesão, que foi feita por um período de 12h. Ambas as exposições (tratamento e lesão) foram conduzidas no 7.º dia in vitro (DIV). Para analisar quantitativamente e qualitativamente os efeitos dos tratamentos, bem como demonstrar a composição das CPNGs foram realizados ensaios de viabilidade celular, com o sal sódico de resazurina (SSR) e, imunomarcações com anticorpos primários para MAP2, NeuN e GFAP. A fração RT10 foi neuroprotetora, pois diminuiu a perda celular nos testes com o SSR em 10%, nas CPNGs, expostas ao L-Glu, além de apresentarem efeito maior (5%), que o do fármaco Riluzol (RIL). A neuroproteção da RT10 também foi observada nos ensaios de imunocitoquimica. Os neurônios tratados com RT10 e RIL, que foram marcados com anti-MAP2 tiveram maior prolongamentos dos dendritos em relação aos neurônios não tratados. Portanto, a intensidade da fluorescência de anti-MAP2 para os neurônios tratados com esta fração foi 38% maior em relação aos não tratados; e 21% maior quando comparados ao grupo RIL. Deste modo, podemos considerar a RT10, como uma ferramenta para a prospecção de novos fármacos contra neurodegenerações, in vitro e principalmente estudos de mecanismo de ação, cujas variáveis podem ser mais bem controladas. / L-Glutamate (L-Glu), the major excitatory neurotransmitter in the central nervous system of vertebrates, is essential to the occurrence of cognitive functions. However, when L-Glu is over-accumulated in a synaptic cleft it can provoke excitotoxicity (EXT), which has been implicated in many neurological disorders (NDs). The current therapies against NDs are undereffective and can provoke side effects, so it is necessary to develop new treatments. In this regard, neuroactive compounds obtained from Parawixia bistriata spider venom are an alternative source of neuroactive compounds, because they showed neuroprotective effects in vitro and in vivo. Thus, the main aim of this work was to evaluate a possible neuroprotective effect of RT10 fraction obtained from P. bistriata venom in primary culture of neuron and glial cells (PCNGCs) from cerebral tissue of newborn Wistar rats, after the exposition to L-glu toxic concentration (5mM). The PCNGCs were submitted to the neuroprotection treatments for 3 hours and previously to the neurotoxic treatment, which the L-glu stayed for 12h in the PNGCs. The both expositions were conducted on the 7th day in vitro (DIV). The Resazurin sodium salt (RSS) and immunocytochemistry (MAP2, NeuN e GFAP primary antibodies) trials were utilized to measure quantitatively and qualitatively the treatments, as well as to prove the culture composition. In the RSS trial, the RT10 was neuroprotector, since avoided the cell death in 10%, under the PCNGCs which were exposed to L-Glu. in addition, RT10 demonstrated higher effect than rilozole (5%). RT10 attenuated the toxic effects of L-Glu under the neuromorphology, consequently the fluorescence intensity of MAP2 at PCNGC treated with RT10 was 38% higher than untreated group and it was 21% higher than riluzole group. Thus, we can consider that RT10 compounds are valuable tools to the prospection of new drugs against NDs.

excitotoxicidade

glia

L-Glu

Neurônio

neuroproteção

neurotransmissão

Parawixia bistriata

Parawixinas

RT10

excitotoxicity

glia cell

L-Glu

Neuron

neuroprotection

neurotransmission

Parawixia bistriata

Parawixins

RT10

Regeneration and plasticity of descending propriospinal neurons after transplantation of Schwann cells overexpressing glial cell line-derived neurotrophic factor following thoracic spinal cord injury in adult rats

Deng, Lingxiao

18 May 2015

Indiana University-Purdue University Indianapolis (IUPUI) / After spinal cord injury (SCI), poor axonal regeneration of the central nervous system, which mainly attributed to glial scar and low intrinsic regenerating capacity of severely injured neurons, causes limited functional recovery. Combinatory strategy has been applied to target multiple mechanisms. Schwann cells (SCs) have been explored as promising donors for transplantation to promote axonal regeneration. Among the central neurons, descending propriospinal neurons (DPSN) displayed the impressive regeneration response to SCs graft. Glial cell line-derived neurotrophic factor (GDNF), which receptor is widely expressed in nervous system, possesses the ability to promote neuronal survival, axonal regeneration/sprouting, remyelination, synaptic formation and modulate the glial response. We constructed a novel axonal permissive pathway in rat model of thoracic complete transection injury by grafting SCs over-expressing GDNF (SCs-GDNF) both inside and caudal to the lesion gap. Behavior evaluation and histological analyses have been applied to this study. Our results indicated that tremendous DPSN axons as well as brain stem axons regenerated across the lesion gap back to the caudal spinal cord. In addition to direct promotion on axonal regeneration, GDNF also significantly improved the astroglial environment around the lesion. These regenerations caused motor functional recovery. The dendritic plasticity of axotomized DPSN also contributed to the functional recovery. We applied a G-mutated rabies virus (G-Rabies) co-expressing green fluorescence protein (GFP) to reveal Golgi-like dendritic morphology of DPSNs and its response to axotomy injury and GDNF treatment. We also investigated the neurotransmitters phenotype of FluoroGold (FG) labeled DPSNs. Our results indicated that over 90 percent of FG-labeled DPSNs were glutamatergic neurons. DPSNs in sham animals had a predominantly dorsal-ventral distribution of dendrites. Transection injury resulted in alterations in the dendritic distribution, with dorsal-ventral retraction and lateral-medial extension of dendrites. Treatment with GDNF significantly increased the terminal dendritic length of DPSNs. The density of spine-like structures was increased after injury and treatment with GDNF enhanced this effect.

Axonal regeneration

Descending propriospinal tract

G-rabies virus

Schwann cell

Spinal cord injury

Central nervous system -- regeneration

Axons -- physiology

Central nervous system -- Physiology

Nervous system -- Regeneration

Spinal cord -- Wounds and injuries

Neuroglia