Mitochondrial injury and cognitive function in HIV infection and methamphetamine use

Var, Susanna R.; Day, Tyler R C; Vitomirov, Andrej; Smith, Davey M.; Soontornniyomkij, Virawudh; Moore, David J.; Achim, Cristian L.; Mehta, Sanjay R.; Pérez-Santiago, Josué

doi:10.1097/qad.0000000000001027

Cited by 37 publications

(30 citation statements)

References 51 publications

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“…Neuropathological studies showed accumulation of mtDNA damage in the frontal cortex of HAND patients (Zhang et al, 2012), which has implications for the processes of mitochondrial biogenesis and ATP production. A recent study found similar markers of mitochondrial damage in a cohort of HIV+ brains that were stratified by use of methamphetamine (Var et al, 2016). In this study, increased mitochondrial injury in Brodmann area 46 of frontal cortices was associated with worse neurocognitive function in HIV+METH À individuals (Var et al, 2016).…”

Section: Mitochondrial Dysfunction In Neurological Disorderssupporting

confidence: 70%

HIV in the cART era and the mitochondrial: immune interface in the CNS

Fields

Ellis

2019

International Review of Neurobiology

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Introduction 30 1.1 HIV neuropathogenesis in pre-and post-cART eras 31 1.2 HAND clinical features 32 1.3 Mitochondrial dysfunction in neurological disorders 34 2. HIV proteins and mitochondrial dysfunction in the CNS 38 2.1 Gp120 39 2.2 Tat 42 2.3 Vpr and Nef 45 2.4 HIV proteins and mitochondrial mediated oxidative stress 46 2.5 HIV proteins and immunometabolism 47 3. cART and mitochondrial dysfunction in the CNS 48 3.1 Post-cART era human studies 48 3.2 cART induces mitochondrial toxicity using in vitro models 50 4. Preventing HIV-induced mitochondrial toxicity 51 5. Conclusion 54 References 55

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Section: Mitochondrial Dysfunction In Neurological Disorderssupporting

confidence: 70%

HIV in the cART era and the mitochondrial: immune interface in the CNS

Fields

Ellis

2019

International Review of Neurobiology

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“…DNA was extracted from CSF supernatant samples using QIAamp DNA Mini Kit (Qiagen, Hilden, Germany) per manufacturer’s protocol. Levels of mtDNA were measured by droplet digital PCR (ddPCR, Bio-Rad, Hercules, CA) using primer-probes combinations targeting the mitochondrial NADH dehydrogenase 2 gene (MT-ND2, Integrated DNA Technologies, IA) and the human genomic DNA (gDNA) by targeting the Ribonuclease P protein subunit p30 gene (RPP30, Integrated DNA Technologies, IA), using ZEN quenched probes [14]. Each sample was run in triplicate in a 20μL of reaction, which consisted of 10μL of 2× Bio-Rad supermix for probes, 1μL of either 20× Primer/FAM-Zen ND2 mix or 20× Primer/HEX-Zen RPP30 mix, 4μL of molecular grade water, and 5μL of total DNA, using the following conditions: (1) an initial activation of 95°C for 10 minutes, (2) 55 cycles of 94°C for 30 seconds and 60°C for 1 min, (3) enzyme inactivation at 98°C for 10 minutes, and 4°C hold.…”

Section: Methodsmentioning

confidence: 99%

Increased cell-free mitochondrial DNA is a marker of ongoing inflammation and better neurocognitive function in virologically suppressed HIV-infected individuals

et al. 2016

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Cell-free Mitochondrial DNA (mtDNA) is a highly immunogenic molecule that is associated with several inflammatory conditions and with neurocognitive impairment during untreated HIV infection. Here, we investigate how cell-free mtDNA in cerebrospinal fluid (CSF) is associated with inflammation, neuronal damage and neurocognitive functioning in the context of long-term suppressive antiretroviral therapy (ART). We quantified the levels of cell-free mtDNA in the CSF from 41 HIV-infected individuals with completely suppressed HIV RNA levels in blood plasma (<50 copies/mL) by droplet digital PCR. We measured soluble CD14, soluble CD163, IP-10, MCP-1, IL-6, IL-8, TNF-α, neopterin, and neurofilament-light (NFL) by immunoassays in CSF supernatant or blood plasma. Higher levels of mtDNA in CSF were associated with higher levels of MCP-1 (r=0.56, p<0.01) in CSF, and TNF-α (r=0.43, p<0.01), and IL-8 (r=0.44, p<0.01) in blood plasma. Subjects with a previous diagnosis of AIDS showed significantly higher levels of mtDNA (p<0.01) than subjects without AIDS. The associations between mtDNA and MCP-1 in CSF, and TNF-α in blood, remained significant after adjusting for previous diagnosis of AIDS (p<0.01). Additionally, higher levels of mtDNA were associated with a lower CD4 nadir (r=−0.41, p<0.01), and lower current CD4% (r=−0.34, p=0.03). Paradoxically, higher levels of mtDNA in CSF were significantly associated with better neurocognitive performance (r=0.43, p=0.02) and with less neuronal damage (i.e. lower NFL). Higher cell-free mtDNA is associated with inflammation during treated HIV-infection but the impact on neurocognitive functioning and neuronal damage remain unclear and may differ in the setting of suppressive ART.

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“…Recent studies using postmortem HIV-infected brains have addressed nuclear DNA methylation, mitochondrial DNA injury, and cerebral gliosis (Desplats et al 2014; Soontornniyomkij et al 2016; Var et al 2016). Epigenetic changes were investigated in the frontal cortex of HIV-infected individuals with or without Meth dependence (Desplats et al 2014).…”

Section: Neuropathologymentioning

confidence: 99%

Effects of HIV and Methamphetamine on Brain and Behavior: Evidence from Human Studies and Animal Models

Soontornniyomkij

Kesby

Morgan

et al. 2016

J Neuroimmune Pharmacol

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Methamphetamine (Meth) use is frequent among HIV-infected persons. Combined HIV and Meth insults may exacerbate neural injury in vulnerable neuroanatomic structures or circuitries in the brain, leading to increased behavioral disturbance and cognitive impairment. While acute and chronic effects of Meth in humans and animal models have been studied for decades, the neurobehavioral effects of Meth in the context of HIV infection are much less explored. In-depth understanding of the scope of neurobehavioral phenotypes and mechanisms in HIV/Meth intersection is needed. The present report summarizes published research findings, as well as unpublished data, in humans and animal models with regard to neurobehavioral disturbance, neuroimaging, and neuropathology, and in vitro experimental systems, with an emphasis on findings emerging from the National Institute on Drug Abuse (NIDA) funded Translational Methamphetamine AIDS Research Center (TMARC). Results from human studies and animal (primarily HIV-1 gp120 transgenic mouse) models thus far suggest that combined HIV and Meth insults increase the likelihood of neural injury in the brain. The neurobehavioral effects include cognitive impairment and increased tendencies toward impaired behavioral inhibition and social cognition. These impairments are relevant to behaviors that affect personal and social risks, e.g. worse medication adherence, riskier behaviors, and greater likelihood of HIV transmission. The underlying mechanisms may include electrochemical changes in neuronal circuitries, injury to white matter microstructures, synaptodendritic damage, and selective neuronal loss. Utilization of research methodologies that are valid across species is instrumental in generating new knowledge with clinical translational value.

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Mitochondrial injury and cognitive function in HIV infection and methamphetamine use

Cited by 37 publications

References 51 publications

HIV in the cART era and the mitochondrial: immune interface in the CNS

HIV in the cART era and the mitochondrial: immune interface in the CNS

Increased cell-free mitochondrial DNA is a marker of ongoing inflammation and better neurocognitive function in virologically suppressed HIV-infected individuals

Effects of HIV and Methamphetamine on Brain and Behavior: Evidence from Human Studies and Animal Models

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