An immune control model for viral replication in the CNS during presymptomatic HIV infection.

The brain is targeted by human immunodeficiency virus type 1 (HIV-1) during the course of untreated infection, leading to cognitive impairment, neurological damage and HIV encephalitis (HIVE). To study early dynamics of HIV entry into the brain, we examined a unique autopsy series of samples obtained from 15 untreated individuals who died in the presymptomatic stages of infection from non-HIV causes. HIV was detected and quantified by limiting dilution PCR and genetically characterized in the V3 region of env. Limiting dilution was shown to be essential for correct estimation of genetic partitioning between brain- and lymphoid-associated HIV populations. While no actively expressing HIV-infected cells were detected by immunohistochemistry, variable and generally extremely low levels of proviral DNA were detected in presymptomatic brain samples. V3 region sequences were frequently genetically distinct from lymphoid-associated HIV variants, with association index (AI) values similar to those observed in cases of HIVE. Infiltration of CD8 lymphocytes in the brain was strongly associated with expression of activation markers (MHCII; R = 0.619; P < 0.05), the presence of HIV-infected cells (proviral load; R = 0.608; P < 0.05) and genetic segregation of brain variants from populations in lymphoid tissue (AI value, R = -0.528; P approximately 0.05). CD8 lymphocytes may thus limit replication of HIV seeded into the brain in early stages of infection. Neurological complications in AIDS occur when this control breaks down, due to systemic immunosuppression from HIV that destroys CD8 lymphocyte function and/or through the evolution of more aggressive neuropathogenic variants.

Hyperphosphorylated tau and amyloid precursor protein deposition is increased in the brains of young drug abusers.

Drug abuse is a major problem worldwide. The incidence of drug-related deaths attributed to opiate abuse is increasing annually. Apart from routine examination, little is known of the neuropathology of drug abuse. We, and others, have shown previously that drug abuse is associated with microglial activation. We hypothesised that neuroinflammation might lead to premature neurodegeneration in drug abusers. We investigated the brains of young opiate abusers (n=34, all<40 years) for the presence of proteins associated with neurodegenerative diseases and compared them with the brains of age-matched, non-drug users (n=16) all of whom died suddenly. Detailed immunohistochemical analysis of the hippocampus, brainstem and basal ganglia for hyperphosphorylated tau, beta-amyloid, beta-amyloid precursor protein (betaAPP) and ubiquitin demonstrated an excess of AT 8-positive neurofibrillary tangles (NFT) in the drug abusers. These were not only more prevalent in the drug abusers than in controls (44%vs. 19%) but also involved more brain areas. In controls NFT were confined to the entorhinal cortex whereas in drug users they were also found in the subiculum, temporal neocortex, nucleus basalis of Meynert and the locus coeruleus. Virtually no amyloid plaques were present but betaAPP positivity was again much more common in drug abusers than controls (73%vs. 20% in the brainstem and 59%vs. 23% in the temporal lobe). There is no suggestion that these drug abusers had displayed major cognitive impairment although detailed neuropsychological assessment is difficult in this subject group. Likely causes of hyperphosphorylated tau deposition in drug abuse include hypoxic-ischaemic injury, microglial-associated cytokine release and possibly drug-associated neurotoxicity or hepatitis. Head injury, which is another major risk factor, does not appear to have contributed to our findings. Genetic factors also merit consideration. It is unclear at present how much of the hyperphosphorylated tau detected in these young drug abusers represents a transitory phenomenon.

Influence of HAART on HIV-related CNS disease and neuroinflammation.

Neuroinflammation has an established link with AIDS-related dementia but has not been investigated in the post-highly active anti-retroviral therapy (HAART) era. In this autopsy study we examined post-HAART cases in Edinburgh for the presence of HIV-related pathology and in well-treated cases for evidence of neuroinflammation. We focused on basal ganglia and the hippocampus, 2 key areas of the brain for cognitive functioning and compared pre- and post-HAART cases for neuroinflammatory status. We find evidence, post-HAART, that there is a high level of microglial/macrophage activation that is comparable with the levels seen, pre-HAART, in HIV encephalitis (HIVE) and AIDS cases. This result was maximal in the hippocampus where microglial/macrophage upregulation in the HAART-treated group exceeded that seen in HIVE. In the basal ganglia, HAART-treated cases showed significantly higher levels of CD68-positive microglia/macrophages than in control brains (p = 0.004), and in the hippocampus levels were significantly higher than those seen in control cases, pre-HAART AIDS, and presymptomatic brains (p = 0.01). However, lymphocyte levels in the areas examined were low in HAART-treated cases. We conclude that there is a surprising degree of ongoing neuroinflammation in HAART-treated patients, particularly in the hippocampus. This may pose a threat for the future health of individuals maintained long-term on HAART therapy.

Does drug abuse alter microglial phenotype and cell turnover in the context of advancing HIV infection?

The aim of this study was to test the effects of drug abuse, in particular opiate abuse, on the phenotype and turnover of microglial cells within the brain in the context of advancing HIV infection. Basal ganglia and hippocampus sections were studied in 51 cases divided into six groups: HIV-negative normal controls, HIV-negative drug abusers, AIDS nondrug abusers, AIDS drug abusers, HIV encephalitis (HIVE) nondrug abusers and HIVE drug abusers. None of the cases studied had received highly active anti-retroviral therapy (HAART). Microglial phenotypes were defined using CD14, CD16, CD68 and major histocompatibility class II (MHC II). Microglial turnover was assessed using terminal deoxynucleotidyl transferase mediated dUTP nick end labelling (TUNEL) (DNA damage), BAX (proapoptotic marker), Fas (CD95) (proapoptotic), proliferating cell nuclear antigen (PCNA) (proliferation and DNA repair), Ki-67 (cell proliferation) and BCL-2 (antiapoptosis). We find increased expression of MHC II and CD16 in response to drug abuse. We also noted increased levels of TUNEL positivity in drug abusers compared to nondrug abusers, although conversely we found lower levels of BAX in those who had abused drugs. We find no evidence of microglial proliferation in any of our study groups, including HIVE, although HIV infection leads to increased expression of CD16, CD68 and MHC II. CD14 expression was restricted to perivascular microglia in all groups (including normal controls) apart from the two HIVE groups where some but not all cases also showed parenchymal expression of CD14. In contrast, CD16 was found in parenchymal microglia in all groups. Using high-pressure antigen retrieval and tyramide signal amplification, we find moderately high levels of CD16 expression in the parenchyma of normal brains which is not normally observed using standard avidin/biotin complex (ABC) techniques. This suggests that a low basal expression of CD16 occurs in many resident microglial cells which may potentially be upregulated in HIV-infected individuals. From these data, we suggest that not all the CD16+ parenchymal cells detected in AIDS brains (using ABC) represent influx of monocyte lineage cells from the blood. Finally the increased expression of MHC II and CD68 detected in drug abusers with HIVE compared to nondrug abusers with HIVE suggests that the combination of drug abuse and HIV infection has a greater deleterious effect on the brain than either individual insult on its own.