Characterization of HIV variants from paired Cerebrospinal fluid and Plasma samples in primary microglia and CD4+ T-cells.

Despite antiretroviral therapy (ART), HIV persistence in the central nervous system (CNS) continues to cause a range of cognitive impairments in people living with HIV (PLWH). Upon disease progression, transmigrating CCR5-using T-cell tropic viruses are hypothesized to evolve into macrophage-tropic viruses in the CNS that can efficiently infect low CD4-expressing cells, such as microglia. We examined HIV-1 RNA concentration, co-receptor usage, and CSF compartmentalization in paired CSF and blood samples from 19 adults not on treatment. Full-length envelope CSF- and plasma-derived reporter viruses were generated from 3 subjects and phenotypically characterized in human primary CD4+ T-cells and primary microglia. Median HIV RNA levels were higher in plasma than in CSF (5.01 vs. 4.12 log10 cp/mL; p = 0.004), and coreceptor usage was mostly concordant for CCR5 across the paired samples (n = 17). Genetically compartmentalized CSF viral populations were detected in 2 subjects, one with and one without neurological symptoms. All viral clones could replicate in T-cells (R5 T cell-tropic). In addition, 3 CSF and 1 plasma patient-derived viral clones also had the capacity to replicate in microglia/macrophages and, therefore have an intermediate macrophage tropic phenotype. Overall, with this study, we demonstrate that in a subset of PLWH, plasma-derived viruses undergo genetic and phenotypic evolution within the CNS, indicating viral infection and replication in CNS cells. It remains to be studied whether the intermediate macrophage-tropic phenotype observed in primary microglia represents a midpoint in the evolution towards a macrophage-tropic phenotype that can efficiently replicate in microglial cells and propagate viral infection in the CNS.

Dynamics of Low-Level Viremia and Immune Activation after Switching to a Darunavir-Based Regimen.

There is an ongoing debate regarding whether low-level viremia (LLV), in particular persistent LLV, during HIV treatment with optimal adherence originates from low-level viral replication, viral production, or both. We performed an observational study in 30 individuals with LLV who switched to a boosted darunavir (DRV)-based therapy. In-depth virological analyses were used to characterize the viral population and the (activity) of the viral reservoir. Immune activation was examined using cell-bound and soluble markers. The primary outcome was defined as the effect on HIV-RNA and was categorized by responders (<50 cp/mL) or non-responders (>50 cp/mL). At week 24, 53% of the individuals were considered responders, 40% non-responders, and 7% could not be assigned. Sequencing showed no evolution or selection of drug resistance in the non-responders. Production of defective virus with mutations in either the protease (D25N) or RT active site contributed to persistent LLV in two individuals. We show that in about half of the study participants, the switch to a DRV-based regimen resulted in a viral response indicative of ongoing low-level viral replication as the cause of LLV before the switch. Our data confirm that in clinical management, high genetic barrier drugs like DRV are a safe choice, irrespective of the source of LLV.

Reptile-associated Salmonella urinary tract infection: a case report.

We present an 18-year-old woman with a urinary tract infection caused by Salmonella Oranienburg. S. Oranienburg was isolated from her pet snake and confirmed as the source of infection using whole genome sequencing. Our case demonstrates the risk of acquiring reptile-associated salmonellosis and stretches the need for awareness to prevent these infections.

Residual viremia is preceding viral blips and persistent low-level viremia in treated HIV-1 patients.

BACKGROUND: It has been suggested that low-level viremia or blips in HIV-infected patients on antiretroviral treatment are related to assay variation and/or increased sensitivity of new commercial assays. The 50-copy cut-off for virologic failure is, therefore, under debate. METHODS: Treated patients with low-level viremia (persistent viral loads (VL) of 50-1000 copies/mL, group A, N = 16) or a blip (single detectable VL, group B, N = 77) were compared to a control group (consistently suppressed viremia since start therapy (<50 copies/mL), N = 79). Residual viremia (detectable viral RNA <50 copies/ml) in the year preceding the first VL above 50 copies/mL (T0) was determined using Roche Cobas-Amplicor v1.5 or CAP-CTM v2.0. Subsequent virologic failure (2 consecutive VLs>500 or 1 VL>1000 copies/mL that was not followed by a VL<50 copies/mL; median follow up 34 months) was assessed. RESULTS: Significantly more patients in groups A and B had residual viremia in the year preceding T0 compared to controls (50% and 19% vs 3% respectively; p<0.001). Residual viremia was associated with development of low-level viremia or blips (OR 10.9 (95% CI 2.9-40.6)). Subsequent virologic failure was seen more often in group A (3/16) and B (2/77) than in the control group (0/79). CONCLUSION: Residual viremia is associated with development of blips and low-level viremia. Virologic failure occurred more often in patients with low-level viremia. These results suggest that low-level viremia results from viral production/replication rather than only assay variation.

Differential genotypic evolution of HIV-1 quasispecies in cerebrospinal fluid and plasma: a systematic review.

HIV-1 enters the central nervous system by passing the blood-brain barrier during primary infection. Despite the introduction of combination antiretroviral therapy, the prevalence of HIV-associated neurocognitive disorders remains high and is probably related to ongoing viral neuropathological processes. The central nervous system forms a distinct physiological, cellular, and pharmacological environment. We aimed to systematically review whether the central nervous system also constitutes a distinct virological compartment, allowing differential genotypic evolution of HIV-1. Only original research papers that compared paired plasma/cerebrospinal fluid samples for drug resistance associated mutations as defined by the IAS-USA Drug Resistance Mutations Panel or compared viral envelope (env) patterns or coreceptor prediction were included. If available, HIV RNA levels were included in the analysis, with a relevant difference defined as 0.5 log10 copies/ml. Data from 35 reports with heterogeneous study design and methods was pooled and statistical analysis was performed as appropriate. A total of 555 subjects with 671 samples could be included in this review. We observed that compartmentalization of the central nervous system occurs frequently as reflected by differences in HIV viral load, resistance associated mutations, and viral coreceptor tropism preference.