A common approach to understanding neurodegenerative disease is comparing gene expression in diseased versus healthy tissues. We illustrate that expression profiles derived from whole tissue RNA highly reflect the degenerating tissues' altered cellular composition, not necessarily transcriptional regulation. To accurately understand transcriptional changes that accompany neuropathology, we acutely purify neurons, astrocytes and microglia from single adult mouse brains and analyse their transcriptomes by RNA sequencing. Using peripheral endotoxemia to establish the method, we reveal highly specific transcriptional responses and altered RNA processing in each cell type, with Tnfr1 required for the astrocytic response. Extending the method to an Alzheimer's disease model, we confirm that transcriptomic changes observed in whole tissue are driven primarily by cell type composition, not transcriptional regulation, and identify hundreds of cell type-specific changes undetected in whole tissue RNA. Applying similar methods to additional models and patient tissues will transform our understanding of aberrant gene expression in neurological disease.
Significance
Identifying the source and dynamics of persistent HIV-1 during combinational antiretroviral therapy (cART) is crucial for understanding the barriers to curing HIV infection. Through genetic characterization of HIV-1 DNA in infected cells from peripheral blood and gut-associated lymphoid tissue from patients after long-term suppressive cART, our study reveals that the primary barrier to a cure is a remarkably stable pool of infected memory CD4
+
T cells. Through in-depth phylogenetic analyses, we determined that the HIV-1 reservoir in these cells from eight patients is kept stable during long-term cART and, with little evidence of viral replication, this population could be maintained by homeostatic cell proliferation or other processes.
Background
The gut is a major reservoir for HIV in patients receiving antiretroviral therapy (ART). We hypothesized that distinct immune environments within the gut may support varying levels of HIV.
Methods
In 8 HIV-1+ adults on ART with CD4>200 and plasma VL<40, levels of HIV and T-cell activation were measured in blood and endoscopic biopsies from the duodenum, ileum, right colon, and rectum.
Results
HIV DNA and RNA per CD4+T-cell were higher in all four gut sites compared to blood. HIV DNA increased from the duodenum to the rectum, while the median HIV RNA peaked in the ileum. HIV DNA correlated positively with T-cell activation in the PBMC but negatively with T-cell activation in the gut. Multiply-spliced RNA was infrequently detected in gut, and unspliced RNA/DNA ratios were lower in the colon and rectum relative to PBMC, reflecting paradoxically low HIV transcription given the higher T-cell activation in the gut.
Conclusions
HIV DNA and RNA are both concentrated in the gut, but the inverse relationship between HIV DNA and T-cell activation in the gut and the paradoxically low levels of HIV expression in the large bowel suggest that different processes drive HIV persistence in the blood and gut.
Memory T cells maintained a relatively constant HIV-1 DNA integrant pool that was genetically stable during long-term effective ART. These integrants appear to be maintained by cellular proliferation and longevity of infected cells, rather than by ongoing viral replication.
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