Cannabinoids Reduce Extracellular Vesicle Release from HIV-1 Infected Myeloid Cells and Inhibit Viral Transcription

2.2. Patient Samples

Plasma specimens were obtained from 15 individuals, including 10 PWH with a suppressed viral load on cART (n = 5 cannabis users and n = 5 non-cannabis users) and HIV-uninfected individuals (n = 5 non-cannabis users) at the Chronic Viral Illness Service/Centre for Innovative Medicine of the McGill University Health Centre (Montreal, QC, Canada). This study was ethically approved by the Research Institute of the McGill University Health Centre Research Ethics Board (MUHC 15-031/18-3835). Written informed consent was obtained before enrolment. The research was conducted in accordance with the Helsinki Declaration.

2.3. ZetaView Nanoparticle Tracking Analysis (NTA)

NTA was performed with the ZetaView Z-NTA (Particle Metrix) and its software (ZetaView 8.04.02; Particle Metrix GmbH, Inning am Ammersee, Germany). The machine was calibrated according to the manufacturer’s protocol, using settings as previously described [5]. Following the measurement and removal of any outliers from the measured 11 positions, the mean size (diameter; nm) and the concentration of the sample (EV number) were analyzed by the associated ZetaView software. Measurement data from the ZetaView were used to calculate averages and standard deviations from technical triplicates using Microsoft Excel 2016.

2.4. EV Enrichment Using Nanotrap Particles

EVs from small volume samples were enriched using Nanotrap particles (Ceres Nanosciences, Inc; Manassas, VA, USA) as previously described [5,10,23,24,25]. Briefly, equal parts NT82 (Ceres #CN2010), NT80 (Ceres #CN1030), and 1× PBS without calcium or magnesium were combined and resuspended to create a 30% slurry. Twenty-five microliters of the NT80/82 slurry were added to 1 mL of culture supernatant and rotated overnight at 4 °C to enrich for EVs. The next day, the Nanotrap particles were pelleted, washed one time with 1× PBS without calcium or magnesium and used for further analyses.

2.5. RNA Isolation, Creation of cDNA, and Quantitative Real-Time PCR (RT-qPCR)

For the isolation of total RNA, cells were harvested, washed once in 1× PBS without calcium or magnesium and resuspended in 50 µL of 1× PBS. For the isolation of total RNA from EVs, Nanotrap particles were incubated and harvested as described above, then resuspended in 50 µL of 1× PBS without calcium or magnesium. Total RNA was isolated from cell pellets and NT80/82 pellets bound with EVs using Trizol Reagent (Invitrogen) as described by the manufacturer’s protocol. cDNA was generated using GoScript Reverse Transcription Systems (Promega) using Envelope Reverse: (5′-TGG GAT AAG GGT CTG AAA CG-3′; Tm = 58 °C), and TAR Reverse: (5′-CAA CAG ACG GGC ACA CAC TAC-3′, Tm = 58 °C) primers. Serial dilutions of DNA from a CEM T-cell line containing a single copy of HIV-1 LAV provirus per cell (8E5 cells) were used as the quantitative standards. cDNA samples (2 µL per well) were plated into a Master Mix (18 µL per well) containing IQ Supermix (Bio-Rad), TAR Forward Primer (5′-GGT CTC TCT GGT TAG ACC AGA TCT G-3′), TAR Reverse Primer (5′-CAA CAG ACG GGC ACA CAC TAC-3′), and TAR Probe (5′56-FAM-AG CCT CAA TAA AGC TTG CCT TGA GTG CTT C-36-TAMSp-3′). RT-qPCR conditions were as follows: one cycle for 2 min at 95 °C followed by 41 cycles of 95 °C for 15 s and 58 °C for 40 s. Reactions were performed in triplicate using the BioRad CFX96 Real-Time System. Quantitation was determined using cycle threshold (Ct) values relative to the 8E5 standard curve using the BioRad CFX Manager Software. Analysis of generated raw data was analyzed using Microsoft Excel 2016.

2.6. Preparation of Whole-Cell Extracts

Infected U1 cell pellets were collected, washed with 1× PBS, and resuspended in 50 µL of lysis buffer (50 mM Tris-HCl (pH 7.5), 120 mM NaCl, 5 mM EDTA, 0.5% Nonidet P-40, 50 mM NaF, 0.2 mM Na₃VO₄, 1 mM DTT, and 1 complete protease inhibitor cocktail tablet per 50 mL (Roche Applied Science; Philadelphia, PA, USA). The mixture was incubated on ice for 20 min with vortexing every 5 min. Following incubation, the cell debris was separated by centrifugation for 10 min at 10,000× g. Protein concentrations of each cell lysate were determined using the Bradford protein assay performed according to the manufacturer’s protocol (Bio-Rad).

2.7. Western Blot

Laemmli buffer was added to sample cell lysates (10–20 µg) or NT80/82 pellets. Lysates were heated at 95 °C for 3 min, and 15 µL of the sample was loaded onto a 4–20% Tris/glycine gel (Invitrogen; Waltham, MA, USA). When analyzing NT80/82 pellets, samples were heated at 95 °C for 3 min, vortexed, and then heated two additional times to release captured material from NT80/82 beads. Following the release of captured cargo, the total sample was then loaded onto a 4–20% Tris-Glycine gel (Invitrogen). Gels were run at 100 V and transferred onto Immobilon PVDF membranes (Millipore; Burlington, MA, USA) at 50 mA overnight. Membranes were blocked in 5% milk in PBS with 0.1% Tween-20 (PBS-T) for 2 h at 4 °C, then incubated overnight at 4 °C in PBS-T with the appropriate primary antibody: α-p24 (Cat: 4121; NIH AIDS Reagent Program), α-Nef (Cat: 3689; NIH AIDS Reagent Program), α-gp120 (Cat: 522; NIH AIDS Reagent Program), α-CD81 (Cat: EXOAB-CD81A-1; SBI, Palo Alto, CA, USA), α-VPS4 (Cat: sc-32922; Santa Cruz Biotechnology Dallas, Texas, USA), α-CHMP6 (Cat: sc-67231; Santa Cruz Biotechnology), α-Actin (ab-49900; Abcam, Waltham, MA, USA), α-CD63 (Cat: EXOAB-CD63A-1; Systems Biosciences, Palo Alto, CA, USA), α-SQSTM1/p62 (Cat: 5114; Cell Signaling Technology), α-MAP LC3 α/β (Cat: sc-398822; Santa Crux Biotechnology), α-Alix (Cat: sc-49268; Santa Cruz Biotechnology), α-ATG12 (Cat: sc-271688; Santa Cruz Biotechnology), and α-Beclin 1 (Cat: sc-48341; Santa Cruz Biotechnology). Membranes were washed with PBS-T and incubated for 2 h with the indicated HRP-conjugated secondary antibody at 4 °C. HRP luminescence was activated with Clarity or Clarity Max Western ECL Substrate (Bio-Rad) and visualized by the Molecular Imager ChemiDoc Touch system (Bio-Rad).

2.8. Cell Viability Assay

Cells were cultured in RPMI with 10% exosome-free FBS at 10⁶ cells per well in 6 well plates. Cells were treated with 0.005% ethanol (control), CBD (1, 5, 10, 50 µm), and THC (1, 5, 10, 50 µg per mL) once per day for 5 days. The MTT assay was used to measure cell death according to the manufacturer’s protocol (Sigma). After incubating with MTT solution for 2 h, the culture medium was aspirated, and 0.1 mL of MTT solvent was added to each well. Cell viability was determined by the formation of formazan crystal and measured by absorbance at 590 nm and 620 nm, as previously described [26].

2.9. Chromatin Immunoprecipitation (ChIP)

Cells were harvested and washed with 1x PBS at 2000× g for 10 min. The cells were resuspended in 1% formaldehyde, made from 37% formaldehyde solution (Cat: F1635; Sigma-Aldrich), and exosome free RPMI media supplemented with l-glutamine, penicillin/streptomycin and FBS. Samples were rocked for 30 min at room temperature and further processed using the Imprint Chromatin Immunoprecipitation Kit (Sigma). Next, the samples were sonicated, followed by an overnight 4 °C incubation while rotating with IgG or Pol II (serine 2/5) antibodies (10 µg). A 50% (v/v) protein A-Sepharose/protein G-Sepharose beads (A/G beads) (Calbiochem) was used to bind the complexes for a 2 h 4°C incubation, rotating. Samples were washed three times with 1× PBS, and proteinase K (800 units per mL) and crosslinking reversing solution (Sigma) was added for 90 min at 65 °C. DNA samples were washed and assayed for TAR DNA using qPCR analysis.

2.10. Kinase Assay

U1 cells (5 × 10⁶) were treated with CBD (1 µM) and THC (3.18 µM) every day for 5 days. Cells were pelleted by centrifugation at 15,000× g for 5 min, washed with 1× PBS, and lysed in 250 µL lysis buffer. Lysates were immunoprecipitated with 10 µg of cdk9 or IgG antibodies overnight at 4 °C, followed by a 2 h incubation with A/G beads at 4 °C. IP complexes were washed with TNE50 + 0.1% NP40 buffer and kinase buffer as described in [27], followed by 1 h incubation period at 37 °C with γ-³²P ATP and purified histone H1. The samples (50%) were loaded and run through SDS-PAGE on a 4–20% Tris-Glycine gel, followed by staining with Coomassie blue overnight and then destained with destaining buffer (50% methanol and 10% acetic acid), and dried for 2 h. The dried gels were exposed to a PhosphorImager Cassette, followed by analysis using Molecular Dynamic’s ImageQuant Software; Los Altos, CA, USA.

2.11. Neurospheres

Neural progenitor cells (NPCs; Cat: ACS-5003; ATCC, Manassas, VA, USA) were grown using STEMdiffTM Neural Progenitor Medium (STEMCELL Technologies^TM; Vancouver, BC, Canada) and differentiated into 3D neurospheres (1 × 10⁵ cells per well) using DMEM:F12 (Cat: 30-2006; ATCC) + Neural Progenitor Cell Dopaminergic Differentiation Kit (Cat: ACS-3004; ATCC) for an incubation period of 14 d. Inverted microscopy using Zen imaging software (Zeiss; Jena, Germany) was used to develop phase-contrast images. Neurospheres were infected with HIV-1 89.6 dual-tropic strain (MOI: 10) and 10 µL of Infectin^TM (Virongy, LLC; Manassas, VA, USA) with a total volume of 200 µL, followed by a 48 h incubation period. Neurospheres were then gently washed with 1× PBS ± treated twice with 10 µM cocktail (Lamivudine, Tenofovir, Emtricitabine, Indinavir) ± treatment (every other day) with a titration of CBD (5 and 10 µM) for a seven-day incubation period. Neurospheres were lysed in 100 µL lysis buffer, and total lysates were run on a 4–20% Tris-Glycine SDS-PAGE, followed by Western blot assessment. For RT-qPCR analysis, RNA was isolated from neurospheres, followed by RT-qPCR analysis.

2.12. Mass Spectrometry Analysis

HIV-1 infected U1 monocytes and U1 monocyte-derived macrophages (MDMs) were cultured, followed by lysis of cell pellets. Each lysate sample (250 µg) was incubated with 100 µg of D-Biotin (ThermoFisher Scientific; Cat: B1595) or biotinylated cannabidiol (KareBay Biochem, Inc., Monmouth Junction, NJ, USA), with a total volume of 800 µL, at 4 °C overnight. Streptavidin-Sepharose Beads (BioVision, Inc; Milpitas, CA, USA. Cat: 6565-2) (30 µL) were then added to each sample and incubated for 2 h at 4 °C. The beads were pelleted through centrifugation at 15,000× g for 5 min. The supernatants were removed, and the pellets were washed twice with TNE300 + 0.1% NP40 buffer at 15,000× g for 5 min. The pellets were washed with 1× PBS at 15,000× g for 5 min, and the supernatant was discarded. The pellets were treated with urea (8 M) and DTT (10 mM) to reduce samples, which were then alkylated with iodoacetamide (50 mM). The samples were then diluted by a solution of equal parts water and NH₄HCO₃ (500 mM). Samples were digested with trypsin (Promega) for 4 h at 37 °C. The sample was desalted by ZipTip, dried in SpeedVac, and then reconstituted with 10 µL of 0.1% formic acid for mass spectrometry (MS) analysis. Liquid chromatography coupled tandem mass spectrometry (LC-MS/MS) experiments were performed on an Orbitrap Fusion (ThermoFisher Scientific, Waltham, MA, USA) equipped with a nanospray EASY-nLC 1200 HPLC system. Peptides were separated using a reversed-phase PepMap RSLC 75 μm i.d. × 15 cm long with 2 μm particle size C18 LC column from ThermoFisher Scientific. The mobile phase consisted of 0.1% aqueous formic acid (mobile phase A) and 0.1% formic acid in 80% acetonitrile (mobile phase B). After sample injection, the peptides were eluted using a linear gradient from 5% to 40% B over 60 min and ramping to 100% B for an additional 2 min. The flow rate was set at 300 nL per min. The Orbitrap Fusion was operated in a data-dependent mode in which one full MS scan (60,000 resolving power) from 300 m/z to 1500 m/z was followed by MS/MS scans in which the most abundant molecular ions were dynamically selected by Top Speed and fragmented by collision-induced dissociation (CID) using a normalized collision energy of 35%. “EASY-Internal Calibration”, “Peptide Monoisotopic Precursor Selection”, and “Dynamic Exclusion” (10 s duration) were enabled, as was the charge state dependency so that only peptide precursors with charge states from +2 to +4 were selected and fragmented by CID.

For data processing, Tandem mass spectra were searched against the NCBI human database using Proteome Discover v 2.3 from ThermoFisher Scientific. The SEQUEST node parameters were set to use full tryptic cleavage constraints with dynamic methionine oxidation. Mass tolerance for precursor ions was 2 ppm, and mass tolerance for fragment ions was 0.5 Da. A 1% false discovery rate (FDR) was used as a cut-off value for reporting peptide spectrum matches (PSM) from the database search. The mass spectrometry proteomics data were deposited to the ProteomeXchange Consortium via the PRIDE [28] partner repository with the dataset identifier PXD027263.

2.13. Pathway Enrichment Analysis

Proteins with ≥2 peptide hit were included for enrichment analysis. Peptide hit filtered lists were used for the removal of non-specific interactions by comparing D-Biotin to CBD-Biotin protein hits. Reactome pathway enrichment analysis was performed using an online tool named “g:Profiler” to determine pathways associated with proteins spectra retrieved from mass spectrometry [29]. For enrichment analysis, protein accession numbers were fed as an input with a cut off threshold of 0.05 and run-on g:SCS algorithm. g:SCS method is the default method for computing multiple testing correction for p-values gained from GO and pathway enrichment analysis, corresponds to an experiment-wide threshold of a = 0.05, i.e., at least 95% of matches above the threshold are statistically significant. a is the already set probabilty cut off value of 0.05. As a result, enriched pathways are shown as a bar graph between the Reactome pathways identification number/name and negative p-value.

2.14. Densitometry Analysis

ImageJ software was used to conduct densitometry analysis on the kinase and Western blot images. Background measurements were deducted from each lane to account for exposure, followed by normalization of each lane to each respective actin measurement. The control lane (lane 1) was set to 100% to demonstrate a concise increase or decrease for the subsequent lanes. Percentage changes were calculated by subtracting normalized lane measurements from the normalized control lane.

3.2. Cannabidiol Decreases EV-Associated Viral Proteins and Viral RNAs

We have previously shown that despite cART, EVs released from HIV-1 infected cells contain viral proteins and RNA that can elicit detrimental effects in uninfected recipient cells [5,6,9,10]. To verify that cannabinoid treatment not only results in a reduction in EV number, but also a reduction in the presence of viral products, cells were treated twice with a titration of CBD and incubated for 5 days. Following incubation, supernatants were collected, and EVs were enriched using NT80/82 particles, which was previously shown to be effective in enriching EVs from low volume culture supernatant [5,10,23,24,25,32]. Enriched samples were then analyzed by Western blot for the presence of EV marker and HIV-1 viral proteins. The data in Figure 2A show a reduced level of CD81, a tetraspanin protein marker associated with exosomes when treated with CBD (lanes 2–4). The most drastic decrease in CD81 expression was achieved by low titer CBD which resulted in an 80% reduction as indicated by densitometry analysis (lane 2; Supplementary Figure S2A).

The viral protein Nef is reported to be incorporated into EVs from numerous cell types, including astrocytes and microglia. Further evidence identified Nef as a potential contributor to HIV-1 pathogenesis through various mechanisms, including the promotion of secreted proinflammatory cytokines, the suppression of neuronal action potentials, and disruption of the BBB [5,7,33,34,35]. Data in Figure 2A illustrate a dose-dependent decrease in EV-associated Nef (30 kDa) and its membrane-associated myristoylated Nef dimer (70 kDa) when treated with CBD. Densitometry analysis shown in Supplemental Figure 2B,C suggests there is a more drastic decrease in the lower molecular weight form of Nef (up to 79%, lane 3; Supplementary Figure S2C) as compared to the myristoylated dimer (up to 31%, lane 3; Supplementary Figure S2B).

Gp120 can contribute to enhanced HIV-1 infection of the CNS and the corresponding neuroinflammation through disruption of the BBB, increased cytokine secretion, specifically TNFα via activation of microglia and astrocytes, and increased neuronal sensitivity to calcium fluctuation [36,37,38,39,40,41,42,43]. Numerous studies have shown the potential of endogenous cannabinoids, or endocannabinoids, to alleviate gp120-induced neuroinflammation in HIV-1 infection [44]. Therefore, we reasoned that CBD, which targets the same receptors as endocannabinoids, could also result in a reduction in EV-associated gp120. Results in Figure 2A show a reduction in EV-associated gp120 ranging from 39–58% (Supplementary Figure S2D; lanes 3–4) with CBD treatment, suggesting a potential to mitigate the gp120-induced neuropathogenesis.

HIV-1 infection also leads to the incorporation of viral RNAs into EVs released from infected cells. HIV-1 TAR RNA is a short, non-coding RNA produced in infected cells as a result of non-processive transcription. We and others have found TAR RNA incorporated into EVs released from infected cells and can be detected in several biofluids at relatively high copy numbers [5,9,10,12]. TAR within EVs was shown to increase viral pathogenesis through the down-regulation of apoptosis, increased susceptibly to HIV-1 infection, and activation of TLR3 to subsequently stimulate the production of pro-inflammatory cytokines within uninfected recipient cells [9,10]. To determine if CBD possessed the potential to limit the incorporation of such RNAs into EVs, the same supernatants were enriched for EVs using NT80/82 particles, total RNA was isolated and subjected to RT-qPCR for the presence of a short non-coding HIV-1 RNA (TAR), and viral full-length genomic RNA (env). The results in Figure 2B show a dose-dependent decrease in the presence of EV-associated TAR RNA following the addition of CBD (lanes 2–4). All doses of CBD elicited a reduction in TAR RNA as compared to the control (lane 1). A statistically significant decrease in TAR RNA within EVs was observed in the two highest concentrations, which produced an average of 55%, and 86% reduction, respectively, from two replicates. Similarly, treatment with CBD resulted in the reduction of env RNA within EVs (Figure 2C). Taken together, these results indicate that CBD can decrease the number of EVs released from HIV-1 infected cells, which leads to a decrease in the amounts of viral products (protein and RNA) available to contribute to chronic inflammation.

To examine whether the same trend could be observed in a primary cell model, three independent HIV-1 infected primary macrophage cell cultures were treated with a titration of CBD. EVs were enriched from the extracellular supernatant using NT80/82 beads and analyzed for HIV-1 TAR and env (Figure 3). Data in Figure 3A demonstrate a relationship between increasing doses of CBD treatment and a decrease in TAR RNA within EVs from all three infected primary macrophages. Additionally, a similar trend is observed with the amount of env RNA in secreted EVs released from two out of three infected primary macrophages (Figure 3B). A similar trend was observed in EVs from HIV-1 infected primary macrophages treated with cART and CBD (Supplementary Figure S3A,B), and EVs from HIV-1 infected primary T-cells treated with CBD alone (Supplementary Figure S4A,B).

We also focused on using THC as a control and asked whether similar effects of CBD could also be observed when applied to infected cells. We titrated THC and performed zeta view analysis, Western blot and RT/qPCR analysis for EVs concentration, tetraspanin/viral protein markers, and viral RNA, respectively. Data indicated that there was a drop in EVs concentrations (Supplementary Figure S5A–D), CD81, and Nef protein levels (Supplementary Figure S6A) and viral RNAs (Supplementary Figure S6B,C). Interestingly, the greatest reduction of Nef (30 kDa) was achieved by administration of CBD, whereas the greatest reduction of myristoylated Nef dimer (70 kDa) was elicited by THC, potentially suggesting two different mechanisms of EV cargo modification.

Additionally, both cannabinoids elicited a decrease in the presence of the processed envelope glycoprotein, gp120, suggesting that both cannabinoids could potentially interfere with the proteolytic cleavage of HIV-1 precursor polyproteins, potentially through the modulation of intracellular Ca²⁺ levels as the primary endoprotease responsible for cleavage is a calcium-dependent enzyme [45]. Therefore, CBD and/or THC may also contribute to the levels of EVs containing unprocessed glycoprotein and/or defective viral particles.

To apply these findings to in vivo HIV-1 infection, total EVs were enriched from plasma samples from 15 individuals; 5 healthy donors, 5 HIV-1 positive donors, and 5 HIV-1 positive donors who used cannabis were trapped using NT80/82 particles and analyzed via Western blot for the presence of HIV-1 Nef protein. The results in Supplementary Figure S7 show a reduction in the presence of Nef protein in EVs (possibly from CBD component of cannabis) isolated from HIV-1 infected individuals who used cannabis. These results confirm that the cannabinoid CBD has the potential to decrease the release of EVs containing viral products from infected primary cells.

3.3. Cannabidiol Inhibit HIV-1 Transcription in Monocytes

Given that our results indicate a reduction in EV release and EV-associated HIV-1 viral RNAs and proteins, we hypothesized that the observed reduction could be the result of changes in intracellular viral transcription resulting in a decreased production of viral products observed in initially released EVs. Therefore, U1 monocytes were treated with a titration of CBD every day for 5 days. Total RNA was isolated from the harvested cell pellets followed by RT-qPCR analysis of three independent replicates for TAR and env RNAs. Both TAR and env viral RNAs exhibited a dose-dependent decrease in response to CBD treatment (Figure 4A; lanes 2–4 vs. lane 1), with the highest dose resulting in a 95% and 96% decrease as compared to the untreated control. This may indicate that the reduction in secreted EV-associated viral TAR and env RNAs may be the result of CBD-mediated transcription inhibition. Furthermore, the reduction in both TAR and full length genomic (env) RNA suggest that CBD has the potential to inhibit viral transcription at the level of transcription initiation.

To verify that the CBD-mediated transcription inhibition resulted in a decrease in the production of viral proteins within HIV-1 infected cells, U1 cells were treated with a titration of CBD every day for 5 days and intracellular lysate was used for Western blot analysis of specific viral proteins, Nef, Pr55, and p24. As expected, intracellular levels of Nef, Pr55, and p24 proteins were downregulated post-CBD treatment in a dose-dependent manner (Figure 4B). The most significant reduction in all three viral proteins, Pr55 (99%), p24 (76%), and Nef (62%), was observed with the highest concentration of CBD (Supplementary Figure S8A–C). This is potentially due to innate differences in the abundance of these mRNAs. Overall, there were typically fewer gag (Pr55/p24) mRNA transcripts within HIV-1 infected cells as compared to nef mRNAs, which account for nearly 50% of all HIV-1 doubly spliced RNA in infected cells [46].

EVs consist of different subpopulations of vesicles that vary in size, biomarker characterization, and functionality [47,48,49]. Previously, we showed that one of the mechanisms by which exosomes (an EV subpopulation) are released, the endosomal sorting complexes required for transport (ESCRT) pathway, is altered when HIV-1 infected cells are treated with combination antiretroviral therapy (cART) drugs [5]. Briefly, the ESCRT pathway involves a series of interactions between four different ESCRT complexes (-0, -I, -II, -III), which contain a specific set of proteins to recruit exosomal cargo and promote intraluminal vesicular (ILV) budding inside multivesicular bodies (MVBs), as well as a VPS4 complex which disassociates ESCRT complexes post exosomal formation [50]. The observed decrease in CD81 levels, an exosomal biomarker, as a result of CBD treatment and the decrease in EV concentration (Figure 1 and Figure 2), suggest that the ESCRT pathway may be involved in the CBD-mediated changes in EV release and cargo. Western blot analysis of ESCRT proteins showed a slight increase in CHMP6, a protein involved in the ESCRT-III complex, and VPS4, a protein involved in exosomal membrane scission, indicating that the later stages of EV maturation may not be the target of CBD (Figure 4B).

CBD-mediated transcription inhibition was further explored by investigating RNA polymerase II (Pol II) loading activity in comparison to a known transcription inhibitor, Flavopiridol (Flavo), which was shown to inhibit cyclin-dependent kinase 9 (cdk9)/Cyclin T1 complex activity [51,52,53,54]. U1 monocytes were treated with CBD or Flavo for short periods (0, 2 and 6 h) due to the fact that HIV-1 transcription activity is a rapid event that can be scored using chromatin immunoprecipitation (ChIP) assay for transcription factor occupancy. Treated samples were lysed and incubated with IgG control and Pol II (serine 2/5) antibodies for ChIP, followed by qPCR analysis for TAR DNA. Data in Figure 4C show minimal TAR DNA for all of the IgG ChIPs, which served as a negative control. As expected, there was no change in the amount of TAR DNA pulled down with Pol II with any treatment compared to the untreated control at 0 h samples (lanes 1–3). However, both the 2 h and 6 h Pol II pulldown samples showed statistically significant decreases of Pol II-associated TAR DNA when treated with CBD or Flavo in comparison to the untreated samples (lanes 4–6 and lanes 7–9), with Flavo exhibiting more effective inhibition in comparison to CBD. It is also important to note that CBD did not inhibit cdk9/Cyclin T1 activity in vitro, indicating that lower Pol II loading onto DNA may not be related to cdk9/Cyclin T1 kinase activity (data not shown). Collectively, these data indicate that CBD has a partial effect on HIV-1 transcription and Pol II loading. This data emphasizes the potential inhibitory nature of CBD (either direct or indirect) on serine 2/5 phosphorylated Pol II activity of HIV-1 viral transcription in monocytes.

3.4. Cannabidiol Alters Intracellular and Secretory Autophagy Pathways

We previously described a complex relationship between the intracellular autophagy pathway, secretory autophagy pathway, and EVs, where regulation of the autophagy pathway in infected cells can result in the blocking of viral protein degradation and, in turn, the export of viral products through EVs [55]. Based on this, we next asked whether CBD had any effect on EV release by examining the secretory autophagy pathway. In order to evaluate the levels of intracellular autophagy proteins in HIV-1 infected cells, U1 cells were treated with CBD for 0, 6, and 24 h, followed by Western blot analysis for autophagosomal markers, p62 and LC3 I/II (Figure 5A). The data indicates that, over time, there was an increase in autophagosomal p62 production in the untreated samples (lanes 1, 3, and 5). Conversely, a 50% decrease of intracellular p62 with CBD treatment was observed at the 24 h (lane 5 vs. lane 6) timepoint. The normalized densitometry results of intracellular p62 are shown in Supplementary Figure S9. This decrease in SQSTM1/p62 protein, an autophagosome cargo adaptor protein that is degraded upon fusion of the autophagosome with the lysosome, suggests an increased autophagic flux in response to CBD treatment. A decrease in LC3 I levels were also observed in CBD treated samples up to 24 h as compared to the untreated control, suggesting an increased conversion of LC3 I to LC3 II, which is indicative of elongation of the pre-autophagosomal membrane and is critical for the initiation of autophagy. This is further supported by the higher levels of LC3 II in CBD treated samples that are sustained at 6- and 24 h as compared to their respective controls, further indicating active autophagosome formation in CBD treated samples. In order to examine any alterations that CBD might have on secretory autophagy in HIV-1 infected monocytes, EVs were enriched from the supernatants using NT80/82 and analyzed by Western blot for changes in secreted autophagosome proteins. As expected, there was an increase in the levels of extracellular p62 in untreated controls (Supplementary Figure S9D, lanes 1, 3, 5), suggesting an increase in the number of secreted autophagosomes over time as a result of virally mediated autophagy inhibition observed in the intracellular protein levels. This is in line with numerous studies which showed that the HIV-1 viral proteins Tat and Nef are involved in autophagy deregulation in infected cells [56,57]. Furthermore, lower p62 levels were observed with CBD treatment from the 6 h time point onwards compared to the untreated controls (lanes 3, 5 vs. 4, 6, respectively), suggesting an overall decreased secretion of autophagosomes from HIV-1 infected cells. Additionally, there was an overall lower level of LC3 I in EVs secreted from CBD treated cells (lanes 3, 5 vs. 4, 6, respectively). The actin normalized densitometry analysis is shown in Supplementary Figure S9. Taken together, decreased p62 and LC3 levels in both intracellular and in secreted autophagosome vesicles suggests that CBD may activate the autophagy pathway, thereby lowering overall secretory autophagy.

To determine the specific points at which CBD inhibits intracellular and extracellular autophagosome formation and secretion, we compared CBD treatment with known inhibitors of various steps in the autophagy pathway. Cell viability was assessed among a panel of titrated autophagy drugs, and the least toxic concentration per drug was utilized for further analysis (Supplementary Figure S10). Post-titrations, we then treated U1 cells with CBD (10 µM) every day, rapamycin (50 nM), INK128 (50 nM), bafilomycin A1 (50 nM), SB203580 (20 µM), or wortmannin (2 nM) for 5 days. Our rationale for using these drugs was that they regulate different steps of autophagy, including nucleation inhibition by inhibiting MTOR activity (Rapamycin, INK128) or by inhibiting pre-autophagosomal VPS34 complex activity (Wortmannin, SB203580) and autophagosome-lysosome fusion inhibition (Bafilomycin A1) [58,59,60,61]. Therefore, a side-by-side comparison to CBD would potentially allow for a better definition of which step of autophagosome formation is primarily regulated by CBD. U1 cells were treated with the autophagy regulators and harvested along with their corresponding supernatants for further analysis using Western blot against p62, LC3, ATG12-ATG5 complex, free ATG12, Beclin-1, and actin. Results in Figure 5B (intracellular proteins, top panel) show autophagy protein profiles associated with the various autophagy regulators. Interestingly, the autophagy protein profile resulting from treatment with CBD most closely reflected the profile exhibited by cells treated with the autophagy inducers, rapamycin and INK128 (lanes 2–4), as indicated by the low levels of LC3 I and ATG12-ATG5 complex, and by high levels of Beclin-1. The corresponding supernatants were enriched for EVs and also analyzed for the presence of autophagy proteins. Treatment with CBD, rapamycin, and INK128 resulted in a reduction of EV-associated p62 and LC3 I levels (Figure 5B, lower panel, lanes 2–4). Conversely, treatment with autophagy inhibitors, bafilomycin A1, SB203580, and wortmannin (Figure 5B, lower panel, lanes 5–7) resulted in sustained levels of EV-associated p62, elevated levels of LC3 I and -II as compared to the untreated, HIV-1 infected control (lane 1). Little to no change in EV-associated levels of ATG12-ATG5 complex and Beclin-1 was observed with any treatment. The Actin normalized densitometry analysis is shown in Supplementary Figure S11. In order to summarize, a quantitative summary of the change in EVs, viral Proteins and RNA is given in Table 1. Furthermore, we investigated the relationship between CBD and autophagy using a biotinylated-CBD pull-down from U1 monocytes and monocyte-derived macrophages for Mass spectrometry analysis. Tandem mass spectra were searched against the NCBI human database using Proteome Discover, and proteins with ≥2 peptide hit were included for analysis. The background non-specific interactions were removed by comparing D-Biotin to CBD-Biotin protein hits. The protein accession number from the filtered list were fed into “g:Profiler” with a cut off threshold of 0.05 for Reactome pathway enrichment analysis. The results from enrichment analysis showed significant enrichment of proteins in Reactome autophagy pathways (Macrophage: R-HSA-9663891, R-HSA-1236974, R-HSA-1632852, R-HSA-9612973; Monocyte: R-HSA-9646399, R-HSA-9663891, R-HSA-9612973, R-HSA-1632852, R-HSA-9613829, Supplementary Figure S14). Collectively, these data indicate that CBD may promote activation of the autophagy pathway, potentially at the level of upstream mTOR signaling and/or pre-autophagosome formation. This is also supported by studies in several tissues, including mesenchymal stem cells, endothelial cells, neurons, as well as in vitro and mouse models of Parkinson’s and Alzheimer’s Disease [62,63,64,65,66].

We would like to thank all members of the Kashanchi lab, especially Gwen Cox and Michelle Pleet.