Abstract
HIV-associated neurocognitive disorders are common in HIV-infected individuals, even in the combination antiretroviral therapy (c-ART) era. Several mechanisms are involved in neuronal damage, including chronic inflammation immune activation. Mammalian 2′-5′-oligoadenylate synthetase (OAS) genes are produced in response to interferon (IFN), mainly by monocytes, and exert their antiviral functions by activation of RNase L that degrades viral and cellular RNAs. In this study, we aimed at exploring OAS gene family RNA expression in simian immunodeficiency virus encephalitis (SIVE), in HIV-associated neurocognitive disorders (HAND), and in HIV-associate dementia (HAD). We analyzed three microarray datasets obtained from the NCBI in order to assess the expression levels of OAS gene family network in brain biopsies of macaques with SIVE vs uninfected animals, as well as post-mortem brain of individuals with HAND (on or off ART) vs uninfected controls and three brain regions of HIV-infected individuals with both neurocognitive impairment (HAD) and encephalitis (HIVE). All OAS genes were upregulated both in SIVE and in HAND. OAS expression was significantly higher in high-viremic individuals; increased expression levels persisted in cART subjects when compared to healthy controls. OAS gene network analysis showed that several genes belonging to the type I IFN pathway, especially CXCL10 and IFIT3, were similarly upregulated in SIVE/HAND. Furthermore, we identified a significant upregulation of OAS gene family RNA expression in basal ganglia, white matter, and frontal cortex of HIV-1, HAD, and HAD/HIVE patients compared to healthy subjects. OAS gene family expression is increased in brain sections from individuals with HAND, HAD, and HIVE as well as macaques with SIVE. OAS family expression is likely to be induced by IFN as a consequence of viral replication in the CNS. Its long-term upregulation may contribute to the chronic inflammatory status and neurocognitive impairment we still observe in virologically suppressed individuals on c-ART.
Similar content being viewed by others
Avoid common mistakes on your manuscript.
Introduction
The introduction of combination antiretroviral therapy (c-ART) has transformed human immunodeficiency virus (HIV) infection in a chronic disease. Despite the dramatic reduction in the prevalence of AIDS-related morbidity and mortality, HIV-infected individuals are at increased risk of non-AIDS-related comorbidities, including cardiovascular, renal, and bone disease, as well as malignancies and neurocognitive impairment [1–6]. Though c-ART has significantly reduced the prevalence of HIV-associated dementia and central nervous system (CNS) opportunistic infections, it is estimated that up to 50% of HIV-patients have mild forms of HIV-associated neurologic disease (HAND), known as asymptomatic neurocognitive impairment (ANI) and mild neurocognitive disorder (MND) [6]. The events leading to neuronal injury are multifaceted and not only related to the direct neurotoxicity of the virus.
Monocyte/macrophages are the main cell type that infiltrates the CNS during HIV infection [7]. Blood-born infected monocytes are able to migrate to the CNS through the blood-brain barrier (BBB) and lead to neuronal damage and loss. Once migrated in the CNS, those cells can live for a long time in the brain as resident macrophages, where they are thought to contribute to the establishment of a reservoir and the promotion of the inflammatory cascade [7]. In fact, impaired neurocognition has been associated with increased production of inflammatory cytokines, such as interleukin IL-6 and interferon IFN-γ, and proteins related with monocyte activation/chemotaxis (soluble CD14, CXCL10, CCL3, MCP-1) in the cerebrospinal fluid (CSF) of HIV-positive subjects on c-ART. The release of inflammatory cytokines promotes neuronal damage and death as well as the expression of adhesion molecules on the brain microvascular endothelium, which recruit more monocytes to the BBB [7]. Similarly, in the setting of advanced HIV infection, c-ART-naive individuals with HAND have been reported to have higher levels of inflammatory chemokines and cytokines than those without HAND, with similar plasma viral load [8]. Globally, these findings suggest the importance of host immune responses, and in particular innate immunity, in HAND pathogenesis.
The 2′-5′-oligoadenylate synthetases (OAS) are IFN-stimulated proteins belonging to a highly conserved family, which consists of four members, OAS1, OAS2, OAS3, and OAS-like protein (OASL). OAS proteins are induced by type I IFN and have been shown to play an important role in innate immune responses. In fact, OASs have antiviral functions, as they act as nucleotidyltransferases, catalyzing the synthesis of 2′-5′-linked oligoadenylates, which leads to the activation of RNAse L and finally to the degradation of viral and cellular RNAs [9, 10].
Considering the role of innate immunity in the pathogenesis of HIV-related neurocognitive disorders, in the present study, we aimed at exploring the correlation between OAS gene family RNA expression and the presence of neurocognitive disorders in the setting of HIV/simian immunodeficiency virus (SIV) infection, by analyzing three microarray datasets obtained from the NCBI.
Methods
Bioinformatics Analysis Tools
For this paper, we analyzed microarray datasets from the NCBI Gene Expression Omnibus (GEO, http://www.ncbi.nlm.nih.gov/geo/) databank under accession number GSE13824, GSE28160 and GSE35864, in order to define a correlation between the OAS gene family network and molecular events of neurological impairment and inflammation associated with HIV infection in the brain regions. From the GSE13824 microarray dataset, we selected the data from the hippocampal region of nine male monkeys with simian immunodeficiency virus encephalitis (SIVE) (used in biological replicate) and nine male healthy controls (used in biological replicate). The author stated that all SIV-infected monkeys had neuropathological evidence of SIVE. SIV-infected monkeys were sacrificed after development of SIVE (median time 93 days post-inoculation) (IQR 56–132). Rhesus macaques-SIV encephalitis (SIVE) is a standard model used to study human HIV-associated dementia (HAD), occurring in patients with advanced HIV. The brain viral load (BVL) was determined on a sample of frontal lobe, containing both gray and white matter, and is given in log viral genome equivalents per microgram RNA. Complete experimental details can be retrieved in the publication by Gersten et al. [11].
To confirm the results obtained with GSE13824, we also analyzed a human microarray dataset (GSE28160). From GSE28160 microarray dataset, we selected the data of post-mortem brain of c-ART-treated (n = 7 and 5 biological replicate) and untreated (n = 8 and 6 biological replicate) HIV-infected patients with neurocognitive disorders (HAND) and healthy subjects (n = 6 and 3 biological replicates). The authors stated that the brain biopsies were obtained from the centrum semiovale (deep white matter) at the coronal level of the genu of the corpus callosum. Complete experimental details can be retrieved in the publication by Borjabad et al. [12].
We decided to extend the analysis of OAS gene expressions to the subjects affected by HIV-associated dementia (HAD). To achieve these results, we selected a human microarray dataset (GSE35864) consisting of three brain regions (basal ganglia, white matter, and frontal cortex) of 24 human subjects dived in four groups (healthy, HIV-infected, HIV-infected with neurocognitive impairment, and HIV-infected with both neurocognitive impairment and encephalitis patients). Complete experimental details can be retrieved in the publication by Gelman et al. [13].
The MultiExperiment Viewer (MeV) software was used to identify differentially expressed genes. In cases where multiple probes insisted on the same NCBI GeneID, we used those with the highest variance. By restricting the threshold level of significance to p < 0.01 and log2 fold to 1.5, for GSE13824, we identified 3426 significant upregulated and 4416 downregulated genes in hippocampus SIVE vs healthy monkeys. For GSE28160, we identified 3426 significant upregulated and 4643 downregulated genes in untreated HAND brain vs healthy subjects. As regard GSE35864, comparing all brain sections, we obtained 2285 significant upregulated and 39 downregulated genes in healthy vs HIV-infected patients (Supplementary Table1). In order to identify genes commonly modulated in OAS gene network and hippocampus SIVE, HAD, or HAND, Venn diagrams were drawn using the Web-based utility Venn Diagram Generator (http://www.bioinformatics.lu). Weighted Gene Networks were built for the commonly modulated genes using STRING software (http://string-db.org/) [14] and GIANT software (http://giant.princeton.edu/) [15]. The STRING combined score was based on data from Neighbourhood in the Genome, Gene Fusions, Co-occurance Across Genomes, Co-Expression, Experimental/Biochemical Data, and Association in Curated Databases.
The OAS gene pathway was obtained from the GIANT database (http://giant.princeton.edu/) setting the tissue menu in Hippocampus, the Network filter with Minimum relationship confidence 0.18 and Maximum number of genes in 50. The relationship confidence score (Edge score) indicates how two genes are significantly coexpressed in the same tissue. Scores corresponded to edges with a tissue-network interaction probability greater than the naive-network probability. High values of Edge score correspond to high index of coexpression in the same tissue [15].
Biological pathway, biological process, heatmap cell localization, and analysis of KEGG pathways was performed with FunRich tool (http://www.funrich.org) against human FunRich background database [16].
Statistical Analysis
For statistical analysis, Prism 7 software (GraphPad Software, USA) was used. Based on Shapiro-Wilk test, almost all data were skewed, so nonparametric tests were used. Significant differences between groups were assessed using the Mann–Whitney U test, and Kruskal-Wallis test was performed to compare data between all groups followed by Dunn’s post hoc test. Correlations were determined using Spearman’s ρ correlation. All tests were two-sided and significance was determined at P < 0.05. To analyze a 2 × 2 contingency table, a chi-squared with Yates correction was performed by GraphPad Prism software (http://graphpad.com/quickcalcs/contingency1.cfm). The association between rows (groups) and columns (outcomes) with p < 0.0001 was considered to be extremely statistically significant.
Results
High Expression Levels of OAS mRNA in SIV-Infected Hippocampus
The GSE13824 analysis was performed in order to determine the expression levels of OAS gene family RNA expression in the hippocampus of monkeys with SIVE. The mRNA levels of OAS1, OAS2, OAS3, and OASL were significantly higher in animals with SIVE compared to healthy controls (p < 0.0001) (Fig. 1). Also, we showed a significant upregulation of RNAseL mRNA in SIV-infected hippocampus compared to healthy control (p < 0.001) (Supplementary Fig. 1).
We found a neat separation between the two groups, as none of the expression values of OAS mRNA in the healthy group was in the expression range of the SIVE group. No significant correlation was observed between the BVL and the OAS mRNA expression levels (Supplementary Fig. 2A). On the contrary, all the OAS mRNA were positively correlated one with the other (Supplementary Fig. 2B).
OAS Gene Network Is Significantly Expressed in SIV-Infected Hippocampus
In order to define a “OAS gene network,” the GIANT software was interrogated. The analysis in the selected tissue (i.e., hippocampus) identified 50 genes significant coexpressed to OAS genes (Supplementary Fig. 3A). Positive regulation of response to virus (p value, FDR corrected 9.80e−9) (GO-BP-0009615), viral life cycle (p value, FDR corrected 1.21e−8) (GO-BP-0019058), and viral process (p value, FDR corrected 2.88e−8) (GO-BP-0016032) was found in enriched Pathways/Processes/Diseases.
The 50 genes obtained by the GIANT analysis were compared to the 3426 genes that were significantly upregulated in SIVE hippocampus vs healthy animal control (Fig. 2a). Among these 50 genes, 33 (61%) were similarly upregulated in the SIVE group vs healthy animal controls (p < 0.0001 by chi-square with Yates’ correction) and 21 (38%) unequivocally belonged to the OAS gene network (Fig. 2a). No significantly common genes to the OAS gene network were observed among the list of downregulated genes (Supplementary Fig. 3b).
This list of upregulated genes included 12 genes coexpressed to the type I IFN pathway (FDR = 8.31e−19) (STRING analysis) (Fig. 2b). The most upregulated mRNA genes were two IFN-induced molecules, CXCL10 (also known as Interferon gamma-induced protein 10) (Fig. 2c), and IFIT3 (Fig. 2d). Both CXCL10 and IFIT3 mRNA were significantly correlated with the expression levels of OAS mRNA in the GSE13824 dataset (Supplementary Fig. 4A/B).
The GIANT/STRING analysis showed that CXCL10 was only directly coexpressed to OAS1 (combined score 0.430) without intermediate genes (Fig. 2b) (Supplementary Fig. 3A). As for IFIT3, we found that it was directly coexpressed to OAS1 (combined score 0.959), OAS2 (combined score 0.950), OAS3 (combined score 0.940), and OASL (combined score 0.961) (Fig. 2b) (Supplementary Fig. 3A).
The FunRich analysis of 33 query genes common to the OAS gene network and SIVE showed that 36.4% of these genes were significantly modulated by type I/II IFN pathways (p < 0.001) (Fig. 3a). Two significant biological process were highlighted, the immune response (30.3%, p < 0.001) and apoptosis (12.1%, p < 0.001) (Fig. 3b). The tissue and cell localization analysis showed a pleiotropic expression of OAS genes in CD4 T cells, CD8 T cells, natural killer cells, and high expression in monocytes (Fig. 3c). Finally, the KEGG pathway analysis showed different viral pathways connected to the 33 query genes (influenza A 29%; measles 23%; herpes simplex 19%; hepatitis C 16%) (Fig. 3d).
OAS Gene Family RNA Expression Are Significantly Upregulated in the Brain Sections of HAND and HAD/HIVE Patients
To validate the results obtained from the GSE13824 analysis, we used further microarrays, GSE28160, containing data on individuals with HAND. We evaluated which genes were similarly upregulated in SIVE (3426 upregulated genes, GSE13824) or HAND (3136 upregulated genes, GSE28160) vs the 50 genes belonging to the OAS gene network (Fig. 4a). The GSE28160 microarray contained two groups of brain samples: 15 HIV-infected patients with HAND and six HIV-negative subjects with neither neurological nor neuropathological abnormalities. Seven out of 15 HIV-positive patients were receiving c-ART therapy. The Venn diagram analysis showed that among the 50 genes belonging to the OAS gene network, 27 (50%) were in common with the SIVE and HAND network (p < 0.0001) (Fig. 4a), including CXCL10 and IFIT3 (Fig. 4b). Of the OAS gene network, 81.4% (44 genes) were significantly upregulated in HAND and 61.2% (33 genes) in SIVE (as shown previously) (Fig. 4a) (Supplementary Table 1).
The analysis confirmed that OAS1, OAS2, OAS3, and OASL mRNA were significantly upregulated in the brain of patients with HAND with high blood viral load compared to healthy controls (Fig. 5). OAS gene family RNA expression levels were significantly reduced in patients on c-ART therapy (Fig. 5a–d). No significant correlation was observed between OAS gene mRNA expression and blood viral load, as well as CD4 T-cell count (data not shown).
Similar results were obtained analyzing the GSE35864 dataset. During the exploration of OAS gene family RNA expression in basal ganglia, white matter, and frontal cortex of HIV-1, HAD, and HAD/HIVE patients, we identified a significant upregulation in HAD/HIVE patients compared to healthy subjects (Supplementary Fig. 5) (Supplementary Table 1). The OAS2 mRNA expressions levels were not significant only in frontal cortex of HAD/HIVE patients (Supplementary Fig. 5B). The Venn diagram analysis showed that among the 50 genes belonging to the OAS gene network, 34 (68%) were in common with the significant upregulated genes in HAD/HIVE vs healthy individuals (p < 0.0001 by chi-square with Yates’ correction) (Supplementary Fig. 6A). No genes were found comparing the significantly downregulated genes in HAD/HIVE vs healthy individuals and OAS gene network (data not shown). In addition, we showed that all OAS genes were significantly upregulated in the three GSE dataset analyzed (Supplementary Fig. 6B).
Discussion
In our microarray analysis, we found that OAS genes were significantly upregulated both in SIVE, HAND, and HAD/HIVE, and that several genes belonging to the OAS network, especially CXCL10 and IFT3, were highly expressed in the setting of SIVE/HAND. Moreover, the OAS gene expressions were significantly higher in c-ART-naive patients with HAND in comparison to virologically suppressed ones. Furthermore, in HAD/HIVE patients’ brain region, the OAS gene expression was significantly upregulated.
Innate immunity has been reported to play a crucial role in the development of neurocognitive disorders in HIV infection. Though the mechanisms of neuronal damage have not been fully explained, it is known that monocyte/macrophages are involved not only in early viral spread to the CNS and viral persistence in the brain, but also in the release of inflammatory cytokines and chemokines, including IFNs, which leads in turn to chronic immune activation and neurocognitive decline [7].
From this perspective, it can be hypothesized that the presence of HIV RNA in the CNS may be responsible for the release of several IFN-induced molecules, including OAS proteins. OASs are nucleotidyltransferases which exert their antiviral functions by stimulating the degradation of RNAs. OAS genes are induced by double-stranded RNAs and IFN, and they are mainly expressed by monocytes [9, 10]. In a recent study, increased expression of OAS gene family was reported in monocytes from HIV-infected high-viremic subjects [10]. Moreover, human macrophages treated with IFN-tau have been shown to increase the synthesis of OAS/RNase L [17].
Few studies have evaluated the expression of OAS gene family in HIV infection. In a report exploring immune responses to SIV in Rhesus macaques after oral infection, the authors found that CXCL10 and OAS genes were upregulated both in the lymph nodes and peripheral blood [18]. In the peripheral blood, OAS upregulation was similar for high- and low-dose infection, while in lymph nodes increased OAS mRNA was observed only when animals were infected with high-dose virus. As expected, the authors identified CD14+ monocytes as the major producers of OAS [18]. Interestingly, the same group found that increased expression of OAS and CXCL10 at the oral and rectal mucosa of macaques was associated with slower disease progression while increased expression of OAS and CXCL10 in lymph nodes and peripheral blood was associated with rapid clinical progression [19]. This discrepancy can be due to the differential increase of one or more cell types migrating to different sites and expressing these molecules. The high mucosal levels of CXCL10 and OAS may represent the attempt of the immune system to stimulate early adaptive responses, while the high levels observed in the lymph nodes can play a detrimental role, bursting immune activation and disease progression. The association between untreated infection and elevated CXCL10 levels has been reported by several groups: Sarkar et al. have shown that macaques with high viral load have an increased frequency of CXCL10-producing cells compared to low-viremic animals [20]. Similarly, patients with HIV have increased circulating levels of CXCL10 compared to uninfected controls [21]; moreover, elevated CXCL10 have been reported in the CSF of subjects with AIDS-dementia complex [22]. As for OAS expression, a report from Read et al. has shown increased circulating OAS levels to predict the risk of progression to AIDS [23].
In the CNS, chronic IFN stimulation, with the subsequent dysregulation of IFN-stimulated genes, is likely to play a crucial role in neuropathogenesis [12, 24]. In fact, IFN-α is known to induce the production of IL-10 by recruiting CXCL10 and Stat3. IL-10, together with macrophage colony-stimulating factor (M-CSF), can drive the development of CD14+/CD16+ monocytes. These CD14+CD16+ monocytes have an increased frequency in HIV-infected subjects, especially those with dementia [25]. Moreover, M-CSF may induce the differentiation of monocytes toward M2-macrophages, with potential important consequences in the induction of CNS damage, as M2-cells are preferentially infected with HIV [26]. Taken together, these results suggest IFN-induced production of antiviral molecules, including OAS proteins, represents the attempt of the immune system to contain HIV replication in the brain; however, chronic induction of these pro-inflammatory pathways is likely to have a significant impact on the development of neurocognitive impairment and immune dysfunction, even after starting c-ART, as confirmed by our finding of persistently increased OAS levels in virologically suppressed individuals compared to uninfected controls.
In conclusion, we found that OAS genes are upregulated both in SIVE and HAND. As OASs are mainly produced in response to IFN by monocytes/microglia, these findings suggest their involvement in the innate immune responses to HIV (Fig. 6). In addition, we found that OAS upregulation is reduced but not normalized after starting c-ART, suggesting that chronic induction of IFN pathways may have a role in the development of neuroimpairment. OAS molecules may potentially represent a new target for immune-modulatory strategies aiming at reducing CNS chronic inflammation and immune activation, which still occur even in the setting of effective c-ART.
Abbreviations
- c-ART:
-
Combination antiretroviral therapy
- HAART:
-
Highly active anti-retroviral therapy
- AIDS:
-
Acquired immune deficiency syndrome
- CNS:
-
Central nervous system
- HIV:
-
Human immunodeficiency virus
- SIV:
-
HIV/simian immunodeficiency virus
- SIVE:
-
Simian immunodeficiency virus encephalitis
- HAND:
-
HIV-associated neurocognitive disorders
- HAD:
-
HIV-infected with neurocognitive impairment or HIV associate dementia
- ANI:
-
Asymptomatic neurocognitive impairment
- HIVE:
-
HIV encephalitis
- BBB:
-
Blood-brain barrier
- CSF:
-
Cerebrospinal fluid
- CXCL10:
-
C-X-C motif chemokine 10
- FDR:
-
False discovery rate
- IFIT3:
-
Interferon-induced protein with tetratricopeptide repeats 3
- OAS1:
-
2′-5′-Oligoadenylate synthetase 1
- OAS2:
-
2′-5′-Oligoadenylate synthetase 2
- OAS3:
-
2′-5′-Oligoadenylate synthetase 3
- OASL:
-
2′-5′-Oligoadenylate synthetase-like
- MeV:
-
MultiExperiment Viewer
- IQR:
-
Interquartile range
- BVL:
-
Brain viral load
References
Scarpino M, Pinzone MR, Di Rosa M, Madeddu G, Foca E, Martellotta F, Schioppa O, Ceccarelli G et al (2013) Kidney disease in HIV-infected patients. European review for medical and pharmacological sciences 17(19):2660–2667
Castronuovo D, Cacopardo B, Pinzone MR, Di Rosa M, Martellotta F, Schioppa O, Moreno S, Nunnari G (2013) Bone disease in the setting of HIV infection: update and review of the literature. European review for medical and pharmacological sciences 17(18):2413–2419
Pinzone MR, Berretta M, Cacopardo B, Nunnari G (2015) Epstein-barr virus- and Kaposi sarcoma-associated herpesvirus-related malignancies in the setting of human immunodeficiency virus infection. Semin Oncol 42(2):258–271. doi:10.1053/j.seminoncol.2014.12.026
Pinzone MR, Fiorica F, Di Rosa M, Malaguarnera G, Malaguarnera L, Cacopardo B, Zanghi G, Nunnari G (2012) Non-AIDS-defining cancers among HIV-infected people. European review for medical and pharmacological sciences 16(10):1377–1388
Nunnari G, Berretta M, Pinzone MR, Di Rosa M, Berretta S, Cunsolo G, Malaguarnera M, Cosentino S et al (2012) Hepatocellular carcinoma in HIV positive patients. European review for medical and pharmacological sciences 16(9):1257–1270
Heaton RK, Clifford DB, Franklin DR Jr, Woods SP, Ake C, Vaida F, Ellis RJ, Letendre SL et al (2010) HIV-associated neurocognitive disorders persist in the era of potent antiretroviral therapy: CHARTER Study. Neurology 75(23):2087–2096. doi:10.1212/WNL.0b013e318200d727
Hong S, Banks WA (2015) Role of the immune system in HIV-associated neuroinflammation and neurocognitive implications. Brain Behav Immun 45:1–12. doi:10.1016/j.bbi.2014.10.008
Airoldi M, Bandera A, Trabattoni D, Tagliabue B, Arosio B, Soria A, Rainone V, Lapadula G et al (2012) Neurocognitive impairment in HIV-infected naive patients with advanced disease: the role of virus and intrathecal immune activation. Clinical & developmental immunology 2012:467154. doi:10.1155/2012/467154
Kristiansen H, Gad HH, Eskildsen-Larsen S, Despres P, Hartmann R (2011) The oligoadenylate synthetase family: an ancient protein family with multiple antiviral activities. Journal of interferon & cytokine research : the official journal of the International Society for Interferon and Cytokine Research 31(1):41–47. doi:10.1089/jir.2010.0107
Fagone P, Nunnari G, Lazzara F, Longo A, Cambria D, Distefano G, Palumbo M, Nicoletti F et al (2016) Induction of OAS gene family in HIV monocyte infected patients with high and low viral load. Antivir Res 131:66–73. doi:10.1016/j.antiviral.2016.04.009
Gersten M, Alirezaei M, Marcondes MC, Flynn C, Ravasi T, Ideker T, Fox HS (2009) An integrated systems analysis implicates EGR1 downregulation in simian immunodeficiency virus encephalitis-induced neural dysfunction. The Journal of neuroscience : the official journal of the Society for Neuroscience 29(40):12467–12476. doi:10.1523/JNEUROSCI.3180-09.2009
Borjabad A, Morgello S, Chao W, Kim SY, Brooks AI, Murray J, Potash MJ, Volsky DJ (2011) Significant effects of antiretroviral therapy on global gene expression in brain tissues of patients with HIV-1-associated neurocognitive disorders. PLoS Pathog 7(9):e1002213. doi:10.1371/journal.ppat.1002213
Gelman BB, Chen T, Lisinicchia JG, Soukup VM, Carmical JR, Starkey JM, Masliah E, Commins DL et al (2012) The National NeuroAIDS Tissue Consortium brain gene array: two types of HIV-associated neurocognitive impairment. PLoS One 7(9):e46178. doi:10.1371/journal.pone.0046178
Szklarczyk D, Franceschini A, Wyder S, Forslund K, Heller D, Huerta-Cepas J, Simonovic M, Roth A et al (2015) STRING v10: protein-protein interaction networks, integrated over the tree of life. Nucleic Acids Res 43(Database issue):D447–D452. doi:10.1093/nar/gku1003
Greene CS, Krishnan A, Wong AK, Ricciotti E, Zelaya RA, Himmelstein DS, Zhang R, Hartmann BM et al (2015) Understanding multicellular function and disease with human tissue-specific networks. Nat Genet 47(6):569–576. doi:10.1038/ng.3259
Pathan M, Keerthikumar S, Ang CS, Gangoda L, Quek CY, Williamson NA, Mouradov D, Sieber OM et al (2015) FunRich: an open access standalone functional enrichment and interaction network analysis tool. Proteomics 15(15):2597–2601. doi:10.1002/pmic.201400515
Maneglier B, Rogez-Kreuz C, Dereuddre-Bosquet N, Martal J, Devillier P, Dormont D, Clayette P (2008) Anti-HIV effects of IFN-tau in human macrophages: role of cellular antiviral factors and interleukin-6. Pathologie-biologie 56(7–8):492–503. doi:10.1016/j.patbio.2008.06.002
Durudas A, Chen HL, Gasper MA, Sundaravaradan V, Milush JM, Silvestri G, Johnson W, Giavedoni LD et al (2011) Differential innate immune responses to low or high dose oral SIV challenge in rhesus macaques. Curr HIV Res 9(5):276–288
Durudas A, Milush JM, Chen HL, Engram JC, Silvestri G, Sodora DL (2009) Elevated levels of innate immune modulators in lymph nodes and blood are associated with more-rapid disease progression in simian immunodeficiency virus-infected monkeys. J Virol 83(23):12229–12240. doi:10.1128/JVI.01311-09
Sarkar S, Kalia V, Murphey-Corb M, Montelaro RC, Reinhart TA (2003) Expression of IFN-gamma induced CXCR3 agonist chemokines and compartmentalization of CXCR3+ cells in the periphery and lymph nodes of rhesus macaques during simian immunodeficiency virus infection and acquired immunodeficiency syndrome. J Med Primatol 32(4–5):247–264
Stacey AR, Norris PJ, Qin L, Haygreen EA, Taylor E, Heitman J, Lebedeva M, DeCamp A et al (2009) Induction of a striking systemic cytokine cascade prior to peak viremia in acute human immunodeficiency virus type 1 infection, in contrast to more modest and delayed responses in acute hepatitis B and C virus infections. J Virol 83(8):3719–3733. doi:10.1128/JVI.01844-08
Cinque P, Bestetti A, Marenzi R, Sala S, Gisslen M, Hagberg L, Price RW (2005) Cerebrospinal fluid interferon-gamma-inducible protein 10 (IP-10, CXCL10) in HIV-1 infection. J Neuroimmunol 168(1–2):154–163. doi:10.1016/j.jneuroim.2005.07.002
Read SE, Williams BR, Coates RA, Evans WK, Fanning MM, Garvey MB, Shepherd FA (1985) Elevated levels of interferon-induced 2'-5' oligoadenylate synthetase in generalized persistent lymphadenopathy and the acquired immunodeficiency syndrome. The Journal of infectious diseases 152(3):466–472
Pulliam L (2014) Cognitive consequences of a sustained monocyte type 1 IFN response in HIV-1 infection. Curr HIV Res 12(2):77–84
Pulliam L, Gascon R, Stubblebine M, McGuire D, McGrath MS (1997) Unique monocyte subset in patients with AIDS dementia. Lancet 349(9053):692–695. doi:10.1016/S0140-6736(96)10178-1
Kalter DC, Nakamura M, Turpin JA, Baca LM, Hoover DL, Dieffenbach C, Ralph P, Gendelman HE et al (1991) Enhanced HIV replication in macrophage colony-stimulating factor-treated monocytes. J Immunol 146(1):298–306
Author information
Authors and Affiliations
Corresponding author
Ethics declarations
Conflict of Interest
The authors declare that they have no conflict of interest.
Electronic supplementary material
Supplementary Figure 1
(GIF 14Â kb)
Supplementary Figure 2
(GIF 43Â kb)
Supplementary Figure 3
(GIF 276Â kb)
Supplementary Figure 4
(GIF 60Â kb)
Supplementary Figure 5
(GIF 82Â kb)
Supplementary Figure 6
(TIFF 104Â kb)
Supplementary Table 1
(XLSX 7355Â kb)
Rights and permissions
About this article
Cite this article
Sanfilippo, C., Pinzone, M., Cambria, D. et al. OAS Gene Family Expression Is Associated with HIV-Related Neurocognitive Disorders. Mol Neurobiol 55, 1905–1914 (2018). https://doi.org/10.1007/s12035-017-0460-3
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s12035-017-0460-3