| Literature DB >> 34670249 |
Shuang Li1, Bin Su1, Qiu-Shui He2, Hao Wu1, Tong Zhang1.
Abstract
ABSTRACT: A massive depletion of CD4+ T lymphocytes has been described in early and acute human immunodeficiency virus (HIV) infection, leading to an imbalance between the human microbiome and immune responses. In recent years, a growing interest in the alterations in gut microbiota in HIV infection has led to many studies; however, only few studies have been conducted to explore the importance of oral microbiome in HIV-infected individuals. Evidence has indicated the dysbiosis of oral microbiota in people living with HIV (PLWH). Potential mechanisms might be related to the immunodeficiency in the oral cavity of HIV-infected individuals, including changes in secretory components such as reduced levels of enzymes and proteins in saliva and altered cellular components involved in the reduction and dysfunction of innate and adaptive immune cells. As a result, disrupted oral immunity in HIV-infected individuals leads to an imbalance between the oral microbiome and local immune responses, which may contribute to the development of HIV-related diseases and HIV-associated non-acquired immunodeficiency syndrome comorbidities. Although the introduction of antiretroviral therapy (ART) has led to a significant decrease in occurrence of the opportunistic oral infections in HIV-infected individuals, the dysbiosis in oral microbiome persists. Furthermore, several studies with the aim to investigate the ability of probiotics to regulate the dysbiosis of oral microbiota in HIV-infected individuals are ongoing. However, the effects of ART and probiotics on oral microbiome in HIV-infected individuals remain unclear. In this article, we review the composition of the oral microbiome in healthy and HIV-infected individuals and the possible effect of oral microbiome on HIV-associated oral diseases. We also discuss how ART and probiotics influence the oral microbiome in HIV infection. We believe that a deeper understanding of composition and function of the oral microbiome is critical for the development of effective preventive and therapeutic strategies for HIV infection.Entities:
Mesh:
Year: 2021 PMID: 34670249 PMCID: PMC8667981 DOI: 10.1097/CM9.0000000000001825
Source DB: PubMed Journal: Chin Med J (Engl) ISSN: 0366-6999 Impact factor: 2.628
Figure 1Proposed mechanisms of oral microbiome dysbiosis in HIV infection. In health, oral epithelial cells have the capability to maintain microbial colonization. However, disrupted oral immunity, including changes in secretory components in saliva (sIgA, lysozyme, and antimicrobial peptides), deficiency of innate immune responses (macrophages and dendritic cells), and adaptive immune response (CD4+ Th), may cause oral microbiome dysbiosis in HIV infection. Such an imbalance between the oral microbiome and oral immune responses may also contribute to the development of HIV-related oral diseases (periodontal disease) and HIV-associated non-AIDS comorbidities. Periodontal disease is caused by the interplay between pathogenic bacteria and host defense, which can also lead to microbial translocation and an increased risk of systemic conditions. AIDS: Acquired Immune Deficiency Syndrome; HIV: Human immunodeficiency virus; IgA: Immunoglobulin A; IFN-γ: Interferon γ; IL-4: Interleukin-4; Th: T helper.
The oral microbiome in HIV infection.
| Study | Cohort | Samples | Design | Major findings |
| Li | 10 HIV+ subjects prior to and after 6 months of ART 10 HIV− controls | Saliva | Cross-sectional and longitudinal | • Increased oral |
| Beck | 18 HIV+ naive 38 HIV+ ART 80 HIV− | Oral wash | Cross-sectional | • Enrichment of a |
| Saxena | 46 HIV+ subjects before and after ART and 69 HIV− controls 8 HIV+ subjects and 8 HIV− subjects | Saliva | Cross-sectional and longitudinal | • Different microbial compositions among HIV+ subjects before and after ART and HIV− controls • Differences in |
| Arirachakaran | 148 HIV+ ART for >5 years 20 HIV+ untreated 53 vertically transmitted ART HIV+ subjects 30 HIV− controls | Tongue, gingival crevices, and mucosal lesions | Cross-sectional | • Higher frequency and load of opportunistic microorganisms in the ART group and non-ART group than the HIV− controls • Increased |
| Presti | 35 HIV+ subjects prior to and after 6 months of ART | Saliva | Longitudinal | • Higher bacterial richness and diversity in HIV+ subjects with persistently low CD4 counts after 24 weeks of ART • Differences in several taxa, including |
| Starr | 154 perinatally HIV-infected youth 100 perinatally HIV-exposed, uninfected youth | Subgingival plaque | Cross-sectional | • Similar microbiomes in the two cohorts • Two |
| Mukherjee | 48 HIV-infected smokers 24 HIV-infected non-smokers 24 HIV-uninfected smokers | Oral wash | Cross-sectional | • Decreased |
| Gonçalves | 27 HIV+ Brazilian children/teenagers 30 HIV− children/ teenagers | Whole saliva, biofilm from the dorsal surface of the tongue, and biofilm from supragingival and subgingival sites | Cross-sectional | • Higher frequency of the phyla |
| Jiménez-Hernández | 12 viremic ART-untreated 18 immunological ART responders 9 immunological ART non-responders 14 HIV-uninfected controls | Saliva | Cross-sectional and longitudinal | • Higher abundance of potential pathogens as |
| Coker | 94 HIV+ children 98 HIV exposed-uninfected children 94 HIV unexposed/ uninfected children | Saliva | Cross-sectional | • Depletion of eight bacterial taxa, including |
| Griffen | 252 HIV+ ART 89 HIV− | Oral rinse | Cross-sectional | • A complex set of clinical features that influenced oral bacterial community composition, including the presence of HIV under ART |
| Yang | 75 HIV+ ART 93 HIV− | Saliva | Cross-sectional | • Increased |
| Annavajhala | 52 HIV+ ART | Saliva and plaque samples | Cross-sectional and longitudinal | • Bacterial and fungal oral microbiome communities were associated with chronic systemic immune activation in HIV. |
| Li | 20 HIV+ subjects before and after 6 months ART 20 HIV− controls | Saliva | Cross-sectional and longitudinal | • Increased |
| Imahashi | 20 HIV+ Japanese with ART 13 HIV− controls | Saliva | Cross-sectional and longitudinal | • No largely differences in three major genera, |
| Fidel | 149 HIV+ subjects 88 HIV− subjects | Oral rinse | Cross-sectional | • Limited number of species dominated oral mycobiome • Several clinical variables, including HIV positivity and highly active antiretroviral therapy (HAART) affected the oral mycobiome |
| Li | 15 acute HIV-infected subjects before and after ART 15 chronic HIV-infected subjects before and after ART 15 HIV− controls | Throat swabs | Cross-sectional and longitudinal | • Increased |
ART: Antiretroviral therapy; HIV: human immunodeficiency virus.