Why the HIV Reservoir Never Runs Dry: Clonal Expansion and the Characteristics of HIV-Infected Cells Challenge Strategies to Cure and Control HIV Infection

Antiretroviral therapy (ART) effectively reduces cycles of viral replication but does not target proviral populations in cells that persist for prolonged periods and that can undergo clonal expansion. Consequently, chronic human immunodeficiency virus (HIV) infection is sustained during ART by a reservoir of long-lived latently infected cells and their progeny. This proviral landscape undergoes change over time on ART. One of the forces driving change in the landscape is the clonal expansion of infected CD4 T cells, which presents a key obstacle to HIV eradication. Potential mechanisms of clonal expansion include general immune activation, antigenic stimulation, homeostatic proliferation, and provirus-driven clonal expansion, each of which likely contributes in varying, and largely unmeasured, amounts to maintaining the reservoir. The role of clinical events, such as infections or neoplasms, in driving these mechanisms remains uncertain, but characterizing these forces may shed light on approaches to effectively eradicate HIV. A limited number of individuals have been cured of HIV infection in the setting of bone marrow transplant; information from these and other studies may identify the means to eradicate or control the virus without ART. In this review, we describe the mechanisms of HIV-1 persistence and clonal expansion, along with the attempts to modify these factors as part of reservoir reduction and cure strategies.

Clonal hematopoiesis is driven by aberrant activation of TCL1A

A diverse set of driver genes, such as regulators of DNA methylation, RNA splicing, and chromatin remodeling, have been associated with pre-malignant clonal expansion of hematopoietic stem cells (HSCs). The factors mediating expansion of these mutant clones remain largely unknown, partially due to a paucity of large cohorts with longitudinal blood sampling. To circumvent this limitation, we developed and validated a method to infer clonal expansion rate from single timepoint data called PACER (passenger-approximated clonal expansion rate). Applying PACER to 5,071 persons with clonal hematopoiesis accurately recapitulated the known fitness effects due to different driver mutations. A genome-wide association study of PACER revealed that a common inherited polymorphism in the TCL1A promoter was associated with slower clonal expansion. Those carrying two copies of this protective allele had up to 80% reduced odds of having driver mutations in TET2, ASXL1, SF3B1, SRSF2, and JAK2, but not DNMT3A. TCL1A was not expressed in normal or DNMT3A-mutated HSCs, but the introduction of mutations in TET2 or ASXL1 by CRISPR editing led to aberrant expression of TCL1A and expansion of HSCs in vitro. These effects were abrogated in HSCs from donors carrying the protective TCL1A allele. Our results indicate that the fitness advantage of multiple common driver genes in clonal hematopoiesis is mediated through TCL1A activation. PACER is an approach that can be widely applied to uncover genetic and environmental determinants of pre-malignant clonal expansion in blood and other tissues.

Analysis of B cell receptor repertoires reveals key signatures of systemic B cell response after SARS-CoV-2 infection

A comprehensive study of the B cell response against SARS-CoV-2 could be significant for understanding the immune response and developing therapeutical antibodies and vaccines. To define the dynamics and characteristics of the antibody repertoire following SARS-CoV-2 infection, we analyzed the mRNA transcripts of immunoglobulin heavy chain (IgH) repertoires of 24 peripheral blood samples collected between 3 and 111 days after symptom onset from 10 COVID-19 patients. Massive clonal expansion of naïve B cells with limited somatic hypermutation (SHM) was observed in the second week after symptom onset. The proportion of low-SHM IgG clones strongly correlated with spike-specific IgG antibody titers, highlighting the significant activation of naïve B cells in response to a novel virus infection. The antibody isotype switching landscape showed a transient IgA surge in the first week after symptom onset, followed by a sustained IgG elevation that lasted for at least 3 months. SARS-CoV-2 infection elicited poly-germline reactive antibody responses. Interestingly, 17 different IGHV germline genes recombined with IGHJ6 showed significant clonal expansion. By comparing the IgH repertoires that we sequenced with the 774 reported SARS-CoV-2–reactive monoclonal antibodies (mAbs), 13 shared spike-specific IgH clusters were found. These shared spike-specific IgH clusters are derived from the same lineage of several recently published neutralizing mAbs, including CC12.1, CC12.3, C102, REGN10977, and 4A8. Furthermore, identical spike-specific IgH sequences were found in different COVID-19 patients, suggesting a highly convergent antibody response to SARS-CoV-2. Our analysis based on sequencing antibody repertoires from different individuals revealed key signatures of the systemic B cell response induced by SARS-CoV-2 infection. IMPORTANCE Although the canonical delineation of serum antibody responses following SARS-CoV-2 infection has been well established, the dynamics of antibody repertoire at the mRNA transcriptional level has not been well understood, especially the correlation between serum antibody titers and the antibody mRNA transcripts. In this study, we analyzed the IgH transcripts and characterized the B cell clonal expansion and differentiation, isotype switching, and somatic hypermutation in COVID-19 patients. This study provided insights at the repertoire level for the B cell response after SARS-CoV-2 infection.

Staphylococcus aureus injection drug use-associated bloodstream infections are propagated by community outbreaks of diverse lineages

Background The ongoing injection drug use (IDU) crisis in the United States has been complicated by an emerging epidemic of Staphylococcus aureus IDU-associated bloodstream infections (IDU-BSI). Methods We performed a case-control study comparing S. aureus IDU-BSI and non-IDU BSI cases identified in a large US Midwestern academic medical center between Jan 1, 2016 and Dec 21, 2019. We obtained the whole-genome sequences of 154 S. aureus IDU-BSI and 91 S. aureus non-IDU BSI cases, which were matched with clinical data. We performed phylogenetic and comparative genomic analyses to investigate clonal expansion of lineages and molecular features characteristic of IDU-BSI isolates. Results Here we show that patients with IDU-BSI experience longer durations of bacteremia and have lower medical therapy completion rates. In phylogenetic analyses, 45/154 and 1/91 contemporaneous IDU-BSI and non-IDU BSI staphylococcal isolates, respectively, group into multiple, unique clonal clusters, revealing that pathogen community transmission distinctively spurs IDU-BSI. Lastly, multiple S. aureus lineages deficient in canonical virulence genes are overrepresented among IDU-BSI, which may contribute to the distinguishable clinical presentation of IDU-BSI cases. Conclusions We identify clonal expansion of multiple S. aureus lineages among IDU-BSI isolates, but not non-IDU BSI isolates, in a community with limited access to needle exchange facilities. In the setting of expanding numbers of staphylococcal IDU-BSI cases consideration should be given to treating IDU-associated invasive staphylococcal infections as a communicable disease.

Keratoacanthoma, Verruca Vulgaris Arising over Porokeratosis of Mibelli : A New Association

Introduction: This case report highlighting the presence of keratoacanthoma and verruca vulgaris over the lesion of porokeratosis of mibelli. Case Report: In this case a 50-year-old housewife came with large well-defined asymptomatic plaque over the upper part of back of the trunk for last 10 years. After evaluation we got the presence of keratoacanthoma and verruca vulgaris on the plaque of porokeratosis of mibelli. Discussion: Porokeratosis is a clonal expansion of keratinocytes. Among the neoplasm squmous cell carcinoma (SCC) is the most commonly reported malignancy in porokeratosis. But in our case we didn’t find lesion of SCC. Porokeratosis of Mibelli, Keratoacanthoma and Verruca vulgaris have an association with human papilloma virus(HPV). This eithopathogenesis may be related to our clinical finding. Conclusion: There were reporting of squmous cell carcinoma or keratoacanthoma on Porokeratosis of Mibelli. But in our case we found both Keratoacanthoma and Verruca Vulgaris over Porokeratosis of Mibelli. Medicine Today 2021 Vol.33(2): 172-175

Clonotype-Immunophenotype Relationships in TET2 and IDH-Mutant Myeloid Transformation

Large scale molecular profiling studies in AML patients have suggested that stepwise acquisition of somatic mutations is crucial in driving leukemic development. High variant allele frequency (VAF) mutations in epigenetic modifier genes, such as TET2 and IDH1/2, are thought to occur early in AML pathogenesis while oncogenic mutations with typically lower VAF mutations, including FLT3 and NRAS, are suggested to occur late in disease evolution. While bulk DNA sequencing has catalogued co-mutations found in individual AMLs, it cannot unveil the heterogeneity and composition of clones that makes up the disease. Elucidating the architecture and clone-specific molecular profiles at the single cell resolution will be key to understanding how sequential and/or parallel mutation acquisition drives myeloid transformation. To assess the clonal architecture of AML, we previously performed single cell DNA sequencing (scDNA seq) in 146 patients with myeloid malignancies. We have further identified specific mutational combinations driving clonal expansion in TET2- or IDH1/2- mutant AML samples. These studies suggest TET2 and IDH1/2 can cooperate to promote clonal expansion with DNMT3A and NPM1 (Figure 1A). However, TET2 or IDH1/2 mutant clones that acquired KRAS mutations underwent minimal clonal expansion, suggesting mutant-pair specific fitness alterations (Figure 1B). To further identify how co-mutational pairing impacted clonal fitness and differentiation, we integrated the scDNA platform with immunophenotypic profiling of 45 cell surface markers and analyzed new TET2- and IDH1/2- mutant AML samples (Figure 1C). We identified clone-specific differences in lineage markers depending on co-mutational partners. NPM1 co-mutant clones were enriched for more primitive markers (CD33), whereas NRAS co-mutant clones possessed high expression of myeloid differentiation markers (CD14/CD11b), suggestive of clone-specific fitness landscapes across hematopoietic differentiation. We also identified divergent clonotype-immunophenotype patterns in TET2- and IDH2-mutant clones harboring NPM1/RAS mutations, suggesting that initiating mutations may prime mutant clones for very different evolutionary trajectories as they acquire similar mutations in leukemogenesis (Figure 1D). To deterministically delineate the relationship between clonal evolution and myeloid transformation, we generated Cre-inducible single (Tet2 -/-), double (Tet2 -/-/Nras G12Dand Tet2 -/-/Npm1 cA/wt), and triple (Tet2 -/-/Npm1 cA/wt/Nras G12D) mutant mice and evaluated differences in chimerism, immunophenotype, and survival. We observed a shortened survival for double and triple mutant mice, compared to Tet2 -/- only mice (Figure 1E). As previously reported, Tet2 -/-/Nras G12D mice developed a CMML-like phenotype. Critically, the addition of Npm1 resulted in a more rapid disease onset and transformation to AML (Figure 1F). Moreover, triple mutant WBM transplanted to form a fully penetrant disease into secondary recipients, while double mutant Tet2 -/-/Nras G12D WBM failed to form disease within 3 months of transplant, suggesting a difference in the cell population responsible for disease propagation. Immunophenotypic alterations were evident with Tet2 -/-/ Nras G12D displaying an increase in Mac1 +Gr1 + cells compared to Tet2 -/-/Npm1 cA/wt/Nras G12D mice which possessed increased Mac1 +Gr1 - cells and expansion of lineage negative cells (Figure 1G). These findings align with the clonotype specific expression patterns observed in clinical specimen and suggest that myeloid transformation and maturation biases are influenced by specific mutational combinations. Figure 1 Figure 1. Disclosures Miles: Mission Bio: Honoraria, Speakers Bureau. Bowman: Mission Bio: Honoraria, Speakers Bureau. Carroll: Janssen Pharmaceutical: Consultancy; Incyte Pharmaceuticals: Research Funding. Levine: Astellas: Consultancy; Janssen: Consultancy; Auron: Membership on an entity's Board of Directors or advisory committees; Amgen: Honoraria; QIAGEN: Membership on an entity's Board of Directors or advisory committees; Mission Bio: Membership on an entity's Board of Directors or advisory committees; Isoplexis: Membership on an entity's Board of Directors or advisory committees; Celgene: Research Funding; Incyte: Consultancy; Imago: Membership on an entity's Board of Directors or advisory committees; Roche: Honoraria, Research Funding; Prelude: Membership on an entity's Board of Directors or advisory committees; Ajax: Membership on an entity's Board of Directors or advisory committees; Zentalis: Membership on an entity's Board of Directors or advisory committees; Gilead: Honoraria; C4 Therapeutics: Membership on an entity's Board of Directors or advisory committees; Lilly: Honoraria; Morphosys: Consultancy.