Distinct transcriptional and epigenomic programs define Hofbauer cells in term placenta
Benjámin R. Baráth, Dóra Bojcsuk, Krisztian Bene, Noemí Caballero-Sánchez, Tímea Cseh, João CR. de Freitas, Petros Tzerpos, Marta Toth, Zhonghua Tang, Seth Guller, Zoárd Tibor Krasznai, Patrícia Neuperger, Gabor J. Szebeni, Gergely Nagy, Tamás Deli, Laszlo Nagy
Benjámin R. Baráth, Dóra Bojcsuk, Krisztian Bene, Noemí Caballero-Sánchez, Tímea Cseh, João CR. de Freitas, Petros Tzerpos, Marta Toth, Zhonghua Tang, Seth Guller, Zoárd Tibor Krasznai, Patrícia Neuperger, Gabor J. Szebeni, Gergely Nagy, Tamás Deli, Laszlo Nagy
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Research Article Immunology Reproductive biology

Distinct transcriptional and epigenomic programs define Hofbauer cells in term placenta

Abstract

Hofbauer cells (HBCs) are fetal macrophages located in the placenta that contribute to antimicrobial defense, angiogenesis, tissue remodeling, and metabolic processes within the chorionic villi. Although their roles in placental biology are increasingly recognized, the mechanisms that regulate HBC identity and function are not yet fully defined. This study aimed to define the core transcriptomic and epigenomic features of HBCs in term placentas and to examine their capacity for transcriptional responsiveness and phenotypic variation. Using chromatin accessibility profiling and bulk RNA-seq, we found that HBCs exhibit a unique gene expression and chromatin accessibility profile compared with other fetal and adult macrophages. We identified a coordinated transcriptional network involving nuclear receptors (NRs) NR4A1–3, the glucocorticoid receptor, and RFX family members (RFX1, RFX2, RFX5) that appears to shape HBC identity, particularly through pathways linked to lipid metabolism and angiogenesis. Although exploratory in nature, in vitro stimulation studies showed that HBCs exhibited increased transcriptional activity in response to combined IL-4 and rosiglitazone treatment, including induction of the lipid transporter CD36. Mass cytometry analysis revealed surface markers indicative of both immature and mature macrophage states. These results together indicate that HBCs are a distinct and diverse population of macrophages with a specialized, adaptable regulatory program in the human placenta.

Authors

Benjámin R. Baráth, Dóra Bojcsuk, Krisztian Bene, Noemí Caballero-Sánchez, Tímea Cseh, João CR. de Freitas, Petros Tzerpos, Marta Toth, Zhonghua Tang, Seth Guller, Zoárd Tibor Krasznai, Patrícia Neuperger, Gabor J. Szebeni, Gergely Nagy, Tamás Deli, Laszlo Nagy

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Figure 3

Transcriptional profiling of nuclear receptor expression and functional specificity in the included macrophage populations.

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Transcriptional profiling of nuclear receptor expression and functional ...
(A) The heatmap represents the significance of the genes (in rank order) of the 6 highlighted sensing and effector functions in the 16 cell types. Genes with an expression higher than 0.5 FPKM (after normalization) in any cell type were considered. (B) The row-normalized heatmap depicts the gene expression of the nuclear receptor superfamily members in the 16 cell types. (C) Scatterplots showing normalized gene expression values (FPKM) for NR4A, PPAR, and RXR family members in sequenced HBC samples. Points represent individual replicates, with horizontal bars indicating the mean and error bars representing SD. (D) The row-normalized heatmap depicts the expression of DEX-responsive genes with nearby GR binding sites, which were previously described (32). (E) Scatterplot showing normalized gene expression values (FPKM) of CD36. Points represent individual replicates, with horizontal bars indicating the mean and error bars representing SD. (F) Bubble plot shows the expression levels (FPKM) of M1 macrophage marker genes (red, left panel) and M2 macrophage marker genes (orange, right panel) in HBCs. The size of each bubble corresponds to the expression value (FPKM) as indicated in the scale legends. Larger bubbles represent higher transcript abundance. KC, Kupffer cell; MDM, monocyte-derived macrophage; AM, alveolar macrophage; aMG, adult microglia; fMG, fetal microglia; fLM, fetal liver macrophage; MoOC, mononuclear osteoclast; MuOC, multinucleated osteoclast; OCP, osteoclast precursor; SpM, spleen macrophage; IM, intestinal macrophage; SkM, skin macrophage; SMo, spleen monocyte; BMo, blood monocyte; CBMo, cord blood monocyte.