Abstract
Using genome-wide approaches, we studied the microRNA (miRNA) expression profile during human plasma cell (PC) differentiation induced by stimulation of human blood B cells with T follicular helper cell–dependent signals. Combining the profiles of differentially expressed genes in PC differentiation with gene ontology (GO) analysis revealed that a significant group of genes involved in the transcription factor (TF) activity was preferentially changed. We thus focused on studying the effects of differentially expressed miRNAs on several key TFs in PC differentiation. Cohorts of differentially expressed miRNAs cooperating as miRNA hubs were predicted and validated to modulate key TFs, including a down-regulated miRNA hub containing miR-101-3p, -125b-5p and -223-3p contributing to induction of PRDM1 as well as an up-regulated miRNA hub containing miR-34a-5p, -148a-3p and -183-5p suppressing BCL6, BACH2 and FOXP1. Induced expression of NF-κB and PRDM1 during PC differentiation controlled the expression of up- and down-regulated miRNA hubs, respectively. Co-expression of miR-101-3p, -125b-5p and -223-3p in stimulated B cells showed synergistic effects on inhibition of PC formation, which can be rescued by re-introduction of PRDM1. Together, we catalogue the complex roadmap of miRNAs and their functional interplay in collaboratively directing PC differentiation.
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Introduction
Lineage-specific, differentially expressed transcription factors (TFs) and stimulus-induced, stage-specific TFs play pivotal roles in the development and function of B cells. For example, paired box gene 5 (PAX5) controls B-cell identity by instructing B-cell lineage commitment and maintaining mature B-cell function1,2. B-cell lymphoma 6 (BCL6) is crucial for establishing germinal center (GC) B cells3. BTB and CNC homology 2 (BACH2) is required for class-switch recombination in GCs4. PR domain zinc finger protein 1 (PRDM1; which is also known as B lymphocyte−induced maturation-1, Blimp-1), X-box binding protein-1 (XBP-1) and interferon regulatory factor 4 (IRF4) are the key TFs that positively control plasma cell (PC) differentiation5,6,7. In particular, PRDM1 is necessary and sufficient for the formation of antibody-secreting PCs8. These key TFs form complex gene regulatory circuits that direct B-cell development/differentiation and shape humoral antibody responses following antigen challenges8. IRF4 up-regulates Prdm19, BCL6 and PRDM1 reciprocally suppress each other10,11 and BACH2 represses Prdm112. PRDM1 suppresses Pax513, thereby allowing the de-repression of Xbp-1, which is the repressive target of PAX5 and which encodes a protein whose splice variant (XBP-1s) is essential for antibody secretion6,14. Despite these studies of transcriptional regulation of B-cell development and function, our knowledge of how post-transcriptional regulation by microRNAs (miRNAs) modulates key TFs in controlling the development/differentiation of B cells is limited.
miRNAs finely tune the expression of genes so that their most significant impact on a biological system may occur only when multiple target genes of a miRNA act in a common regulatory pathway or when multiple miRNAs recognize a common target gene15,16. We thus sought to study the combinatory effects of miRNAs on the regulation of B-cell development/differentiation. In this study, using genome-wide analysis and functional validation of the miRNA expression profile of sorted cell subsets during human PC differentiation in vitro, we identified cohorts of miRNAs that are differentially expressed responding to T follicular helper (Tfh) cell-derived signaling. Further computational analysis and experimental verification revealed the co-targeting effects of several differentially expressed miRNAs that jointly formed a regulatory hub to control key TF genes during human PC differentiation.
Results
miRNA Expression Profiles during Human PC Differentiation
To study the expression profile of miRNAs that were differentially expressed during the formation of antibody-secreting PCs, we isolated CD27−CD19+ naïve B cells from healthy donors and treated them with IL-21 and anti-CD40, stimuli that mimic the signals provided by Tfh cells in GCs17,18. After 3 days in culture, IgDloCD38hi PCs, were not obviously observed; but after 5 days, IgDloCD38hi PCs can be evidently detected (Fig. 1A). Small RNA libraries were then prepared from isolated CD27− naïve B cells at day 0, sorted CD38− cells on days 3 and 5 and sorted CD38+ cells on day 5 from two healthy donors for miRNA microarray analysis.
Among the sorted results, 69 and 70 miRNAs were up and down-regulated (>1.5-fold change, p-value <0.05, in both donors), respectively (Table S1), where 24 and 40 ones were up and down-regulated in all subsets (Fig. 1B). In addition, the up/down-regulated miRNAs, even only detected in one subset, mostly had similar expression trend in all subsets (Fig. S1). Dozens of these miRNAs were selected and further validated with RT-QPCR analysis (Fig. 1C,D). The increase in miR-155-5p and the decrease in miR-150-5p were consistent with previous findings in stimulated mouse B cells19,20,21.
Moreover, without sorting, small RNA libraries prepared from day 0 and day 5 cultures of CD19+ B cells treated in this manner from other three independent healthy donors were combined (Fig. S2A) and subjected to deep sequencing analysis with the Illumina GA2 platform. A second miRNA microarray was conducted with another small-RNA library combined from three other donors. After data processing (see Supplementary Materials and Methods), the expression trend of the unsorted results (Fig. S2B) reconciled the data obtained from sorted subsets (Fig. 1C,D). Some miRNAs that were only represented in one or two experiments may be expressed due to individual variations or the sensitivity of different assay platforms. A panel of miRNAs was selected to confirm their changes in expression from day 0 to day 5 after treatment with IL-21 and anti-CD40 (Fig. S2C). The results with unsorted cells were only used for network construction (Table S2). We suspected the differentially expressed miRNAs that consistently showed up in both sorted and unsorted cells are critical for responding to Tfh cell-derived signals.
Profiling Gene Expression during Human PC Differentiation
To identify the relationship between miRNAs and target genes, we next profile the changes in gene expression during human PC differentiation by using cDNA microarray. The cDNAs derived from three subsets of donor blood B-cell cultures used for miRNA microarray experiments in Fig. 1 were used for microarray analysis of each donor with two replicates. After the within and between sample normalization and data processing (see Supplementary Materials and Methods), we identified 1647, 1356 and 1447 up-regulated genes and 1012, 945 and 1234 down-regulated genes (all p-values <0.05) in day 3 CD38−, day 5 CD38− and day 5 CD38+ subsets, respectively (Table S3) where 628 and 380 genes were respectively up and down-regulated in all subsets (Fig. 2A).
In addition, we analyzed the functional distribution of all up/down-regulated genes with gene ontology (GO). The enriched GO terms for the up-regulated genes were identified in the molecular functions of catalytic activity (all subsets) and antioxidant activity (day 3 CD38− and day 5 CD38−) while the those for down-regulated genes were nucleic acid binding TF activity (all subsets), protein binding TF activity (day 3 CD38− and day 5 CD38−) and translation regulator activity (day 3 CD38− and day 5 CD38+) (bar-plots in the left of Fig. 2B). Regarding biological process, metabolic process (all cell subsets) and cellular component organization or biogenesis (day 3 CD38− and day 5 CD38−) were enriched only for the up-regulated genes, whereas apoptotic process (all subsets), biological regulation (all subsets), developmental process (day 3 CD38− and day 5 CD38−) and multicellular organismal process (day 3 CD38− and day 5 CD38−) were the selective enriched GO terms for the down-regulated genes (bar-plots in the right of Fig. 2C). However, none of cellular component was enriched in all subpopulations (not shown).
Putative miRNA Hubs that Target Key TF Genes
Since the molecular functions of differentially expressed genes preferentially act on nucleic acid binding and protein-binding TF activities, we suspected that the differentially expressed miRNAs may contribute to targeting TFs and thus focused on exploring the regulatory relationship between differentially expressed miRNAs and key TF genes during PC differentiation. Several key TFs, particularly four down-regulated TFs (BACH2, BCL6, PAX5 and FOXP1) and three up-regulated TFs (PRDM1, IRF4 and XBP-1), were the chosen potential target genes and a panel of differentially expressed miRNAs identified from sorted and unsorted cells were used. By analyzing with several predicted and validated interactome databases (see Methods), we first predicted the regulatory network between differentially expressed miRNAs and key TFs as well as among these TFs. In several cases, multiple miRNAs were predicted that commonly targeted one key TF gene (Fig. 3A, Table S4). In addition, several miRNAs were commonly connected to more than one key TF. For instance, both miR-183-5p and miR-34a-5p were predicted as commonly targeting BACH2, BCL6 and FOXP1. We called the miRNAs that commonly targeted to one or more than one TF a miRNA hub and hypothesized that each of these key TF genes is regulated by a miRNA hub consisting of multiple miRNAs. To test this hypothesis, we validated that the changes in protein levels of the key TFs coincided with changes in their mRNA levels (Fig. 3B,C) that also reconciles their reverse association with the differentially expressed miRNA hubs (Fig. 3A).
Regulation of miRNA Hubs by NF-κB or PRDM1
We next asked if the identified down-regulated miRNA hubs were suppressed by PRDM1 because PC differentiation is governed by PRDM1. Stimulated human blood B cells were transduced with lentiviral vectors expressing either GFP alone or GFP-tagged PRDM122. The levels of miR-125b-5p, -222-3p, -101-3p and -223-3p were significantly reduced in human B cells overexpressing PRDM1 (Fig. 4A). Furthermore, we examined if the expression of these miRNAs was perturbed in Prdm1 knockout (KO) mouse B cells. The levels of miR-150-5p, -125b-5p, -222-3p and -223-3p were all reduced in anti-IgM + IL-21 + anti-CD40–treated wild type (WT) splenic B cells (Fig. 4B). miR-101-3p, which is not conserved across species, was not reduced (Fig. 4B). Strikingly, in stimulated Prdm1 KO B cells, the levels of miR-125b-5p were reduced less rapidly at 18 hr; while miR-222-3p and -223-3p were much less reduced than they were in WT cells at later time points (Fig. 4B). Additionally, according to known PRDM1 consensus binding sequences23, several PRDM1 binding sites were predicted in the human miR-101-3p, -125b-5p, -222-3p and -223-3p loci (Fig. S3A). Chromatin immunoprecipitation (ChIP) assay using anti-PRDM1 showed that PRDM1 directly bound to several candidate sites in H929 PC cell line (Fig. S3B). Likewise, induction of PRDM1 in a previously established WI-L2 stable line also led to the binding of PRDM1 to miR-101-3p, -222-3p and -223-3p (Fig. 4C, Fig. S3C). CIITA promoter III region and its the 3′ untranslated regions (UTR) region were served as the positive and negative control loci for PRDM1 binding, respectively24.
Because NF-κB is crucial for inducing GC and antibody production25, we examined whether activated NF-κB controls the up-regulated miRNA hub. Indeed, nuclear translocation of the NF-κB subunit p65 in stimulated mouse splenic B cells and the induction of miR-155-5p, -34a-5p, -183-5p and -365a-3p were all inhibited by treatment with NF-κB inhibitor Bay 11-7082, but miR-148a-3p was not affected (Fig. 4D,E). Together, these data show that induced NF-κB and PRDM1 during PC differentiation activates and suppresses, respectively, these two miRNA hubs.
BCL6, BACH2 and FOXP1 Are Co-Targeted by miRNA Hubs
To investigate if the identified up-regulated miRNAs directly targets the 3′UTRs of down-regulated TF transcripts, including BCL6, BACH2 and FOXP1, we generated a series of luciferase reporters that consisted of various fragments of the 3′UTRs of these key TF genes fused to the 3′ end of luciferase cDNA. The predicted miRNA binding sites on the 3′UTRs of key TF genes were individually mutated using site-directed mutagenesis (Fig. 5A–C). Notably, mutating the miR-34a-5p and miR-183-5p cognate sequences in BCL6 3′UTR completely de-repressed the luciferase activity (Fig. 5A). Mutating the miR-148a-3p and miR-34a-5p, but not miR-183-5p, binding sites in BACH2 3′UTR partially attenuated the repression of luciferase activity (Fig. 5B). Likewise, disruption of the miR-183-5p, miR-34a-5p, or miR-148a-3p site, but not the miR-365a-3p site, attenuated the repression of FOXP1 3′UTR–mediated luciferase activity (Fig. 5C).
We then examined if alteration of identified miRNAs influenced the expression of endogenous BCL6, BACH2 and FOXP1. We used both a gain-of-function approach with lentiviral transduction of miRNAs and a loss-of-function approach with transfection with anti-miR locked nucleic acids (LNAs), which are miRNA inhibitors that absorb miRNAs and prevent their interaction with endogenous target transcripts. BCL6 and BACH2 were suppressed by overexpression of miR-34a-5p, -148a-3p, or -183-5p, but their expression was elevated by their corresponding anti-miR LNAs in a lymphoblastoid cell line, SKW6.4, in which mature B cell genes are expressed (Fig. 5D). miR-148a-3p appeared to indirectly regulate endogenous BCL6 because its conserved binding site was not found in BCL6 3′UTR. Overexpression of miR-365a-3p had a similar effect, as did miR-34a-5p, -148a-3p and -183-5p, on the suppression of endogenous FOXP1 in SKW6.4 cells (Fig. 5E). Conversely, inhibition of these miRNAs with anti-miR LNAs increased endogenous FOXP1 (Fig. 5E).
We next tested if combined alteration of these miRNAs within a miRNA hub could synergize their individual effects on the expression of BCL6, BACH2, or FOXP1. The expression of BACH2 and BCL6 was not changed or was only marginally affected in SKW6.4 cells transduced with lentiviral vectors expressing miR-34a-5p, -148a-3p, or -183-5p at a low multiplicity of infection (moi) (Fig. 5F). However, simultaneous expression of these miRNAs at a low moi induced a more robust reduction of BACH2 and BCL6 than the effects caused by an individual miRNA at a high moi (Fig. 5F). In a reverse trend, transfection with a low dose of individual anti-miR LNAs against miR-34a-5p, -148a-3p, or -183-5p caused minimal effects on the expression of BACH2 and BCL6, but transfection with a mixture of all three anti-miR LNAs at low amounts resulted in substantial increases in the expression of these TFs (Fig. 5F). Similarly, the co-targeting effects of these miRNAs on FOXP1 were also observed (Fig. 5G). These combined data indicate that miRNAs within a miRNA hub collaboratively inhibit BACH2, BCL6 and FOXP1 during PC differentiation.
To understand the role of FOXP1 in human PC differentiation, we transduced a lentiviral vector encoding a GFP-FOXP1 fusion protein into IL-21 + anti-CD40-stimulated human B cells (Fig. 6A) and determined if ectopic expression of FOXP1 affects the formation of PCs. Cells transduced with the GFP-BCL6 expression vector were used as the positive control (Fig. 6A), because Bcl6 negatively controls PC differentiation by suppressing Prdm111. Like GFP-BCL6, the expression of GFP-FOXP1 in stimulated human B cells substantially inhibited the formation of IgDloCD38hi PCs compared with cells transduced with the control vector (Fig. 6B). Likewise, similar to those transduced with GFP-BCL6, GFP-FOXP1 expressing cells produced less IgG (Fig. 6C) and failed to up-regulate PRDM1 mRNA (Fig. 6D). The mRNA levels of B cell activation or cell cycle regulator genes targeted by BCL6, such as CD44, CD69 and p2110, are also changed in FOXP1 expressing cells (Fig. 6D). These results suggest that down-regulation of FOXP1, operated by the up-regulated miRNA hub, is required for the formation of PCs.
Cooperative Effect of miR-101-3p, -125b-5p and -223-3p on Inhibiting PC Formation
We next examined the cooperative effects of the down-regulated miRNAs, including miR-101-3p, -125b-5p and -223-3p, on human PC differentiation. In the 3′UTR of PRDM1, one miR-125b-5p site in the first half of the 3′UTR and one miR-101-3p site and three miR-223-3p sites in the second half of the 3′UTR were predicted by TargetScan (Fig. 7A). As a control26,27, miR-125b-5p bound to the first half of the 3′UTR of PRDM1 via conserved cognate sequences because mutating the miR-125b-5p binding site attenuated the repression (Fig. 7A). Disruption of the miR-101-3p site and the second and third, but not the first, miR-223-3p binding sites de-repressed the luciferase activity (Fig. 7A). miR-125b-5p, -101-3p and -223-3p regulated the expression of PRDM1 because overexpression of either of them decreased PRDM1 protein levels in H929 PCs (Fig. 7B). Blocking the activity of these miRNAs elevated PRDM1 (Fig. 7B). miR-125b-5p, -101-3p and -223-3p also showed the cooperative effects on PRDM1 expression in contrast to the effects caused by individual miRNAs (Fig. 7C). In a reverse trend, transfection with a low dose of individual anti-miR LNAs against either of them barely affected PRDM1 expression, but transfection with a mixture of all three anti-miR LNAs at low amounts resulted in significant increases in PRDM1 (Fig. 7C).
We then examined if miR-101-3p, -125b-5p and -223-3p phenotypically influenced human PC differentiation by co-regulating PRDM1. Isolated human blood B cells stimulated with IL-21 + anti-CD40 were transduced with either control lentiviral vector or lentiviral vectors producing miR-101-3p, -125b-5p, and/or -223-3p. Simultaneous introduction of miR-101-3p, -125b-5p and -223-3p exacerbated the inhibitory effects of each miRNAs (Fig. 7D,E). In addition, inhibition of PC formation was linked with down-regulation of PRDM1 mRNA in all transduced groups (not shown).
To further elucidate if repression of PRDM1 by a mixture of miRNAs attributes to the reduced PC differentiation, we co-transduced another lentiviral vector that encodes GFP alone (Ctrl) or GFP-PRDM1 with or without the vectors producing miR-101-3p, -125b-5p and -223-3p in stimulated human blood B cells. Flow cytometric analysis of the percentage of IgDloCD38hi PCs in the GFP+ gate at day 5 revealed that ectopic expression of GFP-PRDM1 enhanced the generation of IgDloCD38hi PCs as compared with control vector transduced group (Fig. 7F). Ectopic expression of GFP-PRDM1 also promoted the production of IgG (Fig. 7G). More importantly, re-introduction of GFP-PRDM1 that lacks the endogenous PRDM1 3′UTR, compensated for the differentiation block caused by a mixture of miRNAs (Fig. 7F,G). Together, these data show that the hub of miR-101-3p, -125b-5p and -223-3p suppressed PC differentiation largely by inhibiting PRDM1.
Discussion
In this study, we profiled the temporal changes of miRNAs during human PC differentiation using genome-wide approaches. The miRNA expression signatures in various human B-cell subsets obtained from human tonsils, such as naïve B cells, GC B cells, PCs and memory B cells, have been characterized using miRNA microarrays or expression cloning28,29. Based on those studies, many miRNAs are selectively expressed at particular stages of B cells. For instance, the level of miR-223 is higher in naïve B cells than in GC B cells29. Of note, the levels of several miRNAs including miR-15b, -18b, -93, -148a, -183, -365, -425 and -744 are higher in centroblasts, a type of GC cells experiencing Tfh signals, than in naïve B cells28. This observation is consistent with our findings that the levels of these miRNAs were induced in human peripheral B cells treated with Tfh cell-derived stimuli. The differential expression of these miRNAs in centroblasts may reflect their exposure to Tfh stimuli, but the biological significance of these miRNAs in human PC differentiation could not have been assessed before our current study in which we used a primary culture system. Of note, the trend in expression of individual miRNAs within the miRNA hub, such as up-regulation of the miR-34a-5p, -148a-3p and -183-5p hub and down-regulation of the miR-101-3p, -125b-5p and -223-3p hub, is similar, supporting that their co-presence or co-absence may have synergistic effects.
When miR-34a-5p, -148a-3p and -183-5p were individually overexpressed, the fold changes of endogenous BCL-6 protein levels were more dramatic than those of BACH2 and FOXP1, despite that we confirmed that most of these miRNAs can target the 3′UTRs of BCL6, BACH2, or FOXP1. In particular, the target sites of miR-148a-3p and miR-183-5p in the 3′UTR of BACH2 are both highly conserved among vertebrates. Therefore, target site conservation is unlikely the major reason and the efficiency of translation inhibition by miR-34a-5p and -183-5p may contribute to the effects on BCL6 regulation. We checked the target sites in the 3′UTR and found that only seven sites for miRNA families in vertebrates and three sites for miRNA families in mammals were broadly conserved in the 3′UTR of BCL6. In contrast, dozens of conserved sites among vertebrates or only mammals are found in the 3′UTRs of BACH2 and FOXP1. Thus, we speculate that miRNAs targeting a gene transcript with fewer miRNA target sites in the 3′UTR may function more efficiently in translational inhibition than those with more miRNA target sites. In addition, using luciferase reporter assays, we found that miR-183-5p and -365a-3p did not affect BACH2 and FOXP1 3′UTR, respectively, whereas modulation of these miRNAs influenced the expression of BACH2 and FOXP1. Furthermore, some miRNAs may target not only the 3′UTR with a non-seed match30 but also the coding regions of mRNAs31. Therefore, how individual miRNA works on suppressing the expression of key TFs requires further experiments.
In this study, we found an additional layer of complexity of gene regulatory mechanisms in controlling PC differentiation. Overexpression of miR-101-3p, -125b-5p, or -223-3p individually blocked the formation of PCs and this inhibitory effect was synergized when they were over-expressed together. Their target genes in this context are not clear, but PRDM1 appears to be a crucial one because ectopic expression of PRDM1 can rescue the effects of these miRNAs. In addition, miR-223 has been shown to suppress GC marker LIM domain only-2 (LMO2) in a B cell lymphoma line27, but the roles of miR-223 and LMO2 in PC differentiation are still unknown. As initiation of PC differentiation can occur independently of PRDM132, miRNAs likely play a role in this setting. We here further revealed the mechanisms contributing to the effects of FOXP1 on limiting PC differentiation. FOXP1 is a target of miR-34a and knockdown of FOXP1 in mouse bone marrow progenitor cells phenotypically mimics the effect of miR-34a on the inhibition of early B-cell development33. Aberrant expression of FOXP1 results in reduced numbers of GC cells in mice34. Additionally, aberrant expression of FOXP1 reduces Ig class-switch recombination to IgG134, which reconciled our finding that overexpression of FOXP1 in human peripheral blood B cells reduced the production of IgG. FOXP1 binds to genes associated with cell cycle regulation and proliferation in a diffuse large B-cell lymphoma cell line, OCI-Ly134 and absence of FOXP1 affects cell cycle progression by increasing p21 and reducing p27 expression in myocytes35. We found that overexpression of FOXP1 in stimulated B cells not only repressed PRDM1 mRNA but also reduced p21 mRNA. Although both BCL6 and FOXP1 can block PC differentiation by reducing the expression of PRDM1, we suspect that they may function independently because p27 is suppressed by BCL610,11, but not by FOXP1. Additionally, GC relevant gene MYB was induced by BCL636, but not by FOXP1. This notion is supported by the observation that BCL6 and FOXP1 are expressed in distinct spatial locations in human tonsils34.
NF-κB is activated by cross-linking CD40 on B cells37 and activates miR-155 in transformed B cells38. We show that in addition to miR-155-5p, induction of miR-34a-5p, -183-5p and -365a-3p by IL-21 + anti-CD40 also depends on NF-κB. Furthermore, NF-κB signaling induces Prdm139, which in turn switches off the expression of miR-101-3p, -125b-5p and -223-3p. Together, our results not only illustrate the miRNA/TF regulatory cascades in PC differentiation but also may shed light on new therapies for disorders resulting from dysregulation of PC formation; in particular, miRNAs and decoys consisting of artificial target sites of miRNAs have been proposed as therapeutic approaches40,41.
Methods
Human B cell culture and cell lines
Human blood B cells were isolated from human peripheral blood mononuclear cells of healthy donors obtained from the Taipei Blood Donation Center and were cultured as described42. The research involving human subjects was approved by the Institutional Review Board of Academia Sinica and informed consent was obtained from all subjects. The experiments were performed in accordance with the approved guidelines. CD27−CD19+ and CD19+ B cells were purified by RosetteSep (StemCell). Purified human B cells cultured at a density of 1 × 106 cells/mL were stimulated with IL-21 (100 ng/mL; Invitrogen) and anti-CD40 (1 μg/mL; R&D Systems). NCI-H929 (H929) human multiple myeloma cells and SKW6.4 human lymphoblastoid cells were maintained in RPMI 1640 (Life Technologies) containing 10% FBS (Life Technologies) and 2-ME (50 μM; Life Technologies). FLAG-PRDM1-ERD WI-L2 cells were maintained in phenol red-free RPMI 1640 containing 10% C/D FBS (Life Technologies) and Hygromycin B (0.5 mg/mL; invitrogen). All cells were maintained in medium containing penicillin/streptomycin (100 units/mL; Life Technologies).
Flow cytometry
Cells were harvested and washed with PBS once at a density of 106/mL and the staining procedures were described previously43, by using allophycocyanin-conjugated anti-human CD38 (clone HB7), phycoerythrin-conjugated anti-human IgD (clone IA6-2) antibodies. The fluorescence intensity was analyzed by FACSCanto (Becton Dickinson) and FCS Express 3.0 software.
miRNA experssion profiling using miRNA microarrays and data analysis
Total RNA, isolated by TRI Reagent (Sigma-Aldrich), was used to label with Cy3-pCp fluorescent dyes using the Agilent’s miRNA microarray system V2.0 and hybridized to Agilent human miRNA array (V19) for detecting miRNA expression in unsorted B cells and sorted cell subsets. In brief, total RNA (200 ng) was treated with calf intestine phosphatase for 30 min at 37 °C. 100% DMSO was used for denaturation at 100 °C for 5 min, after which the samples were immediately transferred into an ice water bath for the prevention of reannealing. The samples were then labeled with Cy3-pCp by incubating with T4 RNA ligase for 2 hr at 16 °C. After the labeling reaction, the samples were purified on the Micro Bio-Spin 6 column (Bio-Rad Laboratories, USA). The purified RNA was then denatured and hybridized to the microarray probes at 55 °C and then spun at 20 rpm for 20 hr in an Agilent Microarray Hybridization Chamber (Agilent Technologies). The microarray slide was subsequently washed and scanned using the Agilent scanner to obtain microarray images. The scanned signals were extracted with Feature Extraction software version 10.7.1.1 using the default setting (Agilent Technologies). In each miRNA array chip, there are 62,344 probes. All array data were done with the between-sample normalization as follow: for each chip, first sorted the probes by their intensities increasingly. Then, for all the chip data, the intensity values of the same sorting order were replaced by the median of the original intensity values at the same order among all chips. In each miRNA chip, expecting for the control ones there are 60,180 probes for 2,006 human miRNAs that each miRNA has 30 probes. For each miRNA, the expressed intensity value was represented by the median of the intensity values of 30 probes. The log2 fold changes of day 3 sample were calculated by the log2 ratios of the expressed intensity value in day 3 over that in day 0. The log2 fold changes of day 5 CD38+ and day 5 CD38− subpopulations were also calculated by the same method. Finally, the mean and standard derivation of all fold changes for each normalized array data were calculated. The up and down-regulated miRNAs were defined as their log2 fold changes increasingly over or decreasingly under 1.5 standard derivations in both personal samples (p-value < 0.05).
TF and miRNA Regulatory Network Construction and Visualization
Seven key TFs, BACH2, BCL6, FOXP1, IRF4, PAX5, PRDM1 and XBP1, were selected to construct their putative regulatory network with differentially expressed miRNAs identified from both sorted and unsorted cell subsets and with each others. The TF-TF interactions were predicted by Ernst et al.44 and Gerstein et al.45. The miR-target interactions not only used the results predicted by TargetScanHuman and miRDB, as described above, but also by those from targetHub46 (http://app1.bioinformatics.mdanderson.org/tarhub/_design/basic/index.html). targetHub is a database of miRNA-mRNA interactions and the interaction sources include miRTarBase47, TargetScan, PicTar4&548 and miRanda49. However, the version of miRTarBase was Release 2.5. The latest version of miRTarBase (Release 4.5)50 was downloaded and the new interactions related to the seven TFs were added to the interaction data. In addition, TargetScan used in targetHub was version 6.1. The latest version 6.2 was also added for the comparison. These prediction datasets were integrated together, including miRTarBase4.2, TargetScan6.1, TargetScan6.2 conserved and nonconserved, PicTar4, PicTar5, miRanda and miRDB5.0. In addition, the miRNA expression data for the network construction were used by not only the sorted results but also the unsorted data (Table S2). Finally, the datasets were integrated together and only the pairs that both the miRNAs and target TFs with the reversed regulation were selected. A supporting score for each miR-TF pair was also defined as the total number of how many tools predicted the interaction. All networks were visualized by Cytoscape that was downloaded from (http://www.cytoscape.org/).
Immunoblotting
Total cell lysates (60 μg) and nuclear lysates (5 μg), prepared as described42 or by nuclear extraction kit (Panomics, USA), respectively, were subjected to SDS-PAGE and immunoblotting using primary antibodies against PRDM151, actin (1: 5,000 dilution; Sigma), BACH2 (1: 1,000 dilution; abcam), BCL6 (1: 1,000 dilution; Cell Signaling and 1: 1,000; BioLengend), FOXP1 (1: 1,000 dilution; abcam), PAX5 (1: 500 dilution; Santa Cruz), XBP-1 (1: 500 dilution; Santa Cruz), p65 (1: 500 dilution, Santa Cruz), lamin B (1: 400 dilution; Santa Cruz) and GFP (1: 1,000 dilution; Santa Cruz). The detailed procedures, secondary antibodies used and detection of immunoreactive proteins were as described42.
Luciferase reporter construction and activity assay
3′UTR of PRDM1, BACH2, BCL6 and FOXP1, amplified from the cDNA of primary CD19+ peripheral B cells or SKW6.4 cells, was cloned into the downstream of Renilla luciferase cDNA transcribed by the tk promoter (RL-TK). The detailed cloning procedures and the procedures for site-directed mutagenesis of 3′UTR carrying disrupted seed region of miRNA target sites are available upon request. The transfection procedure was performed by electroporation according to a previous reported condition13. Briefly, 3 μg of 3′UTR-RL-TK constructs carrying with or without the 3′UTR of various genes were mixed with 0.5 μg of p-GL3-Promoter vector (Promega), as for internal normalization, for electroporation. Twenty-four hours later, electroporated cells were subjected to a dual-luciferase reporter assay as described previously42. The fold of repression was calculated as the ratios of Renilla luciferase activities/firefly luciferase to the ratios obtained from control cells transfected with empty vector without carrying 3′UTR of key TFs.
Lentiviral vector preparation and transduction
The protocol for preparation of lentiviral vectors and viral transduction has been described43. Stimulated human B cells, SKW6.4 and H929 cells were transduced with virus at various amounts of moi in the presence of 5 μg/mL polybrene (Sigma-Aldrich). The transduced cells expressing GFP were sorted by FACSAria (Becton Dickinson) one day later for the subsequent experiments.
RT-quantitative PCR (RT-QPCR)
RNA was isolated by TRI Reagent (Sigma-Aldrich). Small RNA and cDNA synthesis were carried out as described42,52. The subsequent QPCR analysis on an ABI Prism 7300 sequence detection system (Applied Biosystems) was performed as described42. RT-QPCR analysis of miRNAs and mRNAs was carried out using TaqMan probes purchased from ABI. U6 non-coding small nuclear RNA (snRNA) and GAPDH were used as the control for normalization of miRNA and mRNA levels, respectively. PCR was performed for 30 cycles and the primer sequences are described in Table S5.
Enzyme-linked immunosorbent spot (ELISPOT) assay
ELISPOT analysis for detecting IgG-secreting plasma cells was essentially as described42, by using 1 μg of anti-human Ig H+L (SouthernBiotech) coated on each 96-well-plate with PVDF bottom and anti-human IgG (1: 2,000 dilution; SouthernBiotech) as the secondary antibody. Photomicrographs of the spots were analyzed with the AID EliSpot Reader System (AID Autoimmun Diagnostika GmbH).
Chromatin immunoprecipitation (ChIP)
ChIP assays for analyzing the binding of PRDM1 to endogenous miRNA gene loci were performed essentially as previously described42. Briefly, a total of 1 × 107 H929 or WI-L2 cells were used in each anti-PRDM1 or anti-FLAG ChIP assay. Immunoprecipitated chromatin samples were quantified by QPCR using primers that specifically amplified gene fragments encompassing the PRDM1 binding site or within 200 bp of the PRDM1 binding site at each individual miRNA gene locus. Statistical analysis was done by the comparison with the IgG IP samples. Primer sequences used in this study are listed in Table S5. Values obtained from immunoprecipitated samples were normalized to that of their corresponding input samples.
Statistics
Statistical analysis of experimental data was calculated with a paired, 2-tailed Student’s t test. p values lower than 0.05 were considered statistically significant.
Additional Information
How to cite this article: Tsai, D.-Y. et al. Uncovering MicroRNA Regulatory Hubs that Modulate Plasma Cell Differentiation. Sci. Rep. 5, 17957; doi: 10.1038/srep17957 (2015).
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Acknowledgements
We thank the High Throughput Sequencing Core at Biodiversity Research Center, Academia Sinica for processing small RNA-Seq libraries and sequencing, Chih-Hao Chang, Han-Chu Hsu, Pang-Yen Yang and Yu-Hsuan Tseng for excellent technical assistance. The work was supported by Academia Sinica (AS-99-CDA-L12 to K.-I. L. and AS-100-CDA-M02 to A. C.-C. S.) and by the Ministry of Science and Technology (100-2628-B-001-015-MY4 to K.-I. L. and 103-2221-E-001-025-MY2 to A. C.-C. S.), Taiwan.
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K.-I.L. directed the project. A.C.-C.S., W.-H.L. and K.-I.L. designed the study. D.-Y.T., K.-H.H., I-Y.L., S.-T.S., C.-H.C. and T.-C.W. performed experiments. D.-Y.T., S.-Y.W., A.C.-C.S. and K.-I.L. analyzed the data. A.C.-C.S. and K.-I.L. wrote the paper.
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Tsai, DY., Hung, KH., Lin, IY. et al. Uncovering MicroRNA Regulatory Hubs that Modulate Plasma Cell Differentiation. Sci Rep 5, 17957 (2015). https://doi.org/10.1038/srep17957
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