The Ethics Committee of the Fujian Maternity and Child Health Hospital authorized the present study (Fuzhou, China; approval no. 2019073), which followed the Helsinki Declaration. Peripheral blood samples were collected from 20 patients with β-TM (age, 8.30±1.59 years; female/male, 13/7) and 20 healthy controls (age, 9.00±2.23 years; female/male, 12/8) before blood transfusion or hydroxyurea treatment at Fujian Maternity and Child Health Hospital (Fuzhou, China) between January 2020 to December 2021. For the group comprised of patients with β-thalassemia, the inclusion criteria included patients exhibiting anemia symptoms (Hb <90 g/l; normal reference value in children aged 6 months to 6 years, 105–140 g/l; normal reference value in children aged 7–12 years, 110–160 g/l) and carrying β°/β° (n=16), β°/β⁺ (n=2), β⁺/β⁺ (n=2) genotypes. Control groups were those age-matched individuals with normal thalassemia gene diagnosis and peripheral blood indexes. The exclusion criteria included: i) Patients with asthma, epilepsy and diabetes; ii) patients with acute and chronic lung infection; iii) patients with abnormal blood coagulation; and iv) patients with α-thalassemia, iron deficiency anemia and megaloblastic anemia. All patients or their guardians provided written informed consent.

Peripheral blood samples were gathered as previously described (29). Briefly, 5 ml peripheral blood from the participants was preserved and isolated using a PAX gene blood RNA kit (Qiagen GmbH). Analysis was conducted using the Sysmex XN-3000 automated hematology analyzer (Sysmex Corporation) to evaluate blood cell parameters. An automated capillary electrophoresis device (version 6.2; Sebia) was used to analyze the Hb composition and levels.

The human umbilical cord blood-derived erythroid progenitor (HUDEP-2) cells were provided by RIKEN BioResource Centre through the National BioResource Project of the Ministry of Education, Culture, Sports, Science and Technology (Tsukuba, Ibaraki, Japan). The cells were cultured in a serum-free StemSpan SFEM^® medium (Stemcell Technologies, Inc.), supplemented with 3 IU/ml erythropoietin (EPO; Amgen, Inc.), 1 µg/ml doxycycline (Sigma-Aldrich; Merck KGaA) and 1×10⁻⁶ M dexamethasone (Sigma-Aldrich; Merck KGaA). K562 cells derived from human erythroleukemia were acquired from Shanghai Anwei Biotechnology Co., Ltd. All cells were incubated at 37°C in a humidified atmosphere containing 5% CO₂.

The miR-6747-3p mimic (5′-UCCUGCCUUCCUCUGCACCAG-3′) and its negative control (5′-UUCUCCGAACGUGUCACGUTT-3′), along with the miR-6747-3p inhibitor (5′-CUGGUGCAGAGGAAGGCAGGA-3′) and its control inhibitor (5′-CAGUACUUUUGUGUAGUACAA-3′) were obtained from Shanghai Genepharma Co., Ltd. HUDEP-2/K562 cell transfections were carried out by Amaxa Nucleofector II Device (Lonza Group, Inc.) according to the manufacturer's instructions at room temperature. The reagents used for electroporation of HUDEP-2 and K562 cells were Cell Line Nucleofector^™ Kit (Lonza Group, Inc.), and the electroporation programs were U-008 and ATCC. After electroporation with oligonucleotides at 100 nM concentration at room temperature for 2 sec, the cells were cultured in a 37°C incubator for 48 h for flow cytometry, cell cycle detection and cell RNA extraction. The cell protein was extracted after 72 h. K562 cells were induced by Hemin for 96 h for cell differentiation detection and benzidine staining. HUDEP-2 cells were cultured in three-stage medium for 14 days before erythroid differentiation testing and Wright-Giemsa staining.

Total RNA of peripheral blood samples and HUDEP-2/K562 cells were gathered by the PAX Gene Blood RNA Kit (Qiagen GmbH) and the Eastep^® Super Total RNA Extraction Kit (Promega Corporation) following the manufacturer's guidelines. The RNA was quantified by NanoDrop ND-1000 spectrophotometer (NanoDrop Technologies). The cDNA of miRNA and mRNA were generated with Mir-X^™ miRNA First-Strand Synthesis Kit and PrimeScript^™ RT reagent Kit with gDNA Eraser (Takara Bio, Inc.). γ-globin, BCL11A and miR-6747-3p relative expression levels were computed by applying the comparative cycle threshold approach. The StepOnePlus^™ Real-Time PCR System (Applied Biosystems; Thermo Fisher Scientific, Inc.) was adopted to perform miRNA and mRNA qRT-PCR with TB Green^® Advantage^® qPCR Premix and TB Green^® Premix Ex Taq^™ II Kit (Takara Bio, Inc.,), according to the manufacturer's instruction. The miRNA RT-qPCR protocols were demonstrated as follows: After a 10 sec denaturation stage, there were 40 cycles of incubation at 95°C for 5 sec, 62°C for 20 sec and 55°C for 30 sec. The RT-qPCR detection protocol for mRNA was conducted as follows: After a 30 sec pre-denaturation phase, a total of 40 amplification cycles were executed, comprising denaturation at 95°C for 5 sec, annealing at 60°C for 34 sec, and extension at 95°C for 15 sec. The 2^−ΔΔCq technique was utilized to determine the relative fold-change of each target gene in relation to GAPDH and U6 (30). The primer sequences are available in Table SI.

The Cell Counting Kit-8 (CCK8; APeXBIO Technology LLC) was utilized to quantify cell proliferation ratio. HUDEP-2 and K562 were seeded in 96-well plates after adding 10 µl CCK-8 reagent to each well. After 2 h of incubation at 37°C, the cell viability was assessed using a microtiter reader (Thermo Fisher Scientific, Inc.) at 450 nm. Proliferation of the cells was assessed at 0, 24, 48, 72 and 96 h. Every experiment was run three times.

The impacts of miR-6747-3p on cell cycle and apoptosis were examined using flow cytometry. A total of 5 µl propidium iodide (PI; BD Biosciences) were added to stain HUDEP-2 and K562 cells after fixation with 75% ethanol at −20°C overnight. The G0/G1, S and G2/M ratios were analyzed using ModFit software (V3.2.; Verity Software House, Inc.). Annexin V-FITC/PI (BD Biosciences) was used to stain cells for 30 min at room temperature following the manufacturer's guidelines to detect cell apoptosis. After which, BD LSRFortessa^™ X-20 (BD Biosciences) and FlowJo software V10 (FlowJo LLC) were used to assess the apoptosis experiments.

A three-phase differentiation protocol was used to differentiate HUDEP-2 cells (31). The procedure involved three phases including phase 1 (days 1–4), using Iscove's Modified Dulbecco's Medium (IMDM) supplemented with 100 ng/ml Stem Cell Factor (SCF), 10 µg/ml recombinant human insulin, 5% human AB serum, 1% L-glutamine, 330 µg/ml holo-transferrin, 3 U/ml EPO, 1 µg/ml doxycycline, 2 U/ml heparin and 1% penicillin/streptomycin. Phase 2 (days 5–7) included the same cytokines as phase 1, except without SCF. During phase 3 (days 9–14), DOX was removed. For K562 cells, 50 µM of hemin was added and the cells were cultured for another 96 h. The CD71/CD235a kit (BD Biosciences) was used to detect erythroid lineage differentiation. All cells were incubated at 37°C in a humidified atmosphere containing 5% CO₂.

To assess the differentiation of different groups, HUDEP-2 cells were centrifuged for 300 × g at room temperature for 5 min, resuspended using 20 µl FBS (Stemcell Technologies, Inc.) and coated on the slide. After drying naturally at room temperature, Giemsa A and B solutions (Zhuhai Beso Biotechnology Co., Ltd.) were combined at a 1:1 volume ratio. The slide was washed with running water after staining for 5 min at room temperature, the cell morphology [including basophilic erythroblast (Baso-E), polychromatic erythroblast (Poly-E) and orthochromatic erythroblast (Ortho-E)] was observed and captured using Leica Aperiod CT6 microscope (Leica Microsystems GmbH).

The Hb expression level in K562 cells induced to differentiate by hemin was evaluated by mixing the cell suspension with a freshly made benzidine-H₂O₂ solution, consisting of 50 µl of 3% H₂O₂ (Sigma-Aldrich; Merck KGaA) and 0.4%/ml benzidine (Merck KGaA). After a 5-min treatment at room temperature, the cells were photographed under a light microscope (Olympus Corporation). The benzidine-positive cells were expressed as a percentage of at least 100 cells.

In HUDEP-2 cells, FISH was performed using specific probes for miR-6747-3p and BCL11A according to the manufacturer's instructions (Shanghai GenePharma Co., Ltd.). A total of ~5×10⁴ HUDEP-2 cells were seeded on coverslip (NEST, Inc.; cat. no. 801007) in 24-well plates overnight. After which, the cells were washed with PBS and fixed in a 4% formaldehyde solution for 15 min at room temperature. The cells were incubated at room temperature with 0.1% buffer A for 10 min. After 15 min of incubation at 37°C in Protein Free Rapid Blocking Buffer (EpiZyme, Inc.; cat. no. PS108), 1 µl of 1 µM FAM-labeled miR-6747-3p probe (5′-CTGGTGCAGAGGAAGGCAGGA-3′) or 1 µM cy3-labeled BCL11A probe (5′-CCTGGTATTCTTAGCAGGTTAAAGG-3′) with 73°C rehydrated buffer E was added into the cells and incubated at 37°C overnight in darkness. The next day, the cells were successively washed three times for 10 min: 0.1% buffer F at 37°C, 2X buffer C at 60°C, and 2X buffer C at 37°C. 4′,6′-DAPI was used to dye the cell nuclei for 10 min at room temperature. A Leica TCS SP8 CARS Confocal Microscope (Leica Microsystems GmbH) was used to identify the subcellular localization of miR-6747/BCL11A.

The binding spot between miR-6747-3p and BCL11A was identified using the online tool Targetscan (version 8.0; https://www.targe tscan.org/vert_80/), miRWalk (version 3.0; http://mirwalk.umm.uni-heidelberg.de/) and miRDB (version V6; http://mirdb.org/miRDB/). Luciferase reporter vector pmiR-RB-REPORT^™ (Promega Corporation) was inserted with wt-BCL11A and mut-BCL11A and co-transfected with HUDEP-2 cells with a density of 1×10⁵ cells/well using Lipofectamine^® 3000 (Thermo Fisher Scientific, Inc.). This includes the miR-6747-3p mimic, negative control, miR-6747-3p inhibitor and inhibitor negative control. The relative luciferase activity was calculated by the ratio of Renilla to firefly luciferase after incubation for 48 h at 37°C. A total of three replicates were established for the experiment.

Proteins were extracted following the previously published method (32). Briefly, protein samples were obtained from HUDEP-2 and K562 cells using RIPA lysis buffer (Beyotime Institute of Biotechnology) and quantified by BCA Kit (Beyotime Institute of Biotechnology). After being separated on a 12.5% SDS-PAGE gel, the protein samples (20 µg) were imprinted on a polyvinylidene difluoride membrane. Following 2 h of incubation at room temperature in Protein Free Rapid Blocking Buffer (EpiZyme, Inc.; cat. no. PS108), the membranes were then exposed to the following primary antibodies overnight at 4°C: Anti-GAPDH (1:20,000; cat. no. ab8245; Abcam), anti-γ-globin (1:1,000; cat. no. ab156584; Abcam) and anti-BCL11A (1:1,000; cat. no. ab19487; Abcam). Horseradish peroxidase (HRP)-conjugated goat anti-mouse IgG (1:5,000; Santa Cruz Biotechnology, Inc.; cat. no. SC-2005) and HRP-conjugated goat anti-rabbit IgG (1:5,000; Santa Cruz Biotechnology, Inc.; cat. no. SC-2004) were utilized as the secondary antibodies at room temperature for 2 h. To identify proteins, the Chemiluminescence Western Blotting Detection system (Thermo Fisher Scientific, Inc.) was used. Densitometric analysis with Image J software (version 1.5; National Institutes of Health) was used to ascertain the relative expression of each protein.

GraphPad Prism 9.0 (Dotmatics) and SPSS 26.0 (IBM Corp.) were utilized for data analysis. The Kolmogorov-Smirnov test was employed to examine the normality of the data distributions. The differences between groups with normally distributed data (displayed as mean ± standard deviation) were assessed utilizing the two-tailed unpaired Student's t-test (2 groups) or the one-way ANOVA followed by Tukey's test (≥3 groups), as appropriate. The differences between groups without normally distributed data [displayed as the median and interquartile range M (P25, P75)] were tested by the Mann-Whitney U test (2 groups) or the Kruskal-Wallis test (≥3 groups), as appropriate. The association between hematological indicators and miR-6747-3p was examined using Spearman correlation analysis. Mean ± standard deviation was reported from three separate trials. P<0.05 was considered to indicate a statistically significant difference.

In the present study, 20 patients with β-TM and 20 healthy controls were recruited to confirm the expression of miR-6747-3p and evaluate its clinical significance. Compared with the healthy participants, patients with β-TM had significantly decreased Hb levels and higher HbF levels (Table I), which was consistent with the anemia phenotype of β-TM (33). There was a notable rise in the expression of MiR-6747-3p in patients with β-TM (Fig. 1A). Notably, correlations were evaluated between miR-6747-3p and hematological parameters (Fig. 1B), and HbA₂ was found to be associated with miR-6747-3p. However, miR-6747-3p was statistically not correlated with RBC, HGB, MCV, HbA and PLT. By dividing patients into HbF high (HbF, ≥2.7%) and low (HbF, <2.7%) expressing groups, it was discovered that patients with HbF ≥2.7% had significantly higher levels of miR-6747-3p than the patients with <2.7% HbF (Fig. 1C). Additional examinations uncovered that miR-6747-3p was significantly correlated with HbF levels in patients with β-TM (r=0.636; P<0.05; Fig. 1D). These results indicate that miR-6747-3p may play a role in the elevated HbF in patients with β-TM. Consequently, the effects of miR-6747-3p overexpression and knockdown in erythroid precursor cells were further investigated.

Electroporation transfection with overexpression and knockdown vectors for miR-6747-3p was performed on HUDEP-2 cells and K562 cells. A validation of cell transfection efficiency was provided in Fig. S1. The CCK-8 results showed that the absorbance of the miR-6747-3p mimic group was reduced in HUDEP-2 cells. Conversely, absorbance of the miR-6747-3p inhibitor group exceeded the NC inhibitor group (Fig. 2A). Similar results were detected in K562 cells (Fig. 2B), inferring that miR-6747-3p expression decreases cell proliferation in HUDEP-2 cells and K562 cells.

Cell cycle analysis showed that miR-6747-3p mimic cells led to higher percentages of the S phase, while the inhibitor group had the opposite effect (Fig. 2C and D). Consistent with the cell growth findings where miR-6747-3p demonstrated the capability to reduce cell growth in a laboratory setting, these findings suggested that overexpression of miR-6747-3p results in a halt from S to G2/M phase in the cell cycle.

Apoptosis was examined in HUDEP-2 and K562 cells with either overexpression or knockdown of miR-6747-3p to explore its role in cell apoptosis. The results indicated that the apoptosis rate was increased in the miR-6747-3p mimic group in both HUDEP-2 and K562 cells (P<0.5). By contrast, the group treated with the miR-6747-3p inhibitor had a lower rate of apoptosis than the group treated with the NC inhibitor (P<0.5; Fig. 2E and F). The aforementioned results indicate that miR-6747-3p induces cell cycle arrest and apoptosis, thereby reducing cell proliferation.

The transferrin receptor CD71 is abundantly present in early erythroid cells, whereas the surface marker CD235a becomes more prominent as erythroblasts mature (34). After 14 days of terminal differentiation, flow cytometry analysis revealed that 71.3±2.77% of the differentiated erythroid precursors in the miR-6747-3p mimic group expressed CD71/CD235a, a notably higher percentage compared with the NC mimic group (65.3±2.20%; Fig. 3A), while the cell differentiation rate was reduced in HUDEP-2 cells treated with the miR-6747-3p inhibitor compared with the NC inhibitor group (69.5±3.35% vs. 81.2±2.66%; Fig. 3B).

Wright-Giemsa was applied to stain cultivated erythroblasts. Morphological analysis of HUDEP-2 cells using miR-6747-3p mimics revealed a concomitant increase in Orth-E (Fig. 3C), whereas the miR-6747-3p inhibitor group failed to progress beyond the Poly-E stage of differentiation at day 14 (Fig. 3D).

After 96 h of co-culture with hemin, the miR-6747-3p mimic group showed a greater percentage of positive K562 cells in the Benzidine blue staining compared with the NC group. In Fig. 3E, the miR-6747-3p inhibitor group showed a lower positive rate than the NC inhibitor group. Flow cytometry results showed a rise in CD71/CD235a⁺ cells in the miR-6747-3p mimic group compared with the NC group while the differentiation rate of the miR-6747-3p inhibitor group was lower than that of NC inhibitor group (Fig. 3F), indicating that miR-6747-3p speeds up erythroid differentiation.

It was previously confirmed that miR-6747-3p can enhance the development of HUDEP-2 and K562 cells, and is associated with the levels of HbF in patients with β-TM. Next, F-cell detection in HUDEP-2 cells was performed to further confirm whether miR-6747-3p could regulate the expression of HbF. The expression of HbF was subsequently quantified after 14 days of differentiation in each group. The results indicated that miR-6747-3p could strongly induce γ-globin in erythroid precursor cells. The miR-6747-3p mimic group (55.1±0.76%) had significantly higher HbF expression than the NC group (47.1±0.62%; P<0.05), while the miR-6747-3p inhibitor group had significantly lower HbF expression (44.0±0.47% vs. 37.2±1.80%; P<0.05; Fig. S2).

TargetScan, miRwalk and miRDB were employed to forecast the mRNA targets of miR-6747-3p to illustrate the molecular mechanism of generating HbF expression. According to the results, the anticipated target mRNA numbers were 820, 6,247 and 4,392, according to the sequence. Among the three programs, a total of 326 mRNA targets were shared (Fig. 4A). The erythroid-related transcription factor BCL11A was selected as a possible target gene for previous publications showing the negative regulation of HbF (35–39). RT-qPCR was used to measure BCL11A mRNA levels. The results showed that, in comparison to normal controls, patients with β-TM had considerably lower levels of BCL11A mRNA (Fig. 4B). Furthermore, BCL11A mRNA was found to have a negative correlation with both γ-globin (r=−0.637; P<0.05; Fig. 4C) and miR-6747-3p (r=−0.567; P<0.05; Fig. 4D). In addition, the colocalization of miR-6747-3p and BCL11A in HUDEP-2 cells was confirmed by fluorescence in situ hybridization assay (Fig. 4E), suggesting that the target gene of miR-6747-3p was BCL11A.

Whether miR-6747-3p directly interacts with BCL11A was also examined. The CCGUCC binding site in miR-6747-3p targeting GCAGGA in BCL11A 3′-UTR was identified using Targetscan (Fig. 4F). Thus, HUDEP-2 cells were co-transfected with miR-6747-3p mimic and a pmiR-RB-REPORT^™ plasmid with the wild-type BCL11A 3′-UTR. The miR-6747-3p mimic significantly decreased the luciferase activity, according to the results. This interaction was further validated by demonstrating that it was eliminated when the BCL11A 3′-UTR binding region was mutated from GCAGGA to CCGTCC (Fig. 4G). By contrast, the luciferase activity of the BCL11A seed region was notably higher in the miR-6747-3p inhibitor group, with no significant change observed in the mutant group. Briefly, miR-6747-3p was able to directly attach to the 546–552 loci of the BCL11A 3′-UTR.

Fig. 5 illustrates how the transfection of miR-6747-3p mimics into HUDEP-2 (Fig. 5A) and K562 (Fig. 5B) cells reduces BCL11A transcripts and increases γ-globin mRNA levels. Notably, a >2-fold elevation of BCL11A mRNA in HUDEP-2 (Fig. 5C) and K562 (Fig. 5D) cells in the miR-6747-3p inhibitor group was observed, while γ-globin mRNA expression was significantly decreased. These results were also corroborated at the protein level. Western blot analysis showed a notable increase in BCL11A protein levels in the miR-6747-3p inhibitor group compared with the NC inhibitor group, while γ-globin levels were significantly decreased (Fig. 5E and F). These findings indicate that miR-6747-3p can inhibit the expression of BCL11A in both HUDEP-2 and K562 cells.