Abstract
Aplastic anemia (AA) is believed to be an autoimmune disorder characterized by the pancytopenia due to the depletion of hematopoietic stem and progenitor cells in the bone marrow. There are three forms of AA depending on the severity of pancytopenia: moderate, or non-severe AA (NAA), severe AA (SAA), and very severe AA (VSAA). Clones of cells typical for paroxysmal nocturnal hemoglobinuria (PNH-clones) are frequently present in AA patients in various proportions.
We aimed to study stromal microenvironment of untreated AA patients depending on the AA severity, presence or absence of PNH-clone, and on the response to the therapy after 3 and 6 months of treatment. We analyzed the bone marrow (BM) multipotent mesenchymal stromal cells (MMSCs) in their ability to maintain hematopoietic precursors and examined relative expression levels (REL) of selected genes.
The study included 17 patients with NAA (53% females, 47% males, 33.8±2.2 years old), 12 patients with SAA (33% females, 67% males, 29.3±3.8 years old). Among NAA patients 7 had PNH-clone, and among SAA - 6 patients. Control group consisted of 19 donors (42% females, 58% males, 30.4±3.1 years old). The ability to support hematopoietic precursors by MMSCs from the BM of AA patients was measured by cobble stone area forming cells (CAFC) assay, where BM cells from one healthy donor were seeded on different MMSCs; REL of selected genes was analyzed with TaqMan RT-PCR. Only the genes with statistically significant differences are presented. The data are presented as mean ± standard error of measures, the differences were statistically significant when p<0.05 when Student's unpaired t-test or Mann-Whitney test was applied.
MMSCs from AA patients preserve their ability to maintain hematopoietic precursors. CAFC 7 frequency reflects the number of late hematopoietic precursors. CAFC 7 frequency was slightly higher on MMSCs from NAA patients (9.92±2.73 per 10 6 healthy BM cells) then on MMSCs from healthy donors (5.56±1.14 per 10 6 healthy BM cells), although the difference was not statistically significant. MMSCs from SAA patients maintained CAFC 7 as well as donors' MMSCs (6.75±1.96 per 10 6 healthy BM cells). The frequency of CAFC 28, reflecting the number of early hematopoietic precursor, displayed similar but more pronounced dynamics. CAFC 28 frequency on NAA patients' MMSCs was significantly higher than on donors' ones (2.17±0.34 versus 1.11±0.31 per 10 6 healthy BM cells, p=0.03), while on SAA patients' MMSCs it was also high (1.92±0.57 per 10 6 healthy BM cells) but the difference was insignificant (Table 1). The presence of PNH-clone does not affect the ability of stromal cells to maintain hematopoiesis. MMSCs from the patients that had responded to the therapy in 90 or 180 days did not differ in their ability to maintain hematopoietic precursors from the MMSCs of treatment resistant the patients. Therefore, we can assume that physiological function of stromal microenvironment is not affected deeply in the debut of AA.
Gene expression analysis revealed statistically significant upregulation of FGFR1, PDGFRA, VEGFA and downregulation of ANG1 (in MMSCs from both NAA and SAA patients), and upregulation of FGFR2 and CFH (only in NAA patients' MMSCs) (Table 2). In MMSCs of AA patients (both NAA and SAA) without PNH-clone the upregulation of CFH gene was detected (Table 3). CFH is one of the players in the complement system which is disrupted in PNH. This fact needs to be further scrutinized. In addition, IL1R, SDF1 and VEGFA were statistically significantly downregulated in MMSCs from AA patients with PNH-clone compared with MMSCs from patients without PNH-clone. It seems that the presence of PNH-clone corresponds with the changes in stromal microenvironment. Gene expression of analyzed genes was the same in MMSCs of the patients that had responded or not responded to the treatment in 90 or 180 days since the therapy begun.
Thus, MMSCs from the BM of untreated AA patients preserve their ability to support hematopoietic precursors however display the pronounced changes in gene expression.
The work is supported by the RFBR, project 19-015-00280.
No relevant conflicts of interest to declare.
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