Maternal microchimerism in peripheral blood in type 1 diabetes and pancreatic islet beta cell microchimerism.

Maternal cells have recently been found in the circulation and tissues of mothers' immune-competent children, including in adult life, and is referred to as maternal microchimerism (MMc). Whether MMc confers benefits during development or later in life or sometimes has adverse effects is unknown. Type 1 diabetes (T1D) is an autoimmune disease that primarily affects children and young adults. To identify and quantify MMc, we developed a panel of quantitative PCR assays targeting nontransmitted, nonshared maternal-specific HLA alleles. MMc was assayed in peripheral blood from 172 individuals, 94 with T1D, 54 unaffected siblings, and 24 unrelated healthy subjects. MMc levels, expressed as the genome equivalent per 100,000 proband cells, were significantly higher in T1D patients than unaffected siblings and healthy subjects. Medians and ranges, respectively, were 0.09 (0-530), 0 (0-153), and 0 (0-7.9). Differences between groups were evident irrespective of HLA genotypes. However, for patients with the T1D-associated DQB1*0302-DRB1*04 haplotype, MMc was found more often when the haplotype was paternally (70%) rather than maternally transmitted (14%). In other studies, we looked for female islet beta cells in four male pancreases from autopsies, one from a T1D patient, employing FISH for X and Y chromosomes with concomitant CD45 and beta cell insulin staining. Female islet beta cells (presumed maternal) formed 0.39-0.96% of the total, whereas female hematopoietic cells were very rare. Thus, T1D patients have higher levels of MMc in their circulation than unaffected siblings and healthy individuals, and MMc contributes to islet beta cells in a mother's progeny.

Maternal microchimerism in healthy adults in lymphocytes, monocyte/macrophages and NK cells.

During pregnancy some maternal cells reach the fetal circulation. Microchimerism (Mc) refers to low levels of genetically disparate cells or DNA. Maternal Mc has recently been found in the peripheral blood of healthy adults. We asked whether healthy women have maternal Mc in T and B lymphocytes, monocyte/macrophages and NK cells and, if so, at what levels. Cellular subsets were isolated after fluorescence activated cell sorting. A panel of HLA-specific real-time quantitative PCR assays was employed targeting maternal-specific HLA sequences. Maternal Mc was expressed as the genome equivalent (gEq) number of microchimeric cells per 100,000 proband cells. Thirty-one healthy adult women probands were studied. Overall 39% (12/31) of probands had maternal Mc in at least one cellular subset. Maternal Mc was found in T lymphocytes in 25% (7/28) and B lymphocytes in 14% (3/21) of probands. Maternal Mc levels ranged from 0.9 to 25.6 and 0.9 to 25.3 gEq/100,000 in T and B lymphocytes, respectively. Monocyte/macrophages had maternal Mc in 16% (4/25) and NK cells in 28% (5/18) of probands with levels from 0.3 to 36 and 1.8 to 3.2 gEq/100,000, respectively. When compared to fetal Mc, as assessed by quantification of male DNA in women with sons, maternal Mc was substantially less prevalent in all cellular subsets; fetal Mc prevalence in T and B lymphocytes, monocyte/macrophages and NK cells was 58, 75, 50 and 62% (P=0.01, P=0.005, P=0.04, P=0.05) respectively. In summary, maternal Mc was identified among lymphoid and myeloid compartments of peripheral blood in healthy adult women. Maternal Mc was less frequent than fetal Mc in all cellular subsets tested. Studies are needed to investigate the immunological effects and function of maternal Mc and to explore whether maternal Mc in cellular subsets has biological effects on her progeny.

Quantification of maternal microchimerism by HLA-specific real-time polymerase chain reaction: studies of healthy women and women with scleroderma.

OBJECTIVE: Microchimerism (Mc), originating from bidirectional fetal-maternal cell traffic during pregnancy, has recently been identified in healthy adults and in patients with scleroderma (systemic sclerosis [SSc]). This study was undertaken to investigate the frequency and quantitative levels of maternal Mc (MMc) in healthy women and women with SSc. METHODS: HLA-specific primers and fluorogenic probes were used in real-time quantitative polymerase chain reaction assays to detect and quantify MMc by targeting noninherited, nonshared HLA sequences. DNA-based HLA typing was conducted in 67 proband-mother pairs and in all children if the proband was parous. Statistical analysis was limited to 50 proband-mother pairs (including 32 healthy women and 18 women with SSc) in whom MMc could be distinguished from potential fetal Mc. RESULTS: MMc in peripheral blood mononuclear cells was more frequent among women with SSc (72%) than healthy women (22%) (odds ratio 9.3, P = 0.001). However, levels of MMc, expressed as the genome equivalent of maternal cells per million (gEq/mil), were not significantly different (0-68.6 gEq/mil in SSc patients, 0-54.5 in healthy women). In additional studies, positivity for MMc was demonstrated in a bone marrow aspirate from an SSc patient in whom peripheral blood had been found to be negative for MMc on 4 occasions, and tissue from a subsequent autopsy of this patient had MMc levels of 757 and 1,489 gEq/mil in the lung and heart, respectively. CONCLUSION: MMc is not uncommon in the peripheral blood of healthy adults, is increased in frequency in patients with SSc, and may be present in bone marrow and disease-affected tissues although absent in the peripheral blood.

Male DNA in female donor apheresis and CD34-enriched products.

Increased risk of graft-versus-host disease (GVHD) has been described in recipients of hematopoietic stem cell transplantations when the donor is a parous woman. Cells from prior pregnancies are now known to persist in women and could contribute to GVHD. We asked whether male DNA (presumed fetal microchimerism) is present in apheresis products of female donors. A total of 50 samples were studied by using real-time quantitative polymerase chain reaction (PCR) for the Y chromosome-specific sequence DYS14. Among 29 growth factor-mobilized peripheral blood mononuclear cell (G-PBMC) products, 34% were positive for male DNA. Quantitative results, expressed as DNA genome equivalent of male cells per million host cells (gEq/mil), ranged from 0 to 35 gEq/mil. Among 21 CD34-enriched cell fractions, 48% were positive with a range of 0 to 357 gEq/mil. In summary, male DNA was frequently detected in G-PBMC and CD34-enriched products from female donors. Whether fetal microchimerism contributes to GVHD merits further investigation.

Male microchimerism in healthy women and women with scleroderma: cells or circulating DNA? A quantitative answer.

Male DNA, of presumed fetal origin, can be detected in the maternal circulation decades after delivery and is referred to as fetal microchimerism (FM). We previously found quantitatively greater FM in the circulation of women with the autoimmune disease scleroderma (SSc) than of healthy women. However, it is unknown whether this difference is due to intact circulating cells or free DNA released from breakdown in disease-affected tissues. To distinguish the origin of FM, we developed a real-time quantitative polymerase chain reaction (PCR) assay for the Y-chromosome-specific sequence DYS14, and tested 114 women in peripheral blood mononuclear cells (PBMCs) and/or plasma. Fifty-seven controls and 57 SSc patients were studied, 48 and 43 of whom, respectively, had given birth to at least one son. Circulating FM was quantitatively greater in PBMCs from SSc patients (n = 39; range, 0.0-12.5 male genome-equivalent cells per million maternal cells), compared with healthy women (n = 39; range, 0.0-4.4; P =.03). In contrast, there was no difference between patients (n = 25) and controls (n = 22) in plasma, and no evidence of free DNA. FM was enriched among T lymphocytes compared with PBMCs (P =.01) in controls (n = 14), but not in SSc patients (n = 14); the latter finding was most likely due to immunosuppressive medications. In conclusion, this real-time quantitative assay showed that quantitative differences in the circulation of women with SSc are due to cells and not to free DNA. As FM was not uncommon in healthy women, including among T cells, and because graft-versus-host disease has similarities to SSc, these results also suggest that FM merits investigation in pheresis products used for stem cell transplantation.