Blood fetal microchimerism in primary biliary cirrhosis

The autoimmune nature of primary biliary cirrhosis (PBC) is well established. We tested the hypothesis that fetal microchimerism indicated by the persistence of circulating fetal cells in women years after pregnancy might contribute to the aetiopathogenesis of PBC through a graft-versus-host-like response. We extracted DNA from the peripheral blood cells of 36 women carefully selected from 173 consecutive PBC patients, who were matched with 36 healthy women by age, age of last son, and number of children. Both patients and controls had to have male offspring, and no history of miscarriages or blood transfusions; they could not be twins. We tested all of the samples for the presence of two specific Y-chromosome sequences (SY154 and SRY) by amplifying DNA in a nested polymerase chain reaction. Y-chromosome-specific DNA was detected in the peripheral blood cell DNA of 13 (36%) of the 36 women with PBC and in 11 (31%) of the 36 healthy controls. The two groups of PBC patients with and without male DNA sequences were similar in terms of their clinical, biochemical, and serological features. Y-chromosome sequences were found in three of the four PBC women with associated systemic sclerosis. All of the 24 Y-positive samples contained SY154 sequences, but only three PBC patients and six controls showed the presence of both SY154 and SRY sequences. This discrepancy may suggest that not only fetal cells but also fragments of fetal DNA are present in maternal circulation. Overall, our data do not support the hypothesis that fetal microchimerism plays a significant role in the onset or progression of PBC.     

Maternal microchimerism—Allogenic target of autoimmune disease or Normal Biology?

Chimerism is the state of cells from two distinct individuals living within one body. Fetal cells pass into a mother during pregnancy, where they may persist at low levels for years, creating a state of fetal microchimerism. At the same time, maternal cells pass into the fetus, leading to maternal microchimerism that can persist into adulthood. Hematopoietic stem cell transplantation also creates a state of chimerism, and can lead to a complication of chronic multi-organ inflammation called graft-versus-host disease, (GVHD). The similarities between GVHD and some autoimmune diseases like scleroderma, lupus and myositis suggest that chimerism may be involved in the pathogenesis of both. Maternal and fetal microchimerism in the blood and in tissues have been associated with autoimmune diseases. However, many healthy individuals harbor maternal and fetal cells. Human and animal studies have begun to elucidate the mechanisms for normal tolerance to maternal and fetal microchimeric cells, and how this tolerance may be broken in states of chronic inflammatory disease.     

单链DNA抗体胶乳试验对结缔组织疾病的诊断价值

本文介绍一种新的检测ss-DNA抗体的胶乳试验。60名正常人结果全部阴性。ss-DNA抗体见于 66％(80/122)结缔组织病患者,其中 SLE阳性率为 70％(72/104),硬皮病43％(3/7),皮肌炎80％(4/5)。在SLE,胶乳单链 DNA 抗体试验与荧光 ANA 法二者结果的一致性为73％,该法ss-DNA 抗体与放免法ds-DNA抗体二者的一致性高达82％。由此可见胶乳ss-DNA抗体试验为诊断结缔组织病的一种敏感而特异的实验方法。     

Skewed X-Chromosome Inactivation in Scleroderma

Scleroderma is a female-prevalent autoimmune disease of unclear etiology. Two fundamental gender differences, skewed X-chromosome inactivation (XCI) and pregnancy-related microchimerism, have been implicated in scleroderma. We investigated the XCI patterns of female scleroderma patients and the parental origin of the inactive X chromosome in those patients having skewed XCI patterns (>80%). In addition, we investigated whether a correlation exists between XCI patterns and microchimerism in a well-characterized cohort. About 195 female scleroderma patients and 160 female controls were analyzed for the androgen receptor locus to assess XCI patterns in the DNA extracted from peripheral blood cells. Skewed XCI was observed in 67 (44.9%) of 149 informative patients and in 10 of 124 healthy controls (8.0%) [odds ratio (OR) = 9.3 (95% confidence interval (CI) 4.3-20.6, P < 0.0001)]. Extremely skewed XCI (>90%) was present in 44 of 149 patients (29.5%) but only in 3 of 124 controls (2.4%; OR = 16.9; 95% CI 4.8-70.4, P < 0.0001). Parental origin of the inactive X chromosome was investigated for ten patients for whom maternal DNA was informative, and the inactive X chromosome was of maternal origin in eight patients and of paternal origin in two patients. Skewed XCI mosaicism could be considered as an important risk factor in scleroderma.     

A confocal microscopy study of anticytoskeletal antibody activity in patients with connective tissue disease.

The significance of the presence of antibodies to cytoskeleton proteins in patients with connective tissue diseases is not clear, as there is a high level of these antibodies in healthy controls. In an attempt to improve the visualization of the immunofluorescence binding pattern of autoantibodies to cytoskeletal structures in cultured fibroblasts, we have used confocal microscopy. Of the 256 serum samples tested, 155 (61%) WERE reactive with cytoplasmic structures. These reactive samples could be divided into seven patterns of binding, as determined by double-blind examination of single-section confocal images. While confirming the results of previous immunofluorescence studies which have shown that autoantibodies that bind to filamentous structures in the cytoplasm of cultured cells are common in patients with connective tissue diseases, we were able to identify three patterns of cytoskeletal binding which may be useful as an adjunct to other tests for the diagnosis of some connective tissue diseases, in particular systemic sclerosis (scleroderma) and rheumatoid arthritis/Sjogren's syndrome. None of the seven patterns was exclusive to a particular disease. We conclude that confocal microscopy may be of limited use as an adjunct to other serological assays in the diagnosis of some forms of connective tissue disease.     

Autoimmune Disease During Pregnancy and the Microchimerism Legacy of Pregnancy

Pregnancy has both short-term effects and long-term consequences on the maternal immune system. For women who have an autoimmune disease and subsequently become pregnant, pregnancy can induce amelioration of the mother's disease, such as in rheumatoid arthritis, while exacerbating or having no effect on other autoimmune diseases like systemic lupus erythematosus. That pregnancy also leaves a long-term legacy has recently become apparent by the discovery that bi-directional cell trafficking results in persistence of fetal cells in the mother and of maternal cells in her offspring for decades after birth. The long-term persistence of a small number of cells (or DNA) from a genetically disparate individual is referred to as microchimerism. While microchimerism is common in healthy individuals and is likely to have health benefits, microchimerism has been implicated in some autoimmune diseases such as systemic sclerosis. In this paper, we will first discuss short-term effects of pregnancy on women with autoimmune disease. Pregnancy-associated changes will be reviewed for selected autoimmune diseases including rheumatoid arthritis, systemic lupus erythematosus and autoimmune thyroid disease. The pregnancy-induced amelioration of rheumatoid arthritis presents a window of opportunity for insights into both immunological mechanisms of fetal-maternal tolerance and pathogenic mechanisms in autoimmunity. A mechanistic hypothesis for the pregnancy-induced amelioration of rheumatoid arthritis will be described. We will then discuss the legacy of maternal-fetal cell transfer from the perspective of autoimmune diseases. Fetal and maternal microchimerism will be reviewed with a focus on systemic sclerosis (scleroderma), autoimmune thyroid disease, neonatal lupus and type I diabetes mellitus.     

Analyzing HLA-G polymorphisms in children from women with scleroderma

Embryos during pregnancy and organs during transplantation, express high levels of soluble HLA-G (sHLA-G) molecules for successful implantation and protection against maternal immune cells or recipient’s cells. We and others have shown that women with scleroderma (SSc) carry cells/DNA arising from pregnancy, so-called fetal microchimerism (Mc) more often and in higher quantities than healthy women decades after delivery.     

Fetal-maternal microchimerism: impact on hematopoietic stem cell transplantation

Reciprocal cell traffic between mother and fetus during pregnancy gives rise to postpartum fetal-maternal lymphohematopoietic microchimerism, which is frequently detected in blood or tissue from healthy individuals. Although such microchimerism has been implicated in the pathogenesis of autoimmune diseases and tissue repair, recent clinical experiences have suggested the association of microchimerism with acquired immunologic hyporesponsiveness to non-inherited maternal HLA antigens (NIMAs) or inherited paternal HLA antigens (IPAs); T cell-replete HLA-haploidentical hematopoietic stem cell transplantation from a microchimeric IPA/NIMA-mismatched donor confers relatively lower incidence of severe graft-versus-host disease. The underlying mechanisms by which fetal-maternal microchimerism contributes to IPA/NIMA-specific tolerance are still elusive, although emerging experimental evidence suggests an involvement of the central deletion of IPA/NIMA-reactive T cells, the induction of peripheral regulatory T cells, and affinity-dependent modulation of NIMA-reactive B cells.     

Microchimerism in Human Health and Disease

During pregnancy some cells traffic between the fetus and the mother. Recent investigative work indicates a low level of fetal cells commonly persists in the maternal circulation for years, or even indefinitely, after pregnancy has been completed. The term microchimerism refers to one individual harboring DNA or cells at a low level that derive from another individual. Chronic graft-versus-host disease (cGvHD) shares similarities with some autoimmune diseases and is an iatrogenic form of chimerism, occurring as a complication of hematopoietic stem cell transplantation. The HLA genes of the donor and the host are known to be of central importance to the development of cGvHD. When also considered in light of the female predilection to autoimmunity, these series of observations led to the hypothesis that microchimerism and HLA genes of host and non-host cells are involved in some autoimmune diseases. The hypothesis can also apply to men, children, and women who have not been pregnant because there are other sources of microchimerism. Persistent microchimerism can follow a blood transfusion, or can occur from transfer between twins in utereo. Additionally, maternal cells have recently been found to persist in her immune competent progeny. A number of studies have investigated a potential role of microchimerism in human diseases including systemic sclerosis (SSc), primary biliary cirrhosis (PBC), Sjögren's syndrome, polymorphic eruption of pregnancy, myositis, and thyroid disease. While some studies lend support to the concept that microchimerism is involved in the pathogenesis of selected autoimmune diseases, studies also indicate microchimerism is not uncommon in other human conditions and in healthy individuals.     

Autoimmune disease during pregnancy and the microchimerism legacy of pregnancy

Pregnancy has both short-term effects and long-term consequences on the maternal immune system. For women who have an autoimmune disease and subsequently become pregnant, pregnancy can induce amelioration of the mother's disease, such as in rheumatoid arthritis, while exacerbating or having no effect on other autoimmune diseases like systemic lupus erythematosus. That pregnancy also leaves a long-term legacy has recently become apparent by the discovery that bi-directional cell trafficking results in persistence of fetal cells in the mother and of maternal cells in her offspring for decades after birth. The long-term persistence of a small number of cells (or DNA) from a genetically disparate individual is referred to as microchimerism. While microchimerism is common in healthy individuals and is likely to have health benefits, microchimerism has been implicated in some autoimmune diseases such as systemic sclerosis. In this paper, we will first discuss short-term effects of pregnancy on women with autoimmune disease. Pregnancy-associated changes will be reviewed for selected autoimmune diseases including rheumatoid arthritis, systemic lupus erythematosus and autoimmune thyroid disease. The pregnancy-induced amelioration of rheumatoid arthritis presents a window of opportunity for insights into both immunological mechanisms of fetal-maternal tolerance and pathogenic mechanisms in autoimmunity. A mechanistic hypothesis for the pregnancy-induced amelioration of rheumatoid arthritis will be described. We will then discuss the legacy of maternal-fetal cell transfer from the perspective of autoimmune diseases. Fetal and maternal microchimerism will be reviewed with a focus on systemic sclerosis (scleroderma), autoimmune thyroid disease, neonatal lupus and type I diabetes mellitus.     

Prostaglandin-mediated inhibition of lymphokine secretion in normal individuals and patients with progressive systemic sclerosis (scleroderma,PSS)

The sensitivity of peripheral blood lymphocytes to E-type prostaglandin-mediated inhibition of lymphokine secretion was examined in 3 groups of individuals; normal controls, hospitalized patients, and patients with progressive systemic sclerosis (PSS, scleroderma). Leukocytes were stimulated by a polyclonal T-cell activator, phytohemagglutinin, and the release of the lymphokine, leukocyte migration inhibitory factor (LIF), was measured in the presence or absence of exogenous PGE₂ using a direct agarose droplet migration inhibition technique. Leukocytes of sclerodema patients were found to be hyporesponsive to E-type prostaglandin (i.e., lymphokine secretion by these cells was not inhibited at concentrations of PGE₂ between 2.8×10^–8 and 2.8×10^–5 M). In addition, a marked sex difference in PGE responsiveness was found to exist among normal controls, whereby females were hyporesponsive during the latter half of the mentrual cycle. It is possible that this deficit may facilitate, in part, the development of connective tissue diseases in women of childbearing age. The inability to suppress lymphokine production and arrest persistent immune reactivity, coupled with the known ability of lymphokines to augment fibroblast collagen production, offers a reasonable explanation for the accumulation of tissue collagen in scleroderma.     

Chimerism in health and potential implications on behavior: A systematic review

In this review, we focus on the phenomenon of chimerism and especially microchimerism as one of the currently underexplored explanations for differences in health and behavior. Chimerism is an amalgamation of cells from two or more unique zygotes within a single organism, with microchimerism defined by a minor cell population of <1%. This article first presents an overview of the primary techniques employed to detect and quantify the presence of microchimerism and then reviews empirical studies of chimerism in mammals including primates and humans. In women, male microchimerism, a condition suggested to be the result of fetomaternal exchange in utero, is relatively easily detected by polymerase chain reaction molecular techniques targeting Y‐chromosomal markers. Consequently, studies of chimerism in human diseases have largely focused on diseases with a predilection for females including autoimmune diseases, and female cancers. We detail studies of chimerism in human diseases and also discuss some potential implications in behavior. Understanding the prevalence of chimerism and the associated health outcomes will provide invaluable knowledge of human biology and guide novel approaches for treating diseases.     

Microchimerism in human health and disease

During pregnancy some cells traffic between the fetus and the mother. Recent investigative work indicates a low level of fetal cells commonly persists in the maternal circulation for years, oreven indefinitely, after pregnancy has been completed. The term microchimerism refers to one individual harboring DNA or cells at a low level that derive from another individual. Chronic graft-versus-host disease (cGvHD) shares similarities with some autoimmune diseases and is an iatrogenic form of chimerism, occurring as a complication of hematopoietic stem cell transplantation. The HLA genes of the donor and the host are known to be of central importance to the development of cGvHD. When also considered in light of the female predilection to autoimmunity, these series of observations led to the hypothesis that microchimerism and HLA genes of host and non-host cells are involved in some autoimmune diseases. The hypothesis can also apply to men, children, and women who have not been pregnant because there are other sources of microchimerism. Persistent microchimerism can follow a blood transfusion, or can occur from transfer between twins in utereo. Additionally, maternal cells have recently been found to persist in her immune competent progeny. A number of studies have investigated a potential role of microchimerism in human diseases including systemic sclerosis (SSc), primary biliary cirrhosis (PBC), Sj?gren's syndrome, polymorphic eruption of pregnancy, myositis, and thyroid disease. While some studies lend support to the concept that microchimerism is involved in the pathogenesis of selected autoimmune diseases, studies also indicate microchimerism is not uncommon in other human conditions and in healthy individuals.     

Fetomaternal cell trafficking: a new cause of disease?

Isolation of fetal cells from maternal blood is under active investigation as a noninvasive method of prenatal diagnosis. In the context of studying cell surface antigens expressed on fetal cells we discovered that fetal cells from a prior pregnancy also could be detected. This led to the appreciation of the persistence of fetal cells in maternal blood for as long as 27 years postpartum, and the realization that following pregnancy, a woman becomes a chimera. Quantitative polymerase chain reaction analyses have shown that a term pregnancy is not required for the subsequent development of fetal cell microchimerism. As many as 500,000 fetal nucleated cells are transfused following an elective first trimester termination of pregnancy. The relationship between fetal cell microchimerism and maternal disease is currently being explored. During pregnancy, fetal cells in the maternal skin are related to polymorphic eruptions of pregnancy and increased fetomaternal trafficking is detectable in cases of preeclampsia. After delivery, more male DNA of presumed fetal origin is present in the blood and skin of women with scleroderma as compared with healthy controls. Scleroderma is of particular interest because it shows a strong female predilection and it is an autoimmune disease with clinical similarities to graft-versus-host disease. Fetomaternal cell trafficking provides a potential explanation for the increased prevalence of autoimmune disorders in adult women following their childbearing years.     

Fetal microchimerism and autoimmune disease

Microchimerism is defined by the presence of circulating cells, bi-directionally transferred from one genetically distinct individual to another. The acquisition and persistence of fetal cell microchimerism, small numbers of genetically disparate cells from the fetus in the mother, is now a well-recognized consequence of normal pregnancy. Some of the autoimmune diseases that show a predilection for women in their child-bearing years and beyond are linked to fetal microchimerism from previous pregnancies. Microchimerism has been investigated in different autoimmune disorders, such as systemic sclerosis, systemic lupus erythematosus, autoimmune thyroid diseases, and primary biliary cirrhosis. Recent data have demonstrated the promising role of microchimeric cells in the maternal response to tissue injuries by differentiating into many lineages. Therefore, further understanding of fetal-maternal microchimerism may help in anticipating its implications in disease as well as in more general women's health issues.     

T-cell subpopulations in the peripheral blood of patients with connective tissue diseases as determined by flow cytometry using monoclonal antibodies

We studied by flow cytometry using monoclonal antibodies the T3, T4, and T8 subpopulations of T cells in the peripheral blood of 109 patients with various connective tissue diseases who were not receiving any treatment. Comparison of the results was made with those obtained with normal controls matched for age and sex with each connective tissue disease group. When compared as disease groups, patients with systemic lupus erythematosus (n = 41) had decreased T8 cells, but patients with active disease (n = 17) had all three T-cell subpopulations lower than their controls, whereas those with inactive disease (n = 24) showed no differences. Patients with rheumatoid arthritis (n = 23) had decreased T3 and T8 cells, whereas patients with scleroderma (n = 22) only had decreased T3 cells, and patients with primary Sj?gren's syndrome (n = 15) had lower proportions of all three T-cell subpopulations than their matched controls. Patients with mixed connective tissue disease (n = 8) had proportions of all three T-cell subpopulations akin to those of their matched controls, but showed a tendency to have decreased T8 cells that reached statistical significance when compared to the entire control group. Although our findings tend to support the notion that the abnormalities in immunoregulatory T-cell circuits leading to autoimmunity are different in each connective tissue disease, the great variability found in both patients and controls seems to preclude the use of these determinations in individual patients for clinical purposes.     

Microchimerism in autoimmune disease: more questions than answers?

Recent studies indicate cell traffic occurs between the fetus and mother during pregnancy and that low numbers of fetal cells commonly persist in the maternal circulation for years thereafter. Microchimerism refers to a small number of cells or DNA from one individual harbored in another individual. Autoimmune diseases are more common among women and often increase in incidence following reproductive years. Chronic graft vs. host disease is an iatrogenic form of chimerism with similarities to some autoimmune diseases for which the HLA relationship of donor and host are of central importance. When considered together, these observations led to the hypothesis that microchimerism and HLA relationships of host and non-host cells are involved in autoimmune disease. The hypothesis is applicable to men, children and women without pregnancies because there are other sources of microchimerism, including from a twin, the mother or a blood transfusion. Microchimerism has now been investigated in a number of different diseases with some results supporting a potential role in disease pathogenesis. However, fetal and maternal microchimerism are also found in organs affected by non-autoimmune conditions. Moreover, microchimerism is commonly detected in the peripheral blood of healthy individuals raising the intriguing question of whether these cells are simple remnants of pregnancy or whether they might also have beneficial effects for the host.     

唐氏综合征高危孕妇血浆游离胎儿DNA的检测

目的探讨实时荧光定量PCR(RQ-PCR)检测孕妇血浆游离胎儿DNA;在筛查唐氏综合征高危孕妇中的应用。方法采用RQ-PCR检测22例唐氏综合征高危孕妇及20例低危孕妇血浆中GA;PDH及SRY水平,2-△△Ct法分析两组间的差异。结果 22例孕男胎均检出SRY基因,20例孕女胎中出现2例假阳性,高危组游离胎儿DNA;水平明显高于低危组(P=0.006,<0.05),比值为2.79。结论孕妇血浆游离胎儿DNA;的定量检测在唐氏综合征筛查中有重要价值。     

Fetomaternal cell trafficking: A new cause of disease?

Isolation of fetal cells from maternal blood is under active investigation as a noninvasive method of prenatal diagnosis. In the context of studying cell surface antigens expressed on fetal cells we discovered that fetal cells from a prior pregnancy also could be detected. This led to the appreciation of the persistence of fetal cells in maternal blood for as long as 27 years postpartum, and the realization that following pregnancy, a woman becomes a chimera. Quantitative polymerase chain reaction analyses have shown that a term pregnancy is not required for the subsequent development of fetal cell microchimerism. As many as 500,000 fetal nucleated cells are transfused following an elective first trimester termination of pregnancy. The relationship between fetal cell microchimerism and maternal disease is currently being explored. During pregnancy, fetal cells in the maternal skin are related to polymorphic eruptions of pregnancy and increased fetomaternal trafficking is detectable in cases of preeclampsia. After delivery, more male DNA of presumed fetal origin is present in the blood and skin of women with scleroderma as compared with healthy controls. Scleroderma is of particular interest because it shows a strong female predilection and it is an autoimmune disease with clinical similarities to graft‐versus‐host disease. Fetomaternal cell trafficking provides a potential explanation for the increased prevalence of autoimmune disorders in adult women following their childbearing years. Am. J. Med. Genet. 91:22–28, 2000. © 2000 Wiley‐Liss, Inc.     

Microchimerism in recurrent miscarriage

Maternal-fetal cell exchange during pregnancy results in acquisition of microchimerism, which can durably persist in both recipients. Naturally acquired microchimerism may impact maternal-fetal interaction in pregnancy. We conducted studies to ask whether microchimerism that a woman acquired from her own mother is detectable before or during pregnancy in women with recurrent miscarriage. Fetal microchimerism was also assayed. Women with primary idiopathic recurrent miscarriage （n=23） and controls （n=31） were studied. Genotyping was conducted for probands, their mothers and the fetus, a non-shared polymorphism identified and quantitative polymerase chain reaction performed to measure microchimerismin peripheral blood mononuclear cells. Preconception comparisons were made between recurrent miscarriage subjects and controls, using logistic regression and Wilcoxon rank sum. Longitudinal microchimerism in subsequent pregnancies of recurrent miscarriage subjects was described. There was a trend toward lower preconception detection of microchimerism in recurrent miscarriage versus controls, 6% vs. 19% （1/16 vs. 6/31, P=0.2）. During pregnancy, 3111 （27%） of recurrent miscarriage subjects who went on to have a birth had detection of microchimerism from their own mother, whereas neither of two subjects who went on to miscarry had detection （0/2）. This initial data suggest that microchimerism from a woman＇s own mother, while detectable in women with recurrent miscarriage, may differ from controls and according to subsequent pregnancy outcome. Further studies are needed to determine the cell types,quantities and any potential functional role of microchimerism in recurrent miscarriage.