Article

Maternal Microchimerism in Cord Blood and Risk of Celiac Disease in Childhood

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Abstract

Objectives: During pregnancy, small quantities of maternal cells are naturally transmitted to the fetus. This transmission, termed maternal microchimerism (MMc), has been implicated in autoimmune diseases but its potential role is unclear. We aimed to investigate if MMc at birth predicted childhood celiac disease (CD) risk, a common immune-mediated enteropathy often presenting in childhood. Methods: We designed a case-control study, nested in the Norwegian Mother, Father and Child Cohort. Participants were HLA class II typed to determine noninherited, nonshared maternal alleles (NIMA). Droplet digital (dd) PCR assays specific for common HLA class II NIMAs (HLA-DQB103:01, 04:02 and 06:02/03) were used to estimate the quantity of maternal DNA, as a marker of maternal cells, in cord blood DNA from 124 children who later developed clinically diagnosed CD (median age at end of study 7.4 years, range 3.6-12.9) and 124 random controls. We tested whether presence of MMc was associated with CD using logistic regression, and compared ranks between cases and controls. Results: MMc, for example, maternal HLA antigens not inherited by the child, was found in 42% of cases and 43% of controls, and not associated with CD (odds ratio [OR] 0.97, 95% confidence interval [CI] 0.58-1.60). The ranks of MMc quantities in cases and controls were also similar (Mann-Whitney U-test, P = 0.71). The subgroup with HLA-DQB1:03*01 as their NIMA had a potential association with MMc, where levels greater than median was associated with CD (OR 3.78, 95% CI 1.28-11.18). Conclusion: MMc measured in cord blood was not associated with later risk of CD.

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... Moreover, in another study, rheumatoid nodules of rheumatoid arthritis patients were found to contain microchimerism with evidence of a fetal or maternal source, suggesting an association of microchimerism with the pathogenesis of this autoimmune disease [99]. In contrast, MMc tested in cord blood at birth was not found to be associated with a later risk of developing celiac disease in childhood [100]. ...
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Feto-maternal microchimerism is the bidirectional transfer of cells through the placenta during pregnancy that can affect the health of both the mother and the offspring, even in childhood or adulthood. However, microchimerism seems to have different consequences in the mother, who already has a developed immune system, than in the fetus, which is vulnerable with immature defense mechanisms. Studies have shown that the presence of fetal microchimeric cells in
... It remains to be seen whether such an HLA relationship dangerously increases the maternal-fetal exchange to the point of later triggering an autoimmune disease in the recipient. Yet, two recent studies investigated whether MMc measured in cord blood could predict the risk of future celiac disease or type 1 diabetes in children but did not find an association (43,44). ...
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Risk factors for most autoimmune diseases are multifactorial genetic variants modified by environmental risk factors. Type 1 diabetes and celiac disease share high-risk HLA haplotypes, and the prevalence of both diseases has increased in many regions during the past half century. Unknown environmental factors are suspected to have increased the disease penetrance. Celiac disease depends on immune responses to dietary gluten, whereas the environmental risk factors for type 1 diabetes are not yet clear. Here, we consider the shared heritable genetic factors and review evidence of the dietary and microbial exposures, particularly in early life, that might influence the pathogenesis of one or both diseases. A deeper mechanistic understanding of the environmental factors responsible for increased risk of these diseases should provide opportunities to manipulate exposure in children carrying defined risk markers and thus prevent and attenuate disease, as well as to identify new therapeutic strategies for patients.
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Coeliac disease and type 1 diabetes are the most common paediatric autoimmune disorders. Both conditions have increasing incidence and can often coexist in a patient. The diseases share many genetic and immunological features, but diagnostic and treatment approaches vary substantially worldwide. Because of the often subtle presentation of coeliac disease in children with type 1 diabetes, many are diagnosed only upon screening for coeliac disease. In this Review, we summarise approaches to diagnosis and treatment of children with type 1 diabetes and coeliac disease, with a specific emphasis on those with a double diagnosis. In particular, we examine the pros and cons of screening for coeliac disease and assess the challenges of dietary treatment in children with coexisting type 1 diabetes, which can already be a burden. Furthermore, we present the latest research on the shared genetic and pathogenic mechanisms and introduce some future perspectives.
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Background and objectives: Few birth cohorts have prospectively followed development of type 1 diabetes (T1D) and celiac disease (CD) autoimmunities to determine timing, extent of co-occurrence, and associated genetic and demographic factors. Methods: In this prospective birth cohort study, 8676 children at high genetic risk of both diseases were enrolled and 5891 analyzed in median follow-up of 66 months. Along with demographic factors and HLA-DR-DQ, genotypes for HLA-DPB1 and 5 non-HLA loci conferring risk of both T1D and CD were analyzed. Results: Development of persistent islet autoantibodies (IAs) and tissue transglutaminase autoantibodies (tTGAs), as well as each clinical disease, was evaluated quarterly from 3 to 48 months of age and semiannually thereafter. IAs alone appeared in 367, tTGAs alone in 808, and both in 90 children. Co-occurrence significantly exceeded the expected rate. IAs usually, but not always, appeared earlier than tTGAs. IAs preceding tTGAs was associated with increasing risk of tTGAs (hazard ratio [HR]: 1.48; 95% confidence interval [CI]: 1.15-1.91). After adjusting for country, sex, family history, and all other genetic loci, significantly greater co-occurrence was observed in children with a T1D family history (HR: 2.80), HLA-DR3/4 (HR: 1.94) and single-nucleotide polymorphism rs3184504 at SH2B3 (HR: 1.53). However, observed co-occurrence was not fully accounted for by all analyzed factors. Conclusions: In early childhood, T1D autoimmunity usually precedes CD autoimmunity. Preceding IAs significantly increases the risk of subsequent tTGAs. Co-occurrence is greater than explained by demographic factors and extensive genetic risk loci, indicating that shared environmental or pathophysiological mechanisms may contribute to the increased risk.
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Immunological identity is traditionally defined by genetically encoded antigens, with equal maternal and paternal contributions as a result of Mendelian inheritance. However, vertically transferred maternal cells also persist in individuals at very low levels throughout postnatal development. Reciprocally, mothers are seeded during pregnancy with genetically foreign fetal cells that persist long after parturition. Recent findings suggest that these microchimeric cells expressing non-inherited, familially relevant antigenic traits are not accidental 'souvenirs' of pregnancy, but are purposefully retained within mothers and their offspring to promote genetic fitness by improving the outcome of future pregnancies. In this Review, we discuss the immunological implications, benefits and potential consequences of individuals being constitutively chimeric with a biologically active 'microchiome' of genetically foreign cells.
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Background: A mother's infection with placental malaria (PM) can affect her child's susceptibility to malaria, although the mechanism remains unclear. The fetus acquires a small amount of maternal cells and DNA known as maternal microchimerism (MMc), and we hypothesized that PM increases MMc and that MMc alters risk of P. falciparum malaria during infancy. Methods: In a nested cohort from Muheza, Tanzania, we evaluated the presence and level of cord blood MMc in offspring of women with and without PM. A maternal-specific polymorphism was identified for each maternal-infant pair, and MMc was assayed by quantitative PCR. The ability of MMc to predict malaria outcomes during early childhood was evaluated in longitudinal models. Results: Inflammatory PM increased the detection rate of MMc among offspring of primigravidae and secundigravidae, and both non-inflammatory and inflammatory PM increased the level of MMc. Detectable MMc predicted increased risk of positive blood smear but, interestingly, decreased risk of symptomatic malaria and malaria hospitalization. Conclusions: The acquisition of MMc may result in increased malaria infection but protection from malaria disease. Future studies should be directed at the cellular component of MMc, with attention to its ability to directly or indirectly coordinate anti-malarial immune responses in the offspring.
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Background & aims: Little is known about the incidence of celiac disease in the general population of children in the United States. We aimed to estimate the cumulative incidence of celiac disease in adolescents born in the Denver metropolitan area. Methods: We collected data on HLA-DR, DQ genotypes of 31,766 infants, born from 1993 through 2004 at St. Joseph's Hospital in Denver, from the Diabetes Autoimmunity Study in the Young. Subjects with susceptibility genotypes for celiac disease and type 1 diabetes were followed for up to 20 years for development of tissue transglutaminase autoantibodies (tTGA). Outcomes were the development of celiac disease autoimmunity (CDA) or celiac disease. CDA was defined as persistence of tTGA for at least 3 months or development of celiac disease. Celiac disease was defined based on detection of Marsh 2 or greater lesions in biopsies or persistent high levels of tTGA. For each genotype, the cumulative incidence of CDA and celiac disease were determined. To estimate the cumulative incidence in the Denver general population, outcomes by each genotype were weighted according to the frequency of each of these genotypes in the general population. Results: Of 1339 subjects followed, 66 developed CDA and met criteria for celiac disease and 46 developed only CDA. Seropositivity for tTGA resolved spontaneously, without treatment, in 21 of the 46 subjects with only CDA (46%). The estimated cumulative incidence for CDA in the Denver general population at 5, 10, and 15 years of age was 2.4%, 4.3%, and 5.1% respectively; incidence values for celiac disease were 1.6%, 2.8%, and 3.1%, respectively. Conclusions: In a 20-year prospective study of 1339 children with genetic risk factors for celiac disease, we found the cumulative incidence of CDA and celiac disease to be high within the first 10 years. Although more than 5% of children may experience a period of CDA, not all develop celiac disease or require gluten-free diets.
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Purpose: We aimed to investigate the frequency of fetal-maternal microchimerism among cord blood (CB) from a Korean population. Materials and methods: We previously developed a nested polymerase chain reaction-single-strand conformation polymorphism method for microchimerism detection that is highly sensitive (0.01–0.001%) and specific. We used this method to investigate the frequency of fetal-maternal HLA-DRB1 microchimerism among 153 maternal and 152 CB samples. Results: Among the tested pairs, 41.1% exhibited at least one direction of microchimerism, 32.0% of the mothers possessed fetal microchimerism, and 23.4% of the newborns possessed maternal microchimerism. The overall microchimerism frequency was 28.2%. Conclusions: We hypothesize that the different microchimerism frequencies among population and methods are due to differences in detection specificities and subject characteristics. This study provides basic data on fetal-maternal microchimerism that may be useful for future studies on autoimmune disorder and virtual phenotyping in transplantation.
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Capsule summary: This first investigation of multiple biomarkers reflecting cellular and humoral immune activation in mid-pregnancy or at birth do not support concerns that the prenatal systemic immune response influences celiac disease development in children.
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This is an update of the Norwegian Mother and Child Cohort Study (MoBa) cohort profile which was published in 2006. Pregnant women attending a routine ultrasound examination were initially invited. The first child was born in October 1999 and the last in July 2009. The participation rate was 41%. The cohort includes more than 114 000 children, 95 000 mothers and 75 000 fathers. About 1900 pairs of twins have been born. There are approximately 16 400 women who participate with more than one pregnancy. Blood samples were obtained from both parents during pregnancy and from mothers and children (umbilical cord) after birth. Samples of DNA, RNA, whole blood, plasma and urine are stored in a biobank. During pregnancy, the mother responded to three questionnaires and the father to one. After birth, questionnaires were sent out when the child was 6 months, 18 months and 3 years old. Several sub-projects have selected participants for in-depth clinical assessment and exposure measures. The purpose of this update is to explain and describe new additions to the data collection, including questionnaires at 5, 7, 8 and 13 years as well as linkages to health registries, and to point to some findings and new areas of research. Further information can be found at [www.fhi.no/moba-en]. Researchers interested in collaboration and access to the data can complete an electronic application available on the MoBa website above.
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The only strategy to select individuals at increased risk for type 1 diabetes for primary prevention trials is through genetic risk assessment. While genome-wide association studies have identified more than 40 loci associated with type 1 diabetes, the single most important genetic determinants lie within the human leucocyte antigen gene family on chromosome 6. In this chapter we describe a protocol for a straightforward, cheap strategy to determine HLA class II mediated risk of type 1 diabetes. This method has proved robust for genotyping whole-genome-amplified DNA as well as DNA extracted directly from human tissues.
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Objectives: Studies on early life infections and risk of later celiac disease (CD) are inconsistent but have mostly been limited to retrospective designs, inpatient data, or insufficient statistical power. We aimed to test whether early life infections are associated with increased risk of later CD using prospective population-based data. Methods: This study, based on the Norwegian Mother and Child Cohort Study, includes prospective, repeated assessments of parent-reported infectious disease data up to 18 months of age for 72,921 children born between 2000 and 2009. CD was identified through parental questionnaires and the Norwegian Patient Registry. Logistic regression was used to estimate odds ratios adjusted for child's age and sex (aOR). Results: During a median follow-up period of 8.5 years (range, 4.5-14.5), 581 children (0.8%) were diagnosed with CD. Children with ≥10 infections (≥fourth quartile) up to age 18 months had a significantly higher risk of later CD, as compared with children with ≤4 infections (≤first quartile; aOR=1.32; 95% confidence interval (CI)=1.06-1.65; per increase in infectious episodes, aOR=1.03; 95% CI=1.02-1.05). The aORs per increase in specific types of infections were as follows: upper respiratory tract infections: 1.03 (95% CI=1.02-1.05); lower respiratory tract infections: 1.12 (95% CI=1.01-1.23); and gastroenteritis: 1.05 (95% CI=0.99-1.11). Additional adjustments for maternal CD, education level, smoking, birth weight, prematurity, infant feeding practices, birth season, and antibiotic treatment yielded largely unchanged results. Conclusions: This is the first large-scale population-based cohort study of this association. Our results are in line with immunological data suggesting that early life infections may have a role in CD development. However, non-causal explanations for this association due to surveillance bias and reverse causation cannot be excluded.
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Celiac disease is triggered by an interplay of environmental and genetic factors and is one of the most prevalent autoimmune diseases in children, occurring in about 1% of Europeans. Over the last few decades there has been a growing interest in the role of the perinatal environment in celiac disease and this review discusses the growing body of literature on celiac disease and perinatal risk factors.Conclusion There is still only circumstantial evidence that the perinatal environment influences celiac disease development. Large-scale cohort studies and emerging scientific concepts, such as epigenetics, may help us establish the role of these environmental factors.This article is protected by copyright. All rights reserved.
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Exposure to maternal tissue during in utero development imprints tolerance to immunologically foreign non-inherited maternal antigens (NIMA) that persists into adulthood. The biological advantage of this tolerance, conserved across mammalian species, remains unclear. Here, we show maternal cells that establish microchimerism in female offspring during development promote systemic accumulation of immune suppressive regulatory T cells (Tregs) with NIMA specificity. NIMA-specific Tregs expand during pregnancies sired by males expressing alloantigens with overlapping NIMA specificity, thereby averting fetal wastage triggered by prenatal infection and non-infectious disruptions of fetal tolerance. Therefore, exposure to NIMA selectively enhances reproductive success in second-generation females carrying embryos with overlapping paternally inherited antigens. These findings demonstrate that genetic fitness, canonically thought to be restricted to Mendelian inheritance, is enhanced in female placental mammals through vertically transferred maternal cells that promote conservation of NIMA and enforce cross-generational reproductive benefits. Copyright © 2015 Elsevier Inc. All rights reserved.
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There have been inconsistent reports of prenatal and perinatal factors that affect risk for development of celiac disease. We assessed the association of fetal growth, birth weight, and mode of delivery with development of celiac disease within the Norwegian Mother and Child (MoBa) Cohort Study. The MoBa cohort contains pregnancy information on 95,200 women and data on their 114,500 children, which were collected in Norway from 1999 through 2008; it is linked to the Medical Birth Registry. Women and children with celiac disease were identified from the National Patient Registry and from women's responses to MoBa questionnaires. We calculated odds ratios (ORs) for celiac disease by using a multivariable logistic regression model, adjusting for maternal celiac disease, sex of children, and children's age (model 1); in a second model, we adjusted for age of gluten introduction and duration of breastfeeding (model 2). We identified 650 children with celiac disease and 107,828 controls in the MoBa database. We found no association between birth weight or height with celiac disease (born small for gestational age was not associated). Celiac disease was not associated with mode of delivery (cesarean section, model 1: OR, 0.84; 95% confidence interval [CI], 0.65-1.09, and model 2: OR, 0.83; 95% CI, 0.63-1.09). Maternal celiac disease, adjusted for age and sex of the children (OR, 12.45; 95% CI, 8.29-18.71) and type 1 diabetes (model 1: OR, 2.58; 95% CI, 1.19-5.53, and model 2: OR, 2.61; 95% CI, 1.14-5.98) were associated with development of celiac disease in children, whereas maternal type 2 diabetes and gestational diabetes were not. On the basis of analysis of the Norwegian MoBa cohort, development of celiac disease in children is significantly associated with sex of the child, maternal celiac disease, and type 1 diabetes but not with intrauterine growth. Copyright © 2015 AGA Institute. Published by Elsevier Inc. All rights reserved.
Article
The origins of autoimmunity are not yet understood despite significant advances in immunology. The trafficking of maternal cells to the offspring represents the very first immunological event in foetal life and is reinforced during lactation. The persistence of maternal cells in offspring's tissues and circulation has been associated with several autoimmune disorders. However a direct causal effect has never been demonstrated. Maternal T cells specifically targeting foetal insulin producing cells have been shown to generate islet inflammation without directly participating in this process. Our objective was to evaluate if alloreactive maternal cells could directly trigger a graft-versus host like reaction or indirectly influence the development of the offspring's regulatory T cells favouring autoimmunity. We adopted a breeding strategy comparing genetically identical offspring from either strongly alloreactive transgenic mothers compared to immunodeficient mothers. We detected maternal alloreactive T cells in the offspring and early signs of inflammation in small intestine of 6 weeks old offspring. Interestingly, CD4(+) Foxp3(+) regulatory T cell frequency was diminished in mesenteric lymph nodes from eight months old offspring born of alloreactive mothers compared to offspring of immunodeficient mothers. Our study favours a hypothesis where highly alloreactive maternal cell microchimerism indirectly predisposes offspring to autoimmunity.
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Microchimerism (Mc) refers to the harboring of a small number of cells (or DNA) that originated in a different individual. Naturally acquired Mc derives primarily from maternal cells in her progeny, or cells of fetal origin in women. Both maternal and fetal Mc are detected in hematopoietic cells including T and B cells, monocyte/macrophages, natural killer (NK) cells and granulocytes. Mc appears also to generate cells such as myocytes, hepatocytes, islet β cells and neurons. Here, the detrimental and beneficial potential of Mc is examined. The prevalence, diversity and durability of naturally acquired Mc, including in healthy individuals, indicates that a shift is needed from the conventional paradigm of 'self versus other' to a view of the normal 'self' as constitutively chimeric.
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Recent studies indicate that fetal cells persist in maternal blood for decades after pregnancy. Maternal cells are known to engraft and persist in infants with immunodeficiency, but whether maternal cells persist long-term in immunocompetent offspring has not specifically been investigated. We developed sensitive human leukocyte antigen-specific (HLA-specific) PCR assays and targeted nonshared maternal HLA genes to test for persistent maternal microchimerism in subjects with scleroderma and in healthy normal subjects. Nonshared maternal-specific DNA was found in 6 of 9 scleroderma patients. In situ hybridization with double labeling for X and Y chromosome-specific sequences revealed female cells in peripheral blood samples from 2 male scleroderma patients. HLA-specific PCR also frequently revealed persistent maternal microchimerism in healthy control subjects. The mean age of all subjects with maternal microchimerism was 28 years (range: 9-49 years). With few exceptions, mothers of subjects with persistent maternal microchimerism were HLA incompatible with subjects for class I and class II alleles. These results clearly indicate that HLA-disparate maternal cells can persist in immunocompetent offspring well into adult life. The biological significance of maternal microchimerism and whether it might contribute to autoimmune disease requires further investigation.
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Juvenile dermatomyositis is a disease with similarities to chronic graft-versus-host disease. To identify whether chimerism is present in juvenile dermatomyositis, we investigated the families of 15 children with the disorder. Chimerism was identified by PCR in 13 of the 15 affected children, compared with five of 35 siblings (p<0.0001). Maternal cells among peripheral-blood mononuclear cells were detected in 11 of the 15 boys, compared with five of 17 unaffected controls (p=0.02), and in muscle tissue of 12 of 15 compared with two of ten unaffected siblings (p=0.005). These results suggest that chimerism may be involved in juvenile dermatomyositis.
Article
The application of molecular techniques to the study of human pregnancy has resulted in knowledge that the placenta is only a relative barrier to traffic of fetal and maternal cells. Moreover, long-term persistence of fetal cells in the maternal circulation and maternal cells in her progeny have been described. Harboring of cells from another individual is referred to as chimerism and microchimerism indicates low levels of non-host cells. The clinical features of a known condition of human chimerism, chronic graft-versus-host disease that occurs after stem cell transplantation, resemble spontaneously occurring autoimmune diseases including systemic sclerosis, Sjögren's syndrome, primary biliary cirrhosis, and sometimes myositis and systemic lupus. A critical determinant of chronic graft-versus-host disease is the HLA relationship of donor and host cells. When considered together, these observations have led to a new area of research investigating whether microchimerism and HLA-relationships are involved in the pathogenesis of some autoimmune diseases.
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Genetic susceptibility to celiac disease is strongly associated with HLA-DQA1*05-DQB1*02 (DQ2) and HLA-DQA1*03-DQB1*0302 (DQ8). Study of the HLA associations in patients not carrying these heterodimers has been limited by the rarity of such patients. This European collaboration has provided a unique opportunity to study a large series of such patients. From 1008 European coeliacs, 61 were identified who neither carry the DQ2 nor DQ8 heterodimers. Fifty seven of these encoded half of the DQ2 heterodimer. The remaining 4 patients had a variety of clinical presentations. Three of them carried the DQA1*01-DQB*05 haplotype as did 20/61 of those carrying neither DQ2 nor DQ8. This may implicate a role of the DQA1*01-DQB*05 haplotype. None of these four patients carried the DQB1*06 allele that has previously been reported in this sub-group of patients. Of the 16 DQ2 heterodimer negative patients without DRB1*04 or DRB1*07 haplotypes, it was inferred that none encoded the previously implicated DRB4 gene as none had a DRB1*09 haplotype. These results underline the primary importance of HLA-DQ alleles in susceptibility to celiac disease, and the extreme rarity of celiac patients carrying neither the DQ2 or DQ8 heterodimers nor one half of the DQ2 heterodimer alone.
Article
During pregnancy, maternal cells pass into the fetus, where they can persist for many years after birth. We investigated the presence of maternal cells in neonatal lupus syndrome (NLS), an autoimmune disease that develops in utero. The most serious complication of NLS is inflammation of the atrioventricular node leading to congenital heart block (CHB). In a blinded case-control study, maternal (female) cells were detected and quantified in male NLS and control heart-tissue samples. We used fluorescence in-situ hybridisation to label X and Y chromosomes. Studies in transplantation suggest that donor cells can differentiate into somatic tissue cells. Therefore, we asked whether maternal cells transferred in utero have cellular plasticity. To simultaneously identify and characterise maternal cells, we developed a technique by which multiple phenotypic markers could be detected concurrently with fluorescence in-situ hybridisation in the same cells of a tissue section. Maternal cells were found in 15 of 15 sections of NLS heart tissue, ranging from 0.025% to 2.2% of total cells. By contrast, maternal cells were found in two of eight control sections (0-0.1%). Very few maternal cells expressed the haemopoietic cell marker CD45. Most expressed sarcomeric alpha actin, a specific marker for cardiac myocytes. Our findings suggest that differentiated tissue-specific maternal microchimerism can occur in neonates. Thus, semiallogeneic maternal cells could be the target of an immune response. Alternatively, maternal cells could contribute to a secondary process of tissue repair.
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The aim of the present study was to analyze the presence of maternal cells in human fetal tissues in the second trimester. Tissues from 11 second-trimester fetuses terminated because of social reasons or because of malformations and/or trisomy were investigated. By cell sorting and polymerase chain reaction amplification, we studied the presence of maternal CD3+, CD19+, CD34+, and CD45+ in different fetal tissues and in placenta. In the group of fetuses with normal karyotype and normal autopsy findings, 4 of 5 fetuses were positive for maternal microchimerism. In the group in which the fetuses were diagnosed with trisomy 21 and/or malformations, we found cells of maternal origin in 3 of 6 fetuses. The results from this study indicate that maternal microchimerism is a common phenomenon in the second-trimester fetuses. Maternal cells of lymphoid and myeloid lineages and hematopoietic progenitors are widely distributed in the second-trimester fetuses.
Article
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. 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. 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. 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.