Paulomi Aldo

Trophoblast-macrophage interactions: a regulatory network for the protection of pregnancy.

Problem  Macrophages are one of the first immune cells observed at the implantation site. Their presence has been explained as the result of an immune response toward paternal antigens. The mechanisms regulating monocyte migration and differentiation at the implantation site are largely unknown. In the present study, we demonstrate that trophoblast cells regulate monocyte migration and differentiation. We propose that trophoblast cells ‘educate’ monocytes/macrophages to create an adequate environment that promote trophoblast survival.

A Role for TLRs in the Regulation of Immune Cell Migration by First Trimester Trophoblast Cells

Normal pregnancy is characterized by the presence of innate immune cells at the maternal-fetal interface. Originally, it was postulated that the presence of these leukocytes was due to an immune response toward paternal Ags expressed by the invading trophoblasts. Instead, we and others postulate that these innate immune cells are necessary for successful implantation and pregnancy. However, elevated leukocyte infiltration may be an underlying cause of pregnancy complications, such as preterm labor or preeclampsia. Furthermore, such conditions have been attributed to an intrauterine infection. Therefore, we hypothesize that first trimester trophoblast cells, upon recognition of microbes through TLRs, may coordinate an immune response by recruiting cells of the innate immune system to the maternal-fetal interface. In this study, we have demonstrated that human first trimester trophoblast cells constitutively secrete the chemokines growth-related oncogene, growth-related oncogene α, IL-8, and MCP-1 and are able to recruit monocytes and NK cells, and to a lesser degree, neutrophils. Following the ligation of TLR-3 by the viral ligand, poly(I:C), or TLR-4 by bacterial LPS, trophoblast secretion of chemokines is significantly increased and this in turn results in elevated monocyte and neutrophil chemotaxis. In addition, TLR-3 stimulation also induces trophoblast cells to secrete RANTES. These results suggest a novel mechanism by which first trimester trophoblast cells may differentially modulate the maternal immune system during normal pregnancy and in the presence of an intrauterine infection. Such altered trophoblast cell responses might contribute to the pathogenesis of certain pregnancy complications.

Local injury of the endometrium induces an inflammatory response that promotes successful implantation

OBJECTIVE To study whether an injury-induced inflammation might be the mechanism underlying the favorable effect of endometrial biopsy on the implantation rate in in vitro fertilization (IVF) patients. DESIGN Controlled clinical study. SETTING A medical center IVF unit and a research institute. PATIENT(S) Women undergoing IVF who had previous failed treatment cycles. INTERVENTION(S) Endometrial samples were collected from two groups of patients on day 21 of their spontaneous menstrual cycle. The experimental, but not the control group underwent prior biopsy treatment on days 8 or/and 11 to 13 of that same cycle. MAIN OUTCOME MEASURE(S) Abundance of immune cells, cytokines/chemokines level, correlation between these parameters and pregnancy outcome. RESULT(S) A statistically significantly higher amount of macrophages/dendritic cells (HLA-DR+ CD11c+ cells) and elevated proinflammatory cytokines, tumor necrosis factor-α (TNF-α), growth-regulated oncogene-α (GRO-α), interleukin-15 (IL-15), and macrophage inflammatory protein 1B (MIP-1B), were detected in day-21 endometrial samples of the experimental group. A direct stimulatory effect of TNF-α on MIP-1B, GRO-α, and IL-15 messenger RNA (mRNA) expression was demonstrated. A positive correlation was found between the levels of macrophages/dendritic cells, MIP-1B expression, and TNF-α expression and the pregnancy outcome. CONCLUSION(S) A biopsy-induced inflammatory response may facilitate the preparation of the endometrium for implantation. Increased MIP-1B expression could possibly serve for prediction of implantation competence.

Viral Infection of the Placenta Leads to Fetal Inflammation and Sensitization to Bacterial Products Predisposing to Preterm Labor

Pandemics pose a more significant threat to pregnant women than to the nonpregnant population and may have a detrimental effect on the well being of the fetus. We have developed an animal model to evaluate the consequences of a viral infection characterized by lack of fetal transmission. The experiments described in this work show that viral infection of the placenta can elicit a fetal inflammatory response that, in turn, can cause organ damage and potentially downstream developmental deficiencies. Furthermore, we demonstrate that viral infection of the placenta may sensitize the pregnant mother to bacterial products and promote preterm labor. It is critical to take into consideration the fact that during pregnancy it is not only the maternal immune system responding, but also the fetal/placental unit. Our results further support the immunological role of the placenta and the fetus affecting the global response of the mother to microbial infections. This is relevant for making decisions associated with treatment and prevention during pandemics.

Activation of TLR3 in the trophoblast is associated with preterm delivery.

Problem  Toll‐like receptors (TLRs) recognize conserved sequences on the surface of pathogens and trigger effector cell functions. Previously, we described the expression of TLR3 by human trophoblast and their ability to respond to (Poly[I:C]). Here we evaluate the effect of Poly[I:C] on mouse pregnancy and characterize the local and systemic response.

Understanding the Complexity of the Immune System during Pregnancy

Progress in our understanding of the role of the maternal immune system during healthy pregnancy will help us better understand the role of the immune system in adverse pregnancy outcomes. In this review, we discuss our present understanding of the ‘immunity of pregnancy’ in the context of the response to cervical and placental infections and how these responses affect both the mother and the fetus. We discuss novel and challenging concepts that help explain the immunological aspects of pregnancy and how the mother and fetus respond to infection.

TLR6 Modulates First Trimester Trophoblast Responses to Peptidoglycan

Intrauterine bacterial infections are a well-established cause of pregnancy complications. One key observation in a number of abnormal pregnancies is that placental apoptosis is significantly elevated. First trimester trophoblast cells are known to express TLR1 and TLR2 and to undergo apoptosis following exposure to Gram-positive bacterial peptidoglycan (PDG). Thus, the objectives of this study were to determine whether PDG-induced pregnancy complications are associated with placental apoptosis and to characterize the cellular mechanisms involved. We have demonstrated, using an animal model, that delivery of PDG to pregnant mice early in gestation resulted in highly elevated placental apoptosis, evidenced by trophoblast M-30 and active caspase 3 immunostaining. Using an in vitro model of human first trimester trophoblasts, apoptosis induced by PDG was found to be mediated by both TLR1 and TLR2 and that this could be blocked by the presence of TLR6. Furthermore, in the presence of TLR6, exposure to PDG resulted in trophoblast NF-κB activation and triggered these cells to secrete IL-8 and IL-6. The findings of this study suggest that a Gram-positive bacterial infection, through TLR2 and TLR1, may directly promote the elevated trophoblast cell death and that this may be the underlying mechanism of pregnancy complications, such as preterm delivery. Furthermore, the expression of TLR6 may be a key factor in determining whether the response to PDG would be apoptosis or inflammation.

Viral Infection of the Pregnant Cervix Predisposes to Ascending Bacterial Infection

Preterm birth is the major cause of neonatal mortality and morbidity, and bacterial infections that ascend from the lower female reproductive tract are the most common route of uterine infection leading to preterm birth. The uterus and growing fetus are protected from ascending infection by the cervix, which controls and limits microbial access by the production of mucus, cytokines, and antimicrobial peptides. If this barrier is compromised, bacteria may enter the uterine cavity, leading to preterm birth. Using a mouse model, we demonstrate, to our knowledge for the first time, that viral infection of the cervix during pregnancy reduces the capacity of the female reproductive tract to prevent bacterial infection of the uterus. This is due to differences in susceptibility of the cervix to infection by virus during pregnancy and the associated changes in TLR and antimicrobial peptide expression and function. We suggest that preterm labor is a polymicrobial disease, which requires a multifactorial approach for its prevention and treatment.

Placental Viral Infection Sensitizes to Endotoxin‐Induced Pre‐Term Labor: A Double Hit Hypothesis

Citation Cardenas I, Mor G, Aldo P, Lang SM, Stabach P, Sharp A, Romero R, Mazaki‐Tovi S, Gervasi MTeresa, Means RE. Placental viral infection sensitizes to endotoxin‐induced pre‐term labor: a double hit hypothesis. Am J Reprod Immunol 2011; 65: 110–117

Toll-like receptors and pregnancy: Trophoblast as modulators of the immune response

During normal pregnancy, the decidua is populated by a variety of leucocytes; however, cells of the innate immune system seem to dominate this tissue. Their presence suggests that the innate immune system is not indifferent to the fetus and has been associated with a response of the maternal immune system to the ‘semi‐allograft’ fetus. New evidences, however, indicate that these immune cells are critical for decidual and trophoblast development rather than induction of tolerance. We hypothesized that during implantation, an inflammatory environment is necessary for the attachment and invasion of the blastocyst. The existence of an ‘inflammatory‐mediated embryo implantation’ condition is dependent on the proper ‘education’ of the innate immune system which we propose is mediated by the trophoblast. Here we postulate that trophoblast cells successfully orchestrate their inflammatory environment and regulate immune cells differentiation and activation through Toll‐like receptors (TLR). We will describe potential functions of TLR in trophoblast cells, their recognition and response to microorganisms, and their involvement in innate immunity.