Transfer of specific IgG and IgG subclasses to herpes simplex virus across the blood-brain barrier and placenta in preterm and term newborns

Herpes simplex virus type 1 infection leads to neurodevelopmental disorder-associated neuropathological changes

Neonatal herpes simplex virus type 1 (HSV-1) infections contribute to various neurodevelopmental disabilities and the subsequent long-term neurological sequelae into the adulthood. However, further understanding of fetal brain development and the potential neuropathological effects of the HSV-1 infection are hampered by the limitations of existing neurodevelopmental models due to the dramatic differences between humans and other mammalians. Here we generated in vitro neurodevelopmental disorder models including human induced pluripotent stem cell (hiPSC)-based monolayer neuronal differentiation, three-dimensional (3D) neuroepithelial bud, and 3D cerebral organoid to study fetal brain development and the potential neuropathological effects induced by the HSV-1 infections. Our results revealed that the HSV-1-infected neural stem cells (NSCs) exhibited impaired neural differentiation. HSV-1 infection led to dysregulated neurogenesis in the fetal neurodevelopment. The HSV-1-infected brain organoids modelled the pathological features of the neurodevelopmental disorders in the human fetal brain, including the impaired neuronal differentiation, and the dysregulated cortical layer and brain regionalization. Furthermore, the 3D cerebral organoid model showed that HSV-1 infection promoted the abnormal microglial activation, accompanied by the induction of inflammatory factors, such as TNF-α, IL-6, IL-10, and IL-4. Overall, our in vitro neurodevelopmental disorder models reconstituted the neuropathological features associated with HSV-1 infection in human fetal brain development, providing the causal relationships that link HSV biology with the neurodevelopmental disorder pathogen hypothesis.

HSV-1 is one of the most prevalent human pathogens that can spread into the fetal central nervous system by maternal-fetal transmission, and thus resulting in long-term neurological sequelae in adult, including cognitive dysfunction and learning disabilities. However, there is a very limited progress in understanding the role of HSV-1 on human fetal brain development due to limited access to fetal human brain tissue as well as the limitations of existing neurodevelopmental and infection models. Here, we generated the in vitro neurodevelopmental disorder models including hiPSC-based monolayer neuronal differentiation, three-dimensional (3D) neuroepithelial bud, and 3D cerebral organoid to study the neurodevelopmental disorder-associated neuropathological changes with HSV-1 infection in human fetal brain development. Our results revealed that HSV-1 infection led to impaired neural differentiation and dysregulated neurogenesis in the fetal neurodevelopment. Additionally, HSV-1 infection impaired neuronal differentiation and dysregulated brain regionalization in our cerebral organoid model. Furthermore, the cerebral organoid model showed that HSV-1 infection led to the abnormal microglial proliferation and activation, accompanied by the induction of inflammatory factors including TNF-α, IL-6, IL-10, and IL-4. Taken together, our study provides novel evidence that HSV-1 infection impaired human brain development and contributed to neurodevelopmental disorder pathogen hypothesis, and would have implications for raising the therapeutic opportunities for targeting of viral reservoirs relevant to neurodevelopmental disorder.

Role of IgG antibodies in association with placental function and immunologic diseases in human pregnancy

During human pregnancy, the maternal immune system develops and changes, providing protection for the growing placenta and fetus. These protective changes provide mechanisms allowing two genetically different individuals to interact with each other without allograft rejection. In addition to normal pregnancy, some pregnancies may develop under immunologic diseases, during which specific monitoring and medical treatments are essential. The aim of this current review is to provide information regarding the development of human placental function during pregnancy, the immunology of human pregnancy and the role of the placenta in providing the fetal tissue with antibodies (IgG and its subclasses 1-4), which are required for the passive immunization of the newborn. In addition, the available methods for the determination of placental function will be explored. Furthermore, immunologic diseases observed during pregnancy and the possible therapies for these diseases will be assessed.

An immunohistochemical study of the secretory immune system in human fetal membranes and decidua of the first trimester of pregnancy

PROBLEM

We analyzed the presence and distribution of components of the secretory immune system (SIS) in human fetal membranes (amnion, yolk sac, chorion) and decidua from the first trimester of pregnancy.

MATERIALS AND METHODS

Specimens from 17 embryos (4-8 weeks of pregnancy) and nine fetuses (9-12 weeks) were divided into those that had not been exposed to massive foreign antigenic effects (Group I, n = 18) and those that had suffered acute chorioamnionitis (Group II, n = 8).

RESULTS

Positive immunostaining for secretory component (SC), joining (J) chain, IgG, IgA, and macrophages was seen from 4 to 5 weeks of development and then during the whole first trimester of pregnancy in the syncytio- and cytotrophoblasts, the amniotic epithelium, the yolk sac endoderm and decidual cells. Macrophages with J chain, IgG and IgA were found in embryonic tissues on week 4, whereas lymphocytes, including those synthesizing IgA and IgM, appeared only at the end of the first trimester of pregnancy. In the decidua, lymphocytes and macrophages were recognized during the whole period of study. In cases with chorioamnionitis (Group II), reactivity of IgG and IgA in the mentioned cells of fetuses decreased sharply while the rate of immunoreactivity of SC and J chain as well as the number of T and B lymphocytes did not change. In the decidua, the number of immune reactive cells sharply increased with the appearance of plasma cells.

CONCLUSIONS

In the fetal membranes and decidua all the SIS components are present. We suggest that two SIS, maternal and fetal, participate in the formation of the barrier between a mother and the fetus. Both these systems have different origin and cellular content as well as different immune reactions.

Secretory component, J chain, and immunoglobulins in human embryos and fetuses of the first trimester of pregnancy: immunohistochemical study

In our previous studies, we described the development of the secretory (mucosal) immune system (SIS) in human fetuses in the second trimester of pregnancy. In the present study, we examined the presence and distribution of components of this system in human embryos and early fetuses in the first trimester. An immunohistochemical study was performed on 17 embryos and 9 fetuses (4 to 12 wk of development) using antibodies against secretory component (SC), joining (J) chain, immunoglobulins (IgA, IgM, IgG), subsets of T and B lymphocytes, and macrophages. Cells positive for SC, J chain, and IgG were found in epithelial tissues from wk 4 of pregnancy. In the internal organs, such as the myocardium and endocardium, capillary endothelium, epithelium of the kidney tubules and some others, only J chain and immunoglobulins were seen. IgA was weakly reactive in tissues where SC and/or J chain were presented. IgM was very weak or absent. Among the cellular components of the SIS, only macrophages were seen in 4-wk-old embryos. CD3+ and CD20+ lymphocytes were found at wk 7 to 8. IgA- and IgM-positive lymphocytes appeared at the end of wk 9. The SIS is widespread in embryonic and early fetal periods and begins to function before the appearance of the common immune system in the developing organism. The first functional components of the SIS, such as IgG and IgA observed in this study, are most probably of maternal origin.

Evolution of maternofetal transport of immunoglobulins during human pregnancy

PROBLEM

We determined the evolution of the maternal-fetal transport of immunoglobulins during human pregnancy.

METHOD

Paired blood samples were collected between 17-41 weeks of gestation (WG) by puncture of a peripheral maternal vein and by cordocentesis (17-36 WG, n = 91) or directly at delivery (37-41 WG n = 16) from the umbilical vein. Additional maternal samples were collected from the same individual (n = 16) at 10, 20, 30 WG, and at term. The concentration of IgG and its four subclasses and of IgA were determined in the sera using ELISA method.

RESULTS

The mean level of IgG and IgA in maternal sera at 9-16 WG was 13.72 +/- 2.53 g/L and 3.95 +/- 1.23 g/L, respectively. Both, IgG and IgA throughout pregnancy decreased to a level of 60-70% (37-41 WG) of the initial concentration in early pregnancy. The ratio of IgG1:IgG2 in the maternal circulation was 2-3 and remained constant throughout pregnancy (17-41 WG). IgG3 and IgG4 levels remained constant and together were less than 10% of total IgG. In the fetal circulation a continuous rise in the level of both IgG and IgA was observed between 17 and 41 WG. Fetal level of IgG at 17-22 WG was only 5-10% of the maternal level and at term exceeded the maternal level reaching a value of 11.98 +/- 2.18 g/L. IgG1 at 17-22 WG was 0.93 +/- 0.42 g/L, which is approximately three times higher than IgG2. IgG1 showed an exponential rise and at 37-41 WG its concentration was seven times higher than IgG2. IgG3 and IgG4 also showed an exponential rise and at term reached a similar level as in the maternal circulation. Striking was the difference in results for IgG2 with a slow linear rise throughout gestation. The fetal IgG2 level at term remained significantly below the maternal concentration. The IgG subclasses when characterized according to the differences in transport capacity gave the following sequence: IgG1 > IgG4 > IgG3 > IgG2. Fetal IgA showed a slow linear rise with fetal levels at term remaining approximately 1,000 times lower than the concentration in the maternal circulation.

CONCLUSIONS

Comparison of fetal and maternal levels of immunglobulines indicate that the human placenta during pregnancy develops a specific transport mechanism for IgG. There are differences for the four subclasses with preferential transfer of IgG1 while the slowest transfer is seen for IgG2.