Maternal immune activation (MIA) is a major environmental factor known to increase likelihood of neurodevelopmental conditions such as autism (Paraschivescu et al., 2020) and schizophrenia (Kepinska et al., 2020; Purves-Tyson et al., 2021). MIA is mediated by activation of inflammatory pathways resulting in increased levels of cytokines and chemokines that cross the placental and blood-brain barriers (Patel et al., 2020; Mueller et al., 2021). This surge of inflammatory molecules alters neurodevelopment in the fetus (Patel et al., 2020; Purves-Tyson et al., 2021).

A number of maternal conditions may be responsible for triggering this inflammatory response, including autoimmune conditions (Chen et al., 2016), and asthma and allergic conditions (Gong et al., 2019). However, inflammatory responses caused by maternal viral infections remains one of the major environmental causes of MIA (Careaga et al., 2017; Baines et al., 2020; Cheslack-Postava and Brown, 2021). Case studies have associated viral infection from varicella, cytomegalovirus, mumps and herpes simplex virus with increased likelihood of autism (Patterson, 2011; Estes and McAllister, 2015). Understanding of the effects of virus-mediated MIA have also led researchers to consider the potential effects of maternal SARS-CoV-2 infection on fetal development (Reyes-Lagos et al., 2021).

Studying the effects of viral-induced MIA on the offspring can be very challenging. For decades, scientists relied on either MIA models or human epidemiological data or a combination of both.

Exposure to infections during pregnancy is quite common; almost 50% of pregnant women get respiratory tract infections while close to 20% getting urinary tract infections; nonetheless this high prevalence of maternal infection results in neurodevelopmental abnormalities in only a small portion of the exposed offspring (Milada et al., 2017; Weber-Stadlbauer, 2017; Brown and Meyer, 2018). This dichotomy might hold the key to certain protective that make certain pregnancies less susceptible to others, and mechanistically evidence has suggested impairment of cholinergic anti-inflammatory pathways in some pregnant mothers to be linked to a heightened inflammatory response (Reyes-Lagos et al., 2021).

Positive associations have been reported between maternal proinflammatory molecules [(IL)-1a, IL-6, IL-8, interferon-gamma (IFN-g), tumor necrosis factor alpha (TNF-a), granulocyte macrophage colony-stimulating factor (GMCF), and C-reactive protein (CRP)] and increased likelihood of autism and schizophrenia. Other studies looked at the effects of increased levels of maternal cytokines on fetal brain development, and reported alterations in the connectivity of the amygdala (Graham et al., 2018; Rudolph et al., 2018), and frontolimbic white matter (Rasmussen et al., 2019) and observed cognitive abnormalities in toddlers (Graham et al., 2018; Rudolph et al., 2018; Rasmussen et al., 2019). These studies have confirmed the link between maternal infections, the role of abnormal levels of cytokines and the possibility of developmental anomalies in the offspring (Brown and Meyer, 2018; Gumusoglu and Stevens, 2019; Weber-Stadlbauer and Meyer, 2019). Notwithstanding the abundance of evidence implicating MIA in the etiology of neuropsychiatric conditions, this pathogenic model appears to be naïve. The type of infection, gestational time and the resilience of the maternal immune system are important factors to consider when trying to dissect the heterogeneity of the MIA-induced effects (Meyers, 2019).

Identifying the factors that promote resilience to the MIA or vulnerable factors that might make some pregnancies more susceptible is of crucial importance. Different maternal infections have distinct mode of actions even if the effect associated is dependent on the immune reaction and not the type of infection. Some pathogens can directly affect the offspring through vertical transmission from the mother to the fetus through the placenta or through breast milk. Other pathogens are non-transmissible from the mother to the fetus and they still impose serious influences on the offspring for neurodevelopmental and neuropsychiatric conditions (Mednick et al., 1988; Milada et al., 2017; Brown and Meyer, 2018). The specificity of the proinflammatory modulators produced post infection can influence the severity of MIA effects on fetal brain developments, is the specificity of the proinflammatory modulators produced post infection. For instance, recent studies using animal MIA models report that different subtypes of toll-like receptors produce different outcomes in the offspring (Meyer, 2014; Weber-Stadlbauer and Meyer, 2019). Prenatal activation of TLR3 resulted in cellular, neurochemical, and behavioral phenotypes of a hyperdopaminergic state (Luan et al., 2018) while prenatal activation of TLR4 induced a hypodopaminergic state (Kirsten et al., 2012). This supports the notion that different immunological molecules might have different pathological outcomes. The intensity and timing of infections are potential contributors to the susceptibility of certain pregnancies to MIA. Studies have shown a positive correlation between the severity of maternal inflammation and anomalies in the developing brain in the general population and in a schizophrenia cohort (Graham et al., 2018; Rudolph et al., 2018; Rasmussen et al., 2019). Similarly, dose-dependent effects have been confirmed in animal models of MIA (Meyer et al., 2005; Hornig et al., 2018).

Maternal exposure to TORCH pathogens imposes a higher probability of developing neurodevelopmental anomalies in the first half of the pregnancy while the effects of the infection are subtle and less severe in later gestational periods. Similarly, birth cohort studies suggested a trimester -dependent effects of MIA in increasing autism incidence (Hornig et al., 2018). Maternal micronutrients such as vitamin D, iron, zinc omega-3 fatty acids and choline and others have also been identified as important factors to promote resilience to infections and optimal immune functioning (Brown, 2011; Luan et al., 2018; Maggini et al., 2018; Mattei and Pietrobelli, 2019).

The microbiome has been recently added to the equation as a potential etiological factor not only in the neurodevelopmental condition but also in the dysregulation of immune functions (Conway and Brown, 2019). Therefore, it is one of the most crucial factors in MIA heterogeneity. Immune function abnormalities have been reported in autism and other neuropsychiatric conditions, and recent studies propose the involvement of the microbiota in this dysregulation (Hsiao et al., 2013; Cryan and Dinan, 2015; Erny et al., 2015). Experimental studies looking at the immunological effects of MIA reported dysregulation of offspring microbiota in adulthood (Hsiao et al., 2013; Mandal and Ghosh, 2013; Kim et al., 2017). A 2017 study found that mice that have more T_H17 cells with segmented filamentous bacteria (SFB) were more susceptible to produce behavioral changes caused by MIA (Kim et al., 2017). Both MIA and microbiome dysregulation have been associated with alterations in fetal brain development, autism, and other neurodevelopmental conditions. Moreover, MIA activation alters maternal gut bacteria which can affect the microbiome of the offspring (Conway and Brown, 2019). This makes it extremely challenging to dissect the cause-effect relationship between MIA and the maternal microbiota, on offspring neurodevelopment.

Finally, the genetic background is a crucial contributor to the susceptibility or resilience to neurodevelopmental effect of MIA. Recent epidemiological studies have reported that familial history of psychiatric conditions posits synergistic interaction with MIA in increasing the probability of later developing schizophrenia. However, studies that examining common variants associated with schizophrenia showed no correlation interaction with MIA in increasing the likelihood of schizophrenia in the offspring. The latter does not remove the genetic background as a potential contributor to MIA heterogeneity but rather points out that polygenic scores are not proxy for genetic contribution (Clarke et al., 2009; Nielsen et al., 2013; Benros et al., 2016; Blomström et al., 2016). The genetic factors can be divided into factors that promote MIA susceptibility (Ayhan et al., 2016) or protection (Meyer et al., 2008). For instance, IL-10 polymorphisms have been associated with increased resilience against MIA effects as the increased production of IL-10 offer neurodevelopmental protection in the offspring post maternal infection (Meyer et al., 2008).

SARS-CoV-2 infection is known to stimulate production of MIA-causing pro-inflammatory cytokines such as IL-6, IL10 and TNFα (Pedersen and Ho, 2020). Since the virus has only been identified recently (end of 2019) there are yet no studies that have been able to investigate neurodevelopmental consequences in the offspring of affected mothers. Based on its clinical manifestation and past “similar” infections, theories have been proposed that suggest potential effects on the offspring (Granja et al., 2021). Following infection with SARS-CoV-2, there is an uncontrolled release of inflammatory cytokines and chemokines that have been involved in brain development [e.g., interleukins (IL-1β,−2,−4,−6,−8,−10), tumor necrosis factor alpha, interferons (IFN-α, IFN-γ)] (Reyes-Lagos et al., 2021). Amid the exacerbated long-term inflammatory effects observed in COVID-19 patients and the lessons learned from of viral-mediated MIA effects on the progeny’s brain, it is crucial to consider the neurological consequences of maternal SARS-CoV-2 infection on the offspring.

Human epidemiological data and MIA animal models have consistently shown MIA is associated to increased likelihood of developmental neuropsychiatric conditions; however, the effects are very heterogenous. The high percentage of infected women that give birth to neurotypical offspring highlight that one pregnancy may be more susceptible to MIA adverse outcomes than the other. Studies to identify these factors aim to protect fragile pregnancies and inform us on potential contributors to the development of neurodevelopmental conditions.

AM wrote the manuscript with support from DA and in consultation from DS, SB-C, and MK who supervised and provided critical feedback that shaped the final version of the manuscript.

Any views expressed are those of the author(s) and not necessarily those of the funder.

The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.

All claims expressed in this article are solely those of the authors and do not necessarily represent those of their affiliated organizations, or those of the publisher, the editors and the reviewers. Any product that may be evaluated in this article, or claim that may be made by its manufacturer, is not guaranteed or endorsed by the publisher.