ZIKV Teratogenesis: Clinical Findings in Humans, Mechanisms and Experimental Models

Abstract

Zika virus (ZIKV) is an arthropod-borne virus (arbovirus) from the Flaviviridae family, first isolated from the Rhesus monkey in 1947 in Uganda. ZIKV is transmitted by mosquito bites, but vertical and sexual transmissions have also been reported. ZIKV infection during pregnancy causes malformation in the developing fetus, especially central nervous system (CNS) damages, with a noticed microcephaly, making ZIKV be recognized as a teratogenic agent and the responsible for congenital Zika syndrome (CZS). However, it is still a short time since CZS was first reported. Consequently, ZIKV pathogenesis is not entirely elucidated, especially considering that affected children are still under neurodevelopment. Here, we will explore the current knowledge about ZIKV teratogenesis focusing on neurological clinical findings in humans, mechanisms, and experimental models used to understand ZIKV pathophysiology.

Introduction

Although ZIKV infection is asymptomatic in most cases, the common signs and symptoms are fever, rash, arthralgia, and conjunctival hyperemia (1). It is noteworthy that ZIKV infection has also been related to more severe clinical outcomes, especially considering neurological signs, both in CNS and peripheral nervous systems, such as meningoencephalitis, acute myelitis, and Guillain-Barré syndrome (2).

In 2015, Brazil had a significant increase in the number of cases of newborns with microcephaly. In 2016, key works proved that ZIKV infection during pregnancy was responsible for the malformation in the developing fetus, especially leading to structural and neurological defects (3, 4). In vivo and in vitro approaches were decisive to demonstrate that ZIKV can cross the placental barrier affecting fetal development and has a tropism for neural progenitor cells (NPCs), showing a causal relationship between ZIKV and microcephaly (5, 6). Later on, and based on clinical investigation, other symptoms were associated with ZIKV pathogenesis during fetus neurodevelopment, such as brain calcifications, hydrocephalus, ventriculomegaly, lissencephaly, holoprosencephaly, seizures, and neurosensorial deficits (7). ZIKV was first identified as a possible teratogenic agent in Brazil in 2015, calling the clinical picture of newborns as Congenital Zika Syndrome (CZS). Studies suggest that fetal abnormalities induced by ZIKV may occur in all trimesters of pregnancy. However, the manifestations with the most significant negative impact are associated with infections in the first and second trimester (8), and depending on that period, ZIKV vertical infection can cause limitations of intrauterine growth, spontaneous abortion, and microcephaly.

Considering the information above mentioned, and being established a relationship between the increased number of microcephaly cases in newborns caused by ZIKV infection, the WHO declared in 2016 ZIKV infection during pregnancy as a public health emergency. ZIKV represents a threat on a global scale since there are no drugs and vaccines available to treat or prevent the infection (9).

The pathogenesis of ZIKV is still not fully understood. Here, we will overview ZIKV teratogenesis focusing on neurological clinical findings in humans, mechanisms, and experimental models used to understand ZIKV pathophysiology.

Neurological Clinical Findings in Human

After the outbreak in Brazil, many studies have associated ZIKV with neurological diseases in newborns whose mothers contracted the virus during pregnancy. Additionally, ZIKV RNA was identified in babies with microcephaly brain tissue (4). In microscopic examinations of a fetal brain infected with ZIKV, apoptotic neurons were observed, mainly post-migratory neurons with intermediate differentiation (10).

The harmful effects of congenital viruses on pregnancy and fetal outcomes are partly because of impaired trophoblastic function, as the placenta is a kind of selective barrier due to multiple immune and cellular structures (11). Profound pathological changes were observed in placentas infected by ZIKV, like abnormal fetal capillaries, trophoblastic apoptosis, increased fetal nucleated erythrocytes, which indicates a biological malfunction (12). ZIKV can infect the placenta through blood-placenta transmission leading to microcephaly and a severe loss of intracranial volume (13, 14). A neuroimaging report showed a cranial bone collapse in babies born from mothers suspected of having ZIKV during pregnancy (15). Magnetic resonance identified a spectrum of anomalies that include marked cortical thinning with an abnormal gyratory pattern, increased fluid spaces (ventricular and extra-axial), hypoplasia or absence of corpus callosum, and hypoplasia in the cerebellar vermis (16).

Postmortem CNS analysis from newborns who died within 48 h after birth from ischemia-associated consequences showed that ZIKV infects neuroglial progenitor cells. Calcifications and destructive lesions were also found, supporting changes in the brain, delayed cerebral atrophy, and transient convulsive activities (17–20).

Besides vertical transmission, neurological symptoms were also reported in adults after ZIKV infection. In adults, ZIKV infection has been associated with conditions of transverse myelitis, peripheral neuropathy, and meningoencephalitis (2, 21). An imaging study showed a reduced volume of gray matter in specific motor cortical regions compared with controls, leading to a life-term impact on the CNS (22). Acute myelitis was described 7 days after ZIKV infection in a teenager in Guadalupe. A spinal magnetic resonance imaging showed an increase in the thoracic and cervical spinal cord. ZIKV RNA was found in serum, urine, and cerebrospinal fluid (CSF) on the second day of neurological complaints. The presence of ZIKV in the CSF reinforces that ZIKV is neurotropic (23). Besides CNS, ocular abnormalities have also been reported as part of the effects of CZS and anomalies of the optic nerve, focal pigmentary gait, and chorioretinal atrophy (24, 25).

Based on current knowledge about the pathogenesis of ZIKV and the other defects that the infection causes in fetal development, ZIKV should be considered a TORCH pathogen (Toxoplasmosis, Other (syphilis, varicella-zoster, parvovirus B19), Rubella, Cytomegalovirus, and Herpes) (26). The similarities between congenital disorders considered TORCH and ZIKV are striking and say about their neurotropism (27). Malformations induced by TORCH and ZIKV pathogen depend on the gestational age of the fetal infection, being more severe as the earlier occurs during pregnancy, like in the first trimester of gestation. As the pregnancy progresses, the risk of congenital malformations that result from virus infections decreases and becomes low during and after the second trimester.

Mechanism of Teratogenesis Caused by ZIKV Infection

Studying the SARS-CoV-2′s pathogenesis mechanisms could help understand the symptoms caused by its illness, find drugs to combat the infection, and select potential targets for vaccines.

ZIKV is composed of a single positive-sense RNA strand, with ~10 kb, protected by a capsid and an envelope of lipids and proteins. Its genome codifies three structural proteins, pre-Membrane (prM), Envelope (E), and Capsid (C), and seven non-structural proteins (NS1, NS2A, NS2B, NS3, NS4a, NS4b, NS5).

ZIKV can enter Neural Progenitor Cells (NPCs) (and other cells of CNS) using mainly AXL receptor (AXL Receptor Tyrosine Kinase) in the cell surface (6). Once ZIKV enters the cell, its RNA is rapidly translated by local ribosomes into a polyprotein that encodes structural and non-structural proteins, which become part of the virions and play a role in viral replication. The virus modifies the cellular endoplasmic reticulum (ER), forming “replication factories” where viral replication and production of viral proteins occurs, inducing ER stress and unfolded protein response (UPR), which inhibits protein synthesis and activates ER-associated degradation (ERAD). Lastly, the viral genomes assemble with the new virions particles and are secreted through the Golgi apparatus.

Besides forming the replication machinery, non-structural proteins help to inhibit the antiviral response. NS5, NS2B, and NS3 regulate type 1 IFN pathways, NS5 protein inhibits human STAT2 suppressing IFN-I production and favoring viral proliferation (28) (Figure 1). Further, NS4A and NS4B have an important function related to apoptosis and growth arrest since they act together to inhibit the AKT-mTOR pathway (29), which causes mitochondrial elongation, and extends production of ATP (Adenosine Triphosphate) by oxidative phosphorylation resulting in a rise in reactive oxygen species by glial cells, increasing mitochondrial stress (30, 31). Increased cellular stress could activate the p53 intrinsic apoptosis pathway (32). So, proapoptotic proteins such as Bcl-2-associated protein X (BAX) cause the release of cytochrome C by mitochondria, which activates caspase pathways (33). Moreover, ZIKV's NS4B protein can directly recruit BAX from the cytosol into the mitochondria activating this apoptotic pathway (34) (Figure 1).

Figure 1

It is believed that the immune response elicited by the infection plays a role in this growth arrest. In NPCs, IFN-independent Interferon Stimulated Genes (ISG) activations, such as IRF3 (Interferon Regulatory Factor 3) or NF-?B (Nuclear Factor kappa B), were observed, while no TLR3 (toll-like receptor 3) responses were activated (35). Nevertheless, in brain organoids, in the late stage of development, TLR3 was overexpressed after ZIKV infection. TLR3 activation was correlated with 41 genes expression linked to neuronal development, suggesting a perturbation in neurogenesis. Moreover, since these genetic hubs are regulators of axon guidance processes, anti-apoptotic and cell-cycle pathways, they can mediate microcephaly phenotype as revealed in brain organoid models (36).

The mechanisms described here revealed how ZIKV causes apoptosis, cell cycle-growth arrest and induces premature differentiation, leading to microcephaly and other birth disorders. However, the link between molecular mechanisms and phenotypic clinical findings must be better understood to clarify why some fetuses are affected by ZIKV and others do not or why they have different grades of disease severity. Not only that but elucidating ZIKV pathogenesis will be beneficial for drug discovery to prevent CZS and vaccine development against ZIKV infection.

Experimental In Vitro Models: Brain Cells

Understanding associated teratogenic mechanisms and molecular pathways referred to as CZS are also related to understanding human development. Mouse models have provided important information on the subject, as most protein-coding genes are shared with humans (37, 38), but there are relevant restrictions, especially when considering eye and brain development (37) and gene expression patterns along with development (39) which present significant discrepancies when compared with humans. Furthermore, rodents need to have their antiviral defenses knocked down with dampened interferon responses to allow the viral infection (40, 41), which may raise questions about the use of this model.

Advances in producing and applying induced pluripotent stem cell (iPSC) technology have provided essential tools for disease modeling in vitro (42, 43). Through the application of different protocols of differentiation, neural progenitors, neurons, glia cells, and brain organoids derived from iPSC have been helpful for investigations on ZIKV infection (44).

Neural Progenitor Cells (NPCS)

Reports about ZIKV infection have shown that the Neural Progenitor Cells (NPCs) are sensible and permissive to the virus (45, 46). These reports, concomitant with the investigation of the association of prenatal ZIKV infection and microcephaly, and other malformations, revealed that ZIKV is a potential teratogen agent, culminating in physical or functional congenital disabilities from abnormal fetal development (47).

Until the new circulating strain called ZIKVBR, in 2015, there was no association between the virus and neurological symptoms or brain damage in humans (48). Up to 12 weeks postconception, the maternal blood and tissue face the fetal membranes within the placenta due to the restructured maternal circulation (49), which allows the ZIKVBR to target the NPCs after crossing the placenta, inducing cell apoptosis and autophagy (5). The Brazilian ZIKV strain was revealed as more aggressive and more harmful to the neurogenesis when compared to the first isolated ZIKV strain, the MR766 (5, 8, 29).

The differentiation of NPCs reaches the development process and populates the growing brain with neurons during prenatal development (50). Modeling the neurodifferentiation process by NPCs iPSC-derived helped to elucidate the mechanisms underlying ZIKV pathogenesis. ZIKV prejudices brain development, impairing cell division, proliferation and inducing apoptosis, leading to potentially disastrous consequences for CNS development (51, 52). Human neural stem cells (NSCs) isolated between 18 and 22 weeks of gestational age after conception unveil the suppression of host AKT-mTOR signaling by the cooperation of proteins NS4A and NS4B, upregulating autophagy for viral replication (29). The importance of autophagy relies on homeostasis control, being an efficient mechanism to limit pathogen infection. An AKT-mTOR signaling pathway is critical for cortical development (53) and AKT constitutive activation or loss of function is related to disorders as megalencephaly and microcephaly, respectively (54).

Inductive pathways and signaling shared between two surrounding embryonic structures may influence brain development by paracrine effects (55), like brain and face integrated development. As that craniofacial disproportion is related to ZIKV congenital infection (3), another work used cranial neural crest cells (CNCCs) signaling molecules. This approach provided evidence that the addition of leukemia inhibitory factor (LIF) or vascular endothelial growth factor (VEGF) cytokines in equivalent levels as the one produced during ZIKV infection results in precocious neurogenesis. This precocious neurogenesis contributes to a microcephaly phenotype, as migration and proliferation deregulated timing may affect brain size (56).

Neurons

In vitro neurons have also contributed to the effort to understand ZIKV infection effects over the CNS. ZIKV can infect mature neurons that express AXL receptors causing neurological disorders (30). Recent findings exhibited impaired neurogenesis and synaptogenesis process over neurons derived from iPSCs infected by the Brazilian ZIKV strain (57). Studies revealed a global downregulation of synaptic proteins, such as postsynaptic density protein SHANK2 (58, 59), and proteins associated with presynaptic precursors and presynaptic active zone, as VAMP2 (Vesicle-associated Membrane Protein 2) and complexin 2, Piccolo, Basson, and the Soluble NSF Attachment Receptor (SNARE) proteins (60–62). Those findings highlighted the vulnerability of the synaptic formation to the virus, leading to synaptic loss and contributing to mental and motor disabilities.

In another study, researchers analyzed miRNA profiles of primary mouse neurons after ZIKV infection. They showed that ZIKV causes a global downregulation of miRNAs with only a few upregulated miRNAs. On the other hand, ZIKV infection induces upregulation of antiviral, inflammatory, and apoptotic genes (63).

Glia Cells

Besides the destructive effect on neuronal structures, the pathogen also compromises glia cells functioning in the fetus, negatively impacting brain development. Astrocytes extending into the subarachnoid space were identified in affected brain region slices from a 32-week fetus infected with the virus (4). This period comprises extensive neurogenesis and gliogenesis, suggesting a significant contribution of the astrocyte impaired growth, contributing to microcephaly (64).

Human microglia cell line (CHME3), human astrocytes, and NPCs were challenged with the African ZIKV strain HD78788 for the study of AXL receptor role in ZIKV infection, reporting it as a crucial receptor for the virus infection on human glial cells by promoting viral entry after binding ZIKV-Gas6 complex, also damping innate immune responses in glial cells (65). AXL belongs to a group of tyrosine kinases receptors related to innate immunity regulation and mediates phagocytosis of apoptotic cells (66).

Underlying entry factors, like AXL, have been studied to elucidate flavivirus mechanisms of infection (67). Although signaling mechanisms that promote the disease outcome are still not well understood, further investigations should unveil mechanisms that could be the basis for developing suitable therapeutic strategies.

Brain Organoids

Brain organoids are a three-dimensional structure derived from human iPSC. Brain organoids can be differentiated in various regions from the brain, as hindbrain, midbrain, and forebrain neuron subtypes (68–71). These tools have been a breakthrough in studying neurodegenerative and neurodevelopmental disorders, allowing the modeling of several conditions such as autism and microcephaly (71–73).

Brain organoids have also proved advantageous to study the mechanisms involved in ZIKV pathogenesis. Important findings from ZIKV infection using brain organoids were possible due to the model's physiological relevance and its capacity to mimic the developing fetal brain. ZIKV infection reduces the neuronal cell layer in human brain organoids (52).

Cerebral organoids generated from H9 hESCs (Human Embryonic Stem Cells) were treated with MR766 ZIKV to investigate the role of TLR3 (toll-like receptor 3), an innate immune receptor, in the ZIKV infection, unveiling the TLR3 upregulation after infection on organoids. This upregulation causes dysregulation of neurogenesis, apoptosis, and organoid shrinkage, contributing to impaired neurogenesis and microcephaly (36). TLR3 has also been linked with negative activation of axogenesis (74).

In another study, Brazilian and African ZIKV strains were used to infect three-dimensional neural cell cultures, neurospheres, and cerebral organoids generated from hiPSCs. Brazilian ZIKV infected neurospheres presented significantly more morphological abnormalities than African ZIKV infected at 96 h post-infection (5). Cortical plate thickness and dividing cells reduction on ventricular zone were more significant in organoids infected by Brazilian ZIKV strain, as was the increased number of apoptotic cells. Decreased number of dorsal forebrain progenitors cells was verified in both ZIKV infections. Those findings verify the capacity of cerebral organoids to support analysis of different parts of the brain and highlight neurodevelopmental disorders mechanisms.

Funding

This work was sponsored by FAPESP (18/16748-8 and 16/02978-6), the Brazilian NGO the tooth fairy project and in part by the Coordenação de Aperfeiçoamento de Pessoal de Nivel Superior-Brasil (Capes)-Finance Code 001; and Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq), and a post doc fellowship supported by the Institute Pasteur.

Publisher's Note

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