key: cord-0843530-mxpsyhrn
authors: Bai, Chongzhi; Hao, Jianqing; Li, Shihua; Gao, George Fu; Nie, Yu; Han, Pengcheng
title: Myocarditis and heart function impairment occur in neonatal mice following in utero exposure to the Zika virus
date: 2021-02-15
journal: J Cell Mol Med
DOI: 10.1111/jcmm.16064
sha: f7427b48d16885040172aca1c3015aa7a6245eff
doc_id: 843530
cord_uid: mxpsyhrn

nan

Human cardiovascular diseases can be caused by infection with various viruses, such as coxsackievirus, influenza virus, human herpesvirus, Epstein-Barr virus, hepatitis C virus, human immunodeficiency virus 1 or severe acute respiratory syndrome coronavirus 2, 2 which is currently circulating worldwide. It has been reported that infection with Zika virus (ZIKV) leads to severe neurological disorders, 3 testis damage, 4 and heart failure and arrhythmias. 5, 6 A hypothesis for heart defects associated with intrauterine exposure to ZIKV was proposed by Angelidou et al 7 who reported a case of congenital heart disease in one infant with congenital Zika syndrome. In addition, three other studies reported that antenatal exposure to ZIKV was related to cardiac defects in infants, [8] [9] [10] but the pathophysiological mechanisms by which ZIKV leads to impairment of heart function are still unclear.

Here, we established an in utero transmission model of ZIKV infection by injecting 10 4 plaque-forming units (pfu) of ZIKV into the embryonic placenta of 2-weeks pregnant BALB/c mice. Among the 11 newborns, three neonatal mice presented paralytic symptoms, implying severe neurological disorders. We performed immunohistochemistry with monoclonal antibody Z6 4 to determine whether ZIKV direct infection occurred both in the neonatal brain and heart at day 9 after birth. High levels of ZIKV were detected in both the heart and brain of paralytic mice ( Figure 1A , infected). The other eight newborn mice exhibited normal phenotype, and no virus was detected ( Figure 1A , uninfected). To examine whether direct infection occurred in the myocardium of neonatal mice, ZIKV was detected by immunofluorescence using the monoclonal antibody Z6. We found that Z6 was localized in cardiomyocytes (α-actinin + ) of ZIKV-infected mice 9 days after birth, and Z6 was not observed in the hearts of uninfected mice ( Figure 1B Bai and Hao contributed equally to this work. T (cTnT) was dramatically elevated at days 4 and 9 after birth in ZIKV-infected mice compared to uninfected mice ( Figure 1G ,H), indicating that cardiac injury occurred. Our results indicated that foetal hearts are susceptible to ZIKV infection and that ZIKV can directly infect the myocardium and lead to heart dysfunction in ZIKV-infected neonatal mice.

ZIKV is associated with myocarditis and heart failure in patients. 6 We performed haematoxylin-eosin staining of neonatal mouse heart sections and found that ZIKV causes massive monocyte infiltration in the myocardium at 9 days after birth ( Figure 1I ).

Immunohistochemistry showed that the numbers of F4/80 + macrophages and CD3 + leucocytes were significantly increased in the myocardium at day 9 after birth in ZIKV-infected mice compared to uninfected mice ( Figure 1J ). Gene ontology analysis revealed that up-regulated genes were enriched for immune-related pathways, whereas down-regulated genes were enriched for pathways related to heart function ( Figure 1K ). Simultaneously, the levels of myocarditis-related genes, including Ccl5 11 and Myh7, 12 are increased, whereas the expression of heart development-related genes, including Nrp2 13 and Rbp4, 14 was decreased in heart tissue as demonstrated by RNA sequencing ( Figure 1L ). We observed ZIKV infection and functional impairment in the hearts of foetal mice ( Figure 1B) and IFNα/β receptor knockout mice adult mice ( Figure S1 ), but not in BALB/c WT adult mice hearts ( Figure   S1 ), which indicates that the hearts of immune-deficient and foetal mice are more susceptible to ZIKV infection. Therefore, it will be appropriate to elevate the titre of ZIKV to determine whether adult WT hearts would infect because another study had reported that people who were positive for ZIKV were diagnosed with myocarditis, arrhythmias and heart failure. 6 It will be desirable to investigate whether ZIKV infects BALB/c WT pregnant mice due to a greater burden on the existing physiological changes in organs during pregnancy. 15 Our results using the embryo injection mouse model show important implications for explaining maternal-infant outcome in women exposed to ZIKV during pregnancy. Thus, more attention should be paid to cardiovascular symptoms in clinical practice, and further studies to elucidate the mechanisms underlying cardiac dysfunctions associated with ZIKV infection are urgently needed. 

This study was carried out in accordance with the recommenda- 

In utero exposure of foetal mice to ZIKV leads to myocarditis and heart function impairment. A, Immunohistochemistry of heart tissue sections stained for ZIKV in the brain and heart of offspring at day 9 after birth. In the infected and uninfected groups, n = 3 and n = 8 mice were included, respectively. Representative results from one mouse are displayed. B, Immunostaining shows that ZIKV (green) is detectable in cardiomyocytes (α-actinin + , red) of ZIKV-infected mice 9 d after birth. C-F, Echocardiography revealed that ejection fraction and fractional shortening were decreased at days 4 and 9 after birth (C, D), and diastolic and systolic diameters increased at days 4 and 9 after birth (E, F). Mock (n = 5), ZIKV-infected (n = 3) and uninfected (n = 8) offspring, respectively. Each dot represents one mouse. *P < .05; **P < .01. G, H, ECLA shows that serum CK-MB and cTnT levels are elevated in ZIKV-infected mice at days 4 and 9 after birth. Mock (n = 5), ZIKV-infected (n = 3) and uninfected (n = 8) offspring, respectively. Each dot represents one mouse. *P < .05; **P < .01. I, J, Haematoxylin-eosin staining displays monocyte infiltration in the myocardium. Immunohistochemistry showed that the numbers of F4/80 + macrophages and CD3 + leucocytes were significantly increased in the myocardium of ZIKV-infected mice compared to uninfected mice at 9 d after birth. K, Gene ontology (GO) analysis of up-regulated (left) and down-regulated genes (right), respectively, based on RNA-Seq data. The top 10 GO terms are shown. L, Heat maps showing hierarchical clustering of enriched differentially expressed genes between ZIKVinfected and uninfected mouse hearts. Each lane represents the result from one mouse. n = 3 in each group

Chongzhi Bai https://orcid.org/0000-0002-6293-6141

Autosomal recessive cardiomyopathy presenting as acute myocarditis

The science underlying COVID-19: implications for the cardiovascular system

Zika virus disrupts neural progenitor development and leads to microcephaly in mice

Zika virus causes testis damage and leads to male infertility in mice

Transient myocarditis associated with acute Zika virus infection

Association of Zika virus with myocarditis, heart failure, and arrhythmias: a literature review

Is there more to Zika? Complex cardiac disease in a case of congenital Zika syndrome

Echocardiographic findings in infants with presumed congenital Zika syndrome: retrospective case series study

Cardiac findings in infants with in utero exposure to Zika virus-a cross sectional study

Congenital Zika syndrome: is the heart part of its spectrum?

Innate immune interleukin-1 receptor-associated kinase 4 exacerbates viral myocarditis by reducing CCR5(+) CD11b(+) monocyte migration and impairing interferon production

The translational landscape of the human heart

Emerging roles for neuropilin-2 in cardiovascular disease

Inhibitory effect of octyl-phenol and bisphenol A on calcium signaling in cardiomyocyte differentiation of mouse embryonic stem cells

Serial study of factors influencing changes in cardiac output during human pregnancy