Human influenza A virus causes myocardial and cardiac-specific conduction system infections associated with early inflammation and premature death

AIMS

Human influenza A virus (hIAV) infection is associated with important cardiovascular complications, although cardiac infection pathophysiology is poorly understood. We aimed to study the ability of hIAV of different pathogenicity to infect the mouse heart, and establish the relationship between the infective capacity and the associated in vivo, cellular and molecular alterations.

METHODS AND RESULTS

We evaluated lung and heart viral titres in mice infected with either one of several hIAV strains inoculated intranasally. 3D reconstructions of infected cardiac tissue were used to identify viral proteins inside mouse cardiomyocytes, Purkinje cells, and cardiac vessels. Viral replication was measured in mouse cultured cardiomyocytes. Human-induced pluripotent stem cell-derived cardiomyocytes (hiPSC-CMs) were used to confirm infection and study underlying molecular alterations associated with the in vivo electrophysiological phenotype. Pathogenic and attenuated hIAV strains infected and replicated in cardiomyocytes, Purkinje cells, and hiPSC-CMs. The infection was also present in cardiac endothelial cells. Remarkably, lung viral titres did not statistically correlate with viral titres in the mouse heart. The highly pathogenic human recombinant virus PAmut showed faster replication, higher level of inflammatory cytokines in cardiac tissue and higher viral titres in cardiac HL-1 mouse cells and hiPSC-CMs compared with PB2mut-attenuated virus. Correspondingly, cardiac conduction alterations were especially pronounced in PAmut-infected mice, associated with high mortality rates, compared with PB2mut-infected animals. Consistently, connexin43 and NaV1.5 expression decreased acutely in hiPSC-CMs infected with PAmut virus. YEM1L protease also decreased more rapidly and to lower levels in PAmut-infected hiPSC-CMs compared with PB2mut-infected cells, consistent with mitochondrial dysfunction. Human IAV infection did not increase myocardial fibrosis at 4-day post-infection, although PAmut-infected mice showed an early increase in mRNAs expression of lysyl oxidase.

CONCLUSION

Human IAV can infect the heart and cardiac-specific conduction system, which may contribute to cardiac complications and premature death.

Complete atrioventricular block in experimental murine myocarditis

BACKGROUND

There were few reports on the pathological characteristics of the conduction system in myocarditis. This study was aimed to clarify the pathological characteristics of complete atrioventricular (AV) block in myocarditis.

METHODS AND RESULTS

We studied serial electrocardiograms in experimental myocarditis in mice and also examined their cardiac pathology. After taking baseline electrocardiograms, mice were inoculated intraperitoneally with the encephalomyocarditis virus. Electrocardiograms were serially recorded until day 360. Serial electrocardiograms revealed the appearance of complete AV block. Myocardial lesions were found in the hearts of mice with these ectopic beats. Mononuclear cell infiltrations into the His bundle and necrotic lesions of the conduction system were found in 10.7% (18/168) of mice with complete AV block. However, 17.3% (29/168) of mice showed no evident pathological lesions except the edematous changes of AV node.

CONCLUSIONS

The appearance of complete AV block in myocarditis may suggest not only significantly comparable pathological lesions of the conduction system but also the trivial edematous changes; in clinical settings, in the former case, permanent pacing therapy is necessary, and in the latter case, the disease may be transient and could be recovered from complete AV block. This study may shed light on the pathological characteristics of complete AV block in myocarditis.

Myocarditis and sudden infant death syndrome

This is a retrospective survey of findings of myocarditis in 437 infants under the age of 1 year who died suddenly and unexpectedly between 1982 and 1999, and were investigated at the Department of Forensic Medicine in Stockholm, Sweden. Myocarditis was diagnosed in 69/410 infants who died naturally (16.8%) and in 2/27 violent deaths (7.4%). In 43/410 natural deaths (10.5%) the myocarditis was an isolated finding and the only explanation for cause of death and in 26 (6.3%) there were additional possible causes of death. The myocarditis was acute in 45/69 and chronic in 24/69 natural deaths, and was found to occur as early as at a few weeks of age. No specific risk factors were found when reviewing critical time of year, age, gender, previous symptoms, sleeping position, aspiration of gastric contents and environmental factors in infant deaths with finding of myocarditis compared to 313 deaths due to sudden infant death syndrome. Myocarditis was found in 13 of 37 deaths where cultures for cytomegalovirus were positive. More than 50% of the foci of the isolated myocarditis were located in the upper part of the interventricular septum and the adjacent part of the right atrium, areas including parts of the conduction system. This localisation is significant for the cause of death when comparing deaths with myocarditis as an isolated finding to deaths with other possible causes.

Development of the cardiac conduction system involves recruitment within a multipotent cardiomyogenic lineage

The cardiac pacemaking and conduction system sets and maintains the rhythmic pumping action of the heart. Previously, we have shown that peripheral cells of the conduction network in chick (periarterial Purkinje fibers) are selected within a cardiomyogenic lineage and that this recruitment occurs as a result of paracrine cues from coronary arteries. At present, the cellular derivation of other elements of this specialized system (e.g. the nodes and bundles of the central conduction system) are controversial, with some proposing that the evidence supports a neurogenic and others a myogenic origin for these tissues. While such ontological questions remain, it is unlikely that progress can be made on the molecular mechanisms governing patterning and induction of the central conduction system. Here, we have undertaken lineage-tracing strategies based on the distinct properties of replication-incompetent adenoviral and retroviral lacZ-expressing constructs. Using these complementary approaches, it is shown that cells constituting both peripheral and central conduction tissues originate from cardiomyogenic progenitors present in the looped, tubular heart with no detectable contribution by migratory neuroectoderm-derived populations. Moreover, clonal analyses of retrovirally infected cells incorporated within any part of the conduction system suggest that such cells share closer lineage relationships with nearby contractive myocytes than with other, more distal elements of the conduction system. Differentiation birthdating by label dilution using [(3)H]thymidine also demonstrates the occurrence of ongoing myocyte conscription to conductive specialization and provides a time course for this active and localized selection process in different parts of the system. Together, these data suggest that the cardiac conduction system does not develop by outgrowth from a prespecified pool of ‘primary’ myogenic progenitors. Rather, its assembly and elaboration occur via processes that include progressive and localized recruitment of multipotent cardiomyogenic cells to the developing network of specialized cardiac tissues.