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Review
. 2022 Jan 29;15(7):1231-1252.
doi: 10.1093/ckj/sfac008. eCollection 2022 Jul.

The kidney in hantavirus infection-epidemiology, virology, pathophysiology, clinical presentation, diagnosis and management

Felix C Koehler  1 Veronica Di Cristanziano  2 Martin R Späth  1 K Johanna R Hoyer-Allo  1 Manuel Wanken  1 Roman-Ulrich Müller  1 Volker Burst  1
Affiliations
Review

The kidney in hantavirus infection-epidemiology, virology, pathophysiology, clinical presentation, diagnosis and management

Felix C Koehler et al. Clin Kidney J. .

Abstract

Hantavirus-induced diseases are emerging zoonoses with endemic appearances and frequent outbreaks in different parts of the world. In humans, hantaviral pathology is characterized by the disruption of the endothelial cell barrier followed by increased capillary permeability, thrombocytopenia due to platelet activation/depletion and an overactive immune response. Genetic vulnerability due to certain human leukocyte antigen haplotypes is associated with disease severity. Typically, two different hantavirus-caused clinical syndromes have been reported: hemorrhagic fever with renal syndrome (HFRS) and hantavirus cardiopulmonary syndrome (HCPS). The primarily affected vascular beds differ in these two entities: renal medullary capillaries in HFRS caused by Old World hantaviruses and pulmonary capillaries in HCPS caused by New World hantaviruses. Disease severity in HFRS ranges from mild, e.g. Puumala virus-associated nephropathia epidemica, to moderate, e.g. Hantaan or Dobrava virus infections. HCPS leads to a severe acute respiratory distress syndrome with high mortality rates. Due to novel insights into organ tropism, hantavirus-associated pathophysiology and overlapping clinical features, HFRS and HCPS are believed to be interconnected syndromes frequently involving the kidneys. As there are no specific antiviral treatments or vaccines approved in Europe or the USA, only preventive measures and public awareness may minimize the risk of hantavirus infection. Treatment remains primarily supportive and, depending on disease severity, more invasive measures (e.g., renal replacement therapy, mechanical ventilation and extracorporeal membrane oxygenation) are needed.

Keywords: hantavirus cardiopulmonary syndrome; hantavirus disease; hemorrhagic fever with renal syndrome; kidney; nephropathia epidemica.

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Figures

FIGURE 1:
FIGURE 1:
Epidemiology of hantavirus infections in Europe. Incidence for hantavirus infection in 2019 as recorded by the European Centre for Disease Prevention and Control (ECDC). More than 4000 cases of hantavirus disease were reported in Europe (0.8 cases per 100,000 population), with detection of PUUV as the causative pathogen in 98% of cases. Finland and Germany accounted for 69% of all reported cases. Distribution of PUUV, Dobrava virus (DOBV), HTNV and Tula virus (TULV) across Europe are depicted by colour. Recent outbreak situations as reported to the ECDC from 2011 to 2021 are indicated with approximately affected cases and year of the outbreak in parenthesis. European countries that do not report hantaviral infections to the ECDC are depicted in grey (Belarus, Denmark, Moldavia, Montenegro, Kosovo, Ukraine).
FIGURE 2:
FIGURE 2:
European hosts for pathogenic hantaviruses. Source: Images were provided by Shutterstock.com: (A) Holger Kirk/Shutterstock.com, (B) Monika Surzin/Shutterstock.com, (C) Stephan Morris/Shutterstock.com, (D) corlaffra/Shutterstock.com and (E) Ryzhkov Sergey/Shutterstock.com.
FIGURE 3:
FIGURE 3:
Hantavirus structure and life cycle. Hantavirus virions have a trisegmented single-stranded ribonucleid acid (ssRNA) genome, referred to as L (large), M (medium) and S (small) segments. The particle's surface consists of the glycoproteins Gn and Gc and viral RNA-dependent RNA polymerase (RdRp) is essential for hantavirus replication and transcription. The hantavirus life cycle consists of eight essential steps. (1) Hantaviruses attach to the host cell's surface by binding to surface receptors with their glycoproteins. (2) The virion particle enters the host cell either by Clathrin-dependent (Old World hantavirus) or -independent endocytosis (New World hantavirus). (3) Hantaviruses are uncoated in the host cell's endosomes and lysosomes, facilitating the release of the viral genome and proteins. (4) Viral RNA is transcribed by the RdRp and (5) viral mRNA is translated into viral proteins, hijacking the host cell's machinery. (6) vRNA is replicated by RdRp and (7) all viral components are put together at the Golgi apparatus (Old World hantavirus) or directly at the cell membrane (New World hantavirus). (8) Mature virion particles egress the host cell by fusion of the Golgi apparatus (Old World hantavirus) or the viral vesicle (New World hantavirus) with the cell membrane. ER: endoplasmic reticulum; Gc: C-glycoprotein; Gn: N-glycoprotein; L: large segment; M: medium segment; S: small segment; vRNA: viral RNA. Source: Figure created with Biorender.com.
FIGURE 4:
FIGURE 4:
Hantavirus-caused pathogenesis is characterized by vascular leakage and platelet activation. Hantaviruses primarily infect endothelial cells, reducing their barrier function while increasing vascular permeability. Endothelial cell–cell contacts are disturbed by the downregulation of VE-cadherin in adherens junctions caused by vascular endothelial growth factor A (VEGFA) or bradykinin. Platelets are activated after hantavirus infection by either the direct interaction of viral glycoproteins and platelet integrin αIIβ3 or by endothelial cell damage releasing adhesive factors such as fibrinogen, fibronectin and von Willebrand factor. Hantavirus can additionally cause intravascular coagulation. Both activated platelets and coagulation contribute to thrombocytopenia. Source: Figure created with Biorender.com and figure concept adapted from Vaheri et al. [23].
FIGURE 5:
FIGURE 5:
The typical disease course in HFRS can be divided into five distinct phases: fever, hypotension, oliguria, polyuria and convalescence. After human infection, viral load peaks after 5–10 days and prodromal symptoms such as flu-like symptoms, myalgia, backache, abdominal pain and blurred vision occur. In parallel, platelets as well as urine output and kidney function decrease, leading to the hallmark triad of AKI, hypotension and hemorrhages in HFRS. With the onset of clinical symptoms, antibodies increase, leading to viral clearance and convalescence. Source: Figure created with Biorender.com and figure concept adapted from Avsic-Zupanc et al. [3].
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