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Volume 18, Number 6—June 2012
Letter

Schmallenberg Virus in Calf Born at Term with Porencephaly, Belgium

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To the Editor: From the end of August through the end of October 2011, a clinical syndrome involving adult cattle and the fetuses of pregnant cows emerged in the border area between the Netherlands and North Rhine-Westphalia, Germany (1). The syndrome was characterized by nonspecific clinical signs (fever, decreased milk production), severe diarrhea, and some abortions. A metagenomic analysis was conducted on pooled samples from cattle with acute signs on a farm in the city of Schmallenberg, Germany.

The analysis detected nucleotide sequences homologous to arthropod-borne Akabane, Aino, and Shamonda viruses, all belonging to the family Bunyaviridae, genus Orthobunyavirus, and Simbu serogroup (1). Real-time PCR detected the genomic RNA of the new and emerging virus, tentatively designated Schmallenberg virus (SBV), in the blood of adult cattle, abdominal fluid of a stillborn calf, and brains of lambs born with birth defects on dozens of farms in the Netherlands, Germany, and Belgium. No data are yet available to predict how the emerging virus might affect the cattle industry. We report the case of a 1-week old calf with severe central nervous system (CNS) lesions probably caused by in utero infection with the new virus.

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Thumbnail of A 7-day old, female, Schmallenberg virus–positive calf showing severe central nervous system dysfunctions (A–C) and lesions (D–E). A) Spontaneously lying down; B–C) standing with assistance; D–G) hydranencephaly, either with the encephalon in place (D–E) or extracted (F–G). The cerebral hemispheres were replaced by 2 thin-walled, fluid-filled cysts (diamonds) with some floating islets and peninsulae corresponding to preserved cortex (stars). The cerebrum was variably preserved, the

Figure. . . A 7-day old, female, Schmallenberg virus–positive calf showing severe central nervous system dysfunctions (A–C) and lesions (D–E). A) Spontaneously lying down; B–C) standing with assistance; D–G) porcencephaly, either with...

In Belgium in January 2012, a Belgian Blue multiparous cow gave birth to a 45-kg female calf that was morphologically normal but hypertonic and hyperreflexic. Pregnancy had proceeded uneventfully and lasted 9 months and 4 days. Spontaneous reflexes such as sucking, swallowing, micturition, defecation, and crying were completely preserved, but the calf was unable to stand, and its consciousness alternated from mild to severe depression. It was obviously blind and showed ventrolateral strabismus, but the pupils functioned normally. Muscle tone was permanently increased, as indicated by tetanus-like erection of the ears and by a violent but brief startle response to the slightest acoustic or tactile stimulation (Figure). When the calf was placed upright, loss of conscious proprioception was obvious; it maintained its position only a few seconds before collapsing. Altogether, the clinical signs suggested severe dysfunctions of the cerebral cortex, basal ganglia, and mesencephalon. The calf drank from a bottle twice a day for a week, but then was euthanized for humane reasons (infected decubital ulcers).

At necropsy, the cerebellum, brainstem, and diencephalon appeared normal in shape and volume (Figure). However, the cerebral hemispheres were replaced by 2 thin-walled, fluid-filled cysts with some floating islets and peninsulae corresponding to preserved cortex. There was variable preservation of the cerebrum, total liquefaction of occipital lobes, and irregular preservation of the outer layers of some parts of the temporal and frontal lobes. Altogether, the picture was compatible with severe porencephaly or hydranencephaly. The spine showed no sign of scoliosis, and movement of the limb joints was not restricted (i.e., no arthrogryposis).

Samples were removed from the remnants of the cerebrum, diencephalon, and organs (thymus, lung, myocardium, jejunum, ileum, mesenteric lymph node, liver, spleen, kidney, and striated muscle), and 3 independent real-time PCR protocols were conducted to detect genomes of bovine viral diarrhea/mucosal disease virus, bluetongue virus serotype 8, and the novel SBV. Initial retrotranscription of the RNA genomes was followed by quantitative (real-time) PCR. The process was conducted by using our procedures (2) and, for SBV, by following the protocol and using recently developed control reagents as described (1). The SBV genome was detected in only CNS samples (quantification cycle value 28.8); bovine viral diarrhea/mucosal disease virus and BTV-8 genomes were not detected. The new virus genome load was 1.61 × 104 copies per gram of cerebrum sample.

Taken together, the above data suggest that, like other Simbu serogroup viruses, the new virus crosses the placenta, contaminates the bovine fetus, infects the fetus’ CNS, and causes necrosis and/or developmental arrest of the cerebral cortex. Unlike the viruses mentioned above (3,4), and provided this case is not an exception, the SBV genome seems to persist in the infected fetus and is detectable after birth by real-time reverse transcription PCR, despite gestation length. Although reliable reagents for detecting seroconversion are temporarily unavailable, the persistence of the new virus in fetal tissue should greatly facilitate the epidemiologic monitoring of the emergence and spread of the new virus.

When calves from experimentally infected dams are infected with the closest phylogenetic relative to SBV, Akabane virus, porencephaly develops during gestational days 62–96 (5). If the same is true for the new virus, the above calf was probably infected during June 9–July 13, 2011. Therefore, it is hypothesized that infected arthropods were already circulating in the village of Hamois-in-Condroz (50°24′56′′N, 5°8′7′′E), which is ≈240 km southwest of Schmallenberg (51°8′42′′N, 8°17′18′′E), ≈2 months before the emergence of the clinical syndrome that led to the identification of the new virus.

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Acknowledgment

We thank Michaël Sarlet, Deborah Kleijnen, and Christian Korthase for enthusiastic and skilled technical support.

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Mutien-Marie Garigliany, Bernd Hoffmann, Marc Dive, Arnaud Sartelet, Calixte Bayrou, Dominique Cassart, Martin Beer, and Daniel DesmechtComments to Author 
Author affiliations: University of Liège, Liège, Belgium (M.-M. Garigliany, M. Dive, A. Sartelet, C. Bayrou, D. Cassart, D. Desmecht); Friedrich-Loeffler-Institut, Greifswald–Insel Riems, Germany (B. Hoffmann, M. Beer)

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References

  1. Hoffmann  B, Scheuch  M, Höper  D, Jungblut  R, Holsteg  M, Schirrmeier  H, Novel orthobunyavirus in cattle, Europe, 2011. Emerg Infect Dis. 2012;18:46972. DOIPubMedGoogle Scholar
  2. Garigliany  M, De Leeuw  I, Kleijnen  D, Vandenbussche  F, Callens  J, Van Loo  H, The presence of bluetongue virus serotype 8 RNA in Belgian cattle since 2008. Transbound Emerg Dis. 2011;58:5039. DOIPubMedGoogle Scholar
  3. Porterfield  JS, Della-Porta  AJ. Bunyaviridae: infections and diagnosis. In: Kurstak E, Kurstak C, editors. Comparative diagnosis of viral diseases, Vol. IV. New York: Academic Press; 1981. p. 479–508.
  4. Inaba  Y, Matsumato  M. Akabane virus. In: Dinter Z, Morein B, editors. Virus infections of ruminants. Amsterdam: Elsevier Science Publishers; 1990. p. 467–480.
  5. Kurogi  H, Inaba  Y, Takahashi  E, Sato  K, Satoda  K. Congenital abnormalities in newborn calves after inoculation of pregnant cows with Akabane virus. Infect Immun. 1977;17:33843.PubMedGoogle Scholar

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DOI: 10.3201/eid1806.120104

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Daniel Desmecht, Pathology, Faculty of Veterinary Medicine, University of Liège, Sart Tilman B43, Liège 4000, Belgium

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Page created: May 11, 2012
Page updated: May 11, 2012
Page reviewed: May 11, 2012
The conclusions, findings, and opinions expressed by authors contributing to this journal do not necessarily reflect the official position of the U.S. Department of Health and Human Services, the Public Health Service, the Centers for Disease Control and Prevention, or the authors' affiliated institutions. Use of trade names is for identification only and does not imply endorsement by any of the groups named above.
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