Replication dynamics and cytotoxicity of SARS-CoV-2 Swedish isolate in commonly used laboratory cell lines

We assessed the infectivity, replication dynamics and cytopathogenicity of the first Swedish isolate of SARS-CoV-2 in six different cell lines of human origin and compared their growth characteristics. High replication kinetics in absence of cytopathic-effect observed in many cell lines provided important clues on SARS-CoV-2 pathogenesis.

Heterologous transmission with Dictyocaulus capreolus from roe deer (Capreolus capreolus) to cattle (Bos taurus)

Eight Swedish Red Breed cattle, about 2 months old, were experimentally infected with a Swedish isolate of Dictyocaulus viviparus (Dviv-Se) from cattle and D. capreolus from roe deer. The aims were to determine whether the roe deer lungworm is infective to cattle or if it can induce seroconversion in cattle against D. viviparus as measured with an ELISA. Four calves which were given 500 Dviv-Se infective larvae (L3) each by larval dosing for two successive days developed patent infection between days 23 and 25 post-inoculation (PI). Larval output varied among the calves and during the patent period. However, maximum recovery occurred between 28 and 56 days PI with peak shedding on day 37 PI. Shedding ceased at day 58 PI and adult worms were recovered from one calf at necropsy (day 67 PI). No immature worms were recovered from the lungs at necropsy. Seroconversion was detected on days 35–42 PI. One Dviv-Se infected calf became seronegative on day 67 PI whereas the other calves still remained seropositive during this period. Prepatency and patency periods of D. viviparus and serological findings in this study basically conform to previous studies. Each calf that was infected with 400 L3 of D. capreolus for two successive days, and about 800 L3 of the same species about 8 weeks later, did not develop to patency based on faecal and post-mortem examinations. Consequently, under the conditions of this study, D. capreolus was not infective to cattle. Two of the four calves that were infected with L3 from roe deer were challenged with L3 cultured from faeces of the Dviv-Se-infected calves. This infection did not develop to patency. Whether this was due to cross-protection as a result of the prior priming with L3 from roe deer is not clear. However, if it is so, it opens up the possibility of using D. capreolus L3 for preventing bovine dictyocauliasis.

First Report of Phytophthora Root and Collar Rot of Alder in Hungary

In June 1999, a disease associated with mortality of Alnus glutinosa, was observed in a 12- to 18-year-old peatland plantation in northwest Hungary. The root and collar rot symptoms were similar to those caused by Phytophthora cambivora in tree species other than alders. Nine isolations were made from diseased roots and soil samples using the Rhododendron leaf baiting method. Three isolates recovered from two sites, approximately 2 km apart, exhibited similar growth and morphology in vitro and were pathogenic to 2-year-old trees of A. glutinosa following inoculation of root collars. All three isolates had amphigynous long, two-celled antheridia. The mean diameter of oogonia ranged from 39.5 to 64.6 μm. They also produced nonpapillate, ellipsoid, non-caducous sporangia 26.9 to 50.5 μm long and 19.3 to 38.5 μm wide with broad exit pores in soil filtrate. These characteristics were similar to those reported for Phytophthora on alder from elsewhere in Europe and for P. cambivora that is not a pathogen of alder (1,2). However, Hungarian isolates from alder, in contrast to P. cambivora, were homothallic like previously recorded isolates from alder, formed nonornamented oogonia and developed colonies at lower optimum (approximately 25°C) and maximum (approximately 30°C) temperatures on carrot agar. A comparison with Phytophthora from alder from other countries (courtesy of C. M. Brasier) showed that the Hungarian isolates have smooth-walled oogonia typical of Swedish isolates rather than the ornamented oogonia of U.K. isolates, but have the appressed, slightly woolly colony morphology like U.K. isolates rather than the fluffy growth found in Swedish isolates. Moreover, cellulose acetate electrophoresis of glucose-6-phosphate isomerase revealed one homodimer band in Hungarian isolates that was identical with that of the Swedish isolate from alder P876 and isolates P1010 and P1011 of P. cambivora (courtesy of C. M. Brasier). This band comigrated with the middle one of the five-banded U.K. standard isolate P772. Molecular evidence (2) indicates that the Phytophthora from alder with its unusual characteristics is not a species in the strict sense but comprises natural hybrids that may have originated in an interspecific hybridization event between a P. cambivora-like species and an unknown species similar to P. fragariae. On this basis, the Hungarian Phytophthora from alder might have evolved similarly. It remains to be determined whether the pathogen was introduced or has developed independently. References: (1) C. M. Brasier et al. Plant Pathol. 44:999, 1995. (2) C. M. Brasier et al. Proc. Natl. Acad. Sci. USA 96:5878, 1999.