European Bat Lyssavirus Infection in Spanish Bat Populations

The sequence of 5568 nucleotides of the 3' moiety of the Mokola virus genome (serotype 3 of lyssaviruses) encompassing the nucleoprotein (N), phosphoprotein, matrix protein, and glycoprotein genes is presented and compared to that of the vaccinal strains of serotype 1. It allowed us to determine consensus sequences derived from the transcriptional start/stop signals and the order of protein conservation (nucleoprotein > matrix protein > phosphoprotein) in lyssaviruses. The sequences of the N gene of a fox rabies virus isolate from France (serotype 1), Lagos bat virus (serotype 2), Duvenhage virus (serotype 4), two European bat lyssaviruses (EBL) subtype 1, and two EBL subtype 2 were also determined to study the genetic diversity throughout the whole Lyssavirus genus and reinvestigate the classification of this genus. Six clearly distinct genotypes can be distinguished according to their percentage of amino acid similarity. Genotypes 2 (Lagos bat virus) and 3 (Mokola virus) are the most phylogenetically distant from the vaccinal and classical rabies viruses of genotype 1. Genotypes 4 (Duvenhage virus) and 5 (EBL1) are closely related to each other. Genotype 6 is represented by EBL2. Compared to the N proteins of the four principal serotypes of the Vesiculovirus genus (vesicular stomatitis virus serotype New Jersey and serotype Indiana, Chandipura virus, and Piry virus), the N gene of lyssaviruses exhibits a lower genetic variability.

Forty-seven European bat lyssaviruses (EBL) and two African insectivorous bat lyssaviruses (Duvenhage viruses) were selected for a comparison to be made of their evolutionary relationships. Studies were based on direct sequencing of the PCR-amplified products of the 400 nucleotides coding for the amino terminus of the nucleoprotein. Phylogenetic relationships were analysed after bootstrap resampling using the maximum parsimony and the neighbour-joining methods. Analyses of both the nucleotide and amino acid sequences placed these viruses in three separate clusters, namely genotype 4 (Duvenhage), genotype 5 (EBL1) and genotype 6 (EBL2). Evolutionary analysis of the nucleoprotein gene of EBL1 and EBL2 indicated low intrinsic heterogeneity mainly due to synonymous substitutions. In addition, both EBL1 and EBL2 evolved into at least two genetically distinguishable lineages (a and b) following geographical drifting. We can speculate that subsequently the lineages EBL1a and EBL1b were introduced into parts of northern Europe from two different geographical directions; EBL1b was probably introduced most recently and was from North Africa. Eptesicus serotinus appears to be the principal reservoir for EBL1 and Myotis dasycneme and M. daubentonii the reservoirs for EBL2.

Rabies cDNA clones, obtained by "walking along the genome" using two successive DNA primers, have allowed the sequence determination of the genes encoding the N, M1, M2, G, and the beginning of the L protein as well as the rabies intergenic regions. Start and stop transcription signals located at the border of each gene encoding a protein have been identified and are similar to the corresponding signals from vesicular stomatitis virus (VSV) and Sendai virus. Except for limited stretches of the nucleoprotein, there is no homology between corresponding structural proteins of these three viruses. Rabies intergenic regions are variable both in length and sequence. Evidence for the existence of a remnant protein gene in the 423 nucleotide long G-L intergenic region is presented. This finding is discussed in terms of the evolution of unsegmented negative-strand RNA viruses.