B.A.M. van der Zeijst

Genetic Variation and Evolutionary Origin of the Direct Repeat Locus of Mycobacterium tuberculosis Complex Bacteria

The direct repeat region in Mycobacterium tuberculosis complex strains is composed of multiple direct variant repeats (DVRs), each of which is composed of a 36-bp direct repeat (DR) plus a nonrepetitive spacer sequence of similar size. It has been shown previously that clinical isolates show extensive polymorphism in the DR region by the variable presence of DVRs, and this polymorphism has been used in the epidemiology of tuberculosis. In an attempt to better understand the evolutionary scenario leading to polymorphic DR loci and to improve strain differentiation by spoligotyping, we characterized and compared the DNA sequences of the complete DR region and its flanking DNA of M. tuberculosis complex strains. We identified 94 different spacer sequences among 26 M. tuberculosis complex strains. No sequence homology was found between any of these spacers and M. tuberculosis DNA outside of the DR region or with any other known bacterial sequence. Although strains differed extensively in the presence or absence of DVRs, the order of the spacers in the DR locus was found to be well conserved. The data strongly suggest that the polymorphism in clinical isolates is the result of successive deletions of single discrete DVRs or of multiple contiguous DVRs from a primordial DR region containing many more DVRs than seen in present day isolates and that virtually no scrambling of DVRs took place during evolution. Because the majority of the novel spacer sequences identified in this study were confined to isolates of the rare Mycobacterium canettii taxon, the use of the novel spacers in spoligotyping led only to a slight improvement of strain differentiation by spoligotyping.

Evidence for a coiled-coil structure in the spike proteins of coronaviruses

Abstract The amino acid sequences of the spike proteins from three distantly related coronaviruses have been deduced from cDNA sequences. In the C-terminal half, an homology of about 30% was found, while there was no detectable sequence conservation in the N-terminal regions. Hydrophobic “heptad” repeat patterns indicated the presence of two α-helices with predicted lengths of 100 and 50 Å, respectively. It is suggested that, in the spike oligomer. these α-helices form a complex coiled-coil, resembling the supersecondary structures in two other elongated membrane proteins, the haemagglutinin of influenza virus and the variable surface glycoprotein of trypanosomes.

Location of antigenic sites defined by neutralizing monoclonal antibodies on the S1 avian infectious bronchitis virus glycopolypeptide

Neutralizing monoclonal antibodies directed against five antigenic sites on the spike (S) S1 glycopolypeptide of avian infectious bronchitis virus (IBV) were used to select neutralization-resistant variants of the virus. By comparing the nucleotide sequence of such variants with the sequence of the IBV parent strain, we located five antigenic sites on the amino acid sequence of the S1 glycopolypeptide. The variants had mutations within three regions corresponding to amino acid residues 24 to 61, 132 to 149 and 291 to 398 of the S1 glycopolypeptide. The location of three overlapping antigenic sites on the IBV spike protein was similar to the location of antigenic sites on the spike protein of other coronaviruses.

Phylogeny of antigenic variants of avian coronavirus IBV

Abstract The sequences of the peplomeric S1 protein of four serologically distinct strains of the infectious bronchitis virus (IBV), an avian coronavirus, have been determined. The S1 protein is thought to contain the serotype-specific neutralization epitopes and to be the main target of antigenic variation. An alignment with sequences of three strains published previously showed that from the 545 amino acid residues only 243 have been conserved. Clustering of substitutions suggests that most serotype determinants are located within the first 300 amino acid residues of S1. A phylogenetic tree of the S1 sequences showed very variable rates of divergence. Differences in topology with a tree based on RNAse-T1 fingerprint data indicate that some of the IBV strains have arisen by genetic recombination.

The positive regulator CfaD overcomes the repression mediated by histone-like protein H-NS (H1) in the CFA/I fimbrial operon of Escherichia coli.

CFA/I fimbriae of enterotoxigenic Escherichia coli are expressed at 37 degrees C and not at 20 degrees C. Expression of CFA/I fimbriae requires two DNA regions (regions 1 and 2) which are separated by 40 kb on the wild type plasmid. Region 2 encodes a protein (CfaD) which activates the promoter in region 1. We investigated whether the histone‐like protein H‐NS (H1) of E.coli is involved in the temperature regulated expression of CFA/I fimbriae. As demonstrated recently with other temperature regulated genes, a mutation in the gene coding for this nucleoid‐associated H‐NS (H1) protein resulted in derepression of CFA/I expression. CFA/I fimbriae were now expressed both at 20 degrees C and 37 degrees C. More strinkingly, the positive regulator CfaD was not needed for CFA/I expression in an H‐NS‐ strain. This indicates that CfaD diminishes an inhibitory effect of the H‐NS nucleoid‐associated protein. We also showed that in the H‐NS‐ strain the CfaD protein still has a positive effect on the transcription of CFA/I.

Sequence evidence for RNA recombination in field isolates of avian coronavirus infectious bronchitis virus.

Abstract Under laboratory conditions coronaviruses were shown to have a high frequency of recombination. In The Netherlands, vaccination against infectious bronchitis virus (IBV) is performed with vaccines that contain several life-attenuated virus strains. These highly effective vaccines may create ideal conditions for recombination, and could therefore be dangerous in the long term. This paper addresses the question of the frequency of recombination of avian coronavirus IBV in the field. A method was sought to detect and quantify recombination from sequence data. Nucleotide sequences of eight IBV isolates in a region of the genome suspected to contain recombination, were aligned and compared. Phylogenetic trees were constructed for different sections of this region. Differences in topology between these trees were observed, suggesting that in three out of eight strains in vivo RNA recombinant had occurred.

Molecular epidemiology of infectious bronchitis virus in the Netherlands

Twelve Dutch isolates and the M41 strain of infectious bronchitis virus (IBV), a coronavirus of chickens, were characterized by cross-neutralization and T1 finger-printing to elucidate their evolutionary relationship. The T1 fingerprinting showed that the Dutch isolates formed two clusters. The first cluster contained strains H52, H120, D387, V1259, V1385 and V1397; the estimated sequence homology is 99%. Cluster two comprised strains D207, D274, D212, D1466, D3128 and D3896, which have about 95% sequence homology. The M41 virus did not belong to either cluster. The four different serotypes which arose in the late 1970s belonged to cluster two and appeared to be different from the vaccine strains (H52 and H120) used at that time. This indicates that the strains were newly introduced and could have arisen from a common virus. On the other hand, three recently isolated field strains were genetically closely related to the vaccine strains H120 and H52 (cluster one), suggesting that these live vaccine strains themselves could have given rise to these serologically altered field isolates. The data are relevant to the development of new vaccine strategies.

The peplomer protein sequence of the M41 strain of coronavirus IBV and its comparison with Beaudette strains

Abstract The amino acid sequence of the gene for the peplomer protein of the vaccine strain M41 and the Beaudette laboratory strain M42-Salk of avian infectious bronchitis virus (IBV) have been derived from cDNA sequences. As found with other coronaviruses, the peplomer protein carries the epitopes eliciting neutralizing antibodies. The gene encodes a primary translation product of 1162 amino acids with a molecular weight of 128079. The use of a recent algorithm to predict membrane-protein interactions led to the unambiguous localization of the signah peptide and a transmembrane anchor α-helix at the C-terminus. At 50 positions amino acid differences were found between M41 and two Beaudette strains (M42-Salk and M42-Houghton). They are partly clustered in two regions of the protein. These two regions are candidates for neutralization epitopes of the protein.

The structural proteins of equine arteritis virus

We have recently shown that the genome of equine arteritis virus (EAV) contains seven open reading frames (ORFs). We now present data on the structural proteins of EAV and the assignment of their respective genes. Virions are composed of a 14-kDa nucleocapsid protein (N) and three membrane proteins designated M, GS, and GL. M is an unglycosylated protein of 16 kDa, and GS and GL are N-glycosylated proteins of 25 and 30 to 42 kDa, respectively. The broad size distribution of GL results from heterogeneous N-acetyllactosamine addition since it is susceptible to digestion by endo-beta-galactosidase. Using monospecific antisera as well as an antivirion serum, and by expression of individual ORFs, the genes for the structural proteins were identified: ORF 7 codes for N, ORF 6 for M, ORF 5 for GL, and ORF 2 for GS. With the exception of GS, the proteins are about equally abundant in EAV virions, being present at a molar ratio of 3 (N):2 (M):3 (GL). The GS protein, which is expressed at a level similar to that of M in infected cells, is strikingly underrepresented in virus particles (1 to 2%). Our data justify a distinct taxonomic position for EAV, together with lactate dehydrogenase-elevating virus and simian hemorrhagic fever virus; although coronavirus- and toroviruslike in features of transcription and translation, the virion architecture of EAV is fundamentally different.

Intracellular RNAs of the feline infectious peritonitis coronavirus strain 79-1146.

In Felis catus whole foetus D cells infected with feline infectious peritonitis virus (FIPV), strain 79-1146, six virus-specific, poly(A)-containing RNA species of about 20, 9.6, 5.2, 3.8, 2.8 and 1.6 kb were found. By translation in vitro the 3.8 and 2.8 kb RNAs were shown to encode the 25K envelope protein and the 45K nucleocapsid protein, respectively. The partial map of the FIPV genome was compared with genomic maps of porcine, murine and avian coronaviruses. Differences in these maps suggest that transcription units have been lost or gained during coronavirus divergence.