510 likes | 1.19k Views
Infectious Coryza: Characterization of Bacterium. Prof. Rob Bragg Dept of Microbial, Biochemical and Food Biotechnology University of the Free State Bloemfontein South Africa. Infectious Coryza. Caused by Avibacterium paragallinarum (previously Haemophilus paragallinarum ).
E N D
Infectious Coryza: Characterization of Bacterium Prof. Rob Bragg Dept of Microbial, Biochemical and Food Biotechnology University of the Free State Bloemfontein South Africa
Infectious Coryza • Caused by Avibacterium paragallinarum(previouslyHaemophilus paragallinarum). • Causes drop in egg production in layers which can be up to 40% • Normally bacterium requires NAD for growth. (NAD independent isolates have been found in South Africa since 1990 and recently in Mexico) • Different serogroups of the bacterium (A, B and C)
NAD Independent Isolates • First found in South Africa in 1990. • NAD independence is plasmid mediated. • NAD independent isolates appear to be less virulent that wild-type strains. (demonstrated with wild-type strains and lab produced strains). • Evidence of immune evasion by NAD independent isolates.
Isolation and Identification of the Bacterium • Selection of chickens for isolation. • Growth media and requirements. • Isolation procedures • Conventional identification • PCR • Other strains
Good selection Bad selection Selection of Chickens
Selection of Chickens • This is critical for isolation. • Select birds with only very mild clinical signs. • If birds with severe clinical signs are selected – A. paragallinarum cultures are often overgrown by opportunistic pathogens.
Growth Media and Requirements • Blood Tryptose Agar plates (BTA) give best results. • Bacteria require NAD for growth – this can be added to the medium or can be supplied through the use of a feeder culture of Staphylococcus aureus. • Look for typical satellitism. • Bacteria in micro-aerophilic – use candle jar for isolation at 37C.
Isolation Procedures • Disinfect head. • Make incision into the sinus cavity. • Collect sample with sterile swab. • Streak sample onto BTA plates. • Inoculate with S. aureus across the inoculum. • Incubate in a candle jar at 37C overnight. • Bacteria only survive for 2 to 3 days.
NAD Independent Isolates • Same isolation procedures. • Do not see typical satellitism. • Colonies will grow on plates without the feed culture on passage of the bacteria. • Colonies very similar to Ornithobacterium rhinotracheale.
Identification • For diagnostic purposes – isolation of bacterium showing satellitism from birds with clinical signs is sufficient. • Identification options include biochemical tests or PCR. • PCR tests are preferable and works well. Can be done directly on colonies – no need to first isolate the DNA.
1 2 3 lane 1:1742 lane 2 :46-C3 lane 3: Marker 500bp Fig.1: 1% Agarose gel of the PCR amplification of A. paragallinarum reference strains:1742, 46-C3. Amplification of the DNA resulted in a single band of 500bp.
Identification • There are other NAD requiring organisms which can be isolated from chickens – the so called “Haemophilus avium” strains. • Reclassified into Pasteurella avium, P. volantium and Pasteurella type A species. • Regarded as non-pathogenic. • Can be found quite frequently.
Identification • Biochemical tests are possible. • Must add sterile 0.5% NaCl, 1% sterile chicken serum and 0.025% NAD to basal media for carbohydrate fermentation tests.
Identification • NAD independent strain the same a NAD dependent A. paragallinarum. • PCR test detects both variations. • Biochemical tests are the same. • Serological tests are the same. • Only NAD dependence differs.
Serogroups and Serotyping • Plate agglutination test – three serotypes (A, B and C). • Serotyping scheme based on ability to agglutinate Gluteraldehyde fixed red blood cells. Three groups – found to be the same as serotypes found by plate agglutination test. • Three serogroups (A, B and C)
Serogroups • Serogroups currently sub-divided into 9 different serovars (A-1 to A-4; B-1; C-1 to C-4). • Serotyping to serogroup level is relatively straight forward – HA and HI tests. • Serotyping to serovar level is difficult (also with HA and HI – but can be subjective).
Serogroups • Evidence that different serovars are geographically isolated (C-3 in Southern Africa, C-4 in Australia). • Evidence of new serovars in other countries (South America). (Possibly two new serovar B strains, 1 new serovar C strain and one or two new serovar A strains).
Cross Protection • No cross protection across serogroups. • Good cross protection between serogroup A strains. • Good to poor cross protection with serogroup C strains. • Cross protection in serogroup C is highly strain dependent.
Cross Protection • Important to know serogroup and serovar of strains in a country for the selection of vaccine. • Serotyping to serovar level with HA and HI test is difficult. • Need alternative methods for serotyping – molecular based test would be preferable.
Molecular Serotyping • Develop a serotyping scheme based on haemagglutinin gene of A. paragallinarum(Current research project). • Haemagglutinin gene has been sequenced. • Ideal situation would be to have serovar specific PCR tests – specific primer sets for each serovar. • Alternative – PCR full gene and do RFLP analysis – get serovar specific fingerprint
bp A I II bp A III bp A IV V bp A VI 400 400 400 450 300 300 200 250 250 200 50 50 50 50 (1a) (1b) (1c) (1d) Restriction Digests Patterns
Enterobacterial Repetitive Intergenic Consensus-based PCR • ERIC-PCR. (Current research project). • Use long sequence primers and low annealing temperature. • Amplification of regions in bacterial genome. • Result in genetic fingerprint – different patterns found for different reference strains. • Need to investigate significance to cross protection.
Challenge Models • Most challenge models involve the intra-sinus injection of challenge bacteria into all birds in the group. • Record the number of birds showing clinical signs after 3 to 5 days. • Do bacterial re-isolation. • Calculate protection levels.
Problems with Challenge Model • Not a natural route of exposure. • Always see clinical signs in birds the first few days after injection of challenge bacteria, irrespective of the level of protection in the birds. • What do you do with these clinical signs? • Need for a new challenge model.
Challenge Model • A total of 10 chickens in adjoining cages per test. • Challenge one bird in the middle and allow for natural spread. • Recorded clinical signs daily. • Score clinical signs. • Construct a disease profile using mean daily disease scores.
Moderate Mild Severe Clinical scores
New Challenge Model • Allows for easy comparison between different vaccines, virulence of strains, efficacy of treatments etc. • Allows for statistical analysis of the difference between the disease levels in vaccinated and unvaccinated chickens.
Virulence of Different Isolates • Virulence of the four different South African serovars was tested using the challenge model. • Unvaccinated commercial layers were used. • Groups of chickens were challenged with each of the different serovars.
Virulence of SA Isolates • It was found that serovar C-3 is highly virulent. • Serovar C-2 is less virulent than serovar C-3, but is substantially more virulent than serovars A-1 or B-1.
Conclusions • Knowing the serogroup and serovars of the isolates which occur in a country is important. • Developed a new challenge model which allows for statistical comparisons. • Serovar C-3 has been shown to be highly virulent.