William Horner Andrews (1887-1953)- first professor of physiology at Onderstepoort.

W H Andrews qualified as a veterinarian in London in 1908 and was recruited soon after, in 1909, by Sir Arnold Theiler to join the staff of the newly established veterinary laboratory at Onderstepoort. After initial studies on the treatment of trypanosomosis and on snake venoms he was deployed by Theiler in 1911 to start research on lamsiekte (botulism)at a field station on the farm Kaffraria near Christiana, where he met and married his wife Doris. After a stint as Captain in the SA Veterinary Corps during World War I he succeeded D T Mitchell as head of the Allerton Laboratory in 1918, where he excelled in research on toxic plants, inter alia identifying Matricaria nigellaefolia as the cause of staggers in cattle. When the Faculty of Veterinary Science was established in 1920 he was appointed as the first Professor of Physiology. After the graduation of the first class in 1924, and due to health problems, he returned to the UK, first to the Royal Veterinary College and then to the Weybridge Veterinary Laboratories of which he became Director in 1927. After his retirement in 1947 he returned to South Africa as a guest worker at Onderstepoort where he again became involved in teaching physiology when Prof. Quin unexpectedly died in 1950. Andrews died in Pretoria in 1953 and was buried in the Rebecca Street Cemetery.

History of bluetongue research at Onderstepoort.

Research on this economically important disease of ruminants, especially sheep, which had been named bluetongue by farmers in the 19th century, has been part and parcel of the activities at Onderstepoort ever since its establishment in 1908 and therefore covers a full century of the OVI's existence. In view of Onderstepoort's centenary celebration a brief overview of this research is given in terms of the historic milestones which influenced and guided global research on this and other viral diseases of animals.

Phylogenetic analyses of genes from South African LPAI viruses isolated in 2004 from wild aquatic birds suggests introduction by Eurasian migrants.

In 2004, South Africa experienced its first recorded outbreak of a highly pathogenic notifiable avian influenza (HPNAI) viral strain of the H5N2 subtype in ostriches in the Eastern Cape province. The traditional ostrich-farming areas in the Western Cape province report almost yearly outbreaks of low pathogenicity avian influenza (LPAI) in ostriches, which is attributed to introduction by wild birds and certain climatic patterns. During the winter of 2004, LPAI H3N8, H4N8, H5N2 and H5N1 avian influenza viruses were isolated from wild aquatic birds. All eight genes of the H3N8, H4N8 and H5N1 viruses were analysed. The results show that the H5N1 virus does not belong to the HPAI Z/Z+N genotype currently circulating in Asia, but that the most recent common ancestors are Russian H5N2 and H5N3 viruses. The N1 gene lacks the stalk deletion associated with virulence. Internal genes probably originate from a pool containing Chinese, Middle Eastern and Italian viruses. The South African H3N8 and H4N8 viruses appear to have derived their genes from an ecosystem where Asian H5N1, H6N9 and H9N2, Russian H4, and Danish H3N8 viruses have been circulating since 1997. All three viruses share recent nucleoprotein common ancestors with the German and Dutch HPNAI H7N7 viruses from 2003. The diverse pool of genes from which local viruses are derived suggests that reassortment occurred at the Siberian breeding grounds where migratory paths cross, or within the South African ecosystem. This data highlights the importance of surveillance in aquatic migratory birds, particularly members of the Charadriidae, for their potential roles in the introduction of avian diseases to South African poultry and especially ostriches in the case of avian influenza.

Regulation of MHC class II antigen presentation by sorting of recycling HLA-DM/DO and class II within the multivesicular body.

MHC class II molecules bind antigenic peptides in the late endosomal/lysosomal MHC class II compartments (MIIC) before cell surface presentation. The class II modulatory molecules HLA-DM and HLA-DO mainly localize to the MIICs. Here we show that DM/DO complexes continuously recycle between the plasma membrane and the lysosomal MIICs. Like DMbeta and the class II-associated invariant chain, the DObeta cytoplasmic tail contains potential lysosomal targeting signals. The DObeta signals, however, are not essential for internalization of the DM/DO complex from the plasma membrane or targeting to the MIICs. Instead, the DObeta tail determines the distribution of both DM/DO and class II within the multivesicular MIIC by preferentially localizing them to the limiting membrane and, in lesser amounts, to the internal membranes. This distribution augments the efficiency of class II antigenic peptide loading by affecting the efficacy of lateral interaction between DM/DO and class II molecules. Sorting of DM/DO and class II molecules to specific localizations within the MIIC represents a novel way of regulating MHC class II Ag presentation.

The effect of a natural maedi-visna virus infection on the productivity of South African sheep.

A cohort study was conducted in order to measure the effect of the chronic indurative lymphocytic mastitis caused by the South African strain of maedi visna virus (MVV) on the pre-weaning growth of lambs born either of naturally infected or uninfected ewes kept under similar conditions. Fifty naturally infected ewes as well as another 40 from a maedi-visna-free source to be used as control animals, were purchased and kept in separate flocks which were managed in a similar way. All the ewes were of the same breed and 3-4 years old. During the adaptation period, and through the mating, pregnancy and lactation periods they were periodically monitored for the presence of MVV serum antibodies. The lambs were weighed at birth and thereafter every 2 weeks until the age of 90 days, when they were weaned. The ewes were then slaughtered, and their udders examined histologically and the number of lymphocytic follicles were counted and assessed. Although the calculated values indicated a correlation between the number of follicles in the udder and the reduction in the growth rate of the lambs, this was not statistically significant. Similarly, despite higher counts of lymphoid follicles in the udders of sero-positive ewes as compared to those that were sero-negative and the lower ewe productivity indexes in infected ewes, no statistically significant differences were found in the indexes of ewes in different follicle categories.

Newcastle disease and avian influenza A virus in wild waterfowl in South Africa.

In an intensive ostrich farming area in South Africa with a history of ostrich influenza outbreaks, we conducted a survey of avian influenza virus (AIV) and Newcastle disease virus (NDV) in wild aquatic birds. During late autumn and winter 1998, the time of year when outbreaks in ostriches typically start to occur, 262 aquatic birds comprising 14 species were sampled and tested for both virus infections. From eight samples, AIV, serotype H10N9, could be isolated. All isolates were apathogenic as determined by the intravenous pathogenicity index (0.00). Conversely, none of 33 sera of these wild birds showed antibodies against H10. However, one bird was found serologically positive for H6 AIV. This AIV serotype was later isolated from ostriches during an avian influenza outbreak in this area. No NDV was isolated although 34 of 46 serum samples contained NDV-specific antibodies. This is the first H10N9 isolate to be reported from Africa. In addition, our data support the notion that wild aquatic birds may function as a reservoir for AIV and NDV in South Africa.

Ostrich diseases.

Scientific knowledge of ostrich diseases is incomplete and very fragmented, with specific details on technical aspects of diagnostic and/or screening tests completely absent in most cases. Salmonella Typhimurium is common in multispecies collections and causes mortality in chicks younger than three months on commercial farms, but is rarely found in chicks older than six months, or slaughter birds of twelve to fourteen months in southern Africa. Campylobacter jejuni and Chlamydia psittaci are occasionally reported, mainly in young ostriches, but both remain a diagnostic challenge. Crimean-Congo haemorrhagic fever is transmitted to domestic animals including ostriches, principally by ticks of the genus Hyalomma. In the ostrich, the disease causes no clinical symptoms during a viraemia of approximately four days. Spongiform encephalopathy has not been reliably reported in ostriches, while anthrax has occurred rarely in modern times but was reportedly an important cause of death approximately 100 years ago in South Africa. Salmonella Gallinarum and S. Pullorum are unknown in ostriches. Pasteurella multocida occurs but is easily contained with antibiotics. Mycoplasma spp. are regularly found in an upper respiratory disease syndrome complicated by opportunistic bacterial pathogens. Ostriches of all ages are susceptible to challenge by velogenic Newcastle disease virus (NDV), but standard inactivated La Sota poultry vaccines can stimulate protective immunity lasting over six months. The viraemic period in vaccinated slaughter ostriches is between nine and eleven days and there are no indications of a carrier state or presence of the virus in the meat or any other tissues after this period, with peak immunoglobulin G response reached on day fourteen post infection. Haemagglutination inhibition tests are significantly less sensitive and less specific than enzyme-linked immunosorbent assays. Cloacal and choanal swabs used for direct virological screening in clinically affected cases (field and experimental) could not detect NDV. All avian influenza isolates reported from ostriches have been non-pathogenic to poultry, even the H5 and H7 subtypes. Some of the latter have been associated with mortality of ostrich chicks in localised outbreaks during periods of inclement weather and with significant wild bird (waterfowl) contact. Borna disease causes a nervous syndrome in ostrich chicks, but to date, has only been reported in Israel. Eastern and Western equine encephalomyelitides cause fatal disease in ostriches and other ratites, with mortality ranging from less than 20% to over 80% in affected flocks. These diseases are present in North, Central and South America where the associated ornithophilic mosquito vectors occur. Equine and human vaccines are apparently safe and efficacious in ratites. Wesselsbron disease, infectious bursal disease (type 2), adenovirus and coronavirus infections have been reported from ostriches but the significance of these diseases is unclear. Due to the paucity of data regarding ostrich diseases and the unvalidated state of most poultry tests in this unique group of birds, strict observation of a pre-slaughter quarantine of thirty days is strongly advised, whilst live exports and fertile eggs should be screened through the additional use of sentinel chickens and/or young ostriches.

Enterocin 012, a bacteriocin produced by Enterococcus gallinarum isolated from the intestinal tract of ostrich.

Enterococcus gallinarum strain 012, isolated from the duodenum of ostrich, produced enterocin 012 which is active against Ent. faecalis, Lactobacillus acidophilus, Lact. sake, Listeria innocua, Propionibacterium acidipropionici, Propionibacterium sp., Clostridium perfringens, Pseudomonas aeruginosa and Salmonella typhimurium. One of the four pathogenic strains of Escherichia coli isolated from the intestinal tract of ostrich was inhibited by enterocin 012. No antimicrobial activity was recorded against Bacillus cereus, Cl. sporogenes, Cl. tyrobutyricum, Leuconostoc cremoris, Pediococcus pentosaceus, Staphylococcus carnosus and Streptococcus thermophilus. Enterocin 012 was resistant to treatment with lysozyme, catalase, lipase and papain, but sensitive to Proteinase K, alpha-chymotrypsin, trypsin and pepsin. Treatment of enterocin 012 with gastric juice from the duodenum resulted in a 50% loss of antibacterial activity. Half of the activity was lost when incubated at 80 degrees C for 30 min, or when kept overnight at a pH of 1.0-5.0 and pH 11.0 and 12.0, respectively. Enterocin 012 production started in mid-logarithmic growth and reached a maximum of 800 AU ml-1, but increased further to 1600 AU ml-1 in the stationary growth phase. The peptide is approximately 3.4 kDa in size, as determined after partial purification with Amberlite XAD-1180 and ammonium sulphate precipitation, followed by tricine-sodium dodecyl sulphate-polyacrylamide gel electrophoresis. The mechanism of antimicrobial activity against Lact. sake LMG 13558 is bactericidal and caused cell lysis of active growing cells.

Recycling MHC class I molecules and endosomal peptide loading.

MHC class I molecules usually present peptides derived from endogenous antigens that are bound in the endoplasmic reticulum. Loading of exogenous antigens on class I molecules, e.g., in cross-priming, sometimes occurs, but the intracellular location where interaction between the antigenic fragment and class I takes place is unclear. Here we show that measles virus F protein can be presented by class I in transporters associated with antigen processing-independent, NH(4)Cl-sensitive manner, suggesting that class I molecules are able to interact and bind antigen in acidic compartments, like class II molecules. Studies on intracellular transport of green fluorescent protein-tagged class I molecules in living cells confirmed that a small fraction of class I molecules indeed enters classical MHC class II compartments (MIICs) and is transported in MIICs back to the plasma membrane. Fractionation studies show that class I complexes in MIICs contain peptides. The pH in MIIC (around 5.0) is such that efficient peptide exchange can occur. We thus present evidence for a pathway for class I loading that is shared with class II molecules.

Experimental infection of vaccinated slaughter ostriches in a natural, open-air feedlot facility with virulent Newcastle disease virus.

The presence of virulent Newcastle disease virus (NDV) since the 1993-94 epidemic in southern Africa holds major implications for the export of ostrich products from this region. A challenge experiment with this field strain was conducted in open-air feedlot facilities under strict biosecurity measures. The experiment was designed to follow vaccination and preslaughter quarantine regulations currently enforced in South African export ostrich facilities in order to determine the viremia period and immune response under these specific circumstances. One hundred forty-three slaughter ostriches were allocated into three test groups, according to the time period between pretrial vaccination and challenge (1-2 mo, 2-4 mo, 4-6 mo), and an unchallenged control group. All birds in the test groups were challenged by oral, tracheal, and ocular routes with a field isolate of NDV. They were slaughtered over the next 4 wk on nine separate occasions and bled on 12 occasions. Virus isolation was attempted from seven sets of pooled samples from each bird to determine the viremia period and the serum antibody concentrations were measured by hemagglutination inhibition (HI) and enzyme-linked immunosorbent assay (ELISA) methods to establish an immune response curve. NDV could be back-isolated only up to day 9 postinfection and from only six ostriches with poor immune response titers and corresponding to a rise in antibody levels above an indirect ELISA optical density reading of 0.33. Virus could be recovered only from brain and respiratory tract tissue. The HI test was less sensitive than the ELISA. Immune response curves did not differ significantly between the groups and peaked on day 14 post-infection. From these data, ELISA titers would appear to be a good indicator of the probability that an ostrich will be clinically infected after velogenic NDV challenge. These results also suggest that the current vaccination schedule enforced by the South African Veterinary Authorities results in protective immunity in up to 95% of slaughter ostriches from export approved facilities. The standard 30-day preslaughter quarantine period introduced as part of Crimean-Congo hemorrhagic fever virus control measures also appears sufficient to encompass the determined NDV viremia period of 9-11 days in slaughter ostriches.

Lectin-induced retardation of subcellular organelles during preparative density gradient electrophoresis: selective purification of plasma membranes.

Plasma membranes (PM) are difficult to separate by conventional means from other cellular compartments. Using a density gradient electrophoresis (DGE) apparatus (7 cm, x 2.2 cm), mammalian subcellular organelles were separated from a total postnuclear supernatant. The sialic acid-binding lectin wheat germ agglutinin (WGA) permitted 1.5-fold electrophoretic retardation of plasma membranes lagging far behind endoplasmic reticulum, endosomes, Golgi and lysosomes (in order of increasing electrophoretic mobility). Mobilities of the latter organelles were not affected by wheat germ agglutinin. The retarded plasma membrane was monitored by surface iodination, the presence of Ca(++)- and Na+/K(+)-ATPases and by the presence of clathrin-coated pits using Western immunoblotting. In the presence of WGA two clathrin-containing compartments were detected; in the absence of WGA three clathrin populations were seen in the electropherogram: clathrin-coated vesicles, clathrin-coated pits (on the PM) and clathrin-coated structures on the trans-Golgi network (TGN). Both in the presence and absence of WGA, plasma membrane domains of different electrophoretic mobilities were detected.

Electromigration for separations of protein complexes.

This paper describes electromigration of complexes, consisting of two or more proteins and non-covalently associated peptides. Relatively small complexes (Mr < 1000000) can be resolved in sieving matrices. Large complexes are separated in free liquid systems. Examples of separation are given using native gels, denaturing gels and special formats thereof: blue native PAGE and gels incorporating a transversal temperature gradient. Both preparative and analytical applications are discussed as well as separations leading to mechanistic models of protein interaction. Carrier-free electrophoresis is represented by capillary zone electrophoresis, free-flow electrophoresis and density gradient electrophoresis. Emphasis is put on the free liquid separation of clathrin-coated vesicles and proteasomes.

Experimental infection of ostriches with Crimean-Congo haemorrhagic fever virus.

Following the occurrence of an outbreak of Crimean-Congo haemorrhagic fever (CCHF) among workers at an ostrich abattoir in South Africa in 1996, 9 susceptible young ostriches were infected subcutaneously with the virus in order to study the nature of the infection which they undergo. The ostriches developed viraemia which was demonstrable on days 1-4 following infection, with a maximum intensity of 4.0 log10 mouse intracerebral LD50/ml being recorded on day 2 in 1 of the birds. Virus was detectable in visceral organs such as spleen, liver and kidney up to day 5 post-inoculation, 1 day after it could no longer be found in blood. No infective virus was detected in samples of muscle, but viral nucleic acid was detected by reverse transcription-polymerase chain reaction in muscle from a bird sacrificed on day 3 following infection. It was concluded that the occurrence of infection in ostriches at abattoirs could be prevented by keeping the birds free of ticks for 14 days before slaughter.

High-resolution density gradient electrophoresis of subcellular organelles and proteins under nondenaturing conditions.

We have developed a density gradient electrophoresis device (DGE) and used it for the preparative separation of various endocytic organelles that are hard to separate by other means. Our separation by DGE of late endosomal vesicles, recycling vesicles, early endosomes and plasma membranes is unmatched. Using the same DGE device, we performed preparative high-resolution rate zonal separation of proteins using amphoteric buffers as originally described by Bier (Electrophoresis 1993, 14, 1011-1018). Isoforms of bovine beta-lactoglobulin, human apo-transferrin, and bovine erythrocyte carbonic anhydrase that have isoelectric points within 0.8 pH units were readily separated even in the absence of nonionic detergents. The DGE apparatus is inexpensive and has unique separation abilities for vesicles and proteins.

The role of veterinary research laboratories in the provision of veterinary services.

Veterinary research laboratories play an essential role in the provision of veterinary services in most countries. These laboratories are the source of new knowledge, innovative ideas and improved technology for the surveillance, prevention and control of animal diseases. In addition, many laboratories provide diagnostic and other services. To ensure the optimal integration of various veterinary activities, administrators must understand the functions and constraints of research laboratories. Therefore, a brief discussion is presented of the following: organisational structures methods for developing research programmes outputs of research scientists and how these are measured the management of quality assurance funding of research. Optimal collaboration can only be attained by understanding the environment in which a research scientist functions and the motivational issues at stake.

High performance density gradient electrophoresis of subcellular organelles, protein complexes and proteins.

A density gradient electrophoresis (DGE) apparatus (2.2 x, 14 cm) was constructed for the rapid separation of milligram quantities of proteins. By using binary buffers according to Bier (Electrophoresis 1993, 14, 1011-1018) proteins were rate-zonally separated in less than 60 min. Acidic proteins were separated in a pH 8.6, 56 microS/cm buffer, and basic proteins in a pH 5.4, 76 microS/cm buffer. Thus the A (pI 5.15) and B (pI 5.30) forms of beta-lactoglobulin as well as the sialylated glycoforms of apotransferrin were well separated at pH 8.6. The isoforms of myoglobin (pI 6.9 and 7.35, respectively), RNAse A (pI 9.45) and cytochrome c (pI 10.0) and lysozyme (pI 11) were separated at pH 5.4 within 80 min. On a 7 cm DGE column, subcellular organelles derived from HeLa cells were separated in standard electrophoresis buffer (655 microS/cm) for 90 min at 10 mA. Using a new low conductivity buffer (193 microS/cm) 20 min was sufficient to separate late endosomes, lysosomes, endoplasmic reticulum, early endosomes, plasma membrane, clathrin-coated pits, proteasomes, and clathrin-coated vesicles within a single run directly from a postnuclear supernatant.

Removal and degradation of the free MHC class II beta chain in the endoplasmic reticulum requires proteasomes and is accelerated by BFA.

We have studied the degradation of the free major histocompatibility complex (MHC) class II beta subunit in the ER. Domain swapping experiments demonstrate that both the intra- and extracellular domain determine the rate of degradation. Recently, it has been shown that some ER-retained proteins are exported from the ER by the translocon followed by deglycosylation and degradation in the cytosol by proteasomes. Degradation of the beta chain follows a different route. The proteasome is involved but inhibition of the proteasome by lactacystin does not result in deglycosylation and export to the cytosol. Instead, the beta chain is retained in the ER implying that extraction of the beta chain from the ER membrane requires proteasome activity. Surprisingly, brefeldin A accelerates the degradation of the beta chain by the proteasome. This suggests that various processes outside the ER are involved in ER-degradation. The ER is the site from where misfolded class II beta chains enter a proteasome-dependent degradation pathway.