African Trypanosomiasis

Trypanosoma b. rhodesiense in Homo sapiens - EATRO, Uganda	Hematocrit Centrifuge Technique, trypanosomiasis survey (Woo, 1971)	Human trypanosomiasis (gambian) - EATRO, Uganda (Woo, 1970b)

(2) Woo, P.T.K. 1970b. The haematocrit centrifuge technique for the diagnosis of African trypanosomiasis. Acta Tropica 27: 384-386.
One of his studies on human trypanosomiasis in Africa was the adaptation and use of the Hematocrit Centrifuge Technique (HCT; Woo, 1969) in hospitals to detect trypanosomes in the blood and cerebral spinal fluid of patients with trypanosomiasis (Woo, 1970b). He also adapted the HCT for use under field conditions (Woo, 1971) and used it in a survey on human trypanosomiasis (Onyango & Woo, 1971); this rapid and simple-to-use technique " . . . is still in use in many HAT [Human African Trypanosomiasis] control programs" (Chappuis et al., 2005) and for Chagas' disease caused by T. cruzi ( Moretti et al. 2005). Since it is a sensitive technique (Woo & Rogers, 1974) it is also " . . . widely used for the diagnosis of animal trypanosomiasis" (Schlater & Van Den Bossche, 2004), and as a field technique (~100 T. evansi per mL of blood; its sensitivity is increased by examining more tubes - AUSVETPLAN, 2006). The technique is also used to determine the effectiveness of chemotherapy against trypanosomiasis caused by T. congolense and T. vivax (e.g. Sekoni & Rekwot 2003), and has been modified to detect Cryptobia and cryptobiosis in fish (Woo, 2003).

HCT is sometimes called the "Woo test" (Chappuis et al., 2005), or "Woo technique" (Quispe et al., 2003) , or "Woo method" (Uilenberg, 1998; Schlater & Van Den Bossche, 2004).
Chappuis F et al. (2005) Options for field diagnosis of human African trypanosomiasis. Clinical Micrbiol. Reviews 18: 133-146.
Quispe AP et al. (2003) Prevalencia de Trypanosoma vivax en bovinos de cuatro distritos de la provincia de Coronel Portillo, Ucayali. Rev investig. vet. Peru 14: 161-165.
Uilenberg G (1998) Diagnosis - Chapter 3. In: A field guide for the diagnosis, treatment and prevention of African animal trypanosomosis, Food and Agriculture Organization, UN, 158 pages.
Schlater J & Van Den Bossche P (2004) Trypanosomosis - Chapter 2.3.15. In: Manual of Diagnostic Tests and Vaccines for Terrestrial Animals, 5th edition (eds. Cullen CA & Pearson JE), World Organization for Animal Health, OIE, 1178 pages.

Salmonid Cryptobiosis

Cryptobia (T.) salmositica with a red blood cell from an anaemic fish	Bilateral exophthalmia in acute salmonid cryptobiosis (Woo, 2003)	General edema and abdominal distension with ascites (Woo, 1979)

(4) Woo, P.T.K. & Li, S. 1990. In vitro attenuation of Cryptobia salmositica and its use as a live vaccine against cryptobiosis in Oncorhynchus mykiss. Journal of Parasitology 76: 752-755.
This is the first vaccine against a fish parasite - the live vaccine injected intraperitoneally into fish circulates in the blood of rainbow trout for at least 6 months, does not cause disease but protects fish from cryptobiosis (Woo & Li, 1990). A single dose of the vaccine protects rainbow trout (adaptive immunity) for at least 2 years, and protection is through the production of complement fixing antibodies, enhanced phagocytic activities by marcophages, and cell-mediated cytotoxicity (both antibody-independent and antibody-dependent) (Li & Woo, 1995). Since this vaccine has no detectable bioenergetic costs to juvenile fish and does not affect growth (Beamish et al., 1996) it is used routinely to study the acquisition and mechanism of protective immunity in salmonids (Woo, 2001). The vaccine has remained attenuated (does not secrete metalloprotease, the main virulent factor in cryptobiosis) and it protects both juvenile and adult salmonids from cryptobiosis (Woo, 2003). The two strains (vaccine and pathogen) have been used to detect Atlantic salmon that have a more responsive immune system (Chin et al., 2004) - aims of the study are to identify genes in salmon related to a rapid response to pathogens, and to emphasize this trait in breeding programs. This is a proactive strategy against pathogenic organisms.

(5) Forward, G.M., Ferguson, M.M. & Woo, P.T.K. 1995. Susceptibility of brook charr, Salvelinus fontinalis to the pathogenic haemoflagellate, Cryptobia salmositica, and the inheritance of innate resistance by progenies of resistant fish. Parasitology 111:337-345.
Using a very host specific hemoflagellate (Cryptobia catostomi) from white suckers, Bower & Woo (1977) showed the Alternative Pathway of Complement Activation (APCA) operates in the blood of fish. They described an in vitro technique to determine in vivo susceptibility of fish to parasites. APCA is innate or natural immunity and it also operates in other teleosts; for example, against Cryptobia salmositica ( Wehnert & Woo, 1980), a pathogenic hemoflagellate in salmonids. In salmonid cryptobiosis (Woo 1979) some brook charrs are innately resistant to C. salmositica, and this resistance to infection is inherited and controlled by a dominant Mendelian locus. Cryptobia-susceptible charrs are homozygous recessive while Cryptoba-resistant fish are either homozygous dominant or heterzygous; hence it is now possible to breed C. salmositica-resistant charrs (Forward et al., 1995) where the parasite is ruptured via APCA (Forward & Woo, 1996). The adaptive or acquired immune (both humoral and cell-mediated) responses to various antigenic stimulations (including to a commercial Aeromonas vaccine) are very similar in both Cryptobia-resistant and Cryptobia-susceptible charrs (Ardelli & Woo 1995). APCA is an important protective mechanism in fish against pathogenic protozoa (Woo 2007) and attempts are being made to exploit this form of innate immunity.

(6) Tan, C.W., Jesudhasan, P. & Woo, P.T.K. 2008. Towards a metalloprotease-DNA vaccine against piscine cryptobiosis caused by Cryptobia salmositica. Parasitology Research 102: 265-275.
The pathogenic strain of Cryptobia salmositica has a cysteine and a metallo- protease (Zuo & Woo 1997a). The cysteine protease (49, 60, 66 and 97 kDa) is a metabolic enzyme while the metalloprotease (200 kDa) is the disease-causing factor in cryptobiosis (Zuo & Woo 1997a). The purified metalloprotease digests collagens, laminin and red cell membrane (Zuo & Woo 1997b; Zuo & Woo 2000). A murine monoclonal antibody (mAb 001; Feng & Woo 1996) against a 200 kDa glycoprotein epitope (Feng & Woo 1998a; 1998b) is protective (both prophylactic and therapeutic) when injected into fish (Feng and Woo 1997). Mab001 does not fix complement to rupture the pathogen but agglutinates the parasite (Feng & Woo 1996), inhibits parasite multiplication and respiration (Hontzeas et al. 2001) and neutralizes the enzymatic activities of the metalloprotease (Zuo et al. 1997). The cysteine (Jesudhasan et al 2007a) and metalloprotease (Jesudhasan et al. 2007b) genes have been sequenced and recombinant DNA vaccines produced by inserting the protease genes into plasmid vectors (Tan et al. 2008). The metalloprotease-DNA (MP-DNA) vaccine (secretes metalloprotease) after inoculation into fish (Oncorhynchus mykiss and Salmo salar) causes an anemia but the PCVs of fish start to recover as antibodies are produced to neutralize the secreted metalloprotease. The antibodies also agglutinate live Cryptobia; however, fish inoculated with cysteine-DNA plasmids (or control fish with plasmids alone) are not anemic and they do not have agglutinating antibodies against Cryptobia. As expected MP-DNA-vaccinated fish are not protected from infection after parasite challenge, but they have lower parasitemia, delay peak parasitemia, and faster recovery compared with control fish. However, fish vaccinated with attenuated strain (Woo & Li, 1990) are protected and this confirms that the two vaccines (attenuated and the metalloprotease DNA) operate through different mechanisms. In a recent review on the use of DNA vaccines in aquatic organisms Kurath (2008) confirmed that this is the "... first published demonstration of protective effects of a fish parasite DNA vaccine in fish".