Susceptibility of Brugia malayi to oxidative and nitrosative stress

Thomas, Gladys Ruth

January 1997

No description available.

572

Filariasis; Parasitology

The immune response and microfilaria in cats infected with B. pahangi

Malecela, Mwelecele Ntuli Nyagwa

January 1995

No description available.

610

Lymphatic filariasis

Studies on the cuticlin homologues of Brugia species

Lewis, Emma Katherine

January 1997

No description available.

636.089

Parasitology; Filariasis; Immunology

Modelling lymphatic filariasis transmission and control

Subramanian Swaminathan,

January 1900

Thesis Erasmus University Rotterdam. / ook verschenen in gedrukte versie. With bibliogr., with a summary in Dutch.

Innate immune responses of the mouse and jird to filarial parasites and emulsan : a putative adjuvant /

Panilaitis, Bruce J. B.

January 2001

Thesis (Ph.D.)--Tufts University, 2001. / Adviser: Juliet A. Fuhrman. Submitted to the Dept. of Biology. Includes bibliographical references. Access restricted to members of the Tufts University community. Also available via the World Wide Web;

Immune system. Cytokines. Filariasis.

Galectins and lymphatic filariasis exploring the role of Brugia malayi galectins in parasite persistence /

Mongare, Margaret Mumbi.

January 2010

Honors Project--Smith College, Northampton, Mass., 2010. / Includes bibliographical references (p. 66-70).

Correlation between the antibody response and resistance to Loa loa infection in Gabon

Medzegue, Jean Paul Akue

January 1995

No description available.

610

A comparative analysis of novel filarial retinol binding proteins

Nirmalan, Niroshini Jacintha

January 1999

No description available.

572.8

A study of heat shock protein 90 from the filarial nematode, Brugia pahangi

Cockroft, Alexis Cunliffe

January 1999

No description available.

636.089

Experimental DNA vaccine against filariasis

Luo, Honglin

January 2011

Filarial infections are major causes of morbidity in the tropics and sub-tropics, afflicting over 150 million people in about 80 countries, causing debilitating symptoms such as elephantiasis (lymphatic filariasis), dermatitis and blindness (onchocerciasis or river blindness). Current control of lymphatic filariais relies on mass drug treatment with diethylcarbamazine（DEC) and albendazole while ivermectin is used against onchocerciasis. Repeat treatment is frequently required and this highlights the possibility of development of drug resistance. In addition, risk of adverse reactions following treatment excludes some patients from control programmes. Such circumstances urgently call for the development of complementary control measures such as vaccination. DNA vaccines are novel type of subunit vaccine in which production of the immunizing antigen is induced in host cells after introduction of a plasmid or recombinant viral vector containing the gene that encodes the antigen. DNA vaccines are relatively simple and cheap to produce and their stability makes them particularly suitable for use in remote regions that lack the cold-chain storage facilities required of conventional vaccines. Filarial nematodes are tissue-dwelling parasites that survive for many years in immunocompetent hosts. It is proposed that this longevity is, in part, due to the capacity of the parasites to modulate potentially lethal Th2 responses of their hosts. Consequently, the efficiency of a filarial vaccine may depend on how well it circumvents filarial-driven immunosuppression. To test this hypothesis, a series of DNA vaccines were developed and tested in the Litomosoides sigmodontis-mouse model of filarial infections. The L. sigmodontis Abundant Larval Transcript-1 (Ls-ALT) and Cysteine Protease Inhibitor (Ls-CPI) genes were cloned and genetically engineered to ablate their immunomodulatory properties by deleting the acid domain and by site mutation, respectively. In addition, the L. sigmodontis Venom Allergen Homologue (Ls-VAH) and Thioredoxin Peroxidase (Ls-TPX) were used in their native forms as vaccine targets. To improve immunisation and antigen processing by the host, these parasite genes were fused to a DNA sequence encoding an antibody that specifically binds dendritic cell surface protein (αDEC205 single chain Fv). DNA plasmids carrying mutated forms and/or anti-DEC205 were then co-administered with plasmids encoding the Th2 promoting cytokine IL4, and/or antigen-presenting cell activating MIP1α and Flt3L. Mice immunized with mutated forms (ADDALT and CPImu) of parasite antigens produced more specific antibody post-challenge and showed strongly increased lymphocyte stimulation above controls immunized with the native form. The immune response was further enhanced when plasmids encoding IL4, MIP1α, Flt3L and anti-DEC-205 forms were co-administered, resulting in production of a Th2/IgG1 phenotype. Significant reduction of worm burden (82.3%) was achieved by a cocktail vaccination which combined the ADDALT and CPImu candidates. Mice immunized with Ls-VAH and Ls-TPX DNA carried by αDEC205 elicited Th2-biased responses with up-regulated IgG1 and IgE antibodies as well as enhanced IL5, IL4, and IL13 and diminished IFNγ production compared to controls. The immune responses were further driven towards the Th2/IgG1 phenotype when Ls-VAH and Ls-TPX were injected with plasmids encoding ADDALT and CPImu and with the adjuvants Flt3L, MIP1α and IL4. This resulted in reduction in worm burden of 55.7% (cocktail vaccine containing Ls-VAH) and 41.6% (cocktail vaccine containing Ls-TPX) respectively in vaccinated animals.

616.9883