Delivery of Echinococcus granulosus antigen EG95 to mice and sheep using recombinant vaccinia virus.

The tapeworm Echinococcus granulosus is the causative agent of hydatid disease and affects sheep, cattle, dogs and humans worldwide. It has a two-stage life cycle existing as worms in the gut of infected dogs (definitive host) and as cysts in herbivores and humans (intermediate host). The disease is debilitating and can be life threatening where the cysts interfere with organ function. Interruption of the hydatid life cycle in the intermediate host by vaccination may be a way to control the disease, and a protective oncosphere antigen EG95 has been shown to protect animals against challenge with E. granulosus eggs. We explored the use of recombinant vaccinia virus as a delivery vehicle for EG95. Mice and sheep were immunized with the recombinant vector, and the result monitored at the circulating antibody level. In addition, sera from immunized mice were assayed for the ability to kill E. granulosus oncospheres in vitro. Mice immunized once intranasally developed effective oncosphere-killing antibody by day 42 post-infection. Antibody responses and oncosphere killing were correlated and were significantly enhanced by boosting mice with either EG95 protein or recombinant vector. Sheep antibody responses to the recombinant vector or to EG95 protein mirrored those in mice.

Hyperthermia by near infrared radiation induced immune cells activation and infiltration in breast tumor.

Breast cancer is the most common cancer that causes death in women. Conventional therapies, including surgery and chemotherapy, have different therapeutic effects and are commonly associated with risks and side effects. Near infrared radiation is a technique with few side effects that is used for local hyperthermia, typically as an adjuvant to other cancer therapies. The understanding of the use of near NIR as a monotherapy, and its effects on the immune cells activation and infiltration, are limited. In this study, we investigate the effects of HT treatment using NIR on tumor regression and on the immune cells and molecules in breast tumors. Results from this study demonstrated that local HT by NIR at 43 °C reduced tumor progression and significantly increased the median survival of tumor-bearing mice. Immunohistochemical analysis revealed a significant reduction in cells proliferation in treated tumor, which was accompanied by an abundance of heat shock protein 70 (Hsp70). Increased numbers of activated dendritic cells were observed in the draining lymph nodes of the mice, along with infiltration of T cells, NK cells and B cells into the tumor. In contrast, tumor-infiltrated regulatory T cells were largely diminished from the tumor. In addition, higher IFN-γ and IL-2 secretion was observed in tumor of treated mice. Overall, results from this present study extends the understanding of using local HT by NIR to stimulate a favourable immune response against breast cancer.

Deregulation of E-cadherin by human papillomavirus is not confined to high-risk, cancer-causing types.

BACKGROUND: E-cadherin is a tumour suppressor protein, which is normally expressed on keratinocytes and antigen-presenting Langerhans cells (LCs) in the epidermis. We have previously shown that E-cadherin is lost from tissues infected with the high-risk cancer-causing human papillomavirus (HPV) type 16. OBJECTIVES: To test if E-cadherin dysregulation is associated with the cancer risk of the infecting HPV and to establish if it is conserved among HPVs in the α, ß, γ and µ genera. METHODS: Forty-seven lesions infected with low- or high-risk HPV types spanning four HPV genera were stained for E-cadherin, P-cadherin and CD1a to detect LCs. RESULTS: Surface E-cadherin was reduced in tissues infected with members of the α4, α7 and α9 species and the γ and µ genera but was equivalent to normal epidermis in the ß only-infected lesions tested and patchy in α10-infected tissues. There was a direct relationship between atypical E-cadherin expression and a significant reduction in LCs. Expression of P-cadherin, a protein that is increased in the E-cadherin constitutive knockout mouse, was increased in lesions with reduced E-cadherin. CONCLUSIONS: These data show that E-cadherin dysregulation by HPV is widely conserved across the majority of HPV genera. E-cadherin expression was reduced or lost in epidermis irrespective of the cancer risk of the infecting HPV type or the ability of the virus to degrade retinoblastoma protein or p53. A correlation between dysregulated E-cadherin and reduced numbers of LCs supports viral regulation of surface E-cadherin contributing to viral evasion of the host immune system.

Suppression of the CD8 T cell response by human papillomavirus type 16 E7 occurs in Langerhans cell-depleted mice.

Human papillomavirus (HPV) is an epitheliotropic virus that is the primary causal agent for cervical cancer. Langerhans cells (LC) are skin antigen presenting cells that are reduced in number in HPV-infected skin. The aim of this study was to understand the immune-modulatory effects of HPV16 E7 on LC and on the CD8 T cell response to a skin-expressed antigen. To test this, HPV16 E7 was expressed in mouse skin keratinocytes with the model antigen ovalbumin (Ova). Similar to what is observed in HPV-infected human skin, LC numbers were significantly reduced in E7-expressing mouse skin. This shows that expression of the E7 protein alone is sufficient to mediate LC depletion. Expression of E7 with Ova in keratinocytes strongly suppressed the Ova-specific CD8+ T cell response in the skin draining lymph node. When tested in LC-ablated mice, the CD8 T cell response to skin-expressed Ova in control mice was not affected, nor was the T cell response to Ova restored in E7-expressing skin. These data indicate a role for E7 in regulation of LC homeostasis in the skin and in suppression of antigen specific CD8 T cell expansion, but suggest that these two effects occur independent of each other.

The purification and characterisation of cervine IgM and IgG.

A procedure is described for the isolation of immunoglobulin G (IgG) and immunoglobulin M (IgM) from hyperimmune cervine serum. Hybrids of red deer (Cervus elaphus) and wapiti (Cervus canadensis) were immunised with keyhole limpet hemocyanin (KLH). An immunoglobulin-containing fraction was precipitated from the hyperimmune serum using ammonium sulphate. The antigen-specific immunoglobulins were purified by KLH-conjugated sepharose affinity chromatography and further separated into IgM and IgG by gel-filtration chromatography. Purified immunoglobulin was analysed by polyacrylamide gel electrophoresis and isoelectric focusing. The molecular weights and isoelectric points of the composite chains of cervine IgG and IgM are presented.

The interaction between human papillomavirus type 16 E1 and E2 proteins is blocked by an antibody to the N-terminal region of E2.

Replication of papillomavirus DNA requires two virally encoded proteins, E1 and E2. We expressed human papillomavirus (HPV) type 16 E1 and E2 in bacteria and showed that purified full-length E2 protein interacted directly with E1, in the absence of HPV16 DNA. It was established that the first 142 amino acids of E1 were not required for binding as E2 protein was able to interact with E1 devoid of this region. The interaction of E2 with E1 could be blocked by a monoclonal antibody that bound E2 in the region of amino acids 18-41 of E2 whereas a monoclonal antibody reactive with a nearby part of the molecule (amino acids 2-17) only partially blocked this interaction. These results suggest that a region in the N-terminus of E2 around amino acids 18-41 is a site of interaction with the E1 protein.

Human T helper cell epitopes overlap B cell and putative cytotoxic T cell epitopes in the E2 protein of human papillomavirus type 16.

Activation of T helper cells is a prerequisite for the function of cytotoxic T lymphocytes (CTL) and the maturation of the B cell response. Because epitopes recognized by each of these cells may overlap, we scanned the E2 protein of human papillomavirus (HPV) type 16 to identify the T helper cell epitopes. Four major T helper cell epitopes (mapping between aa:s 11-25, 141-155, 191-205 & 231-245) and adjacent human B cell epitopes were found. The first peptide-defined epitope (RLNV) 11CQDKILTHYENDSTD25 overlapped five putative HLA-I (A1, A2, A0205, A3 & A11) binding motifs (CQDKILTHY, RLNVCQDKI, NVCQDKIL, RLNVCQDK & RLNVCQDK). This epitope is also part of an N-terminal alpha-helix which may form four HLA-II (DR2, DR4, DR7 & DR8) specific agretopes for structures recognizable by the T cell receptor (e.g. KILT). The second epitope 141EEASVTVVEGOVDYY155 (GLYY) overlapped the putative HLA-A1 & HLA-Bw37 binding motifs (VVEGQVDYY/QVDYYGLYY and EEASVTVV), and two HLA-II (DR1 & DR3) specific agretopes. The third and fourth epitopes were not associated with more than one putative CTL epitope each. Only the first epitope shared considerable aa-homology with corresponding regions of other genital HPV types.

The reactivity of monoclonal antibodies against orf virus with other parapoxviruses and the identification of a 39 kDa immunodominant protein.

A panel of 27 mouse monoclonal antibodies (Mabs) was raised against orf virus. Sixteen of these Mabs reacted with a protein with a molecular mass of 65 kDa, 8 reacted with a protein with a molecular mass of 39 kDa and three remain uncharacterised. Reactivity of the Mabs with a library of recombinant vaccinia viruses expressing various regions of the NZ-2 orf virus genome identified the approximate positions of the genes encoding these 2 immunodominant orf virus proteins. The gene encoding the 39 kDa protein was identified and sequenced. The protein was detected in an envelope fraction of orf virus and was shown to be homologous to the envelope protein encoded by the H3L gene of vaccinia virus. The 65 kDa protein has not been fully chracterised, but the gene encoding it has been localised to a 10 kbp region of the orf virus genome. The Mabs were used to discriminate 4 parapoxviruses derived from sheep, 2 from cattle and 1 each from a seal and squirrel. Eighteen Mabs reacted with all 4 sheep viruses, 19 Mabs reacted with both cattle viruses, 6 recognised seal parapoxvirus and 2 recognised the squirrel parapoxvirus. Only one of the 27 Mabs reacted with all 8 parapoxviruses suggesting it recognises a conserved epitope within the genus.