The claimed invention relates to treatment of virus-related respiratory distress, particularly methods for treating such distress by administering a complement inhibitor. The types of virus-related respiratory distress that can be treated according to the invention include acute respiratory distress syndrome and related phenomena, and can be linked to infection by a coronavirus such as SARS-CoV-2. The invention includes administering complement inhibitor, which can be recombinant or purified C1 inhibitor, and administering complement inhibitor in combination with other therapeutics.

A fusion protein is provided which is based on a self-assembling gene-regulatory NSP10 protein and a protein or peptide capable of being fused to NSP10 without interfering with the assembly or aggregation of the resulting fusion protein. The disclosure also relates to any nanoparticle formed thereby whether complete or not, and methods for the use of the NSP10 fusion protein are also disclosed, including use as vaccines for any indication in humans or animals, therapeutic methods involving the use of the fusion proteins such as using the protein to targeted an antibody or receptor, such as for treating or diagnosing cancer, biosensors using the fusion protein, or the use of the fusion proteins in cell sorting or any imaging application.

A fusion protein is provided which is based on a self-assembling gene-regulatory NSP10 protein and a protein or peptide capable of being fused to NSP10 without interfering with the assembly or aggregation of the resulting fusion protein. The disclosure also relates to any nanoparticle formed thereby whether complete or not, and methods for the use of the NSP10 fusion protein are also disclosed, including use as vaccines for any indication in humans or animals, therapeutic methods involving the use of the fusion proteins such as using the protein to targeted an antibody or receptor, such as for treating or diagnosing cancer, biosensors using the fusion protein, or the use of the fusion proteins in cell sorting or any imaging application.

The invention is based on the finding that incubating a Cryptosporidium gp40 protein with an aziridine, significantly increases its immunogenicity. When used as a vaccine, this allows a reduction of the dose, which improves economic feasibility and safety. Consequently the aziridine-treated gp40 can now be used as a safe and effective subunit-vaccine for humans or non-human-animals against Cryptosporidiosis. Specifically for new-born ruminants a vaccination by way of colostral transfer was found to be very effective in reducing clinical signs of Cryptosporidiosis, especially diarrhoea.

The invention is based on the finding that incubating a Cryptosporidium gp40 protein with an aziridine, significantly increases its immunogenicity. When used as a vaccine, this allows a reduction of the dose, which improves economic feasibility and safety. Consequently the aziridine-treated gp40 can now be used as a safe and effective subunit-vaccine for humans or non-human-animals against Cryptosporidiosis. Specifically for new-born ruminants a vaccination by way of colostral transfer was found to be very effective in reducing clinical signs of Cryptosporidiosis, especially diarrhoea.

Described herein are compositions that comprise one or more Babesia microti antigens, one or more Babesia microti nucleic acid molecules, or one or more anti-Babesia microti antibodies and uses thereof in methods for the prophylaxis of babesiosis, the treatment of babesiosis and the monitoring of individuals undergoing prophylactic or therapeutic administration of the compositions of the invention.

The disclosure, in some aspects, provides a composition comprising labelled and/or tagged and/or bound amino acid sequences useful for the detection of Babesia species. Also disclosed are methods for the detection of infection by one or more Babesia species.

Disclosed herein are compositions and methods for detecting antibodies directed to epitopes of the metabolic enzymes, fructose-1,6-bisphosphate aldolase (A), α-enolase (E), and glyceraldehyde-3-phosphate dehydrogenase (G), that are shared between T. vaginalis and human AEG proteins.

Disclosed herein are compositions and methods for detecting antibodies directed to epitopes of the metabolic enzymes, fructose-1,6-bisphosphate aldolase (A), α-enolase (E), and glyceraldehyde-3-phosphate dehydrogenase (G), that are shared between T. vaginalis and human AEG proteins.

The present invention relates to a Babesia antigen comprising at least a portion of a gametocyte HAPLESS2/GCS1 (HAP2) protein, vectors and cells expressing such antigen, compositions and kits comprising such antigens, and methods of using such antigens to interfere with the Babesia transmission by competent ticks.