Tiger prowling: Distribution modelling for northward-expanding Aedes albopictus (Diptera: Culicidae) in Japan.

The Asian tiger mosquito, Aedes albopictus, is a significant public health concern owing to its expanding habitat and vector competence. Disease outbreaks attributed to this species have been reported in areas under its invasion, and its northward expansion in Japan has caused concern because of the potential for dengue virus infection in newly populated areas. Accurate prediction of Ae. albopictus distribution is crucial to prevent the spread of the disease. However, limited studies have focused on the prediction of Ae. albopictus distribution in Japan. Herein, we used the random forest model, a machine learning approach, to predict the current and potential future habitat ranges of Ae. albopictus in Japan. The model revealed that these mosquitoes prefer urban areas over forests in Japan on the current map. Under predictions for the future, the species will expand its range to the surrounding areas and eventually reach many areas of northeastern Kanto, Tohoku District, and Hokkaido, with a few variations in different scenarios. However, the affected human population is predicted to decrease owing to the declining birth rate. Anthropogenic and climatic factors contribute to range expansion, and urban size and population have profound impacts. This prediction map can guide responses to the introduction of this species in new areas, advance the spatial knowledge of diseases vectored by it, and mitigate the possible disease burden. To our knowledge, this is the first distribution-modelling prediction for Ae. albopictus with a focus on Japan.

Pathological examination of Ym1, a chitinase family protein, in Mesocestoides corti-infected mice.

Mammals express a set of chitinase family proteins, comprising chitinases, which can hydrolyze chitin, and chitinase-like proteins without the chitinase activity but possessing chitin-binding properties. They act as endogenous lectins, regulating various physiological/pathological events. Ym1, originally identified as an eosinophil chemotactic factor or a macrophage-derived protein in parasite-infected mice, is a rodent-specific chitinase-like protein. Ym1 is also purified from eosinophilic crystals formed in the lung and urinary system in various disease models. We previously reported that major cellular sources of murine Ym1 are alveolar macrophages in the lung and neutrophils/monocytes lineage cells of the spleen and bone marrow under normal conditions. We here analyzed the detailed cellular expression of Ym1 in Mesocestoides corti (M. corti)-infected mice. Ym1 was significantly increased in the liver containing the larvae, lung, and peritoneal exudate cells in M. corti-infected mice, where activated macrophages expressed Ym1. Characteristic needle-shaped eosinophilic crystals appeared in the larvae-free lung, and Ym1 was localized to endoplasmic reticulum of activated alveolar macrophages. Moreover, swollen mesothelial cells covering the liver, spleen, and heart expressed Ym1 abundantly. Although the role of Ym1 in parasitic infection remains unclear, our findings focusing on an endogenous lectin may help in better understanding defense mechanism against parasites.

Identification of an eosinophil chemotactic factor from anopheline mosquitoes as a chitinase family protein.

Anopheline mosquitoes play an essential role in malaria transmission. The mosquito salivates copiously when probing for the location of a blood vessel. We found that the saliva of anopheline mosquitoes has chemotactic activity for naive eosinophils or neutrophils. The major eosinophil chemotactic component in saliva was shown to be one of the chitinase family proteins. A similar chitinase family protein was found also in the midgut of the anopheline mosquito. Production of antibodies to the chitinase family protein was generally observed in the sera of residents of a malaria endemic area. Both Plasmodium falciparum-infected and uninfected individuals had antibodies to chitinases. These results suggest that the chitinase family protein in mosquito saliva contributes to eliciting an inflammatory response of eosinophils in the host skin followed by antibody production in the host.

Schistosoma mekongi: a prominent neutrophil chemotactic activity of egg antigen with reference to that of Schistosoma japonicum.

Schistosoma mekongi causes granulomatous lesions around eggs deposited in the liver with neutrophil-rich inflammatory reactions in the early stage of the egg laying. To define the aspects of the typical pathogenesis of S. mekongi infection, we determined the difference between soluble egg antigen (SEA) from S. mekongi and S. japonicum with a focus on chemotactic factors for neutrophils or eosinophils. Mean volume and protein amount of S. mekongi eggs was 71 and 58% of those of Schistosoma japonicum eggs, respectively. Neutrophil chemotactic activity of S. mekongi SEA was about two times higher than that of S. japonicum. In contrast, eosinophil chemotactic activity of S. mekongi SEA was about half of that of S. japonicum SEA. Molecular analysis revealed that S. mekongi SEA contains higher molecular-weight components with a lower level of glycosylation, and this is likely to be related to the intense neutrophil chemotactic activity in comparison with S. japonicum SEA. The prominent chemotactic reactivity for neutrophils is likely to be involved in the typical pathogenesis of mekongi schistosomiasis.

Cellular expression of murine Ym1 and Ym2, chitinase family proteins, as revealed by in situ hybridization and immunohistochemistry.

Ym is one of the chitinase family proteins, which are widely distributed in mammalian bodies and can bind glycosaminoglycans such as heparin/heparan sulfate. Ym1 is a macrophage protein produced in parasitic infections, while its isoform, Ym2, is upregulated in lung under allergic conditions. In the present study, we revealed the distinct cellular expression of Ym1 and Ym2 in normal mice by in situ hybridization and immunohistochemistry. Ym1 was principally expressed in the lung, spleen, and bone marrow, while Ym2 was found in the stomach. Ym1-expressing cells in the lung were alveolar macrophages, and the immunoreactivity for Ym1 was localized in rough endoplasmic reticulum. In the spleen, Ym1-expressing cells gathered in the red pulp and were electron microscopically identified as immature neutrophils. In the bone marrow, immature neutrophils were intensely immunoreactive, but lost this immunoreactivity with maturation. Moreover, needle-shaped crystals in the cytoplasm of macrophages, which formed erythroblastic islands, also showed intense Ym1 immunoreactivity. Ym2 expression was restricted to the stratified squamous epithelium in the junctional region between forestomach and glandular stomach. The function of Ym1 and Ym2 is still unclear; however, the distinct cellular localization under normal conditions suggests their important roles in hematopoiesis, tissue remodeling, or immune responses as an endogenous lectin.

Identification of a ubiquitin family protein as a novel neutrophil chemotactic factor.

Neutrophil chemotaxis is a process that is essential for the recruitment of neutrophils to an inflamed site. In the present study, we found a remarkable increase in neutrophil chemotactic activity in the lysate of red blood cells (RBC) of mice infected with murine malaria, Plasmodium yoelii. A neutrophil chemotactic factor with an apparent molecular weight of 17 kDa (IP17) was isolated from RBC by a combination of anion-exchange chromatography on DE52 and cation-exchange chromatography on Mono S. A comprehensive GenBank database search of N-terminal amino acid sequences and MALDI-TOF mass analysis of IP17 revealed that IP17 is identical to a murine homologue of ISG15/UCRP, a member of the ubiquitin family of proteins that are inducible by interferon-beta. Recombinant mouse ISG15 showed neutrophil chemotactic activity comparable to that of natural IP17. IP17 showed specific chemotactic activity forward neutrophils and activated neutrophils to induce the release of eosinophil chemotactic factors. These results suggest that the ubiquitin family protein ISG15/UCRP has novel functions in neutrophil-mediated immune mechanisms.