Human African Trypanosomiasis (HAT), commonly known as sleeping sickness is a vector-borne parasitic infection caused by protozoa of the genus Trypanosoma. It can be fatal if left untreated. HAT is found in sub-Saharan Africa, but is restricted to the range of its tsetse vector. In recent decades, the foci of HAT infections have changed and it has been suggested that climate change and changes to the habitats of the tsetse vectors have influenced the observed changes. The paper by Tongue et al. clearly demonstrates the effects of habitat change on the transmission of African trypanosomiasis. Certain subspecies of Glossina have adjusted to the decrease in natural habitats by exhibiting peri-domestic behaviors that allow them to live in urban and suburban habitats near humans. The increase in urban and suburban habitats for subspecies of the tsetse vector Glossina has reduced the effectiveness of efforts to control, much less eliminate, transmission of the causative species Trypanosoma brucei rhodesiense (causes the acute form of the disease) and Trypanosoma brucei gambiense (causes the chronic from of the disease). This study provides a cautionary tale about the influence of habitat changes and climate change on the future of HAT transmission (and other pathogens), assuming these changes continue to occur. In the next study, we move west off of the continent of Africa to consider a species of mosquito in the genusCulex and its possible role in the transmission of Dirofilaria immitis, the primary causative agent of heartworm disease. Although the Canary Islands are a known endemic focus of Dirofilaria immitis, the mosquito vector on the island has, heretofore, not been identified. This article by Morchon Garcia et al. provides convincing evidence that they found the mosquito species that serves as the vector of D. immitis on the islands. Five potential vector species of mosquitoes were collected on the islands. Using molecular biological techniques, the authors identified one species of mosquito, Culex theileri, which was infected with D. immitis. Recent studies in Iran [4] and Spain [5] suggest that C. theileri is a competent vector species. In addition, comparing analyses of the mtDNA in the cox1 gene between C. theileri populations in the Canary Islands and Iran suggest that the two populations are molecularly similar. Although the results of this study are supportive of the role of C. theileri in the transmission of D. immitis in the Canary Islands, the authors caution that additional studies are required to conclusively support their suggestions. Our next study takes us to Asia and consideration of the status of Visceral Leishmaniasis (VL) in Iran. In his review, Mohebali combines his personal experience with numerous (>3,000) cases of leishmaniasis in Iran with results obtained from a search of databases from 1996 through 2010. The author’s results suggest that canids serve as the primary reservoir hosts of infection of humans a result found in previous studies [6]. Several species of Phlebotomus serve the insect vectors in Iran. In Iran, VL appears to be a disease of the young as children 12 years of age and younger made up 92.8% of the reported cases of VL during the time span under review. Mohebali found that the direct agglutination test was an effective means of detecting antiLeishmania antibodies and recommended it as a surveillance tool. The author concluded that VL is a serious zoonotic threat in Iran with sporadic prevalence in most geographic zones while being endemic in northwestern and southern Iran. Finally, we go further east and north to Mongolia where Papageorgiou et al. examined the epidemiology of tick-borne pathogens in two of the country’s provinces (aimags). Livestock were investigated using serology and PCR to identify exposure and infection