Clustering and Erratic Movement Patterns of Syringe-Injected versus Mosquito-Inoculated Malaria Sporozoites Underlie Decreased Infectivity

C M de Korne; B M F Winkel; M N van Oosterom; S Chevalley-Maurel; H M Houwing; J C Sijtsma; S Azargoshasb; E Baalbergen; B M D Franke-Fayard; F W B van Leeuwen; M Roestenberg

doi:10.1128/mSphere.00218-21

Clustering and Erratic Movement Patterns of Syringe-Injected versus Mosquito-Inoculated Malaria Sporozoites Underlie Decreased Infectivity

mSphere. 2021 Apr 7;6(2):e00218-21. doi: 10.1128/mSphere.00218-21.

Authors

Affiliations

¹ Department of Parasitology, Leiden University Medical Center, Leiden, The Netherlands.
² Interventional Molecular Imaging Laboratory, Department of Radiology, Leiden University Medical Center, Leiden, The Netherlands.
³ Department of Parasitology, Leiden University Medical Center, Leiden, The Netherlands M.Roestenberg@lumc.nl.
⁴ Department of Infectious Diseases, Leiden University Medical Center, Leiden, The Netherlands.

Abstract

Malaria vaccine candidates based on live, attenuated sporozoites have led to high levels of protection. However, their efficacy critically depends on the sporozoites' ability to reach and infect the host liver. Administration via mosquito inoculation is by far the most potent method for inducing immunity but highly impractical. Here, we observed that intradermal syringe-injected Plasmodium berghei sporozoites (^syrSPZ) were 3-fold less efficient in migrating to and infecting mouse liver than mosquito-inoculated sporozoites (^msqSPZ). This was related to a clustered dermal distribution (2-fold-decreased median distance between ^syrSPZ and ^msqSPZ) and, more importantly, a 1.4-fold (significantly)-slower and more erratic movement pattern. These erratic movement patterns were likely caused by alteration of dermal tissue morphology (>15-μm intercellular gaps) due to injection of fluid and may critically decrease sporozoite infectivity. These results suggest that novel microvolume-based administration technologies hold promise for replicating the success of mosquito-inoculated live, attenuated sporozoite vaccines.IMPORTANCE Malaria still causes a major burden on global health and the economy. The efficacy of live, attenuated malaria sporozoites as vaccine candidates critically depends on their ability to migrate to and infect the host liver. This work sheds light on the effect of different administration routes on sporozoite migration. We show that the delivery of sporozoites via mosquito inoculation is more efficient than syringe injection; however, this route of administration is highly impractical for vaccine purposes. Using confocal microscopy and automated imaging software, we demonstrate that syringe-injected sporozoites do cluster, move more slowly, and display more erratic movement due to alterations in tissue morphology. These findings indicate that microneedle-based engineering solutions hold promise for replicating the success of mosquito-inoculated live, attenuated sporozoite vaccines.

Keywords: Plasmodium berghei; fluorescent microscopy; malaria; motility; sporozoite.

MeSH terms

Animals
Culicidae / parasitology*
Drug Delivery Systems
Female
Injections, Intradermal / methods*
Insect Bites and Stings / parasitology*
Liver / parasitology
Malaria / prevention & control
Malaria Vaccines / administration & dosage
Mice
Movement
Plasmodium berghei / physiology*
Sporozoites / physiology*
Syringes*
Vaccines, Attenuated / administration & dosage

Substances

Malaria Vaccines
Vaccines, Attenuated