Repeated intravenous (IV) administration of radiation-attenuated sporozoite (RAS) vaccines induces Plasmodium-specific CD8+ liver-resident T (Trm) cells in mice and achieves sterile protection against challenge. Our heterologous “prime-and-trap” vaccine strategy was previously shown to simplify and improve upon RAS vaccination. Prime-and-trap vaccination combines epidermal priming by DNA-encoded circumsporozoite protein (CSP) antigen followed by a single IV dose of freshly dissected RAS (fresh-RAS) to direct and trap activated and expanding CD8+ T cells in the liver. Prime-and-trap vaccination protects mice against wild-type sporozoite (spz) challenge. Assessment of prime-and-trap vaccines in nonhuman primate (NHP) models and/or humans would be greatly enabled if fresh-RAS could be replaced by cryopreserved RAS (cryo-RAS). Here, we investigated if fresh-RAS could be replaced with cryo cryo-RAS for prime-and-trap vaccination in BALB/cj mice. Despite a reduction in spz vaccine liver burden following cryo-RAS administration compared with fresh-RAS, cryo-RAS induced a similar level of Plasmodium yoelii (Py) CSP-specific CD8+ liver Trm cells and completely protected mice against Pyspz challenge 112 days after vaccination. Additionally, when the glycolipid adjuvant 7DW8-5 was coadministered with cryo-RAS, 7DW8-5 permitted the dose of cryo-RAS to be reduced 4-fold while still achieving high rates of sterile protection. In summary, cryo-RAS with and without 7DW8-5 were compatible with prime-and-trap malaria vaccination in a mouse model, which may accelerate the pathway for this vaccine strategy to move to NHPs and humans.
Pregnant women infected with pathogenic respiratory viruses, such as influenza A viruses (IAV) and coronaviruses, are at higher risk for mortality, hospitalization, preterm birth, and stillbirth. Several factors are likely to contribute to the susceptibility of pregnant individuals to severe lung disease including changes in pulmonary physiology, immune defenses, and effector functions of some immune cells. Pregnancy is also a physiologic state characterized by higher levels of multiple hormones that may impact the effector functions of immune cells, such as progesterone, estrogen, human chorionic gonadotropin, prolactin, and relaxin. Each of these hormones acts to support a tolerogenic immune state of pregnancy, which helps prevent fetal rejection, but may also contribute to an impaired antiviral response. In this review, we address the unique role of adaptive and innate immune cells in the control of pathogenic respiratory viruses and how pregnancy and specific hormones can impact their effector actions. We highlight viruses with sex‐specific differences in infection outcomes and why pregnancy hormones may contribute to fetal protection but aid the virus at the expense of the mother's health.
Herpes Simplex Virus 2 (HSV-2) is the primary cause of genital herpes, affecting 500 million people worldwide of which approximately 64% are women. Despite this disproportionately high burden, the female reproductive tract and its unique mucosal immune environment is surprisingly understudied. Tregs are necessary for CD4 +T cell priming in the draining lymph node (dLN), though their role in shaping tissue-resident memory T cell (T rm) responses during HSV-2 reactivation is unclear. Our preliminary data indicate that activated Tregs accumulate and persist in mouse vaginal tissue (VT) after above baseline out to at least 90 days post-infection (p.i.), thus implicating Tregs in memory recall responses to reinfection. We hypothesize that Tregs restrain robust T rmrecall responses to HSV-2 challenge. Additionally, we hypothesize that vaginal Tregs promote tissue healing in the VT in response to inflammatory alarmins through the expression of the epidermal growth factor ligand, amphiregulin (Areg). Female FoxP3 DTRmice were infected intravaginally with attenuated HSV-2, then systemically depleted of Tregs via intraperitoneal injection of diphtheria toxin and challenged with WT HSV-2 on day 30 p.i. Systemically Treg-depleted mice show increased activation and proliferation of T cells, and increased frequency of cytotoxic HSV-2-specific CD8 +T cells in the VT by day 3 post-challenge. Treg-depleted mice also have significantly higher pathology scores in H&E-stained VT. We also report that VT Tregs from infected mice express more Areg than dLN Tregs via flow cytometry and single cell RNAseq. Ongoing work includes characterization of Areg expressing VT Tregs and further dissection of the T rmrecall responses in Treg-depleted mice. NIH (T32 AI07140, R01 AI141435)
Malaria is caused by Plasmodium parasites and was responsible for over 247 million infections and 619,000 deaths in 2021. Radiation-attenuated sporozoite (RAS) vaccines can completely prevent blood stage infection by inducing protective liver-resident memory CD8+ T cells. Such T cells can be induced by ‘prime-and-trap’ vaccination, which here combines DNA priming against the P. yoelii circumsporozoite protein (CSP) with a subsequent intravenous (IV) dose of liver-homing RAS to “trap” the activated and expanding T cells in the liver. Prime-and-trap confers durable protection in mice, and efforts are underway to translate this vaccine strategy to the clinic. However, it is unclear whether the RAS trapping dose must be strictly administered by the IV route. Here we show that intradermal (ID) RAS administration can be as effective as IV administration if RAS are co-administrated with the glycolipid adjuvant 7DW8-5 in an ultra-low inoculation volume. In mice, the co-administration of RAS and 7DW8-5 in ultra-low ID volumes (2.5 µL) was completely protective and dose sparing compared to standard volumes (10–50 µL) and induced protective levels of CSP-specific CD8+ T cells in the liver. Our finding that adjuvants and ultra-low volumes are required for ID RAS efficacy may explain why prior reports about higher volumes of unadjuvanted ID RAS proved less effective. The ID route may offer significant translational advantages over the IV route and could improve sporozoite vaccine development.
Herpes Simplex Virus type-2 (HSV-2) infection is one of the most prevalent sexually transmitted infections, yet no vaccine is currently available. Detailed analysis of HSV-infected human tissue revealed tissue-resident CD8 T cells (TRM) limit the duration and severity of HSV-2 episodes. Interestingly, recent studies indicate that the sensing and alarming function of CD8 TRMs is not restricted to cognate antigen interaction, but CD8 TRM can mediate protection against antigenically unrelated pathogens, termed “bystander activation.” Here, we investigated if antigen non-specific CD8 T cells could provide some degree of protection in a bystander fashion in the context of HSV infection. To test this, we created antigen non-specific memory compartments through immunization of mice with Listeria expressing ovalbumin (OVA) (LM-OVA). Mice were then challenged with wild-type HSV-2 to assess the degree of bystander-mediated protection. Immunization with LM-OVA-delayed disease progression from lethal viral challenge, suggesting that bystander CD8 T cells may mediate protection despite the lack of antigen-specificity. Furthermore, we found early infiltration of antigen-non-specific CD8 T cells (OVA-specific) in the vaginal tract in the infection setting. Additionally, assessment of the memory CD8 compartment in human vaginal tissue upon in-vitro treatment with cytokines caused bystander activation of memory CD8 T cells. Finally, we found that in-vitro treatment of CD8 T cells with cytokines delayed disease progression and reduced viral burden upon adoptive transfer. Altogether, our findings suggest that local bystander-activation of CD8 memory T cells can participate in protection from HSV-2.
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