Your search keyword '"DeRiso, Elizabeth A"' showing total 7 results

1. Borrelia-specific antibody profiles and complement deposition in joint fluid distinguish antibiotic-refractory from -responsive Lyme arthritis

Author

Bowman, Kathryn A., Wiggins, Christine D., DeRiso, Elizabeth, Paul, Steffan, Strle, Klemen, Branda, John A., Steere, Allen C., Lauffenburger, Douglas A., and Alter, Galit

Published

2024

2. COVID-19 booster dose induces robust antibody response in pregnant, lactating, and nonpregnant women

Author

Atyeo, Caroline, Shook, Lydia L., Nziza, Nadege, Deriso, Elizabeth A., Muir, Cordelia, Baez, Arantxa Medina, Lima, Rosiane S., Demidkin, Stepan, Brigida, Sara, De Guzman, Rose M., Burns, Madeleine D., Balazs, Alejandro B., Fasano, Alessio, Yonker, Lael M., Gray, Kathryn J., Alter, Galit, and Edlow, Andrea G.

Published

2023

3. Accumulation of Neutrophil Phagocytic Antibody Features Tracks With Naturally Acquired Immunity Against Malaria in Children.

Author

Nziza, Nadege, Tran, Tuan M, DeRiso, Elizabeth A, Dolatshahi, Sepideh, Herman, Jonathan D, Lacerda, Luna de, Junqueira, Caroline, Lieberman, Judy, Ongoiba, Aissata, Doumbo, Safiatou, Kayentao, Kassoum, Traore, Boubacar, Crompton, Peter D, and Alter, Galit

Subjects

IMMUNITY, NEUTROPHILS, MALARIA, IMMUNOGLOBULINS, HUMORAL immunity

Abstract

Background Studies have demonstrated the protective role of antibodies against malaria. Young children are known to be particularly vulnerable to malaria, pointing to the evolution of naturally acquired clinical immunity over time. However, whether changes in antibody functionality track with the acquisition of naturally acquired malaria immunity remains incompletely understood. Methods Using systems serology, we characterized sporozoite- and merozoite-specific antibody profiles of uninfected Malian children before the malaria season who differed in their ability to control parasitemia and fever following Plasmodium falciparum (Pf) infection. We then assessed the contributions of individual traits to overall clinical outcomes, focusing on the immunodominant sporozoite CSP and merozoite AMA1 and MSP1 antigens. Results Humoral immunity evolved with age, with an expansion of both magnitude and functional quality, particularly within blood-stage phagocytic antibody activity. Moreover, concerning clinical outcomes postinfection, protected children had higher antibody-dependent neutrophil activity along with higher levels of MSP1-specific IgG3 and IgA and CSP-specific IgG3 and IgG4 prior to the malaria season. Conclusions These data point to the natural evolution of functional humoral immunity to Pf with age and highlight particular antibody Fc-effector profiles associated with the control of malaria in children, providing clues for the design of next-generation vaccines or therapeutics. [ABSTRACT FROM AUTHOR]

Published

2023

4. COVID-19 mRNA vaccines drive differential antibody Fc-functional profiles in pregnant, lactating, and nonpregnant women.

Author

Atyeo, Caroline, DeRiso, Elizabeth A., Davis, Christine, Bordt, Evan A., De Guzman, Rose M., Shook, Lydia L., Yonker, Lael M., Fasano, Alessio, Akinwunmi, Babatunde, Lauffenburger, Douglas A., Elovitz, Michal A., Gray, Kathryn J., Edlow, Andrea G., and Alter, Galit

Subjects

COVID-19 vaccines, LACTATION, COVID-19, MATERNALLY acquired immunity, VACCINE effectiveness, IMMUNE response

Abstract

COVID-19 and pregnancy: Pregnancy results in systemic changes to the maternal immune system that cause distinct responses to infection or vaccination. Here, Bordt et al. and Atyeo et al. investigated how pregnancy influences the immune response to infection with or vaccination against severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2). Bordt et al. characterized placental immune responses in women who were infected with SARS-CoV-2 during pregnancy. The authors observed differential placental immune responses between male and female fetuses that were associated with reduced antibody transfer to male fetuses. Atyeo et al. evaluated immune responses to mRNA vaccination in women who were pregnant, lactating, or not pregnant. The authors found that two doses of vaccine were required for pregnant or lactating women to achieve immune responses comparable to that of nonpregnant women. An accompanying Focus article discusses these findings and the need for vaccination against SARS-CoV-2 during pregnancy. Substantial immunological changes occur throughout pregnancy to render the mother immunologically tolerant to the fetus and allow fetal growth. However, additional local and systemic immunological adaptations also occur, allowing the maternal immune system to continue to protect the dyad against pathogens both during pregnancy and after birth through lactation. This fine balance of tolerance and immunity, along with physiological and hormonal changes, contributes to increased susceptibility to particular infections in pregnancy, including more severe coronavirus disease 2019 (COVID-19). Whether these changes also make pregnant women less responsive to vaccination or induce altered immune responses to vaccination remains incompletely understood. To define potential changes in vaccine response during pregnancy and lactation, we undertook deep sequencing of the humoral vaccine response in a group of pregnant and lactating women and nonpregnant age-matched controls. Vaccine-specific titers were comparable between pregnant women, lactating women, and nonpregnant controls. However, Fc receptor (FcR) binding and antibody effector functions were induced with delayed kinetics in both pregnant and lactating women compared with nonpregnant women after the first vaccine dose, which normalized after the second dose. Vaccine boosting resulted in high FcR-binding titers in breastmilk. These data suggest that pregnancy promotes resistance to generating proinflammatory antibodies and indicates that there is a critical need to follow prime-boost timelines in this vulnerable population to ensure full immunity is attained. [ABSTRACT FROM AUTHOR]

Published

2021

5. Self-adjuvanting bacterial vectors expressing pre-erythrocytic antigens induce sterile protection against malaria.

Author

Bergmann-Leitner, Elke S., Hosie, Heather, Trichilo, Jessica, DeRiso, Elizabeth, Ranallo, RyanT., Alefantis, Timothy, Savranskaya, Tatyana, Grewal, Paul, Ockenhouse, Christian F., Venkatesan, Malabi M., DelVecchio, Vito G., and Angov, Evelina

Subjects

ESCHERICHIA coli, SHIGELLA, MALARIA, ERYTHROCYTES, GRAM-negative bacteria, IMMUNOLOGICAL adjuvants, PLASMODIUM falciparum, MALTOSE-binding proteins, VACCINATION

Abstract

Genetically inactivated, Gram-negative bacteria that express malaria vaccine candidates represent a promising novel self-adjuvanting vaccine approach. Antigens expressed on particulate bacterial carriers not only target directly to antigen-presenting cells but also provide a strong danger signal thus circumventing the requirement for potent extraneous adjuvants. E. coli expressing malarial antigens resulted in the induction of eitherTh1 orTh2 biased responses that were dependent on both antigen and sub-cellular localization. Some of these constructs induced higher quality humoral responses compared to recombinant protein and most importantly they were able to induce sterile protection against sporo zoite challenge in a murine model of malaria. In light of these encouraging results, two major Plasmodium falciparum pre-erythrocytic malaria vaccine targets, the Cell-Traversal protein for Ookinetes and Sporozoites (CelTOS) fused to the Maltose-binding protein in the periplasmic space and the Circumsporozoite Protein (CSP) fused to the Outer membrane (OM) protein A in the OM were expressed in a clinically relevant, attenuated Shigella strain (Shigella flexneri 2a). This type of live-attenuated vector has previously undergone clinical investigations as a vaccine against shigellosis. Using this novel delivery platform for malaria, we find that vaccination with the whole-organism represents an effective vaccination alter native that induces protective efficacy against sporozoite challenge. Shigella GeMI-Vax expressing malaria targets warrant further evaluation to determine their full potential as a dual disease, multivalent, self-adjuvanting vaccine system, against both shigellosis, and malaria. [ABSTRACT FROM AUTHOR]

Published

2013

6. A Molecular Signature in Blood Reveals a Role for p53 in Regulating Malaria-Induced Inflammation.

Author

Tran, Tuan M., Guha, Rajan, Portugal, Silvia, Skinner, Jeff, Ongoiba, Aissata, Bhardwaj, Jyoti, Jones, Marcus, Moebius, Jacqueline, Venepally, Pratap, Doumbo, Safiatou, DeRiso, Elizabeth A., Li, Shanping, Vijayan, Kamalakannan, Anzick, Sarah L., Hart, Geoffrey T., O'Connell, Elise M., Doumbo, Ogobara K., Kaushansky, Alexis, Alter, Galit, and Felgner, Phillip L.

Subjects

*MALARIA, *FC receptors, *IMMUNOGLOBULIN G, *P53 protein, *PARASITEMIA, *FEVER, *T helper cells, *PROTEIN expression

Abstract

Immunity that controls parasitemia and inflammation during Plasmodium falciparum (Pf) malaria can be acquired with repeated infections. A limited understanding of this complex immune response impedes the development of vaccines and adjunctive therapies. We conducted a prospective systems biology study of children who differed in their ability to control parasitemia and fever following Pf infection. By integrating whole-blood transcriptomics, flow-cytometric analysis, and plasma cytokine and antibody profiles, we demonstrate that a pre-infection signature of B cell enrichment, upregulation of T helper type 1 (Th1) and Th2 cell-associated pathways, including interferon responses, and p53 activation associated with control of malarial fever and coordinated with Pf -specific immunoglobulin G (IgG) and Fc receptor activation to control parasitemia. Our hypothesis-generating approach identified host molecules that may contribute to differential clinical outcomes during Pf infection. As a proof of concept, we have shown that enhanced p53 expression in monocytes attenuated Plasmodium -induced inflammation and predicted protection from fever. • A 3-year study identifies children who control malaria fever and parasitemia • Systems analysis before and during infection in immune versus susceptible children • Cellular and humoral immune profiles associate with control of fever and parasitemia • p53 in monocytes attenuates malaria inflammation and predicts protection from fever The mechanisms that protect from febrile malaria remain unclear. Tran et al. applied a systems-based approach to a longitudinal pediatric study to identify immune signatures that associate with control of malaria fever and parasitemia, revealing that p53 upregulation in monocytes attenuates malaria-induced inflammation and predicts protection from fever. [ABSTRACT FROM AUTHOR]

Published

2019

7. COVID-19 mRNA vaccines drive differential Fc-functional profiles in pregnant, lactating, and non-pregnant women.

Author

Atyeo C, DeRiso EA, Davis C, Bordt EA, DeGuzman RM, Shook LL, Yonker LM, Fasano A, Akinwunmi B, Lauffenburger DA, Elovitz MA, Gray KJ, Edlow AG, and Alter G

Abstract

Significant immunological changes occur throughout pregnancy to tolerize the mother and allow growth of the fetal graft. However, additional local and systemic immunological adaptations also occur, allowing the maternal immune system to continue to protect the dyad against foreign invaders both during pregnancy and after birth through lactation. This fine balance of tolerance and immunity, along with physiological and hormonal changes, contribute to increased susceptibility to particular infections in pregnancy, including more severe COVID-19 disease. Whether these changes also make pregnant women less responsive to vaccination or induce altered immune responses to vaccination remains incompletely understood. To holistically define potential changes in vaccine response during pregnancy and lactation, we deeply profiled the humoral vaccine response in a group of pregnant and lactating women and non-pregnant age-matched controls. Vaccine-specific titers were comparable, albeit slightly lower, between pregnant and lactating women, compared to non-pregnant controls. Among pregnant women, we found higher antibody titers and functions in those vaccinated with the Moderna vaccine. FcR-binding and antibody effector functions were induced with delayed kinetics in both pregnant and lactating women compared to non-pregnant women. Antibody boosting resulted in high FcR-binding titers in breastmilk. These data point to an immune resistance to generate highly inflammatory antibodies during pregnancy and lactation, and a critical need to follow prime/boost timelines in this vulnerable population to ensure full immunity is attained.

Published

2021