Your search keyword '"Julius J. Lutwama"' showing total 10 results

1. Longitudinal proteome-wide antibody profiling in Marburg virus survivors identifies wing domain immunogen for vaccine design

Author

Surender Khurana, Gabrielle Grubbs, Supriya Ravichandran, Emily Cluff, JungHyun Kim, Ana I. Kuehne, Samantha Zak, John M. Dye, Julius J. Lutwama, and Andrew S. Herbert

Subjects

Science

Abstract

Abstract Limited knowledge exists on the quality of polyclonal antibody responses generated following Marburg virus (MARV) infection and its evolution in survivors. In this study, we evaluate MARV proteome-wide antibody repertoire longitudinally in convalescent phase approximately every six months for five years following MARV infection in ten human survivors. Differential kinetics were observed for IgM vs IgG vs IgA epitope diversity, antibody binding, antibody affinity maturation and Fc-receptor interaction to MARV proteins. Durability of MARV-neutralizing antibodies is low in survivors. MARV infection induces a diverse epitope repertoire with predominance against GP, VP40, VP30 and VP24 that persisted up to 5 years post-exposure. However, the IgM and IgA repertoire declines over time. Within MARV-GP, IgG recognize antigenic sites predominantly in the amino-terminus, wing domain and GP2-heptad repeat. Interestingly, MARV infection generates robust durable FcɣRI, FcɣRIIA and FcɣRIIIA IgG-Fc receptor interactions. Immunization with immunodominant MARV epitopes reveals conserved wing region between GP1 and GP2, induces neutralizing antibodies against MARV. These findings demonstrate that MARV infection generates a diverse, long-lasting, non-neutralizing, IgG antibody repertoire that perturbs disease by FcɣR activity. This information, along with discovery of neutralizing immunogen in wing domain, could aid in development of effective therapeutics and vaccines against Marburg virus.

Published

2024

2. Severe morbidity and hospital-based mortality from Rift Valley fever disease between November 2017 and March 2020 among humans in Uganda

Author

Zacchaeus Anywaine, Christian Hansen, George M. Warimwe, Ggayi Abu-Baker Mustapher, Luke Nyakarahuka, Stephen Balinandi, Alex Riolexus Ario, Julius J. Lutwama, Alison Elliott, and Pontiano Kaleebu

Subjects

Infectious and parasitic diseases, RC109-216

Abstract

Abstract Background Rift Valley fever (RVF) is a zoonotic viral disease of increasing intensity among humans in Africa and the Arabian Peninsula. In Uganda, cases reported prior to 2016 were mild or not fully documented. We report in this paper on the severe morbidity and hospital-based mortality of human cases in Uganda. Methods Between November 2017 and March 2020 human cases reported to the Uganda Virus Research Institute (UVRI) were confirmed by polymerase chain reaction (PCR). Ethical and regulatory approvals were obtained to enrol survivors into a one-year follow-up study. Data were collected on socio-demographics, medical history, laboratory tests, potential risk factors, and analysed using Stata software. Results Overall, 40 cases were confirmed with acute RVF during this period. Cases were not geographically clustered and nearly all were male (39/40; 98%), median age 32 (range 11–63). The median definitive diagnosis time was 7 days and a delay of three days between presumptive and definitive diagnosis. Most patients (31/40; 78%) presented with fever and bleeding at case detection. Twenty-eight (70%) cases were hospitalised, out of whom 18 (64%) died. Mortality was highest among admissions in regional referral (11/16; 69%) and district (4/5; 80%) hospitals, hospitalized patients with bleeding at case detection (17/27; 63%), and patients older than 44 years (9/9; 100%). Survivors mostly manifested a mild gastro-intestinal syndrome with nausea (83%), anorexia (75%), vomiting (75%), abdominal pain (50%), and diarrhoea (42%), and prolonged symptoms of severe disease including jaundice (67%), visual difficulties (67%), epistaxis (50%), haemoptysis (42%), and dysentery (25%). Symptom duration varied between two to 120 days. Conclusion RVF is associated with high hospital-based mortality, severe and prolonged morbidity among humans that present to the health care system and are confirmed by PCR. One-health composite interventions should be developed to improve environmental and livestock surveillance, prevent infections, promptly detect outbreaks, and improve patient outcomes.

Published

2024

3. Crimean-Congo hemorrhagic fever survivors elicit protective non-neutralizing antibodies that target 11 overlapping regions on glycoprotein GP38

Author

Olivia S. Shin, Stephanie R. Monticelli, Christy K. Hjorth, Vladlena Hornet, Michael Doyle, Dafna Abelson, Ana I. Kuehne, Albert Wang, Russell R. Bakken, Akaash K. Mishra, Marissa Middlecamp, Elizabeth Champney, Lauran Stuart, Daniel P. Maurer, Jiannan Li, Jacob Berrigan, Jennifer Barajas, Stephen Balinandi, Julius J. Lutwama, Leslie Lobel, Larry Zeitlin, Laura M. Walker, John M. Dye, Kartik Chandran, Andrew S. Herbert, Noel T. Pauli, and Jason S. McLellan

Subjects

CP: Immunology, Biology (General), QH301-705.5

Abstract

Summary: Crimean-Congo hemorrhagic fever virus can cause lethal disease in humans yet there are no approved medical countermeasures. Viral glycoprotein GP38, exclusive to Nairoviridae, is a target of protective antibodies and is a key antigen in preclinical vaccine candidates. Here, we isolate 188 GP38-specific antibodies from human survivors of infection. Competition experiments show that these antibodies bind across 5 distinct antigenic sites, encompassing 11 overlapping regions. Additionally, we show structures of GP38 bound with 9 of these antibodies targeting different antigenic sites. Although these GP38-specific antibodies are non-neutralizing, several display protective efficacy equal to or better than murine antibody 13G8 in two highly stringent rodent models of infection. Together, these data expand our understanding regarding this important viral protein and may inform the development of broadly effective CCHFV antibody therapeutics.

Published

2024

4. COVID-19 immune signatures in Uganda persist in HIV co-infection and diverge by pandemic phase

Author

Matthew J. Cummings, Barnabas Bakamutumaho, Julius J. Lutwama, Nicholas Owor, Xiaoyu Che, Maider Astorkia, Thomas S. Postler, John Kayiwa, Jocelyn Kiconco, Moses Muwanga, Christopher Nsereko, Emmanuel Rwamutwe, Irene Nayiga, Stephen Kyebambe, Mercy Haumba, Henry Kyobe Bosa, Felix Ocom, Benjamin Watyaba, Bernard Kikaire, Alin S. Tomoiaga, Stevens Kisaka, Noah Kiwanuka, W. Ian Lipkin, Max R. O’Donnell, and Collaboration for Clinical and Laboratory Characterization of COVID-19 in Uganda

Subjects

Science

Abstract

Abstract Little is known about the pathobiology of SARS-CoV-2 infection in sub-Saharan Africa, where severe COVID-19 fatality rates are among the highest in the world and the immunological landscape is unique. In a prospective cohort study of 306 adults encompassing the entire clinical spectrum of SARS-CoV-2 infection in Uganda, we profile the peripheral blood proteome and transcriptome to characterize the immunopathology of COVID-19 across multiple phases of the pandemic. Beyond the prognostic importance of myeloid cell-driven immune activation and lymphopenia, we show that multifaceted impairment of host protein synthesis and redox imbalance define core biological signatures of severe COVID-19, with central roles for IL-7, IL-15, and lymphotoxin-α in COVID-19 respiratory failure. While prognostic signatures are generally consistent in SARS-CoV-2/HIV-coinfection, type I interferon responses uniquely scale with COVID-19 severity in persons living with HIV. Throughout the pandemic, COVID-19 severity peaked during phases dominated by A.23/A.23.1 and Delta B.1.617.2/AY variants. Independent of clinical severity, Delta phase COVID-19 is distinguished by exaggerated pro-inflammatory myeloid cell and inflammasome activation, NK and CD8+ T cell depletion, and impaired host protein synthesis. Combining these analyses with a contemporary Ugandan cohort of adults hospitalized with influenza and other severe acute respiratory infections, we show that activation of epidermal and platelet-derived growth factor pathways are distinct features of COVID-19, deepening translational understanding of mechanisms potentially underlying SARS-CoV-2-associated pulmonary fibrosis. Collectively, our findings provide biological rationale for use of broad and targeted immunotherapies for severe COVID-19 in sub-Saharan Africa, illustrate the relevance of local viral and host factors to SARS-CoV-2 immunopathology, and highlight underemphasized yet therapeutically exploitable immune pathways driving COVID-19 severity.

Published

2024

5. Crimean-Congo hemorrhagic fever cases diagnosed during an outbreak of Sudan virus disease in Uganda, 2022-23.

Author

Stephen Balinandi, Sophia Mulei, Shannon Whitmer, Luke Nyakarahuka, Caitlin M Cossaboom, Elizabeth Shedroff, Maria Morales-Betoulle, Inna Krapiunaya, Alex Tumusiime, Jackson Kyondo, Jimmy Baluku, Dianah Namanya, Calvin R Torach, Joanita Mutesi, Jocelyn Kiconco, Godfrey Pimundu, Tonny Muyigi, Jessica Rowland, Andrew Nsawotebba, Isaac Ssewanyana, David Muwanguzi, Daniel Kadobera, Julie R Harris, Alex R Ario, Kagirita Atek, Henry B Kyobe, Susan Nabadda, Pontiano Kaleebu, Henry G Mwebesa, Joel M Montgomery, Trevor R Shoemaker, Julius J Lutwama, and John D Klena

Subjects

Arctic medicine. Tropical medicine, RC955-962, Public aspects of medicine, RA1-1270

Abstract

BackgroundIn September 2022, Uganda experienced an outbreak of Sudan virus disease (SVD), mainly in central Uganda. As a result of enhanced surveillance activities for Ebola disease, samples from several patients with suspected viral hemorrhagic fever (VHF) were sent to the VHF Program at Uganda Virus Research Institute (UVRI), Entebbe, Uganda, and identified with infections caused by other viral etiologies. Herein, we report the epidemiologic and laboratory findings of Crimean-Congo hemorrhagic fever (CCHF) cases that were detected during the SVD outbreak response.MethodologyWhole blood samples from VHF suspected cases were tested for Sudan virus (SUDV) by real-time reverse transcription-polymerase chain reaction (RT-PCR); and if negative, were tested for CCHF virus (CCHFV) by RT-PCR. CCHFV genomic sequences generated by metagenomic next generation sequencing were analyzed to ascertain strain relationships.Principal findingsBetween September 2022 and January 2023, a total of 2,626 samples were submitted for VHF testing at UVRI. Overall, 13 CCHF cases (including 7 deaths; case fatality rate of 53.8%), aged 4 to 60 years, were identified from 10 districts, including several districts affected by the SVD outbreak. Four cases were identified within the Ebola Treatment Unit (ETU) at Mubende Hospital. Most CCHF cases were males engaged in livestock farming or had exposure to wildlife (n = 8; 61.5%). Among confirmed cases, the most common clinical symptoms were hemorrhage (n = 12; 92.3%), fever (n = 11; 84.6%), anorexia (n = 10; 76.9%), fatigue (n = 9; 69.2%), abdominal pain (n = 9; 69.2%) and vomiting (n = 9; 69.2%). Sequencing analysis showed that the majority of identified CCHFV strains belonged to the Africa II clade previously identified in Uganda. Two samples, however, were identified with greater similarity to a CCHFV strain that was last reported in Uganda in 1958, suggesting possible reemergence.Conclusions/significanceIdentifying CCHFV from individuals initially suspected to be infected with SUDV emphasizes the need for comprehensive VHF testing during filovirus outbreak responses in VHF endemic countries. Without expanded testing, CCHFV-infected patients would have posed a risk to health care workers and others while receiving treatment after a negative filovirus diagnosis, thereby complicating response dynamics. Additionally, CCHFV-infected cases could acquire an Ebola infection while in the ETU, and upon release because of a negative Ebola virus result, have the potential to spread these infections in the community.

Published

2024

6. Widespread human exposure to ledanteviruses in Uganda: A population study.

Author

James G Shepherd, Shirin Ashraf, Jesus F Salazar-Gonzalez, Maria G Salazar, Robert G Downing, Henry Bukenya, Hanna Jerome, Joseph T Mpanga, Chris Davis, Lily Tong, Vattipally B Sreenu, Linda A Atiku, Nicola Logan, Ezekiel Kajik, Yafesi Mukobi, Cyrus Mungujakisa, Michael V Olowo, Emmanuel Tibo, Fred Wunna, Hollie Jackson Ireland, Andrew E Blunsum, Iyanuoluwani Owolabi, Ana da Silva Filipe, Josephine Bwogi, Brian J Willett, Julius J Lutwama, Daniel G Streicker, Pontiano Kaleebu, and Emma C Thomson

Subjects

Arctic medicine. Tropical medicine, RC955-962, Public aspects of medicine, RA1-1270

Abstract

Le Dantec virus (LDV), assigned to the species Ledantevirus ledantec, genus Ledantevirus, family Rhabdoviridae has been associated with human disease but has gone undetected since the 1970s. We describe the detection of LDV in a human case of undifferentiated fever in Uganda by metagenomic sequencing and demonstrate a serological response using ELISA and pseudotype neutralisation. By screening 997 individuals sampled in 2016, we show frequent exposure to ledanteviruses with 76% of individuals seropositive in Western Uganda, but lower seroprevalence in other areas. Serological cross-reactivity as measured by pseudotype-based neutralisation was confined to ledanteviruses, indicating population seropositivity may represent either exposure to LDV or related ledanteviruses. We also describe the discovery of a closely related ledantevirus in blood from the synanthropic rodent Mastomys erythroleucus. Ledantevirus infection is common in Uganda but is geographically heterogenous. Further surveys of patients presenting with acute fever are required to determine the contribution of these emerging viruses to febrile illness in Uganda.

Published

2024

7. Case Reports of Human Monkeypox Virus Infections, Uganda, 2024.

Author

Bbosa N, Nabirye SE, Namagembe HS, Kiiza R, Ssekagiri A, Munyagwa M, Bwambale A, Bagonza S, Bosa HK, Downing R, Lutwama J, Kaleebu P, and Ssemwanga D

Abstract

Mpox is a zoonotic disease caused by the monkeypox virus. We report on human mpox cases in Uganda identified by PCR and confirmed by deep sequencing. Phylogenetic analysis revealed clustering with other clade Ib sequences associated with recent outbreaks in the Democratic Republic of the Congo.

Published

2024

8. Genotypic and phylogeographic insights into a pre-epidemic variant of Wesselsbron virus detected in sylvatic Aedes mcintoshi from Semuliki Forest, Uganda.

Author

Eibner GJ, Graff SL, Hieke C, Ochieng JR, Kopp A, Drosten C, Lutwama J, Rwego IB, and Junglen S

Abstract

Wesselsbron virus (WSLV) is a neglected mosquito-borne virus within the yellow fever subgroup in the genus Orthoflavivirus of the Flaviviridae family. Despite being primarily a veterinary pathogen able to cause stillbirths, congenital malformations, and mortality in ruminants, WSLV also infects humans, causing a usually self-limiting febrile illness, or may lead to neurological complications in rare cases. WSLV causes sporadic outbreaks in Southern Africa, but findings in mosquitoes from other African countries suggest a wider distribution. Here, we report the detection and isolation of WSLV from an Aedes mcintoshi mosquito collected in a pristine ecosystem within Semuliki National Park, western Uganda. The detected strain M5937-UG-2018 was impaired in infectivity, replication, and production of infectious particles in cell lines derived from different hosts compared to an epidemic reference strain, SA H177. Full-genome sequencing by next-generation sequencing from the mosquito homogenate revealed a maximum nucleotide identity of 98.1% to a WSLV isolate from a human sample collected in South Africa in 1996. M5937-UG-2018 grouped in phylogenetic analyses with strains from South Africa and Senegal. Reconstruction of the temporal and spatial dispersal of WSLV across Africa estimated a likely origin of WSLV in South Africa in the early 19th century and spread in Southern Africa in the following decades. Long-distance movement toward Western and Eastern Africa was modeled to have occurred in the early 21st century. However, displacing the origin of M5937-UG-2018 did not decrease the likelihood of the model supporting the hypothesis that WSLV is widely distributed in Africa.IMPORTANCEWSLV is a neglected mosquito-borne virus causing teratogenicity in ruminants and febrile illness in humans. WSLV is mainly endemic to Southern Africa, but findings in other regions suggest a wider distribution on the continent. Knowledge of the distribution of WSLV is impaired as differential diagnostics are rarely performed in livestock and humans presenting with symptoms compatible with WSLV infection. Our work investigating viral infections in mosquitoes from a remote tropical rainforest region demonstrates that WSLV is endemic in Uganda. The isolated virus was less infective and showed lower replication ability in vitro compared to an epidemic isolate from South Africa. Phylogeographic reconstruction of spatial and temporal movements, along with the displacement of the origin of the newly detected strain , suggests that WSLV may be widely distributed across Africa. Our data show that the geographic distribution of WSLV and its impact on human and animal health are likely underestimated.

Published

2024

9. Mpox global emergency: strengthening African leadership.

Author

Abubakar I, Lutwama J, Kyobutungi C, and Sankoh O

Subjects

Humans, Africa, Emergencies, Global Health, Leadership, Mpox (monkeypox) epidemiology, Mpox (monkeypox) prevention & control

Abstract

Competing Interests: IA reports funding from the European Union under grant agreement no 101046314 and the UK National Institute for Health and Care Research (NIHR) under grant NF-SI-0616–10037. The views and opinions expressed in this Comment are however those of the authors only and do not necessarily reflect those of the European Union or NIHR; neither the European Union nor NIHR the granting authority can be held responsible for them. JL, CK, and OS declare no competing interests.

Published

2024

10. Re-testing as a method of implementing external quality assessment program for COVID-19 real time PCR testing in Uganda.

Author

Okek EJ, Masembe FJ, Kiconco J, Kayiwa J, Amwine E, Obote D, Alele S, Nahabwe C, Were J, Bagaya B, Balinandi S, Lutwama J, and Kaleebu P

Subjects

Humans, Uganda, Real-Time Polymerase Chain Reaction, COVID-19 Testing, Academies and Institutes, COVID-19 diagnosis

Abstract

Background: Significant milestones have been made in the development of COVID19 diagnostics Technologies. Government of the republic of Uganda and the line Ministry of Health mandated Uganda Virus Research Institute to ensure quality of COVID19 diagnostics. Re-testing was one of the methods initiated by the UVRI to implement External Quality assessment of COVID19 molecular diagnostics., Method: participating laboratories were required by UVRI to submit their already tested and archived nasopharyngeal samples and corresponding meta data. These were then re-tested at UVRI using the WHO Berlin protocol, the UVRI results were compared to those of the primary testing laboratories in order to ascertain performance agreement for the qualitative & quantitative results obtained. Ms Excel window 12 and GraphPad prism ver 15 was used in the analysis. Bar graphs, pie charts and line graphs were used to compare performance agreement between the reference Laboratory and primary testing Laboratories., Results: Eleven (11) Ministry of Health/Uganda Virus Research Institute COVID19 accredited laboratories participated in the re-testing of quality control samples. 5/11 (45%) of the primary testing laboratories had 100% performance agreement with that of the National Reference Laboratory for the final test result. Even where there was concordance in the final test outcome (negative or positive) between UVRI and primary testing laboratories, there were still differences in CT values. The differences in the Cycle Threshold (CT) values were insignificant except for Tenna & Pharma Laboratory and the UVRI(p = 0.0296). The difference in the CT values were not skewed to either the National reference Laboratory(UVRI) or the primary testing laboratory but varied from one laboratory to another. In the remaining 6/11 (55%) laboratories where there were discrepancies in the aggregate test results, only samples initially tested and reported as positive by the primary laboratories were tested and found to be false positives by the UVRI COVID19 National Reference Laboratory., Conclusion: False positives were detected from public, private not for profit and private testing laboratories in almost equal proportion. There is need for standardization of molecular testing platforms in Uganda. There is also urgent need to improve on the Laboratory quality management systems of the molecular testing laboratories in order to minimize such discrepancies., Competing Interests: No authors have any competing interest, (Copyright: © 2024 Okek et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.)

Published

2024