Your search keyword '"Richard G. Jarman"' showing total 9 results

1. Precision Tracing of Household Dengue Spread Using Inter- and Intra-Host Viral Variation Data, Kamphaeng Phet, Thailand

Author

Irina Maljkovic Berry, Melanie C. Melendrez, Simon Pollett, Katherine Figueroa, Darunee Buddhari, Chonticha Klungthong, Ananda Nisalak, Michael Panciera, Butsaya Thaisomboonsuk, Tao Li, Tyghe G. Vallard, Louis Macareo, In-Kyu Yoon, Stephen J. Thomas, Timothy Endy, and Richard G. Jarman

Subjects

arboviruses, viruses, dengue, transmission chains, intra-host variants, inter-host variants, Medicine, Infectious and parasitic diseases, RC109-216

Abstract

Dengue control approaches are best informed by granular spatial epidemiology of these viruses, yet reconstruction of inter- and intra-household transmissions is limited when analyzing case count, serologic, or genomic consensus sequence data. To determine viral spread on a finer spatial scale, we extended phylogenomic discrete trait analyses to reconstructions of house-to-house transmissions within a prospective cluster study in Kamphaeng Phet, Thailand. For additional resolution and transmission confirmation, we mapped dengue intra-host single nucleotide variants on the taxa of these time-scaled phylogenies. This approach confirmed 19 household transmissions and revealed that dengue disperses an average of 70 m per day between households in these communities. We describe an evolutionary biology framework for the resolution of dengue transmissions that cannot be differentiated based on epidemiologic and consensus genome data alone. This framework can be used as a public health tool to inform control approaches and enable precise tracing of dengue transmissions.

Published

2021

2. Human Adenovirus Type 55 Distribution, Regional Persistence, and Genetic Variability

Author

Jun Hang, Adriana E. Kajon, Paul C. F. Graf, Irina Maljkovic Berry, Yu Yang, Mark A. Sanborn, Christian K. Fung, Anima Adhikari, Melinda S. Balansay-Ames, Christopher A. Myers, Leonard N. Binn, Richard G. Jarman, Robert A. Kuschner, and Natalie D. Collins

Subjects

adenovirus, acute respiratory disease, emerging infectious disease, genetic variation, whole genome sequencing, viruses, Medicine, Infectious and parasitic diseases, RC109-216

Abstract

Human adenovirus type 55 (HAdV-55) causes acute respiratory disease of variable severity and has become an emergent threat in both civilian and military populations. HAdV-55 infection is endemic to China and South Korea, but data from other regions and time periods are needed for comprehensive assessment of HAdV-55 prevalence from a global perspective. In this study, we subjected HAdV-55 isolates from various countries collected during 1969–2018 to whole-genome sequencing, genomic and proteomic comparison, and phylogenetic analyses. The results show worldwide distribution of HAdV-55; recent strains share a high degree of genomic homogeneity. Distinct strains circulated regionally for several years, suggesting persistent local transmission. Several cases of sporadic introduction of certain strains to other countries were documented. Among the identified amino acid mutations distinguishing HAdV-55 strains, some have potential impact on essential viral functions and may affect infectivity and transmission.

Published

2020

3. Whole-Genome Analysis of Bartonella ancashensis, a Novel Pathogen Causing Verruga Peruana, Rural Ancash Region, Peru

Author

Kristin E. Mullins, Jun Hang, Robert J. Clifford, Fatma Onmus-Leone, Yu Yang, Ju Jiang, Mariana Leguia, Matthew R. Kasper, Ciro Maguina, Emil P. Lesho, Richard G. Jarman, Allen L. Richards, and David Blazes

Subjects

Bartonella, bacteria, novel phylogenetic lineage, whole-genome analysis, verruga peruana, rural Ancash region, Medicine, Infectious and parasitic diseases, RC109-216

Abstract

The genus Bartonella contains >40 species, and an increasing number of these Bartonella species are being implicated in human disease. One such pathogen is Bartonella ancashensis, which was isolated in blood samples from 2 patients living in Caraz, Peru, during a clinical trial of treatment for bartonellosis. Three B. ancashensis strains were analyzed by using whole-genome restriction mapping and high-throughput pyrosequencing. Genome-wide comparative analysis of Bartonella species showed that B. ancashensis has features seen in modern and ancient lineages of Bartonella species and is more related to B. bacilliformis. The divergence between B. ancashensis and B. bacilliformis is much greater than what is seen between known Bartonella genetic lineages. In addition, B. ancashensis contains type IV secretion system proteins, which are not present in B. bacilliformis. Whole-genome analysis indicates that B. ancashensis might represent a distinct Bartonella lineage phylogenetically related to B. bacilliformis.

Published

2017

4. Global Distribution of Novel Rhinovirus Genotype

Author

Thomas Briese, Neil Renwick, Marietjie Venter, Richard G. Jarman, Dhrubaa Ghosh, Sophie Köndgen, Sanjaya K. Shrestha, A. Mette Hoegh, Inmaculada Casas, Edgard Valerie Adjogoua, Chantal Akoua-Koffi, Khin Saw Myint, David T. Williams, Glenys R. Chidlow, Ria van den Berg, Cristina Calvo, Orienka Koch, Gustavo Palacios, Vishal Kapoor, Joseph Villari, Samuel R. Dominguez, Kathryn V. Holmes, Gerry Harnett, David W. Smith, John S. MacKenzie, Heinz Ellerbrok, Brunhilde Schweiger, Kristian Schønning, Mandeep S. Chadha, Fabian H. Leendertz, A.C. Mishra, Robert V. Gibbons, Edward C. Holmes, and W. Ian Lipkin

Subjects

picornavirus, rhinovirus, HRV-C, multiplex MassTag PCR, lower respiratory tract infection, childhood pneumonia, Medicine, Infectious and parasitic diseases, RC109-216

Abstract

Global surveillance for a novel rhinovirus genotype indicated its association with community outbreaks and pediatric respiratory disease in Africa, Asia, Australia, Europe, and North America. Molecular dating indicates that these viruses have been circulating for at least 250 years.

Published

2008

5. Diversity and Origin of Dengue Virus Serotypes 1, 2, and 3, Bhutan

Author

Tandin Dorji, In-Kyu Yoon, Edward C. Holmes, Sonam Wangchuk, Tashi Tobgay, Ananda Nisalak, Piyawan Chinnawirotpisan, Kanittha Sangkachantaranon, Robert V. Gibbons, and Richard G. Jarman

Subjects

Dengue, Bhutan, Nepal, phylogeny, emergence, serotypes, Medicine, Infectious and parasitic diseases, RC109-216

Abstract

To determine the serotype and genotype of dengue virus (DENV) in Bhutan, we conducted phylogenetic analyses of complete envelope gene sequences. DENV-2 (Cosmopolitan genotype) predominated in 2004, and DENV-3 (genotype III) predominated in 2005–2006; these viruses were imported from India. Primary dengue infections outnumbered secondary infections, suggesting recent emergence.

Published

2009

6. Identification of All Dengue Serotypes in Nepal

Author

Sarala Malla, Garib D. Thakur, Sanjaya K. Shrestha, Manas K. Banjeree, Laxmi B. Thapa, Gyanendra Gongal, Prakash Ghimire, Bishnu P. Upadhyay, Purosotam Gautam, Shyam Khanal, Ananda Nisaluk, Richard G. Jarman, and Robert V. Gibbons

Subjects

dengue, Nepal, Aedes, serotype, PCR, ELISA, Medicine, Infectious and parasitic diseases, RC109-216

Published

2008

7. Human Adenovirus Type 55 Distribution, Regional Persistence, and Genetic Variability

Author

Richard G. Jarman, Natalie D. Collins, Anima Adhikari, Christian K. Fung, Mark A. Sanborn, Yu Yang, Paul C. F. Graf, Melinda S. Balansay-Ames, Christopher A. Myers, Adriana E. Kajon, Robert A. Kuschner, Irina Maljkovic Berry, Jun Hang, and Leonard N. Binn

Subjects

Microbiology (medical), Proteomics, China, Epidemiology, 030231 tropical medicine, lcsh:Medicine, Biology, Persistence (computer science), lcsh:Infectious and parasitic diseases, Adenovirus Infections, Human, acute respiratory disease, 03 medical and health sciences, 0302 clinical medicine, Genetic variation, Republic of Korea, Humans, viruses, lcsh:RC109-216, 030212 general & internal medicine, Genetic variability, Respiratory Tract Infections, Phylogeny, Genetics, Infectivity, Whole genome sequencing, whole genome sequencing, Phylogenetic tree, Transmission (medicine), Adenoviruses, Human, Research, lcsh:R, virus diseases, adenovirus, emerging infectious disease, United States, eye diseases, Infectious Diseases, DNA, Viral, genetic variation, Emerging infectious disease, Human Adenovirus Type 55 Distribution, Regional Persistence, and Genetic Variability

Abstract

Human adenovirus type 55 (HAdV-55) causes acute respiratory disease of variable severity and has become an emergent threat in both civilian and military populations. HAdV-55 infection is endemic to China and South Korea, but data from other regions and time periods are needed for comprehensive assessment of HAdV-55 prevalence from a global perspective. In this study, we subjected HAdV-55 isolates from various countries collected during 1969-2018 to whole-genome sequencing, genomic and proteomic comparison, and phylogenetic analyses. The results show worldwide distribution of HAdV-55; recent strains share a high degree of genomic homogeneity. Distinct strains circulated regionally for several years, suggesting persistent local transmission. Several cases of sporadic introduction of certain strains to other countries were documented. Among the identified amino acid mutations distinguishing HAdV-55 strains, some have potential impact on essential viral functions and may affect infectivity and transmission.

Published

2020

8. Whole-Genome Analysis of Bartonella ancashensis, a Novel Pathogen Causing Verruga Peruana, Rural Ancash Region, Peru

Author

Jun Hang, Kristin E. Mullins, Fatma Onmus-Leone, Robert J. Clifford, Mariana Leguia, Yu Yang, Allen L. Richards, Richard G. Jarman, Ju Jiang, Ciro Maguiña, David L. Blazes, Emil Lesho, and Matthew R. Kasper

Subjects

Male, 0301 basic medicine, rural Ancash region, Epidemiology, lcsh:Medicine, population, medicine.disease_cause, Bartonella bacilliformis, hemic and lymphatic diseases, Peru, Whole-Genome Analysis of Bartonellaancashensis, a Novel Human Pathogen Causing Verruga Peruana, Rural Ancash Region, Peru, bacilliformis, Child, bacteria, Phylogeny, education.field_of_study, bartonellosis, Middle Aged, verruga peruana, Infectious Diseases, Bartonella ancashensis, Child, Preschool, endocarditis, Female, Bartonella, Bartonella Infection, Adult, Microbiology (medical), Adolescent, Population, Immunology, Biology, purl.org/pe-repo/ocde/ford#3.03.08 [https], lcsh:Infectious and parasitic diseases, diversity, Young Adult, 03 medical and health sciences, Verruga peruana, Bartonella Infections, medicine, Humans, lcsh:RC109-216, bacteremia, education, whole-genome analysis, Bartonellosis, Research, lcsh:R, Infant, natural-history, Carrion's disease, medicine.disease, biology.organism_classification, bacterial infections and mycoses, Virology, infection, 030104 developmental biology, quintana, novel phylogenetic lineage, Genome, Bacterial

Abstract

The genus Bartonella contains >40 species, and an increasing number of these Bartonella species are being implicated in human disease. One such pathogen is Bartonella ancashensis, which was isolated in blood samples from 2 patients living in Caraz, Peru, during a clinical trial of treatment for bartonellosis. Three B. ancashensis strains were analyzed by using whole-genome restriction mapping and high-throughput pyrosequencing. Genome-wide comparative analysis of Bartonella species showed that B. ancashensis has features seen in modern and ancient lineages of Bartonella species and is more related to B. bacilliformis. The divergence between B. ancashensis and B. bacilliformis is much greater than what is seen between known Bartonella genetic lineages. In addition, B. ancashensis contains type IV secretion system proteins, which are not present in B. bacilliformis. Whole-genome analysis indicates that B. ancashensis might represent a distinct Bartonella lineage phylogenetically related to B. bacilliformis.

Published

2017

9. Identification of All Dengue Serotypes in Nepal

Author

Sanjaya K. Shrestha, Richard G. Jarman, Purosotam Gautam, S Malla, Garib Das Thakur, Prakash Ghimire, Gyanendra Gongal, Ananda Nisaluk, Shyam Prasad Khanal, Laxmi Bikram Thapa, Bishnu Prasad Upadhyay, Manas K. Banjeree, and Robert V. Gibbons

Subjects

Microbiology (medical), Adult, Male, Veterinary medicine, Aedes albopictus, Adolescent, Epidemiology, letter, lcsh:Medicine, Dengue virus, medicine.disease_cause, Dengue fever, lcsh:Infectious and parasitic diseases, Nepal, Aedes, medicine, Animals, Humans, lcsh:RC109-216, serotype, Serotyping, Letters to the Editor, Child, Aged, Molecular Epidemiology, biology, Transmission (medicine), business.industry, lcsh:R, Outbreak, Japanese encephalitis, Dengue Virus, Middle Aged, medicine.disease, biology.organism_classification, dengue, Insect Vectors, Infectious Diseases, PCR, Child, Preschool, ELISA, Female, business, Malaria

Abstract

To the Editor: Nepal is situated on the southern slopes of the Himalayas, surrounded by India on 3 sides and China to the north. Nepal’s altitude ranges from 8,848 m in the Himalayas to 90 m in the Terai, the southern, low, flatland bordering India. Nepal is a disease-endemic area for many vector-borne diseases, including malaria, kala-azar, Japanese encephalitis, and lymphatic filariasis. Because of the porous border between Nepal and India, social, cultural, and economic activities in cross-border areas are common. Dengue is an emerging disease in Nepal; presumably transmission is moving north from India into the Terai (1–5). The first report of dengue virus isolation or RNA (serotype 2 with nucleotide homology closest to a dengue virus type 2 isolate from India) was in 2008 involving a Japanese patient returning from Nepal in October 2004 (5). Entomologic investigations from the 1980s showed Aedes albopictus in the Terai plains, but Ae. aegypti has not been previously reported. After Indian outbreaks now known to include all 4 dengue serotypes (6), a team from the Epidemiology and Disease Control Division, Kathmandu, investigated suspected cases of dengue fever during September–October 2006 in Banke, the district bordering Uttar Pradesh, India. The team collected blood samples from persons in Banke and, subsequently, from persons in a number of other districts and sent them to the National Public Health Laboratory in Kathmandu or the Armed Forces Research Institute of Medical Sciences, Bangkok, Thailand for analysis with ELISA, reverse transcription–PCR, (RT-PCR), or both. Case definitions for dengue fever were adopted based on World Health Organization guidelines (7). Blood samples were obtained from patients with an acute febrile illness of 2–7 days’ duration and with >2 of the following manifestations: headache, retro-orbital pain, muscular or joint pain, and rash. If laboratory tests were positive, cases were confirmed. Results were confirmed by ELISA performed at the Armed Forces Research Institute of Medical Sciences as previously described (8). Positive results were immunoglobulin (Ig) M >40 units or IgG >100 units. RT-PCR was performed by extracting RNA from 140 μL of each serum sample using QIAGEN Viral RNA Extraction Kit per manufacturer’s instructions (QIAGEN, Germantown, MD, USA). RT-PCR and nested PCR were conducted according to the Lanciotti protocol (9) with the following modifications. Reverse transcriptase from avian myeloblastosis virus (Promega, Madison, WI, USA) was used in the first round RT-PCR. The concentrations of the primers used in the RT-PCR and nested reactions were reduced from 50 pmol to 12.5 pmol per reaction, and the number of nested PCR amplification cycles was increased to 25. Serum specimens were obtained from 70 suspected case-patients from 16 districts from October 13 through December 3, 2006; 25 confirmed cases (13 by ELISA, 10 by RT-PCR, and 2 by both tests) came from 9 districts (Table). The average age was 29 years (range 5–65 years); 80% of the case-patients were men. Three patients had a history of travel to India, but clusters of dengue fever cases reported in October (Banke and Dang districts) indicated local transmission was occurring among patients with no travel history. The Terai districts accounted for 80% of cases. Entomologic collections done indoors and outside at 5 different sites reporting suspected cases identified Ae. albopictus and Ae. aegypti in all 5 districts. Table Dengue laboratory test results, National Public Health Laboratory, Nepal, and AFRIMS, Bangkok, 2006* These clinical and laboratory test results confirmed the presence of all 4 dengue serotypes. Notably, patients from the Dang district had no travel history outside the Dang valley. Because Aedes spp. have been identified in Dang, the data strongly suggest the existence of an endemic cycle of dengue. Underreporting is expected in the absence of diagnostic facilities at the field level. It is unclear whether the predominance of male patients is indicative of greater outdoor as opposed to indoor transmission. Of note, Ae. albopictus has been found in the country since the 1980s; in this study, we found Ae. aegypti in Nepal. Men typically wear short-sleeved clothes due to hot and humid conditions and, therefore, are frequently exposed to mosquito bites. However, men may also access the healthcare system more frequently. The ages of case-patients point to a relative lack of dengue immunity among the older population, and this finding is consistent with a new introduction of dengue. Because dengue hemorrhagic fever appears when >1 serotype becomes endemic to an area (10), the presence of all 4 serotypes portends the emergence of more severe dengue disease in Nepal.

Published

2008