Your search keyword '"Sulochana Putil Bai"' showing total 2 results

1. Genomic analysis unveils genome degradation events and gene flux in the emergence and persistence of S. Paratyphi A lineages.

Author

Jobin John Jacob, Agila K Pragasam, Karthick Vasudevan, Aravind Velmurugan, Monisha Priya Teekaraman, Tharani Priya Thirumoorthy, Pallab Ray, Madhu Gupta, Arti Kapil, Sulochana Putil Bai, Savitha Nagaraj, Karnika Saigal, Temsunaro Rongsen Chandola, Maria Thomas, Ashish Bavdekar, Sheena Evelyn Ebenezer, Jayanthi Shastri, Anuradha De, Shantha Dutta, Anna P Alexander, Roshine Mary Koshy, Dasaratha R Jinka, Ashita Singh, Sunil Kumar Srivastava, Shalini Anandan, Gordon Dougan, Jacob John, Gagandeep Kang, Balaji Veeraraghavan, and Ankur Mutreja

Subjects

Immunologic diseases. Allergy, RC581-607, Biology (General), QH301-705.5

Abstract

Paratyphoid fever caused by S. Paratyphi A is endemic in parts of South Asia and Southeast Asia. The proportion of enteric fever cases caused by S. Paratyphi A has substantially increased, yet only limited data is available on the population structure and genetic diversity of this serovar. We examined the phylogenetic distribution and evolutionary trajectory of S. Paratyphi A isolates collected as part of the Indian enteric fever surveillance study "Surveillance of Enteric Fever in India (SEFI)." In the study period (2017-2020), S. Paratyphi A comprised 17.6% (441/2503) of total enteric fever cases in India, with the isolates highly susceptible to all the major antibiotics used for treatment except fluoroquinolones. Phylogenetic analysis clustered the global S. Paratyphi A collection into seven lineages (A-G), and the present study isolates were distributed in lineages A, C and F. Our analysis highlights that the genome degradation events and gene acquisitions or losses are key molecular events in the evolution of new S. Paratyphi A lineages/sub-lineages. A total of 10 hypothetically disrupted coding sequences (HDCS) or pseudogenes-forming mutations possibly associated with the emergence of lineages were identified. The pan-genome analysis identified the insertion of P2/PSP3 phage and acquisition of IncX1 plasmid during the selection in 2.3.2/2.3.3 and 1.2.2 genotypes, respectively. We have identified six characteristic missense mutations associated with lipopolysaccharide (LPS) biosynthesis genes of S. Paratyphi A, however, these mutations confer only a low structural impact and possibly have minimal impact on vaccine effectiveness. Since S. Paratyphi A is human-restricted, high levels of genetic drift are not expected unless these bacteria transmit to naive hosts. However, public-health investigation and monitoring by means of genomic surveillance would be constantly needed to avoid S. Paratyphi A serovar becoming a public health threat similar to the S. Typhi of today.

Published

2023

2. Genomic analysis unveils the role of genome degradation events and gene flux in the emergence and persistence ofS. Paratyphi A lineages

Author

Jobin John Jacob, Agila K Pragasam, Karthick Vasudevan, Aravind V, Monisha Priya T, Tharani Priya T, Pallab Ray, Madhu Gupta, Arti Kapil, Sulochana Putil Bai, Savitha Nagaraj, Karnika Saigal, Temsunaro Rongsen Chandola, Maria Thomas, Ashish Bavdekar, Sheena Evelyn Ebenezer, Jayanthi Shastri, Anuradha De, Shantha Dutta, Anna P Alexander, Roshine Mary Koshy, Dasaratha R Jinka, Ashita Singh, Sunil Kumar Srivastava, Shalini Anandan, Gordon Dougan, Jacob John, Gagandeep Kang, Balaji Veeraraghavan, and Ankur Mutreja

Abstract

Paratyphoid fever caused byS. Paratyphi A is endemic in parts of Asia and Sub-Saharan Africa. The proportion of enteric fever cases caused byS. Paratyphi A has substantially increased, yet only limited data is available on the population structure and genetic diversity of this serovar. We examined the phylogenetic distribution and evolutionary trajectory ofS. Paratyphi A isolates collected as part of the Indian enteric fever surveillance study “Surveillance of Enteric Fever in India (SEFI).” In the study period (2017-2020),S. Paratyphi A comprised 17.6% (441/2503) of total enteric fever cases in India, with the isolates highly susceptible to all the major antibiotics used for treatment except fluoroquinolones. Phylogenetic analysis clustered the globalS. Paratyphi A collection into seven lineages (A-G), and the present study isolates were distributed in lineages A, C and F. Our analysis documented that the genome degradation events and gene acquisitions or losses play a major role in the evolution of newS. Paratyphi A lineages/sub-lineages. A total of 10 pseudogene-forming mutations possibly associated with the emergence of lineages were identified. Pan-genome analysis identified the insertion of P2/PSP3 phage and acquisition of IncX1 plasmid during the selection in 2.3.2/2.3.3 and 1.2.2 genotypes, respectively. We also identified that the six characteristic missense mutations associated with the lipopolysaccharide (LPS) biosynthesis genes ofS. Paratyphi A confer only a low structural impact and would therefore have minimal impact on vaccine effectiveness. SinceS. Paratyphi A is human restricted, high levels of genetic drift are not expected unless these bacteria transmit to naive hosts. However, public-health investigation and intervention by means of genomic surveillance would be continually needed to avoidS. Paratyphi A serovar becoming a public health threat similar to theS. Typhi of today.

Published

2022