Haitian cholera genome decoded and identified as South Asian strain

21 Dec 2010

Scientists from Pacific Biosciences of California, Inc. and Harvard Medical School have successfully employed single molecule, real-time (SMRT) DNA sequencing technology to rapidly characterize the pathogen responsible for the recent deadly cholera epidemic in Haiti.

Published online in the New England Journal of Medicine, the results provide the first whole genome sequence analysis and most detailed genetic profile to date of the Haitian Vibrio cholerae outbreak strain.

The multi-strain sequencing and bioinformatic analysis confirm that the cholera pathogen now present in Haiti is closely related to the “El Tor O1” variant from South Asia. Given that the existence of this strain has never been documented in the Caribbean region or throughout Latin America, the evidence suggests that the Haitian epidemic began as a result of the introduction of a new strain from a distant geographic source. While the sequence analysis confirms a South Asian lineage, it does not identify the specific source of the Haitian strain or suggest how it may have arrived in the country.

In this collaboration, DNA prepared from five V. cholerae strains at Harvard Medical School was received at Pacific Biosciences on Wednesday, November 10, 2010.

“Through the truly remarkable and dedicated efforts of Dr. Schadt and his colleagues at PacBio, we had a good understanding of the genome of the Haitian V. cholerae isolates and their likely origin by Friday evening, November 12,” said John Mekalanos, PhD, Chair of the Department of Microbiology and Molecular Genetics at Harvard Medical School, a senior author on the study. “This understanding has important public health policy implications for preventing cholera outbreaks in the future.”

Members of a team led by Stephen Calderwood, M.D., Chief of the Division of Infectious Diseases at Massachusetts General Hospital and Morton N. Swartz M.D. Academy Professor of Medicine (Microbiology and Molecular Genetics) at Harvard Medical School, recently returned from working alongside public health experts in Haiti where they collected samples for the study in cooperation with Haitian collaborators.

“Witnessing the scale of human suffering caused by the rapidly progressing cholera outbreak, our team was compelled to deploy a technology that could immediately provide comprehensive genomic information about this virulent strain and quickly get it into the hands of the global health and research community,” said Jason Harris, M.D., Physician, Pediatric Infectious Disease Unit at Massachusetts General Hospital and Assistant Professor of Pediatrics at Harvard Medical School.

“In the initial stages of a major epidemic, real time is the speed we need to be working in order to have the greatest impact on saving lives.”

Whole-genome sequencing involves decoding the precise order of nucleotide bases that make up an organism's complete set of DNA and provides more comprehensive information than other analysis methods such as DNA fingerprinting or arrays.

With advances in technology and decreasing cost, whole genome sequencing is emerging as the gold standard method for identifying and classifying infectious agents. SMRT technology is the latest advance in DNA sequencing, capable of generating long sequence reads to resolve structural variations and complex genomes at ultra-fast speeds by ‘eavesdropping’ on DNA replicating in real time.

“Now armed with a more complete characterization of this pathogen, the scientific community is empowered with information that can be used to inform public health policy decisions such as the appropriate use of vaccines to quell this epidemic,” said Eric Schadt, Ph.D., Chief Scientific Officer of Pacific Biosciences and co-author of the paper.

“The ability to quickly and easily perform real-time monitoring of pathogens also opens the door to using this technology as a routine surveillance method, for public health protection in addition to pandemic prevention and response.”

To obtain a comprehensive genomic characterization of the origin of the Haitian cholera pathogen, the PacBio/Harvard team sequenced two samples from the current Haiti outbreak, two samples from South Asia (Bangladeshi isolates from 1971 and 2008), and one sample from Latin America (a 1991 Peruvian isolate). The team then compared this high resolution whole genome sequence information to DNA sequence information available in public databases for 23 diverse strains of V. cholerae.

Real-time infectious disease monitoring is featured in a new documentary film that was produced by Pacific Biosciences called “The New Biology.” The film profiles how new technologies are leading to advances in cancer, infectious diseases, and agriculture.

To view the infectious disease segment, visit http://www.pacificbiosciences.com/newbio

 

To top