EvolHpylori

Untersuchung der Entwicklungsgeschichte des Magenerregers Helicobacter pylori

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  • Project duration: -
  • Project status: finished
  • Funding:
    Internal funding EURAC (Project)
  • Institute: Institut für Mumienforschung

Ungefähr die Hälfte der Weltbevölkerung ist mit dem Magenkeim Helicobacter pylori infiziert. Durch das weltweite Vorkommen, der hohen Infektionsrate und den virulenten Eigenschaften gilt der Keim als eine der gravierendsten globalen Krankheitserreger der modernen Menschen. Das Bakterium hat den Menschen für tausende von Jahren begleitet und durch seine hohe genetische Variabilität und vertikale übertragung spiegelt seine Populationsgenetik die Geschichte der menschlichen Migration wider. In dem geplanten Projekt werden wir antike H. pylori Stämme aus der ganzen Welt untersuchen, um die Evolution dessen Genoms, Veränderungen in der Virulenz und ihre Populationsgeschichte besser zu verstehen.

Wir werden neue, molekulare Methoden, die die genomische Heliobacter DNS für die Next Generation Sequenzierung (NGS) anreichert, mit innovativen Instrumenten der Bioinformatik kombinieren, um antike Genomsequenzen für weitere vergleichende Sequenzanalysen zu gewinnen. Unsere aktuelle Studie über H. pylori in ötzi, einem 5300 Jahre alten mumifizierten Individuum aus der Kupferzeit, lieferte wichtige Details über eine mögliche Krankheitsmanifestation in der Mumie und der Herkunft von pathogenen Magenbakterien in Europa. Die wissenschaftliche Kompetenz, die in der ötzi-Studie erworben wurde, wird sich für das aktuelle interdisziplinäre Projekt, das die Rekonstruktion von antiken H. pylori Genomen aus verschieden Zeiten und Teilen der Welt zum Ziel hat, als nützlich erweisen. Unsere antiken genomischen Daten werden wichtige Details über das Vorkommen und die Ausbreitung der H. pylori Populationen in Europa, Afrika, Amerika und Asien hervorbringen. Insgesamt werden wir einzigartige Einblicke in die genetische Evolution des Magenkeims H. pylori gewinnen.

Description of the overall project:

The stomach bacterium Helicobacter pylori is one of the most prevalent human pathogens. It has dispersed globally with its human host, resulting in a distinct phylogeographic pattern that can be used to reconstruct both recent and ancient human migrations (Falush et al. 2003, Linz et al. 2007, Moodley et al. 2012).

The extant European population of H. pylori (hpEurope) is known to be a hybrid between Asian and African bacteria. However, the precise hybridization zone of the parental populations and the true origin of hpEurope are currently discussed controversially. Ancient DNA analysis can help to resolve such difficult demographic questions. Recently, we reconstructed the 5,300 year old H. pylori genome of the Iceman, a European Copper age individual. Our results provided important details on a possible disease manifestation in the mummy and the origin of the stomach pathogen in Europe (Maixner et al., 2016). The application of technological and conceptual advances in the Iceman study has paved the way for future studies on H. pylori in ancient human remains and provides a solid methodological platform for this proposal.

The present project aims to bring together different scientific expertise such as anthropology, molecular biology, and bioinformatics and populations genetics to illuminate the evolutionary history of H. pylori on the European continent and in various other parts of the world. The methodological approach will follow our protocols that were established in the framework of the Iceman stomach project (legge 14 project no. 1/40.3 of the 23rd of November 2012), including DNA capture enrichment, NGS sequencing and bioinformatics analysis (genome reconstruction, population genetics). In the first part of the project, we intend to reconstruct in more detail the onset and spread of the H. pylori population found in most Europeans today by analyzing ancient coprolite and dental calculus that were identified as H. pylori reservoirs. Especially our diachronic approach with sample material starting from the Neolithic onwards from various sites (Italy, Austria, Switzerland, Hungary, and Germany) will allow us to identify crucial points in the complex demographic history of Europe that shaped modern European H. pylori genomes. In the second part of this project we will focus on the analysis of selected mummified human gut contents from various sites outside the European continent. Based on our publication of the Iceman´s H. pylori in Science early this year, we have contacted several colleagues and got access to intestinal contents of precious mummies from different parts of the world. Thereby, we were able to retrieve sample material that include gut contents of pre-Columbian mummies from Middle and South America, Egyptian mummies from different dynasties and very well preserved gut content of Korean mummies. Our analysis of ancient H. pylori strains in these mummies will provide important insights into the presence of the stomach pathogen in different geographic regions and time periods and elucidate the worldwide spread and evolution using H. pylori genomics. Moreover, it has the potential to gain additional information on the effects of prehistoric peopling events, such as from Polynesia and Africa on the New World before European contacts, the reconstruction of the demographic history of ancient Egypt and the Korean peninsula and the Japanese archipelago using a preexisting reference database of strains from these regions.

Overall, our ancient Helicobacter genomes sequence data from all over the world offers the opportunity to significantly contribute to our understanding of the basic biology and evolution of this important stomach pathogen and will add subsequently an additional chapter to the human demographic history from a bacterial point of view.

Description of the subproject – Principal Applicants

The ancient DNA laboratory at the EURAC Institute for Mummies and the Iceman in Bolzano represents the intersection between paleopathological and modern molecular analyses and thus provides an excellent basis to perform cutting-edge paleomicrobiology research. All sample preparations and DNA-extractions will be performed in a dedicated pre-PCR area following strict procedures required for studies of ancient DNA. The anthropological section of the Iceman institute and their worldwide cooperation partners will support the study with selected ancient gut contents, coprolite and dental calculus material from the Neolithic onwards. One focus of our study will be on specimens from periods of major cultural changes in Europe such as the Bronze Age and the medieval time (Allentoft et al., 2015). Furthermore, we will analyze intestinal contents from precious historical mummies from the American, African and Asian continent. During this project, we will conduct selected, well-preserved material to a novel innovative molecular approach aiming to reconstruct ancient H. pylori genomes. Therefore, we are planning to first enrich Helicobacter genomic DNA using a hybrid selection technique followed by a massively-parallel sequencing of the sample. Thereby generated ancient genome sequences will be unique milestones in the prediction of the evolutionary history of H. pylori in Europe and other parts of the world.

 

Description of the subproject – External Partner 1

The power of modern molecular biology methods for studying ancient remains, coupled with the increasing repertoire of advanced data analysis approaches in computational biology, has triggered novel interdisciplinary research linking these two areas. The DNA-based methodologies will produce enormous amounts of data, which have to be sorted, processed and analyzed by various bioinformatics means. Throughout the project, there will be an intense collaboration with our cooperation partner Prof. Thomas Rattei (University of Vienna, Austria). His institute will provide the necessary bioinformatics support and specialized software to carry out ancient metagenome analysis, comparative genomics, high performance computing, automated large-scale sequence analysis and annotation tools. In a first phase, the read quality will be assessed and after trimming, filtering and merging of reads the sequences will be taxonomically and functionally assigned using various well-established software tools. In particular, Rattei´s group will characterize the virulence factors present in the ancient H. pylori and they will check for antibiotic resistance mutations in strains predating the antibiotic era.

 

Description of the subproject – External Partner 2

To reconstruct the population genetic history of H. pylori, we will assign ancient strains to modern H. pylori populations using population genetics methods. Prof. Yoshan Moodley (University of Venda, South Africa) will perform the analysis using both multilocus sequence typing (MLST) and whole genome population genetics, analyze both ancient and modern strains for signals of admixture and pinpoint the contributing populations using an available reference data set of over 1000 H. pylori strains from across the world. Our diachronic approach that makes use of several strains from slightly different times will allow the reconstruction of demographic processes using coalescent modeling and a simulated applied Bayesian computation (ABC) approach. To further increase the power of resolution of our whole-genome comparative analysis additional 500 extant H. pylori strains from Europe, Africa, Asia and America will be subjected to whole-genome sequences. Comparing ancient H. pylori genomes of different times with this extended modern dataset can provide important insights into even slight evolutionary changes in the pathogen genome on a continental scale.

 

Innovative aspects of the proposed project

The two following aspects make this project unique in the field of life science and will give us the opportunity to study fundamental evolutionary questions in Helicobacter research. For the first time in paleomicrobiology such a large worldwide collection of ancient human remains from different time periods will be screened for H. pylori cases. In an unprecedented extend Helicobacter strain typing data will be linked to the anthropological result to infer occurrence and epidemic spread of the stomach pathogen. Highlight of this project will be the reconstruction of H. pylori genomes by using an innovative sequence-capture sequencing approach. Ancient Helicobacter genomes sequence data will highly contribute to our understanding of the basic biology of the stomach pathogen and will herald a new era in paleomicrobiology.

 

Essential collaborative elements for the project

Our intercontinental multidisciplinary team including a microbiologist, a bioinformatics and an evolutionary biologist displays a unique combination of different scientific expertise in the field of life sciences. There will be a close cooperation between the principal applicant and the other two applicants to adapt all molecular assays to the special demands of ancient DNA. Thereby obtained data will be continuously linked to the anthropological factors provided by the principal applicant´s group such as the nutritional state, signs for urbanization and the family context in order to capture the ancient social and epidemiological aspects of Helicobacter pylori infection. Thus, there will be frequent exchange between all partners and only the sum of all obtained results will make it possible to infer evolutionary scenarios.

 

Key references related to the project

 

Falush, D. et al. (2003). "Traces of human migrations in Helicobacter pylori populations." Science 299(5612): 1582-1585.

Linz, B. et al. (2007). "An African origin for the intimate association between humans and Helicobacter pylori." Nature 445(7130): 915-918.

Moodley, Y. et al. (2012). "Age of the association between Helicobacter pylori and man." PLoS Pathogens 8(5): e1002693.

Maixner, F. et al. (2016). "The 5300-year-old Helicobacter pylori genome of the Iceman." Science 351(6269): 162-165.

Allentoft, M. E. et al. (2015). "Population genomics of Bronze Age Eurasia." Nature 522(7555): 167-172.

 

 

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  • Centre for Translational Microbiome Research (CTMR), Karolinska Institute, Stockholm, Sweden

  • University of Vienna, CUBE - Division of Computational Systems Biology, Department of Microbiology ...

  • University of Venda, Department of Zoology

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