Archival, paleopathological and aDNA-based techniques in leprosy research and the case of Father Petrus Donders at the Leprosarium 'Batavia', Suriname.

OBJECTIVE: We assessed whether Petrus Donders (died 1887), a Dutch priest who for 27 years cared for people with leprosy in the leprosarium Batavia, Suriname, had evidence of Mycobacterium (M.) leprae infection. A positive finding of M. leprae ancient (a)DNA would contribute to the origin of leprosy in Suriname. MATERIALS: Skeletal remains of Father Petrus Donders; two additional skeletons excavated from the Batavia cemetery were used as controls. METHODS: Archival research, paleopathological evaluation and aDNA-based testing of skeletal remains. RESULTS: Neither archives nor inspection of Donders skeletal remains revealed evidence of leprosy, and aDNA-based testing for M. leprae was negative. We detected M. leprae aDNA by RLEP PCR in one control skeleton, which also displayed pathological lesions compatible with leprosy. The M. leprae aDNA was genotyped by Sanger sequencing as SNP type 4; the skeleton displayed mitochondrial haplogroup L3. CONCLUSION: We found no evidence that Donders contracted leprosy despite years of intense leprosy contact, but we successfully isolated an archaeological M. leprae aDNA sample from a control skeleton from South America. SIGNIFICANCE: We successfully genotyped recovered aDNA to a M. leprae strain that likely originated in West Africa. The detected human mitochondrial haplogroup L3 is also associated with this geographical region. This suggests that slave trade contributed to leprosy in Suriname. LIMITATIONS: A limited number of skeletons was examined. SUGGESTIONS FOR FURTHER RESEARCH: Broader review of skeletal collections is advised to expand on diversity of the M. leprae aDNA database.

Paleomicrobiology: Diagnosis and Evolution of Ancient Pathogens.

The last century has witnessed progress in the study of ancient infectious disease from purely medical descriptions of past ailments to dynamic interpretations of past population health that draw upon multiple perspectives. The recent adoption of high-throughput DNA sequencing has led to an expanded understanding of pathogen presence, evolution, and ecology across the globe. This genomic revolution has led to the identification of disease-causing microbes in both expected and unexpected contexts, while also providing for the genomic characterization of ancient pathogens previously believed to be unattainable by available methods. In this review we explore the development of DNA-based ancient pathogen research, the specialized methods and tools that have emerged to authenticate and explore infectious disease of the past, and the unique challenges that persist in molecular paleopathology. We offer guidelines to mitigate the impact of these challenges, which will allow for more reliable interpretations of data in this rapidly evolving field of investigation.

Possible cases of leprosy from the Late Copper Age (3780-3650 cal BC) in Hungary.

At the Abony-Turjányos dulo site, located in Central Hungary, a rescue excavation was carried out. More than 400 features were excavated and dated to the Protoboleráz horizon, at the beginning of the Late Copper Age in the Carpathian Basin, between 3780-3650 cal BC. Besides the domestic and economic units, there were two special areas, with nine-nine pits that differed from the other archaeological features of the site. In the northern pit group seven pits contained human remains belonging to 48 individuals. Some of them were buried carefully, while others were thrown into the pits. The aim of this study is to present the results of the paleopathological and molecular analysis of human remains from this Late Copper Age site. The ratio of neonates to adults was high, 33.3%. Examination of the skeletons revealed a large number of pathological cases, enabling reconstruction of the health profile of the buried individuals. Based on the appearance and frequency of healed ante- and peri mortem trauma, inter-personal (intra-group) violence was characteristic in the Abony Late Copper Age population. However other traces of paleopathology were observed on the bones that appear not to have been caused by warfare or inter-group violence. The remains of one individual demonstrated a rare set of bone lesions that indicate the possible presence of leprosy (Hansen's disease). The most characteristic lesions occurred on the bones of the face, including erosion of the nasal aperture, atrophy of the anterior nasal spine, inflammation of the nasal bone and porosity on both the maxilla and the bones of the lower legs. In a further four cases, leprosy infection is suspected but other infections cannot be excluded. The morphologically diagnosed possible leprosy case significantly modifies our knowledge about the timescale and geographic spread of this specific infectious disease. However, it is not possible to determine the potential connections between the cases of possible leprosy and the special burial circumstances.

Paleomicrobiology of Leprosy.

The use of paleomicrobiological techniques in leprosy has the potential to assist paleopathologists in many important aspects of their studies on the bones of victims, solving at times diagnostic problems. With Mycobacterium leprae, because of the unique nature of the organism, these techniques can help solve problems of differential diagnosis. In cases of co-infection with Mycobacterium tuberculosis, they can also suggest a cause of death and possibly even trace the migratory patterns of people in antiquity, as well as explain changes in the rates and level of infection within populations in antiquity.

Paleopathology of Human Infections: Old Bones, Antique Books, Ancient and Modern Molecules.

Paleopathology studies the traces of disease on human and animal remains from ancient times. Infectious diseases have been, for over a century, one of its main fields of interest. The applications of paleogenetics methods to microbial aDNA, that started in the 90s combined to the recent development of new sequencing techniques allowing 'paleogenomics' approaches, have completely renewed the issue of the infections in the past. These advances open up new challenges in the understanding of the evolution of human-pathogen relationships, integrated in "One Health" concept.In this perspective, an integrative multidisciplinary approach combining data from ancient texts and old bones to those of old molecules is of great interest for reconstructing the past of human infections. Despite some too optimistic prediction of their eradication in the late 20th century, some of these ancient human diseases, such as plague, leprosy or tuberculosis, are still present and continue their evolution at the beginning of this 21rst century. Better know the past to predict a part of the future of human diseases remains, more than ever, the motto of the paleopathological science.

Ancient DNA analysis - An established technique in charting the evolution of tuberculosis and leprosy.

Many tuberculosis and leprosy infections are latent or paucibacillary, suggesting a long time-scale for host and pathogen co-existence. Palaeopathology enables recognition of archaeological cases and PCR detects pathogen ancient DNA (aDNA). Mycobacterium tuberculosis and Mycobacterium leprae cell wall lipids are more stable than aDNA and restrict permeability, thereby possibly aiding long-term persistence of pathogen aDNA. Amplification of aDNA, using specific PCR primers designed for short fragments and linked to fluorescent probes, gives good results, especially when designed to target multi-copy loci. Such studies have confirmed tuberculosis and leprosy, including co-infections. Many tuberculosis cases have non-specific or no visible skeletal pathology, consistent with the natural history of this disease. M. tuberculosis and M. leprae are obligate parasites, closely associated with their human host following recent clonal distribution. Therefore genotyping based on single nucleotide polymorphisms (SNPs) can indicate their origins, spread and phylogeny. Knowledge of extant genetic lineages at particular times in past human populations can be obtained from well-preserved specimens where molecular typing is possible, using deletion analysis, microsatellite analysis and whole genome sequencing. Such studies have identified non-bovine tuberculosis from a Pleistocene bison from 17,500 years BP, human tuberculosis from 9000 years ago and leprosy from over 2000 years ago.

Palaeopathology and genes: investigating the genetics of infectious diseases in excavated human skeletal remains and mummies from past populations.

The aim of this paper is to review the use of genetics in palaeomicrobiology, and to highlight the importance of understanding past diseases. Palaeomicrobiology is the study of disease pathogens in skeletal and mummified remains from archaeological contexts. It has revolutionarised our understanding of health in the past by enabling a deeper knowledge of the origins and evolution of many diseases that have shaped us as a species. Bacterial diseases explored include tuberculosis, leprosy, bubonic plague, typhoid, syphilis, endemic and epidemic typhus, trench fever, and Helicobacter pylori. Viral diseases discussed include influenza, hepatitis B, human papilloma virus (HPV), human T-cell lymphotrophic virus (HTLV-1) and human immunodeficiency virus (HIV). Parasitic diseases investigated include malaria, leishmaniasis, Chagas' disease, roundworm, whipworm, pinworm, Chinese liver fluke, fleas and lice. Through a better understanding of disease origins and their evolution, we can place into context how many infectious diseases are changing over time, and so help us estimate how they may change in the future.

PCR primers that can detect low levels of Mycobacterium leprae DNA.

There are several specific PCR-based methods to detect Mycobacterium leprae DNA, but the amplicons are quite large. For example, primers that target the 36-kDa antigen gene and are in common diagnostic use yield a 530-bp product. This may be a disadvantage when examining samples in which the DNA is likely to be damaged and fragmented. Therefore, two sets of M. leprae-specific nested primers were designed, based on existing primer pairs which have been shown to be specific for M. leprae. Primers that targeted the 18-kDa antigen gene gave an outer product of 136 bp and inner product of 110 bp. The primers based on the RLEP repetitive sequence yielded a 129-bp outer product and 99-bp nested product. With dilutions of a standard M. leprae killed whole-cell preparation as the source of DNA, both single-stage and nested PCR were performed after optimisation of the experimental conditions. Compared with the 36-kDa antigen gene primers, the 18-kDa antigen gene outer primers were 100-fold more sensitive and the RLEP outer primers were 1000-fold more sensitive. As an illustration of two possible applications of these new primers, positive results were obtained from three skin slit samples from treated lepromatous leprosy patients and three archaeological samples from human remains showing typical leprosy palaeopathology. It was concluded that these new primers are a useful means of detecting M. leprae DNA which is damaged or present at a very low level.

Detection of leprosy in ancient human skeletal remains by molecular identification of Mycobacterium leprae.

We isolated ancient DNA from skeletal remains obtained from a South German ossuary (approximately 1400-1800 AD) and from a 10th century Hungarian cemetery partially indicating macromorphologic evidence of leprosy. In samples taken of 2 skulls from Germany and of 1 hard palate from Hungary, Mycobacterium leprae-specific fragments of RLEP1 and RLEP3 were amplified using polymerase chain reaction (PCR), thereby confirming their specificity by sequencing. In another case, PCR with primers targeting IS6110 of Mycobacterium tuberculosis gave positive results only for a mandibular specimen. No signal for any mycobacterial DNA was observed in samples from 2 Hungarian foot bones. In ancient material, osseous involvement of M leprae may be detected and distinguished from other mycobacterial infections by specific PCR. In the small bones of leprous hands and feet, not enough M leprae DNA seems to be present for detection. This supports the view that rhinomaxillary leprous alterations result from direct bacterial involvement, while osseous mutilations of hands and feet result from a nervous involvement and/or secondary infections due to small lacerations of the overlying soft tissues.