Post hoc deconvolution of human mitochondrial DNA mixtures by EMMA 2 using fine-tuned Phylotree nomenclature.

In this paper we present a new algorithm for splitting (partial) human mitogenomes into components with high similarity to haplogroup motifs of Phylotree. The algorithm reads a (partial) mitogenome coded by the differences to the reference (rCRS) and outputs the estimated haplogroups of the putative components. The algorithm requires no special information on the raw data of the sequencing process and is therefore suited for the post hoc analysis of mixtures of any sequencing technology. The software EMMA 2 implementing the algorithm will be made available via the EMPOP (https://empop.online) database and extends the nine years old software EMMA for haplogrouping single mitogenomes to mixtures with at most three components.

Fine-Tuning Phylogenetic Alignment and Haplogrouping of mtDNA Sequences.

In this paper, we present a new algorithm for alignment and haplogroup estimation of mitochondrial DNA (mtDNA) sequences. Based on 26,011 vetted full mitogenome sequences, we refined the 5435 original haplogroup motifs of Phylotree Build 17 without changing the haplogroup nomenclature. We adapted 430 motifs (about 8%) and added 966 motifs for yet undetermined subclades. In summary, this led to an 18% increase of haplogroup defining motifs for full mitogenomes and a 30% increase for the mtDNA control region that is of interest for a variety of scientific disciplines, such as medical, population and forensic genetics. The new algorithm is implemented in the EMPOP mtDNA database and is freely accessible.

Forensically relevant phylogeographic evaluation of mitogenome variation in the Basque Country.

The Basque Country has been the focus of population (genetic) and evolutionary studies for decades, as it represents an interesting evolutionary feature: it is the only European country where a non-Indo-European language is still spoken today and, for which there are no known living or extinct relatives. Early studies that were based on anatomical and serological methods, along with subsequent molecular genetic investigations, contain controversial interpretations of their data. Additionally, the analysis of mitochondrial DNA, which is maternally inherited and thus suitable for the examination of the maternal phylogeny of the population, was the focus of some studies. Early mtDNA studies were however restricted to the information provided by the control region or its hypervariable segments only. These are known to harbour little phylogenetic information, particularly for haplogroup H that is dominant in Westeurasian populations including the Basques. Later studies analysed complete mitogenome sequences. Their information content is however limited, either because the number of samples was low, or because these studies only considered particular haplogroups. In this study we present the full mitogenome sequences of 178 autochthonous Basque individuals that were carefully selected based on their familial descent and discuss the observed phylogenetic signals in the light of earlier published findings. We confirm the presence of Basque-specific mtDNA lineages and extend the knowledge of these lineages by providing data on their distribution in comparison to other Basque and non-Basque populations. This dataset improves our understanding of the Basque mtDNA phylogeny and serves as a high-quality dataset that is provided via EMPOP for forensic genetic purposes.

Resolving mitochondrial haplogroups B2 and B4 with next-generation mitogenome sequencing to distinguish Native American from Asian haplotypes.

Mitochondrial haplogroup information can be useful in forensic contexts that rely primarily on mitochondrial DNA (mtDNA) testing, which often involve limited or degraded DNA. Due to the phylogeographic patterning of mtDNA in human populations, mitochondrial haplogroups are indicative of maternal ancestry (as mtDNA is a maternally inherited marker). In certain circumstances, maternal ancestry inferred from mitochondrial haplogrouping could be beneficial to forensic investigations. For example, ancestry information could assist in the identification of unknown service members from past conflicts, such as the World War II Battle of Tarawa involving American and Japanese forces. In this context, it could be useful to distinguish Native American mtDNA from Asian mtDNA to bolster the anthropological and circumstantial evidence leading to an identification or foreign national determination. Although most of the founding Native American haplogroups contain diagnostic variants in the mitochondrial control region (CR), haplogroup B2 does not, and this makes it more difficult to distinguish B2 from the parental B4 and closely related B4b haplogroups found in Asia. In this paper, the amount of mtDNA information required to distinguish Native American haplotypes from Asian haplotypes within haplogroup B was examined. Fifty-six samples belonging to subtypes of B2 and B4 were sequenced for the entire mitogenome. Haplogroups were estimated from three ranges of mitochondrial DNA (HV1 and 2, CR, and full mitogenome). Half of the samples could not be precisely haplogrouped without full mitogenome data, although enough variants were often provided to make an accurate B2 versus B4 distinction. Native American B2 haplotypes were distinguishable using CR data alone in 82% of samples, though the remaining samples required full mitogenome data for haplogroup B2 designation. The use of full mitogenome data consistently enables accurate haplogroup determination, and opens the possibility for gaining information on maternal ancestry.

Evaluation of mitogenome sequence concordance, heteroplasmy detection, and haplogrouping in a worldwide lineage study using the Precision ID mtDNA Whole Genome Panel.

The emergence of Massively Parallel Sequencing technologies enabled the analysis of full mitochondrial (mt)DNA sequences from forensically relevant samples that have, so far, only been typed in the control region or its hypervariable segments. In this study, we evaluated the performance of a commercially available multiplex-PCR-based assay, the Precision ID mtDNA Whole Genome Panel (Thermo Fisher Scientific), for the amplification and sequencing of the entire mitochondrial genome (mitogenome) from even degraded forensic specimens. For this purpose, more than 500 samples from 24 different populations were selected to cover the vast majority of established superhaplogroups. These are known to harbor different signature sequence motifs corresponding to their phylogenetic background that could have an effect on primer binding and, thus, could limit a broad application of this molecular genetic tool. The selected samples derived from various forensically relevant tissue sources and were DNA extracted using different methods. We evaluated sequence concordance and heteroplasmy detection and compared the findings to conventional Sanger sequencing as well as an orthogonal MPS platform. We discuss advantages and limitations of this approach with respect to forensic genetic workflow and analytical requirements.

Mitochondrial DNA control region variation in Lebanon, Jordan, and Bahrain.

This study investigated the mitochondrial DNA (mtDNA) control region variation in Middle Eastern populations (610 individuals from Lebanon, Jordan and the Kingdom of Bahrain) for which population data are scarce. FST comparison among populations revealed that there are significant differences in mtDNA distributions between Bahrain and the two other populations, while Lebanon and Jordan showed no significant differences. This was also reflected by the distribution of the observed lineages that differed prominently between Bahrain and the other two investigated populations. Jordan and Lebanon fit the hitherto known genetic results of the Levant population. Data are available via EMPOP (https://empop.online) and GenBank.

The maternal inheritance of Alto Paraná revealed by full mitogenome sequences.

Most studies on maternal lineages of South America populations are restricted to control region (CR) markers and, for some geographical regions, the number of studied samples does not adequately represent the existing diversity. This is the case of mitochondrial DNA (mtDNA) studies on Paraguay that are limited to two Native ethnic groups. To overcome this deficiency, we analysed the mitogenomes from 105 individuals living in Alto Paraná, the second most populated department of the country. Using the Precision ID mtDNA Whole Genome Panel, the molecule was sequenced on Ion S5. The majority of the haplotypes belong to the Native American lineages A, B, C and D. Analyses of maximum parsimony using mitogenome data retrieved from publications and in The 1000 Genomes Project showed a high number of new native American subclades in Paraguay. Also, none of the haplotypes found in Alto Paraná match the remaining South American samples, which include admixed populations from Colombia, Peru and Ecuador, and natives from Colombia and Ecuador. FST genetic distance analysis showed that the native genetic background of Alto Paraná has an intermediate position between the Amazonian groups and the admixed populations from Peru and Ecuador, supporting the theory about the Amazonian origin of the Tupi-Guarani and, at the same time, showing the influence of other linguistic groups.

Next generation database search algorithm for forensic mitogenome analyses.

Mitochondrial DNA (mtDNA) variation is being reported relative to the corrected version of the first sequenced human mitochondrial genome. A review of the existing literature across disciplines that employ mtDNA demonstrates that insertions and deletions are not reported in a standardized way. This may lead to false exclusions of identical sequences, unidentified matches in missing persons mtDNA databases, biased mtDNA database frequency estimates and overestimation of the genetic evidence. Seven years ago we introduced alignment-free database search software (SAM) and implemented it into the mtDNA database EMPOP (https://empop.online) to produce reliable and conservative frequency estimates that are required in the forensic context. However, ambiguity remained in how laboratories have been reporting mitotypes, as often more than one single alignment of a given mtDNA sequence was feasible. In order to overcome this limitation we here describe a concept and provide software for producing stable, harmonized phylogenetic alignment of mtDNA sequences for database searches. The new software SAM 2 will be made available via EMPOP and provide the user with the already established conservative frequency estimates. In addition, SAM 2 offers the rCRS-coded haplotype of a given mtDNA sequence following the established and widely accepted phylogenetic alignment. This provides the user with feedback on how mitotypes are stored in EMPOP and how they should be reported in order to harmonize nomenclature. Finally, this approach does not only permit reliable mtDNA nomenclature in forensics but invites related disciplines to take advantage of a standardized way of reporting mtDNA variation, thus closing the ranks between different genetic fields and supporting dialogue and collaboration between mtDNA scholars from various disciplines.

Hallmarks of epithelial to mesenchymal transition are detectable in Crohn's disease associated intestinal fibrosis.

BACKGROUND: Intestinal fibrosis and subsequent stricture formation represent frequent complications of Crohn's disease (CD). In many organs, fibrosis develops as a result of epithelial to mesenchymal transition (EMT). Recent studies suggested that EMT could be involved in intestinal fibrosis as a result of chronic inflammation. Here, we investigated whether EMT might be involved in stricture formation in CD patients. METHODS: Human colonic tissue specimens from fibrotic areas of 18 CD and 10 non-IBD control patients were studied. Immunohistochemical staining of CD68 (marker for monocytes/macrophages), transforming growth factor-ß1 (TGFß1), ß-catenin, SLUG, E-.cadherin, α-smooth muscle actin and fibroblast activation protein (FAP) were performed using standard techniques. RESULTS: In fibrotic areas in the intestine of CD patients, a large number of CD68-positive mononuclear cells was detectable suggesting an inflammatory character of the fibrosis. We found stronger expression of TGFß1, the most powerful driving force for EMT, in and around the fibrotic lesions of CD patients than in non-IBD control patients. In CD patients membrane staining of ß-catenin was generally weaker than in control patients and more cells featured nuclear staining indicating transcriptionally active ß-catenin, in fibrotic areas. In these regions we also detected nuclear localisation of the transcription factor, SLUG, which has also been implicated in EMT pathogenesis. Adjacent to the fibrotic tissue regions, we observed high levels of FAP, a marker of reactive fibroblasts. CONCLUSIONS: We demonstrate the presence of EMT-associated molecules in fibrotic lesions of CD patients. These findings support the hypothesis that EMT might play a role for the development of CD-associated intestinal fibrosis.