Your search keyword '"Baumgarten, S"' showing total 6 results

1. Scalable production of tissue-like vascularized liver organoids from human PSCs.

Author

Harrison SP, Siller R, Tanaka Y, Chollet ME, de la Morena-Barrio ME, Xiang Y, Patterson B, Andersen E, Bravo-Pérez C, Kempf H, Åsrud KS, Lunov O, Dejneka A, Mowinckel MC, Stavik B, Sandset PM, Melum E, Baumgarten S, Bonanini F, Kurek D, Mathapati S, Almaas R, Sharma K, Wilson SR, Skottvoll FS, Boger IC, Bogen IL, Nyman TA, Wu JJ, Bezrouk A, Cizkova D, Corral J, Mokry J, Zweigerdt R, Park IH, and Sullivan GJ

Subjects

Humans, Animals, Mice, Tissue Engineering, Hepatocytes, Cells, Cultured, Liver, Organoids

Abstract

The lack of physiological parity between 2D cell culture and in vivo culture has led to the development of more organotypic models, such as organoids. Organoid models have been developed for a number of tissues, including the liver. Current organoid protocols are characterized by a reliance on extracellular matrices (ECMs), patterning in 2D culture, costly growth factors and a lack of cellular diversity, structure, and organization. Current hepatic organoid models are generally simplistic and composed of hepatocytes or cholangiocytes, rendering them less physiologically relevant compared to native tissue. We have developed an approach that does not require 2D patterning, is ECM independent, and employs small molecules to mimic embryonic liver development that produces large quantities of liver-like organoids. Using single-cell RNA sequencing and immunofluorescence, we demonstrate a liver-like cellular repertoire, a higher order cellular complexity, presenting with vascular luminal structures, and a population of resident macrophages: Kupffer cells. The organoids exhibit key liver functions, including drug metabolism, serum protein production, urea synthesis and coagulation factor production, with preserved post-translational modifications such as N-glycosylation and functionality. The organoids can be transplanted and maintained long term in mice producing human albumin. The organoids exhibit a complex cellular repertoire reflective of the organ and have de novo vascularization and liver-like function. These characteristics are a prerequisite for many applications from cellular therapy, tissue engineering, drug toxicity assessment, and disease modeling to basic developmental biology., (© 2023. The Author(s).)

Published

2023

2. Transcriptome-wide dynamics of extensive m 6 A mRNA methylation during Plasmodium falciparum blood-stage development.

Author

Baumgarten S, Bryant JM, Sinha A, Reyser T, Preiser PR, Dedon PC, and Scherf A

Subjects

Adenosine metabolism, CRISPR-Cas Systems, Erythrocytes parasitology, Gene Expression Regulation, Gene Knockdown Techniques, Genes, Protozoan, Humans, Life Cycle Stages, Malaria, Falciparum parasitology, Methylation, Methyltransferases genetics, Plasmodium falciparum enzymology, Protozoan Proteins genetics, Adenosine analogs & derivatives, Plasmodium falciparum genetics, Plasmodium falciparum metabolism, RNA, Messenger metabolism, Transcriptome

Abstract

Malaria pathogenesis results from the asexual replication of Plasmodium falciparum within human red blood cells, which relies on a precisely timed cascade of gene expression over a 48-h life cycle. Although substantial post-transcriptional regulation of this hardwired program has been observed, it remains unclear how these processes are mediated on a transcriptome-wide level. To this end, we identified mRNA modifications in the P. falciparum transcriptome and performed a comprehensive characterization of N 6 -methyladenosine (m 6 A) over the course of blood-stage development. Using mass spectrometry and m 6 A RNA sequencing, we demonstrate that m 6 A is highly developmentally regulated, exceeding m 6 A levels known in any other eukaryote. We characterize a distinct m 6 A writer complex and show that knockdown of the putative m 6 A methyltransferase, PfMT-A70, by CRISPR interference leads to increased levels of transcripts that normally contain m 6 A. In accordance, we find an inverse correlation between m 6 A methylation and mRNA stability or translational efficiency. We further identify two putative m 6 A-binding YTH proteins that are likely to be involved in the regulation of these processes across the parasite's life cycle. Our data demonstrate unique features of an extensive m 6 A mRNA methylation programme in malaria parasites and reveal its crucial role in dynamically fine-tuning the transcriptional cascade of a unicellular eukaryote.

Published

2019

3. Comparative analysis of the genomes of Stylophora pistillata and Acropora digitifera provides evidence for extensive differences between species of corals.

Author

Voolstra CR, Li Y, Liew YJ, Baumgarten S, Zoccola D, Flot JF, Tambutté S, Allemand D, and Aranda M

Subjects

Animals, Conserved Sequence, Phylogeny, Proteins genetics, Species Specificity, Transcriptome, Anthozoa genetics, Anthozoa physiology, Dinoflagellida genetics, Dinoflagellida physiology, Genomics, Symbiosis genetics

Abstract

Stony corals form the foundation of coral reef ecosystems. Their phylogeny is characterized by a deep evolutionary divergence that separates corals into a robust and complex clade dating back to at least 245 mya. However, the genomic consequences and clade-specific evolution remain unexplored. In this study we have produced the genome of a robust coral, Stylophora pistillata, and compared it to the available genome of a complex coral, Acropora digitifera. We conducted a fine-scale gene-based analysis focusing on ortholog groups. Among the core set of conserved proteins, we found an emphasis on processes related to the cnidarian-dinoflagellate symbiosis. Genes associated with the algal symbiosis were also independently expanded in both species, but both corals diverged on the identity of ortholog groups expanded, and we found uneven expansions in genes associated with innate immunity and stress response. Our analyses demonstrate that coral genomes can be surprisingly disparate. Future analyses incorporating more genomic data should be able to determine whether the patterns elucidated here are not only characteristic of the differences between S. pistillata and A. digitifera but also representative of corals from the robust and complex clade at large.

Published

2017

4. Transcriptomes and expression profiling of deep-sea corals from the Red Sea provide insight into the biology of azooxanthellate corals.

Author

Yum LK, Baumgarten S, Röthig T, Roder C, Roik A, Michell C, and Voolstra CR

Subjects

Animals, Anthozoa physiology, Glycolysis genetics, Indian Ocean, Mitochondria genetics, Mitochondria metabolism, Oxygen metabolism, Anthozoa genetics, Transcriptome

Abstract

Despite the importance of deep-sea corals, our current understanding of their ecology and evolution is limited due to difficulties in sampling and studying deep-sea environments. Moreover, a recent re-evaluation of habitat limitations has been suggested after characterization of deep-sea corals in the Red Sea, where they live at temperatures of above 20 °C at low oxygen concentrations. To gain further insight into the biology of deep-sea corals, we produced reference transcriptomes and studied gene expression of three deep-sea coral species from the Red Sea, i.e. Dendrophyllia sp., Eguchipsammia fistula, and Rhizotrochus typus. Our analyses suggest that deep-sea coral employ mitochondrial hypometabolism and anaerobic glycolysis to manage low oxygen conditions present in the Red Sea. Notably, we found expression of genes related to surface cilia motion that presumably enhance small particle transport rates in the oligotrophic deep-sea environment. This is the first study to characterize transcriptomes and in situ gene expression for deep-sea corals. Our work offers several mechanisms by which deep-sea corals might cope with the distinct environmental conditions present in the Red Sea As such, our data provide direction for future research and further insight to organismal response of deep-sea coral to environmental change and ocean warming.

Published

2017

5. Genomes of coral dinoflagellate symbionts highlight evolutionary adaptations conducive to a symbiotic lifestyle.

Author

Aranda M, Li Y, Liew YJ, Baumgarten S, Simakov O, Wilson MC, Piel J, Ashoor H, Bougouffa S, Bajic VB, Ryu T, Ravasi T, Bayer T, Micklem G, Kim H, Bhak J, LaJeunesse TC, and Voolstra CR

Subjects

Animals, Dinoflagellida classification, Adaptation, Biological physiology, Anthozoa physiology, Dinoflagellida genetics, Evolution, Molecular, Genome, Symbiosis physiology

Abstract

Despite half a century of research, the biology of dinoflagellates remains enigmatic: they defy many functional and genetic traits attributed to typical eukaryotic cells. Genomic approaches to study dinoflagellates are often stymied due to their large, multi-gigabase genomes. Members of the genus Symbiodinium are photosynthetic endosymbionts of stony corals that provide the foundation of coral reef ecosystems. Their smaller genome sizes provide an opportunity to interrogate evolution and functionality of dinoflagellate genomes and endosymbiosis. We sequenced the genome of the ancestral Symbiodinium microadriaticum and compared it to the genomes of the more derived Symbiodinium minutum and Symbiodinium kawagutii and eukaryote model systems as well as transcriptomes from other dinoflagellates. Comparative analyses of genome and transcriptome protein sets show that all dinoflagellates, not only Symbiodinium, possess significantly more transmembrane transporters involved in the exchange of amino acids, lipids, and glycerol than other eukaryotes. Importantly, we find that only Symbiodinium harbor an extensive transporter repertoire associated with the provisioning of carbon and nitrogen. Analyses of these transporters show species-specific expansions, which provides a genomic basis to explain differential compatibilities to an array of hosts and environments, and highlights the putative importance of gene duplications as an evolutionary mechanism in dinoflagellates and Symbiodinium.

Published

2016

6. Aiptasia sp. larvae as a model to reveal mechanisms of symbiont selection in cnidarians.

Author

Wolfowicz I, Baumgarten S, Voss PA, Hambleton EA, Voolstra CR, Hatta M, and Guse A

Subjects

Animals, Anthozoa genetics, Gene Expression Profiling, Genetic Association Studies, Larva, Sea Anemones genetics, Sequence Analysis, RNA, Time Factors, Anthozoa physiology, Models, Biological, Sea Anemones physiology, Symbiosis genetics

Abstract

Symbiosis, defined as the persistent association between two distinct species, is an evolutionary and ecologically critical phenomenon facilitating survival of both partners in diverse habitats. The biodiversity of coral reef ecosystems depends on a functional symbiosis with photosynthetic dinoflagellates of the highly diverse genus Symbiodinium, which reside in coral host cells and continuously support their nutrition. The mechanisms underlying symbiont selection to establish a stable endosymbiosis in non-symbiotic juvenile corals are unclear. Here we show for the first time that symbiont selection patterns for larvae of two Acropora coral species and the model anemone Aiptasia are similar under controlled conditions. We find that Aiptasia larvae distinguish between compatible and incompatible symbionts during uptake into the gastric cavity and phagocytosis. Using RNA-Seq, we identify a set of candidate genes potentially involved in symbiosis establishment. Together, our data complement existing molecular resources to mechanistically dissect symbiont phagocytosis in cnidarians under controlled conditions, thereby strengthening the role of Aiptasia larvae as a powerful model for cnidarian endosymbiosis establishment.

Published

2016