Vitaport: A Learning and Artistic Path for Public Outreach on Transporter Biology, Health and Drug Discovery.

In occasion of its conclusion, the National Center of Competence in Research (NCCR) TransCure launched a temporary learning and artistic path in the city of Bern named 'Vitaport - Was unser Körper transportiert'. The path explained how nutrients are transported through our body and how molecules find their way to the right organ to achieve their effect there. NCCR TransCure researchers, together with students of the Bern School of Design, developed ceramic objects, texts and information graphics that took the public on a multidisciplinary journey of discovery through the human body.

The NCCR TransCure: An Incubator for Interdisciplinary Research.

The National Center of Competence in Research (NCCR) TransCure, funded by the Swiss National Science Foundation and the University of Bern, was active from 2010 to 2022. It provided unique research and educational framework in the membrane transporter and ion channel field. Thanks to an interdisciplinary approach comprising physiology, structural biology, and chemistry, in parallel to a rich offer in complementary areas such as education and technology transfer, the network achieved outstanding scientific results and contributed to the education of young scientists.

Effects of fertilisation on grass and forb gamic reproduction in semi-natural grasslands.

Studying the effects of fertilisation on the seed production of grassland species can help understand the vegetation changes and biodiversity losses due to soil eutrophication. The seed production of fifteen grasses and seventeen forbs from a temperate hay meadow was studied under three fertilisation treatments: 0-0-0, 0-54-108 and 192-108-216 kg N, PO and KO respectively, per year. Fertile shoots collected at the seed maturation stage were analysed for all main traits of the gamic reproduction.

Phenotypic diversity of multicellular filamentation in oral Streptococci.

Filamentous multicellular bacteria are among the most ancient multicellular organisms. They inhabit a great variety of environments and are present in the human body, including the oral cavity. Beside the selective advantages related to the larger size achieved through filamentation, the development of multicellular bacteria can be also driven by simple ecological factors such as birth and death rates at the cellular level.

Correction: Use of a Four-Tiered Graph to Parse the Factors Leading to Phenotypic Clustering in Bacteria: A Case Study Based on Samples from the Aletsch Glacier.

[This corrects the article on p. e65059 in vol. 8.

Use of a four-tiered graph to parse the factors leading to phenotypic clustering in bacteria: a case study based on samples from the Aletsch Glacier.

An understanding of bacterial diversity and evolution in any environment requires knowledge of phenotypic diversity. In this study, the underlying factors leading to phenotypic clustering were analyzed and interpreted using a novel approach based on a four-tiered graph. Bacterial isolates were organized into equivalence classes based on their phenotypic profile.

Advantages of the division of labour for the long-term population dynamics of cyanobacteria at different latitudes.

A fundamental advancement in the evolution of complexity is division of labour. This implies a partition of tasks among cells, either spatially through cellular differentiation, or temporally via a circadian rhythm. Cyanobacteria often employ either spatial differentiation or a circadian rhythm in order to separate the chemically incompatible processes of nitrogen fixation and photosynthesis.

Differences in cell division rates drive the evolution of terminal differentiation in microbes.

Multicellular differentiated organisms are composed of cells that begin by developing from a single pluripotent germ cell. In many organisms, a proportion of cells differentiate into specialized somatic cells. Whether these cells lose their pluripotency or are able to reverse their differentiated state has important consequences.

Emergent multicellular life cycles in filamentous bacteria owing to density-dependent population dynamics.

Filamentous bacteria are the oldest and simplest known multicellular life forms. By using computer simulations and experiments that address cell division in a filamentous context, we investigate some of the ecological factors that can lead to the emergence of a multicellular life cycle in filamentous life forms. The model predicts that if cell division and death rates are dependent on the density of cells in a population, a predictable cycle between short and long filament lengths is produced.

The evolutionary path to terminal differentiation and division of labor in cyanobacteria.

A common trait often associated with multicellularity is cellular differentiation, which is a spatial separation of tasks through the division of labor. In principle, the division of labor does not necessarily have to be constrained to a multicellular setting. In this study, we focus on the possible evolutionary paths leading to terminal differentiation in cyanobacteria.