Max Planck Institute of Molecular Plant Physiology

Max Planck Institute of Molecular Plant Physiology

Founded in 1994, the Max Planck Institute of Molecular Plant Physiology investigates metabolic and molecular processes in plant cells, tissues and organs. The goal of the Institute's research is not only to understand the molecular details of individual processes such as the uptake of substances, the structure, storage, transport and mobilisation of plant components as well as the regulation of these processes, but also to figure out how these different processes interact and are integrated. In this Systems Biology approach, experimental and computational scientists interact closely to understand how metabolism and plant growth are organised and regulated, and how they are affected by different environmental factors.

Contact

Am Mühlenberg 1
14476 Potsdam-Golm
Phone: +49 331 567-80
Fax: +49 331 567-8408

PhD opportunities

This institute has an International Max Planck Research School (IMPRS):
IMPRS Primary Metabolism and Plant Growth

In addition, there is the possibility of individual doctoral research. Please contact the directors or research group leaders at the Institute.

Department Organelle Biology, Biotechnology and Molecular Ecophysiology more
Research highlights from our yearbook
The yearbook of the Max Planck Society illustrates the research carried out at our institutes. We selected a few reports from our 2017 yearbook to illustrate the variety and diversity of topics and projects. more
Marine microalgae: an address plaque for calcium
A biochemical mechanism controls which nanostructures are formed in calcite-forming microorganisms more
New plant engineering method could help fill demand for crucial malaria drug
Novel methods could enable inexpensive mass production for drugs more
Fighting the Colorado potato beetle with RNA
RNA interference protects potato plants against herbivore attack more
Wild genes enhance stress tolerance
The genome of the wild tomato Solanum pennellii provides clues as to why this tomato species is so tolerant to stress more
When plant pollen fertilizes an ovum, the genetic material in the nucleus and the chloroplasts must harmonize. Stephan Greiner from the Max Planck Institute of Molecular Plant Physiology in Golm, near Potsdam, would like to find out which factors in the chloroplasts prevent the interbreeding of plant species. To do this, he works with a model plant that’s not too particular when it comes to the species boundary: the evening primrose.
Plants have lived in close community with certain fungi for millions of years. The microorganisms provide them with vital mineral salts such as phosphate, and in return, they supply the fungi with carbohydrates. Franziska Krajinski from the Max Planck Institute of Molecular Plant Physiology in Golm observes how these unequal partners establish contact with each other and exchange nutrients.
The company metanomics systematically influences plant characteristics through their genes, for example to increase yields.
How were plant cells, and thus higher forms of life on Earth, able to evolve from bacteria? Ralph Bock, Director at the Max Planck Institute of Molecular Plant Physiology in Golm, has been exploring this question for many years.
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The prospects of understanding calcite formation in coccolithophorid algae

2018 Scheffel, André
Cell Biology Physiology Plant Research Structural Biology
Coccolithophores are single-celled marine algae that form intricately-shaped scales made of the mineral calcite. Such complex biominerals are interesting models for bioinspired materials chemistry. Biogenic calcite formation is an important component of the global carbon cycle and exerts major influence on our climate. Understanding calcite biomineralization in coccolithophores has the potential to revolutionize the synthesis of materials for nanotechnology and to improve our predictive models for the future of biogenic calcification, which is relevant for future life on our planet. more

Mobile RNA - do plant cells send a double message?

2017 Kragler, Friedrich
Cell Biology Plant Research
Plant tissues exchange Protein-encoding RNA molecules. These mobile RNA molecules are evolutionary conserved and found in distantly related plant species. In target tissues mobile mRNAs are translated into proteins. The observed high number of mobile RNAs - approximately 20% transcribed genes produce mobile RNAs - questions the concept of cell autonomy and how we define signals in plant science. more

Lifetimes of photosynthetic complexes in higher plants

2016 Schöttler, Mark A.
Plant Research
Plants need to precisely adjust the capacity of photosynthetic electron transport to produce ATP and NADPH to their consumption by the Calvin cycle. Otherwise, an overcapacity of electron transport would lead to an increased production of reactive oxygen species and the destruction of the photosynthetic apparatus. To avoid this, the electron transport capacity is regulated by adjustments of the rate-limiting cytochrome b6f complex. We have analyzed the contribution of complex biogenesis versus degradation to this adjustment. more

Large-scale model predictions by integration of high-throughput data

2015 Kleeßen, Sabrina; Robaina-Estevez, Semidan; Nikoloski, Zoran
Plant Research

In modern biology research, essential aspects of the accumulated genomic and biochemical knowledge are often described as mathematical formulas resulting in metabolic models. These models can be readily used to make predictions. Because of the increasing amount of available high-throughput technologies, there is need for the development of methods allowing the characterization of the activity patterns of metabolic pathways. The ultimate goal of integrating these methods and data is to enhance understanding of plant growth and to improve it.

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The massively increased breadth of sequence variability information allows new avenues in plant research

2014 Korkuć, Paula; Childs, Liam; Walther, Dirk
Cell Biology Genetics Physiology Plant Research Structural Biology

The introduction of novel sequencing technologies has led to a massive expansion of genomic sequence information. Completely sequenced genomes of hundreds of different ecotypes of the model plant Arabidopsis thaliana are now available. Applying bioinformatics methods, the extensive sequence information can be exploited for the identification of trait associated genes or novel regulatory elements.

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