Education
Our group contributes to Biology education in several MSc and BSc programs at Utrecht 木瓜福利影视 in a diverse roles.
Bachelor programs
BSc Biology program
Martijn van Zanten is manager of education of the Biology BSc programme and in this capacity responsible for the business operations (planning, finance, practical organization, communication etc.). He takes part in several education policy committees on the departmental and faculty level. In addition, he organizes the Matching days is responsible for the open days, and is the course coordinator of the Bachelor graduation thesis and internship courses that run year-round. In addition, Martijn is our ''. You can contact Martijn if you are interested in doing a BSc internship in our group.
Rashmi Sasidharan coordinates and teaches the level 3 course 鈥淔ood Forward鈥. This is a unique interdisciplinary course in the Biology programme teaching students on diverse aspects of food technology and innovation as well as the importance of science communication. She also is a lecturer in the level 3 course 鈥淧lant Development and Environment鈥.
Nora Gigli-Bisceglia is a lecturer in the level 2 "Metabolism and Biochemistry" course in the BSc Biology programme.
Furthermore, members of our team participate in teaching and supervising the 'Experimenteerweken' practicals for the biology programme.
Dorota Kawa is a lecturer and a wet lab teacher in the Level 3 鈥淧lant Development and Environment鈥 course for BSc students. Additionally, she actively participates in guiding students during the writing of a scientific proposal in "Molecular Cell Research" also for bachelor students.
Molecular and Biophysical Life Sciences MBLS programme
Nora Gigli-Bisceglia teaches "Research Design and Analysis鈥 for the MBLS students.
Master programs
Molecular and Cellular Life Sciences MCLS
Rashmi Sasidharan serves on the admission committee for the MCLS MSc programme.
Nora Gigli-Bisceglia is the coordinator of the "Applied Plant Biology" master's student course.
Science and Business Management SBM programme
Rashmi Sasidharan and Martijn van Zanten lecture in the SBM course 鈥淏iotechnology and Societal Challenges鈥
Educational projects
Research themes in PSR (Click below for more information):
- Rashmi Sasidharan: Mechanisms of water stress resilience
- Martijn van Zanten: Plant responses to non-optimal temperatures
- Nora Gigli Bisceglia: Cell wall sensing and abiotic stress
- Dorota Kawa: Climate
If you find these research themes interesting, and would like to explore potential internship projects, please send an email to Rashmi Sasidharan (r.sasidharan@uu.nl) or contact the staff members directly.
As climate change progresses, flooding events have become more frequent and intense.
Flooding subjects plant roots to hypoxic (low oxygen) conditions, hindering gas exchange and leading to the accumulation of ethylene (volatile plant hormone), making this an important flood detection cue. Plant plasticity is especially important for plants in order to survive sub-optimal and stress conditions. Meristematic cells are key players in this because they are undifferentiated cells found at shoot and root tips with the potential to generate organs. The mechanisms behind meristem tolerance to stress conditions has yet remained underexplored.
Previous experiments have shown that, in Arabidopsis, an ethylene pre-treatment following subsequent hypoxic stress can enhance root survival. While it is clear that the activating mechanism caused by ethylene accumulation boosts the regrowth capacity of roots after hypoxia, it is yet unknown how meristem protection is conferred. What are the processes that ethylene is interfering with? Is this an overall effect or are there specific cell types that communicate to coordinate meristem protection?
This internship will focus on analyzing previously generated crosses between auxin fluorescent reporter lines and ethylene signaling mutants in order to elucidate the mechanisms through which ethylene confers meristematic protection. Project will include microscopy work and molecular biology techniques.
Daily supervisor
Climate change is increasing the frequency and unpredictability of extreme weather events, including late spring and early autumn frost, which pose significant threats to potato (Solanum tuberosum) cultivation.
Potatoes are particularly susceptible to frost, leading to damage that affects yield and crop quality. Despite its importance, the genetic variation underlying potato's response to frost events remains poorly characterized.
This project aims to establish a comprehensive understanding of the genetic variation in potato frost responses by integrating plant physiology, advanced phenotyping techniques, and molecular phenotyping through gene expression analysis. By evaluating diverse potato genotypes under controlled frost conditions, we will identify key physiological traits and gene expression patterns associated with frost tolerance. The findings from this research will enhance our understanding of the mechanisms underlying frost susceptibility in potato and may guide the development of frost-resistant potato varieties.
Supervisor
Natalia Rodriguez (n.y.rodriguezgranados@uu.nl, Kruyt Building, Room O201)
Potato (Solanum tuberosum) is the most consumed non-cereal crop worldwide. However, its productivity is severely affected by anthropogenic climate change.
The current climate emergency has led to an increase in severity and frequency of flooding events. Waterlogging (i.e. root flooding) poses a significant threat to potato cultivation, leading to substantial yield losses. The primary consequence of waterlogging is soil hypoxia, where reduced oxygen availability severely impacts plant metabolism and survival. However, the molecular mechanisms underlying potato's response to waterlogging, particularly its ability to sense and acclimate to hypoxia, remain poorly understood. This project aims to explore the role of oxygen sensing in potato plants during waterlogging stress. For this purpose, we conducted a reverse genetic approach and created knock-down (RNAi) mutant of a key protein involved in the oxygen sensing pathway. Through a combination of genetic, molecular, and physiological approaches, we will investigate the role of hypoxia sensing in waterlogging responses, thereby paving new venues for improved resilience in this vulnerable, yet essential crop for food security.
Supervisor
Natalia Rodriguez (n.y.rodriguezgranados@uu.nl Kruyt Building, Room O201)
Stresses in nature seldom occur in isolation and effects of multiple stresses on phenotypic output (i.e. plant appearance/responses) usually differs from responses that are induced by single stresses.
For instance, in response to high temperature plants induce a suite of traits collectively termed thermomorphogenesis, which comprises of architectural and physiological traits that are induced by plants to aid cooling capacity by enhancing evaporation. However, under drought conditions, water loss must be limited and therefore drought counteracts thermomorphogenesis on the shoot level. However, belowground, high temperature and drought act additive on root elongation, which is a strategy to reach deeper soil water. Also, on the molecular level we see that the transcriptome response under combined drought and high temperature stress are unique and fundamentally differs from changes in gene expression induced by only high temperature or only drought.
Arabidopsis occurs throughout the Northern hemisphere in the wild, from the tropics to the arctic circle, and Arabidopsis varieties (called accessions) evolved different strategies to cope with their local temperature and precipitation conditions. We thus can directly learn from nature鈥檚 solutions to deal with combined stresses that evolved to deal with very different local environments. In the framework of the national PlantXR consortium, together with the National Plant Eco-Phenotyping Center (NPEC), we are currently assessing a large panel of natural Arabidopsis accessions under a combination of 3 high temperature x 3 drought conditions, to disclose the strategies that natural accessions evolved to deal with combined high temperature and drought stress. After identifying accessions with different strategies, we will phenotype these in even greater detail using the NPEC sensory systems, together with collaborators develop computational functional plant models to understand why the accessions behave under these adverse conditions as they do, and design experiments to understand the underlying molecular genetic networks that are involved. We are looking for one or two enthusiastic and motivated Msc student(s) interested in environmental and/or molecular biology, phenotyping and natural genetic variation, who would like to explore these accessions and help us disclosing the diverse strategies. There are many possibilities for students that can be tailored depending on the expertise and wishes.
Supervisors
Jelle Keijzer, Martijn van Zanten
Contact
Many plant biology studies involve Arabidopsis thaliana as model plant. Together with all first year Biology students and staff members we obtained a large collection (seeds, leaf material and soil samples) of >650+ wild Arabidopsis plants from all over the Netherlands in the springs of 2023 and 2024.
We are looking for one or two enthusiastic and motivated Msc student(s) interested in environmental biology, phenotyping and natural variation, who would like to explore this new collection. There are many possibilities with these samples and the available lines from an ecological to a bioinformatic and a molecular viewpoint. For example, we plan to phenotypically characterize the plant lines in the new NPEC-facility to observe phenotypical differences across environments. Also, we plan to grow the collection in the botanical garden and assess variation in phenology, growth and development. Using the soil samples of each site, we plan to assess parameters like pH, C/N ratio, soil type etc. Moreover, we plan to classify the samples according to their collection site (based on vegetation captured on photo鈥檚 that are available for each accession). We aim to correlate the environment to genetics and morphology to estimate the natural genetic variation in the species and to map traits that mediate resilience to environmental stress conditions.
Furthermore, in a recent study, we have identified a newly found a comovirus; Arabidopsis latent virus 1 (ArLV1), which we encountered in A. thaliana RNA sequencing datasets generated in our laboratories and which was found to be widespread in other datasets obtained from sequence data repositories (Verhoeven et al., 2022). We are also very much interested in disclosing the occurrence of the virus in plants collected from the wild and any sequence divergence among them.
Supervisors
Ava Verhoeven, Basten Snoek, Martijn van Zanten
Contact
We are interested in elucidating the molecular mechanisms regulating cold and warm temperature signalling, sensing and response in plants in many facets.
Our primary focus lies on deciphering thermomorphogenesis, which is a suite of architectural and physiological traits that are induced by plants under high temperatures. The resulting open rosette structure (due to e.g. upward leaf movement, elongation of leaf stalks etc) contributes to cooling capacity, which allows the acclimated plants to better withstand high temperature conditions. For long, studies on mild high temperature acclimation, heat stress, cold acclimation and freezing stress have been four separate fields of research. We now become more and more aware that many proteins that were previously considered to play a role in either heat stress or cold acclimation in fact control plant growth throughout the temperature gradient. In our group we aim to understand how proteins can have promiscuous roles at different temperatures using the model system Arabidopsis thaliana. We focus among others on the transcription factors INDUCER OF CBF EXPRESSION 1, better known as ICE1.
ICE1 is a well-known transcription factor being responsible for acclimation to cold conditions. However, we identified ICE1 in a phosphoproteomics experiments based on differential phosphorylation of the protein in different temperatures and found that ICE1 is also differentially phosphorylated at warm temperatures. In a follow-up experiment, we found that ice1 mutants surprisingly are largely insensitive to high temperature as well and we strive to elucidate the molecular basis of this. To this aim we are generating constructs in which the differentially phosphorylated residues are mutated to test the influence of these residues on the response. This explorative internship will allow diving deeper into the molecular mechanisms how ICE1 affects temperature responses across the temperature spectrum from cold to warmth. Experiments that should be conducted include Western blotting to test the protein abundance in different temperatures, testing marker genes to probe the molecular networks that are affected by ICE1 and making crosses and analysing ice1 mutants/overexpression lines with (mutants of) known temperature regulators to position ice1 in the molecular framework of known temperature signalling cascades.
Supervisors
Martijn van Zanten, Jelle Keijzer
Contact
Salinity affects plant growth by simultaneously causing ionic and osmotic stress, leading to both general and specific signaling responses (Lamers et al., 2020; van Zelm et al., 2020).
Some salt-tolerant plant species have evolved mechanisms to compartmentalize and excrete excess salt, enabling them to thrive in saline environments. High salinity stress can significantly reduce crop yields, emphasizing the importance of developing salt-resistant plant varieties and implementing better soil management practices. Salinity also induces changes in the structure of cell walls (Gigli-Bisceglia et al., 2022), triggering responses that are independent of its toxicity.
Our research group focuses on understanding the factors responsible for cell wall modifications and the molecular pathways that sense and initiate these responses. Recently, we made the discovery that salt application in plants leads to an increase in cell wall thickness. This increase appears to be regulated by an enzyme known as EXAD, which stands for EXTENSIN ARABINOSE DEFICIENT TRANSFERASE. EXAD adds arabinose residues to cell wall-localized proteins known as Extensins.
Figure 1. Impact of Salt on Cell Wall Thickness. The cell wall (depicted by yellow lines) undergoes a significant increase in width in response to salt, with this effect being dependent on EXAD.
Project Goal
Identification of Extensins that are targeted by salt stress and by EXAD.
What You Can Learn
Cell Wall extraction, Protein extraction, Immuno-Precipitation, Western blot
Further reading
Arabidopsis root responses to salinity depend on pectin modification and cell wall sensing. Gigli-Bisceglia et al., 2022 Development. Cell wall extensin arabinosylation is required for root directional response to salinity. Zou, Gigli-Bisceglia et al., 2023 Plant Cell.
Supervisor
Nora Gigli-Bisceglia (n.giglibisceglia@uu.nl)
Salinity exerts a dual impact on plant growth, simultaneously inducing ionic and osmotic stress, which, in turn, elicits both general and specific signaling responses (Lamers et al., 2020; van Zelm et al., 2020).
Some plant species adapted to saline environments have evolved mechanisms for sequestering and excreting excess salt, facilitating their thriving under such conditions. The detrimental effects of high salinity stress on crop yields underscore the imperative need to develop salt-resistant plant varieties and enhance soil management practices. Additionally, salinity provokes alterations in cell wall structure (Gigli-Bisceglia et al., 2022), prompting responses that are independent of its toxic effects.
Our research group is dedicated to unraveling the determinants of cell wall modifications and elucidating the molecular pathways responsible for sensing and triggering these responses. Recently, we made a significant discovery: a class of cell wall-localized enzymes known as Pectin methyl esterases (PMEs) becomes activated in response to salt stress. Recent findings point out the interaction of peptides known as Rapid Alkalinization Like Factors (RALFs) in the binding to pectins. In our lab, we discovered that RALFs genes are controlled by salt stress, but we have no further knowledge of the role of the RALFs in controlling salt stress tolerance.
Project Goal
Unraveling the Influence of Salt Stress on RALF Mutant Lines and Establishing the Link between RALFs' Function and Salt Tolerance.
What You Can Learn
Root phenotyping, RNA extraction, qPCR
Further reading
Arabidopsis root responses to salinity depend on pectin modification and cell wall sensing. Gigli-Bisceglia et al., 2022. The FERONIA Receptor Kinase Maintains Cell-Wall Integrity during Salt Stress through Ca2+ Signaling. Feng et al., 2018
Supervisors
Nora Gigli Bisceglia and Joy Debnath (n.giglibisceglia@uu.nl, j.debnath@uu.nl)
Cellular elongation, a crucial process in the growth and development of plants, plays a pivotal role in various biological phenomena.
This intricate mechanism involves the expansion of individual cells in size and shape, contributing to the overall shaping and elongation of tissues and organisms. One vital factor that influences differential growth and cellular elongation is oxygen availability. Oxygen, an essential element for cellular respiration fuels the metabolic processes that generate energy within cells, is sensed through the N-degron pathway of protein degradation. Yet how the N-degron pathway and oxygen sensing regulate cellular elongation is not known.
Project goal
Identification of novel mechanisms of interaction between oxygen sensing and cell wall elongation
What can you learn?
Genetic cloning and plant transformation, qRT-PCRs, western blotting, Biochemical extractions, Confocal microscopes
Supervisors
Nora Gigli-Bisceglia (n.giglibisceglia@uu.nl)
The Kawa team are affiliated both with Plant Stress Resilience and Experimental and Computational Plant Development. See additional project descriptions at ECPD section.
Introduction
Climate change is taking a devastating toll on crop production. In the Netherlands and Northern Europe, heat waves and drought have been occurring more frequently and with higher intensities. Crops currently grown in the region are prone to yield losses under drought. To ensure food security we need to consider cultivation of drought tolerant crops. As such, sorghum offers a great alternative to maize, as it is drought and heat tolerant and requires less fertilizers. The main obstacle for sorghum cultivation in Northern Europe is that the growing season is too short, as the species is typically grown in areas with long, warm seasons. Hence, planting would need to occur early in the year when soil temperature is still low. Sorghum shows poor establishment in cold soils which motivates the study of mechanisms of cold tolerance of sorghum roots. Previous research focused mostly on sorghum cold tolerance at the reproductive stage, but little is known about the role of the roots therein.
The research questions we address are
- How does cold affect sorghum root system architecture and root cellular patterning?
- Which genes control sorghum root responses to drought?
- What is the natural variation in sorghum in terms of root responses to cold?
Projects鈥 goals
You will get an opportunity to establish a method to study the effect of cold and warmth on sorghum root morphology and physiology. You will use our state-of-the-art temperature gradient table, which has been successfully used to study the effects of cold and higher temperatures. Once the conditions are optimized you will assess how cold is reshaping sorghum roots and ultimately the underlying molecular mechanisms.
What can you learn?
Plant growth and cultivation; temperature assays in plants, root system architecture analysis, root histology, confocal, fluorescent microscopy
Further reading
Praat, M., Jiang, Z., Earle, J. et al. Using a thermal gradient table to study plant temperature signalling and response across a temperature spectrum. Plant Methods 20, 114 (2024).
Supervisors
Dr. Dorota Kawa (d.kawa@uu.nl) and Dr. Martijn van Zanten (M.vanZanten@uu.nl)