Stefanie Rosa

Physical clustering of FLC alleles during Polycomb-mediated epigenetic silencing in vernalization

Vernalization, the promotion of flowering by cold, involves Polycomb-mediated epigenetic silencing of FLOWERING LOCUS C (FLC). Cold progressively promotes cell-autonomous switching to a silenced state. Here, we used live-cell imaging of FLC-lacO to monitor changes in nuclear organization during vernalization. FLC-lacO alleles physically cluster during the cold and generally remain so after plants are returned to warm. Clustering is dependent on the Polycomb trans-factors necessary for establishment of the FLC silenced state but not on LIKE HETEROCHROMATIN PROTEIN 1, which functions to maintain silencing. These data support the view that physical clustering may be a common feature of Polycomb-mediated epigenetic switching mechanisms.

Mutually exclusive sense–antisense transcription at FLC facilitates environmentally induced gene repression

Antisense transcription through genic regions is pervasive in most genomes; however, its functional significance is still unclear. We are studying the role of antisense transcripts (COOLAIR) in the cold-induced, epigenetic silencing of Arabidopsis FLOWERING LOCUS C (FLC), a regulator of the transition to reproduction. Here we use single-molecule RNA FISH to address the mechanistic relationship of FLC and COOLAIR transcription at the cellular level. We demonstrate that while sense and antisense transcripts can co-occur in the same cell they are mutually exclusive at individual loci. Cold strongly upregulates COOLAIR transcription in an increased number of cells and through the mutually exclusive relationship facilitates shutdown of sense FLC transcription in cis. COOLAIR transcripts form dense clouds at each locus, acting to influence FLC transcription through changed H3K36me3 dynamics. These results may have general implications for other loci showing both sense and antisense transcription.

Nuclear Organization Changes and the Epigenetic Silencing of FLC during Vernalization

Changes in nuclear organization are considered an important complement to trans-acting factors, histone modifications and non-coding RNAs in robust and stable epigenetic silencing. However, how these multiple layers interconnect mechanistically to reinforce each others activity is still unclear. A system providing long timescales facilitating analysis of these interconnections is vernalization. This involves the Polycomb-mediated epigenetic silencing of flowering locus C (FLC) that occurs as Arabidopsis plants are exposed to prolonged cold. Analysis of changes in nuclear organization during vernalization has revealed that disruption of a gene loop and physical clustering of FLC loci are part of the vernalization mechanism. These events occur at different times and thus contribute to distinct aspects of the silencing mechanism. The physical clustering of FLC loci is tightly correlated with the accumulation of specific Polycomb complexes/H3K27me3 at a localized intragenic site during the cold. Since the quantitative nature of vernalization is a reflection of a bistable cell autonomous switch in an increasing number of cells, this correlation suggests a tight connection between the switching mechanism and changes in nuclear organization. This integrated picture is likely to be informative for many epigenetic mechanisms.

Cell Differentiation and Development in Arabidopsis Are Associated with Changes in Histone Dynamics at the Single-Cell Level

Histone mobility is regulated during development in Arabidopsis roots, being higher in the division zone and lower in stem cells and differentiated cells, mainly due to changes in histone acetylation. The mechanism whereby the same genome can give rise to different cell types with different gene expression profiles is a fundamental problem in biology. Chromatin organization and dynamics have been shown to vary with altered gene expression in different cultured animal cell types, but there is little evidence yet from whole organisms linking chromatin dynamics with development. Here, we used both fluorescence recovery after photobleaching and two-photon photoactivation to show that in stem cells from Arabidopsis thaliana roots the mobility of the core histone H2B, as judged by exchange dynamics, is lower than in the surrounding cells of the meristem. However, as cells progress from meristematic to fully differentiated, core histones again become less mobile and more strongly bound to chromatin. We show that these transitions are largely mediated by changes in histone acetylation. We further show that altering histone acetylation levels, either in a mutant or by drug treatment, alters both the histone mobility and markers of development and differentiation. We propose that plant stem cells have relatively inactive chromatin, but they keep the potential to divide and differentiate into more dynamic states, and that these states are at least in part determined by histone acetylation levels.

Expression of a recombinant human erythropoietin in suspension cell cultures of Arabidopsis, tobacco and Medicago

In the last two decades, the use of plants to produce recombinant proteins and particularly biopharmaceuticals has become an attractive alternative to established systems. This is due to advantages in scalability, economy and safety. In addition the expression of recombinant proteins in plants can also be achieved utilizing in vitro cell suspensions with all the advantages such systems confer, such as product consistency, production “on demand” and the ability to perform the entire process according to good manufacturing practices. In this study we have produced the glycosylated human hormone Erythropoietin (EPO), in Medicago truncatula and Arabidopsis thaliana plants and also in cultured cell lines of tobacco, Medicago and Arabidopsis. We have also tested two different versions of the protein, one with a KDEL tag for targeted expression in the Endoplasmic Reticulum, and an untagged version expected to be secreted to the apoplast. The recombinant protein was detected in the plant leaf extracts and in the cultured cell lines. In the latter, the rEPO was detected in the cell extracts and in the spent culture medium. It was possible to recover the KDEL version of rEPO from crude cell extracts by nickel affinity chromatography, however the secreted form did not bind to the Ni- agarose beads which may indicate a possible internalization of the his-tag in the folded protein. Although the yield of rEPO obtained in cell suspensions was not as high as expected, the protein was successfully produced and secreted into the culture medium, reinforcing that plant cell suspension cultures are a promising system for production of human biopharmaceuticals.

A method for detecting single mRNA molecules in Arabidopsis thaliana

BackgroundDespite advances in other model organisms, there are currently no techniques to explore cell-to-cell variation and sub-cellular localization of RNA molecules at the single-cell level in plants.ResultsHere we describe a method for imaging individual mRNA molecules in Arabidopsis thaliana root cells using multiple singly labeled oligonucleotide probes. We demonstrate detection of both mRNA and nascent transcripts of the housekeeping gene Protein Phosphatase 2A. Our image analysis pipeline also enables quantification of mRNAs that reveals the frequency distribution of transcripts per cell underlying the population mean.ConclusionThis method allows single molecule RNA in situ to be exploited as a powerful tool for studying gene regulation in plants.

Insights into Chromatin Structure and Dynamics in Plants

The packaging of chromatin into the nucleus of a eukaryotic cell requires an extraordinary degree of compaction and physical organization. In recent years, it has been shown that this organization is dynamically orchestrated to regulate responses to exogenous stimuli as well as to guide complex cell-type-specific developmental programs. Gene expression is regulated by the compartmentalization of functional domains within the nucleus, by distinct nucleosome compositions accomplished via differential modifications on the histone tails and through the replacement of core histones by histone variants. In this review, we focus on these aspects of chromatin organization and discuss novel approaches such as live cell imaging and photobleaching as important tools likely to give significant insights into our understanding of the very dynamic nature of chromatin and chromatin regulatory processes. We highlight the contribution plant studies have made in this area showing the potential advantages of plants as models in understanding this fundamental aspect of biology.

Cell-Size-Dependent Transcription of FLC and Its Antisense Long Non-coding RNA COOLAIR Explain Cell-to-Cell Expression Variation

Summary Single-cell quantification of transcription kinetics and variability promotes a mechanistic understanding of gene regulation. Here, using single-molecule RNA fluorescence in situ hybridization and mathematical modeling, we dissect cellular RNA dynamics for Arabidopsis FLOWERING LOCUS C (FLC). FLC expression quantitatively determines flowering time and is regulated by antisense (COOLAIR) transcription. In cells without observable COOLAIR expression, we quantify FLC transcription initiation, elongation, intron processing, and lariat degradation, as well as mRNA release from the locus and degradation. In these heterogeneously sized cells, FLC mRNA number increases linearly with cell size, resulting in a large cell-to-cell variability in transcript level. This variation is accounted for by cell-size-dependent, Poissonian FLC mRNA production, but not by large transcriptional bursts. In COOLAIR-expressing cells, however, antisense transcription increases with cell size and contributes to FLC transcription decreasing with cell size. Our analysis therefore reveals an unexpected role for antisense transcription in modulating the scaling of transcription with cell size.

Disruption of an RNA-binding hinge region abolishes LHP1-mediated epigenetic repression

Epigenetic maintenance of gene repression is essential for development. Polycomb complexes are central to this memory, but many aspects of the underlying mechanism remain unclear. LIKE HETEROCHROMATIN PROTEIN 1 (LHP1) binds Polycomb-deposited H3K27me3 and is required for repression of many Polycomb target genes in Arabidopsis Here we show that LHP1 binds RNA in vitro through the intrinsically disordered hinge region. By independently perturbing the RNA-binding hinge region and H3K27me3 (trimethylation of histone H3 at Lys27) recognition, we found that both facilitate LHP1 localization and H3K27me3 maintenance. Disruption of the RNA-binding hinge region also prevented formation of subnuclear foci, structures potentially important for epigenetic repression.

Measuring Dynamics of Histone Proteins by Photobleaching in Arabidopsis Roots

Histone proteins play an important role in determining chromatin structure and gene expression. Studies in several systems have established that histones are in continuous turnover within the chromatin. It is therefore important to quantitatively measure the binding dynamics of these proteins in vivo. Photobleaching-based approaches such as fluorescence recovery after photobleaching (FRAP) are advantageous in that they are applied to living cells at a single cell level. In this chapter, I provide a detailed experimental protocol on how to perform histone FRAP experiments in Arabidopsis thaliana roots and how to analyze the most important parameters.