Morphological plasticity in Chlamydomonas reinhardtii and acclimation to micropollutant stress.

Phytoplankton are characterized by a great phenotypic plasticity and amazing morphological variability, both playing a primary role in the acclimation to changing environments. However, there is a knowledge gap concerning the role of algal morphological plasticity in stress responses and acclimation to micropollutants. The present study aims at examining palmelloid colony formation of the green alga Chlamydomonas reinhardtii upon micropollutants exposure. Cells were exposed to four micropollutants (MPs, copper, cadmium, PFOS and paraquat) with different modes of action for a duration of 72 h. Effects of MPs on palmelloid formation, growth and physiological traits (chlorophyll fluorescence, membrane integrity and oxidative stress) were monitored by flow cytometry and fluorescence microscopy. Palmelloid formation was observed upon treatment with the four micropollutants. Number of palmelloid colonies and their size were dependent on MP concentration and exposure duration. Cells reverted to their unicellular lifestyle when colonies were harvested and inoculated in fresh medium indicating that palmelloid formation is a plastic response to micropollutants. No physiological effects of these compounds were observed in cells forming palmelloids. Palmelloid colonies accumulated lower Cd concentration than unicellular C. reinhardtii suggesting that colony formation protects the cells from MPs stress. The results show that colony formation in Chlamydomonas reinhardtii is a stress response strategy activated to face sub-lethal micropollutant concentrations.

Structures of radial spokes and associated complexes important for ciliary motility.

In motile cilia, a mechanoregulatory network is responsible for converting the action of thousands of dynein motors bound to doublet microtubules into a single propulsive waveform. Here, we use two complementary cryo-EM strategies to determine structures of the major mechanoregulators that bind ciliary doublet microtubules in Chlamydomonas reinhardtii. We determine structures of isolated radial spoke RS1 and the microtubule-bound RS1, RS2 and the nexin-dynein regulatory complex (N-DRC). From these structures, we identify and build atomic models for 30 proteins, including 23 radial-spoke subunits. We reveal how mechanoregulatory complexes dock to doublet microtubules with regular 96-nm periodicity and communicate with one another. Additionally, we observe a direct and dynamically coupled association between RS2 and the dynein motor inner dynein arm subform c (IDAc), providing a molecular basis for the control of motor activity by mechanical signals. These structures advance our understanding of the role of mechanoregulation in defining the ciliary waveform.

Structure of the radial spoke head and insights into its role in mechanoregulation of ciliary beating.

Motile cilia power cell locomotion and drive extracellular fluid flow by propagating bending waves from their base to tip. The coordinated bending of cilia requires mechanoregulation by the radial spoke (RS) protein complexes and the microtubule central pair (CP). Despite their importance for ciliary motility across eukaryotes, the molecular function of the RSs is unknown. Here, we reconstituted the Chlamydomonas reinhardtii RS head that abuts the CP and determined its structure using single-particle cryo-EM to 3.1-Å resolution, revealing a flat, negatively charged surface supported by a rigid core of tightly intertwined proteins. Mutations in this core, corresponding to those involved in human ciliopathies, compromised the stability of the recombinant complex, providing a molecular basis for disease. Partially reversing the negative charge on the RS surface impaired motility in C. reinhardtii. We propose that the RS-head architecture is well-suited for mechanoregulation of ciliary beating through physical collisions with the CP.

Produção de proteínas heterólogas em microalga / Production of heterologous protein in microalga

O objetivo desta tese foi explorar o sistema de produção de proteínas heterólogas em microalga com ênfase em Chlamydomonas reinhardtii por meio de: (1) desenvolvimento de um fotobiorreator tubular fechado de escala laboratorial, utilizando técnicas de manufatura digital; (2) avaliação de 7 diferentes proteínas fluorescentes (mTagBFP, Cerulean, Emerald, crGFP, cOFP, tdTomato e mCherry), como sistema reporter de secreção de proteínas em microalga; (3) avaliação do fotobiorreator desenvolvido utilizando cultivo de cepas recombinantes; (4) desenvolvimento de novos peptídeos sinais para secreção de proteínas em C. reinhardtii; (5) avaliação da produção de um biofármaco (hialuronidase) em microalgas, por meio da expressão de duas isoenzimas codificadas pelos genes HYA1 e SPAM1 em C. reinhardtii. O fotobiorreator tubular foi avaliado quanto a sua capacidade de resistir ao processo de esterilização por autoclavação e seu desempenho por meio do cultivo de cepa recombinante secretando mCherry. A fluorescência das proteínas fluorescentes foi medida por leitor de placas de fluorescência e visualizada intracelularmente por microscopia confocal de fluorescência. A atividade de hialuronidase foi determinada através de um ensaio enzimático turbidimétrico. O desenvolvimento do fotobiorreator resultou em um sistema fechado resistente a autoclavação, com capacidade de cultivo de cepas recombinantes de C. reinhardtii. Esse fotobiorreator proporcionou uma produtividade máxima de 10 mg/L.d de mCherry da cepa recombinante em sistema fechado, com velocidade específica de crescimento máxima de 1,27 d-1 para a cepa recombinante testada. Todas as proteínas fluorescentes avaliadas apresentaram capacidade de secreção por C. reinhardtii, com diferentes níveis de interferências em sua medição, permitindo a escolha da mCherry como proteína reporter. Entre os peptídeos sinais avaliados (quatro descritos na literatura - BiP, ARS1, CAH1 e IBP1 - e seis preditos), o peptídeo predito "SP5" foi o que apresentou maior capacidade de secreção, determinado por níveis de fluorescência no sobrenadante. A avaliação dos peptídeos sinais constatou a necessidade de explorar o desenvolvimento de sistemas de expressão (e.g. vetores de expressão) aliados a análises computacionais, como o SignalP 4.0. Por último, os dados desse estudo mostram que C. reinhardtii transformadas com o vetor de expressão foi capaz de produzir as duas isoformas de hialuronidase em sua forma ativa, evidenciando a capacidade desse sistema para a produção de biofármacos. Portanto, nesta tese o sistema de expressão de proteínas heterólogas baseado em microalgas foi explorado, atingindo os objetivos propostos. O fotobiorreator desenvolvido tem a capacidade de esterilização em escala laboratorial (1) e em cultivo com cepa recombinante propiciou elevada produtividade (3). As proteínas vermelhas fluorescentes apresentaram-se como as proteínas com menores interferências para estudos de secreção em C. reinhardtii (2). Além disso, o peptídeo predito SP5 apresentou o melhor desempenho na secreção de proteínas (4) e o vetor de expressão empregado permitiu a identificação de cepas produtoras de biofármaco hialuronidase (5). Portanto, o sistema de produção de proteínas heterólogas por microalgas é um sistema promissor e poderá permitir, utilizando sistemas de secreção, obter proteínas de alto valor comercial a baixos custos, empregando a secreção e técnicas de cultivo como a fermentação extrativa

In this thesis, the heterologous protein production in microalgae with emphasis on Chlamydomonas reinhardtii was explored through: (1) development of a laboratory scale closed tubular photobioreactor using digital manufacturing techniques; (2) evaluation of different fluorescent proteins (mTagBFP, Cerulean, Emerald, crGFP, cOFP, tdTomato and mCherry) as a reporter system for protein secretion in microalgae (3) evaluation of photobioreactor developed using recombinant strains culture; (4) development of new signals peptides for protein secretion in C. reinhardtii (5) expression evaluation of a biopharmaceutical (Hyaluronidase) in microalgae, through the expression of two isoenzymes encoded by the HYA1 and SPAM1 genes in C. reinhardtii. The tubular photobioreactor was evaluated for its ability to resist sterilization process by autoclaving and its performance by culturing recombinant strain secreting mCherry. Fluorescence of fluorescent proteins was measured by fluorescence plate reader and observed intracellularly by confocal fluorescence microscopy. The hyaluronidase activity was determined by a turbidimetric enzymatic assay. The development of the photobioreactor resulted in a closed system resistant to autoclaving, capable of culturing recombinant strains of C. reinhardtii. This recombinant strain achieved a maximum productivity of 10 mg/L.day of mcherry in the closed system, with a maximum growth rate of 1.27 d-1 for the recombinant strain tested. All the fluorescent proteins evaluated had C. reinhardtii secretion capacity, with different interference levels in their measurement, allowing the selection of mCherry as a reporter protein. Among the evaluated peptides (four described in the literature - BiP, ARS1, CAH1 and IBP1 - and six predicted), the predicted peptide "SP5" was the one that presented greater capacity of secretion, determined by levels of fluorescence in the supernatant. The results of this study point out the need to explore the development of biological systems (i.e., expression vectors) allied to computational analysis. Finally, the data from this study showed that C. reinhardtii could produce the two isoforms of hyaluronidase in its active form, evidencing the capacity of this system to produce biopharmaceuticals. Therefore, in this thesis the heterologous protein expression system based on microalgae was explored, reaching the proposed objectives. The developed photobioreator has sterilization capabilityin laboratorial scale (1) and in culture with recombinant strain had high productivity (3). The red fluorescent proteins was found as the most suitable proteins for studies of secretion in C. reinhardtii with lower interference levels(2). In addition, the predicted SP5 peptide showed the best performance in protein secretion (4) and the expression vector employed allowed the identification of strains producing biopharmaceutical hyaluronidase (5). Therefore, the system of heterologous proteins production by microalgae is promising and will allow, using secretion systems, to obtain proteins of high commercial value at low costs, using secretion and cultivation techniques such as extractive fermentation

The awesome power of dikaryons for studying flagella and basal bodies in Chlamydomonas reinhardtii.

Cilia/flagella and basal bodies/centrioles play key roles in human health and homeostasis. Among the organisms used to study these microtubule-based organelles, the green alga Chlamydomonas reinhardtii has several advantages. One is the existence of a temporary phase of the life cycle, termed the dikaryon. These cells are formed during mating when the cells fuse and the behavior of flagella from two genetically distinguishable parents can be observed. During this stage, the cytoplasms mix allowing for a defect in the flagella of one parent to be rescued by proteins from the other parent. This offers the unique advantage of adding back wild-type gene product or labeled protein at endogenous levels that can used to monitor various flagellar and basal body phenotypes. Mutants that show rescue and ones that fail to show rescue are both informative about the nature of the flagella and basal body defects. When rescue occurs, it can be used to determine the mutant gene product and to follow the temporal and spatial patterns of flagellar assembly. This review describes many examples of insights into basal body and flagellar proteins' function and assembly that have been discovered using dikaryons and discusses the potential for further analyses.

The heme-binding protein SOUL3 of Chlamydomonas reinhardtii influences size and position of the eyespot.

The flagellated green alga Chlamydomonas reinhardtii has a primitive visual system, the eyespot. It is situated at the cells equator and allows the cell to phototax. In a previous proteomic analysis of the eyespot, the SOUL3 protein was identified among 202 proteins. Here, we investigate the properties and functions of SOUL3. Heterologously expressed SOUL3 is able to bind specifically to hemin. In C. reinhardtii, SOUL3 is expressed at a constant level over the diurnal cycle, but forms protein complexes that differ in size during day and night phases. SOUL3 is primarily localized in the eyespot and it is situated in the pigment globule layer thereof. This is in contrast to the channelrhodopsin photoreceptors, which are localized in the plasma membrane region of the eyespot. Knockdown lines with a significantly reduced SOUL3 level are characterized by mislocalized eyespots, a decreased eyespot size, and alterations in phototactic behavior. Mislocalizations were either anterior or posterior and did not affect association with acetylated microtubules of the daughter four-membered rootlet. Our data suggest that SOUL3 is involved in the organization and placement of the eyespot within the cell.

Mitochondrial fusion in Chlamydomonas reinhardtii zygotes.

Mitochondria are dynamic organelles that were found to fuse and divide in many different cell types. Mitochondrial fusion plays important roles in maintenance of respiratory capacity, dissipation of metabolic energy, and inheritance of mitochondrial DNA. While the molecular machinery of mitochondrial fusion has been characterized in great detail in yeast and mammals, only little is known about mitochondrial fusion in higher plants and algae. We asked whether mitochondrial fusion can be observed in the unicellular green alga Chlamydomonas reinhardtii. Mitochondria were stained with fluorescent dyes in gametes, and mixing of fluorescent markers was detected by fluorescence microscopy in zygotes indicating fusion. Mitochondrial fusion was observed in wild type zygotes, and also in respiratory mutants, albeit with less efficiency. We conclude that mitochondria readily fuse in green algae.