Reverse genetics of PsaA and PsaB to dissect their function in binding and electron transfer from plastocyanin or cytochrome c6 to the core of photosystem 1

Sommer, Frederik.

Unknown Date

University, Diss., 2004--Jena.

Reakcia na poškodenie DNA v zelených riasach Chlamydomonas reinhardtii a Scenedesmus quadricauda / DNA damage response in green algae Chlamydomonas reinhardtii and Scenedesmus quadricauda

HLAVOVÁ, Monika

January 2011

The effect of FdUrd, zeocin, caffeine and their combination on the cell cycle of green algae Chlamydomonas reinhardtii and Scenedesmus quadricauda and response of these model organisms to DNA damage were studied. Both, FdUrd and zeocin, caused DNA damage that led to cell cycle arrest in these algae. In contrast, caffeine partially abolished G2 phase block imposed by zeocin. Protein levels of three crucial cell cycle regulators - CdkA, CdkB and Wee1 kinases were measured to identify mechanisms controlling reaction to DNA damage.

Rubisco biogenesis and assembly in Chlamydomonas reinhardtii / Biogenèse et assemblage de Rubisco chez Chlamydomonas reinhardtii

Wietrzynski, Wojciech

17 October 2017

La nécessité de coordonner l’expression des gènes provenant de génomes différents chez les plantes a conduit à l’émergence de mécanismes imposant un contrôle nucléaire sur l’expression génétique de l’organelle. Des signaux antérogrades, exercés par des protéines reconnaissant des séquences spécifiques, existent en parallèle avec un contrôle des synthèses chloroplastiques dépendant de l’assemblage (CES). Ensemble, ils coordonnent la formation stoichiométrique des complexes photosynthétiques.La Ribulose bisphosphate carboxylase/oxygénase (Rubisco) est une enzyme localisée dans le chloroplaste qui contient deux sous-unités. La grande sous-unité (LSU) et la petite sous-unité (SSU) sont codées par les génomes chloroplastique et nucléaire respectivement. Elles s’assemblent dans le stroma du chloroplaste pour former une holoenzyme hexadécamérique (LSU8SSU8). Pendant mon travail au laboratoire, j’ai tenté de décrire les étapes régulatrices majeures de la synthèse de la Rubisco chez Chlamydomonas reinhardtii en me focalisant sur la régulation post-transcriptionelle de la LSU.J’ai montré que la protéine PPR – MRL1 est un facteur limitant pour l’accumulation de l’ARN messager de rbcL. Bien qu’il ait été décrit précédemment comme un facteur stabilisateur du transcrit susnommé, MRL1 s’est révélé avoir un rôle dans la traduction.J’ai par ailleurs démontré que chez Chlamydomonas, l’expression de la Rubisco est contrôlée par la présence de la SSU. En son absence, la traduction de rbcL est inhibée par son propre produit – la grande sous-unité non assemblée. J’ai pu montrer qu’un intermédiaire d’assemblage, constitué de LSU en complexe avec sa chaperonne RAF1, est nécessaire pour cette régulation, ce qui prouve que ce processus dépend de l’état d’oligomérisation de la LSU. Parallèlement, j’ai caractérisé le devenir de la LSU non assemblée quand la régulation CES est perturbée, et grâce à cela ait contribué à améliorer la connaissance de son processus de repliement et d’assemblage. / The necessity to coordinate the expression of genes originating from different genomes within the plant cell resulted in the appearance of mechanisms imposing nuclear control over organelle gene expression. Anterograde signaling through sequence-specific trans-acting proteins (OTAFs) coexists in the chloroplast with an assembly dependent control of chloroplast synthesis (CES process) that coordinates the stoichiometric formation of photosynthetic complexes.Ribulose bisphosphate carboxylase/oxygenase (Rubisco) is a chloroplast-located carbon fixing enzyme constituted of two subunits. Large subunit (LSU) and small subunit (SSU) are encoded in the chloroplast and nuclear genomes respectively. In the stroma they assemble to form a hexadecameric holoenzyme (LSU8SSU8). In this study I tried to highlight major regulatory points of its synthesis in Chlamydomonas reinhardtii focusing on the posttranscriptional regulation of LSU.I showed that the MRL1 PPR protein is a limiting factor for rbcL mRNA accumulation. Whereas it has been previously designated as a stabilization factor for the abovementioned transcript, MRL1 appeared also to have a function in rbcL translation.Most notably, I have demonstrated that in Chlamydomonas reinhardtii Rubisco expression is controlled by the small subunit (SSU) presence. In its absence rbcL undergoes an inhibition of translation through its own product – the unassembled Rubisco large subunit. This process depends on LSU-oligomerization state as I was able to show that the presence of a high order LSU assembly intermediate bound to the RAF1 assembly chaperone is essential for the regulation to occur. In parallel I shed light on the fate of unassembled LSU in a deregulated CES context, thereby improving our understanding of the process of its folding and assembly.

Rubisco

Chlamydomonas

CES

RAF1

Assemblage

Biogenèse

Biogenesis

Assembly

Rubisco

572.8

The genetic basis of cooperative aggregation in the green alga Chlamydomonas reinhardtii

Berger, Christopher Michael

January 1900

Master of Science / Division of Biology / Bradley J. Olson / Unicellular organisms alter their behavior and morphology in response to environmental stresses, particularly in response to immediate threats to their survival. A common tactic of predator avoidance for unicellular green algae is to aggregate to form groups. We have found that the model unicellular green algae Chlamydomonas reinhardtii forms aggregates in response to the presence of the filter feeding zooplanktonic predator, Daphnia magna. Chalmydomonas is a member of the volvocine algae, a morphologically diverse group of closely related green algae that is often used to study multicellular development. We have characterized aggregation in Chlamydomonas reinhardtii and found that it is rapid, transient and induced by signals originating from the Daphnia predators. To understand the genetic basis of cooperative aggregation we used an RNA-seq approach. RNA-seq characterized the transcriptomic response by Chlamydomonas during aggregation, and we identified 131 genes are significantly differentially expressed between predated and unpredated cultures of Chlamydomonas. Several candidate genes were characterized based on existing annotations, evolutionary history and expression profile. Evolutionary relationships between candidate aggregation genes in Chlamydomonas and their orthologs in multicellular Volvocales suggest a possible role of aggregation genes in multicellular development. Our results demonstrate that Chlamydomonas dynamically alters its morphology based on its environment and identify several candidate genes for aggregation and multicellular development.

Chlamydomonas reinhardtii

Daphnia

Cooperative aggregation

Multicellular evolution

Volvocales

Predation

Physiological and molecular determinants of the Chlamydomonas reinhardtii pyrenoid

Meyer, Moritz

January 2010

Aquatic photosynthesis accounts for 50% of the global annual net primary production (NPP), despite frequent low availability and limited diffusion of CO2 in the aquatic milieu, and low affinity for CO2 by the primary carboxylating enzyme, Ribulose 1,5-bisphosphate carboxylase/oxygenase (RuBisCO). Many eukaryotic algae, and a single group of land plants, the hornworts, have an inducible carbon concentrating mechanism (CCM), to overcome these limitations. The efficiency of the CCM is improved when RuBisCO is localised to a subcellular compartment, the pyrenoid, which is hypothesised to act as a diffusion barrier for CO2 . Although the pyrenoid is a major player in global carbon balance (we estimate 10-15% of NPP), it is one of the few remaining prominent cellular features without a precise molecular or physiological definition. Under ambient CO2 , at least 90% of the cellular RuBisCO is packed into a dense matrix, together with the chaperone RuBisCO activase. Thylakoid membranes usually traverse the pyrenoid matrix, and the carboxylating substrate is thought to be delivered to the active sites of the enzyme via a carbonic anhydrase located in the lumen of these thylakoids. The mechanism of aggregation of constituents within the pyrenoid, however, still remains largely unknown. Comprehensive mutant screens have yet to reveal mutants incapable of forming pyrenoids other than those mutants with a defective RuBisCO holoenzyme, whereas DNA microarray studies uncovered little with reference to pyrenoid ultrastructure or aggregation. Taken together, this evidence raises the possibility that the basis of pyrenoid ultrastructure and aggregation lies entirely in sequence variations of RuBisCO itself. This work explored, firstly, the advantages conferred by an active CCM in hornworts and in unicellular algae, compared with the passive CO2 acquisition in most terrestrial plants. A physiological framework to CCM and pyrenoid-based photosynthesis, and isotopic discrimination, was provided by comparing the photosynthetic characteristics of selected bryophytes and algae, differing in chloroplast morphology and degrees of internalisation of gas exchanges. The results showed that on-line, carbon isotope discrimination values were a good indicator of CCM occurrence, as well as liquid-phase diffusion limitation, and biochemical limitations resulting from declining RuBisCO activity and electron transport. The methodology was used to diagnose the presence of an active CCM, and the extent of CO2 leakage. Secondly, the effect of RuBisCO sequence variations on the pyrenoid, and associated CCM, was studied using the model alga Chlamydomonas reinhardtii. The starting premise was the report by Nozaki et al. (2002) that, in some species of the family Chlamydomonaceae, a few amino acid residues within the RuBisCO large subunit (LSU) correlated strongly with pyrenoid formation. The specific roles of seven LSU residues were studied by site-directed mutagenesis. Whilst the mutations reduced the affinity of RuBisCO for CO2 and increased CO2 leakage, compared to wild-type Chlamydomonas, there was no effect on the pyrenoid phenotype. Informed by observations that Chlamydomonas mutants with a hybrid RuBisCO, composed of a native LSU, and higher plant small subunit (SSU), lacked a pyrenoid (Genkov et al., 2010), and that defined SSU alterations were neutral with respect to the pyrenoid (Genkov and Spreitzer, 2006), hitherto unexplored SSU domains were modified. A pyrenoid was successfully restored by replacing jointly the two solvent-exposed α-helices, whereas single α-helix replacements had no effect. However, leakage values indicated that the associated CCM was not fully operative, suggesting important correlates between the RuBisCO SSU and the CCM, besides the conditioning of pyrenoid formation. If the pyrenoid is partly defined by simple sequence variations in the RuBisCO SSU, as suggested by the evidence outlined in this thesis, there is the tantalising possibility that transformation of a biophysical CCM into crop plants could be a tractable approach for the future.

571.2

Investigation of heterologous expression of the non-ribosomal peptide blue pigment synthase and its activator from the nuclear genome of the model microalga Chlamydomonas reinhardtii

Shlbi, Manar

31 March 2022

The non-ribosomal peptide synthase (NRPS) blue pigment synthase (BpsA) has been shown in several heterologous hosts to mediate the production of the blue pigment indigoidine from two molecules of L-glutamine. Activation of BpsA is mediated by transfer of a coenzyme A (CoA) by a 4′-phosphopantetheinyl transferase (4′-PPTase). In this thesis, I explored heterologous co-expression of BpsA and the Pseudomonas aeruginosa 4′-PPTase (PaPcpS) and their co- localization to either cytoplasm or chloroplast stroma of the green model microalga Chlamydomonas reinhardtii. The alga represents a potentially sustainable production host for indigoidine, as it is able to grow using CO2 as a sole carbon source and (sun)light for its energy. Both heterologous proteins (BpsA and PaPcpS) could be expressed as full-length fusion proteins with either the mVenus yellow fluorescent reporter or spectinomycin resistance (aadA) selection marker in both subcellular localisations. Dual transformants were identified and subjected to multiple growth conditions to determine whether indigoidine was produced. Under no condition tested was indigoidine detected, indicating that either activation of BpsA or the catalysis of L-glutamine to indigoidine was not occurring in alga. Future work will be required to determine whether it is possible to activate the BpsA in C. reinhardtii. However, this represents the first documented example of expression of a heterologous NRPS in a eukaryotic alga and may serve as foundational work for other target NRPS expression projects.

Indigoidine

BpsA

PaPcpS

Chlamydomonas reinhardtii

non-ribosomal peptide synthase

heterologous expression

Experimental studies on the fate of diversity in heterogeneous environments

Kassen, Rees M.

January 2000

No description available.

Species diversity.

Chlamydomonas reinhardtii -- Variation.

Pseudomonas fluorescens -- Variation.

Ecological heterogeneity.

Heterologous expression of two ice binding proteins from the chloroplast genome of a high-density cultivation enabled Chlamydomonas reinhardtii strain.

Abdullah , Amna

30 April 2023

Advances in molecular biology have revolutionized the field of biotechnology and allowed the development of recombinant protein production as an alternative to harvesting proteins from their natural sources. Production of target proteins in controllable host organisms offers scalable and economic approaches to meet market needs. Current host cell expression systems vary, and each has advantages and disadvantages. Photoautotrophic organisms, like microalgae, represent alternatives to fermentative microbes with the promise of recombinant protein production from sustainable inputs like carbon dioxide as a carbon source. In this thesis, a Chlamydomonas reinhardtii strain that was recently developed for phototrophic high- density cultivation and nuclear transgene expression was used to express target recombinant proteins from its plastid genome as a demonstration of possibilities for expansion of its potential value. Here, sequences of two anti-freeze proteins, the insect Choristoneura fumiferana (CfAFP) and grass Lolium perenne ice binding protein (LpIBP), and a yellow fluorescent protein (YFP, mVenus) were adapted to algal chloroplast genome expression plasmids, transformed, and protein titers characterized under various nutrient and growth regimes in alga. Rather than antibiotic selection, transformants were selected based on photosynthesis restoration in a knock-out recipient strain. LpIBP and mVenus expression were detected by Western blot and in gel fluorescence and estimated to be expressed up to ~7.65% and ~8.41% total soluble protein, respectively, whereas expression of CfAFP was not observed in any transformant. This work forms the basis of further investigation of recombinant protein expression in C. reinhardtii in high-density antibiotic-free culture and may influence feasibility assessments of scale up processes.

chlamydomonas

reinhardtii

recombinant

protein

sustainability

antifreeze

ice-binding

Production and Optimization of Para-Hydroxybenzoic Acid (pHBA) in Algae Using Metabolic Engineering and Genomics Approaches

Saxena, Garima Girish

12 1900

Microalgae being photosynthetic and having quick growth cycles can prove to be excellent candidates as biofactories for the production of aromatic compounds like para-hydroxybenzoic acid (pHBA) that act as a monomer in liquid crystal polymers. We developed transgenic lines of the model alga Chlamydomonas reinhardtii by performing nuclear transformation using electroporation. The transgenic cell lines expressed the ubiC gene that utilized chorismate from the shikimate pathway as a substrate to produce pHBA. The maximum yield of pHBA measured in these lines was 80 mg/L. Accruing pHBA can be toxic to the cells and the mechanism by which C. reinhardtii could detoxify pHBA is not known. C. reinhardtii genome was thus scanned for sequences similar to UDP-glucosyltransferase (UGT) that can transfer the glucose moiety to pHBA, rendering it non-toxic to the cell lines. Our analysis suggested the absence of any potential UGTs that could glycosylate pHBA and detoxify it. We further performed feeding experiments to test the ability of wt-type C. reinhardtii cells to detoxify pHBA and understand its fate. C. reinhardtii cells were fed with varying concentrations of pHBA and harvested at different time intervals. The HPLC chromatograms indicated a majority of the pHBA was catabolized. Based on these results, literature was reviewed to find a suitable UGT candidate to enable the engineering of the glycosylation mechanism in the alga. A transgenic algal line with gene encoding UGT89B1 was created and fed with varying concentrations of pHBA. HPLC chromatograms from the extracts revealed the presence of phenolic glucoside. Following this, C. reinhardtii was co-transformed with ubiC and gene encoding UGT89B1; this led to the production of pHBA and further glycosylation to pHBA glucoside (phenolic glucoside). The maximum yield of pHBA yields in these cell lines was 180 mg/L. Growing C. reinhardtii lines producing pHBA on a large scale can lead to problems like contamination with bacteria and other algal species, a decline in pH, and a rise in temperature. To circumvent these problems, we explored the plausibility of using other algal strains. We analyzed the genome of Galdieria sulphuraria, a photosynthetic thermophile, that can use more than fifty different carbon sources for its growth and metabolism. We hypothesized several of these traits to have arisen by acquiring genes through horizontal gene transfer. We used a segmentation and clustering algorithm to identify regions of the genome that have atypical nucleotide composition. The atypical segments identified by the method were further analyzed using phylogenetic methods to further support claims of their alien origin. Our method identified 69 genes that were not previously reported as alien genes, some of which could be implicated in imparting resistance to environmental stress factors. Our experiments also revealed G. sulphuraria has a greater extent of alien genes compared to C. reinhardtii.

Chlamydomonas

Galdieria

Algae

para-hydroxybenzoic acid (pHBA)

Bioinformatics

A Disulfide-Reducing Pathway Required For Plastid Cytochrome c Assembly

Gabilly, Stephane T.

26 June 2012

No description available.

Biology

Disulfide reducing pathway

Cytochrome c

Chloroplast

Photosynthesis

Chlamydomonas