An Animal-Like Cryptochrome Controls the <i>Chlamydomonas</i> Sexual Cycle

Zou, Yangjun; Wenzel, Sandra; Müller, Nico; Prager, Katja; Jung, Elke‐Martina; Kothe, Erika; Kottke, Tilman; Mittag, Maria

doi:10.1104/pp.17.00493

Cited by 37 publications

(44 citation statements)

References 64 publications

(150 reference statements)

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“…29 We found that this recombination is in competition with protonation of FAD •to form the neutral, red light-absorbing radical FADH • that is the primary target for CraCRY-based red light responses of Chlamydomonas cells. 21,22,104 The protonation was accelerated and hence more efficient at lower pH (see Figure S2D and SI, Section S2.2 for more details), explaining a previous observation 23 Remarkably, on a time scale up to a few nanoseconds, there are less losses by recombination in in the Y373F mutant protein (~20%) than in WT (~40%; Figures 3A and 3C). This may indicate that the .…”

Section: ~60%supporting

confidence: 69%

“…In contrast to other cryptochromes, CraCRY appears to be capable of inducing a genetic response not only to blue, but also to red light. [20][21][22] This feature is probably related to another unique property of CraCRY, the very efficient formation and stabilization of its semireduced (red light-absorbing) flavin cofactor (FADH • ) that can be easily accumulated under blue light illumination and lives for seconds to minutes (depending on pH). 20,23 This process relies on the oxidation of the phenolic moiety of the tyrosine residue Y 373 as its mutation to phenylalanine abolishes this effect.…”

Section: Introductionmentioning

confidence: 99%

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Ultrafast Oxidation of a Tyrosine by Proton-Coupled Electron Transfer Promotes Light Activation of an Animal-like Cryptochrome

et al. 2019

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The animal-like cryptochrome of Chlamydomonas reinhardtii (CraCRY) is a recently discovered photoreceptor that controls the transcriptional profile and sexual life cycle of this alga by both blue and red light. CraCRY has the uncommon feature of efficient formation and longevity of the semi-reduced neutral form of its FAD cofactor upon blue light illumination. Tyrosine Y 373 plays hereby a crucial role by elongating as fourth member the electron transfer (ET) chain that comprises the tryptophan triad otherwise found in most other cryptochromes and DNA photolyases. Here, we report the full mechanism of light-induced FADH • formation in CraCRY using transient absorption spectroscopy from hundreds of femtoseconds to seconds. Electron transfer starts from ultrafast reduction of excited FAD to FAD •by the proximal tryptophan (0.4 ps) and is followed by delocalized migration of the produced WH •+ radical along the tryptophan triad (3.7 and 55 ps). Oxidation of Y 373 by coupled ET to WH •+ and deprotonation then proceeds in ~800 ps, without any significant kinetic isotope effect, nor a pH effect between pH 6.5 and 9.0. The FAD •-/Y 373 • pair is formed with high quantum yield (~60%); its intrinsic decay by recombination is slow (~50 ms), favoring reduction of Y 373 • by extrinsic agents and protonation of FAD •to form the long-lived, red-light absorbing FADH • species. Possible mechanisms of tyrosine oxidation by ultrafast proton-coupled ET in CraCRY, a process about 40 times faster than the archetypal tyrosine-Z oxidation in photosystem II, are discussed in detail.

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Section: ~60%supporting

confidence: 69%

Section: Introductionmentioning

confidence: 99%

Ultrafast Oxidation of a Tyrosine by Proton-Coupled Electron Transfer Promotes Light Activation of an Animal-like Cryptochrome

et al. 2019

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“…The isolation and manipulation of zygotes are facilitated by plating mating mixtures on 4% agar plates, as zygotes adhere strongly to the surface of this medium. Zygotes are later induced to germinate (undergo meiosis) via transfer onto rich medium in the light, which is perceived by the blue light photoreceptors cryptochrome and phototropin (Huang and Beck, 2003;Müller et al, 2017;Zou et al, 2017). Chlamydomonas can be used for tetrad analysis via the dissection of the four germinated meiotic products, as they carry one or the other mating type, which segregate in a 2:2 ratio.…”

Section: Reproductive Cyclementioning

confidence: 99%

A Series of Fortunate Events: Introducing Chlamydomonas as a Reference Organism

2019

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The unicellular alga Chlamydomonas reinhardtii is a classical reference organism for studying photosynthesis, chloroplast biology, cell cycle control, and cilia structure and function. It is also an emerging model for studying sensory cilia, the production of high-value bioproducts, and in situ structural determination. Much of the early appeal of Chlamydomonas was rooted in its promise as a genetic system, but like other classic model organisms, this rise to prominence predated the discovery of the structure of DNA, whole-genome sequences, and molecular techniques for gene manipulation. The haploid genome of C. reinhardtii facilitates genetic analyses and offers many of the advantages of microbial systems applied to a photosynthetic organism. C. reinhardtii has contributed to our understanding of chloroplast-based photosynthesis and cilia biology. Despite pervasive transgene silencing, technological advances have allowed researchers to address outstanding lines of inquiry in algal research. The most thoroughly studied unicellular alga, C. reinhardtii, is the current standard for algal research, and although genome editing is still far from efficient and routine, it nevertheless serves as a template for other algae. We present a historical retrospective of the rise of C. reinhardtii to illuminate its past and present. We also present resources for current and future scientists who may wish to expand their studies to the realm of microalgae. WHY ALGAE (IN GENERAL) AND CHLAMYDOMONAS (SPECIFICALLY)? Algae represent a very large and diverse polyphyletic group of photosynthetic eukaryotes (Blaby-Haas and Merchant, 2019). They occupy all possible ecological niches on the planet, and therefore constitute a potential reservoir of untapped functional capabilities for adaptation to the environment. Algae are primary producers that contribute ;50% of total carbon fixation worldwide (Field et al., 1998), which makes their study fundamental to our understanding of global primary production and carbon flux. They also offer a low-cost option for the large-scale production of high-value molecules, since algae only require water, salts, air, and light. Unicellular algae such as the ciliated green alga Chlamydomonas reinhardtii offer high signal-to-noise during experiments due to the ease of growth in controlled medium and environments (temperature and light regimes) and the homogenous nature of the cultures, and they grow much more rapidly than classic plant models. With its haploid genome, C. reinhardtii is well suited for classical genetics, as loss-of-function mutations are immediately expressed and more likely lead to observable phenotypes compared with diploid organisms. C. reinhardtii not only responds to light, but it also anticipates environmental transitions like dawn and dusk under the supervision of a circadian system, which coordinates cell division, photosynthesis, and cilia biogenesis, representing three fundamental research topics (Noordally and Millar, 2015). Other topics of research using C. reinhardtii include t...

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“…Among the genes associated with light sensing in Chlamydomonas, cryptochromes and phototropin appear to be obvious candidates to play roles in blue-light-dependent regulatory mechanisms (Huang et al, 2002;Zorin et al, 2009;Ahmad, 2016;Petroutsos et al, 2016;Duanmu et al, 2017Zou et al, 2017). Among the five genes encoding cryptochrome (CRY) photoreceptors (for a recent review on algal CRYs, see Duanmu et al, 2017;Kottke et al, 2017), expression levels for the gene encoding plant CRY (pCRY) are highest, peak in the dark, and are rapidly repressed upon the onset of light.…”

Section: Hmox1 Is Dispensable For Light-dependent Transcript Accumulamentioning

confidence: 99%

Bilin-Dependent Photoacclimation in Chlamydomonas reinhardtii

et al. 2017

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In land plants, linear tetrapyrrole (bilin)-based phytochrome photosensors optimize photosynthetic light capture by mediating massive reprogramming of gene expression. But, surprisingly, many green algal genomes lack phytochrome genes. Studies of the heme oxygenase mutant (hmox1) of the green alga Chlamydomonas reinhardtii suggest that bilin biosynthesis in plastids is essential for proper regulation of a nuclear gene network implicated in oxygen detoxification during dark-to-light transitions. hmox1 cannot grow photoautotrophically and photoacclimates poorly to increased illumination. We show that these phenotypes are due to reduced accumulation of photosystem I (PSI) reaction centers, the PSI electron acceptors 59-monohydroxyphylloquinone and phylloquinone, and the loss of PSI and photosystem II antennae complexes during photoacclimation. The hmox1 mutant resembles chlorophyll biosynthesis mutants phenotypically, but can be rescued by exogenous biliverdin IXa, the bilin produced by HMOX1. This rescue is independent of photosynthesis and is strongly dependent on blue light. RNA-seq comparisons of hmox1, genetically complemented hmox1, and chemically rescued hmox1 reveal that tetrapyrrole biosynthesis and known photoreceptor and photosynthesis-related genes are not impacted in the hmox1 mutant at the transcript level. We propose that a bilin-based, bluelight-sensing system within plastids evolved together with a bilin-based retrograde signaling pathway to ensure that a robust photosynthetic apparatus is sustained in light-grown Chlamydomonas.

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An Animal-Like Cryptochrome Controls the Chlamydomonas Sexual Cycle

Cited by 37 publications

References 64 publications

Ultrafast Oxidation of a Tyrosine by Proton-Coupled Electron Transfer Promotes Light Activation of an Animal-like Cryptochrome

Ultrafast Oxidation of a Tyrosine by Proton-Coupled Electron Transfer Promotes Light Activation of an Animal-like Cryptochrome

A Series of Fortunate Events: Introducing Chlamydomonas as a Reference Organism

Bilin-Dependent Photoacclimation in Chlamydomonas reinhardtii

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