Ccs1, a Nuclear Gene Required for the Post-translational Assembly of Chloroplast c-Type Cytochromes

Inoué, Kaori; Dreyfuss, Beth Welty; Kindle, Karen L.; Stern, David B.; Merchant, Sabeeha; Sodeinde, Ola A.

doi:10.1074/jbc.272.50.31747

Cited by 60 publications

(44 citation statements)

References 63 publications

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“…The strain was proposed to be defective in c-type cytochrome synthesis based on a hallmark pleiotropic deficiency in cyt f and cyt c 6 (47). Nevertheless, the relationship to previously characterized CCS loci (44) could not be ascertained by classical genetic methodologies because strain ccs1-5::NIT1 could not mate.…”

Section: Resultsmentioning

confidence: 99%

“…Strains and Culture Conditions-C. reinhardtii wild-type strain CC-125 (MTϩ) and mutant strains ccsA-B6 (CC-2695/CC-2934), ccs1-ac206 (CC-939/CC-1112), ccs1-2 (CC-3422/3423), ccs1-3 (CC-3424/CC-3425), ccs1-4 (CC-3426), abf3 (now ccs1-5::NIT1), ccs2-1 to ccs2-5 (CC-3428 to CC-3437), ccs3-F18 (CC-3092/CC-3093), ccs4-F2D8 (CC-3910/CC-3720), and ccs5-1::ARG7 (CC-3717/CC-3718), described previously (4,43,45,47,56,57), can be obtained from the Chlamydomonas Genetics Center (Duke University, Durham, NC). Arginine-auxotrophic strain arg7cw15A used for insertional mutagenesis was obtained from Prof. J.-D. Rochaix, University of Geneva, Switzerland.…”

Section: Methodsmentioning

confidence: 99%

“…Protein Preparation and Analysis-Cytochromes were detected after freeze-thaw fractionation and analysis of electrophoretically separated supernatant and pellet fractions by immunodecoration or by heme staining as described previously (43,47,65). Enriched thylakoid membrane fractions were prepared from sonicated cell lysates and analyzed immediately by denaturing PAGE according to Ref.…”

Section: Methodsmentioning

confidence: 99%

“…Two of these have been identified molecularly. CcsA, encoded by the ccsA locus (46), is a multiple membrane-spanning protein and contains the tryptophan-rich motif with the "WWD" signature first noted in CcmC and CcmF of system I (4,21,46), and Ccs1, which also displays characteristic features of a membrane protein (47). Ccs1 lacks any domains or structural features that might speak to a specific chemical function, and it appears to be unique to system II (20,47).…”

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confidence: 99%

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Functional Analysis of a Divergent System II Protein, Ccs1, Involved in c-Type Cytochrome Biogenesis

Dreyfuss

Hamel

Nakamoto

et al. 2003

Journal of Biological Chemistry

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The Ccs1 gene, encoding a highly divergent novel component of a system II type c-type cytochrome biogenesis pathway, is encoded by the previously defined CCS1 locus in Chlamydomonas reinhardtii. phoA and lacZ␣ bacterial topological reporters were used to deduce a topological model of the Synechocystis sp. 6803 Ccs1 homologue, CcsB. CcsB, and therefore by analogy Ccs1, possesses a large soluble lumenal domain at its C terminus that is tethered in the thylakoid membrane by three closely spaced transmembrane domains in the N-terminal portion of the protein. Molecular analysis of ccs1 alleles reveals that the entire C-terminal soluble domain is essential for Ccs1 function and that a stromal loop appears to be important in vivo, at least for maintenance of Ccs1. Site-directed mutational analysis reveals that a single histidine (His 274 ) within the last transmembrane domain, preceding the large lumenal domain, is required for c-type cytochrome assembly, whereas an invariant cysteine residue (Cys 199 ) is shown to be nonessential. Ccs1 is proposed to interact with other Ccs components based on its reduced accumulation in ccs2, ccs3, ccs4, and ccsA strains.

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Section: Resultsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

mentioning

confidence: 99%

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Functional Analysis of a Divergent System II Protein, Ccs1, Involved in c-Type Cytochrome Biogenesis

Dreyfuss

Hamel

Nakamoto

et al. 2003

Journal of Biological Chemistry

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“…For example, transcripts encoding proteins of the photosynthetic apparatus, such as CrPSAD (At1g03130/ At4g02770) and CrLHCA1 (At3g54890), are among the most abundant in Chlamydomonas (3200 and 4000 RPKM, respectively, in cells grown photoheterotrophically) (47). In contrast, regulatory proteins or assembly factors, such as AtMBB1 (At3g17040), an mRNA maturation factor for psbB (87), and CrCCS1 (At1g49380), which catalyzes the covalent attachment of heme to c-type cytochromes (88), are generally present in lower amounts, which is reflected by low mRNA abundances (ϳ16 and ϳ15 RPKM, respectively, for Chlamydomonas). The fact that many mRNAs and proteins have been identified through molecular screens that more readily recover abundant targets explains why many characterized proteins in the K and KI categories are encoded by high abundance transcripts.…”

Section: Functional Meta-analysis Of Rna Abundancementioning

confidence: 99%

The GreenCut2 Resource, a Phylogenomically Derived Inventory of Proteins Specific to the Plant Lineage

Karpowicz

Prochnik

Grossman

et al. 2011

Journal of Biological Chemistry

121

152

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The plastid is a defining structure of photosynthetic eukaryotes and houses many plant-specific processes, including the light reactions, carbon fixation, pigment synthesis, and other primary metabolic processes. Identifying proteins associated with catalytic, structural, and regulatory functions that are unique to plastid-containing organisms is necessary to fully define the scope of plant biochemistry. Here, we performed phylogenomics on 20 genomes to compile a new inventory of 597 nucleus-encoded proteins conserved in plants and green algae but not in non-photosynthetic organisms. 286 of these proteins are of known function, whereas 311 are not characterized. This inventory was validated as applicable and relevant to diverse photosynthetic eukaryotes using an additional eight genomes from distantly related plants (including Micromonas, Selaginella, and soybean). Manual curation of the known proteins in the inventory established its importance to plastid biochemistry. To predict functions for the 52% of proteins of unknown function, we used sequence motifs, subcellular localization, co-expression analysis, and RNA abundance data. We demonstrate that 18% of the proteins in the inventory have functions outside the plastid and/or beyond green tissues. Although 32% of proteins in the inventory have homologs in all cyanobacteria, unexpectedly, 30% are eukaryote-specific. Finally, 8% of the proteins of unknown function share no similarity to any characterized protein and are plant lineage-specific. We present this annotated inventory of 597 proteins as a resource for functional analyses of plant-specific biochemistry.The plastid is an organelle in plants and algae that evolved from a photosynthetic cyanobacterium after it was engulfed by an ancestral eukaryotic cell over 1.5 billion years ago (1, 2). How the endosymbiont became integral to host cell functions and evolved into a plastid is still under debate (3), but functions localized to the present day plastid depend on both plastid-and nucleus-encoded proteins. The latter are synthesized in the cytoplasm and imported into the organelle by a specific multiprotein complex composed of the translocon of the outer and inner chloroplast envelope membrane (TOC 4 and TIC, respectively) proteins (4, 5). Over 2000 proteins are estimated to be located in the plastid with the vast majority (Ͼ90%) encoded by genes in the nucleus (6 -9). Many of the nucleus-encoded proteins that function within plastids are conserved among photosynthetic organisms. These conserved proteins function in processes such as the capture and utilization of excitation energy, carbohydrate metabolism, and the synthesis of key cellular metabolites (such as lipids, isoprenoids, pigments, and amino acids). Interestingly, however, many plastid-localized proteins have not yet been assigned a specific biochemical function.The increasing availability of sequence information from diverse organisms has allowed the application of comparative genomics, or phylogenomics, to discover proteins specific to bacteria (...

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Recent Developments on Genetic Engineering of Microalgae for Biofuels and Bio‐Based Chemicals

Tan

Kao

et al. 2017

Biotechnology Journal

186

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Microalgae serve as a promising source for the production of biofuels and bio-based chemicals. They are superior to terrestrial plants as feedstock in many aspects and their biomass is naturally rich in lipids, carbohydrates, proteins, pigments, and other valuable compounds. Due to the relatively slow growth rate and high cultivation cost of microalgae, to screen efficient and robust microalgal strains as well as genetic modifications of the available strains for further improvement are of urgent demand in the development of microalgae-based biorefinery. In genetic engineering of microalgae, transformation and selection methods are the key steps to accomplish the target gene modification. However, determination of the preferable type and dosage of antibiotics used for transformant selection is usually time-consuming and microalgal-strain-dependent. Therefore, more powerful and efficient techniques should be developed to meet this need. In this review, the conventional and emerging genome-editing tools (e.g., CRISPR-Cas9, TALEN, and ZFN) used in editing the genomes of nuclear, mitochondria, and chloroplast of microalgae are thoroughly surveyed. Although all the techniques mentioned above demonstrate their abilities to perform gene editing and desired phenotype screening, there still need to overcome higher production cost and lower biomass productivity, to achieve efficient production of the desired products in microalgal biorefineries.

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Ccs1, a Nuclear Gene Required for the Post-translational Assembly of Chloroplast c-Type Cytochromes

Cited by 60 publications

References 63 publications

Functional Analysis of a Divergent System II Protein, Ccs1, Involved in c-Type Cytochrome Biogenesis

Functional Analysis of a Divergent System II Protein, Ccs1, Involved in c-Type Cytochrome Biogenesis

The GreenCut2 Resource, a Phylogenomically Derived Inventory of Proteins Specific to the Plant Lineage

Recent Developments on Genetic Engineering of Microalgae for Biofuels and Bio‐Based Chemicals

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