Lars Sjögren scite author profile

In contrast with the model Escherichia coli Clp protease, the ATP-dependent Clp protease in higher plants has a remarkably diverse proteolytic core consisting of multiple ClpP and ClpR paralogs, presumably arranged within a dual heptameric ring structure. Using antisense lines for the nucleus-encoded ClpP subunit, ClpP6, we show that the Arabidopsis thaliana Clp protease is vital for chloroplast development and function. Repression of ClpP6 produced a proportional decrease in the Clp proteolytic core, causing a chlorotic phenotype in young leaves that lessened upon maturity. Structural analysis of the proteolytic core revealed two distinct subcomplexes that likely correspond to single heptameric rings, one containing the ClpP1 and ClpR1-4 proteins, the other containing ClpP3-6. Proteomic analysis revealed several stromal proteins more abundant in clpP6 antisense lines, suggesting that some are substrates for the Clp protease. A proteolytic assay developed for intact chloroplasts identified potential substrates for the stromal Clp protease in higher plants, most of which were more abundant in young Arabidopsis leaves, consistent with the severity of the chlorotic phenotype observed in the clpP6 antisense lines. The identified substrates all function in more general housekeeping roles such as plastid protein synthesis, folding, and quality control, rather than in metabolic activities such as photosynthesis.

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Inactivation of the clpC1 Gene Encoding a Chloroplast Hsp100 Molecular Chaperone Causes Growth Retardation, Leaf Chlorosis, Lower Photosynthetic Activity, and a Specific Reduction in Photosystem Content

Sjögren

MacDonald²,

Sutinen³

et al. 2004

133

136

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ClpC is a molecular chaperone of the Hsp100 family. In higher plants there are two chloroplast-localized paralogs (ClpC1 and ClpC2) that are approximately 93% similar in primary sequence. In this study, we have characterized two independent Arabidopsis (Arabidopsis thaliana) clpC1 T-DNA insertion mutants lacking on average 65% of total ClpC content. Both mutants display a retarded-growth phenotype, leaves with a homogenous chlorotic appearance throughout all developmental stages, and more perpendicular secondary influorescences. Photosynthetic performance was also impaired in both knockout lines, with relatively fewer photosystem I and photosystem II complexes, but no changes in ATPase and Rubisco content. However, despite the specific drop in photosystem I and photosystem II content, no changes in leaf cell anatomy or chloroplast ultrastructure were observed in the mutants compared to the wild type. Previously proposed functions for envelope-associated ClpC in chloroplast protein import and degradation of mistargeted precursors were examined and shown not to be significantly impaired in the clpC1 mutants. In the stroma, where the majority of ClpC protein is localized, marked increases of all ClpP paralogs were observed in the clpC1 mutants but less variation for the ClpR paralogs and a corresponding decrease in the other chloroplast-localized Hsp100 protein, ClpD. Increased amounts of other stromal molecular chaperones (Cpn60, Hsp70, and Hsp90) and several RNA-binding proteins were also observed. Our data suggest that overall ClpC as a stromal molecular chaperone plays a vital role in chloroplast function and leaf development and is likely involved in photosystem biogenesis.

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An Arabidopsis thaliana virescent mutant reveals a role for ClpR1 in plastid development

et al. 2006

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The ATP-dependent Clp protease has been well-characterized in Escherichia coli, but knowledge of its function in higher plants is limited. In bacteria, this two-component protease consists of a Ser-type endopeptidase ClpP, which relies on the ATP-dependent unfolding activity from an Hsp100 molecular chaperone to initiate protein degradation. In the chloroplasts of higher plants, multiple isoforms of the proteolytic subunit exist, with Arabidopsis having five ClpPs and four ClpP-like proteins termed ClpR predicted in its genome. In this work we characterized an Arabidopsis mutant impaired in one subunit of the chloroplast-localized Clp protease core, ClpR1. clpR1-1, a virescent mutant, carries a pre-mature stop codon in the clpR1 gene, resulting in no detectable ClpR1 protein. The accumulation of several chloroplast proteins, as well as most of the chloroplast-localized Clp protease subunits, is inhibited in clpR1-1. Unexpectedly, some plastid-encoded proteins do not accumulate, although their transcripts accumulate to wild-type levels. Maturation of 23S and 4.5S chloroplast ribosomal RNA (cp-rRNA) is delayed in clpR1-1, and both RNAs accumulate as higher molecular weight precursors. Also, chloroplasts in clpR1-1 are smaller than in wild type and have fewer thylakoid membranes with smaller grana stacks. We propose that a ClpR1-containing activity is required for chloroplast development and differentiation and in its absence both are delayed.

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Assembly of the Chloroplast ATP-Dependent Clp Protease in Arabidopsis Is Regulated by the ClpT Accessory Proteins

Sjögren

Clarke

2011

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The ATP-dependent caseinolytic protease (Clp) is an essential housekeeping enzyme in plant chloroplasts. It is by far the most complex of all known Clp proteases, with a proteolytic core consisting of multiple catalytic ClpP and noncatalytic ClpR subunits. It also includes a unique form of Clp protein of unknown function designated ClpT, two of which exist in the model species Arabidopsis thaliana. Inactivation of ClpT1 or ClpT2 significantly reduces the amount of Clp proteolytic core, whereas loss of both proves seedling lethal under autotrophic conditions. During assembly of the Clp proteolytic core, ClpT1 first binds to the P-ring (consisting of ClpP3-6 subunits) followed by ClpT2, and only then does the P-ring combine with the R-ring (ClpP1, ClpR1-4 subunits). Most of the ClpT proteins in chloroplasts exist in vivo as homodimers, which then apparently monomerize prior to association with the P-ring. Despite their relative abundance, however, the availability of both ClpT proteins is rate limiting for the core assembly, with the addition of recombinant ClpT1 and ClpT2 increasing core content up to fourfold. Overall, ClpT appears to regulate the assembly of the chloroplast Clp protease, revealing a new and sophisticated control mechanism on the activity of this vital protease in plants.

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The ATP‐dependent Clp protease in chloroplasts of higher plants

Clarke

MacDonald

Sjögren

2005

Physiologia Plantarum

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The best‐known proteases in plastids are those that belong to families common to eubacteria. One of the first identified was the ATP‐dependent caseinolytic protease (Clp), whose structure and function have been well characterized in Escherichia coli. Plastid Clp proteins in higher plants are surprisingly numerous and diverse, with at least 16 distinct Clp proteins in the model plant Arabidopsis thaliana. Multiple paralogues exist for several of the different types of plastid Clp protein, with the most extreme being five for the proteolytic subunit ClpP. Both biochemical and genetic studies have recently begun to reveal the intricate structural interactions between the various Clp proteins, and their importance for chloroplast function and plant development. Much of the recent data suggests that the function of many of the Clp proteins probably affects more specific processes within chloroplasts, in addition to the more general ‘housekeeping’ role previously assumed.

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Lars Sjögren

Structural and Functional Insights into the Chloroplast ATP-Dependent Clp Protease in Arabidopsis

Inactivation of the clpC1 Gene Encoding a Chloroplast Hsp100 Molecular Chaperone Causes Growth Retardation, Leaf Chlorosis, Lower Photosynthetic Activity, and a Specific Reduction in Photosystem Content

An Arabidopsis thaliana virescent mutant reveals a role for ClpR1 in plastid development

Assembly of the Chloroplast ATP-Dependent Clp Protease in Arabidopsis Is Regulated by the ClpT Accessory Proteins

The ATP‐dependent Clp protease in chloroplasts of higher plants

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