Abstract
Plastid transcription is crucial for plant growth and development. There exist two types of RNA polymerases in plastids: a nuclear-encoded RNA polymerase (NEP) and plastid-encoded RNA polymerase (PEP). PEP is the major RNA polymerase activity in chloroplast. Its core subunits are encoded by the plastid genome, and these are embedded into a larger complex of nuclear-encoded subunits. Biochemical and genetics analysis identified at least 12 proteins are tightly associated with the core subunit, while about 34 further proteins are associated more loosely generating larger complexes such as the transcriptionally active chromosome (TAC) or a part of the nucleoid. Domain analyses and functional investigations suggested that these nuclear-encoded factors may form several functional modules that mediate regulation of plastid gene expression by light, redox, phosphorylation, and heat stress. Genetic analyses also identified that some nuclear-encoded proteins in the chloroplast that are important for plastid gene expression, although a physical association with the transcriptional machinery is not observed. This covers several PPR proteins including CLB19, PDM1/SEL1, OTP70, and YS1 which are involved in the processing of transcripts for PEP core subunit as well as AtECB2, Prin2, SVR4-Like, and NARA5 that are also important for plastid gene expression, although their functions are unclear.
Highlights
Plastids are specific organelles in plant and algal cells that are responsible for photosynthesis and some important metabolic pathways
We focused on these nuclear-encoded factors for chloroplast transcription
The Plastid redox insensitive 2 (Prin2) is a small protein possibly involved in redox-mediated retrograde signaling in chloroplast (Kindgren et al, 2012) and the SVR4-like is a homolog of AtECB1/SVR4/MRL7, encoding a chloroplast protein essential for proper function of the chloroplast in Arabidopsis (Powikrowska et al, 2014)
Summary
Plastids are specific organelles in plant and algal cells that are responsible for photosynthesis and some important metabolic pathways. In the knockout mutants of AtECB1/SVR4/MRL7 (Qiao et al, 2011; Yu et al, 2014), PEP-Related Development Arrested 1 (PRDA1) (Qiao et al, 2013), and Delayed Greening 1 (DG1) (Chi et al, 2008), the expression of PEP-dependent chloroplast genes is severely reduced These proteins have not been identified in PEP complex by previous proteomic analyses (Krause and Krupinska, 2000; Suzuki et al, 2004; Pfalz et al, 2006; Steiner et al, 2011). These nuclearencoded proteins can be classified into several groups including
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