Expression of nuclear-encoded plastid proteins and import of those proteins into plastids are indispensable for plastid biogenesis. One possible cellular mechanism that coordinates these two essential processes is retrograde signaling from plastids to the nucleus. However, the molecular details of how this signaling occurs remain elusive. Using the plastid protein import2 mutant of Arabidopsis (Arabidopsis thaliana), which lacks the atToc159 protein import receptor, we demonstrate that the expression of photosynthesis-related nuclear genes is tightly coordinated with their import into plastids. Down-regulation of photosynthesis-related nuclear genes is also observed in mutants lacking other components of the plastid protein import apparatus. Genetic studies indicate that the coordination of plastid protein import and nuclear gene expression is independent of proposed plastid signaling pathways such as the accumulation of Mg-protoporphyrin IX and the activity of ABA INSENSITIVE4 (ABI4). Instead, it may involve GUN1 and the transcription factor AtGLK. The expression level of AtGLK1 is tightly correlated with the expression of photosynthesis-related nuclear genes in mutants defective in plastid protein import. Furthermore, the activity of GUN1 appears to down-regulate the expression of AtGLK1 when plastids are dysfunctional. Based on these data, we suggest that defects in plastid protein import generate a signal that represses photosynthesis-related nuclear genes through repression of AtGLK1 expression but not through activation of ABI4.Plastids are a diverse group of organelles that perform essential metabolic and signaling functions within all plant cells. It is generally believed that plastids originated from a unicellular photosynthetic bacterium that was taken up by a eukaryotic host cell (Dyall et al., 2004). During evolution, most of the genes encoded by the bacterial ancestor have been transferred to the host nuclear genome; for example, the plastid genome of Arabidopsis (Arabidopsis thaliana) encodes fewer than 100 open reading frames (Martin et al., 1998). Consequently, plastid biogenesis is dependent on the import of nuclear-encoded plastid proteins (Keegstra and Cline, 1999;Soll and Schleiff, 2004;Kessler and Schnell, 2006;Inaba and Schnell, 2008;Jarvis, 2008), the genes for which must be expressed at an appropriate level. For example, many of the photosynthesis-related nuclear genes that are required for chloroplast biogenesis are induced via photoreceptors, such as phytochrome, in response to light quality and quantity (Terzaghi and Cashmore, 1995), so that the photosynthesis-related proteins will be available for import into the developing chloroplasts. Other types of plastids, according to their specific metabolic functions, need other sets of nuclear-encoded proteins. Therefore, the expression of specific sets of nuclear genes and the import of their translation products are indispensable for plastid differentiation.After they have been imported into plastids, nuclear-encoded plastid proteins combi...
Many plants acquire increased freezing tolerance when they are exposed to nonfreezing temperatures of a certain duration. This process is known as cold acclimation and allows plants to protect themselves from freezing injury. A wide variety of polypeptides are induced during cold acclimation, among which is one encoded by COR15A in Arabidopsis (Arabidopsis thaliana). Previous studies showed that the COR15A gene encodes a small, plastid-targeted polypeptide that is processed to a mature form called Cor15am. In this study, we examined the biochemical properties and activities of Cor15am in more detail. We provide evidence that Cor15am localizes almost exclusively to the chloroplast stroma. In addition, the cold-regulated accumulation of Cor15am is affected by chloroplast functionality. Both gel-filtration chromatography and protein cross-linking reveal that Cor15am forms oligomers in the stroma of chloroplasts. Although Cor15am accumulates in response to low temperature, cold acclimation is not a prerequisite for oligomerization of Cor15am. Structural analysis suggests that Cor15am is composed of both ordered and random structures, and can stay soluble with small structural change after boiling and freezethaw treatments. Recombinant Cor15am exhibits in vitro cryoprotection of a freeze-labile enzyme, L-lactate dehydrogenase. Furthermore, Cor15am is capable of associating with L-lactate dehydrogenase in vitro and with potential stromal substrates in vivo. On the basis of these results, we propose that Arabidopsis Cor15am is a cryoprotective protein that forms oligomers in the chloroplast stroma, and that direct association of Cor15am with its substrates is part of its cryoprotective mechanism.
Plastids are surrounded by two membrane layers, the outer and inner envelope membranes, which have various transport and metabolic activities. A number of envelope membrane proteins have been identified by biochemical approaches and have been assigned to specific functions. Despite those efforts, the chloroplast envelope membrane is expected to contain a number of as yet unidentified proteins that may affect specific aspects of plant growth and development. In this report, we identify and characterize a novel class of inner envelope membrane proteins, designated as Cor413 chloroplast inner envelope membrane group (Cor413im). Both in vivo and in vitro studies indicate that Cor413im proteins are targeted to the chloroplast envelope. Biochemical analyses of Cor413im1 demonstrate that it is an integral membrane protein in the inner envelope of chloroplasts. Quantitative real-time PCR analysis reveals that COR413IM1 is more abundant than COR413IM2 in cold-acclimated Arabidopsis leaves. The analyses of T-DNA insertion mutants indicate that a single copy of COR413IM genes is sufficient to provide normal freezing tolerance to Arabidopsis. Based on these data, we propose that Cor413im proteins are novel components that are targeted to the chloroplast inner envelope in response to low temperature.
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