Arabidopsis genes encoding components of the chloroplastic protein import apparatus

The process of protein import into plastids has been studied extensively using isolated pea (Pisum sativum) chloroplasts. As a consequence, virtually all of the known components of the proteinaceous apparatus that mediates import were originally cloned from pea. With the recent completion of the Arabidopsis genome sequencing project, it is now possible to identify putative homologs of the import components in this species. Our analysis has revealed that Arabidopsis homologs with high sequence similarity exist for all of the pea import complex subunits, making Arabidopsis a valid model for further study of this system. Multiple homologs can be identified for over one-half of the components. In all but one case it is known that more than one of the putative isoforms for a particular subunit are expressed. Thus, it is possible that multiple types of import complexes are present within the same cell, each having a unique affinity for different chloroplastic precursor proteins, depending upon the exact mix of isoforms it contains. Sequence analysis of the putative Arabidopsis homologs for the chloroplast protein import apparatus has revealed many questions concerning subunit function and evolution. It should now be possible to use the genetic tools available in Arabidopsis, including the generation of knockout mutants and antisense technology, to address these questions and learn more about the molecular functions of each of the components during the import process.     

Protein import into chloroplasts

Three proteins from the chloroplastic outer envelope membrane and four proteins from the inner envelope membrane have been identified as components of the chloroplastic protein import apparatus. Multiple molecular chaperones and a stromal processing peptidase are also important components of the import machinery. The interactions of these proteins with each other and with the precursors destined for transport into chloroplasts are gradually being described using both biochemical and genetic strategies. Homologs of some transport components have been identified in cyanobacteria suggesting that at least some of import machinery was inherited from the cyanobacterial ancestors that gave rise to chloroplasts.     

Protein import into mitochondria: origins and functions today (review)

Mitochondria are organelles derived from alpha-proteobacteria over the course of one to two billion years. Mitochondria from the major eukaryotic lineages display some variation in functions and coding capacity but sequence analysis demonstrates them to be derived from a single common ancestral endosymbiont. The loss of assorted functions, the transfer of genes to the nucleus, and the acquisition of various 'eukaryotic' proteins have resulted in an organelle that contains approximately 1000 different proteins, with most of these proteins imported into the organelle across one or two membranes. A single translocase in the outer membrane and two translocases in the inner membrane mediate protein import. Comparative sequence analysis and functional complementation experiments suggest some components of the import pathways to be directly derived from the eubacterial endosymbiont's own proteins, and some to have arisen 'de novo' at the earliest stages of 'mitochondrification' of the endosymbiont. A third class of components appears lineage-specific, suggesting they were incorporated into the process of protein import long after mitochondria was established as an organelle and after the divergence of the various eukaryotic lineages. Protein sorting pathways inherited from the endosymbiont have been co-opted and play roles in intraorganelle protein sorting after import. The import apparatus of animals and fungi show significant similarity to one another, but vary considerably to the plant apparatus. Increasing complexity in the eukaryotic lineage, i.e., from single celled to multi-cellular life forms, has been accompanied by an expansion in genes encoding each component, resulting in small gene families encoding many components. The functional differences in these gene families remain to be elucidated, but point to a mosaic import apparatus that can be regulated by a variety of signals.     

Protein translocation across mitochondrial membranes.

Protein translocation across biological membranes is of fundamental importance for the biogenesis of organelles and in protein secretion. We will give an overview of the recent achievements in the understanding of protein translocation across mitochondrial membranes. In particular we will focus on recently identified components of the mitochondrial import apparatus.     

Protein translocation across chloroplast envelope membranes

Nuclear-encoded chloroplast proteins are imported from the cytosol into the chloroplast stroma by a common translocation machinery. Several components of the import apparatus, including GTP-binding proteins and Hsp70 proteins, have recently been identified and characterized. This review discusses the role of these proteins in chloroplast protein import.     

The plant mitochondrial protein import apparatus — The differences make it interesting

Background

Mitochondria play essential roles in the life and death of almost all eukaryotic cells, ranging from single-celled to multi-cellular organisms that display tissue and developmental differentiation. As mitochondria only arose once in evolution, much can be learned from studying single celled model systems such as yeast and applying this knowledge to other organisms. However, two billion years of evolution have also resulted in substantial divergence in mitochondrial function between eukaryotic organisms.

Scope of Review

Here we review our current understanding of the mechanisms of mitochondrial protein import between plants and yeast (Saccharomyces cerevisiae) and identify a high level of conservation for the essential subunits of plant mitochondrial import apparatus. Furthermore, we investigate examples whereby divergence and acquisition of functions have arisen and highlight the emerging examples of interactions between the import apparatus and components of the respiratory chain.

Major conclusions

After more than three decades of research into the components and mechanisms of mitochondrial protein import of plants and yeast, the differences between these systems are examined. Specifically, expansions of the small gene families that encode the mitochondrial protein import apparatus in plants are detailed, and their essential role in seed viability is revealed.

General significance

These findings point to the essential role of the inner mitochondrial protein translocases in Arabidopsis, establishing their necessity for seed viability and the crucial role of mitochondrial biogenesis during germination. This article is part of a Special Issue entitled Frontiers of Mitochondrial Research.     

Protein import into mitochondria: origins and functions today (Review)

Mitochondria are organelles derived from α-proteobacteria over the course of one to two billion years. Mitochondria from the major eukaryotic lineages display some variation in functions and coding capacity but sequence analysis demonstrates them to be derived from a single common ancestral endosymbiont. The loss of assorted functions, the transfer of genes to the nucleus, and the acquisition of various ‘eukaryotic’ proteins have resulted in an organelle that contains approximately 1000 different proteins, with most of these proteins imported into the organelle across one or two membranes. A single translocase in the outer membrane and two translocases in the inner membrane mediate protein import. Comparative sequence analysis and functional complementation experiments suggest some components of the import pathways to be directly derived from the eubacterial endosymbiont's own proteins, and some to have arisen ‘de novo’ at the earliest stages of ‘mitochondrification’ of the endosymbiont. A third class of components appears lineage-specific, suggesting they were incorporated into the process of protein import long after mitochondria was established as an organelle and after the divergence of the various eukaryotic lineages. Protein sorting pathways inherited from the endosymbiont have been co-opted and play roles in intraorganelle protein sorting after import. The import apparatus of animals and fungi show significant similarity to one another, but vary considerably to the plant apparatus. Increasing complexity in the eukaryotic lineage, i.e., from single celled to multi-cellular life forms, has been accompanied by an expansion in genes encoding each component, resulting in small gene families encoding many components. The functional differences in these gene families remain to be elucidated, but point to a mosaic import apparatus that can be regulated by a variety of signals.     

Developmental Regulation of the Plastid Protein Import Apparatus

Plastid development involves the programmed accumulation of proteins. Most plastid proteins are synthesized in the cytosol and imported into the organelle by an envelope-based protein import apparatus. Previous studies have shown that developmental rates of protein accumulation correspond to mRNA levels. Here, we examined the relationship between plastid development and the activity of the protein import apparatus. Developing plastids, primarily from wheat leaves, were analyzed for their protein import capability in vitro. Import capability, initially high in proplastids, declined as much as 20-fold as plastid development approached either the mature etioplast or the mature chloroplast. The observed decline was not due to senescence, nonspecific inhibitors, or protein turnover. Furthermore, the import capability of mature etioplasts, initially very low, was transiently reactivated during light-mediated redifferentiation into chloroplasts. These results suggest that plant cells regulate the import apparatus in concert with the protein demands of the developing plastids.     

Organelle evolution: Paulinella breaks a paradigm

It is commonly assumed that transformations of endosymbionts into organelles are exceptionally rare evolutionary events because of hypothetical difficulties in the origin of an import apparatus for nuclear-encoded, organelle-targeted proteins along with their targeting signals. A challenge to this view comes from recent studies of protein import into the cyanobacterial endosymbionts/organelles of Paulinella chromatophora.     

A functionally active protein import complex from

Isolated outer chloroplast envelope membranes were solubilized by digitonin and separated on linear sucrose density gradients. A membrane complex was recovered from the gradients and exhibited characteristics of a protein import apparatus, i.e. the interaction of the complex with the precursor polypeptides depends on the presence of a transit sequence, ATP and protease-sensitive components. Furthermore, trans-location intermediates detected in the organellar system are also found after interaction of the precursor polypeptide with the isolated import complex.     

Transport of proteins into chloroplasts

The import of cytoplasmically synthesized proteins into chloroplasts involves an interaction between at least two components; the precursor protein, and the import apparatus in the chloroplast envelope membrane. This review summarizes the information available about each of these components. Precursor proteins consist of an amino terminal transit peptide attached to a passenger protein. Transit peptides from various precurosrs are diverse with respect to length and amino acid sequence; analysis of their sequences has not revealed insight into their mode of action. A variety of foreign passenger proteins can be imported into chloroplasts when a transit peptide is present at the amino terminus. However, foreign passenger proteins are not imported as efficiently as natural passenger proteins, and some chimeric precursor proteins are not imported into chloroplasts at all. Therefore, the passenger protein, as well as the transit peptide, influences the import process. Import begins by binding of the precursor to the chloroplast surface. It has been suggested that this binding is mediated by a receptor, but evidence to support this hypothesis remains incomplete and a receptor protein has not yet been characterized. Protein translocation requires energy derived from ATP hydrolysis, although there are conflicting reports as to where hydrolysis occurs and it is unclear how this energy is utilized. The mechanism(s) whereby proteins are translocated across either the two envelope membranes or the thylakoid membrane is not known.Abbreviations EPSP 5-enolpyruvyulshikimate-3-phosphate - LHCP Chlorophyll a/b binding protein of the light-harvesting complex - NPT-II Neomycin phosphotransferase II - PC Plastocyanin - Pr Precursor - Rubisco Ribulose-1,5,-bisphosphate carboxylase/oxygenase - SS Small subunit of Rubisco     

Protein import into chloroplasts

Most chloroplastic proteins are encoded in the nucleus, synthesized on cytosolic ribosomes and subsequently imported into the organelle. In general, proteins destined for the chloroplast are synthesized as precursor proteins with a cleavable N-terminal presequence that mediates routing to the inside of the chloroplast. These precursor proteins have to be targeted to the correct organellar membrane surface after their release from the ribosome and furthermore they have to be maintained in a conformation suitable for translocation across the two envelope membranes. Recognition and import of most chloroplastic precursor proteins are accomplished by a jointly used translocation apparatus. Different but complementary studies of several groups converged recently in the identification of the outer envelope proteins OEP86, OEP75, OEP70 (a Hsp 70-related protein), OEP34, and of the inner envelope protein IEP110 as components of this translocation machinery. None of these proteins, except for OEP70, shows any homology to components of other protein translocases. The plastid import machinery thus seems to be an original development in evolution. Following translocation into the organelle, chloroplastic proteins are sorted to their suborganellar destination, i.e., the inner envelope membrane, the thylakoid membrane, and the thylakoid lumen. This structural and evolutionary complexity of chloroplasts is reflected by a variety of routing mechanisms by which proteins reach their final location once inside the organelle. This review will focus on recent advances in the identification of components of the chloroplastic protein import machinery, and new insights into the pathways of inter-and intraorganellar sorting.     

In silico survey of the mitochondrial protein uptake and maturation systems in the brown alga Ectocarpus siliculosus

The acquisition of mitochondria was a key event in eukaryote evolution. The aim of this study was to identify homologues of the components of the mitochondrial protein import machinery in the brown alga Ectocarpus and to use this information to investigate the evolutionary history of this fundamental cellular process. Detailed searches were carried out both for components of the protein import system and for related peptidases. Comparative and phylogenetic analyses were used to investigate the evolution of mitochondrial proteins during eukaryote diversification. Key observations include phylogenetic evidence for very ancient origins for many protein import components (Tim21, Tim50, for example) and indications of differences between the outer membrane receptors that recognize the mitochondrial targeting signals, suggesting replacement, rearrangement and/or emergence of new components across the major eukaryotic lineages. Overall, the mitochondrial protein import components analysed in this study confirmed a high level of conservation during evolution, indicating that most are derived from very ancient, ancestral proteins. Several of the protein import components identified in Ectocarpus, such as Tim21, Tim50 and metaxin, have also been found in other stramenopiles and this study suggests an early origin during the evolution of the eukaryotes.     

The protein-import apparatus of plant mitochondria

The import and assembly of mitochondrial proteins synthesized in the cytosol is mediated by the protein-import apparatus which plays a central role in mitochondrial biogenesis. Ten years ago only some components of the protein-import apparatus from fungi and mammals were characterized, but today its major components have been analyzed at the molecular level also in plants. Interestingly there are specific features which distinguish the protein-import apparatus of plants from that of fungi and mammals. Here we give an overview of all known components of the protein-import apparatus from plants and focus on its differences in comparison to heterotrophic eukaryotes. Received: 29 March 1999 / Accepted: 14 May 1999     

Zinc-dependent intermembrane space proteins stimulate import of carrier proteins into plant mitochondria

Mitochondrial inner membrane carrier proteins are imported into mitochondria from yeast, fungi and mammals by specific machinery, some components of which are distinct from those utilized by other proteins. Import of two different carriers into plant mitochondria showed that one contains a cleavable presequence which was processed during import, while the other imported in a valinomycin-sensitive manner without processing. Mild osmotic shock of mitochondria released intermembrane space (IMS) components and impaired carrier protein import. Adding back the released IMS proteins as a concentrate in the presence of micromolar ZnCl2 stimulated carrier import into IMS-depleted mitochondria, but did not stimulate import of a non-carrier control precursor protein, the alternative oxidase. Anion-exchange separation of IMS components before addition to IMS-depleted mitochondria revealed a correlation between several 9-10 kDa proteins and stimulation of carrier import. MS/MS sequencing of these proteins identified them as plant homologues of the yeast zinc-finger carrier import components Tim9 and Tim10. Stimulation of import was dependent on either Zn2+ or Cd2+ and inhibited by both N-ethylmalamide (NEM) and a divalent cation chelator, consistent with a functional requirement for a zinc finger protein. This represents direct functional evidence for a distinct carrier import pathway in plant mitochondria, and provides a tool for determining the potential function of other IMS proteins associated with protein import.     

Mitochondrial import of the ADP/ATP carrier protein in Saccharomyces cerevisiae. Sequences required for receptor binding and membrane translocation

The ADP/ATP carrier of yeast (309 amino acids) is an abundant transmembrane protein of the mitochondrial inner membrane whose import involves well-defined steps (Pfanner, N., and Neupert, W. (1987) J. Biol. Chem. 262, 7528-7536). Analysis of the in vitro import of gene fusion products containing ADP/ATP carrier (AAC) sequences at the amino terminus and mouse dihydrofolate reductase (DHFR) at the carboxyl terminus indicates that the first 72 amino acids of the soluble carrier protein, a hydrophilic region of the protein, are not by themselves sufficient for initial binding to the AAC receptor on the mitochondrial surface. However, an AAC-DHFR gene fusion containing the first 111 residues of the ADP/ATP carrier protein exhibited binding to mitochondria at low temperature (2 degrees C) and internalization at 25 degrees C to a mitochondrial space protected from proteinase K in the same manner as the wild-type ADP/ATP carrier protein. The AAC-DHFR protein, in contrast to the wild-type AAC protein imported into mitochondria under optimal conditions, remained extractable at alkaline pH and appeared to be blocked at an intermediate step in the AAC import pathway. Based on its extraction properties, this AAC-DHFR hybrid is proposed to be associated with a proteinaceous component of the import apparatus within mitochondria. These data indicate that the import determinants for the AAC protein are not located at its extreme amino terminus and that protein determinants distal to the first 111 residues of the carrier may be necessary to move the protein beyond the alkali-extractable step in the biogenesis of a functional AAC protein.