Sorting of proteins to the vacuoles of plant cells.

The secretory system of plant cells sorts a large number of soluble proteins that either are secreted or accumulate in vacuoles. Secretion is a bulk-flow process that requires no information beyond the presence of a signal peptide necessary to enter the endoplasmic reticulum. Many vacuolar proteins are glycoproteins and the glycans are often modified as the proteins pass through the Golgi complex. Vacuolar targeting information is not contained in glycans as it is in animal cells; rather, targeting information is in polypeptide domains as it is in yeast cells. Several such domains have now been identified, but these show little or no amino acid sequence homology. We discuss the possibilities that targeting of protein to plant vacuoles may involve receptors as well as aggregation of protein at low pH.     

Sorting of proteins to vacuoles in plant cells

An individual plant cell may contain at least two functionally and structurally distinct types of vacuoles: protein storage vacuoles and lytic vacuoles. Presumably a cell that stores proteins in vacuoles must maintain these separate compartments to prevent exposure of the storage proteins to an acidified environment with active hydrolytic enzymes where they would be degraded. Thus, the organization of the secretory pathway in plant cells, which includes the vacuoles, has a fascinating complexity not anticipated from the extensive genetic and biochemical studies of the secretory pathway in yeast. Plant cells must generate the membranes to form two separate types of tonoplast, maintain them as separate organelles, and direct soluble proteins from the secretory flow specifically to one or the other via separate vesicular pathways. Individual soluble and membrane proteins must be recognized and sorted into one or the other pathway by distinct, specific mechanisms. Here we review the emerging picture of how separate plant vacuoles are organized structurally and how proteins are recognized and sorted to each type.     

Promiscuous binding nature of SH3 domains to their target proteins

SH3 domains are small but important domains in cell-signaling and function through protein-protein interactions. Their promiscuous nature in binding to polyproline peptides makes them much more important because many SH3 domains from different proteins bind to different proteins having polyproline template on their surface. Very subtle changes in the sequence of SH3 domains and the binding peptides determine the specificity of the peptide binding. Recent observation that SH3 domains bind to non- proline peptides makes the scenario of peptide binding involving SH3 domains complicated. If domain swapped dimerization as observed in Eps8-SH3 domain also binds different peptides, it proves the versatility of the SH3 domains in binding to peptides in various ways. An overview of the promiscuity of SH3 domains has been discussed.     

Polar transmembrane domains target proteins to the interior of the yeast vacuole

Membrane proteins transported to the yeast vacuole can have two fates. Some reach the outer vacuolar membrane, whereas others enter internal vesicles, which form in late endosomes, and are ultimately degraded. The vacuolar SNAREs Nyv1p and Vam3p avoid this fate by using the AP-3-dependent pathway, which bypasses late endosomes, but the endosomal SNARE Pep12p must avoid it more directly. Deletion analysis revealed no cytoplasmic sequences necessary to prevent the internalization of Pep12p in endosomes. However, introduction of acidic residues into the cytoplasmic half of the transmembrane domain created a dominant internalization signal. In other contexts, this same feature diverted proteins from the Golgi to endosomes and slowed their exit from the endoplasmic reticulum. The more modestly polar transmembrane domains of Sec12p and Ufe1p, which normally serve to hold these proteins in the endoplasmic reticulum, also cause Pep12p to be internalized, as does that of the vacuolar protein Cps1p. It seems that quality control mechanisms recognize polar transmembrane domains at multiple points in the secretory and endocytic pathways and in endosomes sort proteins for subsequent destruction in the vacuole. These mechanisms may minimize the damaging effects of abnormally exposed polar residues while being exploited for the localization of some normal proteins.     

Multiple domains in MtENOD8 protein including the signal peptide target it to the symbiosome

Symbiotic nitrogen fixation occurs in nodules, specialized organs on the roots of legumes. Within nodules, host plant cells are infected with rhizobia that are encapsulated by a plant-derived membrane forming a novel organelle, the symbiosome. In Medicago truncatula, the symbiosome consists of the symbiosome membrane, a single rhizobium, and the soluble space between them, called the symbiosome space. The symbiosome space is enriched with plant-derived proteins, including the M. truncatula EARLY NODULIN8 (MtENOD8) protein. Here, we present evidence from green fluorescent protein (GFP) fusion experiments that the MtENOD8 protein contains at least three symbiosome targeting domains, including its N-terminal signal peptide (SP). When ectopically expressed in nonnodulated root tissue, the MtENOD8 SP delivers GFP to the vacuole. During the course of nodulation, there is a nodule-specific redirection of MtENOD8-SP-GFP from the vacuole to punctate intermediates and subsequently to symbiosomes, with redirection of MtENOD8-SP-GFP from the vacuole to punctate intermediates preceding intracellular rhizobial infection. Experiments with M. truncatula mutants having defects in rhizobial infection and symbiosome development demonstrated that the MtNIP/LATD gene is required for redirection of the MtENOD8-SP-GFP from the vacuoles to punctate intermediates in nodules. Our evidence shows that MtENOD8 has evolved redundant targeting sequences for symbiosome targeting and that intracellular localization of ectopically expressed MtENOD8-SP-GFP is useful as a marker for monitoring the extent of development in mutant nodules.     

Superoxide dismutase of plant cell vacuoles

Metal-dependent superoxide dismutases (SOD; EC 1.15.1.1) are present in many cell compartments (mitochondria, plastids, nuclei, peroxisomes, endoplasmic reticulum, cell wall and cytosol). We have established that SOD is also localized in the central vacuole. Cyanide-sensitive Cu, Zn-SOD was found in the fraction of isolated vacuoles of red beet roots (Beta vulgaris L.). The enzyme was represented by three isoforms. Comparison of isoenzyme composition and the level of SOD activity in vacuoles, nuclei, plastids and mitochondria isolated from root cells has shown that Cu, Zn-SOD is present in vacuoles and nuclei, two SOD forms (Cu, Zn- and Fe-SOD) are present in plastids, and two SOD forms (Cu, Zn- and Mn-SOD) are present in mitochondria. Cu, Zn-SOD of organelles, unlike vacuolar Cu, Zn-SOD, had only one isoform. The level of enzyme activity from the vacuolar fraction was twice higher than the level of SOD activity from the fractions of isolated organelles. Previously it has been suggested that Cu, Zn-SOD may be localized on the vacuolar membrane or in the near-membrane space from the side of cytoplasm. Our tests have revealed the Cu, Zn-SOD activity in water-soluble extracts of isolated vacuole fractions in the absence of detergent, which may confirm localization of the enzyme inside the organelles.     

Interactions of a fluorescently labeled peptide with kringle domains in proteins

The tripeptide Lys-Cys-Lys has been synthesized and covalently labeled at the cysteine sulfhydryl with 4-acetamido-4-maleimidylstilbene-2,2-disulfonic acid to produce a fluorescent labeled peptide (FLP). When excited at 340 nm, the FLP fluoresces strongly with maximal intensity at 405 nm. Addition of proteins containing the kringle lysine-binding domain, such as human lipoprotein (a) and plasminogen kringle 4, significantly attenuate the fluorescence intensity of the FLP. Other proteins, such as bovine serum albumin, did not affect the quantum yield of FLP fluorescence. When human lipoprotein (a) is bound to a lysine-Sepharose affinity column, FLP was found to effectively elute the protein, indicating that the peptide can compete with lysine for the kringle-binding site on lipoprotein (a). The data suggest that FLP binds specifically to kringles through the lysine residues on the peptide, and that binding significantly affects the fluorescence from the labeled peptide. These properties of FLP make it a potentially useful tool for studying the relative affinity of different kringles for lysine binding, which is thought to be an important mechanism for kringle-target protein interactions.     

A 42-kilodalton annexin-like protein is associated with plant vacuoles.

A 42-kD, calcium-dependent, membrane-binding protein (VCaB42) was associated with partially purified vacuole membrane. Membrane-dissociation assays indicated that VCaB42 binding to vacuole membranes was selective for calcium over other cations and that 50% of VCaB42 remained membrane bound at 61 +/- 11 nM free calcium. A 13-amino acid sequence obtained from VCaB42 showed 85% similarity with the endonexin fold, a sequence found in the annexin family of proteins that is thought to be essential for calcium and lipid binding. The greatest similarity in amino acid sequence was observed with annexin VIII (VAC-beta). The calcium-binding properties and sequence similarities suggest that VCaB42 is a member of the annexin family of calcium-dependent, membrane-binding proteins. Functional assays for VCaB42 on vacuole membrane transport processes indicated that it did not significantly affect the initial rate of calcium uptake into vacuole membrane vesicles. Because VCaB42 is vacuole localized (likely on the cytosolic surface of the vacuole) and is 50% dissociated within the physiological range of cytosolic free calcium, we hypothesize that this protein is a sensor that monitors cytosolic calcium levels and transmits that information to the vacuole.     

External surface display of proteins linked to DNA-binding domains.

A novel system (DBDX) was developed which allows the external surface display on filamentous bacteriophage of proteins fused to either the N- or the C-terminus of a DNA-binding protein. In conjunction with helper phage infection, expression of proteins fused to the estrogen receptor DNA-binding domain (DBD) in a phagemid vector containing the DNA sequence recognized by the DBD resulted in the production of phage particles which display the fusion protein through the phage pVIII coat on the external surface of the particle. The viability of the technique was established with several model systems: particles displaying the C-terminal domain of N-cadherin or the biotinylation domain of propionyl coenzyme A carboxylase fused to the C-terminus of the DBD were found to be bound specifically by antibody or streptavidin, respectively. Human kappa constant region cDNA was selected from a N-terminal DBD fusion lymphocyte cDNA library after two rounds of selection with anti-kappa antibody. This display system may complement currently available bacterial selection techniques.     

Heterologous C-terminal signals effectively target fluorescent fusion proteins to leaf peroxisomes in diverse plant species

Peroxisomes are functionally diverse organelles that are wholly dependent on import of nuclear-encoded proteins. The signals that direct proteins into these organelles are either found at the C-terminus (type 1 peroxisomal targeting signal; PTS1) or N-terminus (type 2 peroxisomal targeting signal; PTS2) of the protein. Based on a limited number of tests in heterologous systems, PTS1 signals appear to be conserved across species. To further test the generality of this conclusion and to establish the extent to which the PTS1 signals can be relied on for biotechnological purposes across species, we tested two PTS1 signals for their ability to target fluorescent proteins in diverse plant species. Transient assays following microprojectile bombardment showed that the six amino acid PTS1 sequence (RAVARL) from spinach glycolate oxidase effectively targets green fluorescent fusion protein to the leaf peroxisomes in all 20 crops tested, including four monocots (sugarcane, wheat, corn and onion) and 16 dicots (carrot, cucumber, broccoli, tomato, lettuce, turnip, radish, cauliflower, cabbage, capsicum, celery, tobacco, petunia, beetroot, eggplant and coriander). Similarly, results indicated that the 10 amino acid PTS1 sequence (IHHPRELSRL) from pumpkin malate synthase effectively targets red fluorescent fusion protein to the leaf peroxisomes in all four crops tested including monocot (sugarcane) and dicot (cabbage, celery and pumpkin) species. These signal sequences should be useful metabolic engineering tools to direct recombinant proteins to the leaf peroxisomes in diverse plant species of biotechnological interest.     

Use of peptide tagging to detect proteins expressed from cloned genes: deletion mapping functional domains of Drosophila hsp 70.

We have developed a technique which allows specific detection of proteins expressed from cloned genes. The method involves fusion of an oligonucleotide coding for part of the neuropeptide substance P to the 3' end of the gene; the protein can then be detected with a monoclonal antibody that recognises this peptide. We have used this method to determine the properties of deletion mutants of the major Drosophila heat shock protein, hsp70, expressed in monkey COS cells. The results suggest that this protein has two distinct domains. Both are capable of accumulating in the nucleus of unstressed cells, but only the more highly conserved N-terminal domain is able to bind to nucleoli following a heat shock. This implies that nucleolar binding and nuclear migration are distinct properties of the protein, and suggests that the former may be of functional importance. In addition, we observed a novel effect of heat shock on cellular metabolism: protein fragments that are normally rapidly degraded are stabilized. The effect persists for several hours after the heat shock, but does not require expression of heat shock proteins. Together with previously published data, these results suggest an intimate relationship between protein degradation and the heat shock response.     

Ni-NTA-gold clusters target His-tagged proteins.

Addition of six histidines to recombinant proteins has proved useful in their purification by nickel-affinity columns. This technology was adapted by synthesizing the chelator for nickel (nitrilotriacetic acid, NTA) onto the surface of gold clusters. These Ni-NTA-gold clusters were shown to specifically target the 6His region of tagged proteins. Results were verified by column chromatography, dot and overlay blots, UV-Vis spectroscopy, and scanning transmission electron microscopy. A 6His-tagged adenovirus "knob" protein was also shown to maintain receptor binding activity after gold labeling. Two types of gold clusters were used: 1.4-nm Nanogold and a new 1.8-nm "PeptideGold" coated with an NTA-dipeptide-thiol. These novel labels should be useful in site-specific high-resolution EM labeling, as well as in metallographic development, detection in the light microscope, or direct visualization.