Analysis of the distribution of charged residues in the N-terminal region of signal sequences: implications for protein export in prokaryotic and eukaryotic cells

A statistical analysis of the distribution of charged residues in the N-terminal region of 39 prokaryotic and 134 eukaryotic signal sequences reveals a remarkable similarity between the two samples, both in terms of net charge and in terms of the position of charged residues within the N-terminal region, and suggests that the formyl group on Metf is not removed in prokaryotic signal sequences.     

Positively charged amino acids placed next to a signal sequence block protein translocation more efficiently in Escherichia coli than in mammalian microsomes

Positively charged amino acids are known efficiently to block protein secretion in Escherichia coli, when placed within a short distance downstream of a signal sequence. It is not known whether the same applies to protein secretion in eukaryotic cells, though statistical studies of signal sequences of prokaryotic and eukaryotic secretory proteins have suggested that the situation may be different in this case. Here, we show that identical charge mutations in a model protein have different effects on membrane translocation in E. coli and in mammalian microsomes, and that the charge block effect is much more pronounced in the prokaryotic system. This finding has implications not only for our understanding of the mechanisms of protein secretion, but also points to a potential problem in the expression of eukaryotic secretory proteins in bacteria.     

The net charge of the first 18 residues of the mature sequence affects protein translocation across the cytoplasmic membrane of gram-negative bacteria

This statistical study shows that in proteins of gram-negative bacteria exported by the Sec-dependent pathway, the first 14 to 18 residues of the mature sequences have the highest deviation between the observed and expected net charge distributions. Moreover, almost all sequences have either neutral or negative net charge in this region. This rule is restricted to gram-negative bacteria, since neither eukaryotic nor gram-positive bacterial exported proteins have this charge bias. Subsequent experiments performed with a series of Escherichia coli alkaline phosphatase mutants confirmed that this charge bias is associated with protein translocation across the cytoplasmic membrane. Two consecutive basic residues inhibit translocation effectively when placed within the first 14 residues of the mature protein but not when placed in positions 19 and 20. The sensitivity to arginine partially reappeared again 30 residues away from the signal sequence. These data provide new insight into the mechanism of protein export in gram-negative bacteria and lead to practical recommendations for successful secretion of hybrid proteins.     

The role of the N region in signal sequence and signal-anchor function.

To determine the role of sequences other than the hydrophobic core in mediating signal sequence function, we examined the behavior of fusion proteins and deletion mutants in cell-free systems. We demonstrate that neither the N nor the C region of the preprolactin signal sequence is necessary for translocation. However, insertion of sequences with either a net charge of +2.5 or -6.0 between the N region and the hydrophobic core of the signal converted it into a signal-anchor. The topologies adopted (types I and II, respectively) were opposite those predicted from the distribution of charges surrounding the hydrophobic core of the signals. When these mutant signals were located in the interior of an otherwise secreted protein, both sequences functioned as stop-transfer sequences. Related mutations were assayed in fusion proteins in which the IgM transmembrane domain functioned as an amino-terminal signal-anchor. For these molecules, the distribution of charged residues surrounding the hydrophobic core had no influence on the topology adopted. Our results suggest that features other than simple charge distribution play an important role in determining membrane topology in vitro.     

Positively charged amino acids placed next to a signal sequence block protein translocation more efficiently in Escherichia coli than in mammalian microsomes

Positively charged amino acids are known efficiently to block protein secretion in Escherichia coli, when placed within a short distance downstream of a signal sequence. It is not known whether the same applies to protein secretion in eukaryotic cells, though statistical studies of signal sequences of prokaryotic and eukaryotic secretory proteins have suggested that the situation may be different in this case. Here, we show that identical charge mutations in a model protein have different effects on membrane translocation in E. coli and in mammalian microsomes, and that the ‘charge block’ effect is much more pronounced in the prokaryotic system. This finding has implications not only for our understanding of the mechanisms of protein secretion, but also points to a potential problem in the expression of eukaryotic secretory proteins in bacteria.     

Export of maltose-binding protein species with altered charge distribution surrounding the signal peptide hydrophobic core in Escherichia coli cells harboring prl suppressor mutations.

It is believed that one or more basic residues at the extreme amino terminus of precursor proteins and the lack of a net positive charge immediately following the signal peptide act as topological determinants that promote the insertion of the signal peptide hydrophobic core into the cytoplasmic membrane of Escherichia coli cells with the correct orientation required to initiate the protein export process. The export efficiency of precursor maltose-binding protein (pre-MBP) was found to decrease progressively as the net charge in the early mature region was increased systematically from 0 to +4. This inhibitory effect could be further exacerbated by reducing the net charge in the signal peptide to below 0. One such MBP species, designated MBP-3/+3 and having a net charge of -3 in the signal peptide and +3 in the early mature region, was totally export defective. Revertants in which MBP-3/+3 export was restored were found to harbor mutations in the prlA (secY) gene, encoding a key component of the E. coli protein export machinery. One such mutation, prlA666, was extensively characterized and shown to be a particularly strong suppressor of a variety of MBP export defects. Export of MBP-3/+3 and other MBP species with charge alterations in the early mature region also was substantially improved in E. coli cells harboring certain other prlA mutations originally selected as extragenic suppressors of signal sequence mutations altering the hydrophobic core of the LamB or MBP signal peptide. In addition, the enzymatic activity of alkaline phosphatase (PhoA) fused to a predicted cytoplasmic domain of an integral membrane protein (UhpT) increased significantly in cells harboring prlA666. These results suggest a role for PrlA/SecY in determining the orientation of signal peptides and possibly other membrane-spanning protein domains in the cytoplasmic membrane.     

Distinctive properties of signal sequences from bacterial lipoproteins

We have compared a number of attributes (hydrophobicity, amino acid size, charge and secondary structure propensities) of signal sequences from bacterial lipoproteins with the same attributes of signal peptides from other prokaryotic proteins (non-lipoproteins). Lipoprotein leader sequences tend to be shorter, more hydrophobic and bulky, and they have stronger conformational preferences, the most conspicuous being a predicted beta-turn comprising positions 2 or 3 of the mature protein. Another distinctive feature is a maximum in the local energy profile between positions -1 and +2. With one exception (beta-lactamase III), the lipoproteins do not have Pro in their signal peptides, and they tend to have fewer Ser and Thr but more Gly than non-lipoproteins. Lipoproteins also lack a net negative charge in the N-terminal regions of the mature proteins. The signal peptides of the bacteriocin plasmid-coded lysis proteins appear to be unique in that they have all the ascribed features of lipoprotein signals; these characteristics can be used to guide signal peptide mutagenesis experiments and to construct new secretion vehicles.     

Why are "natively unfolded" proteins unstructured under physiologic conditions?

"Natively unfolded" proteins occupy a unique niche within the protein kingdom in that they lack ordered structure under conditions of neutral pH in vitro. Analysis of amino acid sequences, based on the normalized net charge and mean hydrophobicity, has been applied to two sets of proteins: small globular folded proteins and "natively unfolded" ones. The results show that "natively unfolded" proteins are specifically localized within a unique region of charge-hydrophobicity phase space and indicate that a combination of low overall hydrophobicity and large net charge represent a unique structural feature of "natively unfolded" proteins.     

N-terminal tail export from the mitochondrial matrix. Adherence to the prokaryotic "positive-inside" rule of membrane protein topology.

Export of N-terminal tails of mitochondrial inner membrane proteins from the mitochondrial matrix is a membrane potential-dependent process, mediated by the Oxa1p translocation machinery. The hydrophilic segments of these membrane proteins, which undergo export, display a characteristic charge profile where intermembrane space-localized segments bear a net negative charge, whereas those remaining in the matrix have a net positive one. Using a model protein, preSu9(1-112)-dihydrofolate reductase (DHFR), which undergoes Oxa1p-mediated N-tail export, we demonstrate here that the net charge of N- and C-flanking regions of the transmembrane domain play a critical role in determining the orientation of the insertion process. The N-tail must bear a net negative charge to be exported to the intermembrane space. Furthermore, a net positive charge of the C-terminal region supports this N-tail export event. These data provide experimental evidence that protein export in mitochondria adheres to the "positive-inside" rule, described for sec-independent sorting of membrane proteins in prokaryotes. We propose here that the importance of a charge profile reflects a need for specific protein-protein interactions to occur in the export reaction, presumably at the level of the Oxa1p export machinery.     

Signal peptides: exquisitely designed transport promoters

Prokaryotic proteins destined for transport out of the cytoplasm typically contain an N-terminal extension sequence, called the signal peptide, which is required for export, it is evident that many secretory proteins utilize a common export system, yet the signal sequences themselves display very little primary sequence homology. in attempting to understand how different signal peptides are able to promote protein secretion through the same pathway, the physical features of natural signal sequences have been extensively examined for similarities that might play a part in function. Experimental data have confirmed statistical analyses which highlighted dominant features of natural signal sequences in Escherichia coli: a net positive charge in the N-terminus increases efficiency of transport; the core region must maintain a threshold level of hydrophoblcity within a range of length limitations; the central portion adopts an α-hellcal conformation in hydrophobic environments; and the signal cleavage region is ideally six residues long, with small side-chain amino acids in the −1 and −3 positions. This review focuses on the parallels between signal peptide physical features and their functions, which emerge when the results of a variety of experimental approaches are combined. The requirement for each property may be ascribed to a potential interaction that is critical for efficient protein export. The summation of the key physical features produces signal peptides with the flexibility to function in multiple roles in order to expedite secretion. In this way, nature has indeed evolved exquisitely tuned signal sequences.     

Characterization of the signal that directs Tom20 to the mitochondrial outer membrane

Tom20 is a major receptor of the mitochondrial preprotein translocation system and is bound to the outer membrane through the NH(2)-terminal transmembrane domain (TMD) in an Nin-Ccyt orientation. We analyzed the mitochondria-targeting signal of rat Tom20 (rTom20) in COS-7 cells, using green fluorescent protein (GFP) as the reporter by systematically introducing deletions or mutations into the TMD or the flanking regions. Moderate TMD hydrophobicity and a net positive charge within five residues of the COOH-terminal flanking region were both critical for mitochondria targeting. Constructs without net positive charges within the flanking region, as well as those with high TMD hydrophobicity, were targeted to the ER-Golgi compartments. Intracellular localization of rTom20-GFP fusions, determined by fluorescence microscopy, was further verified by cell fractionation. The signal recognition particle (SRP)-induced translation arrest and photo-cross-linking demonstrated that SRP recognized the TMD of rTom20-GFP, but with reduced affinity, while the positive charge at the COOH-terminal flanking segment inhibited the translation arrest. The mitochondria-targeting signal identified in vivo also functioned in the in vitro system. We conclude that NH(2)-terminal TMD with a moderate hydrophobicity and a net positive charge in the COOH-terminal flanking region function as the mitochondria-targeting signal of the outer membrane proteins, evading SRP-dependent ER targeting.     

Intracellular sorting of the tail-anchored protein cytochrome b5 in plants: a comparative study using different isoforms from rabbit and Arabidopsis

Tail-anchored (TA) proteins are bound to membranes by a hydrophobic sequence located very close to the C-terminus, followed by a short luminal polar region. Their active domains are exposed to the cytosol. TA proteins are synthesized on free cytosolic ribosomes and are found on the surface of every subcellular compartment, where they play various roles. The basic mechanisms of sorting and targeting of TA proteins to the correct membrane are poorly characterized. In mammalian cells, the net charge of the luminal region determines the sorting to the correct target membrane, a positive charge leading to mitochondria and negative or null charge to the endoplasmic reticulum (ER). Here sorting signals of TA proteins were studied in plant cells and compared with those of mammalian proteins, using in vitro translation-translocation and in vivo expression in tobacco protoplasts or leaves. It is shown that rabbit cytochrome b5 (cyt b5) with a negative charge is faithfully sorted to the plant ER, whereas a change to a positive charge leads to chloroplast targeting (instead of to mitochondria as observed in mammalian cells). The subcellular location of two cyt b5 isoforms from Arabidopsis thaliana (At1g26340 and At5g48810, both with positive net charge) was then determined. At5g48810 is targeted to the ER, and At1g26340 to the chloroplast envelope. The results show that the plant ER, unlike the mammalian ER, can accommodate cytochromes with opposite C-terminal net charge, and plant cells have a specific and as yet uncharacterized mechanism to sort TA proteins with the same positive C-terminal charge to different membranes.     

Role of amino-terminal positive charge on signal peptide in staphylokinase export across the cytoplasmic membrane of Escherichia coli

Staphylokinase mutants having amino acid substitutions within the amino-terminal charged segment of the signal peptide have been produced by in vitro oligonucleotide-directed mutagenesis. When the processing of the gene products was analyzed in Escherichia coli cells, the rate of processing of the mutant staphylokinase precursor decreased as the net charge became more negative. A net positive charge, but not specific amino acid residues, was required on the amino-terminal segment for efficient processing. Staphylokinase precursor having a net negative charge accumulated in the cytoplasm, tending to bind to the cytoplasmic membrane as determined by subcellular fractionation and immunoelectron microscopy. Although a mutant carrying an amino acid substitution in the hydrophobic segment and wild-type staphylokinases had an interfering effect on the processing of other normal secreted proteins, this effect was lost when they also contained charge-altering substitutions in the amino-terminal region. From these results, we concluded that a positive charge on the amino-terminal segment of the staphylokinase signal peptide is required for entrance into the protein export process.     

Multiple zones in the sequence of calreticulin (CRP55, calregulin, HACBP), a major calcium binding ER/SR protein.

The complete amino acid sequence of CRP55, the major 55 kd calcium binding protein of the ER lumen, was deduced from the murine cDNA nucleotide sequence. This was completed using a novel application of PCR amplification. The mature 399 residue protein encoded is preceded by a 17 amino acid leader sequence and ends in the ER signal sequence, KDEL. The protein contains no calcium binding motifs of the EF hand type or of the form seen in calelectrin-related proteins. The major region of potential low affinity calcium binding sites is a polyacidic stretch towards the C terminus. The primary structure of the protein is markedly zonal. The N-terminal region, of approximately neutral net charge and hydrophobicity, is followed by a central proline-rich zone with repeat sequences separated from the polyacidic C-terminal stretch by a short hydrophobic sequence. The general shape suggested is a globular domain attached to an extended tail. Immunofluorescence studies show that the protein is present in skeletal muscle and indicate that it is a sarcoplasmic reticulum protein. We propose that the protein be named calreticulin to reflect its calcium binding activity and location in the ER and SR.     

The membrane-interactive tail of cytochrome b(5) can function as a stop-transfer sequence in concert with a signal sequence to give inversion of protein topology in the endoplasmic reticulum

Sequence analyses of the C-terminal membrane intercalative region of the rat cytochrome b(5) indicated that this domain has, in addition to a signal sequence, a combined element of the classic stop-transfer sequence typically found in a variety of transmembrane proteins. Such bitopic protein arrangements arise by tandem but topogenically displaced activities of cleavable/noncleavable signal and stop-transfer sequences. A fusion precursor comprising an N-terminally linked prokaryotic signal sequence and the full-length of mammalian cytochrome b(5), including its C-terminal membrane insertion sequence, was engineered to investigate the outcome of this combination of signals on the targeting and topology of the cytochrome b(5) in the endoplasmic reticulum membrane. Precytochrome b(5) was cotranslationally translocated across the endoplasmic reticulum membrane. The signal-processed cytochrome b(5) was integrally anchored in the membrane with the globular domain facing the lumen. Thus, the topology of the signal sequence-directed cytochrome b(5) in the microsomal vesicle was reversed with respect to that of the native form. Posttranslational incubation of the precytochrome b(5) with microsomes resulted in a "loose" incorporation of the unprocessed form onto the surface of the vesicle. Our findings suggest that the membrane-insertion sequence of cytochrome b(5) has a functional stop-transfer sequence. We discuss the implications of these findings with respect to selective targeting of cytochrome b(5) to the endoplasmic reticulum membrane in the view that signal and stop-transfer sequences are often interchangeable or combined for topogenic functions.     

Identification of a Post-targeting Step Required for Efficient Cotranslational Translocation of Proteins across the Escherichia coli Inner Membrane

Recent studies have shown that cytoplasmic proteins are exported efficiently in Escherichia coli only if they are attached to signal peptides that are recognized by the signal recognition particle and are thereby targeted to the SecYEG complex cotranslationally. The evidence suggests that the entry of these proteins into the secretory pathway at an early stage of translation is necessary to prevent them from folding into a translocation-incompetent conformation. We found, however, that several glycolytic enzymes attached to signal peptides that are recognized by the signal recognition particle were exported inefficiently. Based on previous studies of post-translational export, we hypothesized that the export block was due to the presence of basic residues at the extreme N terminus of each enzyme. Consistent with our hypothesis, we found that the introduction of negatively charged residues into this segment increased the efficiency of export. Export efficiency was sensitive to the number, position, and sequence context of charged residues. The importance of charge for efficient export was underscored by an in silico analysis that revealed a conserved negative charge bias at the N terminus of the mature region of bacterial presecretory proteins. Our results demonstrate that cotranslational targeting of a protein to the E. coli SecYEG complex does not ensure its export but that export also depends on a subsequent event (most likely the initiation of translocation) that involves sequences both within and just beyond the signal peptide.Since the “signal hypothesis” was proposed over 30 years ago (1), it has become clear that signal sequences are not simply generic hydrophobic peptides that earmark proteins for secretion. In bacteria, the features of a signal peptide determine the mechanism by which a given presecretory protein is targeted to the SecYEG translocation complex in the inner membrane (IM).² Whereas most or all signal peptides are recognized by the signal recognition particle (SRP) in mammalian cells, only a small fraction of Escherichia coli signal peptides are recognized by SRP. These signal peptides are typically extremely hydrophobic (2, 3), but SRP apparently can also recognize slightly less hydrophobic signal peptides that contain a highly basic N terminus (4). SRP recognizes signal peptides as they emerge from translating ribosomes and then targets ribosome-nascent chain complexes to the IM cotranslationally (5). The binding of SRP to its receptor (FtsY), which interacts with the SecYEG complex (6), leads to the release of the nascent chain in the immediate vicinity of the translocation machinery. By targeting nascent polypeptides to the SecYEG complex at an early stage of translation, SRP prevents its substrates from folding into a conformation that is incompatible with translocation through the narrow channel formed by the SecYEG complex (7). Because most signal peptides are not recognized by E. coli SRP, the majority of presecretory proteins are fully synthesized and targeted post-translationally to the IM. These proteins are maintained in a translocation-competent conformation by molecular chaperones such as SecB that keep them unfolded (or loosely folded) (8). Signal peptides themselves also appear to play a role in maintaining translocation competence (9, 10). After mediating the targeting reaction, signal peptides likely play a role in gating open the SecYEG complex to initiate translocation.Interestingly, although signal sequences are the most salient feature of presecretory proteins, they are neither completely necessary nor sufficient to mediate protein export in E. coli (11–13). A version of alkaline phosphatase that lacks a signal peptide is still exported, albeit very inefficiently (11). The export of the leaderless protein, unlike the export of wild-type alkaline phosphatase, is strictly dependent on SecB (11). Conversely, the attachment of signal peptides to cytoplasmic proteins often does not promote their export (14). In light of evidence that folding and export are competing events, these observations led to the proposal that exported proteins tend to fold slowly (or are prevented from folding by chaperones) and therefore remain translocation-competent even without a signal peptide, whereas cytoplasmic proteins fold rapidly into a conformation that is incompatible with export. Recent studies that used thioredoxin as a model protein have validated this hypothesis. Whereas the wild-type protein attached to a typical signal peptide remained trapped in the cytoplasm, four of five slow folding mutants were exported efficiently (15). Furthermore, attachment of a signal peptide that is recognized by SRP to thioredoxin led to efficient export (16). This idea was further confirmed by a report in which various DARPins (designed ankyrin Repeat proteins) were attached to different signal peptides. Most of the DARPins were exported efficiently when they were fused to signal peptides that mediate cotranslational targeting but remained in the cytoplasm when they were attached to signal peptides that are bypassed by SRP (17).Despite these observations, there are several lines of evidence suggesting that export efficiency is not simply dictated by the ability of a protein to reach the SecYEG complex before folding into a translocation-incompetent conformation. For reasons that are unclear, some DARPins are secreted inefficiently even when they are routed into the SRP pathway (17). In addition, numerous reports have indicated that the amino acid composition of the segment of post-translationally targeted presecretory proteins that lies just beyond the signal peptide cleavage site has a dramatic effect on export efficiency. Statistical analysis has shown that the first ∼5–15 residues of the mature region of most presecretory proteins produced by Gram-negative bacteria is neutral or has a net negative charge (18). Consistent with the observed sequence bias, the presence of multiple basic residues at the N terminus of the mature region often leads to accumulation of the secretory precursor, whereas conversion of the basic residues to acidic residues restores export (19–22). Because different combinations of proteins and signal peptides were used in these studies, the exact number and location of charged residues that impinge on the efficiency of export is unclear. In any case, the effect of the net charge in the region distal to the signal peptide on protein export has never been explained. Although basic residues might conceivably promote premature folding of presecretory proteins or block the cleavage of signal peptides by leader peptidase, it is also possible that they inhibit an uncharacterized post-targeting event. Even if effects on signal peptide cleavage could have been ruled out in the aforementioned studies, however, it would not have been possible to distinguish between effects on protein folding and effects on a hypothetical post-targeting step because only proteins that are targeted post-translationally were monitored.To gain further insight into the factors that govern the efficiency of protein export, we sought an explanation for the observation that the cotranslational targeting of at least some cytoplasmic proteins is insufficient to guarantee their translocation across the IM. We found that the export of several different endogenous E. coli cytoplasmic proteins required not only the attachment of a signal peptide that is recognized by SRP but also a net negative charge just past the signal peptide cleavage site. Taken together with previous results, our data show that the charge of the segment just beyond the signal peptide influences export efficiency irrespective of the mechanism by which a protein is targeted to the IM. Because proteins that are targeted cotranslationally reach the IM before they have a chance to fold, our results imply the existence of a post-targeting step (most likely the initiation of translocation) that is facilitated by acidic residues distal to the signal peptide and inhibited or delayed by basic residues. These results help to resolve a long-standing puzzle about the influence of the mature region of presecretory proteins on protein export and have significant implications for optimizing the export of cytosolic and heterologous proteins in E. coli.     

Electric charge balance mechanism of extended soluble proteins

Extended proteins such as calmodulin and troponin C have two globular terminal domains linked by a central region that is exposed to water and often acts as a function-regulating element. The mechanisms that stabilize the tertiary structure of extended proteins appear to differ greatly from those of globular proteins. Identifying such differences in physical properties of amino acid sequences between extended proteins and globular proteins can provide clues useful for identification of extended proteins from complete genomes including orphan sequences. In the present study, we examined the structure and amino acid sequence of extended proteins. We found that extended proteins have a large net electric charge, high charge density, and an even balance of charge between the terminal domains, indicating that electrostatic interaction is a dominant factor in stabilization of extended proteins. Additionally, the central domain exposed to water contained many amphiphilic residues. Extended proteins can be identified from these physical properties of the tertiary structure, which can be deduced from the amino acid sequence. Analysis of physical properties of amino acid sequences can provide clues to the mechanism of protein folding. Also, structural changes in extended proteins may be caused by formation of molecular complexes. Long-range effects of electrostatic interactions also appear to play important roles in structural changes of extended proteins.     

Analysis of the charge distribution in the C-terminal region of histone H1 as related to its interaction with DNA

We have studied the net positive charge distribution in the C-terminal region of histone H1. We find that it is not random, but rather uniform. In most histone H1 sequences, 4 +/- 1 positive charges are found in this region of the molecule in over 95% of all possible segments that are 10 amino acids long. Neither alternating sequences (basic-nonbasic) nor more complex repeating sequences are ever found. Clusters of three or more basic amino acids are seldom observed in somatic H1s, yet their presence increases in sperm histones and even more so in protamines. It is concluded that the C-terminal region of histone H1 has a remarkably uniform distribution of charge, in spite of its apparent variations in sequence in different proteins and within individual molecules. The functional significance of these findings is discussed, suggesting a purely electrostatic role for the C-terminal region of histone H1, which may be evenly wrapped around individual segments of DNA molecules, thus decreasing its net charge. A likely candidate for a long alpha-helical region in the C-terminal region of histone H1 from sea urchin spermatozoa also has been located. This region may contribute to the aggregating properties of this histone in sperm chromatin.     

Transport of proteins into chloroplasts. Delineation of envelope "transit" and thylakoid "transfer" signals within the pre-sequences of three imported thylakoid lumen proteins.

The targeting of cytosolically synthesized proteins into the thylakoid lumen is mediated by an aminoterminal pre-sequence consisting of an "envelope transit" and a "thylakoid transfer" signal in tandem. We have investigated the structural characteristics of several thylakoid transfer signals by determining the intermediate sites at which the stromal processing peptidase cleaves to remove the transit sequences. Using this approach we have found that the thylakoid transfer signals of Silene pratensis plastocyanin, 23-kDa oxygen-evolving complex protein from wheat, and 33-kDa oxygen-evolving complex protein from wheat, are 25, 39, and 48 residues in length, respectively. All of the transfer signals contain hydrophobic core sequences and a "-3,-1" motif reminiscent of those found in signal sequences, but the amino-terminal regions of the transfer signals of the 23- and 33-kDa proteins are both longer and more highly charged. The net charge of each amino-terminal region of the transfer sequences is +1, including the amino-terminal amino group. In each case, the stromal processing peptidase cleaves immediately after a positively charged residue, but otherwise the cleavage sites exhibit no common elements of either primary or secondary structure.     

SENTRA, a database of signal transduction proteins

SENTRA, available via URL http://wit.mcs.anl.gov/WIT2/Sentra/, is a database of proteins associated with microbial signal transduction. The database currently includes the classical two-component signal transduction pathway proteins and methyl-accepting chemotaxis proteins, but will be expanded to also include other classes of signal transduction systems that are modulated by phosphorylation or methylation reactions. Although the majority of database entries are from prokaryotic systems, eukaroytic proteins with bacterial-like signal transduction domains are also included. Currently SENTRA contains signal transduction proteins in 34 complete and almost completely sequenced prokaryotic genomes, as well as sequences from 243 organisms available in public databases (SWISS-PROT and EMBL). The analysis was carried out within the framework of the WIT2 system, which is designed and implemented to support genetic sequence analysis and comparative analysis of sequenced genomes.