Can a signal sequence become too hydrophobic?

Pathogenic signal peptide variants in the human genome

Secreted and membrane proteins represent a third of all cellular proteins and contain N-terminal signal peptides that are required for protein targeting to endoplasmic reticulum (ER). Mutations in signal peptides affect protein targeting, translocation, processing, and stability, and are associated with human diseases. However, only a few of them have been identified or characterized. In this report, we identified pathogenic signal peptide variants across the human genome using bioinformatic analyses and predicted the molecular mechanisms of their pathology. We recovered more than 65 thousand signal peptide mutations, over 11 thousand we classified as pathogenic, and proposed framework for distinction of their molecular mechanisms. The pathogenic mutations affect over 3.3 thousand genes coding for secreted and membrane proteins. Most pathogenic mutations alter the signal peptide hydrophobic core, a critical recognition region for the signal recognition particle, potentially activating the Regulation of Aberrant Protein Production (RAPP) quality control and specific mRNA degradation. The remaining pathogenic variants (about 25%) alter either the N-terminal region or signal peptidase processing site that can result in translocation deficiencies at the ER membrane or inhibit protein processing. This work provides a conceptual framework for the identification of mutations across the genome and their connection with human disease.

Functional expression of the human coagulation factor IX using heterologous signal peptide and propeptide sequences in mammalian cell line

OBJECTIVE

To study the functions of pre-pro leader peptides of the human and porcine prothrombins on the human FIX (hFIX) expression.

RESULTS

In silico analysis predicted higher secretion efficiencies for the prothrombins-derived signal peptides, in comparison with the native hFIX signal peptide. Replacements of the hFIX pre-pro sequence with those of the two prothrombins, led to increased levels of transcription of the chimeric transgenes, as compared to the native clone. This was in consistent with the lower minimum free energies, calculated for the recombinant transcripts, based on their secondary structures. Evaluation of secretion efficiency revealed that the highest and lowest FIX secretions belong to signal peptides derived from porcine' prothrombin and hFIX, respectively. Coagulation activities of the FIX expressed from chimeric variants could be increased up to tenfold, relative to the native clone.

CONCLUSION

The feasibility of a leader-peptide replacement for the improvement of both transcription and post-transcriptional processes is described that can be relevant for production the vitamin-K dependent proteins.

Characterization of the secretion pathway of the collagen adhesin EmaA of Aggregatibacter actinomycetemcomitans

The extracellular matrix protein adhesin A (EmaA) surface antennae-like structures of the periodontal pathogen Aggregatibacter actinomycetemcomitans are composed of three identical protein monomers. Recently, we have demonstrated that the protein is synthesized with an extended signal peptide of 56 amino acids necessary for membrane targeting and protein translocation. In this study, EmaA secretion was demonstrated to be reliant on a chaperone-dependent secretion pathway. Deletion of secB partially reduced but did not abolish the amount of EmaA in the membrane. This observation was attributed to an increase in the synthesis of DnaK in the ΔsecB strain. Overexpression of a DnaK substitution mutant (A174T), with diminished activity, in the ΔsecB strain further reduced the amount of EmaA in the membrane. Expression of dnaK A174T in the wild-type strain did not affect the amount of EmaA in the membrane when grown under optimal growth conditions at 37°C. However, EmaA was found to be reduced when this strain was grown at heat-shock temperature. A chromosomal deletion of amino acids 16-39 of the EmaA extended signal peptide, transformed with either the wild-type or dnaK A174T-expressing plasmid, did not affect the amount of EmaA in the membrane. In addition, the level of EmaA in a ΔsecB/emaA(-) double mutant strain expressing EmaAΔ16-39 was unchanged when grown at both temperatures. The data suggest that chaperones are required for the targeting of EmaA to the membrane and a specific region of the signal peptide is necessary for secretion under stress conditions.

Discovery of functional motifs in h-regions of trypanosome signal sequences

N-terminal signal peptides direct secretory proteins into the ER (endoplasmic reticulum) of eukaryotes or the periplasmic space of prokaryotes. A hydrophobic core (h-region) is important for signal sequence function; however, the mechanism of h-region action is not resolved. To gain new insight into signal sequences, bioinformatic analysis of h-regions from humans, Saccharomyces cerevisiae, Trypanosoma brucei and Escherichia coli was performed. Each species contains a unique set of peptide motifs (h-motifs) characterized by identity components (i.e. sequence of conserved amino acids) joined by spacers. Human h-motifs have four identity components, whereas those from the other species utilize three identity components. Example of h-motifs are human Hs3 {L-x(2)-[AGILPV]-L-x(0,2)-L}, S. cerevisiae Sc1 [L-x(0,2)-S-x(0,3)-A], T. brucei Tb2 {L-x(1,2)-L-[AILV]} and E. coli Ec1 [A-x(0,2)-L-x(0,3)-A]. The physiological relevance of h-motifs was tested with a T. brucei microsomal system for translocation of a VSG (variant surface glycoprotein)-117 signal peptide. Disruption of h-motifs by scrambling of sequences in h-regions produced defective signal peptides, although the hydrophobicity of the peptide was not altered. We conclude that: (i) h-regions harbour h-motifs, and are not random hydrophobic amino acids; (ii) h-regions from different species contain unique sets of h-motifs; and (iii) h-motifs contribute to the biological activity of ER signal peptides. h-Regions are ‘scaffolds’ in which functional h-motifs are embedded. A hypothetical model for h-motif interactions with a Sec61p protein translocon is presented.

Topogenesis of membrane proteins: determinants and dynamics

For targeting and integration of proteins into the mammalian endoplasmic reticulum, two types of signals can be distinguished: those that translocate their C-terminal sequence (cleavable signals and signal-anchors) and those that translocate their N-terminus (reverse signal-anchors). In addition to the well established effect of flanking charges, also the length and hydrophobicity of the apolar core of the signal as well as protein folding and glycosylation contribute to orienting the signal in the translocon. In multi-spanning membrane proteins, topogenic determinants are distributed throughout the sequence and may even compete with each other. During topogenesis, segments of up to 60 residues may move back and forth through the translocon, emphasizing unexpected dynamic aspects of topogenesis.

Impaired Cotranslational Processing as a Mechanism for Type I Antithrombin Deficiency

Most secretory proteins, including antithrombin (AT), are synthesized with a signal peptide, which is cleaved before the mature protein is exported from the cell. The signal peptide is important in the process whereby nascent protein is recognized as requiring subsequent modification within the endoplasmic reticulum (ER). We have identified a novel mutation, 2436T→C L(-10)P, which affects the central hydrophobic domain of the AT signal peptide, in a proband presenting with venous thrombotic disease and type I AT deficiency. We investigated the basis of the phenotype by examining expression in mammalian cells of a range of variant AT cDNAs with mutations affecting the –10 residue. Glycosylated AT was secreted from COS-7 cells transfected with wild-type AT, –10L deletion, -10V or -10M variants, but not variants with P, T, R, or G at -10. Cell-free expression of wild-type and variant AT cDNAs was then performed in the presence of canine pancreatic microsomes, as a substitute for ER. Variant AT proteins with P, T, R, or G at residue –10 did not undergo posttranslational glycosylation, and their susceptibility to trypsin digestion suggested they had not been translocated into microsomes. Our results suggest that the ability of AT signal peptide to direct the protein to ER for cotranslational processing events appears to be critically dependent on maintaining the hydrophobic nature of the region including residue –10. The investigations have defined impaired cotranslational processing as a hitherto unrecognized cause of hereditary AT deficiency.

Impaired Cotranslational Processing as a Mechanism for Type I Antithrombin Deficiency

Most secretory proteins, including antithrombin (AT), are synthesized with a signal peptide, which is cleaved before the mature protein is exported from the cell. The signal peptide is important in the process whereby nascent protein is recognized as requiring subsequent modification within the endoplasmic reticulum (ER). We have identified a novel mutation, 2436T→C L(-10)P, which affects the central hydrophobic domain of the AT signal peptide, in a proband presenting with venous thrombotic disease and type I AT deficiency. We investigated the basis of the phenotype by examining expression in mammalian cells of a range of variant AT cDNAs with mutations affecting the –10 residue. Glycosylated AT was secreted from COS-7 cells transfected with wild-type AT, –10L deletion, -10V or -10M variants, but not variants with P, T, R, or G at -10. Cell-free expression of wild-type and variant AT cDNAs was then performed in the presence of canine pancreatic microsomes, as a substitute for ER. Variant AT proteins with P, T, R, or G at residue –10 did not undergo posttranslational glycosylation, and their susceptibility to trypsin digestion suggested they had not been translocated into microsomes. Our results suggest that the ability of AT signal peptide to direct the protein to ER for cotranslational processing events appears to be critically dependent on maintaining the hydrophobic nature of the region including residue –10. The investigations have defined impaired cotranslational processing as a hitherto unrecognized cause of hereditary AT deficiency.

Another factor besides hydrophobicity can affect signal peptide interaction with signal recognition particle

Translocation of alkaline extracellular protease (AEP) into the endoplasmic reticulum of Yarrowia lipolytica is cotranslational and signal recognition particle (SRP)-dependent, whereas translocation of P17M AEP (proline to methionine at position 17, second amino acid in the pro-region) is posttranslational and SRP-independent. P17M signal peptide mutations that resulted in more rapid SRP-dependent translocation of AEP precursor were isolated. Most of these mutations significantly increased hydrophobicity, but the A12P/P17M mutation did not. The switch from SRP-dependent to SRP-independent translocation without a decrease in hydrophobicity (wild type to P17M) and restoration of SRP-dependent translocation without an increase in hydrophobicity (P17M to A12P/P17M) indicate that some factor(s) in addition to hydrophobicity determines selection of targeting pathway. Models of extended forms of wild type and A12P/P17M signal peptides are kinked, whereas the P17M signal peptide is relatively straight. Possibly the conformation/orientation of signal peptides at the ribosomal surface affects SRP binding and consequently the targeting route to the endoplasmic reticulum. Kinked signal peptides might approach SRP more closely more often. Most likely, these effects were only detectable because of the short length and low average hydrophobicity of the AEP signal peptide.

Subunit II of the cytochrome bo3 ubiquinol oxidase from Escherichia coli is a lipoprotein

The purified Escherichia coli cytochrome bo3 ubiquinol oxidase contains four subunits that are each integral components of the cytoplasmic membrane. The molecular weight of each of the subunits has been determined by matrix-assisted laser desorption ionization mass spectrometry (MALDI). The observed molecular weight of subunit II (CyoA) is considerably less than the calculated value from the deduced amino acid sequence, indicating possible posttranslational processing. The similarity of a portion of the sequence near the N-terminus of CyoA with the sequences of known prokaryotic membrane-bound lipoproteins suggested that CyoA is proteolytically processed to generate an N-terminus at Cys25, and that Cys25 is covalently modified by the addition of lipids. This would be consistent with the observed molecular mass, and was confirmed by demonstrating the incorporation of radioactive palmitic acid into subunit II of the cytochrome bo3 oxidase. Site-directed mutagenesis replacing Cys25 by alanine prevents the processing, generating a precursor form of CyoA with a higher molecular mass. The C25A mutant of CyoA still assembles as an active quinol oxidase capable of supporting growth of the cells by aerobic respiration. Hence, this unusual processing of a cytoplasmic membrane protein, which is already anchored to the membrane by two transmembrane helices, is not essential for either assembly or function.

A double-strand break in a herpesvirus genome stimulates targeted homologous recombination with exogenous, cloned viral sequences

A method is described for the highly efficient recovery of recombinant pseudorabies virions; the approach should be applicable to other herpesviruses. Pseudorabies virus (PRV) strain PRV509 contains a unique EcoRI site in its genome, largely replacing the glycoprotein gC gene. By digesting PRV509 DNA with EcoRI prior to cotransfection with plasmid DNA that harbored a cloned copy of gC, we isolated recombinant viruses containing the cloned gC allele at a frequency exceeding 75%. This represented u to a 37-fold increase over the use of intact viral DNA in cotransfection experiments, and may eliminate the need for phenotypic screening of recombinants. Closer analysis of the recombinant viruses revealed that genetic markers up to 1 kilobase pair apart could be recombined into the genome using the EcoRI-digested DNA. Overall, the increased frequency of recombinant viruses can be explained if homologous recombination at sites of double-strand breakage is a more efficient repair mechanism than the re-annealing and ligation of the break itself.

The receptor-binding domain of pseudorabies virus glycoprotein gC is composed of multiple discrete units that are functionally redundant

Many herpesviruses attach to cells in a two-step process, using the glycoprotein gC family of homologs to bind the primary receptor, heparan sulfate (HS) proteoglycan, and glycoprotein gD homologs to bind an unknown secondary receptor. We have previously shown by deletion analysis that the amino-terminal one-third of gC from pseudorabies virus (PRV), a swine herpesvirus, includes at least the principal HS receptor-binding domain. This portion of PRV gC contains three discrete clusters of basic residues that exactly or nearly match proposed consensus sequences for heparin-binding domains (HBDs); four additional potential HBDs lie in the distal two-thirds of the glycoprotein. We now specifically implicate each of the three amino-terminal HBDs in virus attachment. Mutational analysis demonstrated that any one of the three HBDs could mediate efficient virus infectivity; HS-dependent PRV attachment to cells was eliminated only after all three amino-terminal HBDs were altered. Furthermore, the binding dysfunction was due to a disruption of the specific HBDs and not to total charge loss. Thus, unlike previously described viral receptor-binding domains, the PRV gC receptor-binding domain is composed of multiple, discrete units that can function independently of one another. These units may function redundantly either to increase binding affinity or perhaps to effectively increase the virus's host range.

Systematic introduction of proline in a eukaryotic signal sequence suggests asymmetry within the hydrophobic core

The hydrophobic core or h region of both prokaryotic and eukaryotic signal sequences is the predominant structural domain that controls the efficiency of protein translocation across membranes. Characteristically, hydrophobic cores appear to assume alpha-helical conformations, and studies in prokaryotes have indicated that this conformation is necessary for efficient signal sequence function. To address the conformational constraints of a eukaryotic signal sequence, we have introduced a single proline in almost each position of the signal sequence hydrophobic core of glycoprotein C (gC) of the swine herpesvirus, pseudorabies virus. When the resulting mutant virus strains were used to infect cells, we found that substitution of proline at certain positions affected gC translocation greater than its introduction at other sites within the hydrophobic core. The observed positional effects did not completely correlate with reductions in overall hydrophobicity or linear position within the hydrophobic core. Rather, it appeared that one face of the gC signal sequence alpha-helix is far more sensitive to proline disruption than the other, potentially indicating a functional asymmetry.