Signal-anchor sequences are an essential factor for the Golgi-plasma membrane localization of type II membrane proteins.

Despite studies of the mechanism underlying the intracellular localization of membrane proteins, the specific mechanisms by which each membrane protein localizes to the endoplasmic reticulum, Golgi apparatus, and plasma membrane in the secretory pathway are unclear. In this study, a discriminant analysis of endoplasmic reticulum, Golgi apparatus and plasma membrane-localized type II membrane proteins was performed using a position-specific scoring matrix derived from the amino acid propensity of the sequences around signal-anchors. The possibility that the sequence around the signal-anchor is a factor for identifying each localization group was evaluated. The discrimination accuracy between the Golgi apparatus and plasma membrane-localized type II membrane proteins was as high as 90%, indicating that, in addition to other factors, the sequence around signal-anchor is an essential component of the selection mechanism for the Golgi and plasma membrane localization. These results may improve the use of membrane proteins for drug delivery and therapeutic applications.

An androgenic gland membrane-anchored gene associated with the crustacean insulin-like androgenic gland hormone.

Crustacean male sexual differentiation is governed by the androgenic gland (AG) and specifically by the secreted insulin-like AG hormone (IAG), thus far identified in several decapod species including the Australian red claw crayfish Cherax quadricarinatus (termed Cq-IAG). While a few insulin-like AG genes have been identified in crustaceans, other AG-specific genes have not been documented until now. In the present study, we describe the recent identification of a non-IAG AG-specific transcript obtained from the C. quadricarinatus AG cDNA library. This transcript, termed C. quadricarinatus membrane-anchored AG-specific factor (Cq-MAG), was fully sequenced and found to encode a putative product of 189 amino acids including a signal anchoring peptide. Expression of a recombinant GFP fusion protein lacking the signal anchor encoding sequence dramatically affected recombinant protein localization pattern. While the expression of the deleterious fusion protein was observed throughout most of the cell, the native GFP::Cq-MAG fusion protein was observed mainly surrounding the periphery of the nucleus, demonstrating an endoplasmic reticulum (ER)-like localization pattern. Moreover, co-expression of the wild-type Cq-MAG (fused to GFP) and the Cq-IAG hormone revealed that these peptides indeed co-localize. This study is the first to report a protein specifically associated with the insulin-like AG hormone in addition to the finding of another AG-specific transcript in crustaceans. Previous knowledge suggests that insulin/insulin-like factor secretion involves tissue-specific transcripts and membrane-anchored proteins. In this regard, Cq-MAG's tissue specificity, anchoring properties and intracellular co-localization with Cq-IAG suggest that it may play a role in the processing and secretion of this insulin-like AG hormone.

Heterologous expression in Toxoplasma gondii reveals a topogenic signal anchor in a Plasmodium apicoplast protein.

Glutathione peroxidase-like thioredoxin peroxidase (PfTPxGl) is an antioxidant enzyme trafficked to the apicoplast, a secondary endosymbiotic organelle, in Plasmodium falciparum. Apicoplast trafficking signals usually consist of N-terminal signal and transit peptides, but the trafficking signal of PfTPxGl appears to exhibit important differences. As transfection is a protracted process in P. falciparum, we expressed the N terminus of PfTPxGl as a GFP fusion protein in a related apicomplexan, Toxoplasma gondii, in order to dissect its trafficking signals. We show that PfTPxGl possesses an N-terminal signal anchor that takes the protein to the endoplasmic reticulum in Toxoplasma-this is the first step in the apicoplast targeting pathway. We dissected the residues important for endomembrane system uptake, membrane anchorage, orientation, spacing, and cleavage. Protease protection assays and fluorescence complementation revealed that the C terminus of the protein lies in the ER lumen, a topology that is proposed to be retained in the apicoplast. Additionally, we examined one mutant, responsible for altered PfTPxGl targeting in Toxoplasma, in Plasmodium. This study has demonstrated that PfTPxGl belongs to an emergent class of proteins that possess signal anchors, unlike the canonical bipartite targeting signals employed for the trafficking of luminal apicoplast proteins. This work adds to the mounting evidence that the signals involved in the targeting of apicoplast membrane proteins may not be as straightforward as those of luminal proteins, and also highlights the usefulness of T. gondii as a heterologous system in certain aspects of this study, such as reducing screening time and facilitating the verification of membrane topology.

Functional analysis of the N-terminal region of endolysin Lyb5 encoded by Lactobacillus fermentum bacteriophage φPYB5.

Lactobacillus fermentum temperate bacteriophage φPYB5 uses endolysin Lyb5 and holin Hyb5 to burst the host cell. Previous results showed that expression of Lyb5 in Escherichia coli caused host cell lysis slowly, leading us to suppose that Lyb5 could pass the cytoplasmic membrane partly. In this work, the function of a putative signal peptide (SPLyb5) at the N-terminal of Lyb5 was investigated. In E. coli, the cell adopted a spherical shape during induction of Lyb5 protein, while morphological changes were not observed during expression of the SPLyb5 truncation, indicating that the SPLyb5 motif may serve as a functional signal peptide. However, SPLyb5 was not proteolytically cleaved at the predicted site during the translocation of Lyb5, and the expressed Lyb5 protein appeared in the cytoplasm, cytoplasmic membrane and periplasm fractions with the same molecular mass. Similar results were obtained using Lactococcus lactis as a host to express Lyb5. These results indicated that SPLyb5 could direct Lyb5 to the periplasm in a membrane-tethered form, and then release it as a soluble active enzyme into the periplasm. In addition, SPLyb5 could also drive the fused NucleaseB protein to the extracytoplasm environment in E. coli as well as in L. lactis. We proposed that in Gram-negative and Gram-positive hosts SPLyb5 acted as a signal-anchor-release domain, which was firstly identified here by experimental evidences in lactic acid bacteria phages. The application of signal-anchor-release domain for endolysin export in bacteriophages infecting Gram-positive and Gram-negative hosts was discussed.

N-Terminal Signal Peptides of G Protein-Coupled Receptors: Significance for Receptor Biosynthesis, Trafficking, and Signal Transduction.

Signal sequences play a key role during the first steps of the intracellular transport of G protein-coupled receptors (GPCRs). They are involved in targeting of the nascent chains to the membrane of the endoplasmic reticulum (ER) and initiate integration of the newly synthesized receptors into this compartment. Two classes of signal sequences are known: N-terminal signal peptides, which are usually cleaved-off following ER insertion and internal signal sequences, the so-called signal anchor sequences, which form part of the mature proteins. About 5-10% of the GPCRs contain N-terminal signal peptides; the vast majority possesses signal anchor sequences. The reason why only a subset of GPCRs require signal peptides for ER targeting/insertion was addressed in the past decade by a limited number of studies indicating that the presence of signal peptides facilitates N-tail translocation at the ER membrane. Interestingly, recent work showed that signal peptides of GPCRs do not only serve "classical" functions in the early secretory pathway. Uncleaved pseudo signal peptides may regulate receptor densities in the plasma membrane, receptor dimerization, and G protein coupling selectivity. On the other hand, even cleaved and released peptides may have post-ER functions. In this review, we summarize the current knowledge about cleavable signal peptides of GPCRs and address also the question whether these sequences may serve as future drug targets in pharmacology.