Mechanism, specificity, and physiology of signal peptide peptidase (SPP) and SPP-like proteases.

Signal peptide peptidase (SPP) and the homologous SPP-like (SPPL) proteases SPPL2a, SPPL2b, SPPL2c and SPPL3 belong to the family of GxGD intramembrane proteases. SPP/SPPLs selectively cleave transmembrane domains in type II orientation and do not require additional co-factors for proteolytic activity. Orthologues of SPP and SPPLs have been identified in other vertebrates, plants, and eukaryotes. In line with their diverse subcellular localisations ranging from the ER (SPP, SPPL2c), the Golgi (SPPL3), the plasma membrane (SPPL2b) to lysosomes/late endosomes (SPPL2a), the different members of the SPP/SPPL family seem to exhibit distinct functions. Here, we review the substrates of these proteases identified to date as well as the current state of knowledge about the physiological implications of these proteolytic events as deduced from in vivo studies. Furthermore, the present knowledge on the structure of intramembrane proteases of the SPP/SPPL family, their cleavage mechanism and their substrate requirements are summarised. This article is part of a Special Issue entitled: Intramembrane Proteases.

Multifunctional aspartic peptidase prosegments.

The structure-function relationships of aspartic peptidases (APs) (EC 3.4.23.X) have been extensively investigated, yet much remains to be elucidated regarding the various molecular mechanisms of these enzymes. Over the past years, APs have received considerable interest for food applications (e.g. cheese, fermented foods) and as potential targets for pharmaceutical intervention in human diseases including hypertension, cancer, Alzheimer's disease, AIDS (acquired immune deficiency syndrome), and malaria. A deeper understanding of the structure and function of APs, therefore, will have a direct impact on the design of peptidase inhibitors developed to treat such diseases. Most APs are synthesized as zymogens which contain an N-terminal prosegment (PS) domain that is removed at acidic pH by proteolytic cleavage resulting in the active enzyme. While the nature of the AP PS function is not entirely understood, the PS can be important in processes such as the initiation of correct folding, protein stability, blockage of the active site, pH-dependence of activation, and intracellular sorting of the zymogen. This review summarizes the current knowledge of AP PS function (especially within the A1 family), with particular emphasis on protein folding, cellular sorting, and inhibition.

Signal peptide peptidases: a family of intramembrane-cleaving proteases that cleave type 2 transmembrane proteins.

Five genes encode the five human signal peptide peptidases (SPPs), which are intramembrane-cleaving aspartyl proteases (aspartyl I-CLiPs). SPPs have been conserved through evolution with family members found in higher eukaryotes, fungi, protozoa, arachea, and plants. SPPs are related to the presenilin family of aspartyl I-CLiPs but differ in several key aspects. Presenilins (PSENs) and SPPs both cleave the transmembrane region of membrane proteins; however, PSENs cleave type 1 membrane proteins whereas SPPs cleave type 2 membrane proteins. Though the overall homology between SPPs and PSENs is minimal, they are multipass membrane proteins that contain two conserved active site motifs YD and GxGD in adjacent membrane-spanning domains and a conserved PAL motif of unknown function near their COOH-termini. They differ in that the active site YD and GxGD containing transmembrane domains of SPPs are inverted relative to PSENs, thus, orienting the active site in a consistent topology relative to the substrate. At least two of the human SPPs (SPP and SPPL3) appear to function without additional cofactors, but PSENs function as a protease, called gamma-secretase, only when complexed with Nicastrin, APH-1 and Pen-2. The biological roles of SPP are largely unknown, and only a few endogenous substrates for SPPs have been identified. Nevertheless there is emerging evidence that SPP family members are highly druggable and may regulate both essential physiologic and pathophysiologic processes. Further study of the SPP family is needed in order to understand their biological roles and their potential as therapeutic targets.

Aspartic proteases gene family in rice: Gene structure and expression, predicted protein features and phylogenetic relation.

Aspartic proteases constitute a large family in eukaryotes, which play fundamental roles in protein processing, maturation and degradation. In this study, we identified 96 OsAP genes in rice (Oryza sativa L.), the model plant for monocots, by a reiterative database search. The analysis of the complete set of OsAP genes is presented, including chromosomal location, phylogenetic relationships, classification and gene structure. Moreover, a comprehensive expression analysis of OsAP family genes was performed using 24 tissues during the plant life cycle of two rice cultivars. Sixty-six OsAP genes were found to be expressed in at least one of the examined developmental stages, which were divided into 3 classes based on their transcript levels. OsAP genes were also found to be differentially up- or down-regulated in rice seedlings in response to treatments with phytohormones, as well as in plumules/radicles under light/dark conditions. The comprehensive annotation and expression profiling undertaken in this research add to our understanding of OsAP family genes in rice growth and development. Our results also provide a basis for selection of candidate genes for functional validation in future studies.

Widespread tissue expression of nepenthesin-like aspartic protease genes in Arabidopsis thaliana.

There are approximately 69 genes encoding aspartyl protease homologues in Arabidopsis thaliana, and most of the gene products constitute a novel subfamily of aspartic proteases. However, their physiological roles are largely unknown. As an initial step to shed light on the roles of these nepenthesin-like aspartic proteases (NAPs), a phylogenetic tree was constructed, which indicated that these proteases are classified into several distinct sub-sub-groups. Based on these results, specific primers were designed for genes selected from several of these groups and their tissue expression was investigated using RT-PCR. The results indicated that these genes are widely expressed in several tissues, such as leaves, stems, seeds and pods, suggesting ubiquitous occurrence and multiple functions of the corresponding proteases in the tissues of A. thaliana.

A family of glycosylphosphatidylinositol-linked aspartyl proteases is required for virulence of Candida glabrata.

Candida glabrata is a yeast pathogen of humans. We have established a tissue culture model to analyze the interaction of C. glabrata with macrophages. Transcript profiling of yeast ingested by macrophages reveals global changes in metabolism as well as increased expression of a gene family (YPS genes) encoding extracellular glycosylphosphatidylinositol-linked aspartyl proteases. Eight of these YPS genes are found in a cluster that is unique to C. glabrata. Genetic analysis shows that the C. glabrata YPS genes are required for cell wall integrity, adherence to mammalian cells, survival in macrophages and virulence. By monitoring the processing of a cell wall adhesin, Epa1, we also show that Yps proteases play an important role in cell wall re-modeling by removal and release of glycosylphosphatidylinositol-anchored cell wall proteins.

Isolation, activity and immunological characterisation of a secreted aspartic protease, CtsD, from Aspergillus fumigatus.

Aspergillus fumigatus is an opportunistic fungal pathogen that infects immunocompromised patients. A putative aspartic protease gene (ctsD; 1425 bp; intron-free) was identified and cloned. CtsD is evolutionarily distinct from all previously identified A. fumigatus aspartic proteases. Recombinant CtsD was expressed in inclusion bodies in Escherichia coli (0.2mg/g cells) and subjected to extensive proteolysis in the baculovirus expression system. Activation studies performed on purified, refolded, recombinant CtsD resulted in protease activation with a pH(opt)4.0 and specific activity=10 U/mg. Pepstatin A also inhibited recombinant CtsD activity by up to 72% thereby confirming classification as an aspartic protease. Native CtsD was also immunologically identified in culture supernatants and purified from fungal cultures using pepstatin-agarose affinity chromatography (7.8 microg CtsD/g mycelia). In A. fumigatus, semi-quantitative RT-PCR analysis revealed expression of ctsD in minimal and proteinaceous media only. Expression of ctsD was absent under nutrient-rich conditions. Expression of ctsD was also detected, in vivo, in the Galleria mellonella virulence model following A. fumigatus infection.

Isolation and characterization of recombinant Drosophila Copia aspartic proteinase.

The wild type Copia Gag precursor protein of Drosophila melanogaster expressed in Escherichia coli was shown to be processed autocatalytically to generate two daughter proteins with molecular masses of 33 and 23 kDa on SDS/PAGE. The active-site motif of aspartic proteinases, Asp-Ser-Gly, was present in the 23 kDa protein corresponding to the C-terminal half of the precursor protein. The coding region of this daughter protein (152 residues) in the copia gag gene was expressed in E. coli to produce the recombinant enzyme protein as inclusion bodies, which was then purified and refolded to create the active enzyme. Using the peptide substrate His-Gly-Ile-Ala-Phe-Met-Val-Lys-Glu-Val-Asn (cleavage site: Phe-Met) designed on the basis of the sequence of the cleavage-site region of the precursor protein, the enzymatic properties of the proteinase were investigated. The optimum pH and temperature of the proteinase toward the synthetic peptide were 4.0 and 70 degrees C respectively. The proteolytic activity was increased with increasing NaCl concentration in the reaction mixture, the optimum concentration being 2 M. Pepstatin A strongly inhibited the enzyme, with a Ki value of 15 nM at pH 4.0. On the other hand, the active-site residue mutant, in which the putative catalytic aspartic acid residue was mutated to an alanine residue, had no activity. These results show that the Copia proteinase belongs to the family of aspartic proteinases including HIV proteinase. The B-chain of oxidized bovine insulin was hydrolysed at the Leu15-Tyr16 bond fairly selectively. Thus the recombinant Copia proteinase partially resembles HIV proteinase, but is significantly different from it in certain aspects.

Aspartic proteinase content of the Arabidopsis genome.

The sequence of the Arabidopsis genome has given us information about one plant's complement of aspartic proteinases. Using an in silico analysis based on the homology to known aspartic proteinase genes, we have uncovered 51 sequences that potentially encode these enzymes. This is substantial more than the number predicted for other eukaryotic systems. We have grouped the deduced amino acid sequences into 3 classes - typical plant aspartic proteinase, nucellin-like and atypical aspartic proteinase sequences-, depending on their putative domain organizations and their active site sequence motifs. Searching databases has revealed cDNAs or ESTs for nearly 90% of these genes. Sequence analysis using software that detects targeting signals indicates most of the predicted proteins have the expected localization in the secretory system although several of these are membrane bound. The analysis also predicts 8 chloroplast localized proteins and 2 mitochondria-localized aspartic proteinase-like proteins. The wide variety of structures and subcellular locations implies multiple functions for aspartic proteinases in plants.

Abnormalities of peptide metabolism in Alzheimer disease.

The steady-state level of peptide hormones represents a balance between their biosynthesis and proteolytic processing by convertases and their catabolism by proteolytic enzymes. Low levels of neuropeptide Y, somatostatin and corticotropin-releasing factor, described in Alzheimer disease (AD), were related to a defect in proteolytic processing of their protein precursors. In contrast the abundance of beta-amyloid peptides, the major protein constituents of senile plaques is likely related to inefficient catabolism. Therefore, attention is mainly focused on convertases that generate active peptides and counter-regulatory proteases that are involved in their catabolism. Some well-described proteases such as NEP are thought to be involved in beta-amyloid catabolism. The search of other possible candidates represents a primary effort in the field. A variety of vascular risk factors such as diabetes, hypertension and arteriosclerosis suggest that the functional vascular defect contributes to AD pathology. It has also been described that beta-amyloid peptides potentiate endothelin-1 induced vasoconstriction. In this review, we will critically evaluate evidence relating proteases implicated in amyloid protein precursor proteolytic processing and beta-amyloid catabolism.

Aspartic peptidase inhibitors: implications in drug development.

The last decade has witnessed an effervescence of research interest in the development of potent inhibitors of various aspartic peptidases. As an enzyme family, aspartic peptidases are relatively a small group that has received enormous interest because of their significant roles in human diseases like involvement of renin in hypertension, cathepsin D in metastasis of breast cancer, beta-Secretase in Alzheimer's Disease, plasmepsins in malaria, HIV-1 peptidase in acquired immune deficiency syndrome, and secreted aspartic peptidases in candidal infections. There have been developments on clinically active inhibitors of HIV-1 peptidase, which have been licensed for the treatment of AIDS. The inhibitors of plasmepsins and renin are considered a viable therapeutic strategy for the treatment of malaria and hypertension. Relatively few inhibitors of cathepsin D have been reported, partly because of its uncertain role as a viable target for therapeutic intervention. The beta-secretase inhibitors OM99-2 and OM003 were designed based on the substrate specificity information. The present article is a comprehensive state-of-the-art review describing the aspartic peptidase inhibitors illustrating the recent developments in the area. In addition, the homologies between the reported inhibitor sequences have been analyzed. The understanding of the structure-function relationships of aspartic peptidases and inhibitors will have a direct impact on the design of new inhibitor drugs.

Caprine pregnancy-associated glycoproteins (PAG): their cloning, expression, and evolutionary relationship to other PAG.

Pregnancy-associated glycoproteins (PAG) are structurally related to aspartic proteinases and belong to an extensive, rapidly evolving family of recently duplicated genes expressed in the placentas of artiodactyl species. The aim of the present study was to clone PAG from the goat, study their temporal and cell-specific expression, and determine their phylogenetic relationship to PAG from other species. RT-PCR was used to generate PAG cDNA from pooled placental RNA obtained between days 45 and 115 of pregnancy. A total of 11 cDNA, which differed by > 5% from each other, were selected for complete bidirectional sequencing from 60 clones analyzed. A group of nine (caPAG1, caPAG3-7(var), caPAG9-11), which displayed > 80% sequence identity with each other, were expressed after day 45 of pregnancy and were localized to trophoblast binucleate cells. These PAG demonstrated an unusually high ratio of nonsynonymous (amino acid changing) to synonymous nucleotide differences. CaPAG2, by contrast, was detectable only in early pregnancy (days 18 and 19) and expressed throughout trophectoderm. It was of more ancient origin than the PAG1 group, but more recent than caPAG8. The latter was expressed at all stages examined (days 18 to 115). The data confirm that many PAG genes, with different patterns of temporal and spatial expression, are transcribed in the placenta of the goat. The data also suggest that the recently duplicated PAG genes are being selected for rapid diversification of function.

Three-dimensional structure analysis of PROSITE patterns.

Pattern matches for each of the sequence patterns in PROSITE, a database of sequence patterns, were searched in all protein sequences in the Brookhaven Protein Data Bank (PDB). The three-dimensional structures of the pattern matches for the 20 patterns with the largest numbers of hits were analysed. We found that the true positives have a common three-dimensional structure for each pattern; the structures of false positives, found for six of the 20 patterns, were clearly different from those of the true positives. The results suggest that the true pattern matches each have a characteristic common three-dimensional structure, which could be used to create a template to define a three-dimensional functional pattern.

GAP-releasing enzyme is a member of the pro-hormone convertase family of precursor protein processing enzymes.

The recent discovery of mammalian endoproteinases which show extensive sequence homology with the yeast Kex 2 gene product (kexin) has lead to the hypothesis that processing enzymes of pro-hormone precursor proteins belong to a family of calcium dependent, subtilisin-like serine proteinases. We previously showed that hypothalamic GAP-releasing enzyme shares these characteristics and possesses the requisite specificity to be considered as a processing enzyme of progonadotropin releasing hormone (pro-GnRH) precursor protein. Thus, GAP-releasing enzyme (and other non-related proteins) were tested for their immunological reactivity with antisera raised against pituitary pro-hormone convertase 1/3 (PC1/3) and insulinoma PC2. On the basis of indirect enzyme-linked immunosorbent (ELISA) and Western blot assays, GAP-releasing enzyme is now shown to be immunologically related to PC1/3. We can conclude that GAP-releasing enzyme is also likely to be a member of the pro-hormone convertase family and should be considered the physiologically relevant processing enzyme of pro-GnRH. It is possible that GAP-releasing enzyme represents bovine hypothalamic PC1/3.