Corneodesmosin, a component of epidermal corneocyte desmosomes, displays homophilic adhesive properties.

Corneodesmosomes, the modified desmosomes of the uppermost layers of the epidermis, play an important role in corneocyte cohesion. Corneodesmosin is a secreted glycoprotein located in the corneodesmosomal core and covalently linked to the cornified envelope of corneocytes. Its glycine- and serine-rich NH(2)-terminal domain may fold to give structural motifs similar to the glycine loops described in epidermal cytokeratins and loricrin and proposed to display adhesive properties. A chimeric protein comprising human corneodesmosin linked to the transmembrane and cytoplasmic domains of mouse E-cadherin was expressed in mouse fibroblasts to test the ability of corneodesmosin to promote cell-cell adhesion. Classic aggregation assays indicated that corneodesmosin mediates homophilic cell aggregation. Moreover, Ca(2+) depletion showed a moderate effect on aggregation. To assess the involvement of the glycine loop domain in adhesion, full-length corneodesmosin, corneodesmosin lacking this domain, or this domain alone were expressed as glutathione S-transferase fusion proteins and tested for protein-protein interactions by overlay binding assays. The results confirmed that corneodesmosin presents homophilic interactions and indicated that its NH(2)-terminal glycine loop domain is sufficient but not strictly necessary to promote binding. Altogether, these results provide the first experimental evidence for the adhesive properties of corneodesmosin and for the involvement of its glycine loop domain in adhesion.     

The α-helical content of the transmembrane domain of the British dementia protein-2 (Bri2) determines its processing by signal peptide peptidase-like 2b (SPPL2b)

Regulated intramembrane proteolysis is a widely accepted concept describing the processing of various transmembrane proteins via ectodomain shedding followed by an intramembrane cleavage. The resulting cleavage products can be involved in reverse signaling. Presenilins, which constitute the active center of the γ-secretase complex, signal peptide peptidase (SPP), and its homologues, the SPP-like (SPPL) proteases are members of the family of intramembrane-cleaving aspartyl proteases of the GXGD-type. We recently demonstrated that Bri2 (itm2b) is a substrate for regulated intramembrane proteolysis by SPPL2a and SPPL2b. Intramembrane cleavage of Bri2 is triggered by an initial shedding event catalyzed by A Disintegrin and Metalloprotease 10 (ADAM10). Additionally primary sequence determinants within the intracellular domain, the transmembrane domain and the luminal juxtamembrane domain are required for efficient cleavage of Bri2 by SPPL2b. Using mutagenesis and circular dichroism spectroscopy we now demonstrate that a high α-helical content of the Bri2 transmembrane domain (TMD) reduces cleavage efficiency of Bri2 by SPPL2b, while the presence of a GXXXG dimerization motif influences the intramembrane cleavage only to a minor extent. Surprisingly, only one of the four conserved intramembrane glycine residues significantly affects the secondary structure of the Bri2 TMD and thereby its intramembrane cleavage. Other glycine residues do not influence the α-helical content of the transmembrane domain nor its intramembrane processing.     

Limited proteolysis as a probe of the conformation and nucleic acid binding regions of nucleolin.

Nucleolin, also called protein C23, is a RNA-associated protein implicated in the early stages of ribosome assembly. To study the general conformation and map the nucleic acid binding regions, rat nucleolin was subjected to limited proteolysis using trypsin and chymotrypsin in the presence or absence of poly(G). The cleavage sites were classified according to their locations in the three putative domains: the highly polar amino-terminal domain, the central nucleic acid binding domain, which contains four 90-residue repeats, and the carboxyl-terminal domain, which is rich is glycine, dimethylarginine, and phenylalanine. The most labile sites were found in basic segments of the amino-terminal domain. This region was stabilized by Mg2+. At low enzyme concentrations, cleavage by trypsin or chymotrypsin in the amino-terminal domain was enhanced by poly(G). Trypsin produced a relatively stable 48-kDa fragment containing the central and carboxyl-terminal domains. The enhanced cleavage suggests that binding of nucleic acid by the central domain alters the conformation of the amino-terminal domain, exposing sites to proteolytic cleavage. At moderate enzyme concentrations, the 48-kDa fragment was protected by poly(G) against tryptic digestion. At the highest enzyme concentrations, both enzymes cleaved near the boundaries between repeats 2, 3, and 4 with some sites protected by poly(G), suggesting that the repeats themselves form compact units. The carboxyl-terminal domain was resistant to trypsin but was cleaved by chymotrypsin either in the presence or in the absence of poly(G), indicating exposure of some phenylalanines in this region. These studies provide a general picture of the topology of nucleolin and suggest that the nucleic acid binding region communicates with the amino-terminal domain.     

Specific cleavage sites of Nef proteins from human immunodeficiency virus types 1 and 2 for the viral proteases.

Human immunodeficiency virus type 2 (HIV-2) Nef is proteolytically cleaved by the HIV-2-encoded protease. The proteolysis is not influenced by the absence or presence of the N-terminal myristoylation. The main cleavage site is located between residues 39 and 40, suggesting a protease recognition sequence, GGEY-SQFQ. As observed previously for Nef protein from HIV-1, a large, stable core domain with an apparent molecular mass of 30 kDa is produced by the proteolytic activity. Cleavage of Nef from HIV-1 in two domains by its own protease or the protease from HIV-2 is also independent of Nef myristoylation. However, processing of HIV-1 Nef by the HIV-2 protease is less selective than that by the HIV-1 protease: the obtained core fragment is heterogeneous at its N terminus and has an additional cleavage site between amino acids 99 and 100. Preliminary experiments suggest that the full-length Nef of HIV-2 and the core domain are part of the HIV-2 particles, analogous to the situation reported recently for HIV-1.     

C-terminal processing of the toxoplasma protein MIC2 is essential for invasion into host cells

Host cell invasion by apicomplexan parasites is accompanied by the rapid, polarized secretion of parasite proteins that are involved in cell attachment. The Toxoplasma gondii micronemal protein MIC2 contains several extracellular adhesive domains, a transmembrane domain, and a short cytoplasmic tail. Following apical secretion, MIC2 is transiently present on the parasite surface before being translocated backward and released by proteolytic cleavage. Mutations in the extracellular domain of MIC2, directly upstream of the transmembrane domain, prevented processing and release of the soluble protein into the supernatant. A conserved basic residue in MIC2 was essential for cleavage, and basic residues are similarly positioned in other microneme proteins. Following the induction of secretion, MIC2 processing mutants were stably expressed on the surface of the parasite. Surface MIC2-expressing mutants showed increased adhesion to host cells, yet were impaired in their capacity to invade. These data demonstrate that proteolysis is essential for releasing cell surface adhesins prior to cell entry by apicomplexan parasites.     

Combinatorial expression of alpha- and gamma-protocadherins alters their presenilin-dependent processing

Alpha- and gamma-protocadherins (Pcdhs) are type I transmembrane receptors expressed predominantly in the central nervous system and located in part in synapses. They are transcribed from complex genomic loci, giving rise in the mouse to 14 alpha-Pcdh and 22 gamma-Pcdh isoforms consisting of variable domains, each encompassing the extracellular region, the transmembrane region, and part of the intracellular region harboring the alpha- or gamma-Pcdh-specific invariant cytoplasmic domain. Presenilin-dependent intramembrane proteolysis (PS-IP) of gamma-Pcdhs and the formation of alpha/gamma-Pcdh heteromers led us to investigate the effects of homo- and heteromer formation on gamma- and putative alpha-Pcdh membrane processing and signaling. We find that upon surface delivery, alpha-Pcdhs, like gamma-Pcdhs, are subject to matrix metallo-protease cleavage followed by PS-IP in neurons. We further demonstrate that the combinatorial expression of alpha- and gamma-Pcdhs modulates the extent of their PS-IP, indicating the formation of alpha/gamma-Pcdh heteromers with an altered susceptibility to processing. Cell-specific expression of alpha/gamma-Pcdh isoforms could thus determine cell and synapse adhesive properties as well as intracellular and nuclear signaling by their soluble cytoplasmic cleavage products, alpha C-terminal fragment 2 (alpha-CTF-2) and gamma-CTF-2.     

Elimination of KLK5 inhibits early skin tumorigenesis by reducing epidermal proteolysis and reinforcing epidermal microstructure

Epidermal desquamation involves a finely-tuned proteolytic cascade ensuring the regulated cleavage of desmosomes that releases old stratum corneum outermost layers. Although the roles of desmosomes in normal physiology are well-established, their putative involvement in cancer remains unexplored. The KLK5 protease is thought of having fundamental roles in epidermal proteolysis and homeostasis, and its aberrant activity has been linked to skin pathologies. We found that deletion of Klk5 results in significantly higher numbers of lengthier desmosomes and enhanced skin strength. Klk5^−/− mice retained normal skin barrier function and are resistant to chemically-induced skin tumorigenesis. The resistance to tumorigenesis was not due to inhibition of inflammation, and on the contrary, absence of Klk5 increased the TPA-induced inflammatory skin response. We found that increased desmosomes and reduced proteolysis prevent oncogenic signaling by capturing β-catenin into the cytoplasm and facilitate epidermal keratinocyte apoptosis, thus, inhibiting tumor initiation. We highlight that the skin ultrastructure affects early neoplastic transformation by modulating intracellular signaling and suggest that tissue reinforcement provides a novel mode of tumor suppression.     

Proteomic analysis of cleavage events reveals a dynamic two-step mechanism for proteolysis of a key parasite adhesive complex

The transmembrane micronemal protein MIC2 and its partner M2AP comprise an adhesive complex that is required for rapid invasion of host cells by the obligate intracellular parasite Toxoplasma gondii. Recent studies have shown that the MIC2/M2AP complex undergoes extensive proteolytic processing on the parasite surface during invasion, including primary processing of M2AP by unknown proteases and proteolytic shedding of the complex by an anonymous protease called MPP1. While it was shown that MPP1-mediated cleavage is necessary for efficient invasion, it remained unclear whether the adhesive complex was liberated by juxtamembrane or intramembrane proteolysis. Here, using a three-phase strategy of assigning cleavage sites based on intact matrix-assisted laser desorption/ionization mass followed by confirmation by enzymatic digestion and inhibitor profiling, we demonstrate that M2AP is processed by two parasite-derived proteases called MPP2 and MPP3. We also define the substrate repertoire of MPP2 by two-dimensional differential gel electrophoresis using fluorescent tags. Finally, we use complementary mass spectrometric techniques to unequivocally show that MIC2 is shed by intramembrane cleavage within its anchoring domain. Based on the properties of this cleavage site, we conclude that the sheddase, MPP1, is likely a multipass membrane protease of the Rhomboid family. Our data support a novel two-step proteolysis model that includes primary processing of the MIC2/M2AP complex followed by secondary cleavage to shed the complex from the parasite surface during the final steps of invasion.     

Structure and function of procollagen C-proteinase (mTolloid) domains determined by protease digestion, circular dichroism, binding to procollagen type I, and computer modeling

Procollagen C-proteinase-2 (pCP-2, mTld) is derived from the longest splicing variant of the gene encoding bone morphogenetic protein 1 (BMP-1). The variants have identical amino terminal signal peptides, prodomains and astacin-like protease domains. However, they differ in the length of their carboxy terminal part, which in pCP-2 has the composition CUB1, CUB2, EGF-like1, CUB3, EGF-like2, CUB4, CUB5, and C-tail. In the shorter form, pCP-1 (i.e., BMP-1), the sequence ends after the CUB3-domain. Using a combination of mutagenesis and structural approaches, we have investigated the structure and function of subfragments of pCP-2. The full-length latent recombinant enzyme and its N-terminally truncated form lacking the prodomain were tested for their enzymic activity. The intact protein showed only partial processing of procollagen type I, whereas the truncated form expressed enzymic activity indistinguishable from its native counterpart purified from chick embryo tendons. These results clearly demonstrated that the prodomain is required for the latency of the enzyme but not for its correct folding. Limited proteolysis of the recombinant protein with alpha-chymotrypsin produced four discrete fragments revealing the location of cleavage sites between the repetitive CUB/EGF domains. The results provide evidence that the CUB sequences form independently folded modules that are stabilized by two pairs of internal disulfide bridges. The modules are linked to each other by more flexible, hinge-like peptides. Solid-phase binding assays with isolated CUB domains and immobilized procollagen type I demonstrated that the first three but not the last two CUB domains specifically bound to the substrate. To define putative sites for CUB-CUB or CUB-substrate interactions, we generated molecular models for pCP-2 CUB domains. The models were obtained using as a template the structure of CUB domain in zona pellucida adhesion protein PSP-I/PSP-II from porcine sperm. The predicted conformations for homology models were, subsequently, confirmed by circular dichroism spectroscopy of polypeptide domains isolated following limited proteolysis with alpha-chymotrypsin.     

An internal signal sequence directs intramembrane proteolysis of a cellular immunoglobulin domain protein

Precursor proteolysis is a crucial mechanism for regulating protein structure and function. Signal peptidase (SP) is an enzyme with a well defined role in cleaving N-terminal signal sequences but no demonstrated function in the proteolysis of cellular precursor proteins. We provide evidence that SP mediates intraprotein cleavage of IgSF1, a large cellular Ig domain protein that is processed into two separate Ig domain proteins. In addition, our results suggest the involvement of signal peptide peptidase (SPP), an intramembrane protease, which acts on substrates that have been previously cleaved by SP. We show that IgSF1 is processed through sequential proteolysis by SP and SPP. Cleavage is directed by an internal signal sequence and generates two separate Ig domain proteins from a polytopic precursor. Our findings suggest that SP and SPP function are not restricted to N-terminal signal sequence cleavage but also contribute to the processing of cellular transmembrane proteins.     

Are presenilins intramembrane-cleaving proteases? Implications for the molecular mechanism of Alzheimer's disease.

The amyloid-beta protein (Abeta) is strongly implicated in the pathogenesis of Alzheimer's disease. The final step in the production of Abeta from the amyloid precursor protein (APP) is proteolysis by the unidentified gamma-secretases. This cleavage event is unusual in that it apparently occurs within the transmembrane region of the substrate. Studies with substrate-based inhibitors together with molecular modeling and mutagenesis of the gamma-secretase cleavage site of APP suggest that gamma-secretases are aspartyl proteases that catalyze a novel intramembranous proteolysis. This proteolysis requires the presenilins, proteins with eight transmembrane domains that are mutated in most cases of autosomal dominant familial Alzheimer's disease. Two conserved transmembrane aspartates in presenilins are essential for gamma-secretase activity, suggesting that presenilins themselves are gamma-secretases. Moreover, presenilins also mediate the apparently intramembranous cleavage of the Notch receptor, an event critical for Notch signaling and embryonic development. Thus, if presenilins are gamma-secretases, then they are also likely the proteases that cleave Notch within its transmembrane domain. Another protease, S2P, involved in the processing of the sterol regulatory element binding protein, is also a multipass integral membrane protein which cleaves within or very close to the transmembrane region of its substrate. Thus, presenilins and S2P appear to be members of a new type of polytopic protease with an intramembranous active site.     

F-spondin interaction with the apolipoprotein E receptor ApoEr2 affects processing of amyloid precursor protein

A recent study showed that F-spondin, a protein associated with the extracellular matrix, interacted with amyloid precursor protein (APP) and inhibited beta-secretase cleavage. F-spondin contains a thrombospondin domain that we hypothesized could interact with the family of receptors for apolipoprotein E (apoE). Through coimmunoprecipitation experiments, we demonstrated that F-spondin interacts with an apoE receptor (apoE receptor 2 [ApoEr2]) through the thrombospondin domain of F-spondin and the ligand binding domain of ApoEr2. Full-length F-spondin increased coimmunoprecipitation of ApoEr2 and APP in transfected cells and primary neurons and increased surface expression of APP and ApoEr2. Full-length F-spondin, but none of the individual F-spondin domains, increased cleavage of APP and ApoEr2, resulting in more secreted forms of APP and ApoEr2 and more C-terminal fragments (CTF) of these proteins. In addition, full-length F-spondin, but not the individual domains, decreased production of the beta-CTF of APP and Abeta in transfected cells and primary neurons. The reduction in APP beta-CTF was blocked by receptor-associated protein (RAP), an inhibitor of lipoprotein receptors, implicating ApoEr2 in the altered proteolysis of APP. ApoEr2 coprecipitated with APP alpha- and beta-CTF, and F-spondin reduced the levels of APP intracellular domain signaling, suggesting that there are also intracellular interactions between APP and ApoEr2, perhaps involving adaptor proteins. These studies suggest that the extracellular matrix molecule F-spondin can cluster APP and ApoEr2 together on the cell surface and affect the processing of each, resulting in decreased production of Abeta.     

Reduced proteolysis of rabbit growth hormone (GH) receptor substituted with mouse GH receptor cleavage site

GH binding protein (GHBP) is a circulating form of the GH receptor (GHR) extracellular domain, which derives by alternative splicing of the GHR gene (in mice and rats) and by metalloprotease-mediated GHR proteolysis with shedding of the extracellular domain as GHBP (in rabbits, humans, and other species). Inducible proteolysis of either mouse (m) or rabbit (rb) GHR is detected in cell culture in response to phorbol ester and other stimuli, yielding a cell-associated GHR remnant (comprised of the cytoplasmic and transmembrane domains and a small portion of the proximal extracellular domain) and down-regulating GH signaling. In this report, we map the mGHR cleavage site by adenoviral overexpression of a membrane-anchored mGHR mutant lacking its cytoplasmic domain and purification and N-terminal sequencing of the phorbol 12-myristate 13-acetate-induced remnant protein. The sequence obtained was LEACEEDI, which matches the mGHR extracellular domain stem region sequence L265EACEEDI272, indicating that mGHR cleavage occurs in the extracellular domain nine residues outside of the transmembrane domain, in the same region (but at different residues) as the rbGHR cleavage site we recently mapped. We studied the effects on receptor proteolysis and GHBP shedding of replacing rbGHR cleavage site residues with those corresponding to the mGHR cleavage site. We analyzed five separate rodentized rbGHR mutants incorporating mGHR amino acids either at or surrounding the cleavage site. Each mutant was normally processed, displayed at the cell surface, and responded to GH stimulation by undergoing tyrosine phosphorylation. Only the mutants replaced with mGHR cleavage site residues, rather than surrounding residues, exhibited deficient inducible proteolysis and GHBP shedding. These findings suggested that the GHR cleavage sites in the two species differ in their susceptibility to cleavage. This difference may underlie interspecies variation in utilization of proteolysis to generate GHBP.     

Human apolipoprotein E3 in aqueous solution. I. Evidence for two structural domains

The stability and structure of human apolipoprotein (apo) E3 in aqueous solution were investigated by guanidine HCl denaturation and limited proteolysis. The guanidine HCl denaturation curve, as monitored by circular dichroism spectroscopy, was biphasic; the two transition midpoints occurred at 0.7 and 2.5 M guanidine HCl, indicating that there are stable intermediate structures in the unfolding of apoE. Limited proteolysis of apoE with five enzymes demonstrated two proteolytically resistant regions, an amino-terminal domain (residues 20-165) and a carboxyl-terminal domain (residues 225-299). The region between them was highly susceptible to proteolytic cleavage. Because of their similarity to the proteolytically resistant regions, the amino-terminal (residues 1-191) and carboxyl-terminal (residues 216-299) thrombolytic fragments of apoE were used as models for the two domains. Guanidine HCl denaturation of the carboxyl- and amino-terminal fragments gave transition midpoints of 0.7 and 2.4 M guanidine HCl, respectively. The results establish that the two domains identified by limited proteolysis correspond to the two domains detected by protein denaturation experiments. Therefore, the thrombolytic fragments are useful models for the two domains. The free energies of denaturation calculated from the denaturation curves of intact apoE or the model domains were approximately 4 and 8-12 kcal/mol for the carboxyl- and amino-terminal domains, respectively. The value for the carboxyl-terminal domain is similar to those of previously characterized apolipoproteins, whereas the value for the amino-terminal domain is considerably higher and resembles those of soluble globular proteins. These studies suggest that, in aqueous solution, apoE is unlike other apolipoproteins in that it contains two independently folded structural domains of markedly different stabilities: an amino-terminal domain and a carboxyl-terminal domain, separated by residues that may act as a hinge region.     

Endocytosis-independent mechanisms of Delta ligand proteolysis

Delta proteins function as cell surface ligands for Notch receptors in a highly conserved signal transduction mechanism. Delta activates Notch by "trans-endocytosis", whereby endocytosis of Delta that is in complex with Notch on a neighboring cell induces activating cleavages in Notch. Alternatively, proteolysis of Delta renders the ligand inactive by dissociating the extracellular and cytosolic domains. How proteolysis and trans-endocytosis cooperate in Delta function is not well understood. We now show that Drosophila Delta proteolysis occurs independent of and prior to endocytosis in neuroblasts and ganglion mother cells in vivo and cells in culture. Delta cleavage occurs at two novel sites that we identify in the juxtamembrane (JM) and transmembrane (TM) domains. In addition to the previously identified Kuzbanian ADAM protease, which acts on the JM domain, proteolysis in the TM domain is facilitated by a thiol-sensitive aspartyl protease that is distinct from Presenilin. Furthermore, cleavage in the TM domain is upregulated in the presence of Notch. Overall, Drosophila Delta proteolysis differs from the conventional regulated intramembrane proteolysis (RIP) mechanism by two criteria: (1) TM-domain processing of Delta is not sensitive to Presenilin, and (2) TM and JM domain cleavages occur independently of each other. Altogether, these data support a model whereby proteolysis can modulate Delta ligand activity independently of endocytosis.     

Proteolytic processing of turnip yellow mosaic virus replication proteins and functional impact on infectivity

Turnip yellow mosaic virus (TYMV), a positive-strand RNA virus belonging to the alphavirus-like supergroup, encodes its nonstructural replication proteins as a 206K precursor with domains indicative of methyltransferase (MT), proteinase (PRO), NTPase/helicase (HEL), and polymerase (POL) activities. Subsequent processing of 206K generates a 66K protein encompassing the POL domain and uncharacterized 115K and 85K proteins. Here, we demonstrate that TYMV proteinase mediates an additional cleavage between the PRO and HEL domains of the polyprotein, generating the 115K protein and a 42K protein encompassing the HEL domain that can be detected in plant cells using a specific antiserum. Deletion and substitution mutagenesis experiments and sequence comparisons indicate that the scissile bond is located between residues Ser879 and Gln880. The 85K protein is generated by a host proteinase and is likely to result from nonspecific proteolytic degradation occurring during protein sample extraction or analysis. We also report that TYMV proteinase has the ability to process substrates in trans in vivo. Finally, we examined the processing of the 206K protein containing native, mutated, or shuffled cleavage sites and analyzed the effects of cleavage mutations on viral infectivity and RNA synthesis by performing reverse-genetics experiments. We present evidence that PRO/HEL cleavage is critical for productive virus infection and that the impaired infectivity of PRO/HEL cleavage mutants is due mainly to defective synthesis of positive-strand RNA.     

Post-translational proteolytic processing of the calcium-independent receptor of alpha-latrotoxin (CIRL), a natural chimera of the cell adhesion protein and the G protein-coupled receptor. Role of the G protein-coupled receptor proteolysis site (GPS) motif

The calcium-independent receptor of alpha-latrotoxin (CIRL), a neuronal cell surface receptor implicated in the regulation of exocytosis, is a natural chimera of the cell adhesion protein and the G protein-coupled receptor (GPCR). In contrast with canonic GPCRs, CIRL consists of two heterologous non-covalently bound subunits, p120 and p85, due to endogenous proteolytic processing of the receptor precursor in the endoplasmic reticulum. Extracellularly oriented p120 contains hydrophilic cell adhesion domains, whereas p85 resembles a generic GPCR. We determined that the site of the CIRL cleavage is located within a juxtamembrane Cys- and Trp-rich domain of the N-terminal extracellular region of CIRL. Mutations in this domain make CIRL resistant to the cleavage and impair its trafficking. Therefore, we have named it GPS for G protein-coupled receptor proteolysis site. The GPS motif is found in homologous adhesion GPCRs and thus defines a novel receptor family. We postulate that the proteolytic processing and two-subunit structure is a common characteristic feature in the family of GPS-containing adhesion GPCRs.     

Intramembrane cleavage of microneme proteins at the surface of the apicomplexan parasite Toxoplasma gondii

Apicomplexan parasites actively secrete proteins at their apical pole as part of the host cell invasion process. The adhesive micronemal proteins are involved in the recognition of host cell receptors. Redistribution of these receptor-ligand complexes toward the posterior pole of the parasites is powered by the actomyosin system of the parasite and is presumed to drive parasite gliding motility and host cell penetration. The microneme protein protease termed MPP1 is responsible for the removal of the C-terminal domain of TgMIC2 and for shedding of the protein during invasion. In this study, we used site-specific mutagenesis to determine the amino acids essential for this cleavage to occur. Mapping of the cleavage site on TgMIC6 established that this processing occurs within the membrane-spanning domain, at a site that is conserved throughout all apicomplexan microneme proteins. The fusion of the surface antigen SAG1 with these transmembrane domains excluded any significant role for the ectodomain in the cleavage site recognition and provided evidence that MPP1 is constitutively active at the surface of the parasites, ready to sustain invasion at any time.     

Functional domain structure of calcineurin A: mapping by limited proteolysis

Limited proteolysis of calcineurin, the Ca2+/calmodulin-stimulated protein phosphatase, with clostripain is sequential and defines four functional domains in calcineurin A (61 kDa). In the presence of calmodulin, an inhibitory domain located at the carboxyl terminus is rapidly degraded, yielding an Mr 57,000 fragment which retains the ability to bind calmodulin but whose p-nitrophenylphosphatase is fully active in the absence of Ca2+ and no longer stimulated by calmodulin. Subsequent cleavage(s), near the amino terminus, yield(s) an Mr 55,000 fragment which has lost more than 80% of the enzymatic activity. A third, slower, proteolytic cleavage in the carboxyl-terminal half of the protein converts the Mr 55,000 fragment to an Mr 42,000 polypeptide which contains the calcineurin B binding domain and an Mr 14,000 fragment which binds calmodulin in a Ca2+-dependent manner with high affinity. In the absence of calmodulin, clostripain rapidly severs both the calmodulin-binding and the inhibitory domains. The catalytic domain is preserved, and the activity of the proteolyzed 43-kDa enzyme is increased 10-fold in the absence of Ca2+ and 40-fold in its presence. The calcineurin B binding domain and calcineurin B appear unaffected by proteolysis both in the presence and in the absence of calmodulin. Thus, calcineurin A is organized into functionally distinct domains connected by proteolytically sensitive hinge regions. The catalytic, inhibitory, and calmodulin-binding domains are readily removed from the protease-resistant core, which contains the calcineurin B binding domain. Calmodulin stimulation of calcineurin is dependent on intact inhibitory and calmodulin-binding domains, but the degraded enzyme lacking these domains is still regulated by Ca2+.