Rabbit procathepsin E and cathepsin E. Nucleotide sequence of cDNA, hydrolytic specificity for biologically active peptides and gene expression during development

The Role of Substance P Within Traumatic Brain Injury and Implications for Therapy

This review examines the role of the neuropeptide substance P within the neuroinflammation that follows traumatic brain injury. It examines it in reference to its preferential receptor, the neurokinin-1 receptor, and explores the evidence for antagonism of this receptor in traumatic brain injury with therapeutic intent. Expression of substance P increases following traumatic brain injury. Subsequent binding to the neurokinin-1 receptor results in neurogenic inflammation, a cause of deleterious secondary effects that include an increased intracranial pressure and poor clinical outcome. In several animal models of TBI, neurokinin-1 receptor antagonism has been shown to reduce brain edema and the resultant rise in intracranial pressure. A brief overview of the history of substance P is presented, alongside an exploration into the chemistry of the neuropeptide with a relevance to its functions within the central nervous system. This review summarizes the scientific and clinical rationale for substance P antagonism as a promising therapy for human TBI.

Angiotensin-Related Peptides and Their Role in Pain Regulation

Angiotensin (Ang)-generating system has been confirmed to play an important role in the regulation of fluid balance and blood pressure and is essential for the maintenance of biological functions. Ang-related peptides and their receptors are found throughout the body and exhibit diverse physiological effects. Accordingly, elucidating novel physiological roles of Ang-generating system has attracted considerable research attention worldwide. Ang-generating system consists of the classical Ang-converting enzyme (ACE)/Ang II/AT1 or AT2 receptor axis and the ACE2/Ang (1-7)/MAS1 receptor axis, which negatively regulates AT1 receptor-mediated responses. These Ang system components are expressed in various tissues and organs, forming a local Ang-generating system. Recent findings indicate that changes in the expression of Ang system components under pathological conditions are involved in the development of neuropathy, inflammation, and their associated pain. Here, we summarized the effects of changes in the Ang system on pain transmission in various organs and tissues involved in pain development process.

The Role of Substance P in Secondary Pathophysiology after Traumatic Brain Injury

It has recently been shown that substance P (SP) plays a major role in the secondary injury process following traumatic brain injury (TBI), particularly with respect to neuroinflammation, increased blood–brain barrier (BBB) permeability, and edema formation. Edema formation is associated with the development of increased intracranial pressure (ICP) that has been widely associated with increased mortality and morbidity after neurotrauma. However, a pharmacological intervention to specifically reduce ICP is yet to be developed, with current interventions limited to osmotic therapy rather than addressing the cause of increased ICP. Given that previous publications have shown that SP, NK1 receptor antagonists reduce edema after TBI, more recent studies have examined whether these compounds might also reduce ICP and improve brain oxygenation after TBI. We discuss the results of these studies, which demonstrate that NK1 antagonists reduce posttraumatic ICP to near normal levels within 4 h of drug administration, as well as restoring brain oxygenation to near normal levels in the same time frame. The improvements in these parameters occurred in association with an improvement in BBB integrity to serum proteins, suggesting that SP-mediated increases in vascular permeability significantly contribute to the development of increased ICP after acute brain injury. NK1 antagonists may therefore provide a novel, mechanistically targeted approach to the management of increased ICP.

The role of substance p in ischaemic brain injury

Stroke is a leading cause of death, disability and dementia worldwide. Despite extensive pre-clinical investigation, few therapeutic treatment options are available to patients, meaning that death, severe disability and the requirement for long-term rehabilitation are common outcomes. Cell loss and tissue injury following stroke occurs through a number of diverse secondary injury pathways, whose delayed nature provides an opportunity for pharmacological intervention. Amongst these secondary injury factors, increased blood-brain barrier permeability and cerebral oedema are well-documented complications of cerebral ischaemia, whose severity has been shown to be associated with final outcome. Whilst the mechanisms of increased blood-brain barrier permeability and cerebral oedema are largely unknown, recent evidence suggests that the neuropeptide substance P (SP) plays a central role. The aim of this review is to examine the role of SP in ischaemic stroke and report on the potential utility of NK1 tachykinin receptor antagonists as therapeutic agents.

Emerging roles of cathepsin E in host defense mechanisms

Cathepsin E is an intracellular aspartic proteinase of the pepsin superfamily, which is predominantly expressed in certain cell types, including the immune system cells and rapidly regenerating gastric mucosal and epidermal keratinocytes. The intracellular localization of this protein varies with different cell types. The endosomal localization is primarily found in antigen-presenting cells and gastric cells. The membrane association is observed with certain cell types such as erythrocytes, osteoclasts, gastric parietal cells and renal proximal tubule cells. This enzyme is also found in the endoplasmic reticulum, Golgi complex and cytosolic compartments in various cell types. In addition to its intracellular localization, cathepsin E occurs in the culture medium of activated phagocytes and cancer cells as the catalytically active enzyme. Its strategic expression and localization thus suggests the association of this enzyme with specific biological functions of the individual cell types. Recent genetic and pharmacological studies have particularly suggested that cathepsin E plays an important role in host defense against cancer cells and invading microorganisms. This review focuses emerging roles of cathepsin E in immune system cells and skin keratinocytes, and in host defense against cancer cells. This article is part of a Special Issue entitled: Proteolysis 50 years after the discovery of lysosome.

The role of cathepsin E in terminal differentiation of keratinocytes

Cathepsin E (CatE) is predominantly expressed in the rapidly regenerating gastric mucosal cells and epidermal keratinocytes, in addition to the immune system cells. However, the role of CatE in these cells remains unclear. Here we report a crucial role of CatE in keratinocyte terminal differentiation. CatE deficiency in mice induces abnormal keratinocyte differentiation in the epidermis and hair follicle, characterized by the significant expansion of corium and the reduction of subcutaneous tissue and hair follicle. In a model of skin papillomas formed in three different genotypes of syngeneic mice, CatE deficiency results in significantly reduced expression and altered localization of the keratinocyte differentiation induced proteins, keratin 1 and loricrin. Involvement of CatE in the regulation of the expression of epidermal differentiation specific proteins was corroborated by in vitro studies with primary cultures of keratinocytes from the three different genotypes of mice. In wild-type keratinocytes after differentiation inducing stimuli, the CatE expression profile was compatible to those of the terminal differentiation marker genes tested. Overexpression of CatE in mice enhances the keratinocyte terminal differentiation process, whereas CatE deficiency results in delayed differentiation accompanying the reduced expression or the ectopic localization of the differentiation markers. Our findings suggest that in keratinocytes CatE is functionally linked to the expression of terminal differentiation markers, thereby regulating epidermis formation and homeostasis.

Selective detection of Cathepsin E proteolytic activity

BACKGROUND

Aspartic proteases Cathepsin (Cath) E and D are two different proteases, but they share many common characteristics, including molecular weight, catalytic mechanism, substrate preferences, proteolytic conditions and inhibition susceptibility. To define the biological roles of these proteases, it is necessary to elucidate their substrate specificity. In the present study, we report a new peptide-substrate that is only sensitive to Cath E but not Cath D.

METHODS

Substrate e, Mca-Ala-Gly-Phe-Ser-Leu-Pro-Ala-Lys(Dnp)-DArg-CONH₂, designed in such a way that due to the close proximity of a Mca-donor and a Dnp-acceptor, near complete intramolecular quenching effect was achieved in its intact state. After the proteolytic cleavage of the hydrophobic motif of peptide substrate, both Mca and Dnp would be further apart, resulting in bright fluorescence.

RESULTS

Substrate e showed a 265 fold difference in the net fluorescence signals between Cath E and D. This Cath E selectivity was established by having -Leu**Pro- residues at the scissile peptide bond. The confined cleavage site of substrate e was confirmed by LC-MS. The catalytic efficiency (K(cat)/K(M)) of Cath E for substrate e was 16.7 μM⁻¹S⁻¹. No measurable catalytic efficiency was observed using Cath D and no detectable fluorescent changes when incubated with Cath S and Cath B.

CONCLUSIONS

This study demonstrated the promise of using the developed fluorogenic substrate e as a selective probe for Cath E proteolytic activity measurement.

GENERAL SIGNIFICANCE

This study forms the foundation of Cath E specific inhibitor development in further studies.

Association of cathepsin E deficiency with the increased territorial aggressive response of mice

Cathepsin E is an endolysosomal aspartic proteinase predominantly expressed in cells of the immune system, but physiological functions of this protein in the brain remains unclear. In this study, we investigate the behavioral effect of disrupting the gene encoding cathepsin E in mice. We found that the cathepsin E-deficient (CatE-/-) mice were behaviorally normal when housed communally, but they became more aggressive compared with the wild-type littermates when housed individually in a single cage. The increased aggressive response of CatE-/- mice was reduced to the level comparable to that seen for CatE+/+ mice by pretreatment with an NK-1-specific antagonist. Consistent with this, the neurotransmitter substance P (SP) level in affective brain areas including amygdala, hypothalamus, and periaqueductal gray was significantly increased in CatE-/- mice compared with CatE+/+ mice, indicating that the increased aggressive behavior of CatE-/- mice by isolation housing followed by territorial challenge is mainly because of the enhanced SP/NK-1 receptor signaling system. Double immunofluorescence microscopy also revealed the co-localization of SP with synaptophysin but not with microtubule-associated protein-2. Our data thus indicate that cathepsin E is associated with the SP/NK-1 receptor signaling system and thereby regulates the aggressive response of the animals to stressors such as territorial challenge.

Cathepsin E: a mini review

Cathepsin E is a major intracellular aspartic protease which is predominantly present in the cells of immune system and is frequently implicated in antigen processing via the MHC class II pathway. In the present review some of the known features of cathepsin E such as tissue distribution, subcellular localization, enzymatic properties, intracellular trafficking, gene regulation and associated physiological conditions are highlighted.

Substance P in traumatic brain injury

Recent evidence has suggested that neuropeptides, and in particular substance P (SP), may play a critical role in the development of morphological injury and functional deficits following acute insults to the brain. Few studies, however, have examined the role of SP, and more generally, neurogenic inflammation, in the pathophysiology of traumatic brain injury and stroke. Those studies that have been reported suggest that SP is released following injury to the CNS and facilitates the increased permeability of the blood brain barrier, the development of vasogenic edema and the subsequent cell death and functional deficits that are associated with these events. Inhibition of the SP activity, either through inhibition of the neuropeptide release or the use of SP receptor antagonists, have consistently resulted in profound decreases in edema formation and marked improvements in functional outcome. The current review summarizes the role of SP in acute brain injury, focussing on its properties as a neurotransmitter and the potential for SP to adversely affect outcome.

The Role of the Cathepsin E Propeptide in Correct Folding, Maturation and Sorting to the Endosome

Cathepsin E (CE) is an endosomal aspartic proteinase of the A1 family that is highly homologous to the lysosomal aspartic proteinase cathepsin D (CD). Newly synthesized CE undergoes several proteolytic processing events to yield mature CE, from which the N-terminal propeptide usually comprising 39 amino acids is removed. To define the role of the propeptide of CE in its biosynthesis and processing, we constructed two fusion proteins using chimeric DNAs encoding the CE propeptide fused to the mature CD tagged with HA at the COOH terminus (termed ED-HA) and encoding the CD propeptide fused to the mature CE (termed DE). Pulse-chase analysis revealed that wild-type CE expressed in human embryonic kidney cells is autoproteolytically processed into mature CE within a 12-h chase, whereas the chimeric DE failed to be converted into mature CE even after a 24-h chase. The DE chimera was nevertheless capable of acid-dependent autoactivation in vitro to yield a catalytically active form, although its specificity constants (kcat/Km) were considerably high but less (35%) than those of the wild-type CE. By contrast, the chimeric ED-HA expressed in HeLa cells underwent neither processing into a catalytically active enzyme nor acid-dependent autoactivation in vitro. The ED-HA protein was less stable than wt-CD-HA, as determined on pulse-chase analysis and on trypsin digestion. These data indicate that the propeptide of CE is essential for the correct folding, maturation, and targeting of this protein to its final destination.

Crystal structure of cockroach allergen Bla g 2, an unusual zinc binding aspartic protease with a novel mode of self-inhibition

The crystal structure of Bla g 2 was solved in order to investigate the structural basis for the allergenic properties of this unusual protein. This is the first structure of an aspartic protease in which conserved glycine residues, in two canonical DTG triads, are substituted by different amino acid residues. Another unprecedented feature revealed by the structure is the single phenylalanine residue insertion on the tip of the flap, with the side-chain occupying the S1 binding pocket. This and other important amino acid substitutions in the active site region of Bla g 2 modify the interactions in the vicinity of the catalytic aspartate residues, increasing the distance between them to approximately 4A and establishing unique direct contacts between the flap and the catalytic residues. We attribute the absence of substantial catalytic activity in Bla g 2 to these unusual features of the active site. Five disulfide bridges and a Zn-binding site confer stability to the protein, which may contribute to sensitization at lower levels of exposure than other allergens.

Substance P immunoreactive cell reductions in cerebral cortex of Niemann-Pick disease type C mouse

Niemann-Pick disease type C (NPC) is characterized by progressive neurodegeneration and arises from mutations in the NPC1 gene. Cholesterol has received most attention in the pathogenesis of NPC, but normalizing lipid levels in humans or mouse does not prevent neurodegeneration. In NPC mouse, neuronal degeneration in the cerebellum is the most commonly detected change, and thus previous studies have tended to focus on the cerebellum, especially Purkinje cells. Although numerous peptides have been found in the mammalian central nervous system, little data on neurotransmitters in NPC are available, and information on neurotransmitter system abnormalities could explain the complex and characteristic deficits of NPC. Thus, we performed an immunohistochemical study on NPC mouse cortices to compare cell numbers exhibiting vasoactive intestinal polypeptide (VIP), neuropeptide Y (NPY), and substance P (SP) immunoreactivity. In terms of VIP and NPY-immunoreactive (ir) cell numbers in the cerebral cortex, SP-ir cells were significantly reduced by about 90% in NPC (-/-) versus NPC (+/+) mouse, and were also mildly decreased in frontal and parietal NPC (+/-) versus NPC (+/+) mouse cortex. This study demonstrates for the first time, reduced number of SP-ir cells in the NPC mouse cortex.

A new selective substrate for cathepsin E based on the cleavage site sequence of α2-macroglobulin

Cathepsin E is an intracellular aspartic proteinase of the pepsin family predominantly expressed in cells of the immune system and believed to contribute to homeostasis by participating in host defense mechanisms. Studies on its enzymatic properties, however, have been limited by a lack of sensitive and selective substrates. For a better understanding of the importance of this enzymein vivo, we designed and synthesized a highly sensitive peptide substrate for cathepsin E based on the sequence of the specific cleavage site of α2-macroglobulin. The substrate constructed, MOCAc-Gly-Ser-Pro-Ala-Phe-Leu-Ala-Lys(Dnp)-D-Arg-NH2[where MOCAc is (7-methoxycoumarin-4-yl)acetyl and Dnp is dinitrophenyl], derived from the cleavage site sequence of human α2-macroglobulin, was the most sensitive and selective for cathepsin E, withkcat/Kmvalues of 8–11 μM-1S-1, whereas it was resistant to hydrolysis by the analogous aspartic proteinases cathepsin D and pepsin, as well as the lysosomal cysteine proteinases cathepsins B, L, and H. The assay allows the detection of a few fmol of cathepsin E, even in the presence of plasma and cell lysate, and gives accurate results over a wide enzyme concentration range. This substrate might represent a useful tool for monitoring and accurately quantifying cathepsin E, even in crude enzyme preparations.

Molecular cloning of preprocathepsin E cDNA from the stomach of bullfrog Rana catesbeiana

A cDNA library was constructed from a poly(A)(+) RNA fraction of the gastric mucosa of bullfrog Rana catesbeiana. We cloned a cDNA encoding preprocathepsin E (Pre-Pro-CE) from the library. The present study is the first demonstration of the Pre-Pro-CE cDNA of lower vertebrate such as amphibian. Amino acid sequence deduced from the cDNA was compared with partial amino acid sequence determined by Edman degradation, suggesting that the cDNA comprises an open reading frame encoding a signal peptide (16 amino acids), a pro-sequence (33 amino acids) and a mature protein region (348 amino acids). Two consensus tri-peptide sequences (FDT and VDT) as active site and positions of seven cysteine residues were conserved in this amphibian CE. Although the bullfrog CE was deduced to contain one potential N-linked glycosylation site, its position (Asn(139)-Leu(140)-Thr(141)) was different from that of mammalian CEs. Molecular phylogenetic analysis showed that the bullfrog Pro-CE belongs to the typical Pro-CE group among various aspartic proteinases.

Molecular cloning of neonate/infant-specific pepsinogens from rat stomach mucosa and their expressional change during development

To clarify the nature of rat neonate/infant-specific pepsinogens, we carried out their purification and molecular cloning. Prochymosin was found to be the major neonatal pepsinogen. The general proteolytic activity of its active form, chymosin, was, however, lower than those of pepsins A and C which are predominant in adult animals. Molecular cloning of rat prochymosin cDNA was achieved along with cDNA for another neonate-specific pepsinogen, pepsinogen F, although determination of pepsinogen F in neonatal gastric mucosa was unsuccessful, presumably due to its lack of proteolytic activity or different proteolytic specificity. Northern blot analysis confirmed that genes for prochymosin and pepsinogen F are expressed only at neonatal/infant stages and the switching of gene expression to that of pepsinogen C occurred at late infant stages. A phylogenetic tree based on nucleotide sequences showed clearly that pepsinogens fall into four major groups, namely prochymosin and pepsinogen F of the neonate/infant and pepsinogens A and C of adult animals. Although, to date, prochymosin and pepsinogen F were believed to be expressed in only a limited number of mammals, the present results suggest that they might be expressed at the neonatal/infant stage in a variety of mammals.

Role of N-glycosylation in cathepsin E. A comparative study of cathepsin E with distinct N-linked oligosaccharides and its nonglycosylated mutant

Cathepsin E (CE), a nonlysosomal, intracellular aspartic proteinase, exists in several molecular forms that are N-glycosylated with high-mannose and/or complex-type oligosaccharides. To investigate the role of N-glycosylation on the catalytic properties and molecular stability of CE, both natural and recombinant enzymes with distinct oligosaccharides were purified from different sources. An N-glycosylation minus mutant, that was constructed by site-directed mutagenesis (by changing asparagine residues to glutamine and aspartic acid residues at positions 73 and 305 in potential N-glycosylation sites of rat CE) and expressed in normal rat kidney cells, was also purified to homogeneity from the cell extracts. The kinetic parameters of the nonglycosylated mutant were found to be essentially equivalent to those of natural enzymes N-glycosylated with either high-mannose or complex-type oligosaccharides. In contrast, the nonglycosylated mutant showed lower pH and thermal stabilities than the glycosylated enzymes. The nonglycosylated mutant exhibited particular sensitivity to conversion to a monomeric form by 2-mercaptoethanol, as compared with those of the glycosylated enzymes. Further, the high-mannose-type enzymes were more sensitive to this agent than the complex-type proteins. A striking difference was found between the high-mannose and complex-type enzymes in terms of activation by ATP at a weakly acidic pH. At pH 5.5, the complex-type enzymes were stabilized by ATP to be restored to the virtual activity, whereas the high-mannose-type enzymes as well as the nonglycosylated mutant were not affected by ATP. These results suggest that N-glycosylation in CE is important for the maintenance of its proper folding upon changes in temperature, pH and redox state, and that the complex-type oligosaccharides contribute to the completion of the tertiary structure to maintain its active conformation in the weakly acidic pH environments.

A distinct member of the aspartic proteinase gene family from the human malaria parasite Plasmodium falciparum

A gene (hap) transcribed during the intra-erythrocytic life cycle stages of the human malaria parasite Plasmodium falciparum was cloned and sequenced. It was found to encode a protein belonging to the aspartic proteinase family but which carried replacements of catalytically crucial residues in the hallmark sequences contributing to the active site of this type of proteinase. Consideration is given as to whether this protein is the first known parasite equivalent of the pregnancy-associated glycoproteins that have been documented in ungulate mammals. Alternatively, it may be operative as a new type of proteinase with a distinct catalytic mechanism. In this event, since no counterpart is known to exist in humans, it affords an attractive potential target against which to develop new anti-malarial drugs.

Distribution of cathepsin E in the larval and adult organs of the bullfrog with special reference to the mature form in the larval fore-gut

The distibution of cathepsin E in several organs of the bullfrog, Rana catesbeiana, was analyzed at pre- and post-metamorphic stages by the acid proteinase assay, by visualization of enzyme activity on polyacrlamide fore-gut gels after electrophoresis and by immunoblotting with anti-cathepsin E serum. Cathepsin E was mainly distributed in the foregut at the larval stage and in the stomach, duodenum, large intestine and gall bladder at the post-metamorphic stage. In the larval fore-gut, a higher amount of the mature form of cathepsin E was observed in addition to the proform, but in other organs, including the stomach at the post-metamorphic stage, the mature form was barely detected. Developmental changes in the amount of cathepsin E were found in the digestive tract and the gall bladder by quantitative immunoblotting analysis. Finally, the larval fore-gut was stained immunohistochemically with anti-cathepsin E serum and the surface epithelium gave a strong immunoreactive signal.

Mouse procathepsin E gene: molecular organisation and chromosomal localisation

A 15.6 kb genomic clone encompassing the mouse procathepsin E gene was isolated and mapped. Sequencing revealed that the gene consists of nine exons followed by a polyadenylation signal at the 3'-end. The 5'-flanking region appears to be a TATA-less promoter but contains a nucleotide sequence that matches perfectly with the consensus motif of an initiator element [S.T. Smale, Biochim. Biophys. Acta 1351 (1997) 73-88.] to direct accurate initiation of transcription by RNA polymerase. This overlaps the site that was determined for the start of transcription. The absence of features considered typical of TATA-box regulated or housekeeping types of genes is consistent with the low levels of procathepsin E gene expression that are normally observed and might imply a unique sensitivity to or requirement for tissue-specific transcription factors that would account for the sporadic distribution of this aspartic proteinase in cells and tissues. The single copy of the procathepsin E gene was located on chromosome 1, near to that of mouse prorenin, a closely related aspartic proteinase involved in blood pressure regulation.

Cathepsin E immunoreactivity in human ocular tissues: influence of aging and pathological states

We studied the antigenic expression of the aspartic proteinase cathepsin E in normal and pathologic human ocular tissues obtained from donors of different age. In the retina the enzyme was immunolocalized in neurons of outer and inner plexiform layers and in few ganglionic neurons. Muller cells were also sometimes immunoreactive for cathepsin E. An increase of neuronal enzyme immunoreactivity with age was evident. Immunocompetent blood cells invading the vitreous body were strongly immunostained for the enzyme. The enzyme is possibly involved in the retinal protein metabolism and might play immunological roles in certain pathologic events.

Substrate specificity of cathepsins D and E determined by N-terminal and C-terminal sequencing of peptide pools

Degradation of protein antigens by cellular proteases is a crucial step in the initiation of a T-cell-mediated immune response. But still little is known about the enzymes responsible for the processing of antigens, including their specificity. In this paper, we show that the combination of automated N-terminal sequencing with a newly developed method for C-terminal sequencing of peptide pools generated by the aspartic proteases cathepsins D and E is a fast and easy method to obtain detailed information of the substrate specificity of these endopeptidases. Using a 15-residue synthetic peptide library and a native protein as substrates, we confirm and extend the knowledge about the cleavage motif of cathepsin E where positions P1 and P1' of the substrate must be occupied exclusively by hydrophobic amino acids with aromatic or aliphatic side chains. However, Val and Ile residues are not allowed at position P1. Position P2' accepts a broad range of amino acids, including charged and polar ones. Additional requirements concerning the substrate positions P3' and P4' were also defined by pool sequencing. Furthermore, pool sequencing analysis of melittin digests with the aspartic proteases cathepsin D and E provided evidence that both enzymes share the same cleavage motif, identical to the one derived from the peptide library and the native protein. Therefore, pool sequencing analysis is a valuable and fast tool to determine the substrate specificity of any endopeptidase.

Evolutionary conserved cathepsin E substrate specificity as defined by N-terminal and C-terminal sequencing of peptide pools

The substrate specificity of the non-lysosomal aspartic protease cathepsin E from three different species has been studied using the method of automated N-terminal sequencing and a newly developed method for C-terminal sequencing of peptides and peptide pools. The combination of N-terminal and C-terminal sequencing of peptide pools is a fast and easy method to identify and compare the substrate specificity of endopeptidases. Our analysis shows a conserved hydrolytic specificity between human, mouse and bovine cathepsin E, with only small differences in fine specificity. Furthermore, our results confirm and extend the rules governing the interactions of the substrate with the amino acid (aa) side chains of the various pockets within the enzyme's active cleft. We found that the positions flanking the scissile peptide bond P1-P1' are occupied exclusively by hydrophobic aa with both aliphatic or aromatic side chains; Val and Ile, however, are not allowed in the S1 binding site. The S2 and S2' subsites accept hydrophilic aa. Additional requirements concerning the S3' to S5' subsites were also revealed. Finally, the sequences of single peptides generated by cathepsin E from the three different species can be easily aligned to the determined cleavage motif, showing the reliability of our pool sequencing methods.

Cloning, expression and characterisation of murine procathepsin E

The cDNA encoding murine procathepsin E was isolated and sequenced and recombinant enzyme was produced in Escherichia coli. The activity of the purified recombinant mouse cathepsin E was characterised quantitatively using two synthetic peptide substrates and naturally occurring inhibitors. The majority of the recombinant enzyme was present as a homodimer (Mr approximately 80) in which the two monomers were linked by an intermolecular disulfide bond. By analogy to previous studies with human cathepsin E, this is most likely a consequence of the presence of a unique cysteine residue near the N-terminus of the mature proteinase. The availability of (i) recombinant murine enzyme in reasonable quantities and (ii) a full-length cDNA now enables structural investigations and attempts to generate 'knock-out' mice deficient in this important aspartic proteinase to be undertaken.

Computer-aided molecular modeling of cathepsin E, a possible endothelin-converting enzyme

A three-dimensional model of human cathepsin E, a possible endothelin-converting enzyme, is constructed using computer-aided molecular modeling techniques. The structure of porcine pepsin, another aspartic protease, was used as a template. The final structure, after all gaps and deletions were made, was optimized using the AMBER-4 package. A dipeptide (Trp-Val) representing the substrate was docked in the putative active site and the whole structure was optimized after several runs of minimization and dynamics calculations. The result of this modeling study showed that the structure of cathepsin E is similar to that of porcine pepsin and has three disulfide bonds that are conserved in both enzymes. There are two Asp-Thr-Gly sequences at the active site of enzyme. The active site cavity is large enough to accommodate its substrate.

Processing of the precursors to neurotensin and other bioactive peptides by cathepsin E

Cathepsin E (EC 3.4.23.34), an intracellular aspartic proteinase, was purified from monkey intestine by simple procedures that included affinity chromatography and fast protein liquid chromatography. Cathepsin E was very active at weakly acidic pH in the processing of chemically synthesized precursors such as the precursor to neurotensin/neuromedin, proopiomelanocortin, the precursor to xenopsin, and angiotensinogen. The processing sites were adjacent to a dibasic motif in the former two precursors and at hydrophobic recognition sites in the latter two. The common structural features that specified the processing sites were found in the carboxyl-terminal sequences of the active peptide moieties of these precursors; namely, the sequence Pro-Xaa-X'aa-hydrophobic amino acid was found at positions P4 through P1. Pro at the P4 position is thought to be important for directing the processing sites of the various precursor molecules to the active site of cathepsin E. Although the positions of Xaa and X'aa were occupied by various amino acids, including hydrophobic and aromatic amino acids, some of these had a negative effect, as typically observed when Glu/Arg and Pro were present at the P3 and P2 positions, respectively. Cathepsin D was much less active or was almost inactive in the processing of the precursors to neurotensin and related peptides as a result of the inability of the Pro-directed conformation of the precursor molecules to gain access to the active site of cathepsin D. Thus, the consensus sequence of precursors, Pro-Xaa-X'aa-hydrophobic amino acid, might not only generate the best conformation for cleavage by cathepsin E but might be responsible for the difference in specificities between cathepsins E and D.

Monomeric human cathepsin E

Cathepsin E is a homodimer, consisting of two monomers linked by an inter-molecular disulphide bond. The cysteine residue involved is located near to the N-terminus of the mature proteinase. By mutating this residue to alanine, a monomeric form of human cathepsin E was engineered and purified. The activity of the resultant enzyme was not altered significantly (in terms of its ability to hydrolyse two chromogenic peptide substrates; and its susceptibility to inhibition by pepstatin). However, the stability of the mutant enzyme to alkaline pH and to temperature was markedly reduced.

An immunohistochemical study of cathepsin E in Alzheimer-type dementia brains

We studied the immunohistochemical localization of cathepsin E (cath E) in the brains of patients with Alzheimer disease (AD) and control brains. In the normal brain cathepsin E immunoreactivity was detectable in a small number (below 5%) of neocortical and hippocampal neurons. In AD brains cathepsin E antigen was revealed in most large cortical and hippocampal pyramids and in neurons of the Nuc. basalis of Meynert. Cathepsin E was also present in cerebral microvessels, microglia, and in senile plaques. The enzyme might play roles in the process of neurodegeneration taking place in AD.