Beate Wilhelm

Transglutaminases : purification and activity assays

Transglutaminases (TGases) are a widely distributed family of proteins found in many tissues and body fluids of vertebrates. To date the following types have been distinguished: secretory, tissue, epidermal, keratinocyte, and hemocyte TGase as well as factor XIIIa and erythrocyte hand 4.2 TGases are difficult to isolate, as they tend to form irreversible aggregates under native conditions. In this review, the isolation procedures for the different types of TGases are summarized. The most common chromatographic separation methods used for TGase purification are size-exclusion and ion-exchange chromatography. Additionally, other chromatographic methods (hydrophobic-interaction, affinity, adsorption chromatography) and electrophoretic techniques [preparative isoelectric focusing, sodium dodecyl sulphate polyacrylamide gel electrophoresis and zone electrophoresis] are described. Based on the enzymatic function of TGases (cross-linking of a primary amine and peptide bound glutamine), several established activity assays are described.

Cytoplasmic Carbonic Anhydrase II of Rat Coagulating Gland Is Secreted via the Apocrine Export Mode

Two different pathways for protein secretion are described for epithelial cells of rat coagulating gland and dorsal prostate: the classical merocrine and the alternative apocrine release mode. Apocrine-secreted proteins are synthesized on cytoplasmic polyribosomes and are subsequently exported in protrusions on the apical cell surface (aposomes). In this article we report the identification and purification to homogeneity of a 29-kD protein from the secretion of rat coagulating gland. N-terminal amino acid sequence analyses revealed 100% identity to rat brain carbonic anhydrase II (CAH II). In addition, the 29-kD protein showed CAH enzyme activity. On Western blot analysis, a polyclonal anti-CAH II antibody raised in rabbit reacted specifically with the rat and human but not bovine CAH II isoforms. Immunohistochemical studies on rat coagulating gland showed strong labeling for CAH II protein in aposomes. Immunoelectron microscopy confined CAH II protein to the cytoplasm and aposomes, whereas no staining was visible in the compartments of the classical merocrine route, the endoplasmic reticulum and Golgi apparatus. The resident cytoplasmic protein lactate dehydrogenase, however, was not found in the secretion. Taken together, the morphological and biochemical data clearly indicate that cytoplasmic CAH II from rat coagulating gland is specifically selected and then secreted via the apocrine pathway.

The Multi-PDZ domain protein MUPP1 as a lipid raft-associated scaffolding protein controlling the acrosome reaction in mammalian spermatozoa

The success of acrosomal exocytosis, a complex process with a variety of interrelated steps, relies on the coordinated interaction of participating signaling molecules. Since scaffolding proteins are known to spatially organize sequential signaling pathways, we examined whether the Multi‐PDZ domain protein MUPP1, recently identified in mammalian spermatozoa, is functionally active in controlling acrosomal secretion in mammalian sperm cells. To address this question, permeabilized mouse sperm were loaded with inhibitory antibodies against MUPP1 as well as with a photosensitive Ca2+ chelator which allows a controlled release of acrosomal Ca2+. The results revealed that MUPP1 controls initial tethering and docking of the acrosomal vesicle, whereas syntaxin 2, a t‐SNARE protein also expressed in the acrosomal cap of mammalian spermatozoa, appears to take part in the final process of acrosomal fusion. Interestingly, using immunogold electron microscopy, it was found that MUPP1 is detectable in the region of the periacrosomal membrane. Furthermore, in isolated detergent‐insoluble glycolipid‐enriched membrane domains from epididymal spermatozoa, MUPP1 was found to show a striking association with the Triton X‐100 insoluble membrane fraction, which did not change significantly upon sperm capacitation or partial chemical extraction of cholesterol. This evidence points to a role of MUPP1 as a membrane raft‐associated molecular organizer, and suggests that mammalian spermatozoa may use a scaffolding protein and distinct membrane subdomains to spatially organize components involved in the process of acrosomal exocytosis. J. Cell. Physiol. 214: 757–768, 2008.

Simultaneous apocrine and merocrine secretion in the rat coagulating gland

Abstract The coagulating gland of the rat synthesizes two prevalent secretory proteins (transglutaminase and 115 K) that are discharched in a different manner, one being secreted in an apocrine fashion (transglutaminase) and the other one in a merocrine way (115 K). Differences in the intra- cellular pathway and the release of either protein were studied using immunofluorescence on semithin sections, immunoelectron microscopy of preembedding-processed chopper sections and postembedding-processed ultrathin sections of rat coagulating gland. Immunohistochemical staining using an anti-transglutaminase antibody resulted in dense labeling of the cytoplasm of secretory cells and their apical blebs, whereas the cisternae of the rough endoplasmic reticulum and the Golgi apparatus were completely unlabeled. When, on the contrary, the anti-115 K antiserum was used, dense labeling of the cisternae of the rough endoplasmic reticulum, the Golgi apparatus, and the secretory granules was seen. Intraluminal secretion was also labeled, but the secretory blebs remained unlabeled. Our findings show that, in the coagulating gland of the male rat, the two secretory proteins studied are processed in parallel, but at completely different intracellular pathways. They are released via different extrusion mechanisms. Transglutaminase is synthesized outside the endoplasmic reticulum, reaches the apical cell pole by free flow in the cytoplasm, and is released via apocrine blebs, the membranes of which appear to be derived from the apical plasma membrane. The protein 115 K, on the other hand, follows the classic route, being synthesized within the cisternae of rough endoplasmic reticulum, subsequently glycosylated in the Golgi apparatus, and released in a merocrine fashion. The mutual exclusion of the two secretory pathways and the regulation of the alternative release mechanism are still unresolved issues.

Expression of the G-protein α-subunit gustducin in mammalian spermatozoa

Although chemotaxis has been proposed to guide sperm to egg throughout the animal kingdom, sperm attractants released from mammalian eggs have not been identified. Since the G protein subunit α-gustducin is accepted as a marker of chemosensitive cells, attempts were made to explore whether α-gustducin is also expressed in spermatozoa of mammals. Immunohistochemical approaches using an anti-α-gustducin-specific antibody revealed the most intense immunoreactivity in differentiating spermatids. Further evidence for the α-gustducin expression was obtained analyzing testicular and sperm-derived tissue preparations in western blot analyses. To elucidate whether α-gustducin is retained in mature spermatozoa, epididymal mouse and rat sperm were subjected to immunocytochemistry as well as immunogold electron microscopy. A specific staining was obtained within the circumference of the midpiece-localized mitochondria, on the axoneme and the outer dense fibers surrounding the microtubules of this region, whereas no labeling was detectable in the end piece regions. The analysis of ejaculated bovine and human sperm revealed a comparable segmental distribution pattern for α-gustducin. Although a possible function for α-gustducin has yet to be determined, the axonemal-associated localization within the midpiece and principal piece of different mammalian spermatozoa raises the possibility that this G protein α-subunit may process intracellular signals controlling sperm motility.

Identification and characterization of neutral endopeptidase (EC 3. 4. 24. 11) from human prostasomes–localization in prostatic tissue and cell lines

An antibody directed against a 100 kDa protein was immunoselected from a polyvalent antiserum against human prostasomes. The antibody as well as biochemical characteristics of the respective antigen were used to study the structural relationship of the latter with prostate membrane specific antigen (PMSA), another 100 kDa membrane protein of the prostate.

Sulfhydryl oxidase (SOx) from mouse epidermis: molecular cloning, nucleotide sequence, and expression of recombinant protein in the cultured cells.

Skin sulfhydryl oxidase (SOx) is an enzyme that catalyzes disulfide (S-S) cross-linking through the oxidation of sulfhydryl compounds in the skin. In this study, using the enzyme purified from rat seminal vesicle, we obtained peptide sequences for SOx by mass spectrometry. We then searched for SOx nucleotides corresponding highly to the rat peptide sequences by assembling murine-expressed sequence tags (ESTs) from the GeneBank database. The assembled mouse SOx cDNA has an open reading frame of 1704-bp nucleotides, translating into a size of 568 amino acids. The calculated molecular mass of the mouse SOx protein is 65 kDa. This mouse sequence can be amplified from total RNAs of various mouse tissue samples by reverse transcription polymerase chain reaction, especially highly amplified from those of the seminal vesicles and epidermis. The cDNA fragment was subsequently cloned into the mammalian expression vector (pTARGET-MSSOx), allowing us to express mouse recombinant SOx protein in cultured cells. When pTARGET-MSSOx was transfected, Western blot analysis using anti-SOx antiserum could detect a 65 kDa-band of recombinant SOx in both samples from the whole cell extract and the medium after the harvest of the HEK cells. In immunohistochemical analysis, the Pt-K2 cells, following the introduction of pTARGET-MSSOx, seemed to generate a SOx protein reactive to anti-SOx antiserum in the cells. Moreover, the indirect staining of the S-S bonds using N-(7-dimethylamino-4-methyl coumarinyl) maleimide (DACM), following the addition of N-ethylmaleimide and dithiothreitol, showed that the formation of S-S bridges almost matched the localization of SOx expression in the Pt-K2 cells after the transfection. In essence, we cloned skin SOx cDNA and characterized it as one of the S-S cross-linking enzymes. The SOx clone from mouse epidermis seems to be useful for investigating the potential function of the enzyme in the epidermis, especially for understanding the physiological role of SOx in the differentiation of keratinocytes.

Expression, localization and activity of neutral endopeptidase in cultured cells of benign prostatic hyperplasia and prostate cancer

PURPOSE Neutral endopeptidase is a cell surface enzyme that cleaves and inactivates neuropeptides. Neutral endopeptidase is expressed by prostatic epithelial cells and is thought to have a key role in the growth of androgen independent prostate cancer. In contrast to the encouraging data dealing with neutral endopeptidase and prostate cancer progression, only few studies are available of the significance of neutral endopeptidase in prostatic stromal cells and benign prostatic hyperplasia (BPH). We report the expression and activity of neutral endopeptidase in human prostatic stromal cells. MATERIALS AND METHODS We recently established and characterized human prostatic stromal cells from BPH tissue. Reverse transcriptase-polymerase chain reaction, Western blot experiments and immunohistochemistry were performed to investigate the expression levels of neutral endopeptidase and show the cellular localization of the enzyme in these cells. Enzymatic neutral endopeptidase activity was evaluated using a colorimetric assay in nonstimulated cells, and after androgen and estrogen application. RESULTS Stromal BPH cells showed strong expression of the neutral endopeptidase messenger RNA and protein, equaling the neutral endopeptidase expression level in prostate cancer cells. The neutral endopeptidase protein located in the plasma membrane of the cells showed a mean enzymatic activity plus or minus standard deviation of 75% +/- 2.5% compared with LNCaP prostate cancer cells. Interestingly enzymatic activity of the membrane bound neutral endopeptidase in stromal cells was not regulated by androgen and estrogen. CONCLUSIONS These data suggest that neutral endopeptidase is expressed by prostatic stromal cells. In addition to its role in the progression of prostate cancer, it may also be involved in regulatory processes in the stroma, namely the degradation of neuropeptides released from prostatic neuroendocrine cells.

Switch of PMCA4 splice variants in bovine epididymis results in altered isoform expression during functional sperm maturation

Ca2+ and Ca2+-dependent signals are essential for sperm maturation and fertilization. In mouse sperm the plasma membrane Ca2+-ATPase (PMCA) isoform 4 plays a crucial role in Ca2+ transport. The two major splice variants of PMCA4 are PMCA4a and PMCA4b. PMCA4a differs from PMCA4b in the mechanism of calmodulin binding and activation. PMCA4a shows a much higher basal activity and is more effective than PMCA4b in returning Ca2+ to resting levels. Knock-out mice carrying a PMCA4-null mutation are infertile because their sperm cannot achieve a hyperactivated state of motility. As sperm reach functional maturity during their transit through the epididymis, the expression of PMCA4a and 4b was assessed in bull testis and epididymis. Quantitative PCR revealed that PMCA4b is the major splice variant in testis, caput, and corpus epididymidis. In contrast, PMCA4a is the major splice variant in cauda epididymidis, whereas sperm are transcriptionally silent. Immunohistochemical staining using a new antibody against bovine PMCA4a located the PMCA4a to the apical membrane of the epithelium of cauda epididymidis, whereas testis, caput, and corpus epididymidis were negative. Western blotting of testis, epididymis, and sperm isolated from caput and cauda epididymidis showed a much higher level of PMCA4a in cauda epididymidis and sperm from cauda epididymidis compared with testis membranes and sperm from caput epididymidis. These findings suggest that PMCA4a is transferred to bovine sperm membranes in cauda epididymidis. This isoform switch may facilitate a higher calcium turnover in sperm necessary to traverse the female genital tract.

Vesicular transfer of membrane components to bovine epididymal spermatozoa

Epididymosomes (apocrine secreted epididymal vesicles) are assumed to play a crucial role in sperm maturation. Our aim has been to analyze the fusogenic properties of bovine epididymosomes and their involvement in the transfer of membrane components (lipids, proteins, plasma membrane Ca2+-ATPase 4 [PMCA4]) into bovine sperm. The fusogenic properties of epididymosomes with spermatozoa were investigated in vitro by using octadecyl rhodamine-B (R18)-labeled epididymosomes. Spermatozoa isolated from the epididymal caput showed a higher fusion rate than those taken from the cauda. The fusion rate was dependent on pH and time. Furthermore, the lipid and protein content in spermatozoa changed during epididymal transit and after in vitro fusion with epididymosomes. Following the in vitro fusion of caput spermatozoa with epididymosomes, the cholesterol/total phospholipid ratio of the sperm plasma membrane decreased. The effect was comparable with the cholesterol/total phospholipid ratio of native cauda spermatozoa. Co-incubation experiments of spermatozoa with biotinylated epididymosomes additionally revealed that proteins were transferred from epididymosomes to sperm. To examine the potential transfer of epididymis-derived PMCA4 to spermatozoa, immunofluorescence analysis and Ca2+-ATPase activity assays were performed. In caput spermatozoa, the PMCA4 fluorescence signal was slightly raised and Ca2+-ATPase activity increased after in vitro fusion. Thus, our experiments indicate significant changes in the lipid and protein composition of epididymal sperm following interaction with epididymosomes. Moreover, our results substantiate the presumption that PMCA4 is transferred to spermatozoa via epididymosomes.