Pharmacological characterization of PF-00547659, an anti-human MAdCAM monoclonal antibody.

BACKGROUND AND PURPOSE: The adhesion molecule mucosal addressin cell adhesion molecule (MAdCAM) plays an essential role in the recruitment of lymphocytes to specialized high endothelial venules of the gastrointestinal tract and in their excessive tissue extravasation observed in inflammatory conditions, such as Crohn's disease. We have characterized the in vitro pharmacological properties of two monoclonal antibodies blocking MAdCAM, MECA-367 and PF-00547659, and determined their pharmacokinetic/pharmacodynamic profiles in vivo. EXPERIMENTAL APPROACH: Functional adhesion assays and surface plasmon resonance were used to characterize, in vitro, the pharmacological properties of MECA-367 and PF-00547659. The in vivo effects of MECA-367 and PF-00547659 on restriction of beta(7) (+) memory T lymphocytes were determined in mice and macaques, respectively, over the pharmacological dose range to confirm pharmacokinetic/pharmacodynamic relationships. KEY RESULTS: MECA-367 and PF-00547659 bound with high affinity to mouse and human MAdCAM with K(d) values of 5.1 and 16.1 pmol.L(-1) respectively and blocked the adhesion of alpha(4)beta(7) (+) leukocytes to MAdCAM with similar potency. MECA-367 and PF-00547659 induced a similar, dose-dependent two- to threefold increase in circulating populations of beta(7) (+) memory T-cells in the mouse and macaque; without affecting the beta(7) (-) populations. CONCLUSIONS AND IMPLICATIONS: PF-00547659 has potential utility in the treatment of inflammatory conditions by blocking tissue homing of activated alpha(4)beta(7) (+) leukocytes. The characterization of a rodent cross-reacting antibody as a surrogate for PF-00547659 in the search for potential pharmacological biomarkers and the determination of efficacious doses was effective in addressing the restricted orthologous cross-reactivity of PF-00547659 and the challenges this poses with respect to efficacy and safety testing.

Gene expression in Brown Norway rat Leydig cells: effects of age and of age-related germ cell loss.

There is a marked reduction in circulating T and a commensurate decrease in Leydig cell function in males during aging. Aging is also accompanied by progressive loss of germ cells, leading to testicular atrophy. However, in aged animals, there is no difference in T production by Leydig cells from nonregressed testes and from regressed testes. We hypothesize that there are changes in Leydig cell gene expression that accompany aging, and that different changes in gene expression result from testicular regression. To test this hypothesis, the expression of stress response genes was compared in Leydig cells isolated from young rat testes, from aged testes that were not regressed, and from aged testes that were regressed, using an array approach. Similar numbers of transcripts (n = 56-63) were detected in Leydig cells isolated from all three groups of rats. Among these, 21 transcripts were increased in Leydig cells of testes from aged nonregressed animals compared with cells from young animals; 23 were increased with subsequent testicular regression. Only 3 of these transcripts were in common. Thus, age and testicular regression affected Leydig cell transcripts in dramatically different ways. Furthermore, none of the transcripts that decreased when comparing Leydig cells of young and aged nonregressed animals were the same as those that decreased when comparing aged nonregressed and aged regressed animals. In individual gene families, the steady state concentrations of transcripts in Leydig cells from aging and aging regressed testes often differed. Thus, there are major differences in the expression of a wide variety of stress response genes in Leydig cells associated with aging and testicular regression.

Sperm structural and motility changes during aging in the Brown Norway rat.

The Brown Norway rat provides a useful model to study aging of the male reproductive tract because of the selective age-dependent pathological changes that are found in the testis, epididymis, and prostate. In the testis, there is a clear age-dependent decrease in both steroidogenesis and spermatogenesis. In the epididymis, some striking segment-specific changes occur at the histological and biochemical levels prior to the major loss of spermatogenesis. We hypothesized that formation of spermatozoa in the testis and maturation of spermatozoa in the epididymis (ie, acquisition of motility and loss of the cytoplasmic droplet) may be altered during aging. Changes in the morphology of spermatozoa were assessed by light and electron microscopy. Using computer-assisted sperm analysis, the motility parameters of spermatozoa obtained from the caput and cauda epididymidis of young and old Brown Norway rats were compared. In old animals, we also compared the motility of spermatozoa from epididymides adjacent to regressed testes with those from epididymides adjacent to nonregressed testes. There was a marked increase with age in the number of spermatozoa with abnormal flagellar midpieces; the nature of these defects did not change with age. In caput epididymidis, the percentage of motile sperm was similar in young and old rats. In contrast, the percentage of motile spermatozoa was significantly decreased in cauda epididymidis of old rats; spermatozoa from the regressed testis side had altered motility characteristics. Furthermore, in the cauda epididymidis on the regressed testis side of aged Brown Norway rats, the proportion of spermatozoa that retained their cytoplasmic droplet was markedly elevated. Some of these effects are likely due to changes taking place in spermatozoa during the process of spermatogenesis in the testis (eg, formation of the flagellum), whereas others could occur during sperm maturation in the epididymis (eg, acquisition of motility). The multiple effects of aging on sperm morphology, the acquisition of motility, and the shedding of the cytoplasmic droplet clearly indicate that the quality of spermatozoa is affected by aging.

Biochemical characterization of two ram cauda epididymal maturation-dependent sperm glycoproteins.

Rabbit polyclonal antibodies were raised against ram cauda epididymal sperm proteins solubilized by N-octyl-beta-D-glucopy-ranoside (anti-CESP) and against proteins of the fluid obtained from the cauda epididymidis (anti-CEF). The anti-CESP polyclonal antibody reacted with several bands from 17 to 111 kDa with different regionalization throughout the epididymis. The strongest epitopes at 17 kDa and 23 kDa were restricted to the cauda epididymidis. The anti-CEF polyclonal antibody reacted mainly with a 17-kDa and a 23-kDa compound in the cauda sperm extract. These cauda epididymal 17- and 23-kDa proteins disappeared after orchidectomy, but they reappeared in the same regions after testosterone supplementation, indicating that they were secreted by the epithelium. The fluid and membrane 17- and 23-kDa antigens had a low isoelectric point and were glycosylated. The fluid 17- and 23-kDa proteins had hydrophobic properties: they were highly enriched in the Triton X-114 detergent phase and could be extracted from the cauda epididymal fluid by a chloroform-methanol mixture. These proteins were further purified, and their N-terminal sequences did not match any protein in current databases. A polyclonal antibody against the fluid 17-kDa protein recognized the protein in the cauda epididymal sperm extract and immunolocalized it on the sperm flagellum membrane and at the luminal border of all cells in the cauda epididymal epithelium. These results indicated that secreted glycoproteins with hydrophobic properties could be directly integrated in a specific domain of the sperm plasma membrane.

Postnatal development and regulation of proteins secreted in the boar epididymis.

The number of proteins secreted by the boar epididymis increased progressively from 1 mo of age to the adult period. The first specific secretory activity was revealed at 2 mo in the distal caput (hexosaminidase, clusterin, and lactoferrin) and in the corpus (train O/HE1). Train A and glutathione peroxidase specific to the proximal caput, and trains E and M specific to the corpus, appeared at 4 mo. At 5 mo, secretion of procathepsin L occurred in the middle caput and that of mannosidase and E-RABP in the distal caput. Approximately 48% of all the proteins secreted in the adult boar epididymis were dependent on the presence of androgens, either stimulated (33.6%) or repressed (14.4%); 47% were modulated by other factors, and 5% were unregulated. In the proximal caput, 50% of the specific secreted proteins were controlled essentially by factors emanating from the testis. In more distal regions, two proteins secreted in the corpus were regulated by factors from the anterior regions. The regionalization of the secretory activity of the epididymal epithelium resulted in a specific regulation for each protein, which was modulated according to the region of expression and influenced by either testicular or epididymal factors that remain to be identified.

Immunolocalization of CRES (Cystatin-related epididymal spermatogenic) protein in the acrosomes of mouse spermatozoa.

The CRES (cystatin-related epididymal spermatogenic) protein is a member of the cystatin superfamily of cysteine protease inhibitors and exhibits highly restricted expression in the reproductive tract. We have previously shown that CRES protein is present in elongating spermatids in the testis and is synthesized and secreted by the proximal caput epididymal epithelium. The presence of CRES protein in developing germ cells and in the luminal fluid surrounding maturing spermatozoa prompted us to examine whether CRES protein is associated with spermatozoa. In the studies presented, indirect immunofluorescence, immunogold electron microscopy, and Western blot analysis demonstrated that CRES protein is localized in sperm acrosomes and is released during the acrosome reaction. Interestingly, while the 19- and 14-kDa CRES proteins were present in testicular and proximal caput epididymal spermatozoa, the 14-kDa CRES protein was the predominant form present in mid-caput to cauda epididymal spermatozoa. Furthermore, following the ionophore-induced acrosome reaction, CRES protein localization was similar to that of proacrosin/acrosin in that it was detected in the soluble fraction as well as associated with the acrosome-reacted spermatozoa. The presence of CRES protein in the sperm acrosome, a site of high hydrolytic and proteolytic activity, suggests that CRES may play a role in the regulation of intraacrosomal protein processing or may be involved in fertilization.

Role of epididymal secretory proteins in sperm maturation with particular reference to the boar.

This review considers the role of proteins secreted by the epididymis on post-testicular sperm maturation and storage. Two-dimensional gels show that 150 to 200 proteins are secreted into the epididymal lumen. Most are secreted in relatively small amounts; in rams, for example, fewer than ten contribute 90% of the total secretion and only two contribute 52% of the total protein secreted. Most of the proteins are confined to specific regions of the epididymis. The changing pattern of protein secretion along the epididymis corresponds to change in surface protein on spermatozoa, but no epididymal proteins have been identified that appear to be directly involved in modifying the sperm membrane. Most of the major proteins that have been identified seem to be playing a homeostatic role in maintaining the epididymal milieu for spermatozoa.

Molecular cloning and characterization of the epididymis-specific glutathione peroxidase-like protein secreted in the porcine epididymal fluid.

The epididymis-specific glutathione peroxidase was purified from the porcine cauda epididymal fluid in order to analyze its enzymatic activity and roles in the epididymis. The purified protein was found to consist of four identical 23 kDa subunits. The complementary DNA encoding the 23 kDa subunit was cloned from the cDNA library of the porcine proximal caput epididymis, only where the 23 kDa subunit is expressed. Although the selenocysteine codon (TGA) is contained in the cDNA of the other cytosolic type of glutathione peroxidases, it is replaced by cysteine codon (TGT) in the 23 kDa subunit cDNA, similarly to the results previously obtained for cDNAs encoding the epididymis-specific form of the secreted glutathione peroxidases of mouse, rat and monkey. By the direct analysis of the selenium, the purified protein was proved to contain no selenium atom in the molecule. The activities of the purified epididymis-specific glutathione peroxidase toward hydrogen peroxide or organic hydroperoxides were by far lower than the activity of cytosolic selenium-dependent glutathione peroxidase (less than 0.1%). In addition, the concentration of glutathione in the porcine epididymal fluids was about 20 microM, which is much lower than the optimal concentration for the glutathione peroxidase activity of the purified protein. These results strongly suggest that this protein is enzymatically quiescent at least in the porcine epididymal fluid. An immunocytochemical study showed that this protein was found to bind to the acrosomal region of the epididymal sperm and to disappear during the acrosome reaction. Furthermore, this protein significantly retarded the acrosome reaction induced in vitro. The possibilities have been discussed that it protects sperm from the premature acrosome reaction and maintains sperm fertilizing ability in the epididymis.

Characterization and identification of proteins secreted in the various regions of the adult boar epididymis.

The synthesis and secretion of proteins by the boar genital tract were studied in vitro by incubating epididymal tissues with [35S]methionine and cysteine. Characterization of the major neosynthesized proteins was performed electrophoretically by one- and two-dimensional PAGE analysis, and an epididymal protein cartography was established. Some of the proteins secreted were found to be unregionalized. Polarization studies of the secretions in the epididymal tubule were carried out by in vitro incubation of isolated tubules, and most of these unregionalized proteins were found not to be secreted in the epididymal lumen. Inside the epididymal lumen, protein secretion was highly regionalized, and electrophoresis analysis detected few proteins secreted at all points along the organ. A total of 146 epididymal proteins, covering 220 spots, were found to be secreted by the epididymis. The distal caput showed the highest number of spots, the lowest number of proteins secreted being found in the proximal caput and cauda. Most of the epididymal proteins analyzed are highly polymorphic in terms of both isoelectric point and molecular mass. The presence and importance of the different compounds in the various regions of the epididymis were established. Several distinct secretory regions of the epididymis can be determined by the presence of major characteristic proteins. The concentrations of a given protein in the fluids of various regions were not related to the respective secretion intensity of that protein. Identification of some major epididymal proteins was accomplished by N-terminal amino microsequencing and by the use of specific antisera. Of the various major proteins, clusterin, glutathione peroxidase, retinol-binding protein, lactoferrin, EP4, beta-N-acetyl-hexosaminidase, alpha-mannosidase, and procathepsin L were identified and localized along the organ. Several polypeptides found in this study remain unidentified.

Direct evidence for the elevated synthesis and secretion of procathepsin L in the distal caput epididymis of boar.

The proteins which are secreted from the restricted part of the epididymis are suggested to sustain sperm maturation. In porcine species, as the potential abilities of sperm for movement and fertilization greatly increase in the corpus epididymis, the secretions in both the caput and corpus epididymis seem to be very important for the sperm maturation. In this study, we have directed our attention to the 40 kDa protein which is detected in the fluid of the distal caput epididymis of boar. It was purified from the porcine cauda epididymal fluid and its cDNA was cloned from the cDNA library of the distal caput epididymis. According to the deduced amino acid sequence, the 40 kDa protein has been identified as procathepsin L. Northern blot analysis showed that the procathepsin L mRNA was most abundant in the distal caput epididymis among the tissues as examined. Consistent with the distribution of the procathepsin L mRNA in the epididymis, the activity of procathepsin L was absent in the fluid of the proximal and mid caput epididymis and first appeared in the distal caput epididymal fluid, whose contents gradually decreased with the passage through the epididymis. These results first appeared in the first distal caput epididymis expresses very high levels of procathepsin L and unusually secretes it into the luminal fluid instead of targeting it to lysosomes. It has been also found that the mRNA of PDGF, which is known to enhance cathepsin L expression in the culture cells, is very high in the mid caput epididymis, which just precedes the site of procathepsin L secretion. This result indicates that PDGF directly regulates the locally restricted expression and secretion of procathepsin L in the epididymis, which is one of the possible mechanisms involved in the functional differentiation in the epididymis.