TRANSFORMATION OF THE HUMAN PROSTATE GLAND IN INTERMEDIATE AND LATE FETAL PERIODS OF DEVELOPMENT

The purpose of the study was to determinate the morphometric parameters of epithelial cords, prostatic ducts, acini of the human prostate gland and their lining epithelium, the shape of prostate glands, and muscle tissue in fetal periods of development. Material and Method: The study was performed on 19 prostate glands of male sex fetuses of intermediate and late fetal periods. We used the morphometric method of verification of apoptotic cells on stained histoligical preps using the criteria of apoptosis. Morphometric research included measurements of acini and acinar lumen areas, epithelium height, assessment of shape factors. Results: In the late fetal period compared to the intermediate fetal period the acini area was not increased in 1.1 times (p =0,004), the area of acinar lumens increases by 3.8 times (p=0.0005). Changes in the shape of acinar lumens were detected. Conclusion: An insignificant increase of the specific area of the glandular parenchyma in the organ of transformation of the developing glands occurs mainly due to their canalization. The formation of prostatic ducts was not followed by the increase in their total area and was the result of differentiation epithelial cells and apoptosis. Transformation of prostate glands in the prenatal period occurs in a certain sequence: the formation of epithelial buds, their canalization by apoptosis with formation of epithelial ducts and prostatic ducts, and formation of end pieces of prostate glands from these ducts. Apoptotic bodies were removed from the lumen of the prostatic ducts by extrusion. The design and orientation of the smooth muscle bundles around prostatic ducts and acini do not ensure the evacuation of content of the prostate glands in the fetal period.

Influence of postnatal prolactin modulation on the development and maturation of ventral prostate in young rats

Besides androgenic dependence, other hormones also influence the prostate biology. Prolactin has been described as an important hormone associated with maintenance of prostatic morphophysiology; however, there is a lack of information on the involvement of prolactin during prostate development and growth. This study aimed to evaluate whether perinatal prolactin modulation interferes with rat ventral prostate (VP) development and maturation. Therefore, prolactin or bromocriptine (an inhibitor of prolactin release from the pituitary) were administered to Sprague Dawley rats from postnatal Day (PND) 12 to PND 21 or 35. Animals were then killed and serum hormonal quantification, VP morphological–stereological and immunohistochemical analyses and western blotting reactions were employed. Our results demonstrate that prolactin blockage increased serum testosterone on PND 21, which reflected an increase in anogenital distance. Although prolactin modulation did not interfere with VP weight, it modified VP morphology by dilating the acinar lumen and reducing epithelial cell height. Prolactin activated the signal transducer and activator of transcription (STAT) downstream pathway, increased androgen receptor expression and epithelial proliferation. In addition, prolactin and bromocriptine also increased expression of cytokeratin 18, a marker of luminal-differentiated cells. In conclusion, the VP responds to prolactin modulation through a mechanism of increasing the epithelial proliferative response and dynamics of cell differentiation, especially in animals treated for a more prolonged period.

Seasonal digestive gland dynamics of the scallop Pecten maximus in the Bay of Brest (France)

Cytological and biochemical changes in the digestive gland of Pecten maximus throughout a one-year period were investigated in the Bay of Brest (France) relative to lipid storage and glycogen and α-amylase concentrations in tubuloacinar terminations. Seasonal variations in both cell structure and biochemical composition were observed. These changes were independent of the tidal cycle, but correspond to phytoplankton abundance. From November to January, cells of digestive acini were hypertrophied due to the high lipid storage. From February to May, these reserves were markedly reduced, cell size decreased, and the acinar lumen was clearly apparent. From May to September, the RNAs transcribing for α-amylase increased, and a correlation was found between digestion events and lipid storage in acinar cells. The relationships between metabolite transfers from digestive gland to gonad and other tissues are described. Distinct lipid storage sites appear to be associated with maintenance energy and acute demand energy, such as gametogenesis when adductor muscle reserves have been depleted. The digestive gland may thus function as a relay organ during periods of energetic stress, notably during the first gametogenesis in February and March and for shell growth in early spring.

Neural pathways regulating Brunner's gland secretion in guinea pig duodenum in vitro

This study examined the neural pathways innervating Brunner's glands using a novel in vitro model of acinar secretion from Brunner's glands in submucosal preparations from the guinea pig duodenum. Neural pathways were activated by focal electrical stimulation and excitatory agonists, and videomicroscopy was used to monitor dilation of acinar lumen. Electrical stimulation of perivascular nerves evoked large dilations that were blocked by TTX (1 μM) or the muscarinic receptor antagonist 4-diphenylacetoxy- N-(2-chloroethyl)-piperidine hydrochloride (1 μM). The nicotinic agonist 1,1-dimethyl-4-phenylpiperazinium iodide (100 μM) had no effect, and the nerve-evoked responses were not inhibited by hexamethonium (200 μM). Dilations were abolished in preparations from chronically vagotomized animals. Activation of submucosal ganglia significantly dilated submucosal arterioles but not Brunner's glands. Effects of electrical stimulation of perivascular and submucosal nerves were not altered by guanethidine. Capsaicin and substance P also dilated arterioles but had no effect on Brunner's glands. Cholinergic (choline acetyltransferase-immunoreactive) nerve fibers were found in Brunner's glands. These findings demonstrate that Brunner's glands are innervated by cholinergic vagal fibers but not by capsaicin-sensitive or intrinsic enteric nerves.

The Affinity Binding Sites of Pancreatic Bile Salt-Dependent Lipase in Pancreatic and Intestinal Tissues

In previous studies, we have shown that the bile salt-dependent lipase (BSDL) associates with the Grp94 molecular chaperone, an association that appears to play essential roles in the folding of BSDL. More recently, combined biochemical and immunocytochemical investigations were carried out to show that the transport of BSDL occurs via an association with the Grp94 all along the pancreatic secretory route (ER-Golgi-granules). The Grp94-BSDL complex is secreted with the pancreatic juice into the acinar lumen and reaches the duodenal lumen, where it is internalized by enterocytes. The dissociation of the complex could take place within the endosomal compartment because BSDL continues further on its way to the basolateral membrane of the enterocyte. To localize the affinity binding sites of pancreatic BSDL in pancreatic and duodenal tissues, we have used an affinity-gold ultrastructural technique. BSDL coupled to gold particles appears to interact with specific sites in tissue sections. This was confirmed by another indirect morphological approach using biotin-labeled BSDL and streptavidin-gold complexes on tissue sections. We have shown that BSDL associates with sites in the pancreatic secretory pathway compartments and in the microvilli, the endosomal compartment, and the basolateral membrane of enterocytes. By biochemical approaches, biotin-labeled BSDL displayed affinities with proteins of 180-190 kD in both pancreatic and duodenal tissues. We have also shown that the Grp94-BSDL complexes, which are insensitive to denaturing conditions, are present in pancreatic homogenate but not in duodenal lysate. Thus, BSDL is able to bind protein complexes formed by either BSDL-Grp94 or Grp94 dimers.

Endocytosis at the apical plasma membrane of pancreatic acinar cells is regulated by tyrosine kinases

We have shown that endocytosis at the apical plasma membrane of pancreatic acinar cells is regulated by the pH of the acinar lumen and is associated with cleavage of GP2, a glycosyl phosphatidylinositol-anchored protein. The aim of this study was to determine the transduction pathway by which endocytosis is activated. Apical endocytosis was studied in rat pancreatic acini by prestimulation with cholecystokinin followed by measurement of horseradish peroxidase (HRP) uptake. Lanthanum, staurosporine, and forskolin had no effect on HRP uptake. Cytochalasin D significantly inhibited endocytosis, indicating a dependence on actin filament integrity. Genistein and the specific tyrphostin inhibitor B42 also inhibited HRP uptake, implicating tyrosine kinases in the regulation of HRP uptake. With the use of an Src kinase-specific substrate, Src kinase activity was temporally related to activation of endocytosis. The tyrosine-dependent phosphorylation of an 85-kDa substrate in both rat and mouse pancreatic acini correlated with Src kinase activation and pH-dependent regulation of HRP uptake. These results indicate that apical endocytosis in acinar cells is associated with tyrosine kinase activation and is dependent on the actin cytoskeleton.

Developmental expression of a mucinlike glycoprotein (MUCLIN) in pancreas and small intestine of CF mice

The mucinlike glycoprotein MUCLIN, one of two protein products of the CRP-ductin gene, was used to study changes in the expression of sulfated glycoconjugates during the pathogenesis of cystic fibrosis, using the cystic fibrosis transmembrane conductance regulator (CFTR) knockout mouse (CF mouse). We assessed the appearance of dilated lumina containing protein or mucus plugs in pancreatic acini and crypts of the small intestine and quantified MUCLIN protein and CRP-ductin mRNA during postnatal development. In CF mice, the pancreatic acinar lumen was dilated by postnatal day 16( P16), but MUCLIN protein was first significantly increased by P23 and remained elevated through adulthood compared with normal mice. Similarly, intestinal crypts had CF-like mucus plugs by P16, but MUCLIN protein was first elevated by P23 and remained elevated through adulthood compared with normal mice. In both organs, MUCLIN labeling of the luminal surface was increased concomitantly with dilation and protein or mucus plugging but before upregulation of expression. The morphological changes were then followed by upregulation of MUCLIN protein and CRP-ductin mRNA expression. This is the first direct study of CF pathogenesis and the resultant increase in glycoconjugate gene expression. The data are consistent with CF pathogenesis progressing from an initial alteration in protein secretory dynamics (increased luminal MUCLIN and protein/mucus plugs) to an upregulation of glycoprotein/mucin gene expression, which is expected to exacerbate obstruction of the luminal spaces.

Immunocytochemical and cytochemical demonstration of a novel selective lysosomal pathway (SLP) of secretion in the exocrine pancreas.

The intracellular distributions of lysosomal and zymogen granule (ZG) membrane proteins were analyzed in the pancreas exocrine acinar cell by cytochemical and immunocytochemical approaches. A strong signal was observed with acid phosphatase (AcPase) in the trans-Golgi network and condensing vacuoles, whereas mature ZG and acinar lumina were devoid of any detectable reaction. The enzyme appears to exit from the regulated pathway by a shedding process during conversion of condensing vacuoles to mature granules. Trimetaphosphatase (TMPase) shows no reaction in the Golgi apparatus and condensing vacuole but is present in immature granules. The exit from the regulated pathway appears to occur at a later stage of the ZG maturation process. A third lysosomal enzyme, nicotinamide adenine dinucleotide phosphohydrolase (NADPase), was found in the median cisterna of the Golgi stack, was undetectable in condensing vacuoles and ZG, but produced a strong signal in the acinar lumen. Our observations show that only one type of intermediate organelle can explain the transport of that enzyme from the Golgi apparatus to the acinar lumen, and it is represented by a subpopulation of lysosomal bodies (LBs) highly reactive for this enzyme. In parallel, immunocytochemical observations with specific antibodies to GP2, a major protein component of the ZG membrane, have confirmed that most of the GP2 molecules in the acinar lumen do not derive from the ZG compartment but rather are from a subpopulation of highly reactive lysosomal structures. Because both NADPase and GP2 co-localize in specific lysosomal structures, and because these LBs are extruded in the acinar lumen, we conclude that this subpopulation of LBs is involved in selective transport of some lysosomal enzymes from the Golgi apparatus to the acinar lumen. This selective lysosomal pathway of secretion can explain the kinetics of GP2 transport and release from the acinar cell that cannot be explained either by the constitutive or the regulated pathway of secretion.