Atrial but not ventricular fibrosis in mice expressing a mutant transforming growth factor-beta(1) transgene in the heart.

Increased transforming growth factor (TGF)-beta(1) activity has been observed during pathologic cardiac remodeling in a variety of animal models. In an effort to establish a causal role of TGF-beta(1) in this process, transgenic mice with elevated levels of active myocardial TGF-beta(1) were generated. The cardiac-restricted alpha-myosin heavy chain promoter was used to target expression of a mutant TGF-beta(1) cDNA harboring a cysteine-to-serine substitution at amino acid residue 33. This alteration blocks covalent tethering of the TGF-beta(1) latent complex to the extracellular matrix, thereby rendering a large proportion (>60%) of the transgene-encoded TGF-beta(1) constitutively active. Although similar levels of active TGF-beta(1) were present in the transgenic atria and ventricles, overt fibrosis was observed only in the atria. Surprisingly, increased active TGF-beta(1) levels inhibited ventricular fibroblast DNA synthesis in uninjured hearts and delayed wound healing after myocardial injury. These data suggest that increased TGF-beta(1) activity by itself is insufficient to promote ventricular fibrosis in the adult mouse ventricle.

Differential distribution of mannose-6-phosphate receptors and furin in immature secretory granules.

In neuroendocrine cells sorting of proteins from immature secretory granules (ISGs) occurs during maturation and is achieved by clathrin-coated vesicles containing the adaptor protein (AP)-1. We have investigated the role of the mannose-6-phosphate receptors (M6PRs) in the recruitment of AP-1 to ISGs. M6PRs were detected in ISGs isolated from PC12 cells by subcellular fractionation, and by immuno-EM labelling on cryosections. In light of our previous results, where greater than 80% of the ISGs were found to contain furin, we examined the relationship between furin and M6PR on ISGs. By immunoisolation techniques we find that 50% at most of the ISGs contain the cation-independent (CI)-M6PR. Using sequential immunoisolation we could demonstrate that there are two populations of ISGs: those that have both M6PR and furin, and those which contain only furin. Furthermore, using immobilized GST-fusion proteins containing the cytoplasmic domain of the CI-M6PR we have shown binding of AP-1 requires casein kinase II phosphorylation of the CI-M6PR fusion protein, and in particular phosphorylation of Ser(2474). Addition of these phosphorylated GST-CI-M6PR fusion proteins to a cell-free assay reconstituting AP-1 binding to ISGs inhibits AP-1 recruitment to ISGs.

Interaction of furin in immature secretory granules from neuroendocrine cells with the AP-1 adaptor complex is modulated by casein kinase II phosphorylation.

The composition of secretory granules in neuroendocrine and endocrine cells is determined by two sorting events; the first in the trans-Golgi complex (TGN), the second in the immature secretory granule (ISG). Sorting from the ISG, which may be mediated by the AP-1 type adaptor complex and clathrin-coated vesicles, occurs during ISG maturation. Here we show that furin, a ubiquitously expressed, TGN/endosomal membrane endoprotease, is present in the regulated pathway of neuroendocrine cells where it is found in ISGs. By contrast, TGN38, a membrane protein that is also routed through the TGN/endosomal system does not enter ISGs. Furin, however, is excluded from mature secretory granules, suggesting that the endoprotease is retrieved from the clathrin-coated ISGs. Consistent with this, we show that the furin cytoplasmic domain interacts with AP-1, a component of the TGN/ISG-localized clathrin sorting machinery. Interaction between AP-1 and furin is dependent on phosphorylation of the enzyme's cytoplasmic domain by casein kinase II. Finally, in support of a requirement for the phosphorylation-dependent association of furin with AP-1, expression of furin mutants that mimic either the phosphorylated or unphosphorylated forms of the endoprotease in AtT-20 cells demonstrates that the integrity of the CKII sites is necessary for removal of furin from the regulated pathway.

pH-dependent processing of secretogranin II by the endopeptidase PC2 in isolated immature secretory granules.

We have previously characterized the processing of secretogranin II (SgII) in PC12 cells that were stably transfected with the endopeptidase PC2. Here we show that processing of SgII can be observed in isolated immature secretory granules (ISGs) derived from this cell line in a temperature- and ATP-dependent manner. The stimulatory effect of ATP on processing can be attributed to the activation of the vacuolar H(+)-ATPase and a concomitant decrease in intragranular pH. The immature secretory granule therefore provides an adequate environment for correct processing of SgII by PC2. The rate of SgII processing was strongly dependent on the intragranular pH, suggesting that processing of SgII can be used as a pH indicator for the granule interior. A standard curve was prepared using SgII processing in ISGs equilibrated at a range of pH values. The extent of processing in ISGs incubated in the presence of ATP at physiological pH was compared with the standard curve, and the intragranular pH was determined. From these observations, we propose an intragranular pH of 6.3 +/- 0.1 for ISGs in a physiological buffer in the presence of ATP. Hence, the pH of ISGs seems to be similar to the pH of the trans-Golgi network (TGN) and is clearly higher than the pH of mature secretory granules (pH 5.0-5.5). Interestingly, no processing of SgII could be observed in a membrane fraction that is highly enriched in TGN under conditions for which processing was readily obtained in isolated ISGs.

The AP-1 adaptor complex binds to immature secretory granules from PC12 cells, and is regulated by ADP-ribosylation factor.

Immature secretory granules (ISGs) in endocrine and neuroendocrine cells have been shown by morphological techniques to be partially clathrin coated (Orci, L., M. Ravazzola, M. Amherdt, D. Lonvard, A. Perrelet. 1985a. Proc. Natl. Acad. Sci. USA. 82:5385-5389; Tooze, J., and S. A. Tooze. 1986. J. Cell Biol. 103:839-850). The function, and composition, of this clathrin coat has remained an enigma. Here we demonstrate using three independent techniques that immature secretory granules isolated from the rat neuroendocrine cell line PC12 have clathrin coat components associated with their membrane. To study the nature of the coat association we have developed an assay whereby the binding of the AP-1 subunit gamma-adaptin to ISGs was reconstituted by addition of rat or bovine brain cytosol. The amount of gamma-adaptin bound to the ISGs was ATP independent and was increased fourfold by the addition of GTPgammaS. The level of exogenous gamma-adaptin recruited to the ISG was similar to the level of gamma-adaptin present on the ISG after isolation. Addition of myristoylated ARF1 peptide stimulated binding. Reconstitution of the assay using AP-1 adaptor complex and recombinant ARF1 provided further evidence that ARF is involved in gamma-adaptin binding to ISGs; BFA inhibited this binding. Trypsin treatment and Trisstripping of the ISGs suggest that additional soluble and membrane-associated components are required for gamma-adaptin binding.

Characterization of the endopeptidase PC2 activity towards secretogranin II in stably transfected PC12 cells.

To study the processing of secretogranin II (SgII) by the prohormone convertase PC2 we have generated a stable PC12 cell line which expresses mouse PC2. We here present the characteristics of the PC12/PC2 cell line and demonstrate that the exogenous PC2 is sorted and stored in secretory granules in the PC12/PC2 cell line as efficiently as the endogenous granins. By indirect immunofluorescence with antibodies specific for chromogranin B (CgB) and PC2 we were able to establish that the PC2 is stored in secretory granules in the PC12/PC2 cell line. After subcellular fractionation, followed by immunoblotting, the mature 68 kDa form of PC2 was found co-sedimented with SgII in fractions containing secretory granules. Two-dimensional gel electrophoresis was used to characterize a secretory granule fraction obtained from the PC12/PC2 cells, and a comparison was done of the electrophoretic pattern obtained from the PC12/PC2 cells with the parent cell line PC12. The products derived from the processing of SgII by PC2 were identified by immunoblotting with a panel of antibodies directed against SgII. Using [35S]sulphate to label the newly synthesized SgII, we performed a time course to monitor the appearance of the lower-molecular-mass fragments of SgII: beginning 15 min after a 5 min pulse of [35S]sulphate we were able to detect the first proteolytic fragment of SgII. Our results demonstrate that SgII is proteolytically processed by PC2 in the immature secretory granule into several lower-molecular-mass proteins, the major ones being an 18 kDa sulphated fragment and a 28 kDa fragment.

Antibodies to secretogranin II reveal potential processing sites.

Several events occur during secretory granule maturation in endocrine and neuronal cells, one of the most important being the processing of prohormones. In addition, secretory granules undergo several changes during storage and maturation within the cell. We have been investigating the maturation of secretory granules in the neuroendocrine cell line PC12. Our working hypothesis postulates that fusion of newly budded secretory granules occurs during maturation and results in a larger secretory granule. We have been investigating the kinetics and specificity of the prohormone processing enzymes towards secretogranin II. Processing of secretogranin II must occur predominantly in the maturing secretory granule and could be used as a method to monitor secretory granule maturation.