Abnormalities of pancreatic exocrine function in obesity: studies in the obese mouse

Insulin is known to play a specific role in the biosynthesis of pancreatic amylase. In the insulin resistant adult C57 BL/6J--ob/ob mouse there is a reduction of pancreatic amylase content. The differences of enzyme content could not be explained by differences of food intake between obese and lean mice, but are more likely to be the consequence of insulin resistance at the level of the exocrine pancreas. By contrast, greater pancreatic content of amylase and lipase seen in young obese mice (less than 2-months old) was associated with the greater food intake of these mice with respect to lean controls.     

Dissection of the nucleotide and metal-phosphate binding sites in cAMP-dependent protein kinase.

The catalytic (C) subunit of cAMP-dependent protein kinase (cAPK) is more stable by several criteria when it is part of a holoenzyme complex. By measuring the thermal stability of the free C subunit in the presence and absence of nucleotides and/or divalent metal ions, it was found that most of the stabilizing effects associated with the type I holoenzyme could be attributed to the nucleotide. The specific requirements for this enhanced stability were further dissected: Adenosine stabilized the C subunit up to 5 degrees C; however, divalent cations (i.e., Mg2+, Ca2+, and Mn2+) do not increase heat stability in combination with adenosine and adenine (1). Divalent cations as well as ATP and ADP have no effect by themselves (2). The enhanced stability derived from both ATP and ADP requires divalent cations. MnATP (12 degrees C) shows a much stronger effect than CaATP (7 degrees C) and MgATP (5 degrees C) (3). In the holoenzyme complex or the protein kinase inhibitor/C subunit complex, metal/ATP is also required for enhanced stability; neither the RI or RII subunits nor PKI alone stabilize the C subunit significantly (4). For high thermal stability, the occupation of the second, low-affinity metal-binding site is necessary (5). From these results, we concluded that the adenine moiety works independently from the metal-binding sites, stabilizing the free C subunit by itself. When the beta- and gamma-phosphates are present, divalent metals are required for positioning these phosphates, and two metals are required to achieve thermostability comparable to adenosine alone. The complex containing two metals is the most stable. A comparison of several conformations of the C subunit derived from different crystal structures is given attributing open and closed forms of the C subunit to less and more thermostable enzymes, respectively.     

Cyclic nucleotides as affinity tools: phosphorothioate cAMP analogues address specific PKA subproteomes

cAMP (adenosine-3',5'-cyclic monophosphate) is a general second messenger controlling distinct targets in eukaryotic cells. In a (sub)proteomic approach, two classes of phosphorothioate cAMP affinity tools were used to isolate and to identify signalling complexes of the main cAMP target, cAMP dependent protein kinase (PKA). Agonist analogues (here: Sp-cAMPS) bind to the regulatory subunits of PKA (PKA-R), together with their interaction partners, and cause dissociation of a holoenzyme complex comprising PKA-R and catalytic subunits of PKA (PKA-C). Antagonist analogues (here: Rp-cAMPS) bind to the holoenzyme without dissociating the complex and were developed to identify interaction partners that bind to the entire complex or to PKA-C. More than 80 different proteins were isolated from tissue extracts including several PKA isoforms and known as well as potentially new interaction partners. Nevertheless, unspecific binding of general nucleotide binding proteins limited the outcome of this chemical proteomics approach. Surface plasmon resonance (SPR) was employed to optimise the entire workflow of pull down proteomics and to quantify the effects of different nucleotides (ATP, ADP, GTP and NADH) on PKA-R binding to affinity material. We could demonstrate that the addition of NADH to lysates improved specificity in pull down experiments. Using a combination of SPR studies and pull down experiments it was shown unambiguously that it is possible to specifically elute protein complexes with cAMP or cGMP from cAMPS analogue matrices. The side-by-side analysis of the PKA-R interactome and the holoenzyme complexed with interacting proteins will contribute to a further dissection of the multifaceted PKA signalling network.     

Analysis of A-kinase anchoring protein (AKAP) interaction with protein kinase A (PKA) regulatory subunits: PKA isoform specificity in AKAP binding

Compartmentalization of cAMP-dependent protein kinase (PKA) is in part mediated by specialized protein motifs in the dimerization domain of the regulatory (R)-subunits of PKA that participate in protein-protein interactions with an amphipathic helix region in A-kinase anchoring proteins (AKAPs). In order to develop a molecular understanding of the subcellular distribution and specific functions of PKA isozymes mediated by association with AKAPs, it is of importance to determine the apparent binding constants of the R-subunit-AKAP interactions. Here, we present a novel approach using surface plasmon resonance (SPR) to examine directly the association and dissociation of AKAPs with all four R-subunit isoforms immobilized on a modified cAMP surface with a high level of accuracy. We show that both AKAP79 and S-AKAP84/D-AKAP1 bind RIIalpha very well (apparent K(D) values of 0.5 and 2 nM, respectively). Both proteins also bind RIIbeta quite well, but with three- to fourfold lower affinities than those observed versus RIIalpha. However, only S-AKAP84/D-AKAP1 interacts with RIalpha at a nanomolar affinity (apparent K(D) of 185 nM). In comparison, AKAP95 binds RIIalpha (apparent K(D) of 5.9 nM) with a tenfold higher affinity than RIIbeta and has no detectable binding to RIalpha. Surface competition assays with increasing concentrations of a competitor peptide covering amino acid residues 493 to 515 of the thyroid anchoring protein Ht31, demonstrated that Ht31, but not a proline-substituted peptide, Ht31-P, competed binding of RIIalpha and RIIbeta to all the AKAPs examined (EC(50)-values from 6 to 360 nM). Furthermore, RIalpha interaction with S-AKAP84/D-AKAP1 was competed (EC(50) 355 nM) with the same peptide. Here we report for the first time an approach to determine apparent rate- and equilibria binding constants for the interaction of all PKA isoforms with any AKAP as well as a novel approach for characterizing peptide competitors that disrupt PKA-AKAP anchoring.     

Identification of a novel A-kinase anchoring protein 18 isoform and evidence for its role in the vasopressin-induced aquaporin-2 shuttle in renal principal cells

Arginine vasopressin (AVP) increases the water permeability of renal collecting duct principal cells by inducing the fusion of vesicles containing the water channel aquaporin-2 (AQP2) with the plasma membrane (AQP2 shuttle). This event is initiated by activation of vasopressin V2 receptors, followed by an elevation of cAMP and the activation of protein kinase A (PKA). The tethering of PKA to subcellular compartments by protein kinase A anchoring proteins (AKAPs) is a prerequisite for the AQP2 shuttle. During the search for AKAP(s) involved in the shuttle, a new splice variant of AKAP18, AKAP18delta, was identified. AKAP18delta functions as an AKAP in vitro and in vivo. In the kidney, it is mainly expressed in principal cells of the inner medullary collecting duct, closely resembling the distribution of AQP2. It is present in both the soluble and particulate fractions derived from renal inner medullary tissue. Within the particulate fraction, AKAP18delta was identified on the same intracellular vesicles as AQP2 and PKA. AVP not only recruited AQP2, but also AKAP18delta to the plasma membrane. The elevation of cAMP caused the dissociation of AKAP18delta and PKA. The data suggest that AKAP18delta is involved in the AQP2 shuttle.     

Introduction of the European minnow into a subalpine lake: habitat use and long-term changes in population dynamics

Minnows Phoxinus phoxinus , studied 30 years after the first record of the species in the subalpine Lake Øvre Heimdalsvatn, Norway, ≥55 mm L _T, were estimated to have densities of c . 4.7 kg ha⁻¹ (120 000 fish) in June 1999 and 2.1 kg ha⁻¹ (63 000 fish) in June 2000. The population was characterized by low individual growth, delayed age of maturity and lived longer when compared to values reported in a previous study in the early phase of its establishment, and other values reported in the literature. Most minnows reached sexual maturity at 4–5 years and >55 mm L _T. Although the estimated annual survival of minnows >55 mm was low ( S =0.2), ages up to 13 years were recorded. Despite a moderate increase in the population size during the last 20 years, the present reduction in individual growth, followed by delayed age of maturity, suggested the existence of density-dependent effects on the population dynamics of the minnows. The minnows were restricted to the littoral zone and near bottom areas. A vertical or horizontal expansion in habitat use was probably prevented by the presence of piscivorous brown trout Salmo trutta .     

Importance of the A-helix of the catalytic subunit of cAMP-dependent protein kinase for stability and for orienting subdomains at the cleft interface.

All eukaryotic protein kinases share a conserved catalytic core. In the catalytic (C) subunit of cAMP-dependent protein kinase (cAPK) this core is preceded by a myristylation motif followed by a long helix with Trp 30 at the end of this A-helix filling a hydrophobic cavity between the two lobes of the core. To understand the importance of the A-helix, the myristylation motif (delta 1-14) as well as the entire N-terminal segment (delta 1 -39) were deleted. In addition, Trp 30 was replaced with both Tyr and Ala. All proteins were overexpressed in E. coli and purified to homogeneity. rC(delta 1-14), rC(W30Y), and rC(W30A) all had reduced thermostability, but were catalytically indistinguishable from wild-type C. Based on Surface Plasmon Resonance, all three also formed stable holoenzyme complexes with the RI-subunit, although the appKds were reduced by more than 10-fold due to decrease in the association rate. Surprisingly, however, the holoenzymes were even more thermostable than wild-type holoenzyme. To obtain active enzyme, it was necessary to purify rC(delta 1-39) as a fusion protein with glutathione-S-transferase (GST-rC(delta 1-39), although its thermostability (Tm) was decreased by 12.5 degrees C, was catalytically similar to wild-type C and was inhibited by both the type I and II R-subunits and the heat-stable protein kinase inhibitor (PKI). The Tm for holoenzyme II formed with GST-rC(delta 1-39) was 16.5 degrees C greater than the Tm for free GST-rC(delta 1-39), and the Ka(cAMP) was increased nearly 10-fold. These mutants point out striking and unanticipated differences in how the RI and RII subunits associate with the C-subunit to form a stable holoenzyme and indicate, furthermore, that this N-terminal segment, far from the active site cleft, influences those interactions. The importance of the A-helix and Trp 30 for stability correlates with its location at the cleft interface where it orients the C-helix in the small lobe and the activation loop in the large so that these subdomains are aligned in a way that allows for correct configuration of residues at the active site. This extensive network of contacts that links the A-helix directly to the active site in cAPK is compared to other kinases whose crystal structures have been solved.     

Glucagon receptor-mediated activation of Gs is accompanied by subunit dissociation

The effect of the glucagon receptor on the activation of the stimulatory GTP-binding protein of adenylyl cyclase (Gs) in the native rat liver membrane environment was studied. The activated state of Gs was assessed by its ability to reconstitute the cyc- S49 cell membrane adenylyl cyclase. The Gs protein was activated by saturating concentrations of guanosine 5'-thiotriphosphate (GTP gamma S) or guanyl-5'-yl imidodiphosphate in a hormone-dependent manner at 0.4 mM Mg2+ in native membranes or in membranes that had been treated with 1 mM N-ethylmaleimide to eliminate the catalytic activity of adenylyl cyclase. At 50 mM Mg2+, Gs was fully activated by GTP gamma S in the absence of hormone. The unactivated Gs protein migrates around 4 S, whereas activated Gs migrates around 2 S on sucrose density gradients. When pure Gs is analyzed on sucrose density gradients, it is found that the unactivated protein migrates at 4.1 S. Gs was activated by saturating concentrations of GTP gamma S and Mg2+, and the alpha subunit of Gs was chromatographically purified. The resolved alpha subunit of Gs that is capable of stimulating the cyc- adenylyl cyclase migrates at 2.1 S. From these data, we conclude that activation of Gs results in the dissociation of this protein in the membrane environment and that the hormone-occupied receptor promotes this dissociation process under conditions where Mg2+ ions are limiting.