Developmental regulation of alternatively spliced acetyl-CoA carboxylase-alpha mRNAs encoding isozymes with or without an eight amino acid domain upstream of the Ser-1200 phosphorylation motif in the mammary gland.

Expression of a variant acetyl-CoA carboxylase-alpha (ACC-alpha) mRNA encoding an isozyme either comprising (+24nt) or lacking (Delta24nt) an eight amino acid domain proximal to the Ser-1200 phosphorylation motif has been investigated in ovine and rat mammary tissue throughout pregnancy and lactation. The ratio of the Delta24nt mRNA: +24nt mRNA in ovine tissues varied from 0.1-0.25 (spleen, lung, muscle, heart, adipose tissue, brain) to 0.6-0.8 (pancreas, liver, kidney) to approximately 5.0 (lactating mammary gland). The sixfold increase in total ACC-alpha mRNA expression in mammary gland during lactation was due entirely to a tenfold increase in the level of the Delta24nt species as the level of expression of the +24nt species remained unaltered between pregnancy and lactation. This mode of expression of the +24nt and Delta24nt mRNAs was similar in rat mammary gland. Between day 20 of pregnancy and day 4 of lactation the ratio of the Delta24nt : +24nt mRNA increased from 2:1 to 10-20:1. Forced involution reduced the ratio of the two mRNAs to levels observed throughout pregnancy. Treatment of lactating rats with bromocryptine reduced the ratio of the Delta24nt : +24nt mRNA to relative levels observed after forced involution, suggesting that the exonic splicing responsible for the generation of the two mRNA isoforms is prolactin responsive.

Intracellular compartmentalization of PDE4 cyclic AMP-specific phosphodiesterases.

The PDE4 cyclic AMP-specific phosphodiesterase family comprises a large number of different isoforms encoded by four distinct genes, with additional complexity arising through alternate mRNA splicing. This generates a number of distinct PDE4 isoforms with unique N-terminal regions. The range of such splice variants emanating from the four PDE4 genes appears to be highly conserved across species. One key role for such regions appears to be their potential to target isoforms to specific intracellular sites. Evidence for such a targeting role for these N-terminal regions can be gleaned by a variety of techniques. These include subcellular fractionation, confocal microscopy, binding assays to show association with proteins having src homology 3 (SH3) domains, and generation of chimeric constructs of these N-terminal regions with proteins that are normally expressed in the cytosol.

Phosphodiesterase isoforms in the pulmonary arterial circulation of the rat: changes in pulmonary hypertension.

Phosphodiesterase (PDE) activity was determined in pulmonary arteries removed from control and chronic hypoxia-induced pulmonary hypertensive rats. The main, first-branch, intrapulmonary and resistance pulmonary arteries were studied. We measured total cAMP PDE activity and cGMP PDE activity, as well as that of individual isoforms (PDE1-5). cAMP PDE activity in chronic hypoxic rats was increased in first-branch and intrapulmonary arteries from hypoxic rats. No changes were observed in the main or resistance pulmonary arteries. Similarly, cGMP PDE activity was increased in the main, first-branch and intra-pulmonary arteries of the hypoxic rats. No changes in cGMP PDE activity were observed in resistance arteries. There was evidence for PDE1-5 activity in all pulmonary arteries. The increased cAMP PDE activity in first-branch and intrapulmonary vessels was associated with an increase in cilostimide-inhibited PDE (PDE3) activity. Increased total cGMP PDE in main pulmonary artery was associated with increases in Ca++/calmodulin-stimulated (PDE1) activity. An increase in zaprinast-inhibited (PDE5) activity was observed in first-branch and intrapulmonary arteries. Our results suggest that decreases in intracellular cyclic nucleotide levels in pulmonary arteries from pulmonary hypertensive rats are associated with increased PDE activity. Further, these changes may reflect alterations at the level of specific types of PDE isoforms.

Intracellular localization of the PDE4A cAMP-specific phosphodiesterase splice variant RD1 (RNPDE4A1A) in stably transfected human thyroid carcinoma FTC cell lines.

Cells of two human follicular thyroid carcinoma cell lines (FTC133, FTC236) were stably transfected with a cDNA encoding the PDE4A cAMP-specific phosphodiesterase (PDE) splice variant RD1 (RNPDE4A1A) so as to generate the cloned cell lines, FTC133A and FTC236A. This allowed the expression of a novel rolipram-inhibited cAMP-specific PDE activity in these cells. Unlike the parent cell lines in which Ca2+/calmodulin caused a profound activation (approx. 3-4-fold) of homogenate PDE activity, no such stimulation was evident in the RD1-expressing cell lines, indicating loss of PDE1 activity. Reverse transcriptase-PCR analysis indicated that this was due to the down-regulation of the PDE1C isoform. The novel PDE4 activity in transfected cells was located exclusively in the membrane fraction, as was immunoreactive RD1. Low concentrations of the detergent Triton X-100, but not high NaCl concentrations, allowed RD1 to be solubilized. Laser scanning confocal immunofluorescence analyses identified RD1 immunoreactivity in a discrete perinuclear region of these RD1-expressing transfected cell lines. A similar pattern of labelling was observed using the antiserum Tex1, which specifically identified the Golgi apparatus. Treatment of FTC133A cells with the Golgi-perturbing agents monensin and brefeldin A led to a similar redistribution of immunoreactive species detected using both the Tex1 and anti-RD1 antisera. It is suggested that the PDE4A splice variant RD1 contains a membrane-association signal which allows the targeted expression of RD1 within the Golgi complex of these human follicular thyroid carcinoma cell lines.

The human cyclic AMP-specific phosphodiesterase PDE-46 (HSPDE4A4B) expressed in transfected COS7 cells occurs as both particulate and cytosolic species that exhibit distinct kinetics of inhibition by the antidepressant rolipram.

Transfection of COS7 cells with a plasmid encoding the human cyclic AMP-specific PDE4A phosphodiesterase PDE-46 (HSPDE4A4B) led to the expression of a rolipram-inhibited PDE4 activity, which contributed approximately 96% of the total COS cell PDE activity. A fusion protein was generated which encompassed residues (788-886) at the extreme C terminus of PDE-46 and was used to generate an antiserum that detected PDE-46 in transfected COS7 cells. Immunoblotting studies identified PDE-46 as a approximately 125-kDa species that was associated with both the soluble and particulate fractions. The relative Vmax of particulate PDE-46 was approximately 56% that of cytosolic PDE-46. Particulate PDE-46 was not solubilized using Triton X-100 or high NaCl concentrations. Immunofluorescence analysis by laser scanning confocal microscopy showed that PDE-46 was located at discrete margins of the cell, indicative of association with membrane cortical regions. The human PDE4A species, h6.1 (HSPDE4A4C), which lacks the N-terminal extension of PDE-46, was found as an entirely soluble species when expressed in COS7 cells. h6.1 was shown to have an approximately 11-fold higher Vmax relative to that of PDE-46. In dose-response studies rolipram inhibited particulate PDE-46 at much lower concentrations (IC50 = 0. 195 microM) than those needed to inhibit the cytosolic enzyme (IC50 = 1.6 microM). The basis of this difference lay in the fact that rolipram served as a simple competitive inhibitor of the cytosol enzyme (Ki = 1.6 microM) but as a partial competitive inhibitor of the particulate enzyme (Ki = 0.037 microM; Ki' = 2.3 microM). Particulate PDE-46 thus showed a approximately 60-fold higher affinity for rolipram than cytosolic PDE-46.

Identification, characterization and regional distribution in brain of RPDE-6 (RNPDE4A5), a novel splice variant of the PDE4A cyclic AMP phosphodiesterase family.

COS-7 cells were transfected with a plasmid encoding a putative splice variant of PDE4A cyclic AMP-specific phosphodiesterase, RPDE-6 (RNPDE4A5). This led to the expression of a novel, cyclic AMP-specific, rolipram-inhibited phosphodiesterase activity. In such transfected cells a novel approximately 109 kDa species was recognized by anti-peptide sera raised against a dodecapeptide whose sequence is found at the extreme C-terminus of both RPDE-6 and another PDE4A splice variant. RD1 (RNPDE4A1A). RPDE-6 activity and immunoreactivity was found distributed between both pellet (approximately 25%) and cytosol (approximately 75%) fractions of transfected COS-7 cells. Soluble and pellet RPDE-6 activities exhibited similar low Km values for cyclic AMP (approximately 2.4 microM) and were both inhibited by low concentrations of rolipram, with IC50 values for the soluble activity being lower (approximately 0.16 microM) than for the pellet activity (approximately 1.2 microM). Pellet RPDE-6 was resistant to release by either high NaCl concentrations or the detergent Triton X-100. Probing brain homogenates with the anti-(C-terminal peptide) sera identified two immunoreactive species, namely an approximately 79 kDa species reflecting RD1 and an approximately 109 kDa species that co-migrated with the immunoreactive species seen in COS cells transfected to express RPDE-6. The approximately 109 kDa species was found distributed between both the low-speed (P1) and high-speed (P2) pellet fractions as well as the cytosol fractions derived from both brain and RPDE-6-transfected COS cells. In contrast, RD1 was found exclusively in the P2 fraction. Phosphodiesterase (PDE) activity immuno-precipitated by these antisera from brain cytosol had the characteristics of COS cell-expressed RPDE-6 with KmcyclicAMP approximately 3.7 microM and IC50rolipram approximately 0.12 microM. The distribution of PDE activity immunoprecipitated from the cytosol of various brain regions paralleled that seen for the distribution of the approximately 109 kDa immunoreactive species. It is suggested that the 109 kDa species identified in brain cytosol and pellet fractions is the native form of RPDE-6. The PDE4A splice variants, RD1 and RPDE-6, were shown to have distinct patterns of expression among various brain regions. PDE4A and PDE4B activities appear to provide the major source of PDE4 activity in brain membranes, whereas the cytosolic PDE4 activity is suggested to reflect predominantly the activity of the PDE4D family. Alternative splicing of the PDE4A gene confers distinct N-terminal domains on RPDE-6 and RD1, which attenuates the Vmax. of these enzymes and defines their distinct subcellular distribution pattern.

Identification and characterization of the type-IVA cyclic AMP-specific phosphodiesterase RD1 as a membrane-bound protein expressed in cerebellum.

An antiserum was generated against a dodecapeptide whose sequence is found at the C-terminus of a cyclic AMP (cAMP)-specific, type-IVA phosphodiesterase encoded by the rat 'dunc-like' cyclic AMP phosphodiesterase (RD1) cDNA. This antiserum identified a single approximately 73 kDa protein species upon immunoblotting of cerebellum homogenates. This species co-migrated upon SDS/PAGE with a single immunoreactive species observed in COS cells transfected with the cDNA for RD1. Native RD1 in cerebellum was found to be predominantly (approximately 93%) membrane-associated and could be found in isolated synaptosome populations, in particular those enriched in post-synaptic densities. Fractionation of lysed synaptosomes on sucrose density gradients identified RD1 as co-migrating with the plasma membrane marker 5'-nucleotidase. Laser scanning confocal and digital deconvolution immunofluorescence studies done on intact COS cells transfected with RD1 cDNA showed RD1 to be predominantly localized to plasma membranes but also associated with the Golgi apparatus and intracellular vesicles. RD1-specific antisera immunoprecipitated phosphodiesterase activity from solubilized cerebellum membranes. This activity had the characteristics expected of the type-IV cAMP phosphodiesterase RD1 in that it was cAMP specific, exhibited a low Km cAMP of 2.3 microM, high sensitivity to inhibition by 4-[3-(cyclopentoxyl)-4-methoxyphenyl]-2-pyrrolidone (rolipram) (Ki approximately 0.7 microM) and was unaffected by Ca2+/calmodulin and low concentrations of cyclic GMP. The phosphodiesterase activities of RD1 solubilized from both cerebellum and transfected COS cell membranes showed identical first-order thermal denaturation kinetics at 50 degrees C. Native RD1 from cerebellum was shown to be an integral protein in that it was solubilized using the non-ionic detergent Triton X-100 but not by either re-homogenization or high NaCl concentrations. The observation that hydroxylamine was unable to cause the release of RD1 from either cerebellum or COS membranes and that [3H]palmitate was not incorporated into the RD1 protein immunoprecipitated from COS cells transfected with RD1 cDNA, indicated that RD1 was not anchored by N-terminal acylation. The engineered deletion of the 25 residues forming the unique N-terminal domain of RD1 caused both a profound increase in its activity (approximately 2-fold increase in Vmax) and a profound change in intracellular distribution. Thus, immunofluorescence studies identified the N-terminal truncated species as occurring exclusively ion the cytosol of transfected COS cells. The cDNA for RD1 thus appears to encode a native full-length type-IVA phosphodiesterase that is expressed in cerebellum.(ABSTRACT TRUNCATED AT 400 WORDS)

How does dietary lipid lower blood alcohol concentrations?

To determine the mechanism, whereby food lowers blood alcohol concentrations, gastric emptying and blood alcohol profiles were measured in six healthy male volunteers after they had drunk a 200 ml solution of vodka and orange juice containing 0.5 g/kg alcohol. Subjects were studied on two separate occasions during infusion of isosmotic solutions of either Intralipid or saline into the ileum via an intestinal tube. Gastric emptying was significantly delayed by ileal infusion of fat emulsion and the peak blood alcohol concentration was significantly depressed. Similar effects were observed in three subjects when the solutions were infused into the duodenum. These results suggest that the reduction in alcohol absorption by food does not depend on the physical relationship between the alcohol and the food or between the food and the absorbing epithelium, but is probably caused by a delay in the delivery of alcohol to the small intestine, from where it is rapidly absorbed.