Synthesis of bile acid monosulphates by the isolated perfused rat kidney.

Perfusion of an isolated rat kidney with labelled bile acids, in a protein-free medium, resulted in the urinary excretion of the labelled bile acid, 3% being converted into polar metabolities in 1h. These metabolities were neither glycine nor taurine conjugates, nor bile acid glucuronides, and on solovolysis yielded the free bile acid. On t.l.c. the metabolite of [24-14C]lithocholic acid had the mobility of lithocholate 3-sulphate. The principal metabolite of [24-14C]chenodeoxycholic acid had the mobility of chenodeoxycholate 7-sulphate; trace amounts appeared as chenodeoxycholate 3-sulphate. [35S]sulphate was incorporated in chenodeoxycholic acid by the kidney, resulting in a similar pattern of sulphation. No disulphate salt of chenodeoxycholic acid was detected. These findings lend support to the hypothesis that renal synthesis may account for some of the bile acid sulphates present in urine in the cholestatic syndrome in man.     

Hepatic microsomal glucuronidation of bilirubin in unilamellar liposomal membranes. Implications for intracellular transport of lipophilic substrates

It has been assumed that following hepatic uptake, bilirubin is bound exclusively to cytosolic proteins prior to conjugation by microsomal UDP-glucuronyl-transferase. Since bilirubin partitions into lipid rather than the aqueous phase at neutral pH, we postulated that bilirubin reaches the sites of glucuronidation by rapid diffusion within membranes. To examine this hypothesis, [14C]bilirubin was incorporated into the membrane bilayer of small unilamellar liposomes of egg phosphatidylcholine. Radiochemical assay of this membrane-bound substrate in a physiologic concentration, using native rat liver microsomes, demonstrated immediate formation of bilirubin glucuronides at a more rapid initial velocity than for bilirubin bound to the high-affinity sites of purified cytosolic binding proteins, i.e. glutathione S-transferases (p less than 0.025) or native liver cytosol (p less than 0.05). Kinetic analysis suggested that the mechanisms of substrate transfer from liposomal membranes and from purified glutathione S-transferases to microsomal UDP-glucuronyltransferase were similar. The exchange of 3H- and 14C-labeled bilirubin substrate between binding proteins and liposomal membranes was then investigated using Sepharose 4B chromatography. As the concentration of bilirubin was increased relative to that of protein, net transfer of substrate from the protein to the membrane pool was observed. These findings indicate that bilirubin is efficiently transported by membrane-membrane transfer to hepatic microsomes, where it undergoes rapid conjugation. Bilirubin entering hepatocytes may partition between membrane and cytosolic protein pools, but as intracellular bilirubin concentration increases, the membrane pool is likely to provide a greater proportion of the substrate for glucuronidation.     

The FKBP families of higher plants: Exploring the structures and functions of protein interaction specialists

The FK506-binding proteins (FKBPs) are known both as the receptors for immunosuppressant drugs and as prolyl isomerase (PPIase) enzymes that catalyse rotation of prolyl bonds. FKBPs are characterised by the inclusion of at least one FK506-binding domain (FKBd), the receptor site for proline and the active site for PPIase catalysis. The FKBPs form large and diverse families in most organisms, with the largest FKBP families occurring in higher plants. Plant FKBPs are molecular chaperones that interact with specific protein partners to regulate a diversity of cellular processes. Recent studies have found that plant FKBPs operate in intricate and coordinated mechanisms for regulating stress response and development processes, and discoveries of new interaction partners expand their cellular influences to gene expression and photosynthetic adaptations. This review presents an examination of the molecular and structural features and functional roles of the higher plant FKBP family within the context of these recent findings, and discusses the significance of domain conservation and variation for the development of a diverse, versatile and complex chaperone family.     

Subcellular distribution and regulation of hepatic bilirubin UDP-glucuronyltransferase

We have investigated the subcellular location and regulation of hepatic bilirubin UDP-glucuronyltransferase, which has been presumed to be located largely in the smooth endoplasmic reticulum. Purity of subcellular membrane fractions isolated from rat liver was assessed by electron microscopy and marker enzymes. Bilirubin UDP-glucuronyltransferase activity was measured by radiochemical assay using a physiologic concentration of [14C]bilirubin, and formation rates of bilirubin diglucuronide and monoglucuronides (C-8 and C-12 isomers) were determined. Activity of the enzyme was widely distributed in subcellular membranes, the majority being found in smooth and rough endoplasmic reticulum, with small amounts in nuclear envelope and Golgi membranes. No measurable activity was found in plasma membranes or in cytosol. Synthesis of bilirubin diglucuronide as a percentage of total conjugates and the ratio of C-8/C-12 bilirubin monoglucuronide isomers formed were comparable in all membranes, suggesting that the same enzyme is present in all locations. However, the regulation of bilirubin UDP-glucuronyltransferase activity differed among intracellular membranes; enzyme activity measured in the presence of the allosteric effector uridine 5'-diphospho-N-acetylglucosamine exhibited latency in smooth endoplasmic reticulum and Golgi membranes, but not in rough endoplasmic reticulum and nuclear envelope. Since rough membranes comprise 60% of hepatocyte endoplasmic reticulum and bilirubin UDP-glucuronyltransferase activity in vitro is maximal in this membrane fraction under presumed physiologic conditions, it is likely that the rough endoplasmic reticulum represents the major site of bilirubin glucuronidation in hepatocytes.     

The importance of temporal climate variability for spatial patterns in plant diversity

Spatial variation in absolute climatic conditions (means, maxima or minima) is widely acknowledged to play a fundamental role in controlling species diversity patterns. In contrast, while evidence is accumulating that variability around mean climatic conditions may also influence species coexistence and persistence, the importance of spatial variation in temporal climatic variability for species diversity is still largely unknown. We used a unique dataset capturing fine‐scale spatial heterogeneity in temperature variability across 2490 plots in southeast Australia to examine the comparative strength of absolute temperature and temperature variability in explaining spatial variation in plant diversity. Across all plots combined and in three of five forest types, temperature variability emerged as the better predictor of diversity. In all but one forest type, diversity also exhibited either a significant unimodal or positive linear correlation with temperature variability. This relationship is consistent with theory that predicts diversity will initially increase along a climate variability gradient due to temporal niche partitioning, but at an intermediary point, may decline as the risk of stochastic extinction exceeds competitive stabilization. These findings provide critical empirical evidence of a linkage between spatial variation in temporal climate variability and plant species diversity, and in light of changing climate variability regimes, highlight the need for ecologists to expand their purview beyond absolutes and averages.