On the substrate specificity of human CYP27A1: implications for bile acid and cholestanol formation

The mitochondrial sterol 27-hydroxylase (CYP27A1) is required for degradation of the C27-sterol side chain in bile acid biosynthesis. CYP27A1 seems, however, to have roles beyond this, as illustrated by patients with a deficient sterol 27-hydroxylase due to mutations of the CYP27A1 gene [cerebrotendinous xanthomatosis (CTX)]. These subjects have symptoms ranging from accumulation of bile alcohols and cholestanol to accelerated atherosclerosis and progressive neurologic impairment. The present work describes a detailed investigation on the substrate specificity of recombinant human CYP27A1. In accordance with some previous work with rat liver mitochondria, the activity in general increased with the polarity of the substrate. An obvious example was the finding that cholesterol was 27-hydroxylated more efficiently than cholesterol oleate but less efficiently than cholesterol sulfate. The oxysterols 24S-hydroxycholesterol and 25-hydroxycholesterol were 27-hydroxylated less efficiently than cholesterol, possibly due to steric hindrance. Surprisingly, sterols with a 3-oxo-Delta4 structure were found to be hydroxylated at a much higher rate than the corresponding sterols with a 3beta-hydroxy-Delta5 structure. The rates of hydroxylation of the sterols were: 7alpha-hydroxy-4-cholesten-3-one>4-cholesten-3-one>7alpha-hydroxycholesterol>24-hydroxy-4-cholesten-3-one> cholesterol>25-hydroxy-4-cholesten-3-one>24-hydroxycholesterol>or=25-hydroxycholesterol. The possibility is discussed that the findings may have implications for oxysterol-mediated regulation of gene expression. The very high activity of CYP27A1 towards the cholestanol precursor 4-cholesten-3-one may be of importance in connection with the accumulation of cholestanol in patients with CTX.     

The atypical lipase B from Candida antarctica is better adapted for organic media than the typical lipase from Thermomyces lanuginosa

Candida antarctica lipase B (CALB) and Thermomyces lanuginosa lipase (TLL) were evaluated as catalysts in different reaction media using hydrolysis of tributyrin as model reaction. In o/w emulsions, the enzymes were used in the free form and for use in monophasic organic media, the lipases were adsorbed on porous polypropylene (Accurel EP-100). In monophasic organic media, the highest specific activity of both lipases was obtained in pure tributyrin at a water activity of >0.5 and at an enzyme loading of 10 mg/g support. With tributyrin emulsified in water, the specific activities were 2780 micromol min(-1) mg(-1) for TLL and 535 micromol min(-1) mg(-1) for CALB. Under optimal conditions in pure tributyrin, CALB expressed 49% of the activity in emulsion (264 micromol min(-1) mg(-1)) while TLL expressed only 9.2% (256 micromol min(-1) mg(-1)) of its activity in emulsion. This large decrease is probably due to the structure of TLL, which is a typical lipase with a large lid domain. Conversion between open and closed conformers of TLL involves large internal movements and catalysis probably requires more protein mobility in TLL than in CALB, which does not have a typical lid region. Furthermore, TLL lost more activity than CALB when the water activity was reduced below 0.5, which could be due to further reduction in protein mobility.     

Grafting of features of cystatins C or B into the N-terminal region or second binding loop of cystatin A (stefin A) substantially enhances inhibition of cysteine proteinases

Replacement of the three N-terminal residues preceding the conserved Gly of cystatin A by the corresponding 10-residue long segment of cystatin C increased the affinity of the inhibitor for the major lysosomal cysteine proteinase, cathepsin B, by approximately 15-fold. This tighter binding was predominantly due to a higher overall association rate constant. Characterization of the interaction with an inactive Cys29 to Ala variant of cathepsin B indicated that the higher rate constant was a result of an increased ability of the N-terminal region of the chimeric inhibitor to promote displacement of the cathepsin B occluding loop in the second binding step. The low dissociation rate constant for the binding of cystatin A to cathepsin B was retained by the chimeric inhibitor, which therefore had a higher affinity for this enzyme than any natural cystatin identified so far. In contrast, the N-terminal substitution negligibly affected the ability of cystatin A to inhibit papain. However, substitutions of Gly75 in the second binding loop of cystatin A by Trp or His, making the loop similar to those of cystatins C or B, respectively, increased the affinity for papain by approximately 10-fold. This enhanced affinity was due to both a higher association rate constant and a lower dissociation rate constant. Modeling of complexes between the two variants and papain indicated the possibility of favorable interactions being established between the substituting residues and the enzyme. The second-loop substitutions negligibly affected or moderately reduced the affinity for cathepsin B. Together, these results show that the inhibitory ability of cystatins can be substantially improved by protein engineering.     

Broad substrate specificity of human cytochrome P450 46A1 which initiates cholesterol degradation in the brain

The known activity of cytochrome P450 46A1 (P450 46A1) is 24(S)-hydroxylation of cholesterol. This reaction produces biologically active oxysterol, 24(S)-hydroxycholesterol, and is also the first step in enzymatic degradation of cholesterol in the brain. We report here that P450 46A1 can further metabolize 24(S)-hydroxycholesterol, giving 24,25- and 24,27-dihydroxycholesterols in both the cell cultures transfected with P450 46A1 cDNA and the in vitro reconstituted system with recombinant enzyme. In addition, P450 46A1 was able to carry out side chain hydroxylations of two endogenous C27-steroids with and without a double bond between C5-C6 (7alpha-hydroxycholesterol and cholestanol, respectively) and introduce a hydroxyl group on the steroid nucleus of the C21-steroid hormones with the C4-C5 double bond (progesterone and testosterone). Also, P450 46A1 was found to metabolize xenobiotics carrying out dextromethorphan O- and N-demethylations, diclofenac 4'-hydroxylation, and phenacetin O-deethylation. Thus, substrate specificities of P450 46A1 are not limited to cholesterol and include a number of structurally diverse compounds. Activities of P450 46A1 suggest that, in addition to the involvement in cholesterol homeostasis in the brain, this enzyme may participate in metabolism of neurosteroids and drugs that can cross the blood-brain barrier and are targeted to the central nervous system.     

Linker histone subtype composition and affinity for chromatin in situ in nucleated mature erythrocytes

The replacement linker histones H1(0) and H5 are present in frog and chicken erythrocytes, respectively, and their accumulation coincides with cessation of proliferation and compaction of chromatin. These cells have been analyzed for the affinity of linker histones for chromatin with cytochemical and biochemical methods. Our results show a stronger association between linker histones and chromatin in chicken erythrocyte nuclei than in frog erythrocyte nuclei. Analyses of linker histones from chicken erythrocytes using capillary electrophoresis showed H5 to be the subtype strongest associated with chromatin. The corresponding analyses of frog erythrocyte linker histones using reverse-phase high performance liquid chromatography showed that H1(0) dissociated from chromatin at somewhat higher ionic strength than the three additional subtypes present in frog blood but at lower ionic strength than chicken H5. Which of the two H1(0) variants in frog is expressed in erythrocytes has thus far been unknown. Amino acid sequencing showed that H1(0)-2 is the only H1(0) subtype present in frog erythrocytes and that it is 100% acetylated at its N termini. In conclusion, our results show differences between frog and chicken linker histone affinity for chromatin probably caused by the specific subtype composition present in each cell type. Our data also indicate a lack of correlation between linker histone affinity and chromatin condensation.     

Oxysterols in human circulation: which role do they have?

Oxysterols are oxygenated derivatives of cholesterol that are intermediates in cholesterol excretion pathways. They may also be regarded as transport forms of cholesterol and introduction of an additional hydroxyl group facilitates flux of cholesterol across cell membranes and the blood-brain barrier. According to current concepts, oxysterols are also mediating a number of cholesterol-induced metabolic effects. The recent discovery of nuclear receptors with an affinity for oxysterols has given support to this concept. Nuclear receptors such as liver X receptor alpha do have a role in cholesterol homeostasis, but there is still only indirect evidence that oxysterols are the physiological ligands. In this overview we report some recent advancements in our knowledge about the origin and metabolic fate of the quantitatively most important oxysterols occurring in the circulation. In addition, we discuss the possibility that some of these oxysterols may activate liver X receptors and regulate cholesterol homeostasis.     

Synthesis of potential thrombin inhibitors. Incorporation of tartaric acid templates as P2 proline mimetics

With the objective to prepare novel non-peptidic thrombin inhibitors, bioisosteres of the inhibitory tripeptide D-Phe-Pro-Arg chain have been examined. Thus, the P1 Arg was replaced with p-amidinobenzylamine, an elongated homologue of the same and with 2,5-dichloro benzylamine. The P2-P3, D-Phe-Pro, was replaced with a novel tartaric acid template coupled to a series of readily available, mainly lipophilic, amines. Some of these compounds exhibit promising thrombin inhibition activity in vitro, IC(50 ) approximately 5.9 microM.     

Microplate based biosensing with a computer screen aided technique

Melanophores, dark pigment cells from the frog Xenopus laevis, have the ability to change light absorbance upon stimulation by different biological agents. Hormone exposure (e.g. melatonin or alpha-melanocyte stimulating hormone) has been used here as a reversible stimulus to test a new compact microplate reading platform. As an application, the detection of the asthma drug formoterol in blood plasma samples is demonstrated. The present system utilizes a computer screen as a (programmable) large area light source, and a standard web camera as recording media enabling even kinetic microplate reading with a versatile and broadly available platform, which suffices to evaluate numerous bioassays. Especially in the context of point of care testing or self testing applications these possibilities become advantageous compared with highly dedicated comparatively expensive commercial systems.     

Buffering Capacity and Membrane H+ Conductance of Neutrophilic and Alkalophilic Gram-Positive Bacteria

Buffering capacity and membrane H⁺ conductance were examined in three gram-positive bacteria, Staphylococcus aureus, Bacillus subtilis, and Bacillus alcalophilus. An acid pulse technique was used to measure both parameters. The buffering capacity and membrane H⁺ conductance of B. alcalophilus are influenced by the pH of the medium and the culture conditions. Suspensions of B. alcalophilus cells from both H. A. medium and l-malate medium cultures grown at pH 10.5 exhibited higher values for these parameters than cells grown at pH 8.5. B. alcalophilus grown aerobically had a lower buffering capacity and a lower membrane conductance for protons than the neutrophilic bacteria S. aureus and B. subtilis. Fermenting cells exhibited significantly higher values for both variables than respiring cells.Most microorganisms are neutrophiles, since they survive only at pH values ranging from 5 to 8.5 and exhibit maximum growth rates at pH 7.4 (24). There is, however, a diverse group of bacteria that thrive in highly alkaline environments (11). Bacillus alcalophilus is an obligate alkalophile that can grow at pH values ranging from 8.5 to 11.5, and optimum growth occurs at pH 10.6 (12). It has been suggested that the obligate alkalophiles fail to grow at neutral pH because their membranes become leaky (2). In addition, Krulwich et al. (13) encountered difficulties when they measured the buffering capacities (as determined with suspensions of cells permeabilized with Triton X-100 or n-butanol) of two alkalophilic bacteria, B. alcalophilus and Bacillus firmus RAB, at pH values below 6.5 due to loss of cell integrity.The work presented here is the last part of an extensive study of the buffering capacity and membrane H⁺ conductance of gram-negative and gram-positive bacteria (17–22). We used a method in which the decay of an acid pulse is used to determine both parameters (15). By using this approach, we avoided the technical problems of the method involving permeabilizing cells, as described by Krulwich et al. (13). Here we report buffering capacity and membrane H⁺ conductance values for the following gram-positive bacteria: two mesophilic neutrophiles, Staphylococcus aureus and Bacillus subtilis, and the obligately alkalophilic bacillus B. alcalophilus. We measured both parameters in B. alcalophilus cells grown in two media at pH 8.5 and 10.5.