Formation of novel C21-bile acids from cholesterol in the rat. Structure identification of the major Di- and trihydroxylated species

We recently showed that previously unknown di- and trihydroxylated C21-bile acids are major degradation products of sitosterol and campesterol in bile-fistulated female Wistar rats. Using a mixture of 4-14C- and 22-3H-labeled cholesterol it was shown that such C21-bile acids are formed also from cholesterol in amounts up to about 25% of the total formation of bile acids. The C21-bile acids were formed from labeled cholesterol also in perfused rat liver, demonstrating that the liver is the site of synthesis. The major trihydroxylated C21-bile acids in bile were identified, by means of mass spectrometry, NMR, stereospecific dehydrogenases, and reagents, as 5 beta-pregnan-3 alpha, 11 beta, 15 beta-triol-21-oic acid and 5 beta-pregnan-3 alpha, 11 beta, 15 alpha-triol-21-oic acid. The corresponding 11-oxo-isomers were also present. A minor trihydroxylated C21-bile acid was identified as 5 beta-pregnan-3 alpha, 11 beta, 16-triol-21-oic acid. The major dihydroxylated C21-bile acid was identified by the same means as 5 alpha-pregnan-3 alpha, 12 alpha-diol-21-oic acid. Male rats converted 4-14C-cholesterol into C21-bile acids less efficiently than did female rats. None of the C21-bile acids from male rats contained a 15-hydroxyl group. It is speculated that the novel C21-bile acids are formed both from cholesterol and from plant sterols by an initial hydroxylation at C21 followed by peroxisomal or mitochondrial beta-oxidation. The presence of a hydroxyl group at C15 may facilitate this reaction. The above formation of C21-bile acids shows that mammalian liver is able to degrade the side chain of cholesterol beyond the C24 stage, even in the absence of a blocking group at C24. C21-bile acids, or one of their precursors, are hydroxylated in the liver by a hitherto unknown 11 beta-hydroxylase. The possible physiological importance of the C21-bile acids is discussed.     

The posttranslationally modified C-terminal structure of bovine aortic smooth muscle rhoA p21

rhoA p21, a ras p21-like small GTP-binding protein, has the same C-terminal consensus motif of Cys-A-A-X (A is an aliphatic amino acid and X is any amino acid) as ras p21s, which is posttranslationally processed. We here determine the posttranslationally processed C-terminal structure of the rhoA p21 purified from bovine aortic smooth muscle. Incubation of rhoA p21-expressing insect cells with exogenous [3H]mevalonolactone caused the labeling of rhoA p21, suggesting that rhoA p21 is prenylated. Consistently, Raney nickel treatment of rhoA p21 released a geranylgeranyl moiety as estimated by gas chromatography/mass spectrometry. No lipid moiety was released by KOH or NH2OH treatment. Extensive digestion of rhoA p21 with Achromobacter protease I yielded a C-terminal peptide, Ser-Gly-Cys190, that lacked the three C-terminal amino acids predicted from the cDNA but was geranylgeranylated and carboxyl methylated at the cysteine residue. Bovine brain cytosol geranylgeranylated the bacterial rhoA p21 having the three C-terminal amino acids predicted from the cDNA but not the protein lacking the three C-terminal amino acids. Bovine brain membranes methylated the synthetic C-terminal peptide with 10 amino acids of rhoA p21 which was geranylgeranylated at its C-terminal cysteine residue but not the peptide which was not geranylgeranylated. These results suggest that rhoA p21 is first geranylgeranylated followed by removal of the three C-terminal amino acids and the subsequent carboxyl methylation of the exposed cysteine residue.     

Identification of a novel FGF, FGF-21, preferentially expressed in the liver

We isolated cDNA encoding a novel FGF (210 amino acids) from mouse embryos. As this is the 21st documented FGF, we tentatively term it FGF-21. FGF-21 has a hydrophobic amino terminus ( approximately 30 amino acids), which is a typical signal sequence, and appears to be a secreted protein. The expression of FGF-21 mRNA in mouse adult tissues was examined by Northern blotting analysis. FGF-21 mRNA was most abundantly expressed in the liver, and also expressed in the thymus at lower levels. We also isolated human cDNA encoding FGF-21 (209 amino acids). Human FGF-21 is highly identical ( approximately 75% amino acid identity) to mouse FGF-21. Among human FGF family members, FGF-21 is most similar ( approximately 35% amino acid identity) to FGF-19.     

玉米21kD富硫种子贮存蛋白的cDNA克隆及其序列分析

利用逆转录－聚合酶链式反应（ＲＴ－ＰＣＲ）方法从玉米掖单－２０开花后１０ｄ的叶片中分离到２１ｋＤ玉米种子贮存蛋白ｃＤＮＡ（Ｎ２１ＫＺＹ）,并进行了序列分析．其编码蛋白包含２１１个氨基酸,极其富含甲硫氨酸,高达２７％;其Ｎ端有一个２１个氨基酸的信号肽．Ｎ２１ＫＺＹ及其编码蛋白和Ｃｈｕｉ等人分离的该基因的基因组克隆及其编码蛋白的同源性分别为９５．１％和９０．５％;两者的编码蛋白与玉米１０ｋＤ醇溶蛋白极其相似,其中间多出一个５４氨基酸的肽段和一个６氨基酸的肽段,这表明它们可能是来源于同一个祖先基因,后来通过基因重排、缺失或不均等交换等过程而形成的不同的蛋白质．     

An improved method for the chemical synthesis of steroidal 20-oxo-21-oic acids

A procedure is described for the chemical synthesis of steroidal-20-oxo-21-oic acids and -17c(-hydroxy-20-oxo-21-oic acids. Corticosteroid derivatives containing the 20-oxo-21-aldehyde side chain are oxidized with freshly generated silver oxide in dilute aqueous sodium hydroxide.     

Identification of the active region of the DNA synthesis inhibitory gene p21Sdi1/CIP1/WAF1.

The cloning of the negative growth regulatory gene, p21Sdi1, has led to the convergence of the fields of cellular senescence, cell cycle regulation and tumor suppression. This gene was first cloned as an inhibitor of DNA synthesis that was overexpressed in terminally non-dividing senescent human fibroblasts (SD11) and later as a p53 transactivated gene (WAF1) and a Cdk-interacting protein (CIP1, p21) that inhibited cyclin-dependent kinase activity. To identify the active region(s) of p21Sdi1, cDNA constructs encoding various deleted forms of the protein were analyzed. Amino acids 22-71 were found to be the minimal region required for DNA synthesis inhibition. Amino acids 49-71 were involved in binding to Cdk2, and constructs deleted in this region expressed proteins that were unable to inhibit Cdk2 kinase activity in vitro. The latter stretch of amino acids shared sequence similarity with amino acids 60-76 of the p27Kip1 protein, another Cdk inhibitor. Point mutations made in p21Sdi1 in this region confirmed that amino acids common to both proteins were involved in DNA synthesis inhibition. Additionally, a chimeric protein, in which amino acids 49-65 of p21Sdi1 were substituted with amino acids 60-76 of p27Kip1, had almost the same DNA synthesis inhibitory activity as the wild-type protein. The results indicate that the region of sequence similarity between p21Sdi1 and p27Kip1 encodes an inhibitory motif characteristic of this family of Cdk inhibitors.     

The modulating action of amino acids upon development in an organotypic culture

The effect of L-amino acids in concentration 0.05 ng/ml was investigated in organotypic tissue culture of spleen, liver and brain cortex at the age of 1 and 21 days. The high molecular and low hydrophobic amino acids: asparagin, lysine, arginine, and glutamine, are active inducing both a less intensive growth zone in explants of all three tissue types in 1-day old rats and more intensive growth zone in spleen, liver explants in 21-day rats as compared to control. Another group of low molecular and high hydrophobic amino acids is active inducing a more intensive growth zone in brain cortex explant in 21-day rats, as compared to control. The data obtained suggest a modulating role of amino acids in the tissues at different stages of maturation.     

Characterization of the purified components of a new homologous series of alpha-mycolic acids from Mycobacterium tuberculosis H37Ra.

Homologous series of alpha-mycolic acids from Mycobacterium tuberculosis H37Ra were separated according to size as their p-bromophenacyl ester by bonded C18 reverse-phase, high performance liquid chromatography. Mass spectrometry of the prominent components separated by high performance liquid chromatography gave relatively simple spectra and showed a series of components differing by 28 atomic mass units. A total of different structures were identified. The structures were established as follow: (formula see text) where a = 17, 18, 19; b = 10; c = 15, 17, 19, 21; and d = 21, 23. The C76 and C78 acids contained some C24 alpha-branch acid (d - 21), whereas the C80 and C82 acids contained some a = 19 acids. Several new homologous series were revealed.     

Phosphorylation in the carboxyl-terminal domain of the capsid protein of hepatitis B virus: evaluation with a monoclonal antibody.

The capsid protein of hepatitis B virus (p21c) is made of 183 amino acids coded for by the C gene. By using p21c isolated from Dane particles (hepatitis B virus) as an immunogen, a monoclonal antibody (no. 2212) which recognized an epitope dependent on the phosphorylation of p21c was raised. The binding of no. 2212 antibody to authentic p21c was completely inhibited by a synthetic undecapeptide with a sequence of RRRSQSPRRRR, representing amino acids 165 to 175 of p21c, only when the peptide was phosphorylated. Either or both of Ser-168 and Ser-170 were phosphorylated in p21c in vivo, therefore, and contributed to the manifestation of the epitope. No. 2212 antibody bound to p21c from core particles derived from Dane particles or hepatocellular carcinoma tissues (PLC/342) propagated in nude mice but did not bind to p21c from core particles expressed in Escherichia coli or yeast cells, indicating different states of phosphorylation in them. Nonphosphorylated p21c showed a higher affinity for the viral DNA than did phosphorylated p21c. Since the serum from an asymptomatic carrier, with a high titer for antibody to hepatitis B core antigen, specifically bound to phosphorylated undecapeptide (amino acids 165 to 175), the epitope would stimulate humoral antibody responses in the human host.     

Inhibition of the action of the stimulatory GDP/GTP exchange protein for smg p21 by the geranylgeranylated synthetic peptides designed from its C-terminal region

smg p21B, a member of the ras p21-like small GTP-binding protein superfamily, undergoes post-translational modifications, which are geranylgeranylation of the cysteine residue in the C-terminal region followed by removal of the three C-terminal amino acids (QLL) and the subsequent carboxyl methylation of the exposed prenylated cysteine residue. smg p21B has a polybasic region upstream of the prenylated cysteine residue. We have previously proposed that these C-terminal structures of smg p21B are essential for the action of its stimulatory GDP/GTP exchange protein, named GDP dissociation stimulator (GDS). We studied here which structure of the C-terminal region of smg p21B is important for its interaction with smg p21 GDS. For this purpose, we synthesized a peptide according to the C-terminal structure of smg p21B, which was PGKARKKSSC-geranylgeranyl-carboxyl methyl, and its variously modified peptides and examined their ability to interact with smg p21 GDS and to interfere with the smg p21 GDS action to stimulate the GDP/GTP exchange reaction of smg p21B. The results indicate that the phosphorylated form of PGKARKKSSC-geranylgeranyl stoichiometrically interacts with smg p21 GDS, that the presence of the geranylgeranyl moiety is essential for, but not sufficient for, the smg p21 GDS action, and that the presence of the methyl moiety, removal of the three C-terminal amino acids, and the presence of the polybasic amino acids also affect the smg p21 GDS action. It is likely that all the steps of the post-translational processing and presence of the polybasic region in the C-terminal region of smg p21B are related to its interaction with smg p21 GDS.     

Preparation and characterization of 3-monohydroxylated bile acids of different side chain length and configuration at C-3. Novel approach to the synthesis of 24-norlithocholic acid

A series of 3-monohydroxylated bile acids, in unlabeled and radioactive form, of varying side chain length and configuration at C-3 has been synthesized and rigorously characterized. They include: 3 alpha- and 3 beta-hydroxy-5 beta-androstane-17 beta-carboxylic acids (C20); 3 alpha- and 3 beta-hydroxy-5 beta-pregnan-21-oic acids (C21); 3 alpha- and 3 beta-hydroxy-23,24-bisnor-5 beta-cholan-22-oic acids (C22); 3 alpha- and 3 beta-hydroxy-24-nor-5 beta-cholan-23-oic acids (C23, norlithocholic and isonorlithocholic acids); and 3 beta-hydroxy-5 beta-cholan-24-oic acid (C24, isolithocholic acid). A novel approach to the degradation of lithocholic acid acetate to 24-norlithocholic acid is described. This degradation involves the photochemical modification of a Hunsdiecker reaction and Kornblum oxidation of the intermediate 23-bromide. The availability of these compounds makes it possible to study the metabolism and biological effects of short chain bile acids.     

Large hepatitis delta antigen in packaging and replication inhibition: role of the carboxyl-terminal 19 amino acids and amino-terminal sequences.

Hepatitis delta virus (HDV) encodes two proteins, the small delta antigen (SHDAg) and large delta antigen (LHDAg). The latter is identical to the former except for the presence of additional 19 amino acids at the C terminus. While SHDAg is required for HDV replication, LHDAg inhibits replication and, together with hepatitis B surface antigen (HBsAg), is required for the assembly of HDV. The last 19 C-terminal amino acids of LHDAg are essential for HDV assembly. Most of LHDAg (amino acids 19 to 146 and 163 to 195) had been shown to be dispensable for packaging with HBsAg. To discern whether the last 19 C-terminal amino acids solely constitute the signal for packaging with HBsAg, we constructed two LHDAg deletion mutants and tested their abilities to be packaged with HBsAg in cotransfection experiments. We found that deletion of amino acids 2 to 21 and 142 to 165 did not affect LHDAg packaging. This result suggested that only the last 19 C-terminal amino acids of LHDAg are required for packaging. We further constructed two plasmids which expressed c-H-ras with or without additional 19 C-terminal amino acids identical to those in LHDAg. Only c-H-ras with additional 19 amino acids could be cosecreted with HBsAg in the cotransfection experiment. This result confirmed that the C-terminal 19 amino acids are the packaging signal for HBsAg. We also tested the trans activation activity and trans-dominant inhibitory activity of the deletion mutants of SHDAg and LHDAg, respectively. In contrast to deletion of amino acids 142 to 165, deletion of amino acids 2 to 21 impaired the trans-dominant inhibitory activity of LHDAg. Deletion of amino acids 2 to 21 and 142 to 165 did not affect the trans activation activity of SHDAg. This result suggested that a functional domain which is important for the trans-dominant inhibitory activity of LHDAg exists in the amino terminus of HDAg.     

Diet preferences of warblers for specific fatty acids in relation to nutritional requirements and digestive capabilities

During energy-demanding periods of the annual cycle such as migration or during cold days in winter, birds store fat comprised mostly of 16- or 18-carbon unsaturated fatty acids. In such situations, birds may feed selectively on foods with specific fatty acids that enable efficient fat deposition. We offered wild-caught yellow-rumped warblers Dendroica coronata paired choices between semi-synthetic diets that differed only in their fatty acid composition. Warblers strongly preferred diets containing long-chain (18:1; carbon atoms:double bonds) unsaturated, unesterified fatty acids to diets containing long-chain saturated, unesterified fatty acids (18:0) and they preferred diets containing mono-unsaturated fats (18:1) to diets containing poly-unsaturated fats (18:2). The preference for diets containing long-chain unsaturated fatty acids to diets containing long-chain saturated fatty acids was consistent in birds tested one week after capture at 21°C, one month after capture when cold-acclimated (1°C), and six weeks after capture at 21°C. Birds acclimated to a diet with 50% of the fat comprised of unesterified stearic acid (18:0) lost mass and reduced their food intake when we reduced ambient temperature from 21°C to 11°C over three days. We conclude that especially in energy-demanding situations there are limits to the yellow-rumped warblers' ability to assimilate some long-chain saturated fatty acids and that this digestive constraint can explain in part why yellow-rumped warblers prefer diets containing long-chain unsaturated fatty acids to diets containing long-chain saturated fatty acids.     

Aldehyde oxidoreductase as a biocatalyst: Reductions of vanillic acid

Aldehyde oxidoreductase (carboxylic acid reductase) catalyzes the Mg(2+), ATP and NADPH dependent reduction of carboxylic acids to their corresponding aldehydes. The identification of the gene from Nocardia sp. NRRL 5646 and its expression in E. coli BL21-CodonPlus(?)(DE3)-RP/pHAT305 provided an avenue to develop a biocatalyst for reduction of carboxylic acids. In addition to aromatic acids, the recombinant carboxylic acid reductase also accepts several aliphatic mono, di and tri carboxylic acids as substrates. A recently identified Nocardia sp., phosphopantetheinyl transferase gene (npt) enhanced the activity of carboxylic acid reductase. Coexpression of car and npt in E. coli BL21-CodonPlus(?)(DE3)-RP/pPV2.83 resulted in a purified recombinant carboxylic acid reductase with improved specific activity of 2.2U/mg protein. The utility of the recombinant carboxylic acid reductase as a biocatalyst has been demonstrated using vanillic acid as substrate. E. coli BL21-CodonPlus(?)(DE3)-RP/pHAT305 expressing Car reduced 50% of vanillic acid to vanillin in 10h. E. coli BL21-CodonPlus(?)(DE3)-RP/pPV2.83 resting cells expressing Car and Npt reduced 90% of vanillic acid to vanillin in 6h. Enhanced, in vivo cofactor NADPH regeneration by glucose dehydrogenase (gdh) was accomplished using E. coli BL21-CodonPlus(?)(DE3)-RP/pPV2.85, that carried car, npt, and gdh. Resting cell reactions using E. coli BL21-CodonPlus(?)(DE3)-RP/pPV2.85 with in situ product removal by XAD-2 resin efficiently reduced 5g/L of vanillic and benzoic acids within 2h.     

Structure-activity relationship between carboxylic acids and T cell cycle blockade

This study was designed to examine the potential structure-activity relationship between carboxylic acids, histone acetylation and T cell cycle blockade. Toward this goal a series of structural homologues of the short-chain carboxylic acid n-butyrate were studied for their ability to block the IL-2-stimulated proliferation of cloned CD4+ T cells. The carboxylic acids were also tested for their ability to inhibit histone deacetylation. In addition, Western blotting was used to examine the relative capacity of the carboxlic acids to upregulate the cyclin kinase-dependent inhibitor p21cip1 in T cells. As shown earlier n-butyrate effectively inhibited histone deacetylation. The increased acetylation induced by n-butyrate was associated with the upregulation of the cyclin-dependent kinase inhibitor p21cip1 and the cell cycle blockade of CD4+ T cells. Of the other carboxylic acids studied, the short chain acids, C3-C5, without branching were the best inhibitors of histone deacetylase. This inhibition correlated with increased expression of the cell cycle blocker p21cip1, and the associated suppression of CD4+ T cell proliferation. The branched-chain carboxylic acids tested were ineffective in all the assays. These results underline the relationship between the ability of a carboxylic acid to inhibit histone deacetylation, and their ability to block T cell proliferation, and suggests that branching inhibits these effects.     

氨基酸与生化药物

回顾中国氨基酸类药物的发展历程,并对２０００年后的发展提出意见。     

Studying the evolutionary relationships and phylogenetic trees of 21 groups of tRNA sequences based on complex networks

To find out the evolutionary relationships among different tRNA sequences of 21 amino acids, 22 networks are constructed. One is constructed from whole tRNAs, and the other 21 networks are constructed from the tRNAs which carry the same amino acids. A new method is proposed such that the alignment scores of any two amino acids groups are determined by the average degree and the average clustering coefficient of their networks. The anticodon feature of isolated tRNA and the phylogenetic trees of 21 group networks are discussed. We find that some isolated tRNA sequences in 21 networks still connect with other tRNAs outside their group, which reflects the fact that those tRNAs might evolve by intercrossing among these 21 groups. We also find that most anticodons among the same cluster are only one base different in the same sites when S ≥ 70, and they stay in the same rank in the ladder of evolutionary relationships. Those observations seem to agree on that some tRNAs might mutate from the same ancestor sequences based on point mutation mechanisms.     

Formation of C21 bile acids from plant sterols in the rat

Formation of bile acids from sitosterol in bile-fistulated female Wistar rats was studied with use of 4-14C-labeled sitosterol and sitosterol labeled with 3H in specific positions. The major part (about 75%) of the 14C radioactivity recovered as bile acids in bile after intravenous administration of [4-14C]sitosterol was found to be considerably more polar than cholic acid, and only trace amounts of radioactivity had chromatographic properties similar to those of cholic acid and chenodeoxycholic acid. It was shown that polar metabolites were formed by intermediate oxidation of the 3 beta-hydroxyl group (loss of 3H from 3 alpha-3H-labeled sitosterol) and that the most polar fraction did not contain a hydroxyl group at C7 (retention of 3H in 7 alpha,7 beta-3H2-labeled sitosterol). Furthermore, the polar metabolites had lost at least the terminal 6 or 7 carbon atoms of the side chain (loss of 3H from 22,23-3H2- and 24,28-3H2-labeled sitosterol). Experiments with 3H-labeled 7 alpha-hydroxysitosterol and 4-14C-labeled 26-hydroxysitosterol showed that none of these compounds was an efficient precursor to the polar metabolites. By analysis of purified most polar products of [4-14C] sitosterol by radio-gas chromatography and the same products of 7 alpha,7 beta-[2H2]sitosterol by combined gas chromatography-mass spectrometry, two major metabolites could be identified as C21 bile acids. One metabolite had three hydroxyl groups (3 alpha, 15, and unknown), and one had two hydroxyl groups (3 alpha, 15) and one keto group. Considerably less C21 bile acids were formed from [4-14C]sitosterol in male than in female Wistar rats. The C21 bile acids formed in male rats did not contain a 15-hydroxyl group. Conversion of a [4-14C]sitosterol into C21 bile acids did also occur in adrenalectomized and ovariectomized rats, indicating that endocrine tissues are not involved. Experiments with isolated perfused liver gave direct evidence that the overall conversion of sitosterol into C21 bile acids occurs in this organ. Intravenously injected 7 alpha,7 beta-3H-labeled campesterol gave a product pattern identical to that of 4-14C-labeled sitosterol. Possible mechanisms for hepatic conversion of sitosterol and campesterol into C21 bile acids are discussed.     

Identification of the nuclear localization signal of p21(cip1) and consequences of its mutation on cell proliferation

Overexpression of p21(cip1) induces cell cycle arrest. Although this ability has been correlated with its nuclear localization, the evidence is not conclusive. The mutants that were used to inhibit its nuclear translocation could no longer bind to several proteins known to interact with the last 25 amino acids of p21(cip1). Here we used point mutation analysis and fusion of the proteins to DsRed to identify which amino acids are essential for the nuclear localization of p21(cip1). We conclude that amino acids RKR(140-142) are essential for nuclear translocation of p21(cip1). While wild-type DsRed-p21 induces cell cycle arrest in 95% of transfected cells, overexpression of cytoplasmatic p21AAA(140-142) arrested only 20% of transfected cells. We conclude that cytoplasmatic p21, with no deletion in the C-terminal region, had a much lower capacity to arrest the cell cycle.