A new type of a multifunctional beta-oxidation enzyme in euglena

The biochemical and molecular properties of the beta-oxidation enzymes from algae have not been investigated yet. The present study provides such data for the phylogenetically old alga Euglena (Euglena gracilis). A novel multifunctional beta-oxidation complex was purified to homogeneity by ammonium sulfate precipitation, density gradient centrifugation, and ion-exchange chromatography. Monospecific antibodies used in immunocytochemical experiments revealed that the enzyme is located in mitochondria. The enzyme complex is composed of 3-hydroxyacyl-coenzyme A (-CoA) dehydrogenase, 2-enoyl-CoA hydratase, thiolase, and epimerase activities. The purified enzyme exhibits a native molecular mass of about 460 kD, consisting of 45.5-, 44.5-, 34-, and 32-kD subunits. Subunits dissociated from the complete complex revealed that the hydratase and the thiolase functions are located on the large subunits, whereas two dehydrogenase functions are located on the two smaller subunits. Epimerase activity was only measurable in the complete enzyme complex. From the use of stereoisomers and sequence data, it was concluded that the 2-enoyl-CoA hydratase catalyzes the formation of L-hydroxyacyl CoA isomers and that both of the different 3-hydroxyacyl-CoA dehydrogenase functions on the 32- and 34-kD subunits are specific to L-isomers as substrates, respectively. All of these data suggest that the Euglena enzyme belongs to the family of beta-oxidation enzymes that degrade acyl-CoAs via L-isomers and that it is composed of subunits comparable with subunits of monofunctional beta-oxidation enzymes. It is concluded that the Euglena enzyme phylogenetically developed from monospecific enzymes in archeons by non-covalent combination of subunits and presents an additional line for the evolutionary development of multifunctional beta-oxidation enzymes.     

Photoaffinity Labeling of Developing Jojoba Seed Microsomal Membranes with a Photoreactive Analog of Acyl-Coenzyme A (Acyl-CoA) (Identification of a Putative Acyl-CoA:Fatty Alcohol Acyltransferase

Jojoba (Simmondsia chinensis, Link) is the only plant known that synthesizes liquid wax. The final step in liquid wax biosynthesis is catalyzed by an integral membrane enzyme, fatty acyl-coenzyme A (CoA):fatty alcohol acyltransferase, which transfers an acyl chain from acyl-CoA to a fatty alcohol to form the wax ester. To purify the acyltransferase, we have labeled the enzyme with a radioiodinated, photoreactive analog of acyl-CoA, 12-[N-(4-azidosalicyl)amino] dodecanoyl-CoA (ASD-CoA). This molecule acts as an inhibitor of acyltransferase activity in the dark and as an irreversible inhibitor upon exposure to ultraviolet light. Oleoyl-CoA protects enzymatic activity in a concentration-dependent manner. Photolysis of microsomal membranes with labeled ASD-CoA resulted in strong labeling of two polypeptides of 57 and 52 kD. Increasing concentrations of oleoyl-CoA reduced the labeling of the 57-kD polypeptide dramatically, whereas the labeling of the 52-kD polypeptide was much less responsive to oleoyl-CoA. Also, unlike the other polypeptide, the labeling of the 57-kD polypeptide was enhanced considerably when photolyzed in the presence of dodecanol. These results suggest that a 57-kD polypeptide from jojoba microsomes may be the acyl-CoA:fatty alcohol acyltransferase.     

Expression of Dictyostelium myosin tail segments in Escherichia coli: domains required for assembly and phosphorylation

The assembly of myosins into filaments is a property common to all conventional myosins. The ability of myosins to form filaments is conferred by the tail of the large asymmetric molecule. We are studying cloned portions of the Dictyostelium myosin gene expressed in Escherichia coli to investigate functional properties of defined segments of the myosin tail. We have focused on five segments derived from the 68-kD carboxyl-terminus of the myosin tail. These have been expressed and purified to homogeneity from E. coli, and thus the boundaries of each segment within the myosin gene and protein sequence are known. We identified an internal 34-kD segment of the tail, N-LMM-34, which is required and sufficient for assembly. This 287-amino acid domain represents the smallest tail segment purified from any myosin that is capable of forming highly ordered paracrystals characteristic of myosin. Because the assembly of Dictyostelium myosin can be regulated by phosphorylation of the heavy chain, we have studied the in vitro phosphorylation of the expressed tail segments. We have determined which segments are phosphorylated to a high level by a Dictyostelium myosin heavy chain kinase purified from developed cells. While LMM-68, the 68-kD carboxyl terminus of Dictyostelium myosin, or LMM-58, which lacks the 10-kD carboxyl terminus of LMM-68, are phosphorylated to the same extent as purified myosin, subdomains of these segments do not serve as efficient substrates for the kinase. Thus LMM-58 is one minimal substrate for efficient phosphorylation by the myosin heavy chain kinase purified from developed cells. Taken together these results identify two functional domains in Dictyostelium myosin: a 34-kD assembly domain bounded by amino acids 1533-1819 within the myosin sequence and a larger 58-kD phosphorylation domain bounded by amino acids 1533-2034 within the myosin sequence.     

Acetylation of 13-sophorosyloxydocosanoic acid by an acetyltransferase purified from Candida bogoriensis.

Acetyl-coenzyme A: 13-sophorosyloxydocosanoic acid (Glc2HDA) acetyltransferase was purified 14-fold in low yield from Candida bogoriensis cells. The enzyme catalyzes acetylation of the 6' and 6" positions of the sophorosyl group, producing the 13-[2'-O-beta-D-glucopyranosyl-beta-D-glucopyranosyloxy]-docosanoic acid 6',6"-diacetate (Ac2Glc2HDA) and monoacetate (AcGlc2HDA) in a product ratio of 5:1. Neither the purification steps nor heat denaturation studies indicated separation of the first and second acetylation steps. The acetyltransferase has a molecular weight of about 500,000 as determined by gel filtration on a Sepharose 4-B column. It shows a pH optimum range from 7 to 9, is strongly inhibited by 1 mM concentrations of the sulfhydryl reagents N-ethylmaleimide, p-hydroxymercuribenzoate, and 5,5'-dithiobis(2-nitrobenzoic acid), but only partly inhibited by 10 mM iodoacetamide. It has an apparent Km of 30 muM for acetyl-CoA, utilizes propionyl-CoA at 45% the rate of acetyl-CoA, and utilizes longer chain acyl-CoA derivatives much less efficiently. The critical micelle concentrations of the C. bogoriensis glycolipids in pH 7.7 phosphate buffer were estimated by pinacyanol chloride binding as follows: Glc2HDA, 50 mum; AcGlc2HDA, 30 muM; Ac2Glc2HDA, 12 muM. The Stokes radius of Ac2Glc2HDA micelles was 22 A as estimated by gel filtration on Bio-Gel P-150. Glc2HDA was a much better acceptor than its methyl ester in the acetyltransferase assay. A plateau in the Glc2HDA saturation curve at 50 muM and a corresponding break in the reciprocal plot at this concentration indicate the enzyme utilizes the monomeric form of this lipid as substrate.     

Glucose deprivation and hexose transporter polypeptides of murine fibroblasts

The effect of Glc deprivation (starvation) on hexose transporter (GT) polypeptide(s) (pp) was studied in 3T3-C2 murine fibroblasts. Cells deprived of Glc exhibit 5-fold increases in hexose transport and Glc-displaceable cytochalasin B binding. Immunoblots of membranes reveal a Mr 55,000 GT pp in fed (4 g of Glc/liter) cells and Mr 55,000 and Mr 42,000 GT pp in starved cells. A 10-40-fold increase in total GT pp occurs upon Glc deprivation; part of this accumulation (2-5-fold) is in the Mr 55,000 GT pp, and the remaining increase is in the Mr 42,000 GT pp. During the first 12 h of Glc deprivation only the Mr 55,000 GT pp accumulates. At later times (24-72 h) the Mr 42,000 GT pp appears and constitutes a larger fraction of the total accumulation. Similarly, the Glc concentration dependence of these phenomena reveals that the Mr 55,000 GT pp accumulates at higher concentrations of Glc (less than or equal to g/liter) than the Mr 42,000 GT pp (less than or equal to 0.5 g/liter). Using alternative nutrients, sugar analogs, and inhibitors we observed that the accumulation of total GT pp is dependent upon both hexose phosphate metabolism and the interaction of substrate with the GT. The role(s) of oligosaccharide biosynthesis, protein synthesis, and the transport process itself in the Glc deprivation-induced accumulation of GT pp were examined. The appearance of the Mr 42,000 GT pp but not the Mr 55,000 GT pp was dependent upon protein synthesis. The Glc deprivation-induced accumulation of GT pp is reversible upon refeeding with Glc (4 g/liter, 12 h). This reversal was dependent upon protein synthesis. The electrophoretic mobility of the Mr 42,000 GT pp is similar to the GT pp observed after tunicamycin treatment. The Mr 55,000 but not the Mr 42,000 GT pp binds specifically to agarose-bound wheat germ agglutinin and is sensitive to endoglycosidase F digestion. Oligosaccharide-stripped GT pp and the Mr 42,000 GT pp have the same Mr. The results suggest that the accumulation of total GT pp induced by Glc deprivation is partially independent of the effect of Glc deprivation on glycoprotein biogenesis. The appearance of the Mr 42,000 GT pp with aglyco characteristics is the result of the latter. The accumulation of total GT pp, however, is the result of a specialized and sensitive adaptation of the cell to Glc deprivation. The GT pp synthesized during chronic Glc deprivation has an Mr of 42,000; fed cells synthesize the Mr 55,000 GT pp. Neither the level of in vitro translatable GT mRNA nor the rate of GT pp synthesis are increased by Glc deprivation.(ABSTRACT TRUNCATED AT 400 WORDS)     

Purification and properties of rat liver globotriaosylceramide synthase, UDP-galactose:lactosylceramide alpha 1-4-galactosyltransferase

The enzyme which catalyzes the transfer of galactose from UDP-galactose to lactosylceramide (LacCer) was obtained in a 32,000-fold purified and apparently homogeneous form from rat liver by a procedure involving affinity chromatography on UDP-hexanolamine-Sepharose and LacCer-Sepharose. The enzyme is composed of two nonidentical subunits whose apparent molecular weights are 65,000 and 22,000. Methylation and hydrolysis of the product formed by incubation of the enzyme with UDP-galactose and [3H]LacCer yielded 2,3,6-tri-O-methyl-[3H]galactose, indicating that a galactose residue was introduced to position C-4 of the terminal galactose of the LacCer. The product also specifically reacted with monoclonal antibody directed to globotriaosylceramide (Gal alpha 1-4Gal beta 1-4Glc beta 1-1Cer). This indicates that the purified enzyme is exclusively alpha 1-4-galactosyltransferase. Studies on substrate specificity indicate that the purified enzyme is highly specific for the synthesis of GbOse3Cer and is clearly distinct from the enzymes responsible for the formation of iGbOse3Cer (Gal alpha 1-3Gal beta 1-4Glc-Cer) and blood group-B substance, which possess alpha 1-3 galactosidic linkages at the nonreducing termini. The enzyme is also distinct from the alpha 1-4-galactosyltransferase which catalyzes the formation of galabiaosylceramide (Gal alpha 1-4Gal beta 1-1Cer) and IV4Gal-nLacOse4 (P1 antigen). These studies represent the first report of the properties of a highly purified alpha-galactosyltransferase catalyzing the transfer of sugar residues to glycolipids.     

Molecular and Biochemical Characterization of Cytosolic Phosphoglucomutase in Maize : Expression during Development and in Response to Oxygen Deprivation

Phosphoglucomutase (PGM) catalyzes the interconversion of glucose (Glc)-1- and Glc-6-phosphate in the synthesis and consumption of sucrose. We isolated two maize (Zea mays L.) cDNAs that encode PGM with 98.5% identity in their deduced amino acid sequence. Southern-blot analysis with genomic DNA from lines with different Pgm1 and Pgm2 genotypes suggested that the cDNAs encode the two known cytosolic PGM isozymes, PGM1 and PGM2. The cytosolic PGMs of maize are distinct from a plastidic PGM of spinach (Spinacia oleracea). The deduced amino acid sequences of the cytosolic PGMs contain the conserved phosphate-transfer catalytic center and the metal-ion-binding site of known prokaryotic and eukaryotic PGMs. PGM mRNA was detectable by RNA-blot analysis in all tissues and organs examined except silk. A reduction in PGM mRNA accumulation was detected in roots deprived of O₂ for 24 h, along with reduced synthesis of a PGM identified as a 67-kD phosphoprotein on two-dimensional gels. Therefore, PGM is not one of the so-called “anaerobic polypeptides.” Nevertheless, the specific activity of PGM was not significantly affected in roots deprived of O₂ for 24 h. We propose that PGM is a stable protein and that existing levels are sufficient to maintain the flux of Glc-1-phosphate into glycolysis under O₂ deprivation.     

Effects of mutation of Asn694 in Aspergillus niger α-glucosidase on hydrolysis and transglucosylation

Aspergillus niger α-glucosidase (ANG), a member of glycoside hydrolase family 31, catalyzes hydrolysis of α-glucosidic linkages at the non-reducing end. In the presence of high concentrations of maltose, the enzyme also catalyzes the formation of α-(1→6)-glucosyl products by transglucosylation and it is used for production of the industrially useful panose and isomaltooligosaccharides. The initial transglucosylation by wild-type ANG in the presence of 100 mM maltose [Glc(α1–4)Glc] yields both α-(1→6)- and α-(1→4)-glucosidic linkages, the latter constituting ~25% of the total transfer reaction product. The maltotriose [Glc(α1–4)Glc(α1–4)Glc], α-(1→4)-glucosyl product disappears quickly, whereas the α-(1→6)-glucosyl products panose [Glc(α1–6)Glc(α1–4)Glc], isomaltose [Glc(α1–6)Glc], and isomaltotriose [Glc(α1–6)Glc(α1–6)Glc] accumulate. To modify the transglucosylation properties of ANG, residue Asn694, which was predicted to be involved in formation of the plus subsites of ANG, was replaced with Ala, Leu, Phe, and Trp. Except for N694A, the mutations enhanced the initial velocity of the α-(1→4)-transfer reaction to produce maltotriose, which was then degraded at a rate similar to that by wild-type ANG. With increasing reaction time, N694F and N694W mutations led to the accumulation of larger amounts of isomaltose and isomaltotriose than achieved with the wild-type enzyme. In the final stage of the reaction, the major product was panose (N694A and N694L) or isomaltose (N694F and N694W).

     

Glucose phosphorylation is not rate limiting for accumulation of glycogen from glucose in perfused livers from fasted rats

Incorporation of Glc and Fru into glycogen was measured in perfused livers from 24-h fasted rats using [6-3H]Glc and [U-14C]Fru. For the initial 20 min, livers were perfused with low Glc (2 mM) to deplete hepatic glycogen and were perfused for the following 30 min with various combinations of Glc and Fru. With constant Fru (2 mM), increasing perfusate Glc increased the relative contribution of Glc carbons to glycogen (7.2 +/- 0.4, 34.9 +/- 2.8, and 59.1 +/- 2.7% at 2, 10, and 20 mM Glc, respectively; n = 5 for each). During perfusion with substrate levels seen during refeeding (10 mM Glc, 1.8 mumol/g/min gluconeogenic flux from 2 mM Fru), Fru provided 54.7 +/- 2.7% of the carbons for glycogen, while Glc provided only 34.9 +/- 2.8%, consistent with in vivo estimations. However, the estimated rate of Glc phosphorylation was at least 1.10 +/- 0.11 mumol/g/min, which exceeded by at least 4-fold the glycogen accumulation rate (0.28 +/- 0.04 mumol of glucose/g/min). The total rate of glucose 6-phosphate supply via Glc phosphorylation and gluconeogenesis (2.9 mumol/g/min) exceeded reported in vivo rates of glycogen accumulation during refeeding. Thus, in perfused livers of 24-h fasted rats there is an apparent redundancy in glucose 6-phosphate supply. These results suggest that the rate-limiting step for hepatic glycogen accumulation during refeeding is located between glucose 6-phosphate and glycogen, rather than at the step of Glc phosphorylation or in the gluconeogenic pathway.     

Functional size of acyl coenzyme A:diacylglycerol acyltransferase by radiation inactivation

Rat liver acyl coenzyme A:diacylglycerol acyltransferase, an intrinsic membrane activity associated with the endoplasmic reticulum, catalyzes the terminal and rate-limiting step in triglyceride synthesis. This enzyme has never been purified nor has its gene been isolated. Inactivation by ionizing radiation and target analysis were used to determine its functional size in situ. Monoexponential radiation inactivation curves were obtained which indicated that a single-sized unit of 72 +/- 4 kDa is required for expression of activity. The size corresponds only to the protein portion of the target and may represent one or several polypeptides.     

Activity and crystal structure of Arabidopsis thaliana UDP-N-acetylglucosamine acyltransferase

The UDP-N-acetylglucosamine (UDP-GlcNAc) acyltransferase, encoded by lpxA, catalyzes the first step of lipid A biosynthesis in Gram-negative bacteria, the (R)-3-hydroxyacyl-ACP-dependent acylation of the 3-OH group of UDP-GlcNAc. Recently, we demonstrated that the Arabidopsis thaliana orthologs of six enzymes of the bacterial lipid A pathway produce lipid A precursors with structures similar to those of Escherichia coli lipid A precursors [Li, C., et al. (2011) Proc. Natl. Acad. Sci. U.S.A. 108, 11387-11392]. To build upon this finding, we have cloned, purified, and determined the crystal structure of the A. thaliana LpxA ortholog (AtLpxA) to 2.1 ? resolution. The overall structure of AtLpxA is very similar to that of E. coli LpxA (EcLpxA) with an α-helical-rich C-terminus and characteristic N-terminal left-handed parallel β-helix (LβH). All key catalytic and chain length-determining residues of EcLpxA are conserved in AtLpxA; however, AtLpxA has an additional coil and loop added to the LβH not seen in EcLpxA. Consistent with the similarities between the two structures, purified AtLpxA catalyzes the same reaction as EcLpxA. In addition, A. thaliana lpxA complements an E. coli mutant lacking the chromosomal lpxA and promotes the synthesis of lipid A in vivo similar to the lipid A produced in the presence of E. coli lpxA. This work shows that AtLpxA is a functional UDP-GlcNAc acyltransferase that is able to catalyze the same reaction as EcLpxA and supports the hypothesis that lipid A molecules are biosynthesized in Arabidopsis and other plants.     

N-acetylglucosamine-6-O-sulfotransferase-1: production in the baculovirus system and its applications to the synthesis of a sulfated oligosaccharide and to the modification of oligosaccharides in fibrinogen

N-acetylglucosamine-6-O-sulfotransferase (GlcNAc6ST) catalyzes the transfer of sulfate from 3'-phosphoadenosine 5'-phosphosulfate to the C-6 position of non-reducing GlcNAc. Human GlcNAc6ST-1 was expressed as a fusion protein with protein A in an insect cell line (Tn 5 cells) using the baculovirus system. The recombinant enzyme was purified to homogeneity by IgG Sepharose column chromatography. The substrate specificity and the kinetic properties of the enzyme were similar to those of the enzyme expressed in the mammalian system. The purified recombinant enzyme was used to synthesize 6-sulfo GlcNAcbeta1-3Galbeta1-4Glc, which was identified by time of flight mass spectrometry. This sulfated trisaccharide served as a better substrate for microsomal galactosyltransferase from the mouse colon compared to 6-sulfo GlcNAc. The purified recombinant enzyme was also used to sulfate oligosaccharide chains on fibrinogen after enzymatic desialylation and degalactosylation to expose nonreducing GlcNAc residues. It is known that desialylation greatly increases the rate of clotting of fibrinogen after the addition of thrombin. Subsequent sulfation of desialylated and degalactosylated fibrinogen slightly decreased the rate of clotting. The recombinant GlcNAc6ST-1 is a useful reagent for 6-sulfate exposed GlcNAc residues both in oligosaccharides and in glycoproteins.     

Glycolipid transfer protein from pig brain transfers glycolipids with beta-linked sugars but not with alpha-linked sugars at the sugar-lipid linkage

The glycolipid transfer protein purified from pig brain facilitates the transfer of various glycosphingolipids and glyceroglycolipids (Yamada, K., Abe, A. and Sasaki, T. (1985) J. Biol. Chem. 260, 4615-4621). In this paper, the transfer of Man beta 1----4Glc beta 1-Cer and Man alpha 1----4Man beta 1-Cer isolated from a bivalve, Corbicula japonica, the transfer of 3-[Glc alpha 1-]-sn-1,2-diacylglycerol and 3-[Glc alpha 1----2Glc alpha 1-]-sn-1,2-diacylglycerol prepared from Streptococcus lactis, and the transfer of 3-[Glc beta 1-]-rac-1,2-dipalmitylglycerol have been investigated. The transfer of these lipids from liposomes to mitochondria was assayed by the decrease of these lipids in the donor liposomes. These lipids were determined by chromatographic isolation of the lipids, acid hydrolysis of the isolated lipids, and subsequent determination of glucose in the hydrolysate. The glycolipid transfer protein facilitated the transfer of ManGlcCer and ManManGlcCer. The transfer protein did not facilitate the transfer of Glc alpha-diacylglycerol or Glc alpha Glc alpha-diacylglycerol. However, the transfer of Glc beta-dipalmitylglycerol was facilitated by the protein. These results strongly suggest that the glycolipid transfer protein has the specificity to the presence of beta-linked glucose or galactose directly linked to either ceramide or diacylglycerol.     

Solubilization and properties of UDP-D-glucose:N-acetylglucosaminyl pyrophosphorylundecaprenol glucosyltransferase from Bacillus coagulans AHU 1366 membranes

The glucosyltransferase which catalyzes the conversion of GlcNAc-PP-undecaprenol into Glc(beta 1----4)GlcNAc-PP-undecaprenol in the presence of UDP-glucose was solubilized from Bacillus coagulans AHU 1366 membranes by treatment with 0.1% Triton X-100 and partially purified by means of column chromatography on Sephacryl S-300 and DEAE-Sephacel. The final preparation was virtually free from other enzymes involved in the de novo synthesis of teichoic acid. The enzyme had a pH optimum of 6.6-8.0 and a Km value for UDP-glucose of 21 microM. The enzyme required 40 mM MgCl2, 0.6 M KCl, and 0.1% Nonidet P-40 for full activity.     

Identification of a 34-kD polypeptide as a light chain of microtubule- associated protein-1 (MAP-1) and its association with a MAP-1 peptide that binds to microtubules

We examined the association of a 34-kD light chain component to the heavy chains of MAP-1 using a monoclonal antibody that specifically binds the 34-kD component and labels neuronal microtubules in a specific and saturable manner. Immunoprecipitation of MAP-1 heavy chains together with the 34-kD component by the antibody indicates that the 34-kD polypeptide forms a complex with MAP-1 heavy chains. Both major isoforms of MAP-1 heavy chains (MAP-1A and MAP-1B) were found in the immunoprecipitate. Digestion of MAP-1 with alpha-chymotrypsin and analysis of the chymotryptic peptides reveals a 120-kD fragment of the MAP-1 heavy chain that binds to microtubules and is precipitable with the 34-kD light chain antibody, suggesting that the 34-kD light chain also binds to this domain of the molecule. Since microtubules that contain the 120-kD fragment lack the long lateral projections characteristic of microtubules with intact MAP-1, the 34-kD light chains may be localized at or near the microtubule surface.     

Interaction of high-molecular-weight basic fibroblast growth factor with endothelium: Biological activity and intracellular fate of human recombinant Mr 24,000 bFGF

The single-copy gene of human basic fibroblast growth factor (bFGF) encodes four co-expressed isoforms, with an apparent molecular weight (M_r) of 24kD, 22.5 kD, 22kD, and 18kD, co-translated from a single mRNA. As a tool for the study of the role exerted by the different bFGF isoforms in the biology of endothelial cells, human recombinant 24-kD bFGF was produced and purified from transformed Escherichia coli cells. To this purpose, the novel CUG start codon present in human bFGF cDNA and responsible for the synthesis of 24-kD bFGF was mutagenized to the classic AUG start codon. Transient expression of the mutagenized cDNA in simian COS-1 cells, followed by immunolocalization and subcellular fractionation, resulted in the synthesis of high levels of 24-kD bFGF, which localizes in the cell nucleus as an intact protein. When the same 24-kD bFGF, cDNA was expressed in E. coli, the recombinant protein was purified to homogeneity by heparin-Sepharose and ion-exchange chromatography. Recombinant 24-kD bFGF was similar to recombinant 18-kD bFGF in receptor-binding activity and in inducing cell proliferation, plasminogen activator production, and chemotactic movement in cultured endothelial cells. In agreement with the in vitro observations, 24-kD bFGF and 18-kD bFGF exerted a similar angiogenic response when assayed in vivo in the rabbit cornea. Experiments performed with the radiolabeled molecule demonstrated that 24-kD bFGF has an intrinsic ability to bind to high-affinity receptors when added to endothelial GM 7373 cell cultures. Receptor-bound 24-kD bFGF is internalized within the cell and associates with the nucleus with kinetics similar to 13-kD bFGF. Internalized 24-kD bFGF is first processed to the 18-kD form via a chloroquine-insensitive pathway and then to smaller fragments into the lysosomal compartment. At variance with the data obtained in transfected COS-1 cells, only limited amounts of exogenous internalized 24-kD bFGF associates with the nucleus in the intact form, mostly of the nuclear-bound molecule being represented by the processed 18-kD protein and by smaller degradation products. In conclusion, human recombinant 24-kD bFGF exerts a biological response in endothelial cells similar to 18-kD bFGF both in vitro and in vivo. Our data point to a different intracellular behavior of the high-molecular-weight bFGF isoform when added exogenously to cultured cells or when produced endogenously in transfected cells. © 1994 Wiley-Liss, Inc.     

Sds22p is a subunit of a stable isolatable form of protein phosphatase 1 (Glc7p) from Saccharomyces cerevisiae

Protein phosphatase 1 (PP1) is one of the major protein phosphatases in eukaryotic cells. PP1 activity is believed to be controlled by the interaction of PP1 catalytic subunit with various regulatory subunits. The essential gene GLC7 encodes the PP1 catalytic subunit in Saccharomyces cerevisiae. In this study, full-length GLC7(1-312), C-terminal deletion mutants, and C-terminally poly-his tagged mutants were constructed and expressed in a GLC7 knockout strain of S. cerevisiae. Viability studies of the GLC7 knockout strains carrying the plasmids expressing GLC7 C-terminal deletion mutants and their tagged forms showed that the mutants 1-295 and 1-304 were functional, whereas the mutant 1-245 was not. The C-terminally poly-his tagged Glc7p with and without an N-terminal hemagglutinin (HA) tag was partially purified by immobilized Ni(2+) affinity chromatography and further analyzed by gel filtration and ion exchange chromatography. Phosphatase activity assays, SDS-PAGE, and Western blot analyses of the chromatographic fractions suggested that the Glc7p associated with regulatory subunits in vivo. A 40-kDa protein was copurified with tagged Glc7p through several chromatographic procedures. Monoclonal antibody against the HA tag coimmunoprecipitated the tagged Glc7p and the 40-kDa protein. This protein was further purified by a reverse phase HPLC column. Analysis by CNBr digestion, peptide sequencing, and electrospray mass spectrometry showed that this 40-kDa protein is Sds22p, one of the proteins proposed to be a regulatory subunit of Glc7. These results demonstrate that Sds22p forms a complex with Glc7p and that Sds22p:Glc7p is a stable isolatable form of yeast PP1.     

Regulation of Triacylglucose Fatty Acid Composition (Uridine Diphosphate Glucose:Fatty Acid Glucosyltransferases with Overlapping Chain-Length Specificity)

UDP-glucose (UDP-Glc):fatty acid glucosyltransferases catalyze the UDP-Glc-dependent activation of fatty acids as 1-O-acyl-[beta]-glucoses. 1-O-Acyl-[beta]-glucoses act as acyl donors in the biosynthesis of 2,3,4-tri-O-acylglucoses secreted by wild tomato (Lycopersicon pennellii) glandular trichomes. The acyl composition of L. pennellii 2,3,4-tri-O-acylglucoses is dominated by branched short-chain acids (4:0 and 5:0; approximately 65%) and straight and branched medium-chain-length fatty acids (10:0 and 12:0; approximately 35%). Two operationally soluble UDP-Glc:fatty acid glucosyltransferases (I and II) were separated and partially purified from L. pennellii (LA1376) leaves by polyethylene glycol precipitation followed by DEAE-Sepharose and Cibacron Blue 3GA-agarose chromatography. Whereas both transferases possessed similar affinity for UDP-Glc, glucosyltransferase I showed higher specificity toward short-chain fatty acids (4:0) and glucosyltransferase II showed higher specificity toward medium-chain fatty acids (8:0 and 12:0). The overlapping specificity of UDP-Glc:fatty acid glucosyltransferases for 4:0 to 12:0 fatty acid chain lengths suggests that the mechanism of 6:0 to 9:0 exclusion from acyl substituents of 2,3,4-tri-O-acylglucoses is unlikely to be controlled at the level of fatty acid activation. UDP-Glc:fatty acid glucosyltransferases are also present in cultivated tomato (Lycopersicon esculentum), and activities toward 4:0, 8:0, and 12:0 fatty acids do not appear to be primarily epidermal when assayed in interspecific periclinal chimeras.     

Density Gradient Study of Victorin-Binding Proteins in Oat (Avena sativa) Cells

Victorin-binding proteins (VBPs) in oat (Avena sativa) cells were identified using native victorin and anti-victorin polyclonal antibodies. Homogenates of oat tissues were fractionated in continuous or discontinuous sucrose density gradients or with an aqueous two-phase method, and covalent binding sites of victorin were detected by western blotting. In a 20 to 45% (w/w) sucrose continuous density gradient, the 100-kD VBP was located in fractions of 37 to 44% sucrose, with a peak at 39% sucrose. Based on marker enzyme assays, plasma membranes peaked at 39 to 41% sucrose, mitochondria peaked at 41%, but Golgi and endoplasmic reticulum were in lower density fractions, peaking at 28 to 29% and 22 to 24% sucrose, respectively. The 100-kD VBP was not found in plasma membranes purified by the aqueous two-phase method or in mitochondria purified by discontinuous density gradient centrifugation. Victorin binding to 65- and 45-kD proteins was detected in all fractions in the continuous sucrose density gradients. The 65- and 45-kD proteins were both detected in purified plasma membranes, but only the 65-kD protein was detected in purified mitochondria. The subcellular location of VBPs was the same in sensitive and resistant oat cells.