Hydrophobic interactions of transcobalamin II (TC II) from mammalian sera

The hydrophobic properties of mammalian transcobalamin IIs (TC II) were studied by chromatography of radioactive cyanocobalamin (CN[57Co]Cbl)-labeled serum on phenyl-Sepharose CL-4B. Mammalian holo TC IIs (CN[57Co]Cbl-TC II) exhibited species variability in their affinity for the hydrophobic matrix in the order: dog greater than mouse greater than human greater than rat greater than rabbit. Phenyl-Sepharose chromatography of the isolated CN[57Co]Cbl-TC II peaks from gel filtration of dog and rat serum showed no hydrophobic change in dog TC II, but an increase in hydrophobicity of rat TC II. Phenyl-Sepharose chromatography of CN[57Co]Cbl-labeled rabbit serum (holo TC II) and the unlabeled serum (apo TC II) showed apo TC II to be more hydrophobic than holo TC II as has been shown for human TC II (Begley et al., Biochem Biophys Res Commun 103:434-441, 1981). Thus mammalian holo TC IIs differ in their hydrophobic properties and apo TC II, in man and rabbit, is more hydrophobic than holo TC II. In addition, isolation of the TC II in some animal sera by gel filtration may result in a TC II that is more hydrophobic than the native molecule.     

Interaction between transcobalamin II and immobilized Cibacron Blue F3GA

Human serum transcobalamin II (TC II), a vitamin B₁₂ (Cbl) transport protein, complexes with Cibacron Blue F3GA, a reactive blue dye which can bind to proteins that require nucleotides as cofactors. Apo-TC II and holo-TC II both bind, but intrinsic factor (IF) and R-type binders of Cbl do not. Other mammalian species TC II also complex with the dye. Greater than 87% of the applied TC II-CN-[⁵⁷Co]Cbl remains bound to the dye even at pH 4.0. At pH values below this, the CN-[⁵⁷Co]Cbl dissociates off TC II which remains bound to the dye. High salt concentrations will break the TC II-dye complex. Ionic forces were considered not to be involved since complexing also occurred at pH 9.0, 2.5 pH units above the isoelectric point of TC II. Failure to dissociate the TC II-dye complex with 50% glycerol makes hydrophobic interactions unlikely. In addition to the potential uses of TC II-Cibacron Blue F3GA complexes in a total scheme for protein purification, the possibility that TC II is a nucleotide-requiring protein should be explored.     

Cobalamin transport proteins and their cell-surface receptors

The primary function of cobalamin (Cbl; vitamin B12) is the formation of red blood cells and the maintenance of a healthy nervous system. Before cells can utilise dietary Cbl, the vitamin must undergo cellular transport using two distinct receptor-mediated events. First, dietary Cbl bound to gastric intrinsic factor (IF) is taken up from the apical pole of ileal epithelial cells via a 460 kDa receptor, cubilin, and is transported across the cell bound to another Cbl-binding protein, transcobalamin II (TC II). Second, plasma TC II-Cbl is taken up by cells that need Cbl via the TC II receptor (TC II-R), a 62 kDa protein that is expressed as a functional dimer in cellular plasma membranes. Human Cbl deficiency can develop as a result of acquired or inherited dysfunction in either of these two transmembrane transport events. This review focuses on the biochemical, cellular and molecular aspects of IF and TC II and their cell-surface receptors.     

Quantifying Hg within ectomycorrhizal fruiting bodies,from emergence to senescence

Ectomycorrhizal fruiting bodies (basidiomata) collected from forested areas in southwestern New Brunswick were analyzed for total mercury, sulphur, nitrogen, and carbon concentrations (THg, TS, TN, and TC, respectively). This analysis was done for caps and stalks and by development stage (emergent, mature, senescent) across 27 species associated with five classes, eight families, and 13 genera. Across the species, THg correlated positively with TN and TS, thereby implying N as well as S mitigated transfer of Hg from the mycelia into the basidiomata, with THg ranging from 3 to 10?457 ppb. TS, TN, and TC varied from 0.07 to 1, 1 to 11, and 43 to 53 %, respectively. Cap and stalk THg, TS, TN, and TC were also correlated to one another, with mean stalk/cap ratios of 0.59, 0.76, 0.71, and 0.98, respectively. Soil availability indexed by THg, TS, TN, and TC within the forest floor contributed to basidiomatal THg as well. THg, THg/TS, and THg/N varied strongly by species. These variations involved: (i) no growth dilution and no volatilization (Group I), (ii) growth dilution only (Group II), (iii) growth dilution followed by loss during senescence (Group III), and (iv) growth dilution combined with loss from emergence onward (Group IV). Depending on species, TN and TS remained the same or declined from 100 % at emergence to about 80 and 70 % at senescence. Lack of THg decline for the Group I species would be due to HgS encapsulation. Reanalyzing the freeze-dried samples revealed that THg continued to drop during the first year of air-dry storage for the Group II, II, and IV species, but TS, TN, and TC remained stable. The results were quantified by way of best-fitted regression models.     

Function and stability of human transcobalamin II: role of intramolecular disulfide bonds C98-C291 and C147-C187

The current studies have investigated the role of three disulfide bonds of human transcobalamin II (TC II), a plasma transporter of cobalamin (Cbl; vitamin B12), in its function and stability. When translated in vitro in the presence or absence of microsomal vesicles, TC II constructs with a single substitution, C3S or C249S, demonstrated synthesis of a stable functional protein. However, TC II synthesized in the presence of microsomal vesicles using constructs with a single (C98S, C147S, C187S, C291S), double (C3/147/S, C98/147/S) or triple (C3/98/147/S) substitution was unstable. In the absence of microsomal vesicles, the percentage of binding to Cbl-Sepharose matrix by TC II expressed by constructs C3S, C3/147/S, C98/147/S, or C3/98/147/S was 100, 49, 52, and 35%, respectively. Upon their reductive alkylation, the binding of TC II expressed by these constructs was reduced to approximately 25-30%. TC II constructs C3S or C249S, when expressed in TC II-deficient fibroblasts, produced a stable functional protein, but those expressed by constructs C147S, C187S, C291S, C3/147/S, C98/147/S, or C3/98/147/S were rapidly degraded. The intracellular degradation of TC II expressed by these constructs was inhibited by lactacystin or MG-132 but not by the lysosomal degradation inhibitors ammonium chloride or chloroquine. These studies suggest that optimal binding of Cbl by human TC II is supported by disulfide bonds C98-C291 and C147-C187 and that their disruption results in loss of Cbl binding and their rapid degradation by the proteasomal machinery.     

Evaluation of Antioxidant Activity of Dihydroquercetin Complexes with Biogenic Metal Ions

The antioxidant activity of dihydroquercetin (DHQ) complexes with zinc, copper(II) and calcium was studied in vitro in blood plasma of healthy donors. The state of lipid peroxidation (LPO) in blood plasma was assessed by the content of malondialdehyde (MDA), diene (DC) and triene (TC) conjugates. The effect of DHQ and the complexes on the activity of the catalase enzyme in blood plasma was determined. It was found that DHQ complex with zinc ion reduces the MDA content in blood plasma by 14.9% compared with the control, which is twice as high as for DHQ (7.5%). The corresponding parameters of DHQ complexes with copper(II) and calcium ions were 11.2 and 3.7%, respectively. The effect of the complexes on the decrease in the DC and TC content in blood plasma compared with the control is comparable with the corresponding parameters for DHQ. The DHQ complex with zinc ion increases the catalase activity by 1.5% compared with DHQ. The complexes containing copper(II) and calcium ions increase the catalase activity no more than DHQ.     

Solid-phase immunoassay for the vitamin B12-binding protein transcobalamin II in human serum

A solid-phase radio immunoassay was developed for total immunoreactive transcobalamin II (TC II). Rabbit antihuman TC II antiserum (which recognizes both apo- and holo-TC II), was immobilized by covalent binding to acrylamide-acrylic acid copolymer beads. A normal mean and SD for immunoreactive TC II in serum was determined in 130 healthy adult individuals and found to be 1150 ± 250 ng/liter cobalamin equivalent. Mean holo-TC II (N = 30), estimated by substraction of apo-TC II from total TC II, was 137 ng/liter bound cobalamin (or 12% of total TC II). Three patients with lack of functional TC II had immunoreactive TC II levels between 22 and 39% of normal mean, which demonstrated that the solid-phase bound antiserum recognized deficient TC II molecules, whereas the same antiserum in its soluble form did not. Eight out of nine individuals, recognized as heterozygous for TC II deficiency, had TC II levels below the normal range, on the order of 50% of the normal mean. The stability of immunoreactive TC II was strongly enhanced by the presence of an unknown serum factor not corresponding to serum albumin.     

Congenital disorders of vitamin B12 transport and their contributions to concepts. II.

Congenital deficiencies of Transcobalamin II (TC II) and R binders of vitamin B12 (B12, cobalamin, Cbl) have been described in several families. The deficiency of TC II exists as at least three variants. The deficiency of TC II is expressed by a profound megaloblastic pancytopenia during the first few weeks of life, but the serum Cbl is normal. In contrast, the deficiency of R binder is asymptomatic, tissues are replete in Cbl, but the serum Cbl is low. All of the R binder in the several body sources is under the same genetic control. Studies of the congenital deficiency TC II suggest the following: (1) The function of TC II is the promotion of cell uptake of physiologic amounts of Cbl, which can also be accomplished by very large amounts of Cbl, and not in any intracellular process. (2) TC II is essential for the absorption, postabsorptive distribution, and recycling of TC II. (3) The metabolic consequences of TC II deficiency are expressed primarily in rapidly dividing cells probably because they are dependent upon the constant need for new Cbl.     

Monoclonal antibodies to different sites on human transcobalamin II

Two IgG1K monoclonal antibodies to human transcobalamin II (TC II) were generated. These antibodies, 16.1 and 16.6, did not cross-react with the other two types of human cobalamin-binding proteins, intrinsic factor and R binder (TC I). Both antibodies cross-reacted with orangutan and simiang TC II but not with TC II from cynomolgus and howler monkeys, who are less closely related to humans. This finding suggests close structural similarity of human to ape TC II. The antibodies also did not react with TC II of lower mammals which included the horse, dog, guinea pig, and mouse; in particular, reaction did not occur with rabbit TC II, which has been considered structurally close to human TC II. Neither of the two antibodies was directed at the cobalamin-binding site of TC II. However, antibody 16.6 hindered TC II binding to cell receptor. This reactivity with the receptor-binding site should prove particularly useful in studies of that region of the TC II molecule.     

Inheritance and genetic linkage of transcobalamin II

Summary The genetic polymorphism of the vitamin B₁₂ transport protein transcobalamin II (TC II) was studied in a Caucasian population and in families. There are five codominent alleles of TC II which show a Mendelian mode of inheritance. No genetic linkage of TC II was found with gene loci for ADA, GLOI, Pi, HLA, AB0 and AK₁. TC II like proteints could be detected on autoradiograph of PAGE in two patients with congenital homozygosity for functional TC II deficiency. These vitamin B₁₂ binding proteins in the patients' serum were shown not to be normal R-proteins.Supported in part by grants from U.S. Public Health Service, NCI CA-22507, CA-19267, CA-08748, NIAID AI-07073. A portion of this work was conducted through the Clinical Research Center Facility of the University of Washington (RR-37)     

GTP Hydrolysis of TC10 Promotes Neurite Outgrowth through Exocytic Fusion of Rab11- and L1-Containing Vesicles by Releasing Exocyst Component Exo70

The use of exocytosis for membrane expansion at nerve growth cones is critical for neurite outgrowth. TC10 is a Rho family GTPase that is essential for specific types of vesicular trafficking to the plasma membrane. Recent studies have shown that TC10 and its effector Exo70, a component of the exocyst tethering complex, contribute to neurite outgrowth. However, the molecular mechanisms of the neuritogenesis-promoting functions of TC10 remain to be established. Here, we propose that GTP hydrolysis of vesicular TC10 near the plasma membrane promotes neurite outgrowth by accelerating vesicle fusion by releasing Exo70. Using Förster resonance energy transfer (FRET)-based biosensors, we show that TC10 activity at the plasma membrane decreased at extending growth cones in hippocampal neurons and nerve growth factor (NGF)-treated PC12 cells. In neuronal cells, TC10 activity at vesicles was higher than its activity at the plasma membrane, and TC10-positive vesicles were found to fuse to the plasma membrane in NGF-treated PC12 cells. Therefore, activity of TC10 at vesicles is presumed to be inactivated near the plasma membrane during neuronal exocytosis. Our model is supported by functional evidence that constitutively active TC10 could not rescue decrease in NGF-induced neurite outgrowth induced by TC10 depletion. Furthermore, TC10 knockdown experiments and colocalization analyses confirmed the involvement of Exo70 in TC10-mediated trafficking in neuronal cells. TC10 frequently resided on vesicles containing Rab11, which is a key regulator of recycling pathways and implicated in neurite outgrowth. In growth cones, most of the vesicles containing the cell adhesion molecule L1 had TC10. Exocytosis of Rab11- and L1-positive vesicles may play a central role in TC10-mediated neurite outgrowth. The combination of this study and our previous work on the role of TC10 in EGF-induced exocytosis in HeLa cells suggests that the signaling machinery containing TC10 proposed here may be broadly used for exocytosis.     

The function of cellular transcobalamin II in cultured human cells

The known function of human transcobalamin II (TC II) is to transport cobalamin (Cbl) in the circulation to tissue receptors for TC II-Cbl. Several types of human cells synthesize apo (unsaturated) TC II and the present study was conducted in order to evaluate possible functions of this endogenous TC II. The approach consisted of a correlation between the abilities of cultured cells to produce apo TC II and to internalized Cbl when presented in the free form. The amount of apo TC II produced by six lines of cultured human cells ranged from abundant to nil. The amount of free Cbl internalized by these cells correlated directly with the capacity to produce apo TC II. The interactions between endogenous TC II and free Cbl took place either at the cell surface or in the medium surrounding the cell. It was also shown that cells in culture contain free Cbl and release free Cbl into the surrounding medium. Thus it was concluded that the apo TC II produced by human cells remains intact to interact with free Cbl and to participate in the cellular metabolism of Cbl.     

High affinity binding of the transcobalamin II–cobalamin complex and mRNA expression of haptocorrin by human mammary epithelial cells

Little is known about the acquisition of cobalamin by the mammary gland and its secretion into milk. Human milk and plasma contain at least two types of cobalamin binding proteins: transcobalamin II (TC) and haptocorrin (HC). In plasma, TC is responsible for the transport of cobalamin to tissues and cells; however, cobalamin in milk is present exclusively bound to HC. We show that human mammary epithelial cells (HMEC) exhibit high affinity for TC; Scatchard analysis revealed a single class of binding sites for the TC–[⁵⁷Co]cyanocobalamin complex with a dissociation constant (K_d) of 4.9×10⁻¹¹ M. Uptake of the TC–[⁵⁷Co]cyanocobalamin complex at 37°C was saturable by 24 h. Binding of free [⁵⁷Co]cyanocobalamin to HMEC was not saturable and very limited binding of the HC–[⁵⁷Co]cyanocobalamin complex was observed. Expression of the haptocorrin gene by HMEC was confirmed by Northern blot and PCR analysis. Thus, a specific cell surface receptor for the TC–cobalamin complex exists in the mammary gland and once cobalamin is internalized, it may be transferred to HC and subsequently secreted into milk as a HC–cobalamin complex.     

High affinity binding of the transcobalamin II-cobalamin complex and mRNA expression of haptocorrin by human mammary epithelial cells

Little is known about the acquisition of cobalamin by the mammary gland and its secretion into milk. Human milk and plasma contain at least two types of cobalamin binding proteins: transcobalamin II (TC) and haptocorrin (HC). In plasma, TC is responsible for the transport of cobalamin to tissues and cells; however, cobalamin in milk is present exclusively bound to HC. We show that human mammary epithelial cells (HMEC) exhibit high affinity for TC; Scatchard analysis revealed a single class of binding sites for the TC-[(57)Co]cyanocobalamin complex with a dissociation constant (K(d)) of 4.9 x 10(-11) M. Uptake of the TC-[(57)Co]cyanocobalamin complex at 37 degrees C was saturable by 24 h. Binding of free [(57)Co]cyanocobalamin to HMEC was not saturable and very limited binding of the HC-[(57)Co]cyanocobalamin complex was observed. Expression of the haptocorrin gene by HMEC was confirmed by Northern blot and PCR analysis. Thus, a specific cell surface receptor for the TC-cobalamin complex exists in the mammary gland and once cobalamin is internalized, it may be transferred to HC and subsequently secreted into milk as a HC-cobalamin complex.     

The role of transcobalamin II in the methionine dependency of human lymphocytes

Neither normal human B lymphoblasts (RPMI 6410) transformed by the EB virus nor human peripheral blood lymphocytes (PBL) stimulated by a mitogen replicated well when the methionine (Met) of the medium was replaced with homocysteine (Hcy). Cbl bound to human transcobalamin II (TC II) substantially increased cell division over that observed when the Cbl of the medium was in the free form. Although, as expected, the TC II enhanced the cell entry of Cbl 1000-fold, this was not the basis of the TC II effect. Through adjustment of the respective concentrations of free Cbl and TC II-Cbl in the medium, equal amounts of Cbl entered the cell, yet the TC II effect persisted. TC II-Cbl did not restore cell division in the absence of Met by virus-transformed lymphoblasts from a child with defective Met synthesis from Hcy. The TC II did not act by enhanced induction of the Cbl-dependent methionine synthase activity of cell extracts but the ability of intact cells to produce Met from Hcy by the Cbl-dependent process appeared to have a role in the TC II effect.     

Computer simulation of Zn(II) speciation and effect of Gd(III) on Zn(II) speciation in human blood plasma

The speciation and distribution of Zn(II) and the effect of Gd(III) on Zn(II) speciation in human blood plasma were studied by computer simulation. The results show that, in normal blood plasma, the most predominant species of Zn(II) are [Zn(HSA)] (58.2%), [Zn(IgG)](20.1%), [Zn(Tf)] (10.4%), ternary complexes of [Zn(Cit)(Cys)] (6.6%) and of [Zn(Cys)(His)H] (1.6%), and the binary complex of [Zn(Cys)₂H] (1.2%). When zinc is deficient, the distribution of Zn(II) species is similar to that in normal blood plasma. Then, the distribution changes with increasing zinc(II) total concentration. Overloading Zn(II) is initially mainly bound to human serum albumin (HSA). As the available amount of HSA is exceeded, phosphate metal and carbonate metal species are established. Gd(III) entering human blood plasma predominantly competes for phosphate and carbonate to form precipitate species. However, Zn(II) complexes with phosphate and carbonate are negligible in normal blood plasma, so Gd(III) only have a little effect on zinc(II) species in human blood plasma at a concentration above 1.0×10⁻⁴ M.     

Transcobalamin II Receptor Interacts with Megalin in the Renal Apical Brush Border Membrane

Purified human transcobalamin II receptor (TC II-R) binds to megalin, a 600 kDa endocytic receptor with an association constant, K(a), of 66 n M and bound(max) of 1.1 mole of TC II-R/mole of megalin both in the presence and absence of its ligand, transcobalamin II (TC II). Immunoprecipitation followed by immunoblotting of Triton X-100 extracts of the apical brush border membrane (BBM) from rabbit renal cortex revealed association of these two proteins. (35)[S]-TC II complexed with cobalamin (Cbl; Vitamin B(12)) bound to Sepharose-megalin affinity matrix and the binding was enhanced 5-fold when TC II-R was prebound to megalin. Megalin antiserum inhibited both the TC II-R-dependent and -independent binding of (35)[S]-TC II-Cbl to megalin, while TC II-R antiserum inhibited only the TC II-R-dependent binding. In rabbits with circulating antiserum to megalin, renal apical BBM megalin was present as an immune complex, but its levels were not altered. However, the protein levels of both TC II-R and the cation-independent mannose 6-phosphate receptor (CIMPR) were drastically reduced and the urinary excretion of TC II, albumin, and other low-molecular weight proteins was significantly increased. These results suggest that megalin contains a distinct single high-affinity binding site for TC II-R and their association in the native renal BBM is important for tubular reabsorption of many proteins, including TC II.     

The exocytotic trafficking of TC10 occurs through both classical and nonclassical secretory transport pathways in 3T3L1 adipocytes

To examine the structural determinants necessary for TC10 trafficking, localization, and function in adipocytes, we generated a series of point mutations in the carboxyl-terminal targeting domain of TC10. Wild-type TC10 (TC10/WT) localized to secretory membrane compartments and caveolin-positive lipid raft microdomains at the plasma membrane. Expression of a TC10/C206S point mutant resulted in a trafficking and localization pattern that was indistinguishable from that of TC10/WT. In contrast, although TC10/C209S or the double TC10/C206,209S mutant was plasma membrane localized, it was excluded from both the secretory membrane system and the lipid raft compartments. Surprisingly, inhibition of Golgi membrane transport with brefeldin A did not prevent plasma membrane localization of TC10 or H-Ras. Moreover, inhibition of trans-Golgi network exit with a 19 degrees C temperature block did not prevent the trafficking of TC10 or H-Ras to the plasma membrane. These data demonstrate that TC10 and H-Ras can both traffic to the plasma membrane by at least two distinct transport mechanisms in adipocytes, one dependent upon intracellular membrane transport and another independent of the classical secretory membrane system. Moreover, the transport through the secretory pathway is necessary for the localization of TC10 to lipid raft microdomains at the plasma membrane.     

A comparative study of the toxicity of mercury dichloride and methylmercury, assayed by the Frog Embryo Teratogenesis Assay--Xenopus (FETAX)

The Frog Embryo Teratogenesis Assay-Xenopus (FETAX) is a powerful and flexible bioassay that makes use of the embryos of the anuran amphibian Xenopus laevis. The FETAX can detect xenobiotics that affect embryonic development, when mortality, teratogenicity and growth inhibition are used as endpoints. The FETAX was used to compare the embryotoxic and teratogenic potentials of two chemical species of mercury, inorganic mercury(II) chloride (HgCl2) and organic methylmercury chloride (MeHgCl). A higher toxicity of MeHgCl (the estimated median lethal concentration [LC50] and median teratogenic concentration [TC50] were 0.313microM and 0.236microM, respectively) over HgCl2, with estimated LC50 and TC50 values of 0.601microM and 0.513microM, respectively). On the basis of these results, HgCl2 and MeHgCl can be classified as "slightly teratogenic compounds", as the ratio of LC50/TC50 is less than 1.5. There was a significant deviation from the commonly described monotonic behaviour of the concentration-response curves, suggesting a hormetic effect of both species of mercury. Uptake experiments, followed by neutron activation analysis, showed a higher incorporation of mercury in embryos exposed to MeHgCl compared with those exposed to HgCl2. Interestingly, Hg- exposed embryos showed a higher content of selenium and zinc than did control embryos.