Antibodies to blood-brain barrier bind selectively to brain capillary endothelial lateral membranes and to a 46K protein.

To begin elucidating the biochemical basis of the polarized membrane features of the blood-brain barrier (BBB), a series of immunochemical and immunoperoxidase studies were initiated with bovine brain microvessels that make up the BBB in vivo. A rabbit antiserum was prepared against isolated bovine brain BBB plasma membranes. The bovine microvessel plasma membranes were radioiodinated with chloramine-T, and the antiserum selectively immunoprecipitated a 46K protein. The antibodies directed against the 46K protein were quantitatively absorbed with bovine brain capillaries but not with rat kidney or liver powder. Only the capillaries of brain reacted with the rat kidney-absorbed antiserum in immunoperoxidase studies of ethanol-fixed, 8-micron sections of bovine brain cortex, whereas the capillaries in heart, liver, and kidney did not react. This antiserum also strongly illuminated the lateral membranes of isolated bovine brain capillary endothelial cells grown in primary tissue culture. These studies provide evidence for a polarized distribution of a surface antigen in bovine brain capillary endothelial cells that is not present in capillary endothelia of liver, heart, or kidney. The correlation of the immunoperoxidase and immunoprecipitation techniques suggests that a candidate for the asymmetrically distributed surface antigen in the BBB is the 46K protein. The relationship between the 46K protein and the composition of BBB tight junctions remains to be determined.

Kinetics of neutral amino acid transport through the blood-brain barrier of the newborn rabbit.

Since protein synthesis in the developing brain may, under certain conditions, be limited by amino acid availability, the present studies were undertaken to characterize the kinetics of large neutral amino acid transport through the blood-brain barrier (BBB) of the newborn rabbit. The Km, Vmax, and KD of the transport of eight amino acids were determined by a nonlinear regression analysis of data obtained with the carotid injection technique. Compared with kinetic parameters observed for the adult rat, the Km, Vmax, and KD of amino acid transport were all two- to threefold higher in the newborn. Albumin was found to bind tryptophan actively in vitro, but had no inhibitory effect on tryptophan transport through the newborn BBB. Glutamine was transported through the BBB of the newborn at rates severalfold higher than are seen in the adult rat. However, glutamine transport was not inhibited by high concentrations of N-methylaminoisobutyric acid (NMAIB), a model amino acid that is specific for the alanine-preferring of A-system present in peripheral tissues. In conclusion, these studies show that the BBB neutral amino acid transport system of the newborn rabbit has a lower affinity and higher capacity than does the BBB of the adult rat. Under conditions of high plasma amino acids, the increased capacity of the newborn transport system allows for a higher rate of amino acid transport into brain than would occur via the lower capacity system present in the adult rat brain.

Kinetics of regional blood-brain barrier transport and brain phosphorylation of glucose and 2-deoxyglucose the barbiturate-anesthetized rat.

Recent studies indicate the lumped constant (LC), which defines the relative rates of brain utilization of glucose and 2-deoxyglucose (2-DG), doubles to values greater than 1.0 under conditions of hypoglycemia. Since changes in the LC should be predictable given the kinetic parameters of blood-brain barrier (BBB) transport and brain phosphorylation of glucose and 2-DG, the present studies were designed to measure the necessary kinetic parameters. The carotid injection technique ws used to determine cerebral blood flow and the Km, Vmax, and KD of glucose and 2-DG transport through the BBB in seven brain regions in rats anesthetized with 50 mg/kg i.lp. pentobarbital. Regional glucose transport through the BBB was characterized by an average Km = 6.3 mM, average Vmax = 0.53 mumol min-1g-1, and average KD = 0.022 ml min-1g-1.l The nonsaturable route of transport of glucose represented on the average 40% of the total glucose influx into brain regions at an arterial glucose concentration of 10 mM. In addition, the rate constants of phosphorylation of glucose and 2-DG were measured for each region. Substitutions of the measured kinetic parameters for sugar transport and phosphorylation into equations defining the LC confirm the observation that the LC would be expected to vary under extreme conditions such as hypoglycemia and to exceed values of 1.0 under these conditions.

Nomogram for 2-deoxyglucose lumped constant for rat brain cortex.

The quantitation of local cerebral metabolic rate of glucose with the 2-deoxyglucose technique of Sokoloff requires the use of a correction factor, or lumped constant. We have shown previously (Pardridge et al., 1982) that a simple model may be formulated to predict changes in the lumped constant that occur due to alterations in the distribution of glucose and 2-deoxyglucose in brain. Given experimentally observed values for brain and plasma glucose concentrations, the 2-deoxyglucose lumped constant may be determined from a nomogram constructed from knowledge of the blood-brain barrier transport constants (KM, Vmax, KD) for glucose and for 2-deoxyglucose. However, the nomogram is constructed from transport constants determined in the barbiturate-anesthetized state. The applicability of the nomogram to other physiologic states was examined in the present studies. Large changes in blood-brain barrier hexose transport constants do not appreciably alter the shape of the nomogram, if the changes in KM or Vmax for glucose or for 2-deoxyglucose are the same. Moreover, glucose and 2-deoxyglucose are both transported by the same hexose carrier, and selective changes in the transport of only one hexose have not been reported. Therefore, it is probable that the nomogram constructed from transport constants measured under barbiturate anesthesia is useful in predicting the lumped constant in a variety of physiologic states.

Hepatic bioavailability of serum thyroid hormones in nonthyroidal illness.

Serum was obtained from 11 patients with nonthyroidal illness (NTI) and from 9 control subjects. Patients with NTI demonstrated decreased total T4 and T3 levels; increased rT3, T3 resin uptake, and percent free (dialyzable) T4 levels; and normal TSH and free T4 concentrations in vitro. In addition, the effects of control and patient sera on the first pass extraction of labeled T4 and T3 by rat liver was measured with a tissue sampling-single injection technique. The percent of total serum T4 and T3 that was transported into liver on one pass was 17 +/- 2% and 77 +/- 5%, respectively, in the case of NTI, and these values were no different from control estimates. The concentrations of total serum T4 and T3 available for transport into liver in vivo were 0.69 +/- 0.13 micrograms/100 ml and 21 +/- 2 ng/100 ml, respectively, in NTI, and these values were 46% and 18% of control values, respectively. Therefore, in contrast to in vitro estimates of free T4, in vivo measurements indicate the amount of circulating T4 or T3 that is available for transport into liver cells in NTI is reduced in proportion to the decrease in total plasma hormone.

Influx of thyroid hormones into rat liver in vivo. Differential availability of thyroxine and triiodothyronine bound by plasma proteins.

The transport of [(125)I]thyroxine (T(4)) and [(125)I]triiodothyronine (T(3)) into liver was investigated with a tissue sampling-portal vein injection technique in the anesthetized rat. The method allows the investigation of the effects of plasma proteins in human serum on the unidirectional influx of T(4) or T(3) into liver cells. The percent extraction of unidirectional clearance of T(3) and T(4) was 77+/-2% and 43+/-2%, respectively, after portal injection of a bolus of Ringer's solution. Cell membrane transport of T(4) or T(3) was nonsaturable because 50-muM concentrations of unlabeled hormone had no effect on transport. The addition of bovine albumin in concentrations of 1, 5, or 10 g/100 ml bound >98% of T(4) or T(3) in vitro, but had no significant effect on T(3) or T(4) transport in vivo. Conversely, 10% rabbit antisera specific for T(3) or T(4), completely abolished the intracellular distribution of thyroid hormone into liver. In the presence of rat serum, which contains albumin and thyroid hormone binding pre-albumin (TBPA), 18 and 81% of total plasma T(4) and T(3), respectively, were available for transport in vivo. The fraction of hormone available for transport in the presence of normal human serum, which contains albumin, TBPA, and thyroid hormone binding globulin (TBG) was 11% for T(4) and 72% for T(3). The fraction of hormone transported into liver after injection of serum obtained from pregnant or birth control pilltreated volunteers was 4% for T(4) (but this was not significantly different from zero) and 54% for T(3). THESE DATA SUGGEST: (a) The mechanism by which T(4) and T(3) traverse the liver cell membrane is probably free diffusion. (b) Albumin-bound T(4) or T(3) is freely cleared by liver, approximately 50% of TBG-bound T(3) is transported, but little, if any, of TBPA-bound T(4) or TBG-bound T(4) is cleared by liver cells. (c) Although the albumin-bound fraction of T(4) greatly exceeds the free (dialyzable) moiety, the two fractions are both inversely related to the existing TBA or TBG level; therefore, in vitro measurements of free T(4) would be expected to accurately reflect what is available for transport in vivo. Conversely, TBG-bound T(3) is readily transported in vivo; therefore, it is proposed that in vitro measurements of free T(3) do not reliably predict the fraction of T(3) available for transport into liver in vivo.

Effects of human serum on transport of testosterone and estradiol into rat brain.

The effect in vivo of the plasma proteins in human serum on the transport of [3H]testosterone (T), [3H]-dihydrotestosterone (DHT), and [3H]estradiol (E2) through the brain capillary wall, i.e., the blood-brain barrier, was studied in anesthetized rats using a tissue-sampling-single-injection technique, In the absence of plasma proteins, approximately 90% of plasma T, DHT, or E2 was transported into brain on a single pass after a bolus carotid injection of labeled hormone. Serum was obtained from 57 patients in seven different clinical conditions: pregnancy, oral contraceptive use, thin and obese postmenopausal, follicular phase female, hirsutism, and normal male; the level (mean +/- SD) of sex hormone-binding globulin (SHBG) varied from 17 +/- 5 nM (hirsutism) to 323 +/- 83 nM (pregnancy). When the carotid injection solution was made 67% serum, the amount of T, DHT, or E2 transported into brain was inhibited in proportion to the concentration of SHBG. Among the patient groups, an overall linear inverse correlation between the mean SHBG level and the mean extraction of unidirectional influx of testosterone (r = 0.99) and estradiol (r = 0.98) was observed. These studies indicate that a) the undirectional clearance by brain of both testosterone and estradiol is inversely related to the SHBG level and b) the fraction of hormone transported into brain greatly exceeds the free (dialyzable) moiety and is essentially equal to the albumin-bound fraction of plasma testosterone or estradiol.

Transport of protein-bound steroid hormones into liver in vivo.

The unidirectional influx of 3H-gonadal (progesterone, dihydrotestosterone, testosterone, estradiol) and adrenal (aldosterone, cortisol) steroid hormones into liver was studied with a tissue-sampling single-injection technique in barbiturate-anesthetized rats. Liver uptake of the steroid hormone was measured relative to [14C]butanol, a highly diffusible reference, after a single pass through the liver. Portal flow (1.4 ml.min-1.g-1) under the experimental conditions was measured with 3H2O. The extraction of unidirectional influx of all six steroid hormones was 70-100% after a bolus portal injection of labeled steroid in Ringer solution (0.1% albumin). Steroid transport was nonsaturable because 35 muM concentrations of unlabeled hormone resulted in no inhibition of liver transport. The plasma proteins (albumin and specific globulins) in serum from human (male, female, pregnancy), rat (male), and guinea pig (pregnancy) sources inhibited the liver clearance of the respective steroid hormones to a variable extent. In all cases albumin-bound steroid hormone was freely cleared by liver and, in the case of cortisol or estradiol, the fraction bound to a specific globulin was also transported into liver.

Transport of steroid hormones through the rat blood-brain barrier. Primary role of albumin-bound hormone.

These studies were undertaken to investigate (a) the permeability properties of the blood-brain barrier (BBB) to the major gonadal and adrenal steroid hormones, and (b) the role of the binding proteins of plasma (albumin and specific globulins) in the regulation of BBB steroid hormone transport. The permeability of the BBB to [(3)H]-labeled progesterone, testosterone, estradiol, corticosterone, aldosterone, and cortisol, was measured relative to [(14)C]butanol, a freely diffusable reference, in the barbiturate anesthetized rat using a tissue sampling-single injection technique. The isotopes were rapidly injected in a 200-mul bolus of Ringer's solution (0.1 g/dl albumin) via the common carotid artery and the percent extraction of unidirectional influx of hormone was determined after a single pass through brain: progesterone, 83+/-4%; testosterone, 85+/-1%; estradiol, 83+/-3%; corticosterone, 39+/-2%; aldosterone, 3.5+/-0.8%; and cortisol, 1.4+/-0.3%. The selective permeability of the BBB was inversely related to the number of hydrogen bonds each steroid formed in aqueous solution and directly related to the respective 1-octanol/Ringer's partition coefficient. When the bolus injection was 67% human serum, >95% of the labeled steroid was bound as determined by equilibrium dialysis. However, the influx of the steroids through the BBB was inhibited by human serum to a much less extent than would be expected if only the free (dialyzable) hormone was transported; progesterone, estradiol, testosterone, and corticosterone transport was inhibited 18, 47, 70, and 85% respectively, or in proportion to the steroid binding to plasma globulins. Rat serum (67%) only inhibited the transport of these four hormones, 0, 13, 12, and 69%, respectively, reflecting the absence of a sex hormone-binding globulin in rat plasma. However, neonatal rat serum (67%) inhibited progesterone, testosterone, and estradiol transport 0, 0, and 91%, respectively, consistent with the presence of an estradiol-binding protein in neonatal rat serum. The binding of steroid hormone to bovine albumin in vitro (as determined by equilibrium dialysis) was compared to albumin binding in vivo (as determined by the single injection technique). The ratio of apparent dissociation constant in vivo, K(D)(app), to the in vitro K(D) was: >>200 for progesterone, >200 for testosterone, 120 for estradiol, and 7.7 for corticosterone. Assuming the steady-state condition, the K(D)(app)/K(D) was found to be proportional to the BBB permeability for each steroid. These data demonstrate (a) the selective permeability properties of the BBB to the major steroid hormones is proportional to the tendency of the steroid to partition in a polar lipid phase and is inversely related to the number of hydrogen bond-forming functional groups on the steroid nucleus; (b) the presence of albumin in serum may bind considerable quantities of steroid hormone, but exerts little inhibitory effects on the transport of steroids into brain, whereas globulin-bound hormone does not appear to be transported into brain to a significant extent. Therefore, the hormone fraction in plasma that is available for transport into brain is not restricted to the free (dialyzable) fraction, but includes the larger albumin-bound moiety.