Multiple-time Regression Analysis Research Articles

Transport of the Chemokines CCL5 and CCL2 Across the Mouse Blood‐Brain Barrier under Physiological and Inflammatory Conditions

Chemokines are important regulators of neuroinflammation and interact with brain endothelial cells that comprise the blood-brain barrier (BBB) to modulate their function and promote their interactions with leukocytes. Chemokines can also cross the intact BBB, which may contribute to their functions in the brain, but interactions of chemokines with the BBB in vivo are understudied. Here, we show that the chemokines C-C motif ligand 2 (CCL2) and C-C motif ligand 5 (CCL5), which have been well-studied in context of their neuroinflammatory functions, are amenable to labeling with 125I. This affords highly sensitive and quantitative detection of CCL2 and CCL5 in vivo, and allows for rapid assessment of the distribution of circulating chemokines. Multiple-time regression analysis was used to characterize chemokine transport across the mouse BBB. In untreated mice, we evaluated the brain uptake of CCL2 and CCL5 and characterized saturability of uptake and endothelial binding vs. transport. We then determined whether CCL2 and CCL5 interactions with the BBB are altered in mice treated with three doses of 3mg/kg lipopolysaccharide. Our results indicate that in addition to endothelial binding at the glycocalyx, there is uptake of both CCL5 and CCL2 into the mouse brain parenchyma. We found no significant difference in the rate of chemokine uptake in mice treated with LPS versus untreated mice. However, the 125I counts per minute (CPM) was significantly higher in the brains of LPS mice versus untreated mice brains, indicating that more radio-labelled chemokine had entered the brain after LPS-induced inflammation. In conclusion, we have found that chemokines interact with the intact BBB, and alterations in theses interactions with inflammation can be detected in vivo. As a future direction, this method can be utilized to evaluate pharmacological approaches to inhibiting BBB/chemokine interactions, which may protect against harmful neuroinflammation during neurological disease.

Transport of Extracellular Vesicles across the Blood-Brain Barrier: Brain Pharmacokinetics and Effects of Inflammation.

Extracellular vesicles can cross the blood–brain barrier (BBB), but little is known about passage. Here, we used multiple-time regression analysis to examine the ability of 10 exosome populations derived from mouse, human, cancerous, and non-cancerous cell lines to cross the BBB. All crossed the BBB, but rates varied over 10-fold. Lipopolysaccharide (LPS), an activator of the innate immune system, enhanced uptake independently of BBB disruption for six exosomes and decreased uptake for one. Wheatgerm agglutinin (WGA) modulated transport of five exosome populations, suggesting passage by adsorptive transcytosis. Mannose 6-phosphate inhibited uptake of J774A.1, demonstrating that its BBB transporter is the mannose 6-phosphate receptor. Uptake rates, patterns, and effects of LPS or WGA were not predicted by exosome source (mouse vs. human) or cancer status of the cell lines. The cell surface proteins CD46, AVβ6, AVβ3, and ICAM-1 were variably expressed but not predictive of transport rate nor responses to LPS or WGA. A brain-to-blood efflux mechanism variably affected CNS retention and explains how CNS-derived exosomes enter blood. In summary, all exosomes tested here readily crossed the BBB, but at varying rates and by a variety of vesicular-mediated mechanisms involving specific transporters, adsorptive transcytosis, and a brain-to-blood efflux system.

Modest Blood-Brain Barrier Permeability of the Cyclodextrin Kleptose: Modification by Efflux and Luminal Surface Binding.

Cyclodextrins (CDs) have a variety of uses from acting as excipients to aiding the ability of lipid soluble drugs to cross the blood-brain barrier (BBB). They are being investigated as an active pharmaceutical ingredient, most recently for the treatment of Niemann-Pick disease, a lysosomal storage disease. Cyclodextrins are helpful in animal models and human subjects/patients afflicted with Neimann-Pick disease, including improving the neurologic component of the disease. The improvement in brain disease by intravenous administration implies that CDs can cross the BBB; however, there are only a few studies that have directly addressed this. In the current studies, multiple-time regression analysis indicated that 2-hydroxypropyl-β-cyclodextrin [Kleptose (Klep)] radioactively labeled with 14C (C-Klep) crossed the BBB at a slow rate by a nonsaturable mechanism consistent with transcellular diffusion. However, the rate of transport varied greatly by the brain region with no detectable uptake by the spinal cord; additionally, many regions rapidly reached equilibrium between the brain and blood. The presence of a brain-to-blood efflux system was also detected and much of the C-Klep did not completely cross the BBB, but loosely adhered to the luminal surface of brain endothelial cells. Peripheral tissues also took up C-Klep, with the kidney taking up the most, which is consistent with renal clearance. In conclusion, we demonstrated minimal uptake of the β-cyclodextrin Kleptose by the brain with accumulation being affected by efflux and reversible luminal binding. SIGNIFICANCE STATEMENT: This cyclodextrin, which produces therapeutic effects on the central nervous system after peripheral administration, penetrates the BBB poorly. Uptake by the brain to a therapeutic level will likely be difficult to achieve without giving high peripheral doses, bypassing the BBB, or otherwise altering penetration into the brain.

Ghrelin transport across the blood–brain barrier can occur independently of the growth hormone secretagogue receptor

ObjectiveThe blood–brain barrier (BBB) regulates the entry of substrates and peptides into the brain. Ghrelin is mainly produced in the stomach but exerts its actions in the central nervous system (CNS) by crossing the BBB. Once present in the CNS, ghrelin can act in the hypothalamus to regulate food intake, in the hippocampus to regulate neurogenesis, and in the olfactory bulb to regulate food-seeking behavior. The goal of this study was to determine whether the primary signaling receptor for ghrelin, the growth hormone secretagogue receptor (GHSR), mediates the transport of ghrelin from blood to brain. MethodsWe utilized the sensitive and quantitative multiple-time regression analysis technique to determine the transport rate of mouse and human acyl ghrelin (AG) and desacyl ghrelin (DAG) in wildtype and Ghsr null mice. We also measured the regional distribution of these ghrelin peptides throughout the brain. Lastly, we characterized the transport characteristics of human DAG by measuring the stability in serum and brain, saturability of transport, and the complete transfer across the brain endothelial cell. ResultsWe found the transport rate across the BBB of both forms of ghrelin, AG, and DAG, were not affected by the loss of GHSR. We did find differences in the transport rate between the two isoforms, with DAG being faster than AG; this was dependent on the species of ghrelin, human being faster than mouse. Lastly, based on the ubiquitous properties of ghrelin throughout the CNS, we looked at regional distribution of ghrelin uptake and found the highest levels of uptake in the olfactory bulb. ConclusionsThe data presented here suggest that ghrelin transport can occur independently of the GHSR, and ghrelin uptake varies regionally throughout the brain. These findings better our understanding of the gut-brain communication and may lead to new understandings of ghrelin physiology.

Bacterial melanin crosses the blood-brain barrier in rat experimental model.

BackgroundBacterial melanin has been proven to stimulate regeneration after CNS lesions. The purpose of this study was to test, whether bacterial melanin can enter the brain via the blood–brain barrier (BBB).MethodsBacterial melanin (BM) was radioactively labeled by the iodobead method and used to test the BBB permeability after systemic injection into rats. The unidirectional influx rate from the blood was calculated by multiple-time regression analysis. A subgroup of the animals was co-injected with non-labeled BM to determine if BM has a saturable transport across the BBB. The levels of radioactivity were determined in the serum and tissues. Arterial blood was sampled to obtain the level of I-BM at different time points after injection. After systemic perfusion with saline, animals were decapitated and brain, spinal cord, liver and kidney samples were obtained and homogenized to test the I-BM level.ResultsStudy results showed that radioactively-labeled bacterial melanin crossed the BBB, was enzymatically stable in blood and in brain parenchyma. Entry to brain was reduced when non-labeled BM was also present. Circulating melanin entered all regions of the CNS but the uptake was higher in lumbar spinal cord, thalamus, hypothalamus and substantia nigra. Liver and kidneys had high uptake rates of BM.ConclusionsThese results show that bacterial melanin has saturable transport across the BBB and selectively targets some CNS regions. Such transport may contribute to the neuroprotective action of bacterial melanin.

Fibroblast growth factor 19 entry into brain

BackgroundFibroblast growth factor (FGF)-19, an endocrine FGF protein mainly produced by the ileum, stimulates metabolic activity and alleviates obesity. FGF19 modulates metabolism after either intravenous or intracerebroventricular injection, and its receptor FGFR4 is present in the hypothalamus. This led to the question whether blood-borne FGF19 crosses the blood-brain barrier (BBB) to exert its metabolic effects.MethodsWe determined the pharmacokinetics of FGF19 permeation from blood to brain in comparison with its distribution in peripheral organs. Multiple-time regression analysis after intravenous bolus injection, in-situ brain perfusion, and HPLC assays were performed.ResultsFGF19 was relatively stable in blood and in the brain compartment. Significant influx was seen in the presence of excess unlabeled FGF19 in blood. This coincided with a slower decline of 125I-FGF19 in blood which suggested there was decreased clearance or peripheral tissue uptake. In support of an altered pattern of peripheral processing of 125I-FGF19 by excess unlabeled FGF19, the high influx to liver was significantly attenuated, whereas the minimal renal uptake was linearly accelerated. In the present setting, we did not detect a saturable transport of FGF19 across the BBB, as the entry rate of 125I-FGF19 was not altered by excess unlabeled FGF19 or its mouse homologue FGF15 during in-situ brain perfusion.ConclusionFGF19 remained stable in the blood and brain compartments for up to 10 min. Its influx to the brain was non-linear, non-saturable, and affected by its blood concentration and distribution in peripheral organs. Liver showed a robust and specific uptake of FGF19 that could be inhibited by the presence of excess unlabeled FGF19, whereas kidney clearance was dose-dependent.

Corticotropin-Releasing Hormone Receptor-1 in Cerebral Microvessels Changes during Development and Influences Urocortin Transport across the Blood-Brain Barrier

In this study we tested the hypothesis that receptor-mediated transport of urocortin across the blood-brain barrier (BBB) undergoes developmental changes. Urocortin is a peptide produced by both selective brain regions and peripheral organs, and it is involved in feeding, memory, mood, cardiovascular functions, and immune regulation. In BBB studies with multiple-time regression analysis, we found that neonatal mice had a significant influx of (125)I-urocortin. By contrast, adult mice did not transport urocortin across the BBB. Quantitative RT-PCR showed that corticotropin-releasing hormone receptor (CRHR)-1 was developmentally regulated in enriched cerebral microvessels as well as hypothalamus, being significantly higher in neonatal than adult mice. This change was less dramatic in agouti viable yellow mice, a strain that develops adult-onset obesity. The level of expression of CRHR1 mRNA was 33-fold higher in the microvessels than in hypothalamic homogenates. The mRNA for CRHR2 was less abundant in both regions and less prone to changes with development or the agouti viable yellow mutation. Supported by previous findings of receptor-mediated endocytosis of urocortin, these results suggest that permeation of urocortin across the BBB is dependent on the level of CRHR1 expression in cerebral microvessels. These novel findings of differential regulation of CRH receptor subtypes help elucidate developmental processes in the brain, particularly for the urocortin system.

Effects of triglycerides, obesity, and starvation on ghrelin transport across the blood–brain barrier

Human ghrelin is transported across the blood–brain barrier (BBB) of normal mice. Here, we studied the effects of triglycerides, obesity, and starvation in retired breeder mice maintained on a high fat diet, mice age-matched to the retired breeders but maintained on normal chow, and 8-week-old mice maintained on breeder chow. The rate of ghrelin transport across the BBB was studied by both the intravenous administration method of multiple-time regression analysis and by the brain perfusion method. We found that (1) obese, aged mice lost the ability to transport intravenously administered ghrelin across the BBB, resulting in an inverse relation between body weight and ghrelin BBB permeability; (2) serum triglycerides promoted transport of intravenously administered ghrelin across the BBB, whereas epinephrine had no effect; (3) fasting tended to promote ghrelin transport across the BBB as most readily shown in brain perfusion studies; (4) evidence suggested that a serum factor promoted ghrelin transport in 8-week-old mice. Overall, these results show that serum factors and physiological states influence the rate at which ghrelin is transported across the blood–brain barrier.

Starvation and Triglycerides Reverse the Obesity-Induced Impairment of Insulin Transport at the Blood-Brain Barrier

Insulin in the brain acts as a satiety factor, reduces appetite, and decreases body mass. Altered sensing by brain of insulin may be a leading cause of weight gain and insulin resistance. A decrease in the transport across the blood-brain barrier (BBB) of insulin may induce brain insulin resistance by inducing obesity. We here report that transport of iv administrated insulin across the BBB of obese mice, as measured by multiple-time regression analysis, was significantly lower than that in thin adult mice. The reduction in obese mice was reversed by starvation for 48 h. There were no differences in insulin transport rates across the BBB of obese, thin, or starved obese mice when studied by the brain perfusion model, demonstrating that BBB transport of insulin is modulated by circulating factors. In the brain perfusion study, the triglyceride triolein significantly increased the brain uptake of insulin, an effect opposite to that on leptin transport, in starved obese mice. Thus, circulating triglycerides are one of the systemic modulators for the transport of insulin across the BBB.

The fasting polypeptide FGF21 can enter brain from blood

FGF21 recently has been proposed as a missing link in the biology of fasting, raising the question of whether it directly reaches the brain. We used multiple time-regression analysis to quantify the influx rate of this polypeptide across the blood–brain barrier (BBB), size-exclusion chromatography to examine degradation, capillary depletion to differentiate entry into brain parenchyma from retention in the microvasculature, and measurement of efflux rate to determine a possible confounding effect on measurement of entry. FGF21 was 94% intact in serum and 75% in brain 10 min after intravenous bolus delivery. Its influx rate was 0.23 ± 0.12 μl/g-min, nearly four times faster than that of the vascular marker albumin. At 10 min, about 0.5% of the administered FGF21 was present in a gram of brain tissue. Of this, 70% reached the parenchyma of the brain. Co-injection of excess FGF21 failed to inhibit the influx, showing a lack of saturation. Efflux, which occurred at the same rate as the bulk reabsorption of cerebrospinal fluid, also was not saturable. In summary, FGF21 shows significant, non-saturable, unidirectional influx across the BBB.

Nesfatin-1 crosses the blood–brain barrier without saturation

Nesfatin-1 is an 82 amino acid peptide that suppresses food intake after intracerebroventricular injection. Nesfatin-1 and its precursor NUCB2 were identified by subtraction cloning in cell lines of both neuronal and adipocytic origin. This provides a strong basis for studies to determine how peripherally derived nesfatin-1 permeates the blood–brain barrier (BBB) to participate in its CNS actions and whether pharmacological delivery by the peripheral route is feasible. In this study, nesfatin-1 remained stable in blood at least 20 min after intravenous injection and permeated the BBB by a non-saturable mechanism. The influx rate of nesfatin-1 after intravenous delivery was 0.27 ± 0.11 μl/g-min, and 0.3% of nesfatin-1 reached brain parenchyma 10 min after injection. The lack of saturation of influx was shown by use of excess unlabeled nesfatin-1 in multiple-time regression analysis, capillary depletion, and in situ brain perfusion. After intracerebroventricular injection, nesfatin-1 had a half-time disappearance of 23.8 min, which was not significantly different from that of albumin. This indicates that nesfatin-1 exited the brain by bulk absorption of cerebrospinal fluid without a specific efflux transport system. We conclude that the permeation of nesfatin-1 is a non-saturable process in either the blood-to-brain or brain-to-blood direction. Thus, the limited penetration under physiological conditions does not limit the pharmacological delivery of this satiety peptide as a potential therapeutic agent.

Soluble receptor inhibits leptin transport

Evidence both from mice and cultured cells suggests an important role of soluble leptin receptors in obesity and leptin signaling. However, the direct effects of soluble receptors on leptin uptake by cells are not clear. This study shows that soluble leptin receptors antagonize the permeation of leptin across the mouse blood-brain barrier by reducing the binding and endocytosis of leptin. This is illustrated by analysis of radioactively labeled and fluorescent-tagged leptin in normal mice and in cultured cells overexpressing various forms of leptin receptors. Three constructs of soluble leptin receptors were generated in this study: ObRe (805 aa), ObR839, and ObR852. (125)I-leptin was injected intravenously and its influx rate from blood to brain determined by multiple-time regression analysis. Pre-incubation with ObR839 caused a significant reduction of leptin influx across the blood-brain barrier. Endocytosis assays and fluorescent image analysis further showed that ObRe, ObR839, and ObR852 failed to mediate leptin internalization and trafficking within the cells. Instead, these soluble receptors inhibited surface binding and endocytosis of leptin. Thus, we provide novel direct evidence both in vivo and in vitro that soluble receptors of leptin serve as antagonists of the transport of leptin.

Permeation of hepatocyte growth factor across the blood–brain barrier

Hepatocyte growth factor (HGF), mainly produced and acting in the periphery, attenuates cerebral ischemia-induced cell death and thus shows therapeutic potential in CNS regeneration. Accordingly, we tested its ability to permeate the blood–brain barrier (BBB). HGF was stable in the circulating blood of adult mice for up to 20 min, as HPLC showed intact 125I-HGF in both serum and brain homogenate. Multiple time regression analysis revealed a rapid blood-to-brain influx rate of 0.38 ± 0.07 μl/g min, faster than might be expected for a protein of this size. Although excess unlabeled HGF failed to inhibit of the influx of 125I-HGF in mice, the use of a higher dose of unlabeled HGF in cellular uptake studies showed the presence of saturable endocytosis. Furthermore, capillary depletion studies showed that about 32% of the HGF present in brain entered the parenchymal compartment in contrast to the 11% entrapped in endothelial cells 10 min after intravenous bolus injection. The amount of HGF that crossed the BBB in intact form was substantial and could be physiologically important in the CNS.

Reciprocal Interactions of Insulin and Insulin-Like Growth Factor I in Receptor-Mediated Transport across the Blood-Brain Barrier

Although the blood-brain barrier limits free passage of peptides and proteins from the peripheral circulation to the central nervous system, specific transport systems for insulin and IGF-I have been identified. To further determine whether insulin and IGF-I share the same transport system, and if not, whether the two transport systems interact with each other, we performed multiple-time regression analysis in mice after iv injection and in situ brain perfusion of these peptides. Insulin and IGF-I caused reciprocal inhibition of each other's transport, although the effect of insulin was detected only by the in situ brain perfusion system. The interaction took place mainly at the step of cell surface binding as seen in cultured rat brain endothelium 4 brain microvessel endothelial cells. Further studies in 3T3 cells stably overexpressing the insulin receptor showed that the sharing of the transport systems was only partial. We conclude that insulin and IGF-I are mainly transported by their own transport systems, but a small amount can enter the brain by their "noncognate" transporters. The redundancy of their transport systems illustrates the regulatory function of the blood-brain barrier and reflects the importance of blood-borne insulin and IGF-I in the central nervous system.

Permeation of Growth Hormone across the Blood-Brain Barrier

Exogenous GH can affect central nervous system function when given peripherally to animals and as a supplemental therapy to humans. This study tested whether GH crosses the blood-brain barrier (BBB) by a specific transport system and found that both mice and rats have small but significant uptake of GH into the brain without a species difference. Determined by multiple-time regression analysis, the blood-to-brain influx transfer constants of 125I-labeled rat GH in mice (0.23+/-0.07 microl/g.min) and rats (0.32+/-0.04 microl/g.min) were comparable to those of some cytokines of similar size, with a half-time disappearance of 125I-GH of 3.8-7.6 min in blood. Intact 125I-GH was present in both serum and brain homogenate 20 min after iv injection. At this time, about 26.8% of GH in brain entered the parenchyma, whereas 10% was entrapped in endothelial cells. Neither excess GH nor insulin showed acute modulation of the influx, indicating lack of a saturable transport system for GH at the BBB. Binding and cellular uptake studies in cultured cerebral microvessel endothelial cells (RBE4) further ruled out the presence of high-capacity adsorptive endocytosis. The brain influx of GH by simple diffusion adds definitive value to the long-disputed question of whether and how GH crosses the BBB. The central nervous system effects of peripheral GH can be attributed to permeation of the BBB despite the absence of a specific transport system.

Effect of lipopolysaccharide on the transport of pituitary adenylate cyclase activating polypeptide across the blood–brain barrier

Pituitary adenylate cyclase activating polypeptide (PACAP) has neuroprotective effects against ischemia, even when given by intravenous (iv) administration 24 h after stroke. Transport of PACAP across the blood–brain barrier (BBB) by peptide transport system (PTS)-6 underlies its effectiveness after iv administration. However, PACAP transport is modified after central nervous system (CNS) injury, raising the question of whether cytokines or BBB disruption affects PTS-6 activity. Lipopolysaccharide (LPS) is derived from bacterial cell walls and affects the passage of other proteins across the BBB through its release of cytokines and disruption of the BBB. Here, we examined by several methods the transport of radioactively labeled PACAP (I-PACAP) across the BBB after intraperitoneal (ip) injection of LPS. After three doses of LPS, studies at a single time point found a differential effect of LPS on the brain/serum ratio for I-PACAP and radioactively labeled albumin (I-Albumin). Whereas LPS increased the ratio for I-Albumin, demonstrating BBB disruption, it decreased the ratio for I-PACAP. Multiple-time regression analysis, capillary depletion, and brain perfusion showed that this decrease was fully explained by a decrease in the initial, reversible binding of I-PACAP to brain endothelium, while the rate of transport of PACAP into the brain was not altered. These methods also showed that the LPS-treated mice were volume contracted. This volume contraction concentrated the amount of I-PACAP in the blood and so increased the amount of I-PACAP presented to the BBB. Lack of change in transport rate combined with volume contraction resulted in a net increase of about 30% of the iv dose of I-PACAP entering the brain. LPS did not alter the efflux of I-PACAP from the CNS. In conclusion, PTS-6 remains active and should be able to deliver therapeutic amounts of PACAP to the CNS in brain injuries involving cytokine release and BBB disruption.

Passage of erythropoietic agents across the blood–brain barrier: a comparison of human and murine erythropoietin and the analog darbepoetin alfa

Studies have suggested that erythropoietin (EPO) may be used to treat stroke in both animals and humans. It is thought to exert its effects directly on the brain and studies with therapeutic doses have shown that it can cross the blood–brain barrier. Here, we compared in a blinded fashion the ability of three erythropoietic agents (murine erythropoietin, human erythropoietin, and darbepoetin alfa, an analog of human erythropoietin in clinical use) to cross the blood–brain barrier of the mouse. High-performance liquid chromatography (HPLC) results showed that all three erythropoietic agents were enzymatically resistant in brain and blood. The unidirectional blood-to-brain influx rates ( K i) as measured by multiple-time regression analysis showed that all the erythropoietic agents crossed the blood–brain barrier at about the same rate as albumin, suggesting that they cross the blood–brain barrier by way of the extracellular pathways. No saturable component to influx was found, but indirect evidence suggested a brain-to-blood efflux system. The percent of the intravenously injected dose taken up per gram of brain (%Inj/g) ranged from 0.05 to 0.1 %Inj/g among the three erythropoietic agents and peaked about 3 h after IV injection. For other substances, this range of %Inj/g is known to produce direct effects on brain function. We conclude that erythropoietic agents cross the blood–brain barrier by way of the extracellular pathways in amounts that are likely sufficient to explain their neuroprotective effects.

Different mechanisms influencing permeation of PDGF-AA and PDGF-BB across the blood-brain barrier.

Platelet-derived growth factor (PDGF) exerts neurotrophic and neuromodulatory effects on the CNS. To determine the permeability of the blood-brain barrier (BBB) to PDGF, we examined the blood-to-brain influx of radioactively labeled PDGF isoforms (PDGF-AA and PDGF-BB) by multiple-time regression analysis after intravenous (i.v.) injection and by in-situ perfusion, and also determined the physicochemical characteristics which affect their permeation across the BBB, including lipophilicity (measured by octanol:buffer partition coefficient), hydrogen bonding (measured by differences in octanol : buffer and isooctane : buffer partition coefficients), serum protein binding (measured by capillary electrophoresis), and stability of PDGF in blood 10 min after i.v. injection (measured by HPLC). After i.v. bolus injection, neither 125I-PDGF-AA nor 125I-PDGF-BB crossed the BBB, their influx rates being similar to that of the vascular marker 99mTc-albumin. 125I-PDGF-AA degraded significantly faster in blood than 125I-PDGF-BB. PDGF-BB, however, was completely bound to a large protein in serum whereas PDGF-AA showed no binding. Thus, degradation might explain the poor blood-to-brain influx of PDGF-AA, whereas protein binding could explain the poor influx of circulating PDGF-BB. Despite their lack of permeation in the intact mouse, both 125I-PDGF-AA and 125I-PDGF-BB entered the brain by perfusion in blood-free buffer, and the significantly faster rate of 125I-PDGF-AA than 125I-PDGF-BB may be explained by the lower hydrogen bonding potential of 125I-PDGF-AA. Thus, the lack of significant distribution of PDGF from blood to brain is not because of the intrinsic barrier function of the BBB but probably because of degradation and protein binding. Information from these studies could be useful in the design of analogues for delivery of PDGF as a therapeutic agent.

Characterization of blood-brain barrier permeability to PYY3-36 in the mouse.

Peptide YY3-36 (PYY) has emerged as an important signal in the gut-brain axis, with peripherally administered PYY affecting feeding and brain function. For these effects to be direct, PYY would have to cross the blood-brain barrier (BBB). Here, we determined the permeability of the BBB to PYY radioactively labeled with 131I (I-PYY). Multiple-time regression analysis showed the unidirectional influx rate (Ki) from blood-to-brain for I-PYY to be 0.49 +/- 0.19 microl/g-min, a rate similar to that previously measured for leptin. Influx was not inhibited by 1 microg/mouse of unlabeled PYY, suggesting PYY crosses the BBB by transmembrane diffusion. About 0.176% of the i.v.-injected dose of I-PYY was taken up by brain, an amount similar to that for other peptides important in gut-brain communication. Capillary depletion showed that 69% of I-PYY crossed the BBB to enter the parenchymal space of the brain, and high-performance liquid chromatography demonstrated that the radioactivity in this space represented intact I-PYY. After intracerebroventricular injection, I-PYY crossed from brain to blood by the mechanism of bulk flow. We conclude that PYY crosses in both the blood-to-brain and brain-to-blood directions by nonsaturable mechanisms. Passage across the BBB provides a mechanism by which blood-borne PYY can affect appetite and brain function.

Glial cell line-derived neurotrophic factor does not enter normal mouse brain

Glial cell line-derived neurotrophic factor (GDNF) is produced both in the central nervous system (CNS) and the periphery. Effective in ameliorating neurodegeneration in several animal models of CNS disease, its promise as a therapeutic agent would be greatly enhanced if it readily crossed the blood–brain barrier (BBB) in unmodified form. Here, we used the sensitive techniques of multiple-time regression analysis and ex-vivo perfusion in blood-free buffer to examine the entry of 125I-GDNF into mouse brain. The integrity of GDNF in blood and brain was examined by high performance liquid chromatography and the physicochemical properties determining permeability were measured by octanol/buffer partition coefficient and hydrogen bonding. The efflux of 125I-GDNF was determined to test for the presence of a bidirectional transport system. The results show that 125I-GDNF differs from other peptides and polypeptides in that it does not enter brain any faster than 99mTc-albumin, an effect that cannot be explained by degradation, rapid efflux, protein binding, or inadequate lipophilicity. Thus, GDNF shows a different type of interaction with the BBB. In normal mice, the BBB functions as a substantial physical barrier; in pathological or traumatic situations when the barrier is partially disrupted, the lack of restriction by a saturable transport system could make GDNF a suitable candidate for peripheral delivery in promoting neuroregeneration.