Angiogenesis in developing rat brain: an in vivo and in vitro study

Coordinate expression of vascular endothelial growth factor receptor-1 (flt-1) and its ligand suggests a paracrine regulation of murine vascular development

Vascular endothelial growth factor (VEGF) is a candidate regulator of blood vessel growth during embryonic development and in tumors. To evaluate the role of VEGF receptor-1/flt-1 (VEGFR1/flt-1) in the development of the vascular system, we have characterized the murine homolog of the human flt-1 gene and have analyzed its expression pattern during mouse embryogenesis. Receptor binding studies using transfected COS cells revealed that the murine flt-1 gene encodes a high affinity receptor for VEGF. The apparent Kd for VEGF binding, as determined by Scatchard analysis, was 114 pM, demonstrating that VEGFR1/flt-1 has a higher affinity to VEGF than VEGF receptor-2/flk-1 (VEGFR2/flk-1). By in situ hybridization, VEGFR1/flt-1 was detected in the yolk sac mesoderm already at the early stages of vascular development, while the receptor ligand was expressed in the entire endoderm of 7.5-day mouse embryos. A comparison with VEGFR2/flk-1 showed that the two receptors shared a common expression domain in the yolk sac mesoderm, but were expressed at different sites in the ectoplacental cone. The differential expression of the two VEGF receptors persisted in the developing placenta, where VEGFR1/flt-1 mRNA was detected in the spongiotrophoblast layer, whereas VEGFR2/flk-1 transcripts were present in the labyrinthine layer which is the site of VEGF expression. In the embryo proper, VEGFR1/flt-1 mRNA was specifically localized in blood vessels and capillaries of the developing organs, closely resembling the pattern of VEGFR2/flk-1 transcript distribution. In the developing brain, the expression of VEGF receptors in the perineural capillary plexus and in capillary sprouts which have invaded the neuro-ectoderm correlated with endothelial cell proliferation and brain angiogenesis. The data are consistent with the hypothesis that VEGF and its receptors have an important function both in the differentiation of the endothelial lineage and in the neovascularization of developing organs, and act in a paracrine fashion.

Effect of local administration of basic fibroblast growth factor against neuronal damage caused by transient intracerebral mass lesion in rats

There has been controversy regarding the best treatment for acute intracerebral hemorrhage. Early surgical evacuation alone seems to provide only limited amelioration of this condition, and additional therapeutic strategies should be investigated to obtain a better outcome. To test the feasibility of post-evacuation treatment, basic fibroblast growth factor (b-FGF) was administered into the evacuated cavity and its effect was evaluated in terms of the pathological changes around the lesion. A transient (10 min) intracerebral mass lesion was created by inflation of a microballoon in the caudate nucleus in rats. Basic-FGF (500 or 1000 ng) was injected into the evacuated cavity after deflation and removal of the balloon, and then histological changes were evaluated in the CA1 subfield of the hippocampus and cavity wall. The results demonstrate a protective effect against the neuronal damage in CA1 pyramidal cells and an increase of angiogenesis in the evacuated cavity wall after b-FGF administration. These observations suggest that local administration of b-FGF after evacuation may prevent secondary neuronal damage in the area surrounding an acute mass lesion and facilitate more rapid repair of the damaged brain.

Novel mouse endothelial cell surface marker is suppressed during differentiation of the blood brain barrier

Few markers specific for mouse endothelium exist. We describe here one such marker, MECA-32, a monoclonal antibody which shows high specificity for mouse endothelium in both embryonic and mature tissues. The MECA-32 antigen has a M(r) of 50-55 x 10(3) under reducing conditions and M(r) of 100-120 x 10(3) under nonreducing conditions. It is expressed on most endothelial cells in the embryonic and in the adult mouse, with the exception of the brain, skeletal, and cardiac muscle, where it has a more restricted distribution. In skeletal and cardiac muscle only small arterioles and venules express the MECA-32 antigen, while in the brain its expression is negatively correlated with the differentiation of the vasculature to form the blood brain barrier. Interestingly, during embryonic development the antigen occurs on the brain vasculature up to day 16 of gestation (E16), whereupon it disappears. The embryonic brain is an avascular organ anlage which is vascularized by ingrowth of external blood vessels. Differentiation of the vasculature to form the blood brain barrier occurs at approximately E16 in the mouse. This differentiation correlates with the downregulation of MECA-32 antigen expression. Between E12 and E16 MECA-32 detects most endothelial cell surfaces of the blood vessels in the brain. No MECA-32 antigen is found in the brain at E17 or any later stage of development with the exception of the vasculature of the circumventricular organs. The results suggest that MECA-32 antigen expression is temporally and spatially correlated with the development of the blood brain barrier.

Effects of transferrin receptor antibody-NGF conjugate on young and aged septal transplants in oculo

The purpose of this study was to investigate the effects of nerve growth factor (NGF) conjugated to a monoclonal transferrin receptor antibody (OX-26) on septal transplants in oculo. Three different doses of OX-26-NGF conjugate (0.3, 3, and 50 micrograms/injection) were injected into the tail vein of young adult hosts 2, 4, and 6 weeks following intraocular transplantation of fetal forebrain tissue containing septal nuclei. Intravenous injections of OX-26 alone, NGF alone, and saline served as controls. An increase in intraocular tissue growth, as well as an increase in the intensity of immunoreactivity for p75 receptors and acetylcholinesterase, was observed following peripheral OX-26-NGF administration at the two highest doses tested. In addition, aged host rats with 16-month-old intraocular septal grafts were injected intravenously with OX-26 or OX-26-NGF (10 micrograms NGF/injection) every 2 weeks until the transplants were 24 months old. The intensity of choline acetyltransferase-like (ChAT) staining appeared to be greater and the cell bodies were larger with more processes in aged transplants in hosts treated with the OX-26-NGF conjugate than in aged OX-26-treated subjects. The present results suggest that peripheral OX-26-NGF can deliver biologically active NGF across the blood-brain barrier and have dose-dependent positive effects on both aged and developing cholinergic neurons in septal transplants.

Immunocytochemical expression of the blood-brain barrier glucose transporter (GLUT-1) in neural transplants and brain wounds

The present study examined the immunocytochemical expression of the blood-brain barrier glucose transporter (GLUT-1) in a series of fetal neocortical transplants, autonomic tissue transplants, and stab wounds to the rat brain. GLUT-1 is one of a family of different glucose transporters and is found exclusively on barrier-type endothelial cells. In the brain it is responsible for the regulated facilitative diffusion of glucose across the blood-brain barrier. This investigation is the first to determine if this important molecule is altered during the process of angiogenesis that occurs following neural transplantation procedures or direct brain injury. Beginning in late fetal brain, e.g., E18 and continuing into maturity, GLUT-1 was strongly and exclusively expressed on normal cerebral vessels. In solid fetal central nervous system (CNS) transplants up to around 3 weeks postoperative, GLUT-1 was only weakly expressed, particularly as exemplified by colloidal gold immunostaining when compared with the host. At later times examined, up to 15 months postoperative, GLUT-1 immunoexpression was comparable with the normal adjacent brain. In autonomic tissue transplants, where the vessels do not have a blood-brain barrier, as expected, GLUT-1 was not expressed. In stab wounds, at 1 week there was extensive gliosis, and the injured vessels appeared fragmented and collapsed but still expressed GLUT-1, although to a somewhat lesser extent than normal brain. Between 3 and 6 weeks, GLUT-1 was expressed on tortuous vessels and in apparently fibrillar processes in the wound vicinity with a similar pattern to astrocyte (GFAP) reactivity. These results suggest the occurrence of a down-regulation of GLUT-1 in early transplants, perhaps related to reduced glycolytic activity or transient ischemia, or possibly due to the utilization of alternative energy sources. That GLUT-1 expression was not entirely lost in stab wounds to the mature brain suggests that the protein may be more labile in fetal or perinatal brain than in the adult and may not be affected by direct injury. Coupled with previous transplantation studies that have shown reduced neuronal glycolysis and potential barrier alterations, the reduction of GLUT-1 activity within nearly the identical time frame could indicate a relatively early critical period in cellular metabolism following transplantation of CNS tissue.

Glucose transport in developing rat brain: glucose transporter proteins, rate constants and cerebral glucose utilization

Developing rat brain undergoes a series of functional and anatomic changes which affect its rate of cerebral glucose utilization (CGU). These changes include increases in the levels of the glucose transporter proteins, GLUT1 and GLUT3, in the blood-brain barrier as well as in the neurons and glia. 55 kDa GLUT1 is concentrated in endothelial cells of the blood-brain barrier, whereas GLUT3 is the predominant neuronal transporter. 45 kDa GLUT1 is in non-vascular brain, probably glia. Studies of glucose utilization with the 2-14C-deoxyglucose method of Sokoloff et al., (1977), rely on glucose transport rate constants, k1 and k2, which have been determined in the adult rat brain. The determination of these constants directly in immature brain, in association with the measurement of GLUT1, GLUT3 and cerebral glucose utilization suggests that the observed increases in the rate constants for the transport of glucose into (ki) and out of (k2) brain correspond to the increases in 55 kDa GLUT1 in the blood-brain barrier. The maturational increases in cerebral glucose utilization, however, more closely relate to the pattern of expression of non-vascular GLUT1 (45 kDa), and more specifically GLUT3, suggesting that the cellular expression of the glucose transporter proteins is rate limiting for cerebral glucose utilization during early postnatal development in the rat.

Immunocytochemical distribution of the brain glucose transporter (GLUT 1) in experimental gliosis

The present study has examined the immunocytochemical expression of the blood-brain barrier glucose transporter GLUT 1 as compared with GFAP in models of experimental gliosis. In neocortical grafts, gliosis was prominent at the graft-host interface mostly associated with blood vessels. Consecutive sections examined for anti-GLUT 1 showed that the protein was distributed in nearly an identical pattern to the anti-GFAP, staining fibrillar processes and all vessels and also appeared extracellularly. In stab wounds, GLUT 1 immunoexpression was similar to GFAP reactivity and stained injured vessels and glial-like processes that were reminiscent of astrocytic end-feet. Normal glial cells and processes in unaffected neuropil, however, were never stained. This report suggests that GLUT 1 protein may be upregulated in non-endothelial components, such as reactive astroglia or possibly microglia, that are associated with injured or angiogenic vessels.

Experimental gliopathy in the adult rat CNS: effect on the blood-spinal cord barrier

The expression of certain blood-brain barrier (BBB) properties in CNS endothelial cells appear to be dependent on astroglial interactions in vitro. However, evidence for direct astroglial support of BBB function in vivo is controversial. To determine if perivascular astroglial damage or loss would compromise BBB function in situ, localized astroglial degeneration was produced in adult rat spinal cords by systemic injections of the anti-metabolite 6-aminonicotinamide (6-AN). Between 1 and 5 days after 6-AN administration, microvessels in the lumbar spinal cord (blood-spinal cord barrier) were examined for the expression of several BBB markers and for leakage of endogenous and exogenous proteins by means of immunocytochemical and histochemical procedures. Glial cells throughout the gray matter were swollen after 24 h, and by 5 days post-injection perivascular astroglia in laminae VI-VIII appeared completely degenerated. Microvessels were undamaged and continued to express BBB markers such as GLUT-I, gamma-glutamyltranspeptidase, and endothelial barrier antigen in this region in a manner comparable to control animals. These results suggest that differentiated, BBB-competent microvascular endothelia in situ may not depend on continuous astroglial support to maintain these particular BBB characteristics. However, the BBB to protein appeared to be compromised; the gray matter was immunoreactive for serum albumin and some areas were permeable to intravascularly injected horseradish peroxidase (HRP). No increase in microvascular transport vesicles was apparent, and no open, tracer-containing interendothelial junctions were detected using standard ultrastructural methods. Some venous structures were surrounded by hemorrhages and HRP reaction product. Thus, astrocytic injury may alter venous, and possibly microvascular, permeability to macromolecules.

Molecular mechanisms of developmental and tumor angiogenesis

Angiogenesis, the sprouting of capillaries from preexisting vessels, is of fundamental importance during embryonic development and is the principal process by which the brain and certain other organs become vascularized. Angiogenesis occurs during embryonic development but is almost absent in adult tissues. Transient and tightly controlled (physiological) angiogenesis in adult tissues occurs during the female reproductive cycle and during wound healing. In contrast, pathological angiogenesis is characterized by the persistent proliferation of endothelial cells, and is a prominent feature of diseases such as proliferative retinopathy, rheumathoid arthritis, and psoriasis. In addition, many tumors are able to attract blood vessels from neighbouring tissues. Tumor-induced angiogenesis requires a constitutive activation of endothelial cells. These endothelial cells dissolve their surrounding extracellular matrix, migrate toward the tumor, proliferate, and form a new vascular network, thus supplying the tumor with nutrients and oxygen and removing waste products. The onset of angiogenesis in human gliomas is characterized by the expression of genes encoding angiogenic growth factors such as vascular endothelial growth factor (VEGF), platelet-derived growth factor (PDGF) in tumor cells, and coordinate induction of genes in endothelial cells which encode the respective growth factor receptors. Developmental and tumor angiogenesis appear to be regulated by a paracrine mechanism involving VEGF and VEGF receptor-1 and -2.

Normal and abnormal development of the blood-brain barrier

The blood-brain barrier is responsible for the maintenance of the neuronal microenvironment. This is accomplished by isolation of the brain from the blood by the tight junctions that join endothelial cells in cerebral microvessels, and by selective transport and metabolism of substances from blood or brain by the endothelial cells. This review describes the growth and maturation of the brain vasculature, and the development of the special properties of the endothelia at the blood-brain interface. Evidence suggests that the development of the unique properties of the brain microvasculature is a consequence of tissue-specific interactions between endothelial cells of extraneural origin and developing brain cells. The cellular and molecular mechanisms that control these processes are as yet unknown but this review will include experimental studies which have used in vivo and in vitro systems to investigate what factors may be involved, and some pathological conditions in which abnormal barrier development is thought to be an important aspect of the disease process.

Molecular biology of blood-brain barrier ontogenesis and function

The vascular system of the central nervous system is derived from capillary endothelial cells, which have invaded the early embryonic neuroectoderm. This process is called angiogenesis and is probably regulated by brain-derived factors. Vascular endothelial cell growth factor (VEGF) is an angiogenic growth factor whose expression correlates with embryonic brain angiogenesis, i.e. expression is high in the embryonic brain when angiogenesis occurs and low in the adult brain when angiogenesis is shut off under normal physiological conditions. VEGF is also a vascular permeability factor (VPF) and, therefore, its expression is also consistent with the formation of the blood-brain barrier by brain endothelial cells, i.e. capillaries are leaky in the embryonic brain but are tight in the postnatal and adult brain. Thus, VEGF/VPF may be a key factor regulating endothelial cell growth and permeability. This notion is further supported by the observation that VEGF expression is induced and strongly upregulated in human malignant glioblastoma. This tumor is characterized by vascular proliferations, vascular leakage and edema. The differentiation of blood-brain barrier endothelial cells is probably regulated by astrocytes which form foot processes apposed to the abluminal vascular basement membrane. Blood-brain barrier endothelial cells express a set of cell surface proteins that are absent from permeable capillaries. We have characterized one such novel transmembrane glycoprotein which is a new member of the immunoglobulin superfamily. This protein and the analysis of the in vitro characteristics of brain endothelial cells may help to define the molecular mechanisms that are involved in blood-brain barrier induction and permeability.

Developmental expression of GLUT1 and GLUT3 glucose transporters in rat brain

Two glucose transport proteins, GLUT1 and GLUT3, have been detected in brain. GLUT1 is concentrated in the endothelial cells of the blood-brain barrier and may be present in neurons and glia; GLUT3 is probably the major neuronal glucose transporter. Of the few studies of glucose transport in the immature brain, none has quantified GLUT3. This study used membrane isolation and immunoblotting techniques to examine the developmental expression of GLUT1 and GLUT3 in four forebrain regions, cerebral microvessels, and choroid plexus, from rats 1-30 days postnatally as compared with adults. The GLUT1 level in whole brain samples was low for 14 days, doubled by 21 days, and doubled again to attain adult levels by 30 days; there was no regional variation. The GLUT3 level in these samples was low during the first postnatal week, increased steadily to adult levels by 21-30 days, and demonstrated regional specificity. The concentration of GLUT1 in microvessels increased steadily after the first postnatal week; the GLUT1 level in choroid plexus was high at birth, decreased at 1 week, and then returned to near fetal levels. GLUT3 was not found in microvessels or choroid plexus. This study indicates that both GLUT1 and GLUT3 are developmentally regulated in rat brain: GLUT1 appears to relate to the nutrient supply and overall growth of the brain, whereas GLUT3 more closely relates to functional activity and neuronal maturation.

Expression of tie-2, a member of a novel family of receptor tyrosine kinases, in the endothelial cell lineage

We are interested in the molecular mechanisms that are involved in the development of the vascular system. In order to respond to morphogenetic and mitogenic signals, endothelial cells must express appropriate receptors. To characterize endothelial cell-specific receptors, we have concentrated on receptor tyrosine kinases, because several lines of evidence suggested the importance of controlled phosphotyrosine levels in endothelial cells. A strategy based on PCR amplification using degenerate oligonucleotides and mouse brain capillaries as mRNA source, led to the identification of a novel receptor tyrosine kinase, which we designated tie-2. In situ hybridization using a tie-2-specific probe revealed an interesting spatial and temporal expression pattern. The gene was expressed specifically in the endothelial lineage. tie-2 transcripts were present in endothelial cell precursors (angioblasts) and also in endothelial cells of sprouting blood vessels throughout development and in all organs and tissues so far examined. tie-2 was down-regulated in the adult. Because of the unusual combination of immunoglobulin, EGF-like and fibronectin type III domains in the extracellular portion of tie-2 which is shared by TEK and tie, these molecules may be considered members of a new family of receptor tyrosine kinases. Signal transduction via this new class of tyrosine kinases could lead to a better understanding of the molecular mechanisms of blood vessel formation.

An electron microscopic immunogold analysis of developmental up-regulation of the blood-brain barrier GLUT1 glucose transporter

Electron microscopy was used to quantitate blood-brain barrier (BBB) glucose transporters in newborn, 14-day-old suckling, 28-day-old weanling, and adult rabbits. A rabbit polyclonal antiserum to a synthetic peptide encoding the 13 C-terminal amino acids of the human erythrocyte glucose transporter (GLUT1) was labeled with 10-nm gold particle-secondary antibody conjugates and localized immunoreactive GLUT1 molecules in rabbit brain capillary endothelia. Three distinct populations of brain capillary profiles were identified in newborn rabbits: prepatent capillary buds, partially patent capillaries with highly amplified luminal membranes, and patent capillaries. Immunogold analyses indicated that the GLUT1 transporter abundance positively correlated with capillary developmental status. The mean number of gold particles per capillary profile increased at each developmental age examined, suggesting that developmental up-regulation of the BBB glucose transporter occurred in rabbits. GLUT1 immunoreactivity was three- to fourfold greater on the abluminal than luminal capillary membranes among all ages examined. Changes in the proportions of GLUT1 transporter were also seen, and possible reasons for the postnatal decrease in the percentage of cytoplasmic GLUT1 transporter are discussed. The numbers of cytoplasmic and membrane-associated immunogold particles increased with age. We conclude that regulatory modulations of BB glucose transport may be characterized by increases in BBB glucose transporter density with age and state of development. In addition, modulation of glucose transporter activity may be reflected by minor postnatal shifts of GLUT1 from cytoplasmic to membrane compartments, which can be demonstrated with quantitative immunogold electron microscopy.

Effect of astroglial degeneration on the blood-brain barrier to protein in neonatal rats

Recent in vitro studies have suggested that astrocytes may be responsible for the induction of several blood-brain barrier (BBB) characteristics. To examine this hypothesis in an in vivo situation, we have investigated the effect of chronic astrocytic deprivation on the BBB to proteins in neonatal rats. Intraperitoneal injections of the gliotoxin 6-aminonicotinamide (6-AN) resulted in cytotoxic edema with subsequent necrobiosis of differentiated astrocytes and oligodendrocytes throughout the CNS. Animals were sacrificed 1-5 days after chronic exposure to 6-AN during the first postnatal week. Animals sacrificed 24 h after the final injection of 6-AN had the greatest depletion of perivascular astroglia. The BBB to exogenous protein, examined by intravascular administration of horseradish peroxidase, remained intact, as did the BBB to endogenous protein as determined by immunocytochemical detection of rat serum albumin. In no case was any leakage of protein found other than in areas that do not normally possess BBB characteristics. These data show that CNS endothelial cells retain BBB characteristics without a full complement of astrocytic contacts. Since the astroglial cytoplasm was destroyed and only membrane fragments remained, we suggest that factors continuously produced by astroglia cannot be responsible for the induction and maintenance of the BBB to protein, but that substances produced during the prenatal period may be the primary determinant of endothelial phenotype.

High affinity VEGF binding and developmental expression suggest Flk-1 as a major regulator of vasculogenesis and angiogenesis

Examination of flk-1 receptor tyrosine kinase mRNA expression by in situ hybridization analysis revealed specific association with endothelial cells at all stages of mouse development, including the blood islands in the yolk sac of day 8.5-10.5 embryos, in which the early progenitors of this lineage originate. flk-1 transcripts were abundant in proliferating endothelial cells of vascular sprouts and branching vessels of embryonic and early postnatal brain, but were drastically reduced in adult brain, where proliferation has ceased. Identification of the angiogenic mitogen, vascular endothelial growth factor (VEGF), as the high affinity ligand of Flk-1 and correlation of the temporal and spatial expression pattern of Flk-1 and VEGF suggest a major role of this ligand-receptor signaling system in vasculogenesis and angiogenesis.

Ontogeny of the erythroid/HepG2-type glucose transporter (GLUT-1) in the rat nervous system

Central nervous system (CNS) microvessels of adult mammals have an unusually high density of the facilitative glucose transporter GLUT-1. Most systemic microvessels and those of the brain's circumventricular organs, which lack 'barrier' properties, do not express a high density of GLUT-1. Thus, a high GLUT-1 density is a marker of adult brain endothelium. To determine the stage at which CNS microvessels acquire GLUT-1, we studied by immunocytochemistry GLUT-1 ontogeny in the rat CNS from embryonic day (E) 11 to senescence. At E11, before blood vessels invaded the neuroectodermal tube, GLUT-1 immunoreactivity was already evident in the perineural plexus of vessels and in most of the vascular endothelium of the embryo. GLUT-1 immunoreactivity was also evident in the neuroectoderm. The neuroectoderm gradually lost GLUT-1 expression, and at about E16, GLUT-1 immunoreactivity was no longer detectable in most of the neuroectodermal epithelium, while CNS microvessels had increased their GLUT-1 immunoreactivity. By birth, GLUT-1 immunoreactivity in the CNS was restricted to the endothelium, the epithelium (but not the endothelium) of the choroid plexus, and tanycytes. This cellular distribution of GLUT-1 did not change much between birth and senescence despite considerable postnatal brain development and the increased brain capillary density. Our results suggest that while a CNS factor(s) may not have a role in the induction of the high expression of GLUT-1 in CNS endothelium, such a factor(s) is probably important in maintaining the high level of GLUT-1 in these endothelia.

Dexamethasone reduces vascular density and plasminogen activator activity in 9L rat brain tumors

Angiogenesis, a process dependent upon perivascular proteolysis, is required for solid tumor growth and is inhibited by certain steroids including glucocorticoids. We examined the relationship between tumor growth and vessel density in experimental rat brain 9L glial tumors following chronic treatment with the glucocorticoid dexamethasone. Tumor growth was inhibited by intraperitoneal administration of 3 mg/kg/day dexamethasone. Maximal cross-sectional areas of post-implantation day 9 tumors were 4.6 +/- 1.0 mm2 in dexamethasone-treated animals and 17.0 +/- 3.4 mm2 in controls (P < 0.01). Microvessel density assessed by laminin immunohistochemistry was 59% lower in dexamethasone-treated tumors (P < 0.01). Plasminogen activator (PA) activity, a proteolytic enzyme related to endothelial migration and vessel growth, was 4.2 +/- 0.9 IU/micrograms protein in dexamethasone-treated tumors and 9.0 +/- 1.0 IU/micrograms protein in control tumors (P < 0.01). Exposure of cultured 9L and central nervous system microvessel endothelial cells to dexamethasone concentrations comparable to those achieved in vivo had no effect on cell growth, but reduced the PA activity of culture supernatant fractions by 78% and 99%, respectively. These findings suggest that inhibition of proteolytic steps involved in vessel growth may underlie, in part, the mechanism by which glucocorticoids decrease brain tumor growth.

Inhibition of astroglia-induced endothelial differentiation by inorganic lead: a role for protein kinase C

Microvascular endothelial function in developing brain is particularly sensitive to lead toxicity, and it has been hypothesized that this results from the modulation of protein kinase C (PKC) by lead. We examined the effects of inorganic lead on an in vitro model of central nervous system endothelial differentiation in which astroglial cells induce central nervous system endothelial cells to form capillary-like structures. Capillary-like structure formation within C6 astroglial-endothelial cocultures was inhibited by lead acetate with 50% maximal inhibition at 0.5 microM total lead. Inhibition was independent of effects on cell viability or growth. Under conditions that inhibited capillary-like structure formation, we found that lead increased membrane-associated PKC in both C6 astroglial and endothelial cells. Prolonged exposure of C6 cells to 5 microM lead for up to 16 h resulted in a time-dependent increase in membranous PKC as determined by immunoblot analysis. Membranous PKC increased after 5-h exposures to as little as 50 nM lead and was maximal at approximately 1 microM. Phorbol esters were used to determine whether PKC modulation was causally related to the inhibition of endothelial differentiation by lead. Phorbol 12-myristate 13-acetate (10 nM) inhibited capillary-like structure formation by 65 +/- 5%, whereas 4 alpha-phorbol 12,13-didecanoate was without effect. These findings suggest that inorganic lead induces cerebral microvessel dysfunction by interfering with PKC modulation in microvascular endothelial or perivascular astroglial cells.

Some effects of aluminium on rat brain protein synthesis

1. Infant rats and rabbits received intraperitonal aluminium (Al) chloride (5, 10 or 20 mg Al/kg body weight) every third day from one to four weeks of age. 2. When the polysomal fraction was tested in a protein synthesizing system, a significant increase in the incorporation of [14C] leucine, [14C] phenylalanine, or [35S] methionine into proteins in vitro was observed at the higher doses in rats but not rabbits. 3. The incorporation of [35S]methionine into brain ferritin was measured using polysomal mRNA or mRNA "stored" in the ribonucleoprotein (RNP) particle fraction. 4. The results suggest that Al exposure causes the mobilization of ferritin mRNA from the latter fraction to the polysomal fraction for increased ferritin synthesis.

Morphological differentiation of endothelial cells co-cultured with astrocytes on type-I or type-IV collagen

In this study bovine aortic endothelial cells were co-cultured with astrocytes from fetal Wistar Kyoto rats. Endothelial cells growing on type-I collagen, co-cultured with astrocytes, showed various stages of development. Although some cells appeared to be mature, horseradish peroxidase penetrated within 1 min of incubation through the intercellular junctions of these endothelial elements maintained on type-I collagen. In contrast, endothelial cells on type-IV collagen, co-cultured with astrocytes, were well developed; their intercellular junctions were well established, and plasmalemmal vesicles reduced in number. As a result, horseradish peroxidase was unable to penetrate through the endothelial cells grown on type-IV collagen and co-cultured with astrocytes because of the reduced extent of the junctional and vesicular transport. These findings reveal that (1) type-IV collagen is essential for the differentiation of endothelial cells, (2) endothelial cell-astrocyte interactions occur during co-culture, and (3) endothelial permeability depends on astrocyte-produced factors, in addition to type-IV collagen.

Unilateral naris closure and vascular development in the rat olfactory bulb

The blood supply to the brain has been linked closely to nervous system function and metabolism, thereby possibly playing a direct role in brain maturation. Previously, we demonstrated that closure of an external naris early in life results in large changes within the olfactory bulb, including reductions in laminar volume and cell number and a rapid decline in metabolism and protein synthesis. To understand the role of the blood supply in the dramatic changes following naris closure, the present study examines the development of olfactory bulb vasculature in unilaterally odor-deprived and control rats. On post-partum day 1 (P1; the day after birth), littermate rat pups underwent either unilateral naris occlusion or sham surgery. On P5, P10, P15, P20, P30 and P60, animals were perfused with an india ink-gelatin mixture to assess blood vessel amount and complexity. Densitometric analyses were performed to obtain values of blood vessel area ratios (vessel area/tissue area), branch point number and branch point density. Considerable vessel development in all bulbs occurred over the first two to three weeks post-partum. By P20, large reductions in vessel area ratios were observed in all constituent laminae of deprived bulbs. While similar reductions in number of vessel branch points/tissue area were seen, few changes were noted in the number of branch points/vessel area. The effects were primarily confined to early developmental periods: bulb vasculature in animals deprived at older ages (P40) appeared normal. The results indicate that the vasculature responds to alterations in sensory stimulation early in life, therefore potentially playing an important regulative role in neural development.

Exercise and the brain: angiogenesis in the adult rat cerebellum after vigorous physical activity and motor skill learning

This study compared the morphology of cerebellar cortex in adult female rats exposed for 1 month to repetitive exercise, motor learning, or an inactive condition. In the exercise conditions, rats that were run on a treadmill or housed with access to a running wheel had a shorter diffusion distance from blood vessels in the molecular layer of the paramedian lobule when compared to rats housed individually or rats that participated in a motor skill learning task. Rats taught complex motor skills substantially increased the volume of the molecular layer per Purkinje neuron and increased blood vessel number sufficiently to maintain the diffusion distance. These results dissociate angiogenesis associated with increased neuropil volume (as seen in the motor learning group) from angiogenesis associated with increased metabolic demands (as seen in the exercise groups). While the volume fraction of mitochondria did not differ among groups, the mitochondrial volume fraction per Purkinje cell was significantly increased in the motor skill rats. This appears to parallel the previously reported increase in synapses and associated neuropil volume change.

Transferrin and iron uptake by the brain: effects of altered iron status

Transferrin (Tf) and iron uptake by the brain were measured in rats using 59Fe-125I-Tf and 131I-albumin (to correct for the plasma content of 59Fe and 125I-Tf in the organs). The rats were aged from 15 to 63 days and were fed (a) a low-iron diet (iron-deficient) or, as control, the same diet supplemented with iron, or (b) a chow diet with added carbonyl iron (iron overload), the chow diet alone acting as its control. Iron deficiency was associated with a significant decrease and iron overload with a significant increase in brain nonheme iron concentration relative to the controls. In each dietary treatment group, the uptake of Tf and iron by the brain decreased as the rats aged from 15 to 63 days. Both Tf and iron uptake were significantly greater in the iron-deficient rats than in their controls and lower in the iron-loaded rats than in the corresponding controls. Overall, iron deficiency produced about a doubling and iron overload a halving of the uptake values compared with the controls. In contrast to that in the brain, iron uptake by the femurs did not decrease with age and there was relatively little difference between the different dietary groups. 125I-Tf uptake by the brains of the iron-deficient rats increased very rapidly after injection of the labelled proteins, within 15 min reaching a plateau level which was maintained for at least 6 h. The uptake of 59Fe, however, increased rapidly for 1 h and then more slowly, and in terms of percentage of injected dose reached much higher values than did 125I-Tf uptake.(ABSTRACT TRUNCATED AT 250 WORDS)

Developmental changes of acidic fibroblast growth factor (aFGF) transcription and expression in mouse brain

In order to increase our knowledge of the in vivo role of acidic fibroblast growth factor (aFGF) in the central nervous system, we have examined aFGF levels during mouse brain development. Using a specific polyclonal antibody raised against aFGF, we measured levels of aFGF-immunoreactive material (IRMaFGF) in extract of total mouse brain taken at different days of development. We found that the level of measurable IRMaFGF remained low and without significant variation during fetal brain development (0.2 ng/mg of extracted proteins). During the first 11 days postnatal (P0 to P11), IRMaFGF increased from 0.5 to 1.5 ng/mg. Between P11 and P14 IRMaFGF levels went up more rapidly, reaching 5 ng/mg. From P30 to adulthood a constant value of 2.5 ng/mg was measured, aFGF content in the different brain extracts was further characterized by its affinity for heparin-Sepharose, its elution at 1 M NaCl from this column and its capacity to induce thymidine incorporation in quiescent fibroblasts. These results were confirmed at the mRNA level. Northern blot analyses of poly A+ mRNA from brains with a specific riboprobe for bovine aFGF, revealed a major 4.5-Kb transcript and a minor 2.7-Kb transcript detectable only in postnatal brains. A similar pattern to that observed for IRMaFGF was seen with these mRNA transcripts, indicating that these aFGFmRNA are translated in the mouse brain. Our results suggest that aFGF may act in the postnatal phases of brain maturation.

Permeability to blood-borne protein and 3HGABA in CNS tissue grafts. I. Intraventricular grafts

In the present study, solid grafts of fetal CNS tissue from the rat neocortex, cerebellum, or ventral mesencephalon were placed into the lateral, III or IV ventricles of young adult hosts. Survival periods ranged from 2 days to 20 months. To study the permeability to protein and potential changes in the blood-brain barrier (BBB), macromolecules such as HRP, HRP-human serum albumin, and HRP-human IgG were administered intravascularly and circulated for periods between 3 minutes and 1 hour. Younger grafts were completely filled with the protein, even at 2 days, when the graft vasculature already contained host macrophages, whereas all older grafts showed variability in permeation with protein ingress initiating at the graft-host interface and subsequently diffusing through the extracellular spaces. Permeation was from several sources: permeable vessels of the circumventricular organs and the choroid plexus which grew into the grafts, the perivascular spaces surrounding these vessels, or from the normally impermeable vessels of the pia mater, which, because of their engulfment by the graft and subsequent angiogenesis, may have been rendered permanently leaky. Invading vessels were often "cuffed" by lymphocytic cells. Many grafts were only partially filled by the glycoprotein conjugates; ventral mesencephalic grafts allowed the least diffusion even when vascularized by choroidal vessels. Fenestrated vessels were not directly observed even though petechial leaks were evident and vessels indigenous to the CNS grafts retained BBB properties. To determine endogenous protein exudation, noninjected animals were immunocytochemically examined for rat serum albumin (RSA). The distribution of RSA mimicked that of the injected proteins at interface regions, although in most instances the entire graft was filled by a light, diffuse labeling suggesting a steady-state protein leakage over the life of the graft. When HRP was delivered intraventricularly, the intraventricular grafts were nearly filled with reaction product by 20 minutes. The depth of penetration in the grafts from the CSF interface was generally threefold greater than in normal brain. The increase in permeation suggests that solutes may flow through these grafts (out of or into the CSF) at an increased rate. Lastly the neurotransmitter tritiated gamma-aminobutyric acid (3HGABA) which does not cross the BBB was vascularly administered to hosts bearing neocortical grafts. These experiments not only confirmed the permeability in these grafts but showed that the blood-borne amino acid could be directly sequestered by grafted neurons or glia.(ABSTRACT TRUNCATED AT 400 WORDS)

Brain angiogenesis: variations in vascular basement membrane glycoprotein immunoreactivity

Changes in the distribution and quantity of laminin and fibronectin within the basement membranes of developing or regenerating CNS blood vessels were investigated using two immunocytochemical techniques. Three models of angiogenesis were studied: normal pre- and postnatal development, wound healing, and vascularization of fetal neocortical transplants placed in the adult rat brain. Although all brain vessels were stained in enzymatically pretreated immunoreacted paraffin sections, those associated with wound and transplant sites were the most intensely reactive with both antisera during the first postoperative week. When 40-microns vibratome sections of normal adult brains were immunoprocessed, only the meninges and vessels of the circumventricular organs were stained. The remainder of the brain vasculature was immunoreactive only if sections were enzymatically treated prior to immunoprocessing. In contrast, the nascent vasculature in developing brain and the regenerating vessels at wound and transplant sites were reactive to both antisera without enzymatic pretreatment of the sections. This immunoreactivity decreased by 11 days postnatal in normal animals and 4 weeks postoperative in experimental animals, coinciding with the period of astrocytic contact and complete vascular basement membrane formation in both cases. The variations in staining pattern and intensity may be reflections of differences in the quantity of laminin and fibronectin within the basement membranes of proliferating and/or non-blood-brain barrier vasculature. However, the results of the different experimental protocols suggest that immature vascular basement membranes may have a molecular configuration that does not require an enzymatic unmasking step to react with the antisera. Alternatively, the looseness of the surrounding neuropil inherent in developing and injured CNS could allow the antisera greater access to basement membrane antigens.

Embryonic angiogenesis factors

The vascular system develops during embryonic development by at least two distinct processes; vasculogenesis is the development of blood vessels from in situ differentiating angioblasts and angiogenesis is the sprouting of capillaries from pre-existing vessels. The molecular mechanisms involved in the regulation of these processes are poorly understood. Endoderm-mesoderm interactions seem to play an important role in angioblast differentiation and vasculogenesis. Soluble angiogenic factors may be involved in the vascularization of some embryonic organs, e.g. kidney and brain. Angiogenic growth factors have been isolated and purified from embryonic brain and identified as acidic and basic fibroblast growth factors. More specific endothelial cell growth factors such as platelet-derived endothelial cell growth factor and vascular endothelial growth factor may also play a role in embryonic angiogenesis.

Immunohistochemical study of the vasculature in the developing brain

In this study, the developmental proliferation of human brain vessels, from the fetal to the adult stage, was analyzed by immunohistochemical methods using antitype IV collagen, antilaminin, and antifibronectin antibodies. Examination of the frontal lobe indicates that these antibodies bind to the vessels, both arteries and veins. During cortical angiogenesis, the density and diameter of vessels increase rapidly from about 26 weeks gestation and peak at 35 weeks; after 35 weeks, the density and diameter of vessels are the same as those in adult brain. The white matter demonstrates no major changes in vessel density, although the pattern of the changes in vessel diameter resembles that of the cortex. Small immunopositive spots suggesting neovascularization reveal the same developmental tendency as the density of vessels in the cortex and white matter; therefore, it appears that neovascularization in the fetal brain during development is more rapid than cortical expansion and is equal to the growth of white matter. Neovascularization may be closely related to normal brain development and may play an undefined role in perinatal cerebrovascular insults.

Developmental changes in transferrin and iron uptake by the brain in the rat

The uptake of transferrin and iron by the brain, liver and femurs was investigated in rats using 125I-59Fe-transferrin (Tf), and 131I-albumin in order to measure the plasma content of the organs. Measurements in rats ranging in age from birth to 70 days revealed that the rate of iron uptake by the brain increased rapidly over the first 15 days of life, peaking at 15 days and thereafter declining. A similar pattern occurred in the uptake of 125I-Tf. These changes were accompanied by rapid growth of the brain up to 15 days and a decrease in the concentration of non-haem iron. The turnover of 59Fe and 125I-Tf in the brain was also determined by measuring radioactivity in the brain of 15-day rats at various times after injection from 15 min to 13 days. The amount of 59Fe in the brain increased over the first 4 h and thereafter remained constant. By contrast, the 125I-Tf values increased rapidly during the first 15 min to reach a relatively constant level which was maintained for at least 6 h after which it declined. The patterns of uptake by the brain were different from those found in the liver and femurs, indicating that the changes in the brain were specific for that organ.(ABSTRACT TRUNCATED AT 250 WORDS)

Development of the blood-brain barrier

The microenvironment of the CNS is important for neuronal function, and the blood-brain barrier is involved in its maintenance. The barrier is present in a complex cellular system at the level of the tight junctions between endothelial cells. The unique properties of the endothelial cells in the CNS compared with those present in other organs are not predetermined by brain-specific endothelial precursors but are induced by the neural environment during the development of the vascular system. Astrocytes that tightly appose endfeet onto the abluminal side of brain capillaries seem to be important for the induction and maintenance of the endothelial barrier.

Fibroblast growth factor (FGF) levels in the developing rat brain

Acidic and basic fibroblast growth factors (FGF) are polypeptides with potent multipotential trophic effects on central nervous system (CNS) glia, endothelial cells, and neurons. These factors are characterized by strong binding to heparin, and are commonly assayed by their mitogenic activity on Balb/c 3T3 cells in vitro. We found a marked (ca. 13-fold) increase in Balb/c 3T3 mitogenic activity in the developing rat brain from the embryonic stage to the third postnatal week. High levels were sustained in the mature brain. Most of the mitogenic activity from rat brain bound strongly to heparin-affinity columns, and was eluted at positions characteristic of acidic FGF (aFGF) and basic FGF (bFGF). The presence of aFGF and bFGF in eluted peaks was confirmed by immunoblotting techniques using specific anti-FGF sera. Heparin-affinity high performance liquid chromatography (HPLC) showed a proportionately greater increase in levels of aFGF than bFGF between the tenth and fortieth postnatal days. Increases in FGF levels during late embryonic and early postnatal stages of brain development may play an important role in the glial and capillary proliferation, as well as in the neuronal outgrowth and synapse formation that is occurring during this time. The differential rates of accumulation of aFGF vs bFGF suggest different physiological roles for these factors in the developing brain.

Postnatal development of vascularity in the inferior colliculus of the young rat

The inferior colliculus in the rat midbrain is an auditory relay center whose functional maturation occurs postnatally. We examined by morphometry the vascularity and the nuclear profile density of the inferior colliculus in normal young rats at different ages (before and after the onset of auditory input). We also compared this region with a frontal region of the cerebral cortex in 24-day-old rats. The inferior colliculus from aldehyde-perfused Sprague-Dawley rats aged 5, 9, 14, and 24 days was analyzed by light microscopy of semithin plastic sections. The central region (mostly the central nucleus) was sampled at 5 levels representing its entire rostrocaudal extent. Patent-blood-vessel profiles were counted and classified according to their size and profile orientation. Counts of nuclear profiles in the same sections were also made. In the inferior colliculus of rats between 5 and 24 days of age, the small (less than 10-microns diameter) cross-sectioned vessel profiles increased over 6-fold in number per unit area. Correspondingly the vascular volume density, estimated by differential point counting, increased between these ages. However, there was a decrease in the number of neuronal and glial nuclear profiles per unit area, probably because of growth in the volume of the neuronal perikarya and processes, along with cell emigration reported to occur at early postnatal ages. This study has shown that an increase in vascularity in the central region of the rat inferior colliculus continues for up to 2 weeks after the onset of hearing.(ABSTRACT TRUNCATED AT 250 WORDS)

Local and remote microvascular changes in excitotoxin-induced focal brain lesions

We have examined the changes in the microvascular diameter, number/mm2 (NA) and area (AAi%) which occur after local brain lesions by the excitotoxin ibotenic acid (IBO). Rats (n = 18) were anesthetized with halothane. IBO (10 micrograms in 1 microliters of phosphate buffer) or vehicle was microinjected in a target region of the parietal cortex via glass micropipettes stereotaxically placed and animals were allowed to recover. Four 9, 15 and 30 days later rats were sacrificed and their brains removed, sectioned (thickness: 20 microns) and processed for the microvascular marker alkaline phosphatase. AAi%, NA and diameter were measured in the area of the lesion and in the homotopic contralateral cortical area by computer-assisted image analysis. In the lesion, AAi% increased by 83% at day 4, reached its maximum at day 9 (+227%) and then declined. Vascular diameter and NA also increased. However while diameter peaked at day 9 (+75%), Na reached its maximum at day 15 (+50%), at a time when AAi% was declining. In the contralateral cortex diameter increased at day 9 (+21%) but NA decreased (-35%) resulting in unchanged vascular area. Thus, focal brain lesions by excitotoxins produce substantial local and remote microvascular changes which have different patterns and may be mediated by distinct cellular and molecular mechanisms.

Vascularization of fetal cell suspension grafts in the excitotoxically lesioned adult rat thalamus

Several studies have considered the establishment of vascularization in intracerebral solid transplants of neural tissue. The widely supported interpretation of the results is that the vascular network of the solid grafts is already present before implantation into the host brain. The situation is different when dissociated fetal tissue is transplanted as a cell suspension because in these conditions the fetal vascular network is disrupted. The present study has, therefore, been undertaken to follow the angiogenesis in a transplant of dissociated fetal cells implanted into the excitotoxically neuron-depleted thalamus. The vascular network is compared to that observed in the intact and in the lesioned thalamus both in terms of morphology of the capillaries and of the function of the blood-brain barrier (BBB). In the transplant, capillaries, stained by Indian ink, are very few in number and have very fine calibers during the first 20 days after grafting. Some structures can be identified as immature blood vessels at the electron microscopic level. The blood vessels are progressively more numerous in the graft and they demonstrate mature ultrastructural features 2 months after grafting. Last, there is no leakage of the BBB for peroxidase. The vascularization seems to follow a pattern of maturation comparable to that described during development in the literature. In contrast, in the lesioned area, there is a reactive angiogenesis: 10 days after the excitotoxic injection (shortest time studied), there are many wide caliber vessels with expanded perivascular spaces engorged with mesodermal cells. A microvascularization also develops transiently during the first two months. Capillaries are abnormal from the functional point of view, since there is a leakage of the BBB to macromolecules. The use of an experimental model in which transplant had to grow in a lesioned area permits to determine two types of vascularization: an apparently normal developmental timetable, normal morphological and functional characteristics, in the transplant; a reactive angiogenesis, in the lesioned area.

Angiogenesis on the optic tectum of albino Xenopus laevis tadpoles

Developing blood vessels were observed directly on the dorsal surface of the optic tectum of anesthetized, transparent albino Xenopus laevis tadpoles, stages 41-54. Case histories of individual tadpoles indicated that pial capillaries developed by the classical mechanism of sprouting of endothelial cells from existing blood vessels. 'Deep sources' appeared on the tectal surface during development. These were sites of upwelling blood cells from capillaries within the nervous tissue of the tectum into vessels on the surface. Few 'deep sinks' were observed in the dorsal tectum of normal tadpoles. The earliest deep sources were probably formed by sprouts from the surface vessels through the basement membrane and into the nervous tissue; later ones may also have formed from internal sprouts back to the surface. Maps of deep sources and of surface vessels in case histories indicated that neural tissue and blood vessels in the caudal half of the tectum grew faster than in the rostral half. The medial venules on the dorsal tectum originated as ordinary-sized rostrocaudal capillaries. They enlarged in diameter as they drained the increasing flow of blood from the tectum into the choroid plexus over the 4th ventricle. Some capillaries disappeared or regressed during development. Our observations on the tectum were consistent with the classical sequence of loss of flow, narrowing, collapse of the lumen, and retraction of endothelial cells into adjacent vessels. Likely sites for regression were upstream from a deep source and at crosslinks between transverse vessels on the lateral tectum. Morphometric parameters for tectal angiogenesis were (a) surface density (mm-1) calculated as total length of surface vessels divided by the dorsally projected surface area, and (b) density of deep sources (mm-2) calculated as total number divided by surface area. From stages 41/42 to 50 average surface density approximately doubled, and average density of deep sources increased about 5-fold. Some of the factors which might be expected to alter brain angiogenesis include nervous activity, availability of O2, and metabolic rate. Removal of one eye deprived the contralateral tectum of direct retinal inputs, while the ipsilateral side was a control in the same animal. Anterograde labeling of retinal axons with diI18 from the remaining eye confirmed projections only to the opposite side. No significant differences in densities of surface vessels or of deep sources were observed between the contralateral and ipsilateral sides of the tectum.(ABSTRACT TRUNCATED AT 400 WORDS)

Expression of the jimpy gene in the spinal cords of heterozygous female mice. 2. Oligodendroglial and endothelial cell hyperplasia

The jimpy mutation is characterized by a severe deficiency of myelin formation throughout the central nervous system of hemizygous male mice. The female carrier of the jimpy gene is also hypomyelinated, but the myelin deficit in the female is less severe than age-matched controls, while the myelin content of 30-day-old carriers is nearly normal. Several different mechanisms might be employed by oligodendrocytes in the mosaic to compensate for the early myelin deficit. In the present autoradiographic study, we examine the ability of oligodendrocytes in the carrier to increase their rate of proliferation. Our results demonstrate that the number of oligodendrocytes incorporating tritiated-thymidine in the two-week mosaic is nearly 4 times greater than controls. The increased proliferation of oligodendrocytes is likely to be one mechanism which the mosaic utilizes to compensate for defective oligodendrocytes. The rate of glial proliferation returns to normal in older carriers. The rate of capillary cell proliferation was also significantly increased in the young mosaic, a phenomenon which does not occur in hemizygous males. These observations demonstrate the utility of the female carrier of the jimpy gene as a model to study the responses of glia and capillary cells to hypomyelination.

Direct evidence that complex experience increases capillary branching and surface area in visual cortex of young rats

Rats housed in complex environments with toys and other rats generate new synapses, and the expanding neuropil tends to spread apart existing blood vessels. Previous work demonstrated that weanling rats kept in complex environments had more closely packed capillaries, suggesting that new capillaries had sprouted into the newly added neuropil. The present study directly investigates the issue of new branching by using india ink perfusions of weanling rats kept for 30 days in a complex environment (EC), paired in standard caging (SC), or individual cages (IC) to examine the density of capillary branch points and the capillary surface area per unit tissue volume. EC rats had a greater density of branch points than the SC and IC littermates, a finding consistent with increased capillary sprouting. Capillary surface area per unit tissue volume and the number of branch points per unit of capillary surface area were also higher for EC rats. This suggests that blood vessels of EC rats branch off more often than those of animals kept in more standard conditions, and provides further evidence that complex experience can increase angiogenesis in cerebral cortex of postweanling rats.

Low [3H]cytochalasin B binding in the cerebral cortex of newborn rat

The concentrations of glucose transporter in the cerebral cortex and brainstem of neonatal (4-7 days old) and adult rats were measured using [3H]cytochalasin B binding. There was significantly lower binding in neonatal cortex (1.9 +/- 0.7 pmol/mg protein) compared to adult (8.9 +/- 2.5 pmol/mg protein). Scatchard analysis indicates this difference is due to a lower Bmax (neonate, 9.7 pmol/mg protein; adult, 18.6 +/- 1.3 pmol/mg protein). Measurement of [3H]cytochalasin B binding in microvessels prepared from cortex of adult (28.1 +/- 3.5 pmol/mg protein) and neonate (12.8 +/- 1.9 pmol/mg protein) indicates a lower binding in the microvasculature of neonates, whereas no such difference was seen in the binding in microvessels prepared from adult and neonatal brainstem (adult, 11.8 +/- 2.3 pmol/mg protein; neonate, 9.4 +/- 2.7 pmol/mg protein). In both adult and neonate brain, there is an enrichment of glucose transporters in the microvasculature.

Endothelial cell-astrocyte interactions. A cellular model of the blood-brain barrier

Microvascular endothelial cells in the brain have a number of special properties that underlie formation of the blood-brain barrier (BBB) and contribute to control of the neuronal microenvironment. Evidence from transplantation experiments indicates that signals arising within brain rather than a programmed commitment of the endothelial cells are responsible for the expression of blood-brain barrier properties. The close anatomic relationship between brain endothelial cells and the foot processes of astrocytes suggests a role for astrocytes as a source of the differentiation signals. It is now possible to isolate and separately culture populations of brain-derived endothelial cells and astrocytes. When the two cell types are grown together, a characteristic morphologic organization occurs that is associated with induction of enzymes and tight junctions similar to those found in vivo. Endothelial cells and astrocytes in culture differ in their production of and response to specific polypeptide growth factors. These findings provide the basis for a model of endothelial cell-astrocyte interaction that may explain several aspects of BBB behavior.

Patterns of angiogenesis in neural transplant models: II. Fetal neocortical transplants

Vascular integration between transplanted fetal CNS tissues and host brain is essential for long-term transplant survival. This study compares the time course and mechanism of vascularization in allografts of fetal cerebral cortex inserted either into the fourth ventricle or directly into the parietal cortex or hippocampus of perinatal rats. Recipient animals were administered 3H-thymidine after various postoperative time periods. The tissues were processed for light microscopic autoradiography to determine the temporal pattern of endothelial proliferation at the graft sites. Correlative electron microscopy depicted the morphological changes in transplant vasculature. Some recipients were prelabelled with 3H-thymidine prior to transplantation to determine if host vessels invaded the grafts; conversely, some donor tissues were prelabelled in utero to ascertain if the intrinsic vascular anlagen survived. Intraventricular transplants contained patent vessels, probably originating from the host pia mater, as early as 24 hours postoperative. Intraparenchymal transplants had patent vessels by 72 hours and a more complete network by 5 days. Prelabelling experiments and ultrastructural observations demonstrated that adjacent host pial vessels became incorporated into the perimeter of the intraventricular transplants and later grew centrally into the grafts. Intraparenchymal transplants also contained host vessels that exhibited a similar growth pattern. Intrinsic graft vessels remained viable and continued their development, and presumably anastomosed with the ingrowing host vasculature. Temporal labelling studies revealed that both vessel populations attained their highest proliferative rates within 72 hours after transplantation. This study demonstrates that the vasculature which develops within both intraventricular and intraparenchymal fetal CNS transplants is chimeric, consisting of intrinsic fetal vasculature and proliferating host vessels. The mechanism of transplant vascularization may be significant with regard to astrocytic, immunological, or blood-brain-barrier characteristics at these transplantation sites.

Transforming growth factor beta activates protein kinase C in microvessels isolated from immature rat brain

We investigated the activation of protein kinase C in microvessels isolated from rat brain. We found that unstimulated kinase activity in microvessels from immature animals is soluble while that from adults is particulate. The tumor promoter, phorbol 12-myristate 13-acetate, and the diacylglycerol analog, 1-oleoyl-2-acetyl-sn-glycerol, caused the redistribution of protein kinase C activity to the membrane fraction in microvessels from immature rats. Exposure to transforming growth factor beta resulted in similar redistribution of kinase activity. To our knowledge, this is the first report of an effect of transforming growth factor beta on protein kinase C. The kinase activity in microvessels from adult animals was unaffected by exposure to these agonists. We suggest that protein kinase C activation promotes differentiation of the brain microvasculature. Transforming growth factor beta may mediate this process.

Patterns of angiogenesis in neural transplant models: I. Autonomic tissue transplants

Functional vascular connections must form rapidly to prevent ischemic damage to grafted neural tissues. The temporal sequence by which transplant circulation is re-established provides information about the angiogenic capacity of either intact or damaged CNS blood vessels. This study compares the time course and mechanism of vascular reperfusion in allografts of superior cervical ganglia or adrenal medulla inserted either into the fourth ventricle or directly into the parietal cortex of perinatal rats. Tritiated thymidine was administered to recipients to determine angiogenic patterns at various postoperative time periods. After processing for light microscopic autoradiography, host and graft endothelial labelling indices were determined in order to establish the temporal sequence and location of vascular proliferation. Correlative electron microscopy depicted the morphological changes in transplant vasculature. Some recipients were prelabelled with 3H thymidine prior to transplantation to determine if host vessels invaded the grafts. Intraventricular graft vessels initially collapsed but sustained minimal ischemic damage and were completely reperfused by 24 hours postoperative. Adjacent intact host vessels attained peak 3H thymidine incorporation at 20 hours. Intrinsic graft vessels were radioactively labelled only after 48 hours. Intraparenchymal transplants surrounded by minimal trauma exhibited a similar temporal sequence of reperfusion and host endothelial proliferation. Intrinsic graft vessels in intraparenchymal grafts sustained more severe damage. With increased trauma, a concomitant delay in graft reperfusion time was observed. Grafts within prelabelled hosts rarely contained any labelled endothelium, indicating that anastomotic connections were made between original, intrinsic graft vessels and nearby host vascular sprouts. This study demonstrates that mature autonomic tissue stimulates the growth of adjacent host vessels when transplanted to undamaged brain surfaces. The anastomosis of nascent host vessels with pre-existing graft vessels is responsible for the rapid re-establishment of circulation within the transplants. A similar mechanism occurs within intraparenchymal grafts, although the rapidity of reperfusion appears to be predicated on the amount of trauma present at the graft site.