Paul Bornstein

Thrombospondins Are Astrocyte-Secreted Proteins that Promote CNS Synaptogenesis

The establishment of neural circuitry requires vast numbers of synapses to be generated during a specific window of brain development, but it is not known why the developing mammalian brain has a much greater capacity to generate new synapses than the adult brain. Here we report that immature but not mature astrocytes express thrombospondins (TSPs)-1 and -2 and that these TSPs promote CNS synaptogenesis in vitro and in vivo. TSPs induce ultrastructurally normal synapses that are presynaptically active but postsynaptically silent and work in concert with other, as yet unidentified, astrocyte-derived signals to produce functional synapses. These studies identify TSPs as CNS synaptogenic proteins, provide evidence that astrocytes are important contributors to synaptogenesis within the developing CNS, and suggest that TSP-1 and -2 act as a permissive switch that times CNS synaptogenesis by enabling neuronal molecules to assemble into synapses within a specific window of CNS development.

Thrombospondins as matricellular modulators of cell function.

Thrombospondins (TSPs) are a small family of secreted, modular glycoproteins whose functions, at a mechanistic level, are not well understood, despite increasing scrutiny in recent years. TSP1 and TSP2 form one subgroup and are trimers with a chain molecular mass of about 145 kDa. The pentameric TSPs 3–5 are significantly smaller, with a subunit molecular mass of about 100 kDa (1), and their physiological roles are probably distinct. This Perspective will concern itself with TSP1 and TSP2.

Akt1 regulates pathological angiogenesis, vascular maturation and permeability in vivo.

Akt kinases control essential cellular functions, including proliferation, apoptosis, metabolism and transcription, and have been proposed as promising targets for treatment of angiogenesis-dependent pathologies, such as cancer and ischemic injury. But their precise roles in neovascularization remain elusive. Here we show that Akt1 is the predominant isoform in vascular cells and describe the unexpected consequences of Akt1 knockout on vascular integrity and pathological angiogenesis. Angiogenic responses in three distinct in vivo models were enhanced in Akt1−/− mice; these enhanced responses were associated with impairment of blood vessel maturation and increased vascular permeability. Although impaired vascular maturation in Akt1−/− mice may be attributed to reduced activation of endothelial nitric oxide synthase (eNOS), the major phenotypic changes in vascular permeability and angiogenesis were linked to reduced expression of two endogenous vascular regulators, thrombospondins 1 (TSP-1) and 2 (TSP-2). Re-expression of TSP-1 and TSP-2 in mice transplanted with wild-type bone marrow corrected the angiogenic abnormalities in Akt1−/− mice. These findings establish a crucial role of an Akt-thrombospondin axis in angiogenesis.

[14] Cleavage at AsnGly bonds with hydroxylamine

Publisher Summary This chapter presents a procedure for nonenzymic cleavage of proteins with hydroxylamine, which provides a relatively specific means of producing large peptide fragments suitable for further chemical analysis. Cleavage occurs at Asn-Gly bonds and results from the tendency of the asparaginyl side chain to cyclize, forming a substituted succinimide that is susceptible to nucleophilic attack by hydroxylamine. The increased susceptibility of Asn-Gly bonds in comparison with other asparaginyl bonds may result from the greater ease with which the asparaginyl side chain can cyclize in the absence of steric hindrance imposed by a side chain on the succeeding amino acid. The extent of cleavage achieved varies with the protein; cleavage is enhanced by complete denaturation of the protein and by the use of 6 M guanidine as a solvent during hydroxylaminolysis. A low level of cleavage at Asn-X bonds has been observed in some cases, but aspartyl bonds appear to be resistant under conditions used. The infrequency of Asn-Gly bonds in most proteins results in the production of very large fragments that may overlap CNBr-produced fragments and could serve as new start points for sequential Edman degradation.

Thrombospondins 1 and 2 function as inhibitors of angiogenesis

Thrombospondins (TSPs) 1 and 2 are matricellular proteins with the well-characterized ability to inhibit angiogenesis in vivo, and the migration and proliferation of cultured microvascular endothelial cells (ECs). Angiogenesis in developing tumors and in various models of wound healing is diminished or delayed by the presence of TSP1 or 2. Sequences within the type I repeats of TSP1 and 2 have been demonstrated to mediate the anti-migratory effects of TSPs on microvascular EC, although, paradoxically, sequences in the N- and C-terminal domains have pro-angiogenic effects. A scavenger receptor, CD36, recognizes the active sequences in the type I repeats, and is required for the anti-angiogenic effects of TSP1 in the corneal neovascularization assay. However, interactions of TSPs with growth factors, proteases, histidine-rich glycoprotein, and other cell-surface receptors on EC have the potential to modulate CD36-mediated effects. Binding of TSP1 to CD36 has been shown to activate apoptosis by inducing p38 and Jun N-terminal kinase, members of the mitogen-activated protein kinase superfamily, and subsequently the cell-surface expression of FasL. Ligation of Fas by FasL then induces a caspase cascade and apoptotic cell death. However, we have recently shown that inhibition of proliferation of microvascular EC by TSPs can occur in the absence of cell death. This finding raises the possibility that TSPs can activate separate cell death and anti-proliferative pathways.

Extracellular matrix metalloproteinase 2 levels are regulated by the low density lipoprotein-related scavenger receptor and thrombospondin 2.

We have recently shown that the adhesive defect observed in dermal fibroblasts derived from thrombospondin 2 (TSP2)-null mice results from an increase in matrix metalloproteinase 2 (MMP2) levels (Yang, Z., Kyriakides, T. R., and Bornstein, P. (2000) Mol. Biol. Cell 11, 3353–3364). Adhesion was restored by replacement of TSP2 and by inhibitors of MMP2 activity. In pursuing the observation that TSP2 and MMP2 interact, we now demonstrate that this interaction is required for optimal clearance of extracellular MMP2 by fibroblasts. Since TSP2 is known to be endocytosed by the scavenger receptor, low density lipoprotein receptor-related protein (LRP), we determined whether interference with LRP function affected fibroblast adhesion and/or extracellular MMP2 levels. Addition of heparin, which competes for the binding of TSP2 to LRP coreceptor proteoglycans, inhibited adhesion of control but not TSP2-null cells, and a blocking antibody to LRP as well as the LRP inhibitor, receptor-associated protein, also inhibited adhesion and increased MMP2 levels only in control fibroblasts. TSP2 did not inhibit active MMP2 directly and did not inhibit the activation of pro-MMP2. Finally, the internalization of 125I-MMP2 was reduced in TSP2-null compared with control fibroblasts. We propose that clearance of MMP2-TSP2 complexes by LRP is an important mechanism for the regulation of extracellular MMP2 levels in fibroblasts, and perhaps in other cells. Thus, some features of the phenotype of TSP2-null mice, such as abnormal collagen fibrillogenesis, accelerated wound healing, and increased angiogenesis, could result in part from increased MMP2 activity.

Dynamic reciprocity in the wound microenvironment.

Here, we define dynamic reciprocity (DR) as an ongoing, bidirectional interaction among cells and their surrounding microenvironment. In this review, we posit that DR is especially meaningful during wound healing as the DR‐driven biochemical, biophysical, and cellular responses to injury play pivotal roles in regulating tissue regenerative responses. Such cell–extracellular matrix interactions not only guide and regulate cellular morphology, but also cellular differentiation, migration, proliferation, and survival during tissue development, including, e.g., embryogenesis, angiogenesis, as well as during pathologic processes including cancer, diabetes, hypertension, and chronic wound healing. Herein, we examine DR within the wound microenvironment while considering specific examples across acute and chronic wound healing. This review also considers how a number of hypotheses that attempt to explain chronic wound pathophysiology may be understood within the DR framework. The implications of applying the principles of DR to optimize wound care practice and future development of innovative wound healing therapeutics are also briefly considered.

The Lack of Thrombospondin-1 (TSP1) Dictates the Course of Wound Healing in Double-TSP1/TSP2-Null Mice

Thrombospondin (TSP) 1 and 2, share the same overall structure and interact with a number of the same cell-surface receptors. In an attempt to elucidate their biological roles more clearly, we generated double-TSP1/TSP2-null animals and compared their phenotype to those of TSP1- and TSP2-null mice. Double-null mice exhibited an apparent phenotype that primarily represented the sum of the abnormalities observed in the single-null mice. However, surprisingly, the wound-healing response in double-null mice resembled that in TSP1-null animals and differed from that in TSP2-nulls. Thus, although the excisional wounds of TSP2-null mice are characterized by increased neovascularization and heal at an accelerated rate, TSP1-null and double-null animals demonstrated delayed healing, as indicated by the prolonged persistence of inflammation and delayed scab loss. Immunohistochemical analysis showed that, similar to TSP1-null mice, the granulation tissue of double-null mice was not excessively vascularized. Furthermore as in TSP1-nulls, decreases in macrophage recruitment and in the levels of monocyte chemoattractant protein-1 indicated that the inflammatory phase of the wound-healing response was impaired in double-null mice. Our data demonstrate that the consequences of a lack of TSP1 predominate in the response of double-null mice, and dictate the course of wound healing. These findings reflect distinct temporal and spatial expressions of TSP1 and TSP2 in the healing wound.

Light microscopic immunolocation of thrombospondin in human tissues.

Affinity-purified antisera against thrombospondin were used to locate the presence of this glycoprotein in frozen sections of several human tissues by immunofluorescence techniques. Immunostaining was observed in the peritubular connective tissue and in basement membrane regions beneath glandular epithelium in skin and lung. Intense immunostaining was observed at the dermal-epidermal junction in skin and in small blood vessels throughout this tissue. Skeletal muscle exhibited positive staining with anti-thrombospondin antisera within interstitial areas. Immunostaining was confined to the luminal portions of large blood vessels such as aorta. In large blood vessels that contained lesions of atherosclerosis, immunostaining was observed throughout the lesion area and was especially prominent surrounding some of the lesion cells. These results indicate that thrombospondin is located within the matrix of a variety of human tissues and supports the suggestion that this glycoprotein is an endogenous component of some extracellular matrices.

Differential expression of SPARC and thrombospondin 1 in wound repair: immunolocalization and in situ hybridization.

SPARC and thrombospondin 1 (TSP-1) are secreted glycoproteins expressed by similar types of cells in culture and in tissues. To compare these two proteins in vivo, we analyzed the differential expression of SPARC and TSP-1 during wound repair. Full-thickness incision wounds were made in rats and biopsied at 12 hr-14 days. Antibodies against SPARC revealed an increased proportion of immunoreactive fibroblastic cells at the wound edge at 3 days with maximal numbers at 7 days. In situ hybridization for SPARC produced results consistent with those of immunohistochemistry. With combined immunohistochemistry and in situ hybridization, some of the macrophages at the wound edge expressed SPARC mRNA. In contrast, immunoreactivity for TSP-1 was extracellular; expression at the wound edge was noted at 12 hr and was maximal at 1-2 days. TSP-1 mRNA was found in the thrombus, but not at the wound edge. In conclusion, SPARC and TSP-1 have contrasting roles during wound healing. SPARC expression from the middle through late stages of repair was consistent with its previously proposed functions in remodeling; in contrast, the transient expression of TSP-1 early in repair might facilitate the action of other proteins in recruitment and/or proliferation of cells in the healing wound.