Tatiana Coelho-Sampaio

Two-photon fluorescence lifetime imaging microscopy of macrophage-mediated antigen processing

Two‐photon fluorescence lifetime imaging microscopy was used noninvasively to monitor a fluorescent antigen during macrophage‐mediated endocytosis, intracellular vacuolar encapsulation, and protease‐dependent processing. Fluorescein‐conjugated bovine serum albumin (FITC–BSA) served as the soluble exogenous antigen. As a relatively nonfluorescent probe in the native state, the antigen was designed to reflect sequential intracellular antigen processing events through time‐dependent changes in fluorescence properties. Using two‐photon lifetime imaging microscopy, antigen processing events were monitored continuously for several hours. During this time, the initial fluorescein fluorescence lifetime of 0.5 ns increased to α 3.0 ns. Control experiments using fluorescein conjugated poly‐l‐lysine and poly‐d‐lysine demonstrated that the increase in fluorescence parameters observed with FITC–BSA were due to intracellular proteolysis since addition of the inert d‐isomer did not promote an increase in fluorescence lifetime or intensity. Comparisons of intravacuolar and extracellular FITC–dextran concentration suggested active localization of dextran in the vacuoles by the macrophage. In addition, the kinetics of degradation observed using two‐photon microscopy were similar to results obtained on the flow cytometer, thus validating the use of flow cytometry for future studies.

Structure of laminin substrate modulates cellular signaling for neuritogenesis

Laminin, a major component of basement membranes, can self-assemble in vitro into a typical mesh-like structure, according to a mass-action-driven process. Previously, we showed that pH acidification dramatically increased the efficiency of laminin self-assembly, practically abolishing the necessity for a minimal protein concentration. Here we have characterized the morphologies of laminin matrices produced in either neutral or acidic conditions and compared their capacities to induce neuritogenesis of rat embryonic cortical neurons. Although laminin matrices formed in neutral buffer presented aggregates of heterogeneous morphology, the acidic matrix consisted of a homogeneous hexagonal sheet-like structure. The latter was comparable to the matrix assembled in vivo at the inner limiting membrane of the retina in newborn rats, shown here, and to matrices secreted by cultivated cells, shown elsewhere. The average neurite length of cortical neurons plated on acidic matrices was 244.9 μm, whereas on neutral matrices this value dropped to 104.1 μm. Increased neuritogenesis on the acidic matrix seemed to be associated with a higher degree of neuronal differentiation, since cell proliferation was immediately arrested upon plating, whereas on neutral matrices, the cell number increased six-fold within 24 hours. Investigation of the mechanisms mediating neurite outgrowth on each condition revealed that the extensive neuritogenesis observed on the acidic matrix involved activation of protein kinase A, whereas moderate neuritogenesis on neutral laminin was mediated by activation of protein kinase C and/or myosin light-chain kinase. Explants of cerebral cortex from P2 rats did not grow on the neutral laminin substrate but presented extensive cell migration and neurite outgrowth on the acidic laminin matrix. We propose that laminin can self-assemble independently of cell contact and that the assembling mode differentially modulates neuritogenesis and neuroplasticity.

Self-assembly of Laminin Induced by Acidic pH

The supramolecular architecture of the basement membrane is provided by two enmeshed networks of collagen IV and laminin. The laminin network is maintained exclusively by interactions among individual laminin molecules and does not depend on the presence of other extracellular matrix components. Laminin polymers can be obtained in vitro either in solution or in association with the surface of bilayers containing acidic lipids. In this work, we have tested the hypothesis that the negative charges present on acidic lipids establish an acid microenvironment that is directly responsible for inducing laminin aggregation. Using light-scattering measurements, we show that laminin does not aggregate on vesicles of neutral lipids, whereas instantaneous aggregation occurs to progressively greater extents as the proportion of acidic phospholipids in the vesicles is increased. Aggregation of laminin induced by vesicles containing acidic phospholipids occurs very rapidly, so that maximal aggregation for each condition is reached within 1 min after laminin dilution. Aggregation depends on the presence of Ca2+ ions, is reversed by increasing ionic strength, and can be detected at laminin concentrations as low as 6 nm. In addition, we show that, in the absence of vesicles, acidification of the bulk solution can also induce laminin self-polymerization through a process that exhibits the same properties as lipid-induced polymerization. The fact that there is a correspondence between the processes of self-polymerization of laminin in acidic medium and in neutral medium but in the presence of vesicles containing negatively charged lipids leads us to propose that the microenvironment of an acidic surface may trigger the assembly of laminin networks. In vivo, such an acidic microenvironment would be provided by negatively charged sialic acid and sulfate groups present in the glycocalyx surrounding the cells.

Acidic pH Modulates the Interaction between Human Granulocyte-Macrophage Colony-stimulating Factor and Glycosaminoglycans

Granulocyte-macrophage colony-stimulating factor (GM-CSF) controls growth and differentiation of hematopoietic cells. Previous reports have indicated that the mitogenic activity of GM-CSF may be modulated by the glycosidic moiety of proteoglycans associated with the membrane of stromal cells. In this work, we have performed in vitrostudies of the interaction between GM-CSF and glycosaminoglycans. The addition of heparin promoted a marked blue shift in the fluorescence emission spectrum of GM-CSF as well as a 30-fold increase in the intensity of light scattering, which indicates formation of large molecular weight complexes between the two molecules. Interestingly, heparin-induced changes in the spectral properties of GM-CSF were only observed at acidic pH. The dependence on acidic pH, together with a strict dependence on glycosaminoglycan sulfation and the fact that high ionic strength destabilized the interaction, indicates that the association between GM-CSF and glycosaminoglycans is mediated by electrostatic interactions. These interactions probably involve sulfate groups in the glycosaminoglycans and positively charged histidine residues in GM-CSF. We propose that negatively charged glycolipids present on the plasma membrane of the hematopoietic and/or the stromal cell could promote an acidic microenvironment capable of triggering interaction between GM-CSF and membrane-bound proteoglycans in vivo.

A novel methodology for the investigation of intracellular proteolytic processing in intact cells.

Taking advantage of the unique spectral properties of the fluorescent probe FL-Bodipy, we have developed a new methodology to study processing of exogenous proteins in intact cells. FL-Bodipy was conjugated to bovine serum albumin (BSA) at a molar ratio of 29 probe molecules to 1 albumin equivalent. The resulting conjugate was 98% self-quenched due to fluorescence resonance energy transfer (homotransfer) between neighboring Bodipy molecules. In vitro proteolytic cleavage of the conjugate led to relaxation of self-quenching and to a significant increase in fluorescence. Flow cytometry and fluorescence microscopy indicated that Bodipy-labeled BSA was readily internalized by J774 macrophages and accumulated in intracellular compartments. The kinetics of intracellular degradation of Bodipy-BSA was linear for up to 2 hours and was completely inhibited by a combination of protease inhibitors. Future applications of the methodology reported here may comprise studies of antigen processing and presentation, as well as the investigation of cellular events related to processing and disassembly of intracellular pathogens such as parasites, bacteria and viruses.

Sialic acid residues on astrocytes regulate neuritogenesis by controlling the assembly of laminin matrices

In the developing nervous system migrating neurons and growing axons are guided by diffusible and/or substrate-bound cues, such as extracellular matrix-associated laminin. In a previous work we demonstrated that laminin molecules could self-assemble in two different manners, giving rise to matrices that could favor either neuritogenesis or proliferation of cortical precursor cells. We investigated whether the ability of astrocytes to promote neuritogenesis of co-cultivated neurons was modulated by the assembling mode of the laminin matrix secreted by them. We compared the morphologies and neuritogenic potentials of laminin deposited by in vitro-differentiated astrocytes obtained from embryonic or neonatal rat brain cortices. We showed that, while permissive astrocytes derived from embryonic brain produced a flat laminin matrix that remained associated to the cell surface, astrocytes derived from newborn brain secreted a laminin matrix resembling a fibrillar web that protruded from the cell plane. The average neurite lengths obtained for E16 neurons cultured on each astrocyte layer were 198±22 and 123±13 μm, respectively. Analyses of surface-associated electrostatic potentials revealed that embryonic astrocytes presented a pI of -2.8, while in newborn cells this value was -3.8. Removal of the sialic acid groups on the embryonic monolayer by neuraminidase treatment led to the immediate release of matrix-associated laminin. Interestingly, laminin reassembled 1 hour after neuraminidase removal converted to the features of the newborn matrix. Alternatively, treatment of astrocytes with the cholesterol-solubilizing detergent methyl-β-cyclodextrin also resulted in release of the extracellular laminin. To test the hypothesis that sialic-acid-containing lipids localized at cholesterol-rich membrane domains could affect the process of laminin assembly, we devised a cell-free assay where laminin polymerization was carried out over artificial lipid films. Films of either a mixture of gangliosides or pure ganglioside GT1b induced formation of matrices of morpho-functional features similar to the matrices deposited by embryonic astrocytes. Conversely, films of phosphatidylcholine or ganglioside GM1 led to the formation of bulky laminin aggregates that lacked a defined structure. We propose that the expression of negative lipids on astrocytes can control the extracellular polymerization of laminin and, consequently, the permissivity to neuritogenesis of astrocytes during development.

Human Mesenchymal Cells from Adipose Tissue Deposit Laminin and Promote Regeneration of Injured Spinal Cord in Rats

Cell therapy is a promising strategy to pursue the unmet need for treatment of spinal cord injury (SCI). Although several studies have shown that adult mesenchymal cells contribute to improve the outcomes of SCI, a descripton of the pro-regenerative events triggered by these cells is still lacking. Here we investigated the regenerative properties of human adipose tissue derived stromal cells (hADSCs) in a rat model of spinal cord compression. Cells were delivered directly into the spinal parenchyma immediately after injury. Human ADSCs promoted functional recovery, tissue preservation, and axonal regeneration. Analysis of the cord tissue showed an abundant deposition of laminin of human origin at the lesion site and spinal midline; the appearance of cell clusters composed of neural precursors in the areas of laminin deposition, and the appearance of blood vessels with separated basement membranes along the spinal axis. These effects were also observed after injection of hADSCs into non-injured spinal cord. Considering that laminin is a well-known inducer of axonal growth, as well a component of the extracellular matrix associated to neural progenitors, we propose that it can be the paracrine factor mediating the pro-regenerative effects of hADSCs in spinal cord injury.

Polylaminin, a polymeric form of laminin, promotes regeneration after spinal cord injury

Regeneration of spinal cord injury (SCI) is a major topic of biomedical research. Laminin is an extracellular matrix protein implicated in neural development and regeneration, but despite that, there are no reports of exogenous laminin contributing to improve the outcome of experimental SCI. Here we investigated whether a biomimetic polymer of laminin assembled on pH acidification, henceforth called polylaminin, could be used to treat SCI in rats. Acute local injection of polylaminin, but not of nonpolymerized laminin, improved motor function after thoracic compression, partial or complete transection. In the latter case, the BBB score for open field locomotion 8 wk after lesion increased from 4.2 ± 0.48 to 8.8 ± 1.14 in animals treated with polylaminin of human origin. Accordingly, neurons retrogradely labeled from the sublesion stump were detected in the spinal cord and brain stem, indicating regrowth of short and long fibers across a complete transection. Polylaminin also played an unsuspected anti‐inflammatory role, which underlies the early onset of its positive effects on locomotion from the first week after treatment. The beneficial effects of polylaminin were not observed in animals treated with the nonpolymerized protein or vehicle only. We propose that polylaminin is a promising therapeutic agent to treat human SCI.—Menezes, K., Menezes, J. R. L., Nascimento, M. A., Siqueira Santos, R., Coelho‐Sampaio, T. Polylaminin, a polymeric form of laminin, promotes regeneration after spinal cord injury. FASEB J. 24, 4513–4522 (2010). www.fasebj.org

Stroma-mediated granulocyte-macrophage colony-stimulating factor (GM-CSF) control of myelopoiesis: spatial organisation of intercellular interactions

Granulocyte-macrophage colony-stimulating factor (GM-CSF) is one of the major cytokines involved in control of haemopoiesis both in bone marrow and in extramedullar sites. Its biological activity depends upon the composition and physicochemical properties of the microenvironment provided by the supporting stroma. GM-CSF activity is modulated and controlled by the stromal heparan-sulphate proteoglycans, but their optimal interaction occurs only at low pH. We questioned whether the microenvironment organisation of the interface between stroma and haemopoietic cells provides such conditions. We studied myeloid progenitor proliferation in contact with bone marrow-derived and extramedullar stromas using electron microscopy and selective labelling of pericellular components. We present evidence that, upon interaction, the two cell types reorganise their interface both in shape and molecular composition. Haemopoietic cells extend projections that considerably increase the area of intercellular contact, and stromal cells form lamellipodia and carry out a redistribution of membrane-associated sialylated glycoconjugates and proteoglycans. Such rearrangements lead to extensive capping of negatively charged molecules at the interface between the supporting stroma and the haemopoietic cells, leading potentially to a local decrease in pH. Our results indicate that the distribution of negative charges at the cellular interface may be responsible for the selectivity of cell response to GM-CSF.

Artificial Laminin Polymers Assembled in Acidic pH Mimic Basement Membrane Organization

Natural laminin matrices are formed on cell membranes by a cooperative process involving laminin self-polymerization and binding to cognate cellular receptors. In a cell-free system, laminin can self-polymerize, given that a minimal critical concentration is achieved. We have previously described that pH acidification renders self-polymerization independent of protein concentration. Here we studied the ultrastructure of acid-induced laminin polymers using electron and atomic force microscopies. Polymers presented the overall appearance of natural matrices and could be described as homogeneous polygonal sheets, presenting struts of 21 ± 5 and 86 ± 3 nm of height, which approximately correspond to the sizes of the short and the long arms of the molecule, respectively. The addition of fragment E3 (the distal two domains of the long arm) did not affect the polymerization in solution nor the formation of adsorbed matrices. On the other hand, the addition of fragment E1′, which contains two intact short arms, completely disrupted polymerization. These results indicate that acid-induced polymers, like natural ones, involve only interactions between the short arms. The electrostatic surface map of laminin α1 LG4-5 shows that acidification renders the distal end in the long arms exclusively positive, precluding homophylic interactions between them. Therefore, acidification reproduces in vitro, and at a physiological protein concentration, what receptor interaction does in the cellular context, namely, it prevents the long arm from disturbing formation of the homogeneous matrix involving the short arms only. We propose that acid-induced polymers are the best tool to study cellular response to laminin in the future.