- Philippines
David Bueno
Cebu Institute of Technology - University, Mechanical Engineering, Department Member
Research Interests: Mass Spectrometry, Proteomics, Neurodegenerative Diseases, Mammals, Biological Sciences, and 16 moreApolipoproteins, Cerebrospinal Fluid, Brain, Humans, Birds, Animals, Proteins, Neurons, Enzyme, CHEMICAL SCIENCES, Rats, Chickens, Time Factors, Two-Dimensional Gel Electrophoresis, Cell Proliferation, and Proteome
Research Interests:
Early in development, the behavior of neuroepithelial cells is controlled by several factors, which act in a developmentally regulated manner. Diffusible factors are secreted locally by the neuroepithelium itself, although other nearby... more
Early in development, the behavior of neuroepithelial cells is controlled by several factors, which act in a developmentally regulated manner. Diffusible factors are secreted locally by the neuroepithelium itself, although other nearby structures may also be involved. Evidence suggests a physiological role for the cerebrospinal fluid in the development of the brain. Here, using organotypic cultures of chick embryo neuroepithelial explants from the mesencephalon, we show that the neuroepithelium in vitro is not able to self-induce cell survival, replication, and neurogenesis. We also show that the embryonic cerebrospinal fluid (E-CSF) promotes neuroepithelial stem cell survival and induces proliferation and neurogenesis in mesencephalic explants. These data strongly suggest that E-CSF is involved in the regulation of neuroepithelial cells behavior, supporting the hypothesis that this fluid plays a key role during the early development of the central nervous system. © 2005 Wiley-Liss, Inc.
Research Interests:
The special morphological features of freshwater planarians make them an attractive and informative model for studying the processes of regeneration and pattern formation. In this work, we investigate pattern formation and maturation of... more
The special morphological features of freshwater planarians make them an attractive and informative model for studying the processes of regeneration and pattern formation. In this work, we investigate pattern formation and maturation of the planarian pharynx during regeneration in tail fragments. Using three monoclonal antibodies (TCAV-1, TF-26 and TMUS-13) specific for epithelial, secretory and muscle cells, respectively, we followed the sequence and timing of differentiation and maturation of these three cell types within the regenerating pharynx. Two of these monoclonal antibodies, TCAV-1 and TMUS-13, also labelled morphologically immature cells that appear to be committed to the differentiation pathway leading to their respective adult cell types. Our results show that the cells forming the new pharynx come from undifferentiated cells through proliferation and differentiation processes rather than from differentiated cells of the old stump. We describe three stages of pharynx regeneration according to the immunoreactivity shown: (1) no immunoreactivity, corresponding to the accumulation of undifferentiated cells that form the pharynx primordium; (2) immunoreactivity to TCAV-1 and TMUS-13, corresponding to the re-building of the pharynx; and (3) immunoreactivity to TF-26, corresponding to a fully mature and functional pharynx. The sequence of differentiation of these three cell types suggests that the pharynx grows by intercalation of new undifferentiated cells coming from the parenchyma between the older pharyngeal cells, in agreement with existing models of pharynx regeneration. Finally, our results suggest an intercalary model for pharynx epithelial cell renewal.
Research Interests:
The special morphological features of freshwater planarians make them an attractive and informative model for studying the processes of regeneration and pattern formation. In this work, we investigate pattern formation and maturation of... more
The special morphological features of freshwater planarians make them an attractive and informative model for studying the processes of regeneration and pattern formation. In this work, we investigate pattern formation and maturation of the planarian pharynx during regeneration in tail fragments. Using three monoclonal antibodies (TCAV-1, TF-26 and TMUS-13) specific for epithelial, secretory and muscle cells, respectively, we followed the sequence and timing of differentiation and maturation of these three cell types within the regenerating pharynx. Two of these monoclonal antibodies, TCAV-1 and TMUS-13, also labelled morphologically immature cells that appear to be committed to the differentiation pathway leading to their respective adult cell types. Our results show that the cells forming the new pharynx come from undifferentiated cells through proliferation and differentiation processes rather than from differentiated cells of the old stump. We describe three stages of pharynx regeneration according to the immunoreactivity shown: (1) no immunoreactivity, corresponding to the accumulation of undifferentiated cells that form the pharynx primordium; (2) immunoreactivity to TCAV-1 and TMUS-13, corresponding to the re-building of the pharynx; and (3) immunoreactivity to TF-26, corresponding to a fully mature and functional pharynx. The sequence of differentiation of these three cell types suggests that the pharynx grows by intercalation of new undifferentiated cells coming from the parenchyma between the older pharyngeal cells, in agreement with existing models of pharynx regeneration. Finally, our results suggest an intercalary model for pharynx epithelial cell renewal.
Research Interests:
The special morphological features of freshwater planarians make them an attractive and informative model for studying the processes of regeneration and pattern formation. In this work, we investigate pattern formation and maturation of... more
The special morphological features of freshwater planarians make them an attractive and informative model for studying the processes of regeneration and pattern formation. In this work, we investigate pattern formation and maturation of the planarian pharynx during regeneration in tail fragments. Using three monoclonal antibodies (TCAV-1, TF-26 and TMUS-13) specific for epithelial, secretory and muscle cells, respectively, we followed the sequence and timing of differentiation and maturation of these three cell types within the regenerating pharynx. Two of these monoclonal antibodies, TCAV-1 and TMUS-13, also labelled morphologically immature cells that appear to be committed to the differentiation pathway leading to their respective adult cell types. Our results show that the cells forming the new pharynx come from undifferentiated cells through proliferation and differentiation processes rather than from differentiated cells of the old stump. We describe three stages of pharynx regeneration according to the immunoreactivity shown: (1) no immunoreactivity, corresponding to the accumulation of undifferentiated cells that form the pharynx primordium; (2) immunoreactivity to TCAV-1 and TMUS-13, corresponding to the re-building of the pharynx; and (3) immunoreactivity to TF-26, corresponding to a fully mature and functional pharynx. The sequence of differentiation of these three cell types suggests that the pharynx grows by intercalation of new undifferentiated cells coming from the parenchyma between the older pharyngeal cells, in agreement with existing models of pharynx regeneration. Finally, our results suggest an intercalary model for pharynx epithelial cell renewal.
Research Interests:
Freshwater planarians (Platyhelminthes, Turbellaria) show a great degree of morphological plasticity, making them a useful model for studying cell differentiation and pattern restoration processes during regeneration. Using confocal... more
Freshwater planarians (Platyhelminthes, Turbellaria) show a great degree of morphological plasticity, making them a useful model for studying cell differentiation and pattern restoration processes during regeneration. Using confocal microscopy and a monoclonal antibody specific for muscle cells (TMUS-13), we have monitored the restoration of the body wall musculature during head regeneration in whole-mount organisms. Our results show that until the 4th day of regeneration the blastema is occupied by very disorganized muscle fibers, that from this moment become progressively organized restoring the original muscle pattern. In addition to recognizing mature muscle cells, TMUS-13 also recognizes differentiating myocytes, allowing us to trace the origin of newly formed muscle cells. We report that myocytes are detected in the postblastema region as early as day 1 of regeneration. This is the first demonstration that, in addition to serving as a proliferative zone as previously described, overt differentiation begins in the postblastema, at least for muscle cells. We also show that the TMUS13 antigen is the myosin heavy-chain gene from planarians.
Research Interests:
Freshwater planarians (Platyhelminthes, Turbellaria) show a great degree of morphological plasticity, making them a useful model for studying cell differentiation and pattern restoration processes during regeneration. Using confocal... more
Freshwater planarians (Platyhelminthes, Turbellaria) show a great degree of morphological plasticity, making them a useful model for studying cell differentiation and pattern restoration processes during regeneration. Using confocal microscopy and a monoclonal antibody specific for muscle cells (TMUS-13), we have monitored the restoration of the body wall musculature during head regeneration in whole-mount organisms. Our results show that until the 4th day of regeneration the blastema is occupied by very disorganized muscle fibers, that from this moment become progressively organized restoring the original muscle pattern. In addition to recognizing mature muscle cells, TMUS-13 also recognizes differentiating myocytes, allowing us to trace the origin of newly formed muscle cells. We report that myocytes are detected in the postblastema region as early as day 1 of regeneration. This is the first demonstration that, in addition to serving as a proliferative zone as previously described, overt differentiation begins in the postblastema, at least for muscle cells. We also show that the TMUS13 antigen is the myosin heavy-chain gene from planarians.
Research Interests:
To obtain specific immunological probes for studying molecular mechanisms involved in cell renewal, cell differentiation, and pattern formation in intact and regenerating planarians, we have produced a hybridoma library specific for the... more
To obtain specific immunological probes for studying molecular mechanisms involved in cell renewal, cell differentiation, and pattern formation in intact and regenerating planarians, we have produced a hybridoma library specific for the asexual race of the freshwater planarian Dugesia (Girardia) tigrina. Among the 276 monoclonal antibodies showing tissue-, cell-, cell subtype-, subcellular- and position-specific staining, we have found monoclonal antibodies against all tissues and cell types with the exception of neoblasts, the undifferentiated totipotent stem-cells in planarians. We have also detected position-specific antigens that label anterior, central, and posterior regions. Patterns of expression uncovered an unexpected heterogeneity among previously thought single cell types, as well as interesting cross-reactivities that deserve further study. Characterization of some of these monoclonal antibodies suggests they may be extremely useful as molecular markers for studying cell renewal and cell differentiation in the intact and regenerating organism, tracing the origin, lineage, and differentiation of blastema cells, and characterizing the stages and mechanisms of early pattern formation. Moreover, two position-specific monoclonals, the first ones isolated in planarians, will be instrumental in describing in molecular terms how the new pattern unfolds during regeneration and in devising the pattern formation model that best fits classical data on regeneration in planarians.
Research Interests:
To obtain specific immunological probes for studying molecular mechanisms involved in cell renewal, cell differentiation, and pattern formation in intact and regenerating planarians, we have produced a hybridoma library specific for the... more
To obtain specific immunological probes for studying molecular mechanisms involved in cell renewal, cell differentiation, and pattern formation in intact and regenerating planarians, we have produced a hybridoma library specific for the asexual race of the freshwater planarian Dugesia (Girardia) tigrina. Among the 276 monoclonal antibodies showing tissue-, cell-, cell subtype-, subcellular- and position-specific staining, we have found monoclonal antibodies against all tissues and cell types with the exception of neoblasts, the undifferentiated totipotent stem-cells in planarians. We have also detected position-specific antigens that label anterior, central, and posterior regions. Patterns of expression uncovered an unexpected heterogeneity among previously thought single cell types, as well as interesting cross-reactivities that deserve further study. Characterization of some of these monoclonal antibodies suggests they may be extremely useful as molecular markers for studying cell renewal and cell differentiation in the intact and regenerating organism, tracing the origin, lineage, and differentiation of blastema cells, and characterizing the stages and mechanisms of early pattern formation. Moreover, two position-specific monoclonals, the first ones isolated in planarians, will be instrumental in describing in molecular terms how the new pattern unfolds during regeneration and in devising the pattern formation model that best fits classical data on regeneration in planarians.
Research Interests:
Freshwater planarians (Platyhelminthes, Turbellaria) show a great degree of morphological plasticity, making them a useful model for studying cell differentiation and pattern restoration processes during regeneration. Using confocal... more
Freshwater planarians (Platyhelminthes, Turbellaria) show a great degree of morphological plasticity, making them a useful model for studying cell differentiation and pattern restoration processes during regeneration. Using confocal microscopy and a monoclonal antibody specific for muscle cells (TMUS-13), we have monitored the restoration of the body wall musculature during head regeneration in whole-mount organisms. Our results show that until the 4th day of regeneration the blastema is occupied by very disorganized muscle fibers, that from this moment become progressively organized restoring the original muscle pattern. In addition to recognizing mature muscle cells, TMUS-13 also recognizes differentiating myocytes, allowing us to trace the origin of newly formed muscle cells. We report that myocytes are detected in the postblastema region as early as day 1 of regeneration. This is the first demonstration that, in addition to serving as a proliferative zone as previously described, overt differentiation begins in the postblastema, at least for muscle cells. We also show that the TMUS13 antigen is the myosin heavy-chain gene from planarians.
Research Interests:
We have produced monoclonal antibodies (mAb's) against antigens of the fresh-water planarian Dugesia (G.) tigrina (Girard) using standard protocols. Labeling these mAb's with PAP (peroxidase-antiperoxidase) and indirect-immunofluorescence... more
We have produced monoclonal antibodies (mAb's) against antigens of the fresh-water planarian Dugesia (G.) tigrina (Girard) using standard protocols. Labeling these mAb's with PAP (peroxidase-antiperoxidase) and indirect-immunofluorescence methods, we then determined the distribution of their antigens in the planarian. Out of 112 mAb's that showed some specificity for restricted parts of the planarian, 71 were found to be cell- or tissue-specific — among them 36 for parenchymal cells, 7 for muscle cells, 11 for epidermal cells, 8 for gastrodermis, and 7 to basement membrane. Another 41 showed different, but overlapping, regional specificities, namely to pharynx and parenchyma. So far, we have been unable to isolate specific mAb's against undifferentiated cells (neoblasts). These mAb's should be important tools in study of tissue and cell morphology, regeneration, and growth and degrowth.
Research Interests:
We have produced monoclonal antibodies (mAb's) against antigens of the fresh-water planarian Dugesia (G.) tigrina (Girard) using standard protocols. Labeling these mAb's with PAP (peroxidase-antiperoxidase) and indirect-immunofluorescence... more
We have produced monoclonal antibodies (mAb's) against antigens of the fresh-water planarian Dugesia (G.) tigrina (Girard) using standard protocols. Labeling these mAb's with PAP (peroxidase-antiperoxidase) and indirect-immunofluorescence methods, we then determined the distribution of their antigens in the planarian. Out of 112 mAb's that showed some specificity for restricted parts of the planarian, 71 were found to be cell- or tissue-specific — among them 36 for parenchymal cells, 7 for muscle cells, 11 for epidermal cells, 8 for gastrodermis, and 7 to basement membrane. Another 41 showed different, but overlapping, regional specificities, namely to pharynx and parenchyma. So far, we have been unable to isolate specific mAb's against undifferentiated cells (neoblasts). These mAb's should be important tools in study of tissue and cell morphology, regeneration, and growth and degrowth.
Research Interests:
The special morphological features of freshwater planarians make them an attractive and informative model for studying the processes of regeneration and pattern formation. In this work, we investigate pattern formation and maturation of... more
The special morphological features of freshwater planarians make them an attractive and informative model for studying the processes of regeneration and pattern formation. In this work, we investigate pattern formation and maturation of the planarian pharynx during regeneration in tail fragments. Using three monoclonal antibodies (TCAV-1, TF-26 and TMUS-13) specific for epithelial, secretory and muscle cells, respectively, we followed the sequence and timing of differentiation and maturation of these three cell types within the regenerating pharynx. Two of these monoclonal antibodies, TCAV-1 and TMUS-13, also labelled morphologically immature cells that appear to be committed to the differentiation pathway leading to their respective adult cell types. Our results show that the cells forming the new pharynx come from undifferentiated cells through proliferation and differentiation processes rather than from differentiated cells of the old stump. We describe three stages of pharynx regeneration according to the immunoreactivity shown: (1) no immunoreactivity, corresponding to the accumulation of undifferentiated cells that form the pharynx primordium; (2) immunoreactivity to TCAV-1 and TMUS-13, corresponding to the re-building of the pharynx; and (3) immunoreactivity to TF-26, corresponding to a fully mature and functional pharynx. The sequence of differentiation of these three cell types suggests that the pharynx grows by intercalation of new undifferentiated cells coming from the parenchyma between the older pharyngeal cells, in agreement with existing models of pharynx regeneration. Finally, our results suggest an intercalary model for pharynx epithelial cell renewal.
Research Interests:
To obtain specific immunological probes for studying molecular mechanisms involved in cell renewal, cell differentiation, and pattern formation in intact and regenerating planarians, we have produced a hybridoma library specific for the... more
To obtain specific immunological probes for studying molecular mechanisms involved in cell renewal, cell differentiation, and pattern formation in intact and regenerating planarians, we have produced a hybridoma library specific for the asexual race of the freshwater planarian Dugesia (Girardia) tigrina. Among the 276 monoclonal antibodies showing tissue-, cell-, cell subtype-, subcellular- and position-specific staining, we have found monoclonal antibodies against all tissues and cell types with the exception of neoblasts, the undifferentiated totipotent stem-cells in planarians. We have also detected position-specific antigens that label anterior, central, and posterior regions. Patterns of expression uncovered an unexpected heterogeneity among previously thought single cell types, as well as interesting cross-reactivities that deserve further study. Characterization of some of these monoclonal antibodies suggests they may be extremely useful as molecular markers for studying cell renewal and cell differentiation in the intact and regenerating organism, tracing the origin, lineage, and differentiation of blastema cells, and characterizing the stages and mechanisms of early pattern formation. Moreover, two position-specific monoclonals, the first ones isolated in planarians, will be instrumental in describing in molecular terms how the new pattern unfolds during regeneration and in devising the pattern formation model that best fits classical data on regeneration in planarians.
Research Interests:
Research Interests: Developmental Biology, Electron Microscopy, Regeneration, Immunohistochemistry, Extracellular Matrix, and 11 moreBiological Sciences, Animals, P-glycoprotein, Monoclonal Antibodies, Positional information, Molecular weight, Monoclonal Antibody, Sensitivity and Specificity, Antigens, Planarians, and Relative Position
Freshwater planarians (Platyhelminthes, Turbellaria) show a great degree of morphological plasticity, making them a useful model for studying cell differentiation and pattern restoration processes during regeneration. Using confocal... more
Freshwater planarians (Platyhelminthes, Turbellaria) show a great degree of morphological plasticity, making them a useful model for studying cell differentiation and pattern restoration processes during regeneration. Using confocal microscopy and a monoclonal antibody specific for muscle cells (TMUS-13), we have monitored the restoration of the body wall musculature during head regeneration in whole-mount organisms. Our results show that until the 4th day of regeneration the blastema is occupied by very disorganized muscle fibers, that from this moment become progressively organized restoring the original muscle pattern. In addition to recognizing mature muscle cells, TMUS-13 also recognizes differentiating myocytes, allowing us to trace the origin of newly formed muscle cells. We report that myocytes are detected in the postblastema region as early as day 1 of regeneration. This is the first demonstration that, in addition to serving as a proliferative zone as previously described, overt differentiation begins in the postblastema, at least for muscle cells. We also show that the TMUS13 antigen is the myosin heavy-chain gene from planarians.
Research Interests:
Research Interests: Developmental Biology, Electron Microscopy, Regeneration, Immunohistochemistry, Extracellular Matrix, and 11 moreBiological Sciences, Animals, P-glycoprotein, Monoclonal Antibodies, Positional information, Molecular weight, Monoclonal Antibody, Sensitivity and Specificity, Antigens, Planarians, and Relative Position
Planarian cell renewal is achieved as a result of proliferation and differentiation of totipotent undifferentiated cells called neoblasts. The absence of mitosis within the planarian pharynx raises the question as to how cell renewal and... more
Planarian cell renewal is achieved as a result of proliferation and differentiation of totipotent undifferentiated cells called neoblasts. The absence of mitosis within the planarian pharynx raises the question as to how cell renewal and growth occur within this organ. Two explanations have been advanced: one proposes that new cells remain close to the base of the pharynx, which then grows by distal displacement of older cells, and the other suggests that the new cells are intercalated between older cells throughout the pharynx. The second alternative, however, does not explain how new cells enter the pharynx or how they reach their final destination. In this study of myosin heavy-chain gene expression within planarian pharynx, a row of differentiating myocytes was detected all along the pharynx parenchyma. According to the hybridization pattern, all these myocytes appeared to be at early stages of differentiation. These data favour an intercalary model for muscle cell renewal within the pharynx. According to this model, neoblasts at the base of the pharynx would enter the pharynx, where they would start differentiation to myocytes, move to the subepithelial musculature and intercalate between the old muscle cells. The possible application of this intercalary model to other pharynx cell types is also discussed.
Research Interests:
We have produced monoclonal antibodies (mAb's) against antigens of the fresh-water planarian Dugesia (G.) tigrina (Girard) using standard protocols. Labeling these mAb's with PAP (peroxidase-antiperoxidase) and indirect-immunofluorescence... more
We have produced monoclonal antibodies (mAb's) against antigens of the fresh-water planarian Dugesia (G.) tigrina (Girard) using standard protocols. Labeling these mAb's with PAP (peroxidase-antiperoxidase) and indirect-immunofluorescence methods, we then determined the distribution of their antigens in the planarian. Out of 112 mAb's that showed some specificity for restricted parts of the planarian, 71 were found to be cell- or tissue-specific — among them 36 for parenchymal cells, 7 for muscle cells, 11 for epidermal cells, 8 for gastrodermis, and 7 to basement membrane. Another 41 showed different, but overlapping, regional specificities, namely to pharynx and parenchyma. So far, we have been unable to isolate specific mAb's against undifferentiated cells (neoblasts). These mAb's should be important tools in study of tissue and cell morphology, regeneration, and growth and degrowth.
Research Interests:
The special morphological features of freshwater planarians make them an attractive and informative model for studying the processes of regeneration and pattern formation. In this work, we investigate pattern formation and maturation of... more
The special morphological features of freshwater planarians make them an attractive and informative model for studying the processes of regeneration and pattern formation. In this work, we investigate pattern formation and maturation of the planarian pharynx during regeneration in tail fragments. Using three monoclonal antibodies (TCAV-1, TF-26 and TMUS-13) specific for epithelial, secretory and muscle cells, respectively, we followed the sequence and timing of differentiation and maturation of these three cell types within the regenerating pharynx. Two of these monoclonal antibodies, TCAV-1 and TMUS-13, also labelled morphologically immature cells that appear to be committed to the differentiation pathway leading to their respective adult cell types. Our results show that the cells forming the new pharynx come from undifferentiated cells through proliferation and differentiation processes rather than from differentiated cells of the old stump. We describe three stages of pharynx regeneration according to the immunoreactivity shown: (1) no immunoreactivity, corresponding to the accumulation of undifferentiated cells that form the pharynx primordium; (2) immunoreactivity to TCAV-1 and TMUS-13, corresponding to the re-building of the pharynx; and (3) immunoreactivity to TF-26, corresponding to a fully mature and functional pharynx. The sequence of differentiation of these three cell types suggests that the pharynx grows by intercalation of new undifferentiated cells coming from the parenchyma between the older pharyngeal cells, in agreement with existing models of pharynx regeneration. Finally, our results suggest an intercalary model for pharynx epithelial cell renewal.
Research Interests:
Planarian cell renewal is achieved as a result of proliferation and differentiation of totipotent undifferentiated cells called neoblasts. The absence of mitosis within the planarian pharynx raises the question as to how cell renewal and... more
Planarian cell renewal is achieved as a result of proliferation and differentiation of totipotent undifferentiated cells called neoblasts. The absence of mitosis within the planarian pharynx raises the question as to how cell renewal and growth occur within this organ. Two explanations have been advanced: one proposes that new cells remain close to the base of the pharynx, which then grows by distal displacement of older cells, and the other suggests that the new cells are intercalated between older cells throughout the pharynx. The second alternative, however, does not explain how new cells enter the pharynx or how they reach their final destination. In this study of myosin heavy-chain gene expression within planarian pharynx, a row of differentiating myocytes was detected all along the pharynx parenchyma. According to the hybridization pattern, all these myocytes appeared to be at early stages of differentiation. These data favour an intercalary model for muscle cell renewal within the pharynx. According to this model, neoblasts at the base of the pharynx would enter the pharynx, where they would start differentiation to myocytes, move to the subepithelial musculature and intercalate between the old muscle cells. The possible application of this intercalary model to other pharynx cell types is also discussed.
Research Interests:
To obtain specific immunological probes for studying molecular mechanisms involved in cell renewal, cell differentiation, and pattern formation in intact and regenerating planarians, we have produced a hybridoma library specific for the... more
To obtain specific immunological probes for studying molecular mechanisms involved in cell renewal, cell differentiation, and pattern formation in intact and regenerating planarians, we have produced a hybridoma library specific for the asexual race of the freshwater planarian Dugesia (Girardia) tigrina. Among the 276 monoclonal antibodies showing tissue-, cell-, cell subtype-, subcellular- and position-specific staining, we have found monoclonal antibodies against all tissues and cell types with the exception of neoblasts, the undifferentiated totipotent stem-cells in planarians. We have also detected position-specific antigens that label anterior, central, and posterior regions. Patterns of expression uncovered an unexpected heterogeneity among previously thought single cell types, as well as interesting cross-reactivities that deserve further study. Characterization of some of these monoclonal antibodies suggests they may be extremely useful as molecular markers for studying cell renewal and cell differentiation in the intact and regenerating organism, tracing the origin, lineage, and differentiation of blastema cells, and characterizing the stages and mechanisms of early pattern formation. Moreover, two position-specific monoclonals, the first ones isolated in planarians, will be instrumental in describing in molecular terms how the new pattern unfolds during regeneration and in devising the pattern formation model that best fits classical data on regeneration in planarians.
Research Interests:
We have produced monoclonal antibodies (mAbs) against antigens of the freshwater planarian Dugesia (G.) tigrina (Girard) using standard protocols. One of these mAbs, TCEN-49, detects an antigen (TCEN-49Ag) present in most cells of the... more
We have produced monoclonal antibodies (mAbs) against antigens of the freshwater planarian Dugesia (G.) tigrina (Girard) using standard protocols. One of these mAbs, TCEN-49, detects an antigen (TCEN-49Ag) present in most cells of the central area of the body, including the pharynx. Labelled cells seem more related by position than by lineage, suggesting that TCEN-49Ag is involved somehow in the expression of central body positional identity. The spatial and temporal changes in TCEN-49Ag expression during growth/degrowth and regeneration have been monitored and the implications of these results are discussed.
Research Interests:
Research Interests: Developmental Biology, Electron Microscopy, Regeneration, Immunohistochemistry, Extracellular Matrix, and 11 moreBiological Sciences, Animals, P-glycoprotein, Monoclonal Antibodies, Positional information, Molecular weight, Monoclonal Antibody, Sensitivity and Specificity, Antigens, Planarians, and Relative Position
Freshwater planarians (Platyhelminthes, Turbellaria) show a great degree of morphological plasticity, making them a useful model for studying cell differentiation and pattern restoration processes during regeneration. Using confocal... more
Freshwater planarians (Platyhelminthes, Turbellaria) show a great degree of morphological plasticity, making them a useful model for studying cell differentiation and pattern restoration processes during regeneration. Using confocal microscopy and a monoclonal antibody specific for muscle cells (TMUS-13), we have monitored the restoration of the body wall musculature during head regeneration in whole-mount organisms. Our results show that until the 4th day of regeneration the blastema is occupied by very disorganized muscle fibers, that from this moment become progressively organized restoring the original muscle pattern. In addition to recognizing mature muscle cells, TMUS-13 also recognizes differentiating myocytes, allowing us to trace the origin of newly formed muscle cells. We report that myocytes are detected in the postblastema region as early as day 1 of regeneration. This is the first demonstration that, in addition to serving as a proliferative zone as previously described, overt differentiation begins in the postblastema, at least for muscle cells. We also show that the TMUS13 antigen is the myosin heavy-chain gene from planarians.
Research Interests:
The special morphological features of freshwater planarians make them an attractive and informative model for studying the processes of regeneration and pattern formation. In this work, we investigate pattern formation and maturation of... more
The special morphological features of freshwater planarians make them an attractive and informative model for studying the processes of regeneration and pattern formation. In this work, we investigate pattern formation and maturation of the planarian pharynx during regeneration in tail fragments. Using three monoclonal antibodies (TCAV-1, TF-26 and TMUS-13) specific for epithelial, secretory and muscle cells, respectively, we followed the sequence and timing of differentiation and maturation of these three cell types within the regenerating pharynx. Two of these monoclonal antibodies, TCAV-1 and TMUS-13, also labelled morphologically immature cells that appear to be committed to the differentiation pathway leading to their respective adult cell types. Our results show that the cells forming the new pharynx come from undifferentiated cells through proliferation and differentiation processes rather than from differentiated cells of the old stump. We describe three stages of pharynx regeneration according to the immunoreactivity shown: (1) no immunoreactivity, corresponding to the accumulation of undifferentiated cells that form the pharynx primordium; (2) immunoreactivity to TCAV-1 and TMUS-13, corresponding to the re-building of the pharynx; and (3) immunoreactivity to TF-26, corresponding to a fully mature and functional pharynx. The sequence of differentiation of these three cell types suggests that the pharynx grows by intercalation of new undifferentiated cells coming from the parenchyma between the older pharyngeal cells, in agreement with existing models of pharynx regeneration. Finally, our results suggest an intercalary model for pharynx epithelial cell renewal.
Research Interests:
We have produced monoclonal antibodies (mAb's) against antigens of the fresh-water planarian Dugesia (G.) tigrina (Girard) using standard protocols. Labeling these mAb's with PAP (peroxidase-antiperoxidase) and indirect-immunofluorescence... more
We have produced monoclonal antibodies (mAb's) against antigens of the fresh-water planarian Dugesia (G.) tigrina (Girard) using standard protocols. Labeling these mAb's with PAP (peroxidase-antiperoxidase) and indirect-immunofluorescence methods, we then determined the distribution of their antigens in the planarian. Out of 112 mAb's that showed some specificity for restricted parts of the planarian, 71 were found to be cell- or tissue-specific — among them 36 for parenchymal cells, 7 for muscle cells, 11 for epidermal cells, 8 for gastrodermis, and 7 to basement membrane. Another 41 showed different, but overlapping, regional specificities, namely to pharynx and parenchyma. So far, we have been unable to isolate specific mAb's against undifferentiated cells (neoblasts). These mAb's should be important tools in study of tissue and cell morphology, regeneration, and growth and degrowth.
Research Interests:
Planarian cell renewal is achieved as a result of proliferation and differentiation of totipotent undifferentiated cells called neoblasts. The absence of mitosis within the planarian pharynx raises the question as to how cell renewal and... more
Planarian cell renewal is achieved as a result of proliferation and differentiation of totipotent undifferentiated cells called neoblasts. The absence of mitosis within the planarian pharynx raises the question as to how cell renewal and growth occur within this organ. Two explanations have been advanced: one proposes that new cells remain close to the base of the pharynx, which then grows by distal displacement of older cells, and the other suggests that the new cells are intercalated between older cells throughout the pharynx. The second alternative, however, does not explain how new cells enter the pharynx or how they reach their final destination. In this study of myosin heavy-chain gene expression within planarian pharynx, a row of differentiating myocytes was detected all along the pharynx parenchyma. According to the hybridization pattern, all these myocytes appeared to be at early stages of differentiation. These data favour an intercalary model for muscle cell renewal within the pharynx. According to this model, neoblasts at the base of the pharynx would enter the pharynx, where they would start differentiation to myocytes, move to the subepithelial musculature and intercalate between the old muscle cells. The possible application of this intercalary model to other pharynx cell types is also discussed.
Research Interests:
To obtain specific immunological probes for studying molecular mechanisms involved in cell renewal, cell differentiation, and pattern formation in intact and regenerating planarians, we have produced a hybridoma library specific for the... more
To obtain specific immunological probes for studying molecular mechanisms involved in cell renewal, cell differentiation, and pattern formation in intact and regenerating planarians, we have produced a hybridoma library specific for the asexual race of the freshwater planarian Dugesia (Girardia) tigrina. Among the 276 monoclonal antibodies showing tissue-, cell-, cell subtype-, subcellular- and position-specific staining, we have found monoclonal antibodies against all tissues and cell types with the exception of neoblasts, the undifferentiated totipotent stem-cells in planarians. We have also detected position-specific antigens that label anterior, central, and posterior regions. Patterns of expression uncovered an unexpected heterogeneity among previously thought single cell types, as well as interesting cross-reactivities that deserve further study. Characterization of some of these monoclonal antibodies suggests they may be extremely useful as molecular markers for studying cell renewal and cell differentiation in the intact and regenerating organism, tracing the origin, lineage, and differentiation of blastema cells, and characterizing the stages and mechanisms of early pattern formation. Moreover, two position-specific monoclonals, the first ones isolated in planarians, will be instrumental in describing in molecular terms how the new pattern unfolds during regeneration and in devising the pattern formation model that best fits classical data on regeneration in planarians.
Research Interests:
Freshwater planarians (Platyhelminthes, Turbellaria) show a great degree of morphological plasticity, making them a useful model for studying cell differentiation and pattern restoration processes during regeneration. Using confocal... more
Freshwater planarians (Platyhelminthes, Turbellaria) show a great degree of morphological plasticity, making them a useful model for studying cell differentiation and pattern restoration processes during regeneration. Using confocal microscopy and a monoclonal antibody specific for muscle cells (TMUS-13), we have monitored the restoration of the body wall musculature during head regeneration in whole-mount organisms. Our results show that until the 4th day of regeneration the blastema is occupied by very disorganized muscle fibers, that from this moment become progressively organized restoring the original muscle pattern. In addition to recognizing mature muscle cells, TMUS-13 also recognizes differentiating myocytes, allowing us to trace the origin of newly formed muscle cells. We report that myocytes are detected in the postblastema region as early as day 1 of regeneration. This is the first demonstration that, in addition to serving as a proliferative zone as previously described, overt differentiation begins in the postblastema, at least for muscle cells. We also show that the TMUS13 antigen is the myosin heavy-chain gene from planarians.
Research Interests:
We have produced monoclonal antibodies (mAb's) against antigens of the fresh-water planarian Dugesia (G.) tigrina (Girard) using standard protocols. Labeling these mAb's with PAP (peroxidase-antiperoxidase) and indirect-immunofluorescence... more
We have produced monoclonal antibodies (mAb's) against antigens of the fresh-water planarian Dugesia (G.) tigrina (Girard) using standard protocols. Labeling these mAb's with PAP (peroxidase-antiperoxidase) and indirect-immunofluorescence methods, we then determined the distribution of their antigens in the planarian. Out of 112 mAb's that showed some specificity for restricted parts of the planarian, 71 were found to be cell- or tissue-specific — among them 36 for parenchymal cells, 7 for muscle cells, 11 for epidermal cells, 8 for gastrodermis, and 7 to basement membrane. Another 41 showed different, but overlapping, regional specificities, namely to pharynx and parenchyma. So far, we have been unable to isolate specific mAb's against undifferentiated cells (neoblasts). These mAb's should be important tools in study of tissue and cell morphology, regeneration, and growth and degrowth.
Research Interests:
Research Interests: Developmental Biology, Electron Microscopy, Regeneration, Immunohistochemistry, Extracellular Matrix, and 11 moreBiological Sciences, Animals, P-glycoprotein, Monoclonal Antibodies, Positional information, Molecular weight, Monoclonal Antibody, Sensitivity and Specificity, Antigens, Planarians, and Relative Position
We have produced monoclonal antibodies (mAbs) against antigens of the freshwater planarian Dugesia (G.) tigrina (Girard) using standard protocols. One of these mAbs, TCEN-49, detects an antigen (TCEN-49Ag) present in most cells of the... more
We have produced monoclonal antibodies (mAbs) against antigens of the freshwater planarian Dugesia (G.) tigrina (Girard) using standard protocols. One of these mAbs, TCEN-49, detects an antigen (TCEN-49Ag) present in most cells of the central area of the body, including the pharynx. Labelled cells seem more related by position than by lineage, suggesting that TCEN-49Ag is involved somehow in the expression of central body positional identity. The spatial and temporal changes in TCEN-49Ag expression during growth/degrowth and regeneration have been monitored and the implications of these results are discussed.
Research Interests:
To obtain specific immunological probes for studying molecular mechanisms involved in cell renewal, cell differentiation, and pattern formation in intact and regenerating planarians, we have produced a hybridoma library specific for the... more
To obtain specific immunological probes for studying molecular mechanisms involved in cell renewal, cell differentiation, and pattern formation in intact and regenerating planarians, we have produced a hybridoma library specific for the asexual race of the freshwater planarian Dugesia (Girardia) tigrina. Among the 276 monoclonal antibodies showing tissue-, cell-, cell subtype-, subcellular- and position-specific staining, we have found monoclonal antibodies against all tissues and cell types with the exception of neoblasts, the undifferentiated totipotent stem-cells in planarians. We have also detected position-specific antigens that label anterior, central, and posterior regions. Patterns of expression uncovered an unexpected heterogeneity among previously thought single cell types, as well as interesting cross-reactivities that deserve further study. Characterization of some of these monoclonal antibodies suggests they may be extremely useful as molecular markers for studying cell renewal and cell differentiation in the intact and regenerating organism, tracing the origin, lineage, and differentiation of blastema cells, and characterizing the stages and mechanisms of early pattern formation. Moreover, two position-specific monoclonals, the first ones isolated in planarians, will be instrumental in describing in molecular terms how the new pattern unfolds during regeneration and in devising the pattern formation model that best fits classical data on regeneration in planarians.
Research Interests:
Planarian cell renewal is achieved as a result of proliferation and differentiation of totipotent undifferentiated cells called neoblasts. The absence of mitosis within the planarian pharynx raises the question as to how cell renewal and... more
Planarian cell renewal is achieved as a result of proliferation and differentiation of totipotent undifferentiated cells called neoblasts. The absence of mitosis within the planarian pharynx raises the question as to how cell renewal and growth occur within this organ. Two explanations have been advanced: one proposes that new cells remain close to the base of the pharynx, which then grows by distal displacement of older cells, and the other suggests that the new cells are intercalated between older cells throughout the pharynx. The second alternative, however, does not explain how new cells enter the pharynx or how they reach their final destination. In this study of myosin heavy-chain gene expression within planarian pharynx, a row of differentiating myocytes was detected all along the pharynx parenchyma. According to the hybridization pattern, all these myocytes appeared to be at early stages of differentiation. These data favour an intercalary model for muscle cell renewal within the pharynx. According to this model, neoblasts at the base of the pharynx would enter the pharynx, where they would start differentiation to myocytes, move to the subepithelial musculature and intercalate between the old muscle cells. The possible application of this intercalary model to other pharynx cell types is also discussed.
Research Interests:
Research Interests: Developmental Biology, Electron Microscopy, Regeneration, Immunohistochemistry, Extracellular Matrix, and 11 moreBiological Sciences, Animals, P-glycoprotein, Monoclonal Antibodies, Positional information, Molecular weight, Monoclonal Antibody, Sensitivity and Specificity, Antigens, Planarians, and Relative Position
We have produced monoclonal antibodies (mAb's) against antigens of the fresh-water planarian Dugesia (G.) tigrina (Girard) using standard protocols. Labeling these mAb's with PAP (peroxidase-antiperoxidase) and indirect-immunofluorescence... more
We have produced monoclonal antibodies (mAb's) against antigens of the fresh-water planarian Dugesia (G.) tigrina (Girard) using standard protocols. Labeling these mAb's with PAP (peroxidase-antiperoxidase) and indirect-immunofluorescence methods, we then determined the distribution of their antigens in the planarian. Out of 112 mAb's that showed some specificity for restricted parts of the planarian, 71 were found to be cell- or tissue-specific — among them 36 for parenchymal cells, 7 for muscle cells, 11 for epidermal cells, 8 for gastrodermis, and 7 to basement membrane. Another 41 showed different, but overlapping, regional specificities, namely to pharynx and parenchyma. So far, we have been unable to isolate specific mAb's against undifferentiated cells (neoblasts). These mAb's should be important tools in study of tissue and cell morphology, regeneration, and growth and degrowth.
Research Interests:
We have produced monoclonal antibodies (mAbs) against antigens of the freshwater planarian Dugesia (G.) tigrina (Girard) using standard protocols. One of these mAbs, TCEN-49, detects an antigen (TCEN-49Ag) present in most cells of the... more
We have produced monoclonal antibodies (mAbs) against antigens of the freshwater planarian Dugesia (G.) tigrina (Girard) using standard protocols. One of these mAbs, TCEN-49, detects an antigen (TCEN-49Ag) present in most cells of the central area of the body, including the pharynx. Labelled cells seem more related by position than by lineage, suggesting that TCEN-49Ag is involved somehow in the expression of central body positional identity. The spatial and temporal changes in TCEN-49Ag expression during growth/degrowth and regeneration have been monitored and the implications of these results are discussed.
Research Interests:
Planarian cell renewal is achieved as a result of proliferation and differentiation of totipotent undifferentiated cells called neoblasts. The absence of mitosis within the planarian pharynx raises the question as to how cell renewal and... more
Planarian cell renewal is achieved as a result of proliferation and differentiation of totipotent undifferentiated cells called neoblasts. The absence of mitosis within the planarian pharynx raises the question as to how cell renewal and growth occur within this organ. Two explanations have been advanced: one proposes that new cells remain close to the base of the pharynx, which then grows by distal displacement of older cells, and the other suggests that the new cells are intercalated between older cells throughout the pharynx. The second alternative, however, does not explain how new cells enter the pharynx or how they reach their final destination. In this study of myosin heavy-chain gene expression within planarian pharynx, a row of differentiating myocytes was detected all along the pharynx parenchyma. According to the hybridization pattern, all these myocytes appeared to be at early stages of differentiation. These data favour an intercalary model for muscle cell renewal within the pharynx. According to this model, neoblasts at the base of the pharynx would enter the pharynx, where they would start differentiation to myocytes, move to the subepithelial musculature and intercalate between the old muscle cells. The possible application of this intercalary model to other pharynx cell types is also discussed.
Research Interests:
Research Interests: Developmental Biology, Electron Microscopy, Regeneration, Immunohistochemistry, Extracellular Matrix, and 11 moreBiological Sciences, Animals, P-glycoprotein, Monoclonal Antibodies, Positional information, Molecular weight, Monoclonal Antibody, Sensitivity and Specificity, Antigens, Planarians, and Relative Position
We have produced monoclonal antibodies (mAbs) against antigens of the freshwater planarian Dugesia (G.) tigrina (Girard) using standard protocols. One of these mAbs, TCEN-49, detects an antigen (TCEN-49Ag) present in most cells of the... more
We have produced monoclonal antibodies (mAbs) against antigens of the freshwater planarian Dugesia (G.) tigrina (Girard) using standard protocols. One of these mAbs, TCEN-49, detects an antigen (TCEN-49Ag) present in most cells of the central area of the body, including the pharynx. Labelled cells seem more related by position than by lineage, suggesting that TCEN-49Ag is involved somehow in the expression of central body positional identity. The spatial and temporal changes in TCEN-49Ag expression during growth/degrowth and regeneration have been monitored and the implications of these results are discussed.
Research Interests:
We have produced monoclonal antibodies (mAbs) against antigens of the freshwater planarian Dugesia (G.) tigrina (Girard) using standard protocols. One of these mAbs, TCEN-49, detects an antigen (TCEN-49Ag) present in most cells of the... more
We have produced monoclonal antibodies (mAbs) against antigens of the freshwater planarian Dugesia (G.) tigrina (Girard) using standard protocols. One of these mAbs, TCEN-49, detects an antigen (TCEN-49Ag) present in most cells of the central area of the body, including the pharynx. Labelled cells seem more related by position than by lineage, suggesting that TCEN-49Ag is involved somehow in the expression of central body positional identity. The spatial and temporal changes in TCEN-49Ag expression during growth/degrowth and regeneration have been monitored and the implications of these results are discussed.
Research Interests:
Planarian cell renewal is achieved as a result of proliferation and differentiation of totipotent undifferentiated cells called neoblasts. The absence of mitosis within the planarian pharynx raises the question as to how cell renewal and... more
Planarian cell renewal is achieved as a result of proliferation and differentiation of totipotent undifferentiated cells called neoblasts. The absence of mitosis within the planarian pharynx raises the question as to how cell renewal and growth occur within this organ. Two explanations have been advanced: one proposes that new cells remain close to the base of the pharynx, which then grows by distal displacement of older cells, and the other suggests that the new cells are intercalated between older cells throughout the pharynx. The second alternative, however, does not explain how new cells enter the pharynx or how they reach their final destination. In this study of myosin heavy-chain gene expression within planarian pharynx, a row of differentiating myocytes was detected all along the pharynx parenchyma. According to the hybridization pattern, all these myocytes appeared to be at early stages of differentiation. These data favour an intercalary model for muscle cell renewal within the pharynx. According to this model, neoblasts at the base of the pharynx would enter the pharynx, where they would start differentiation to myocytes, move to the subepithelial musculature and intercalate between the old muscle cells. The possible application of this intercalary model to other pharynx cell types is also discussed.
Research Interests:
We have produced monoclonal antibodies (mAbs) against antigens of the freshwater planarian Dugesia (G.) tigrina (Girard) using standard protocols. One of these mAbs, TCEN-49, detects an antigen (TCEN-49Ag) present in most cells of the... more
We have produced monoclonal antibodies (mAbs) against antigens of the freshwater planarian Dugesia (G.) tigrina (Girard) using standard protocols. One of these mAbs, TCEN-49, detects an antigen (TCEN-49Ag) present in most cells of the central area of the body, including the pharynx. Labelled cells seem more related by position than by lineage, suggesting that TCEN-49Ag is involved somehow in the expression of central body positional identity. The spatial and temporal changes in TCEN-49Ag expression during growth/degrowth and regeneration have been monitored and the implications of these results are discussed.
Research Interests:
The idea of personalizing the interactions of a system is not new. With stereotypes the users are grouped into classes where all the users in a class have similar characteristics. Personalization was therefore not on individual basis but... more
The idea of personalizing the interactions of a system is not new. With stereotypes the users are grouped into classes where all the users in a class have similar characteristics. Personalization was therefore not on individual basis but on a group of users. Personalized systems are also used in Intelligent Tutoring Systems (ITS) and in information filtering. In ITS, the pedagogical activities of a learner is personalized and in information filtering, the long-term stable information need of the user is used to filter incoming new information. We propose an explicit individual user model for representing the user’s activities during information retrieval. One of the new ideas here is that personalization is really individualized and linked with the user’s objective, that is his information need. Our proposals are implemented in the prototype METIORE for providing access to the publications in our laboratory. This prototype was experimented and we present in this paper the first results of our observation.
Research Interests:
Most of the information of the WWW is not adaptive, rather it is dispersed and disorganized. On the other hand, the creation of an adaptive course is a complex task. SIGUE is an author tool that makes possible to build adaptive courses... more
Most of the information of the WWW is not adaptive, rather it is dispersed and disorganized. On the other hand, the creation of an adaptive course is a complex task. SIGUE is an author tool that makes possible to build adaptive courses using existing web pages. This means that if there is a lot of information on the web about the same topic the author doesn’t have to design the content of a specific course, he can reuse these pages to build his own course, taking the best pages for the concepts he wants to explain. The author can also construct adaptive courses reusing previously non-adaptive ones. SIGUE provides an enhanced interface for the student, controls his interaction, and annotates the visited links in a student model.
Research Interests:
The size of Internet has been growing very fast and many documents appear every day in the Net. Users find many problems in obtaining the information that they really need. In order to help users in this task of finding relevant... more
The size of Internet has been growing very fast and many documents appear every day in the Net. Users find many problems in obtaining the information that they really need. In order to help users in this task of finding relevant information, recommending systems were proposed. They give advice using two methods: the content-based method that extracts information from the already evaluated documents by the user in order to obtain new related documents; the collaborative method that recommends documents to the user based on the evaluation by users with similar information needs. In this paper we analyze some existing Web recommending systems and identify some problems which we try to solve in our system METIOREW.
Research Interests:
The idea of personalizing the interactions of a system is not new. With stereotypes the users are grouped into classes where all the users in a class have similar characteristics. Personalization was therefore not on individual basis but... more
The idea of personalizing the interactions of a system is not new. With stereotypes the users are grouped into classes where all the users in a class have similar characteristics. Personalization was therefore not on individual basis but on a group of users. Personalized systems are also used in Intelligent Tutoring Systems (ITS) and in information filtering. In ITS, the pedagogical activities of a learner is personalized and in information filtering, the long-term stable information need of the user is used to filter incoming new information. We propose an explicit individual user model for representing the user’s activities during information retrieval. One of the new ideas here is that personalization is really individualized and linked with the user’s objective, that is his information need. Our proposals are implemented in the prototype METIORE for providing access to the publications in our laboratory. This prototype was experimented and we present in this paper the first results of our observation.
Research Interests:
Most of the information of the WWW is not adaptive, rather it is dispersed and disorganized. On the other hand, the creation of an adaptive course is a complex task. SIGUE is an author tool that makes possible to build adaptive courses... more
Most of the information of the WWW is not adaptive, rather it is dispersed and disorganized. On the other hand, the creation of an adaptive course is a complex task. SIGUE is an author tool that makes possible to build adaptive courses using existing web pages. This means that if there is a lot of information on the web about the same topic the author doesn’t have to design the content of a specific course, he can reuse these pages to build his own course, taking the best pages for the concepts he wants to explain. The author can also construct adaptive courses reusing previously non-adaptive ones. SIGUE provides an enhanced interface for the student, controls his interaction, and annotates the visited links in a student model.