Your search keyword '"Keith R. Porter"' showing total 7 results

1. Chromatophores--models for studying cytomatrix translocations

Author

Keith R. Porter and M. A. McNiven

Subjects

Cytoplasm, Supplement: The Cytoplasmic Matrix and the Integration of Cellular Function, Energy metabolism, Melanophores, chemistry.chemical_element, Chromosomal translocation, Biology, Calcium, Microtubules, chemistry.chemical_compound, Adenosine Triphosphate, Microtubule, Organoid, Animals, Chromatophores, Fishes, Biological Transport, Cell Biology, Actomyosin, Pigments, Biological, Chromatophore, Cell biology, Organoids, chemistry, Energy Metabolism, Adenosine triphosphate

Published

1984

2. Microtubule polarity confers direction to pigment transport in chromatophores

Author

Keith R. Porter and Mark A. McNiven

Subjects

Melanins, education.field_of_study, Paclitaxel, Polarity (physics), Population, Fishes, Melanophores, Biological Transport, Cell Biology, Anatomy, Articles, Biology, Chromatophore, Microtubules, Melanophore, Pigment, Alkaloids, Microtubule, visual_art, Organelle, visual_art.visual_art_medium, Biophysics, Animals, education

Abstract

The cellular mechanisms used to direct translocating organelles are poorly understood. It is believed that the intrinsic structural polarity of microtubules may play a role in this process. We have examined the effects that differently oriented microtubules have upon the direction of pigment transport in surgically severed melanophore arms. In a previous paper (McNiven, M. A., M. Wang, and K. R. Porter, 1984, Cell, 37:753-765) we reported that after isolation, arms repolarized and reoriented their microtubules outward from their centers as if to form new "microcells." Pigment aggregation in these arms was toward a new focal point located at the arm centers. In this study we monitored pigment movement in isolated arms containing taxol-stabilized microtubules to test if the reversal in direction of pigment transport is dependent upon the repolarization of microtubules. We report that taxol delays both the microtubule reorientation and reversal in transport direction in a concentration-dependent manner. These and other presented data suggest that the polarity of the microtubule population within a melanophore confers direction on pigment transport.

Published

1986

3. CYTOPLASMIC COMPONENTS IN HEPATIC CELL LYSOSOMES

Author

Thomas P. Ashford and Keith R. Porter

Subjects

Cytoplasm, Liver, Hepatic stellate cell, Hepatocytes, Humans, Cell Biology, Biology, Lysosomes, ATG16L1, Brief Notes, Article, Cell biology

Published

1962

4. MICROTUBULES IN THE FORMATION AND DEVELOPMENT OF THE PRIMARY MESENCHYME IN ARBACIA PUNCTULATA

Author

Lewis G. Tilney, Keith R. Porter, and John R. Gibbins

Subjects

Cytoplasm, Centriole, Mesenchyme, Cell Membrane, Mitosis, Cell Differentiation, Cell Biology, Aster (cell biology), Biology, Endoplasmic Reticulum, Article, Cell biology, Microscopy, Electron, medicine.anatomical_structure, Microtubule, medicine, Morphogenesis, Basal body, Animals, Pseudopodia, Astral microtubules, Ribosomes, Germ Layers, Echinodermata

Abstract

Prior to gastrulation, the microtubules in the presumptive primary mesenchyme cells appear to diverge from points (satellites) in close association with the basal body of the cilium; from here most of the microtubules extend basally down the lateral margins of the cell. As these cells begin their migration into the blastocoel, they lose their cilia and adopt a spherical form. At the center of these newly formed mesenchyme cells is a centriole on which the microtubules directly converge and from which they radiate in all directions. Later these same cells develop slender pseudopodia containing large numbers of microtubules; the pseudopodia come into contact and fuse to form a "cable" of cytoplasm. Microtubules are now distributed parallel to the long axis of the cable and parallel to the stalks which connect the cell bodies of the mesenchyme cells to the cable. Microtubules are no longer connected to the centrioles in the cell bodies. On the basis of these observations we suggest that microtubules are a morphological expression of a framework which opeartes to shape cells. Since at each stage in the developmental sequence microtubules appear to originate (or insert) on different sites in the cytoplasm, the possibility is discussed that these sites may ultimately control the distribution of the microtubules and thus the developmental sequence of form changes.

Published

1969

5. YOLK PROTEIN UPTAKE IN THE OOCYTE OF THE MOSQUITO AEDES AEGYPTI. L

Author

Keith R. Porter and Thomas F. Roth

Subjects

Cytoplasm, food.ingredient, Egg protein, Biology, Article, food, Aedes, Yolk, medicine, Animals, Humans, Micropinocytosis, Microscopy, Vesicle, Research, Cell Membrane, Egg Proteins, Ovary, Proteins, Midgut, Cell Biology, Oocyte, Transport protein, Cell biology, Microscopy, Electron, Protein Transport, medicine.anatomical_structure, Biochemistry, Oocytes, Pinocytosis, Female, Vitellogenesis

Abstract

Yolk proteins are thought to enter certain eggs by a process akin to micropinocytosis but the detailed mechanism has not been previously depicted. In this study the formation of protein yolk was investigated in the mosquito Aedes aegypti L. Ovaries were fixed in phosphate-buffered osmium tetroxide, for electron microscopy, before and at intervals after a meal of blood. The deposition of protein yolk in the oocyte was correlated with a 15-fold increase in 140 mµ pit-like depressions on the oocyte surface. These pits form by invagination of the oocyte cell membrane. They have a 20 mµ bristle coat on their convex cytoplasmic side. They also show a layer of protein on their concave extracellular side which we propose accumulates by selective adsorption from the extraoocyte space. The pits, by pinching off from the cell membrane become bristle-coated vesicles which carry the adsorbed protein into the oocyte. These vesicles lose the coat and then fuse to form small crystalline yolk droplets, which subsequently coalesce to form the large proteid yolk bodies of the mature oocyte. Preliminary radioautographs, and certain morphological features of the fat body, ovary, and midgut, suggest that the midgut is the principal site of yolk protein synthesis in the mosquito.

Published

1964

6. STUDIES ON THE MICROTUBULES IN HELIOZOA

Author

Keith R. Porter and Lewis G. Tilney

Subjects

Axoneme, Cytoplasm, biology, Eukaryota, Actinosphaerium nucleofilum, Cold treatment, Cell Biology, Anatomy, Models, Theoretical, biology.organism_classification, Article, Cold Temperature, Organoids, Recovery period, Heliozoa, Microscopy, Electron, Tubule, Microtubule, Biophysics, Animals

Abstract

When specimens of Actinosphaerium nucleofilum are placed at 4°C, the axopodia retract and the birefringent core (axoneme) of each axopodium disappears. In fixed specimens, it has been shown that this structure consists of a highly patterned bundle of microtubules, each 220 A in diameter; during cold treatment these microtubules disappear and do not reform until the organisms are removed to room temperature. Within a few minutes after returning the specimens to room temperature, the axonemes reappear and the axopodia begin to reform reaching normal length 30–45 min later. In thin sections of cells fixed during the early stages of this recovery period, microtubules, organized in the pattern of the untreated specimens, are found in each reforming axopodium. Reforming axopodia without birefringent axonemes (and thus without microtubules) are never encountered. From these observations we conclude that the microtubules may be instrumental not only in the maintenance of the axopodia but also in their growth. Thus, if the microtubules are destroyed, the axopodia should retract and not reform until these tubular units are reassembled. During the cold treatment short segments of a 340-A tubule appeared; when the organisms were removed from the cold, these tubular segments disappeared. It seems probable that they are one of the disintegration products of the microtubules. A model is presented of our interpretation of how a 220-A microtubule transforms into a 340-A tubule and what this means in terms of the substructure of the untreated microtubules.

Published

1967

7. SARCOLEMMAL INVAGINATIONS CONSTITUTING THE T SYSTEM IN FISH MUSCLE FIBERS

Author

Clara Franzini-Armstrong and Keith R. Porter

Subjects

Sarcomeres, Cytoplasm, Electrons, Biology, Sarcomere, Article, chemistry.chemical_compound, Sarcolemma, Myofibrils, Extracellular, Animals, Histology, Comparative, Fixation (histology), Microscopy, Endoplasmic reticulum, Muscles, Research, Fishes, Cell Biology, Anatomy, Microscopy, Electron, Sarcoplasmic Reticulum, chemistry, Osmium tetroxide, Biophysics, Glutaraldehyde, Myofibril

Abstract

Striated muscle fibers from the body and tail myotomes of a fish, the black Mollie, have been examined with particular attention to the sarcoplasmic reticulum (SR) and transverse tubular (or T) system. The material was fixed in osmium tetroxide and in glutaraldehyde, and the images provided by the two kinds of fixatives were compared. Glutaraldehyde fixes a fine structure that is broadly comparable with that preserved by osmium tetroxide alone but differs in some significant details. Especially significant improvements were obtained in the preservation of the T system, that is, the system of small tubules that pervades the fiber at every Z line or A-I junction level. As a result of this improved glutaraldehyde fixation, the T system is now clearly defined as an entity of fine structure distinct from the SR but uniquely associated with the SR and myofibrils. Glutaraldehyde fixation also reveals that the T system is a sarcolemmal derivative that retains its continuity with the sarcolemma and limits a space that is in direct communication with the extracellular environment. These structural features favor the conclusion that the T system plays a prominent role in the fast intracellular conduction of the excitatory impulse. The preservation of other elements of muscle fine structure, including the myofibrils, seems for reasons discussed, to be substantially improved by glutaraldehyde.

Published

1964