Organization of the cortical endoplasmic reticulum in the squid giant axon.

The organization of the cortical endoplasmic reticulum in the squid giant axon was investigated by rapid freeze and freeze-substitution electron microscopy, thereby eliminating the effects of fixatives on this potentially labile structure. Juvenile squid, which have thinner Schwann sheaths, were used in order to achieve freezing deep enough to include the entire axonal cortex. The smooth endoplasmic reticulum is composed of subaxolemmal and deeper cisternae, tubules, tethers and vesicles. The subaxolemmal cisternae make junctional contacts with the axolemma which are characterized by filamentous-granular bridging structures approximately 3 nm in diameter. The subaxolemmal junctions with the axolemma resemble the coupling junctions between the sarcoplasmic reticulum and the T-tubules in muscle. Reconstruction of short series of sections showed that a number of the elements of the endoplasmic reticulum were continuous but numerous separate vesicles were present as well. The morphology of endoplasmic reticulum as described here suggests that it is a highly dynamic entity as well as a Ca2+ sequestering organelle.

Role of cytokeratin intermediate filaments in transhepatic transport and canalicular secretion.

The role of cytokeratin filaments in the function of hepatocytes was investigated using a nickel-treated hepatocyte in vitro model. Cytokeratin intermediate filaments were selectively dissociated from the cell cortex by nickel treatment. Cytokeratins and ubiquitin were observed using immunofluorescence and immunoelectron microscopy. Hepatocytic function was assessed by visualizing uptake, transhepatic transport and secretion of fluorescein diacetate and horseradish peroxidase into the bile canaliculi. In control primary cultures, most of the bile canaliculi were surrounded by an inner layer of actin filaments and an outer pericanalicular sheath of cytokeratin filaments and microtubules. The cytoplasmic distribution of ubiquitin was diffuse and particulate. After treatment with NiCl2 (150 micrograms/ml) for 24 hr, the cytokeratin filaments and desmoplakin became focally detached from the cell cortex and retracted to form an aggregate around the nucleus. These aggregates were associated with intense ubiquitin immunoreactivity. Only a few attachments of the cytokeratin filaments to the cell cortex remained. F-actin remained attached to the cell cortex in the areas where the cytokeratin filaments had become detached. The pericanalicular sheath of cytokeratin filaments and the bile canaliculi disappeared and actin was dispersed over the entire cell periphery. Fluorescein diacetate secretion and horseradish peroxidase uptake were almost completely absent in the hepatocytes treated with nickel. The effects of nickel persisted 24 hr after its removal from the medium. It is concluded that cytokeratin intermediate filaments play a critical role in the formation of the bile canaliculus, secretion of fluorescein diacetate and uptake of horseradish peroxidase. Further, our study indicates that cytokeratin ubiquitination occurs during collapse and aggregation of the cytokeratin filaments. The formation of cytokeratin-ubiquitin conjugates during aggregation suggests a role of ubiquitin in the control of cytokeratin organization in hepatocytes in the response to cell stress.

Paired helical filaments and the cytoplasmic-nuclear interface in Alzheimer's disease.

The cytoplasmic-nuclear interface has been investigated by conventional thin sectioning electron microscopy of neurons from frontal lobe biopsies of 13 patients with Alzheimer's disease. Nine patients were in the early and intermediate stages of the disease and four patients in the advanced stage. Fascicles of paired helical filament-like strands and paired helical filaments appose the nuclear envelope, the nuclear pore complexes and the perinuclear polysomes. Paired helical filament profiles have also been identified in the nucleoplasm. These observations indicate that the cytoplasmic-nuclear interface and, consequently, the relationships between the cytoplasm and the nucleus, might be impaired in Alzheimer's disease.

Ubiquitin is present on the cytokeratin intermediate filaments and Mallory bodies of hepatocytes.

To investigate the relationship of cytokeratin intermediate filaments (IFs) and Mallory bodies (MBs) to the regulatory protein ubiquitin, the griseofulvin-fed mouse was examined by double-label immunocytochemistry. In controls, immunofluorescence of hepatocytes showed that an antiserum specific to ubiquitin stained the cell border and the cytoplasm as well as the nuclear rim. In griseofulvin-fed liver cells, the MBs induced by this treatment were stained in an identical pattern by the antiserum to ubiquitin and a monoclonal antibody specific to cytokeratin (TROMA 1). Upon examination of the immunoreaction at the ultrastructural level, the ubiquitin antiserum decorated the cytokeratin filaments as well as MB filaments. Particularly striking was the coincidence of localization of TROMA 1 and ubiquitin epitopes, many IF surrounding MBs being either intensely decorated or alternatively nonimmunoreactive. These results suggest that normal cytokeratin IFs are lightly ubiquitinated, whereas MBs are heavily ubiquitinated. Immunoblot analysis of extracted cytoskeletal proteins separated by gel electrophoresis showed that extensive ubiquitination of peptides was present in the livers of the griseofulvin-fed mice. Further, the lack of ubiquitin and TROMA 1 epitopes in some liver IF suggest that loss of the TROMA 1 epitope may lead to concomitant loss of the ability to bind ubiquitin. Although the role ubiquitin plays in Mallory body formation remains to be elucidated, we suggest that its significance here may be related to its normal association with cytokeratin.

Neuronal transformations in Alzheimer's disease.

Brains of nine early and four advanced Alzheimer patients have been investigated, utilizing three approaches to specify the threshold state of Alzheimer's disease (AD). Extensive thin sectioning electron microscopy (EM) of frontal lobe biopsies, correlated with stringent clinical assessment, has demonstrated that the neuronal cytoskeleton undergoes specific transformations into paired helical filament-like (PHF-like) strands, which lead to the formation of the insoluble paracrystalline paired helical filaments (PHFs). The neurofilamentous network (NFN) transformation plays an important role in this process, whereby segregation, posttranslational modifications and reassembly of the modified components through autocrosslinking, and phase transition occur. According to our data, the threshold state can be defined as the state of irreversible segregation and posttranslational modification of the NFN and the microtubule-associated proteins. At this state, therapeutic intervention to reverse the disease process may be possible. The results indicate similarities between the formation of the paracrystals of the PHFs and the formation of the tropomyosin-like crystals of the Hirano bodies. Close relationships among PHFs and smooth endoplasmic reticulum and plasma membrane do exist. Enveloped virus-like particles have been observed in neurons containing PHFs. A possible role of these virus-like particles as an etiological agent for AD is discussed.

In vitro polymorphism and phase transitions of the neurofilamentous network isolated from the giant axon of the squid (Loligo pealei L.).

Using electron microscopy (EM), optical diffraction and image reconstruction techniques, we have demonstrated polymorphism of neurofilamentous network (NFN) in vitro based on phase transitions of the protein assemblies. The specific polymorphic appearances depended upon a number of factors, such as K+, Mg2+, Ca2+ ions, as well as the charge and hydration state of the molecules. Furthermore, modifications initiated by the state of phosphorylation of the sidearm proteins played an important role, especially in determining the sidearm disposition of the NFN. The Ca2+-activated protease removed the sidearms. Other enzymes activated by Ca2+ may initiate new association patterns of the peptide remnants and the intercoiling of two smooth neurofilaments (NFs) into paired helical filament-like (PHF-like) strands. Prolonged storage of the isolated NFs in Rubinson-Baker solution resulted in autocrosslinking and intercoiling of modified NFN components. The in vitro polymorphism and phase transitions of squid NFN induced under controlled conditions have been compared to modifications of cytoskeleton observed by EM in frontal lobe biopsies of Alzheimer patients. We conclude that similar processes, as induced in vitro, do occur in neurons of Alzheimer patients.

Neurofilamentous network and filamentous matrix preserved and isolated by different techniques from squid giant axon.

The contribution of the neurofilamentous network to the structure of the squid giant axon was analyzed electron-microscopically. Axial 10-nm filaments cross-linked by radial 5-nm bridges form a network that is present in preparations prepared by a variety of techniques. The axoplasm is differentiated into dense and less dense regions. In the presence of Co(II) ions, the neurofilamentous network was remarkably well preserved and appeared to be associated with a dense web of fine filament matrix, which also was identified in extracted axoplasm and in fractions enriched with neurofilament protein complex. In the presence of La(III) ions, the neurofilamentous network had a coarse and open appearance. The stereo images of extracted and critical-point dried axoplasm suggested that the neurofilamentous network contains ordered lattice-like regions. Extracted preparations of extruded axoplasm and fractions enriched with neurofilament protein complex suggested that the properties of the network are determined by the neurofilament protein complex. It is proposed that the neurofilamentous network is the essential determinant of the form of the axon, and that the order within the network is determined by the radial components of the network. The structures observed in the different preparations are not artifacts, but rather are related closely to their native state in the axon.

Fast axonal transport in squid giant axon.

Video-enhanced contrast-differential interference contrast microscopy has revealed new features of axonal transport in the giant axon of the squid, where no movement had been detected previously by conventional microscopy. The newly discovered dominant feature is vast numbers of "submicroscopic" particles, probably 30- to 50-nanometer vesicles and other tubulovesicular elements, moving parallel to linear elements, primarily in the orthograde direction but also in a retrograde direction, at a range of steady velocities up to +/- 5 micrometers per second. Medium (0.2 to 0.6 micrometer) and large (0.8 micrometer) particles move more slowly and more intermittently with a tendency at times to exhibit elastic recoil. The behavior of the smallest particles and the larger particles during actual translocation suggests that the fundamental processes in the mechanisms of organelle movement in axonal transport are not saltatory but continuous.

Organization of the neurofilamentous network.

The neurofilamentous network of the normal rabbit brain (lateral vestibular nucleus) and of biopsies of human patients (cerebral cortex, sural nerve) was investigated electron microscopically. Thin sections of samples prepared by standard techniques and unfixed spreads of freshly isolated perikarya were utilized. The neurofilaments are assembled into a three-dimensional network associated with the axolemma, microtubules, mitochondria and polyribosomes. The elements of this network demonstrate helicity at several levels of organization. It is proposed that they are in a dynamic state of equilibrium between ordered lattice and open network paracrystalline states. Reversible phase transitions in the subunit proteins of the neurofilaments may lead to coiling and uncoiling of the filaments and induce alterations in the network structure of the neuroplasm. Giant axonal swellings in biopsies of the sural nerve are interpreted as accumulations of cytoskeletal elements in the absence of the orienting effect of microtubules. In cortical neurons of patients with Alzheimer's disease parts of the neurofilamentous network are in altered paracrystalline states; virus-like particles occur within this modified network. These concepts of cytoskeletal organization - network, helicity, phase transitions, and paracrystallinity - are useful for the interpretation of pathological alterations of the cytoskeleton and for an understanding of cytoskeletal organization in general.

Removal of the Schwann sheath from the giant nerve fiber of the squid: an electron-microscopic study of the axolemma and associated axoplasmic structures.

The axolemma is associated structurally and functionally with the axoplasm, forming an axolemma-ectoplasm complex. To study the structure of this complex, a new technique was developed for removing the Schwann sheath from a portion of the giant nerve fiber. An isolated fiber was treated, without loss of excitability, with trypsin dissolved in natural seawater. Next, the fiber was treated with a mild fixative and then was placed in a hypertonic solution of sucrose in seawater. The elevated sheath was transected and everted, thus exposing the surface of the axon. Desheathed axons were examined by scanning and transmission electron microscopy. The surface of the axon has a ridge-and-groove pattern, reflecting an underlying helical arrangement of filaments which bundle and unbundle. Both left and right axons of the squid possess right-handed helical twists with a tilt angle of 10 degrees. Hemispherical protuberances about 1.5 microns at their base are observed along the ridges. Thin sections of the desheathed axons reveal that the desheathing procedure leaves the axolemma intact. Desheathed axons display electron-dense bodies associated with the axolemma and with the filaments of the ectoplasm similar to the dense bodies observed in whole fibers fixed in the presence of 10 mM Co(II) ions. Axons perfused for 40 min with a solution containing 2 mM Co(II) ions retain their excitability and display a smooth inner ectoplasmic face. A portion of the axolemma, together with adhering ectoplasm, was removed from desheathed axons, mounted between folding double grids, stained, and critical-point dried. Through this novel method a network of 10 nm filaments spaced 40 nm apart and cross-linked by filaments 5 to 7 nm in diameter was demonstrated.

Subaxolemmal filamentous network in the giant nerve fiber of the squid (Loligo pealei L.) and its possible role in excitability.

A new technique utilizing the squid giant nerve fiber has been developed which permits direct examination of the inner face of the axolemma by scanning electron microscopy. The axoplasm was removed sequentially in a 15-mm long segment of the fiber by intracellular perfusion with a solution of KF, KCl, Ca++-containing seawater, or with pronase. The action potential of the fibers was monitored during these treatments. After brief prefixation in 1% paraformaldehyde and 1% glutaraldehyde, the perfused segment was opened by a lne could be related to information on the detailed morphology of the cytoplasmic face of the axolemma and the ectoplasm. The results obtained by scanning electron microscopy were further substantiated by transmission electron microscopy of thin sections. In addition, living axons were studied with polarized light during axoplasm removal, and the identification of actin by heavy meromyosin labeling and sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis was accomplished. These observations demonstrate that a three-dimensional network of interwoven filaments, consisting partly of an actinlike protein, is firmly attached to the axolemma. The axoplasmic face of fibers in which the filaments have been removed partially after perfusion with pronase displays smooth membranous blebs and large profiles which sppose the axolemma. In fibers where the excitability has been suppressed by pronase perfusion, approximately one-third of the inner face of the axolemma in the perfusion zone is free of filaments. It is hypothesized that the attachment of axoplasm filaments to the axolemma may have a role in the maintenance of the normal morphology of the axolemma, and, thus, in some aspect of excitability.

Purification and characterization of squid brain myosin.

Myosin was extracted from frozen squid brain and purified by a modification of the procedure of Pollard et al. (Pollard, T.D., Thomas, S.M., and Niederman, R. (1974) Anal. Biochem. 60, 258-266). Myosin was eluted from Bio-Gel A-15m column as a single peak of (K+-EDTA)-activated ATPase ((K+-EDTA)-ATPase) activity with an average partition coefficient (Kav) of 0.22. In sodium dodecyl sulfate-acrylamide gel electrophoresis, the purified myosin showed a predominant band with similar electrophoretic mobility as the heavy chain of rabbit skeletal muscle myosin, and two less intense bands near the bottom of the gel. No actin band was seen. The properties of the (K+-EDTA)-ATPase activity were: (a) the time course of the reaction was biphasic at 25 degrees but linear at 32 degrees; (b) the optimum rate of reaction was obtained between 0.3 and 0.8 M KCl; (c) the pH optimum was between 8.0 and 9.0; (d) the reaction was specific for ATP with an apparent Km of 0.19 mM. ATPase activity in 0.06 M KCl and 5 mM MgCl2 was increased about 1.5 times by a 10-fold excess of rabbit skeletal muscle F-actin and about 5 times by a 40-fold excess. The actin activation was inhibited slightly by the addition of 0.2 mM CaCl2 and completely by the addition of 10 mM CaCl2. Myosin formed arrowhead patterns with rabbit skeletal muscle F-actin as observed by electron microscopy of negatively stained samples. It also aggregated in bipolar filaments which attached to decorated actin filaments at different angles, as well as formed cross-connections and ladder-like patterns between actin filaments. These two forms of interactions between myosin and actin were abolished by treatment with MgATP.

Electron microscope and experimental investigations of the neurofilamentous network in Deiters' neurons. Relationship with the cell surface and nuclear pores.

The assembly of filamentous elements and their relations to the plasma membrane and to the nuclear pores have been studied in Deiters' neurons of rabbit brain. Electron microscopy of thin sections and of ectoplasm spread preparations have been integrated with physicochemical experiments and differential interference microscopy of freshly isolated cells. A neurofilamentous network extends as a continuous, three-dimensional, semilattice structure throughout the ectoplasm, the "plasma roads," and the perinuclear zone of the perikaryon. This space network consists of approximately 90-A wide neurofilaments arranged in fascicles which are interconnected by an exchange of neurofilaments. The neurofilaments consist of intercoiled approximately 20-A wide unit-filaments and are associated through cross-associating filaments with other neurofilaments of the fascicle and with microfilaments. The approximately 20-50-A wide microfilaments display intimate associations with the plasma membrane and with the nuclear pores. Electron microscopy of thin sections from glycerinated and heavy meromyosin-treated Deiters' neurons shows that actin-like filaments are present in the pre- and postsynaptic regions of synapses terminating on these neurons. It is proposed that the neurofilamentous space network serves a transducing function by linking plasma membrane activities with the genetic machinery of the neuron.

Hereditary nephropathy with hematuria (Alport's syndrome).

Among 82 members and four generations of a French-Canadian family, 14 cases of hereditary nephropathy (Alport's syndrome) were documented. Five additional members of the family had died, probably because of this same illness. Deafness occurred in five family members with nephropathy and in one without renal disease. Ten of 12 affected males died in uremia before they had reached the age of 40 years. One of seven affected females died following a pregnancy. In two surviving patients, special investigations failed to elicit intrinsic tubular defects such as amino-aciduria, renal tubular acidosis, hyperphosphaturia or renal glucosuria. Systemic illness such as abnormal aminoacids in serum, primary hyperoxaluria, diabetes mellitus and infections were also excluded. Immunological defects were not demonstrable and the staining of renal biopsy tissue with fluorescein-labelled anti-beta(1)c, anti-IgG and antifibrinogen was negative. Renal tissue material of early, advanced and terminal hereditary nephropathy showed both tubular and interstitial, vascular and glomerular lesions. Electronmicroscopy showed marked thickening of tubular and glomerular basement membranes, increase of mesangial tissue and fusion of foot processes but failed to demonstrate "immune deposits." It is postulated therefore that hereditary nephropathy results from an inborn error of metabolism where an as yet unidentified metabolite damages the renal tissue as well as the acoustic nerve, analogous perhaps to the action of certain drugs, e.g. nephro-ototoxic antibiotics.

Spatial patterns of threadlike elements in the axoplasm of the giant nerve fiber of the squid (Loligo pealii L.) as disclosed by differential interference microscopy and by electron microscopy.

The giant nerve fiber of the squid (Loligo pealii L.) has been investigated in situ, and in fresh and fixed preparations, by differential interference microscopy and electron microscopy. A continuous, three-dimensional network, composed of threadlike elements, was disclosed in the axoplasm. The threadlike elements in the axoplasm are twisted as a whole into a steep, right-handed helix. In a peripheral ectoplasmic region, the elements are more parallel to one another and more densely packed than in a central endoplasmic core. The threadlike elements can be resolved into a hierarchy of decreasing order of size. Successive levels of the hierarchy are formed by the association of smaller elements into larger ones. The following levels in the hierarchy of network elements have been distinguished: 1-3-micro-wide threads, 0.1-0.35-micro-wide strands, and 70-250-A-wide unit-filament strands. The differential interference microscope selects, from the network, threads oriented at a specific angle to the long axis of the axon. The specific angle depends upon the orientation of the long axis of the axon relative to the direction of shear. It is postulated that the network configuration is expressed in the solid-state properties of the axoplasm essential for the normal functioning of the nerve fiber.

Configuration of a filamentous network in the axoplasm of the squid (Loligo pealii L.) giant nerve fiber.

High-resolution electron microscopy is integrated with physicochemical methods in order to investigate the following preparations of the giant nerve fibers of the squid (Loligo pealii L.): (1) Thin sections of fibers fixed in four different fixatives; (2) fresh axoplasm stained negatively in solutions of different pH and composition; (3) chemically isolated threadlike elements of the axoplasm. A continuous, three-dimensional network can be identified in all these preparations of the axoplasm. The network is composed of coiled or looped unit-filaments approximately 30 A wide. The unit-filaments are intercoiled in strands approximately 70-250 A wide. The strands are oriented longitudinally in the axoplasm, often having a sinuous course and cross-associations. Microtubules are surrounded by intercoiled unit-filaments and filamentous strands. Calcium ions cause loosening and disintegration of the network configuration. UO(2) (++) ions of a 1% uranyl acetate solution at pH 4.4 display a specific affinity for filamentous protein structures of the squid giant nerve fiber axoplasm, segregating the filamentous elements of the axoplasm in a coiled, threadlike preparation. The uranyl ions combine probably with the carboxyl groups of the main amino acids of the protein-glutamic and aspartic acids. It is proposed that by coiling/decoiling and folding/unfolding of the unit-filaments, shifts in physicochemical properties of the axoplasm are maintained.