Nucleocytoplasmic traffic of CPEB1 and accumulation in Crm1 nucleolar bodies

The translational regulator CPEB1 plays a major role in the control of maternal mRNA in oocytes, as well as of subsynaptic mRNAs in neurons. Although mainly cytoplasmic, we found that CPEB1 protein is continuously shuttling between nucleus and cytoplasm. Its export is controlled by two redundant NES motifs dependent on the nuclear export receptor Crm1. In the nucleus, CPEB1 accumulates in a few foci most often associated with nucleoli. These foci are different from previously identified nuclear bodies. They contain Crm1 and were called Crm1 nucleolar bodies (CNoBs). CNoBs depend on RNA polymerase I activity, indicating a role in ribosome biogenesis. However, although they form in the nucleolus, they never migrate to the nuclear envelope, precluding a role as a mediator for ribosome export. They could rather constitute a platform providing factors for ribosome assembly or export. The behavior of CPEB1 in CNoBs raises the possibility that it is involved in ribosome biogenesis.     

Characterization of the cytoplasmic inclusion bodies of the spleens from patients with adult form Gaucher's disease

The twisted tubular cytoplasmic inclusion bodies were isolated from spleens of four patients with adult form Gaucher's disease. The chemical composition of the CIB (cytoplasmic inclusion bodies) was as follows: proteins, 10%, cholesterol, 10%, phospholipids, 10%, glycolipids, 70%. More than 90% of glycolipids from CIB were glucosylceramide. The structural protein profile of these bodies was examined by SDS-polyacrylamide disc gel electrophoresis on a semimicro-scale (s-PAGE). A similar protein composition which included two glycoproteins was found in all the four cases. The tubular structure of the bodies was changed to a small and round form by the treatment with 1 mM EDTA-Na2 which removed some structural proteins from the bodies. This indicated that some proteins might have an important role in maintaining the tubular structure of CIB.     

ISOLATION AND CHARACTERIZATION OF LAMELLAR BODIES AND TUBULAR MYELIN FROM RAT LUNG HOMOGENATES

Three surface-active fractions which differ in their morphology have been isolated from rat lung homogenates by ultracentrifugation in a discontinuous sucrose density gradient. In order of increasing density, the fractions consisted, as shown by electron microscopy, primarily of common myelin figures, lamellar bodies, and tubular myelin figures. The lipid of all three fractions contained approximately 94% polar lipids and 2% cholesterol. In the case of the common myelin figures and the lamellar bodies, the polar lipids consisted of 73% phosphatidylcholines, 9% phosphatidylserines and inositols, and 8% phosphatidylethanolamines. In the case of the tubular myelin figures, the respective percentages were 58, 19, and 5. Over 90% of the fatty acids of the lecithins of all three fractions were saturated. Electrophoresis of the proteins of the fractions in sodium dodecyl sulfate or Triton X-100 revealed that the lamellar bodies and the tubular myelin figures differed in the mobilities of their proteins. The common myelin figures, however, contained proteins from both of the other fractions. These data indicate that, whereas the lipids of the extracellular, alveolar surfactant(s) originate in the lamellar bodies, the proteins arise from another source. It is further postulated that the tubular myelin figures represent a liquid crystalline state of the alveolar surface-active lipoproteins.     

Comparison of the ultrastructure of stimulated and unstimulated mechanoreceptors in the taste hairs of the blowfly Phaenicia serricata

The structure of mechanoreceptors at the base of labeilar taste hairs of the blowfly Phaenicia serricata were examined in stimulated and unstimulated conditions (i.e. with the hair bent or unbent). Physiological recordings from the mechanoreceptor showed that the receptors responded when the hair is bent dorsally or ventrally and when the hair is bent at extreme angles. These conditions are the same as those placed on hairs in the anatomical studies. Bending the hair toward the ventral labellar surface caused the hair base to compress and indent the tubular body and its surrounding membrane and sheath at the distal end of the mechanoreceptor dendrite. In compressed tubular bodies, microtubules oriented longitudinally were bent and separated a greater distance from each other. Separation as much as 70 nm was observed in compressed tubular bodies as compared with a maximum of 26 nm between microtubules in tubular bodies of unbent hairs. The dense amorphous material between microtubules of compressed tubular bodies formed prominent bridges 18 nm thick connecting the microtubules at intervals of 48–74 nm. Thin 10 nm filaments were also evident in the spaces between microtubules. When the hair was bent toward the proximal end of the proboscis, the tip of the tubular body was bent about 15 °. The tubular body appears to function as a firm but resilient structure over which the dendritic membrane can be stretched during mechanostimulation. Comparison of morphology of bent and unbent hairs suggests a means by which mechanical force from the movement of the hair is transferred to the receptors by structures in the hair socket region. No differences were found in ciliary structures of stimulated and unstimulated receptors.     

The nucleolus: a site of ribonucleoprotein maturation

The nucleolus is the site of ribosomal RNA synthesis, processing and ribosome maturation. Various small ribonucleoproteins also undergo maturation in the nucleolus, involving RNA modification and RNA-protein assembly. Such steps and other activities of small ribonucleoproteins also take place in Cajal (coiled) bodies. Events of ribosome biogenesis are found solely in the nucleolus, which is the final destination of small nucleolar RNAs after their traffic through Cajal bodies. However, nucleoli are just a stopping point in the intricate cellular traffic for small nuclear RNAs and other ribonucleoproteins.     

Surfactant protein A is localized at the corners of the pulmonary tubular myelin lattice

Immunogold labeling on sections of a freeze-substituted tubular myelin-enriched fraction isolated from a bronchoalveolar lavage of rat lung showed that surfactant protein A (SP-A) occurs predominantly at the corners of the tubular myelin lattice. Seventy-nine percent of the gold particles were located within 20 nm from a corner. Extracellular SP-A was detected only in the tubular myelin lattice and not in vesicles or secreted lamellar bodies. Ultra-thin cryosections of rat lung fixed in vivo showed that intracellular SP-A was distributed homogeneously over the stacked membranes of lamellar bodies in alveolar Type II cells. The presence of SP-A at the corners of the tubular myelin lattice suggests an important role of this protein in the formation and/or maintenance of this highly ordered lattice.     

The three-dimensional aspect of the mammalian lung surfactant myelin figure.

Rodent and primate lung surfactant was studied at the ultrastructural level utilizing procedures that retained most of the carbohydrates and lipids in thin section. The three-dimensional aspect of tubular myelin surfactant was observed to be four, lipid bilayer membranes oriented at right angles so that in cross-section it was square. In longitudinal section it appeared as two parallel lipid bilayers. Inside the tubular myelin was a homogeneous matrix material that completely filled the tubule except for a small, central area. A single multilamellar body, after it expanded and rearranged lamellae to form tubular myelin surfactant, still retained its basic morphology so that it was possible to determine the number and orientation of bodies that comprised a given surfactant area. This enabled quantification of surfactant by serial sectioning. Each transformed multilamellar body was observed to contain from 2 to 13 groups of tubular myelin, oriented at angles within the transformed body. With three-dimensional understanding, many of the areas previously reported to be homogeneous were determined to actually be oblique cross or longitudinal sections through tubular myelin surfactant.Five distinct layers characterized tubular myelin surfactant: (1) Unexpanded layer—up to 63 recently secreted multilamellar bodies. (2) Formation layerp?aired lamellae expanding and rearranging to form tubules. (3) Mature layer—tubular myelin surfactant. (4) Air-surfactant interface layer—usually a single lipid bilayer which was the outermost layer of tubular myelin of from 1 to 12 transformed multilamellar bodies. (5) Degraded surfactant layer—lipid bilayer spheres were formed at the interface and degraded in the alveolar space.     

Lamellar bodies of cultured human fetal lung: content of surfactant protein A (SP-A), surface film formation and structural transformation in vitro

Lamellar bodies were isolated from dexamethasone and T3-treated explant cultures of human fetal lung, using sucrose density-gradient centrifugation. We examined their content of surfactant apoprotein A (SP-A), and their ability to form surface films and to undergo structural transformation in vitro. SP-A measured by ELISA composed less than 2% of total protein within lamellar bodies; this represented, as a minimum estimate, a 2-12-fold enrichment over homogenate. One- and two-dimensional gel electrophoresis also suggested that SP-A was a minor protein component of lamellar bodies. Adsorption of lamellar bodies to an air/water interface was moderately rapid, but accelerated dramatically upon addition of exogenous SP-A in ratios of 1:2-16 (SP-A:phospholipid, w/w). Similar adsorption patterns were seen for lamellar bodies from fresh adult rat and rabbit lung. Lamellar bodies incubated under conditions that promote formation of tubular myelin underwent structural rearrangement only in the presence of exogenous SP-A, with extensive formation of multilamellate whorls of lipid bilayers (but no classical tubular myelin lattices). We conclude that lamellar bodies are enriched in SP-A, but have insufficient content of SP-A for structural transformation to tubular myelin and rapid surface film formation in vitro.     

Examination of calf prochymosin accumulation in Escherichia coli: disulphide linkages are a structural component of prochymosin-containing inclusion bodies.

Recent reports have shown that synthesis of certain recombinant proteins in Escherichia coli results in the production of intracellular inclusion bodies. These studies have not analyzed the structure of the inclusion body especially regarding the intermolecular forces holding it together. We have examined structural aspects of inclusion bodies made in E. coli as a result of high level expression of the eukaryotic protein, calf prochymosin. Prochymosin is a monomeric protein containing three disulfide bridges. It was expressed at up to 20% of cell protein from a plasmid containing the E. coli tryptophan promoter, operator and ribosome binding site. Proteins in the inclusion bodies were analysed by Western blotting of SDS-polyacrylamide gels. When experiments were done using conditions which preserved the in vitro state of thiol groups, inclusions were shown to be composed of multimers of prochymosin molecules which were interlinked partly by disulfide bonds. The inclusion bodies also contained a high concentration of reduced prochymosin. The presence of intermolecular disulfides probably contributes to the difficulty of solubilizing recombinant prochymosin during its purification from E. coli.     

Stable oil bodies sheltered by a unique oleosin in lily pollen

Stable oil bodies were purified from mature lily (Lilium longiflorum Thunb.) pollen. The integrity of pollen oil bodies was maintained via electronegative repulsion and steric hindrance possibly provided by their surface proteins. Immunodetection revealed that a major protein of 18 kDa was exclusively present in pollen oil bodies and massively accumulated in late stages of pollen maturation. According to mass spectrometric analyses, this oil body protein possessed a tryptic fragment of 13 residues matching that of a theoretical rice oleosin. A complete cDNA fragment encoding this putative oleosin was obtained by PCR cloning with primers derived from its known 13-residue sequence. Sequence analysis as well as immunological non-cross-reactivity suggests that this pollen oleosin represents a distinct class in comparison with oleosins found in seed oil bodies and tapetum. In pollen cells observed by electron microscopy, oil bodies were presumably surrounded by tubular membrane structures, and encapsulated in the vacuoles after germination. It seems that pollen oil bodies are mobilized via a different route from that of glyoxysomal mobilization of seed oil bodies after germination.     

A mode of formation of tubular myelin from lamellar bodies in the lung

A mechanism is suggested by which the membranes of lamellar bodies are converted to tubular myelin (TM) in the lung. It is argued that a simple corrugation of the membranous sheets can produce the TM formation. Such corrugation would occur in response to simple stresses acting on the lamellar body membranes. The intersections of the tubular figures are formed by fusion of adjacent corners in the corrugations. This results in a more stable hydrophobic bonding of phospholipid molecules. Strong supportive evidence for the mechanism is given by electron micrographs of TM formations.     

Formation of cytoplasmic nucleolus-like bodies from pre-existing nucleolar material in the mitotic cells of Vicia faba

The origin and behaviour of cytoplasmic nucleolus-like bodies was examined and correlated with the fate of the nucleolar material during mitosis of Vicia faba. The minute cytoplasmic nucleolus-like bodies first appeared in late anaphase. Relatively large bodies more than 1 μm in diameter were detected almost exclusively in early telophase but did not persist long in mid or late telophase. Ultrastructural survey revealed that the minute cytoplasmic nucleolus-like bodies in late anaphase consisted of ribosome-like granules and/or a fibrillogranular substance similar to the nucleolar remnants in prometaphase. Two types of the nucleolus-like bodies, however, were discerned in early telophase; one was composed of ribosome-like granules and/or the fibrillogranular substance and the other was exclusively fibrous in texture.     

Tubular lysosomes in ruffle-ended ameloblasts associated with enamel maturation in rat incisor

Trimetaphosphatase (TMPase) and cytidine-5'-monophosphatase (CMPase) were localized to investigate the lysosomal system, particularly tubular lysosomes, in ruffle-ended ameloblasts associated with maturation of enamel in rat incisor. Demineralized specimens were incubated for TMPase and for CMPase in a modified medium where cerium was used as the capture ion. Ruffle-ended ameloblasts showed distal invaginations and membrane-bound bodies filled with fine granular material, some of which displayed CMPase reaction product. Elongated tubular configurations 80-140 nm wide were distributed throughout the cytoplasm and were reactive with both TMPase and CMPase, thus characterizing these structures as lysosomes. They often contained fine granular material morphologically similar to that present in multivesicular bodies. During late enamel maturation, fewer tubular lysosomes were observed when compared to early maturation. These cytochemical results demonstrate the presence of tubular lysosomes in ruffle-ended ameloblasts, and it is suggested that they are elements of the endosomal system in these cells. These findings are also consistent with a resorptive function for ruffle-ended ameloblasts during enamel maturation.     

Binding of misacylated tRNAs to the ribosomal A site

To test whether the ribosome displays specificity for the esterified amino acid and the tRNA body of an aminoacyl-tRNA (aa-tRNA), the stabilities of 4 correctly acylated and 12 misacylated tRNAs in the ribosomal A site were determined. By introducing the GAC (valine) anticodon into each tRNA, a constant anticodon.codon interaction was maintained, thus removing concern that different anticodon.codon strengths might affect the binding of the different aa-tRNAs to the A site. Surprisingly, all 16 aa-tRNAs displayed similar dissociation rate constants from the A site. These results suggest that either the ribosome is not specific for different amino acids and tRNA bodies when intact aa-tRNAs are used or the specificity for the amino acid side chain and tRNA body is masked by a conformational change upon aa-tRNA release.     

Immunocytochemical localization of lysozyme and surfactant protein A in rat type II cells and extracellular surfactant forms.

Using immunogold labeling of fixed, cryosubstituted tissue sections, we compared the distribution of lysozyme, an oxidant-sensitive lamellar body protein, with that of surfactant protein A (SP-A) in rat Type II cells, extracellular surfactant forms, and alveolar macrophages. Morphometric analysis of gold particle distribution revealed that lysozyme and SP-A were present throughout the secretory and endosomal pathways of Type II cells, with prominent localization of lysozyme in the peripheral compartment of lamellar bodies. All extracellular surfactant forms were labeled for both proteins with preferential labeling of tubular myelin and unilamellar vesicles. Labeling of tubular myelin for SP-A was striking when compared with that of lamellar bodies and other extracellular surfactant forms. Lamellar body-like forms and multilamellar structures were uniformly labeled for lysozyme, suggesting that this protein is rapidly redistributed within these forms after secretion of lysozyme-laden lamellar bodies. By contrast, increased labeling for SP-A was observed over peripheral membranes of lamellar body-like forms and multilamellar structures, apparently reflecting progressive SP-A enrichment of these membranes during tubular myelin formation. The results indicate that lysozyme is an integral component of the lamellar body peripheral compartment and secreted surfactant membranes, and support the concept that lysozyme may participate in the structural organization of lung surfactant.     

Insights into the molecular determinants of EF-G catalyzed translocation

Translocation, the directional movement of transfer RNA (tRNA) and messenger RNA (mRNA) substrates on the ribosome during protein synthesis, is regulated by dynamic processes intrinsic to the translating particle. Using single-molecule fluorescence resonance energy transfer (smFRET) imaging, in combination with site-directed mutagenesis of the ribosome and tRNA substrates, we show that peptidyl-tRNA within the aminoacyl site of the bacterial pretranslocation complex can adopt distinct hybrid tRNA configurations resulting from uncoupled motions of the 3'-CCA terminus and the tRNA body. As expected for an on-path translocation intermediate, the hybrid configuration where both the 3'-CCA end and body of peptidyl-tRNA have moved in the direction of translocation exhibits dramatically enhanced puromycin reactivity, an increase in the rate at which EF-G engages the ribosome, and accelerated rates of translocation. These findings provide compelling evidence that the substrate for EF-G catalyzed translocation is an intermediate wherein the bodies of both tRNA substrates adopt hybrid positions within the translating ribosome.     

Tubular cytoplasmic bodies in pancreatic islet B-cells of mice

Summary Tubular bodies of varying length and thickness are found in the cytoplasm of pancreatic islet B-cells of obese-hyperglycemic mice and a few of their lean litter mates. Most of these bodies are elongated with tapered ends. There are also some rounded or peculiarly formed variants. They are composed of numerous small electron dense tubular units, often in parallel arrangement. The tubules are embedded in a moderately dense matrix and their interior shows also moderate density. Smaller or larger electron opaque rounded particles are seen in some of the cytoplasmic bodies. Tubular bodies sometimes occur in association with mitochondria, indicating that they might be derived from these cellular organelles. Though the chemical composition and significance of the tubular bodies still are unknown, mitochondrial changes, possibly related to altered metabolic activity, are suggested to form the basis of their development.This work was supported by grants from the Swedish Medical Research Council (Project No. B69-12X-718-04A).