Structure of the 50S ribosomal subunit from Escherichia coli. Investigation of the intact subunit and core particles by electron microscopy and analogue image processing.

Structures of 50S ribosomal subunits, CsCl and ethidium bromide core particles from these subunits have been investigated by electron microscopy and image processing by FAIRS. This method revealed structural details which are obscured in individual images, and enabled to distinguish six crown forms, different in their side protuberances, and two kidney forms. Crown forms were imaged as symmetrical or asymmetrical forms. The latter type was far more frequent in untreated populations than the first. The depletion of proteins by both agents caused stepwise degradation of the side protuberances in the crown forms thereby transforming asymmetrical to symmetrical forms. It is concluded from these findings that asymmetrical and symmetrical forms in untreated populations represent also structurally different particles. From the higher complexity in terms of component composition and structure it is concluded that the asymmetrical crown forms are more likely to represent the native structure of isolated 50S subunits than the symmetrical forms. Existing models for this subunit are discussed in terms of this finding.     

IX. Meaning and the Semantic Act

Shpet concludes his definition of the structure of the word as follows:

Indeed, if one accepts that morphological forms are external and agrees to call ontic forms of named things pure, then the logical forms lying between them will be inner forms with respect to both the former and the latter since, in this latter case, the "content" of an object is inner content veiled by its pure forms. It is this content, being internally logically formed, that constitutes sense. Logical forms are inner forms as forms of ideal sense, expressed and communicated; ontic forms are pure forms of real and possible corporeal content.     

Parameters of searching activity in the structure of feeding, defensive, and drinking behavior (comparative analysis)

Searching activity (SA) is the way to satisfy the need of overcoming and the mechanism of development of all forms of behavior under conditions of deficit of pragmatic information. SA is temporarily incorporated into the structure of the initial phase of all behavioral forms. The SA has energy and cognitive components that can be measured using Grigoriev's technique and his problem box. Quantitative and qualitative characteristics of SA are of prior significance in the structure of appetitive behavior and minimal significance in the structure of drinking behavior. Under described experimental conditions, in the structure of defensive behavior the values of the SA indices are mean.     

Structural basis of presequence recognition by the mitochondrial protein import receptor Tom20

Most mitochondrial proteins are synthesized in the cytosol as precursor proteins with a cleavable N-terminal presequence and are imported into mitochondria. We report here the NMR structure of a general import receptor, rat Tom20, in a complex with a presequence peptide derived from rat aldehyde dehydrogenase. The cytosolic domain of Tom20 forms an all alpha-helical structure with a groove to accommodate the presequence peptide. The bound presequence forms an amphiphilic helical structure with hydrophobic leucines aligned on one side to interact with a hydrophobic patch in the Tom20 groove. Although the positive charges of the presequence are essential for import ability, presequence binding to Tom20 is mediated mainly by hydrophobic rather than ionic interactions.     

Crystal structure of the C-terminal three-helix bundle subdomain of C. elegans Hsp70

Hsp70 chaperones are composed of two domains; the 40 kDa N-terminal nucleotide-binding domain (NDB) and the 30 kDa C-terminal substrate-binding domain (SBD). Structures of the SBD from Escherichia coli homologues DnaK and HscA show it can be further divided into an 18 kDa beta-sandwich subdomain, which forms the hydrophobic binding pocket, and a 10 kDa C-terminal three-helix bundle that forms a lid over the binding pocket. Across prokaryotes and eukaryotes, the NBD and beta-sandwich subdomain are well conserved in both sequence and structure. The C-terminal subdomain is, however, more evolutionary variable and the only eukaryotic structure from rat Hsc70 revealed a diverged helix-loop-helix fold. We have solved the crystal structure of the C-terminal 10 kDa subdomain from Caenorhabditis elegans Hsp70 which forms a helical-bundle similar to the prokaryotic homologues. This provides the first confirmation of the structural conservation of this subdomain in eukaryotes. Comparison with the rat structure reveals a domain-swap dimerisation mechanism; however, the C. elegans subdomain exists exclusively as a monomer in solution in agreement with the hypothesis that regions out with the C-terminal subdomain are necessary for Hsp70 self-association.     

A hexamer origin of the echinoderms' five rays

Of the major deuterostome groups, the echinoderms with their multiple forms and complex development are arguably the most mysterious. Although larval echinoderms are bilaterally symmetric, the adult body seems to abandon the larval body plan and to develop independently a new structure with different symmetries. The prevalent pentamer structure, the asymmetry of Lovén's rule and the variable location of the periproct and madrepore present enormous difficulties in homologizing structures across the major clades, despite the excellent fossil record. This irregularity in body forms seems to place echinoderms outside the other deuterostomes. Here I propose that the predominant five-ray structure is derived from a hexamer structure that is grounded directly in the structure of the bilaterally symmetric larva. This hypothesis implies that the adult echinoderm body can be derived directly from the larval bilateral symmetry and thus firmly ranks even the adult echinoderms among the bilaterians. In order to test the hypothesis rigorously, a model is developed in which one ray is missing between rays IV-V (Lovén's schema) or rays C-D (Carpenter's schema). The model is used to make predictions, which are tested and verified for the process of metamorphosis and for the morphology of recent and fossil forms. The theory provides fundamental insight into the M-plane and the Ubisch', Lovén's, and Carpenter's planes and generalizes them for all echinoderms. The theory also makes robust predictions about the evolution of the pentamer structure and its developmental basis.     

Crystal structure of the lambda repressor C-terminal domain octamer.

The three-dimensional structure of the lambda repressor C-terminal domain (CTD) has been determined at atomic resolution. In the crystal, the CTD forms a 2-fold symmetric tetramer that mediates cooperative binding of two repressor dimers to pairs of operator sites. Based upon this structure, a model was proposed for the structure of an octameric repressor that forms both in the presence and absence of DNA. Here, we have determined the structure of the lambda repressor CTD in three new crystal forms, under a wide variety of conditions. All crystals have essentially the same tetramer, confirming the results of the earlier study. One crystal form has two tetramers bound to form an octamer, which has the same overall architecture as the previously proposed model. An unexpected feature of the octamer in the crystal structure is a unique interaction at the tetramer-tetramer interface, formed by residues Gln209, Tyr210 and Pro211, which contact symmetry-equivalent residues from other subunits of the octamer. Interestingly, these residues are also located at the dimer-dimer interface, where the specific interactions are different. The structures thus indicate specific amino acid residues that, at least in principle, when altered could result in repressors that form tetramers but not octamers.     

Rational design of carbonitrile-carboxaldehyde cation receptor models: probing the nature of the heteroatom–metal interaction

Amino acids are constituents of proteins and enzymes which take part almost in all metabolic reactions. Glutamic acid, with an ability to form a negatively charged side chain, plays a major role in intra and intermolecular interactions of proteins, peptides, and enzymes. An exhaustive conformational analysis has been performed for all eight possible forms at B3LYP/cc-pVTZ level. All possible neutral, zwitterionic, protonated, and deprotonated forms of glutamic acid structures have been investigated in solution by using polarizable continuum model mimicking water as the solvent. Nine families based on the dihedral angles have been classified for eight glutamic acid forms. The electrostatic effects included in the solvent model usually stabilize the charged forms more. However, the stability of the zwitterionic form has been underestimated due to the lack of hydrogen bonding between the solute and solvent; therefore, it is observed that compact neutral glutamic acid structures are more stable in solution than they are in vacuum. Our calculations have shown that among all eight possible forms, some are not stable in solution and are immediately converted to other more stable forms. Comparison of isoelectronic glutamic acid forms indicated that one of the structures among possible zwitterionic and anionic forms may dominate over the other possible forms. Additional investigations using explicit solvent models are necessary to determine the stability of charged forms of glutamic acid in solution as our results clearly indicate that hydrogen bonding and its type have a major role in the structure and energy of conformers.     

Structural and functional analysis of the sarcoglycan-sarcospan subcomplex

Sarcospan is a component of the dystrophin-glycoprotein complex that forms a tight subcomplex with the sarcoglycans. The sarcoglycan-sarcospan subcomplex functions to stabilize α-dystroglycan at the plasma membrane and perturbations of this subcomplex are associated with autosomal recessive limb-girdle muscular dystrophy. In order to characterize protein interactions within this subcomplex, we first demonstrate that sarcospan forms homo-oligomers within the membrane. Experiments with a panel of site-directed mutants reveal that proper structure of the large extracellular loop is an important determinant of oligo formation. Furthermore, the intracellular N- and C-termini contribute to stability of sarcospan-mediated webs. Point mutation of each cysteine residue reveals that Cys 162 and Cys 164 within the large extracellular loop form disulfide bridges, which are critical for proper sarcospan structure. The extracellular domain of sarcospan also forms the main binding site for the sarcoglycans. We propose a model whereby sarcospan forms homo-oligomers that cluster the components of the dystrophin-glycoprotein complex within the membrane.     

Quantitative ultrastructural investigations of the life cycle of Trypanosoma brucei: a morphometric analysis.

The quantitative ultrastructure of the developmental stages of Trypanosoma brucei brucei in its vector Glossina morsitans was studied by morphometric analysis. Values from ectoperitrophic midgut forms, proventricular forms, epimastigote and metacyclic forms in the salivary gland are compared with results from bloodstream forms, published previously. Significant differences in the volume densities of the trypanosome's single mitochondrion, of microbody-like organelles and in the surface densities of inner and outer mitochondrial membranes were found throughout the whole life cycle. A great increase in volume density of the mitochondrion was observed after transfer to the insect host; reduction took place during metacyclic development. Parallel to the biogenesis of the mitochondrion a reduction of microbodies was found in proventricular forms and there was a great increase in metacyclic forms concomitant with the regression of the mitochondrion. Metacyclic forms had a close quantitative morphologic similarity to bloodstream forms. The results are discussed in connection with changes in structure and in oxidative metabolism.     

Morphology and Reproductive Processes of the L Forms of Bacteria II. Comparative Study of L Forms and Mycoplasma with the Electron Microscope

Representative electron micrographs, from the study of eight strains of L forms and one strain of Mycoplasma, are presented. A- and B-type L forms were derived from two strains of Proteus, two other L forms were derived from a diphtheroid and from a staphylococcus strain, and two strains (designated as LX) were isolated from L forms derived from a group A beta-hemolytic streptococcus and from a staphylococcus. The Mycoplasma strain was isolated from goats. Sections were made of young colonies grown within agar and from parts of surface colonies embedded in the agar. B-type L colonies of Proteus were produced by inoculation of bacteria into media containing penicillin. The large bodies developing from the bacteria and the organisms in B-type L colonies of Proteus, like the parent bacteria, had a cell wall consisting of a plasma membrane and an outer cell wall. The loss of rigidity in the cell wall indicated an alteration in its structure. The A-type L cultures of Proteus consisted of irregular branching masses extending in several directions, of small dense organisms corresponding to the elementary corpuscles present in cultures of Mycoplasma, and of intermediary forms. In contrast to the B-type, all organisms in the A-type colonies were surrounded by a single unit membrane corresponding to the plasma membrane of bacteria. The structures inside the cell membrane, both in the A- and B-type, seemed to correspond to the structure of the parent bacteria, which contained ribosomes and threads of DNA. The elementary corpuscles formed chains and filaments, and, apparently, these corpuscles took part in the multiplication by gradual enlargement. The organisms seen in the cultures of all L forms and Mycoplasma studied, except in the B-type L forms of Proteus, corresponded in size, shape, and structure, as well as in the development of elementary corpuscles, to the organisms in the A-type L form of Proteus. In contrast to the spherical organisms usually seen in broth cultures, the organisms in young cultures of Mycoplasma, which were grown within the agar, were similar in morphology, as well as in the discernible structure of the organisms, to L forms. Significant morphological and structural differences were not apparent between the L forms and Mycoplasma (in cultures grown within agar media) under the conditions of this investigation.     

Relationship of R6K replicating forms to the folded chromosome of Escherichia coli.

An examination of the relationship of both nonreplicating and replicating forms of R6K plasmid DNA to the Escherichia coli folded chromosome showed that both forms cosediment with the chromosome in neutral sucrose gradients. Approximately 20% of the nonreplicatin molecules was found as freely sedimenting forms when the folded-configuration of the chromosomes was preserved. However, under the same conditions negligible amounts of the replicating forms were found as freely sedimenting molecules. Thus, it is concluded that the replicating forms, when compared with nonreplicating molecules, are preferentially associated with the folded chromosomal structure. Exposure of the folded chromosomal structure to RNase resulted in an unfolding of the chromosome and a concomitant increase in the amount of freely sedimenting replicating and nonreplicating forms of R6K DNA. Analyses of the single-stranded length of RNase-released nascent molecules suggest that they replicate in continuous association with the folded chromsome complex. Nonenzymatic unfolding of the chromosomes by progressively lowering the sodium ion concentration during lysis resulted in a progressive increase in the release of nonreplicating molecules. Replicating molecules wer not released by unfolding the chromosome in this fashion.     

The three-dimensional structure of the autoproteolytic,nuclear pore-targeting domain of the human nucleoporin Nup98

Nup98 is a component of the nuclear pore that plays its primary role in the export of RNAs. Nup98 is expressed in two forms, derived from alternate mRNA splicing. Both forms are processed into two peptides through autoproteolysis mediated by the C-terminal domain of hNup98. The three-dimensional structure of the C-terminal domain reveals a novel protein fold, and thus a new class of autocatalytic proteases. The structure further reveals that the suggested nucleoporin RNA binding motif is unlikely to bind to RNA. The C terminus also contains sequences that target hNup98 to the nuclear pore complex. Noncovalent interactions between the C-terminal domain and the cleaved peptide tail are visible and suggest a model for cleavage-dependent targeting of hNup98 to the nuclear pore.     

Quantitative Ultrastructural Investigations of the Life Cycle of Trypanosoma brucei: A Morphometric Analysis*

SYNOPSIS. The quantitative ultrastructure of the developmental stages of Trypanosoma brucei brucei in its vector Glossina morsitans was studied by morphometric analysis. Values from ectoperitrophic midgut forms, proventricular forms, epimastigote and metacyclic forms in the salivary gland are compared with results from bloodstream forms, published previously. Significant differences in the volume densities of the trypanosome's single mitochondrion, of microbody-like organelles and in the surface densities of inner and outer mitochondrial membranes were found throughout the whole life cycle. A great increase in volume density of the mitochondrion was observed after transfer to the insect host; reduction took place during metacyclic development. Parallel to the biogenesis of the mitochondrion a reduction of microbodies was found in proventricular forms and there was a great increase in metacyclic forms concomitant with the regression of the mitochondrion. Metacyclic forms had a close quantitative morphologic similarity to bloodstream forms. The results are discussed in connection with changes in structure and in oxidative metabolism.     

Comparison of the dynamics of myoglobin in different crystal forms.

Crystals have been grown of "sperm whale" myoglobin produced in Escherichia coli from a synthetic gene and the structure has been solved to 1.9 A resolution. Because of a remaining initiator methionine, this protein crystallizes in a different space group from native sperm whale myoglobin. The three-dimensional structure of the synthetic protein is essentially identical to the native sperm whale protein. However, the crystallographic B-factors for parts of the molecule are quite different in the two crystal forms, and provide a measure of the effect of different packing constraints on the flexibility of the protein. The effect of the packing forces is to reduce the mobility of the protein in the regions of contact and thereby introduce differences in mobilities between the two crystal forms. Discrepancies between mobilities calculated from molecular dynamics simulations and crystallography can be reduced by considering the data from both crystal forms.     

Molecular basis for the functional diversity of enzyme forms of the LMW (Mr 38,000) acid phosphatase of the frog liver.

Recent studies on the structure and function of the tartrate-resistant acid phosphatase (Mr 38,000) of the frog liver are reviewed. The nature of the enzyme heterogeneity is elucidated on a molecular and physiological basis. The following structure-activity relationship is proposed: the enzyme protein is modified by glycosylation processes leading to formation of the different enzyme forms. The oligosaccharide chain stabilizes the final structure of the enzyme forms with altered conformation causing different exposure of the essential functional groups (e.g. sulfhydryl residues, antigen determinants). This leads to different physiological events necessary for fulfillment of metabolic requirements of the cell.     

Ecological structure and stage of ecogenesis of Paleozoic ammonoids in the Uralian paleobasin

The ecological structure of Paleozoic ammonoid assemblages of the Uralian paleobasin is discussed. Life forms (nektobenthic, planktonic, and benthopelagic) are used as ecological units. Four stages in evolution of the communities, with distinct structure and evolutionary pathways, are recognized.     

Duplications of the wing-hinge structures in the Pth mutants of drosophila melanogaster]

The Pth mutation of Drosophila melanogaster, a unique dominant mutation obtained by us, causes the notum duplications that are followed by the duplications of ventral and dorsal wing-hinge structures. The duplications of the wing hinge have a strictly coordinated structure, can be ranged in a continuous series, and are divided into four distinct types, none of which overlaps with the other. The order of the emergence of the ventral wing-hinge structures was determined in duplication forms, and the shape, size, and location of these structures were compared with normal parameters. The growth of the presumptive wing-hinge region was shown to have a vectorial mode; the directions of the main vectors and their center were determined. A geometrical model is proposed, which adequately explains the strict specificity in the structure of duplications as well as the agreement between the duplication forms to one another in each of the four types.     

Proteasomes and transplantology: Current state of the problem and the search for promising trends

Basic research of the structure and functions of multiple forms of proteasomes is overviewed. The proteasomes of liver, acting as a primary lymphoid organ in embryogenesis, displaying nonspecific local immunity, and providing development of tolerance to food and other foreign antigens during the lifespan, are described. The role of individual forms of liver proteasomes in transplantology is considered as well as their utility as markers for endocrine transplant survival.     

Differences in the solution structures of oxidized and reduced cytochrome c measured by small-angle X-ray scattering

While X-ray crystallographic data on cytochrome c show the reduced and oxidized forms to have very similar structures, there is a considerable body of data, mostly from solution studies, that indicates the reduced form is more stable and that the interior of the protein is less accessible to solvent in this state. These observations have led to the hypothesis that while the time-averaged structure is preserved between the two forms, the dynamics of the two forms are different. The oxidized form has been proposed to undergo more large-amplitude, low-frequency motions than the reduced form. The crystal structure data were derived from crystals grown in high salt concentrations, but the solution studies were done at relatively low ionic strength. Small-angle X-ray scattering has been used to examine the effects of the ionic strength and oxidation state on the solution structure of cytochrome c. We find that the radius of gyration and the maximum linear dimension of oxidized cytochrome c are significantly larger than those for reduced cytochrome c, in 5 mM phosphate buffer at pH 7.3, and further that this difference is suppressed by addition of 200 mM sodium chloride. We conclude that there is a real structural difference between the two forms at low ionic strength in solution and that this difference is likely to contribute to the observed differences in accessibility and compressibility.