Isolation and sequence analysis of human bombesin-like peptides

The decapeptide form of human gastrin releasing peptide was isolated from acid extracts of liver tissue containing a metastatic human bronchial carcinoid tumor. A larger form also was isolated and partially characterized. During gel permeation chromatography the major immunoreactive peak eluted in the same region as synthetic gastrin releasing decapeptide while a second minor immunoreactive peak eluted near gastrin releasing peptide. Bombesin-like immunoreactivity (BLI) was purified by successive applications to reverse phase high pressure liquid chromatography (HPLC) columns. After four successive HPLC purifications a single peak of bombesin-like immunoreactivity was detected. Amino acid analysis, microsequence analysis and coelution with synthetic peptide indicated that the predominant form present in metastatic tumor tissue was identical to the decapeptide form of canine gastrin-releasing peptide. The less abundant form was purified by cation exchange chromatography followed by reverse phase high pressure liquid chromatography. Partial microsequence analysis of this peptide, through the first 11 residues, was Val-Pro-Leu-Pro-Ala-Gly-Gly-Gly-Thr-Val-Leu. This sequence differed from that of hog heptacosapeptide gastrin releasing peptide at positions 1,3,4 and 5 and from the canine peptide as positions 1,3,5, and 7.     

Sequence and glycosylation site identity of two distinct glycoforms of nonspecific cross-reacting antigen as demonstrated by sequence analysis and fast atom bombardment mass spectrometry

Nonspecific cross-reacting antigen (NCA) is a highly glycosylated membrane protein which is immunologically and structurally related to carcinoembryonic antigen, an important tumor-associated antigen. Two glycoforms of NCA were purified from a single liver metastasis of a colonic carcinoma and characterized with respect to their primary sequence and position of glycosylation sites. The two glycoforms (designated TEX (tumor-extracted antigen), Mr 75,000, and NCA, Mr 45,000) each showed a deglycosylated Mr of 35,000 and yielded identical peptide maps. The structural characterization of TEX and NCA and the assignment of glycosylation sites was performed by fast atom bombardment mass spectrometry and microsequence analysis of the resulting peptides. This approach showed that TEX and NCA were identical with respect to primary sequence and provided direct evidence that 11 of the 12 predicted asparagine-linked glycosylation sites were glycosylated in both TEX and NCA. Indirect evidence was obtained for glycosylation at the other site. Both glycoforms also contain ethanolamine linked to Gly-286, a finding consistent with the conclusion that these proteins are anchored to the plasma membrane through a glycosyl-phosphatidylinositol tail. The large difference in the molecular weights of glycosylated TEX and NCA suggests significant variations in their oligosaccharide structures.     

Complete amino acid sequence of 21-hydroxylase cytochrome P-450 from porcine adrenal microsomes

Adrenal microsomal 21-hydroxylase is essential for biosynthesis or metabolism of various steroid hormones. The complete amino acid sequence of this cytochrome P-450 from pig adrenal was determined by sequence analysis on several sets of proteolytic fragments. The mature protein consists of 492 amino acid residues, corresponding to a molecular weight of 55,484. Seven out of nine total cysteine residues are localized in the amino terminal half of the molecule. The carboxyl terminal half contains only two cysteines, one of which is located at the highly conserved heme-binding region proposed in all cytochromes P-450. A structural comparison between 21-hydroxylase and 17 alpha-hydroxylase reveals that there is a preponderance of sequence homology at the carboxyl terminal region. These studies indicate that a single gene product is expressed for steroid 21-hydroxylase in porcine adrenal glands.     

Structural and functional analysis of NADPH-cytochrome P-450 reductase from human liver: complete sequence of human enzyme and NADPH-binding sites

The complete amino acid sequence of human liver NADPH-cytochrome P-450 reductase has been determined by microsequence analysis and mass spectrometry. The total sequence consists of 676 amino acids initiated by an amino-terminal acetyl group. There is no evidence for posttranslational modifications, including Asn-linked glycosylation. The human enzyme exhibits sequence homology in the range of 92-95% with other mammalian enzymes. Sequence differences were mainly confined to several hydrophilic regions in the NH2-terminal and COOH-terminal domains. Since the human enzyme is immunochemically distinct from the rabbit enzyme despite similar enzymatic properties, it is likely that these variable hydrophilic regions are potential antigenic determinants. The NADPH-depleted enzyme is inactivated by either fluorescein isothiocyanate, a lysine-specific reagent, or 5-(iodoacetamido)fluorescein, a cysteine-specific reagent. In both cases, protection by NADP(H) prevents enzyme inactivation by the reagents. Isolation of fluorescent peptide from 5-(iodoacetamido)fluorescein-inactivated enzyme identified Cys 565 as the specifically NADPH-protected residue.     

Do Plant Cells Secrete Exosomes Derived from Multivesicular Bodies?

Multivesicular bodies (MVBs) are spherical endosomal organelles containing small vesicles formed by inward budding of the limiting membrane into the endosomal lumen. In mammalian red cells and cells of immune system, MVBs fuse with the plasma membrane in an exocytic manner, leading to release their contents including internal vesicles into the extracellular space. These released vesicles are termed exosomes. Transmission electron microscopy studies have shown that paramural vesicles situated between the plasma membrane and the cell wall occur in various cell wall-associated processes and are similar to exosomes both in location and in morphology. Our recent studies have revealed that MVBs and paramural vesicles proliferate when cell wall appositions are rapidly deposited beneath fungal penetration attempts or during plugging of plasmodesmata between hypersensitive cells and their intact neighboring cells. This indicates a potential secretion of exosome-like vesicles into the extracellular space by fusion of MVBs with the plasma membrane. This MVB-mediated secretion pathway was proposed on the basis of pioneer studies of MVBs and paramural vesicles in plants some forty years ago. Here, we recall the attention to the occurrence of MVB-mediated secretion of exosomes in plants.Key Words: cell wall, endocytosis, endosome, exocytosis, exosome, multivesicular body, paramural bodyMultivesicular bodies (MVBs) are spherical endosomal organelles containing a number of small vesicles formed by inward budding of the limiting membrane into the endosomal lumen.¹ MVBs contain endocytosed cargoes and deliver them into lysosomal/vacuolar compartments for degradation. They also incorporate newly synthesized proteins destined for lysosomal/vacuolar compartments.² In mammalian cells of hematopoietic origin, endosomal MVBs function in removal of endocytosed surface proteins in an exocytic manner. They are redirected to the plasma membrane, where they release their contents including internal vesicles into the extracellular space by membrane fusion. The released vesicles are termed exosomes.³ During reticulocyte maturation to erythrocyte, a group of surface proteins, such as the transferrin receptor, become obsolete and are discarded via MVB-mediated secretion.³ Time-course transmission electron microscopy (TEM) first revealed that colloidal gold-transferrin was internalized into MVBs via receptor-mediated endocytosis and then transferrin together with its receptor were delivered into the extracellular space via the fusion of MVBs with the plasma membrane of reticulocytes.⁴ Some other cell types of hematopoietic origin, such as activated platelets, cytotoxic T cells and antigen-presenting cells, also secrete exosomes. Exosomes thus may play a role in various physiological processes other than discarding obsolete proteins.³Our recent TEM studies provided ultrastructural evidence on the enhanced vesicle trafficking in barley leaf cells attacked by the biotrophic powdery mildew fungus. Multivesicular compartments including MVBs, intravacuolar MVBs, and paramural bodies turned out to proliferate in intact host cells during formation of cell wall appositions (papilla response), in the hypersensitive response, and during accommodation of haustoria.^5,6 MVBs proliferated in the cytoplasm of haustorium-containing epidermal cells during compatible interactions and near sites of cell wall-associated oxidative microburst either during the papilla response or during the hypersensitive response. Because MVBs in plant cells have been demonstrated to be endosomal compartments,^7–9 they may participate in internalization of nutrients from the apoplast of intact haustorium-containing epidermal cells and sequestration of damaged membranes and deleterious materials originating from the oxidative microburst.^5,6 The presence of intravacuolar MVBs with double limiting membranes (Fig. 1A) indicates an engulfment of MVBs by the tonoplast and a vacuole-mediated autophagy of MVBs.^5,6 MVBs, as prevacuolar compartments in plant cells,⁹ thus probably deliver their contents into the central vacuole via both the fusion with the tonoplast and the engulfment by the tonoplast (Fig. 2A and B). On the other hand, paramural bodies, in which small vesicles are situated between the cell wall and the plasma membrane, were associated with cell wall appositions deposited beneath fungal penetration attempts (Fig. 1B) or around hypersensitive cells including sites of plugged plasmodesmata (Fig. 1C and D).^5,6 Because paramural vesicles are similar to exosomes both in location and in morphology, we speculated that MVBs fuse with the plasma membrane in an exocytic manner to form paramural bodies.^5,6 Endocytosed cell surface materials in endosomal MVBs may be reused and delivered together with newly synthesized materials in Golgi apparatus-derived vesicles to cell wall appositions, which are deposited rapidly to prevent fungal penetration (Fig. 2A) or to contain hypersensitive cell death (Fig. 2B). MVBs thus may be driven along two distinct pathways to deliver their contents into either central vacuole or extracellular space.Open in a separate windowFigure 1Multivesicular compartments in intact cells in barley leaves attacked by the barley powdery mildew fungus. (A) An intravacuolar multivesicular body (MVB) with double limiting membranes in an intact epidermal cell (EC) adjacent to a hypersensitive epidermal cell (EC*). The arrows point to the outer limiting membrane, which is seemingly derived from the tonoplast. Note that neighboring intravacuolar vesicles (in between two arrowheads) may result from degradation of double limiting membranes of intravacuolar MVBs or may be delivered into the vacuole by MVB-fusion with the tonoplast. (B) Paramural vesicles (arrowheads) in a paramural body associated with cell wall appositions (asterisk) deposited by an intact epidermal cell. (C) A multivesicular body (MVB) in contact with a paramural body (PMB) (a nonmedian section) associated with cell wall appositions (asterisk) deposited by an intact mesophyll cell adjacent to a hypersensitive mesophyll cell. Note that cell wall appositions deposit beside an intercellular space (IS). The arrows point to the tonoplast. (D) A paramural body (PMB) associated with cell wall appositions (asterisks) blocking plasmodesmata (in between two arrowheads) at the side of an intact mesophyll cell (MC) underlying a hypersensitive epidermal cell (EC*). The arrows point to the tonoplast. CV, central vacuole; CW, cell wall; MB, microbody. Bars, 1µm.Open in a separate windowFigure 2Hypothetical diagram of delivery of endocytosed cell surface materials via MVBs into the central vacuole or the extracellular space where intact barley cells deposit cell wall appositions. (A) Deposition of cell wall appositions (asterisk) beneath powdery mildew penetration attempts. AGT, appressorial germ tube; PP, penetration peg. (B) Deposition of cell wall appositions (asterisks) against constricted plasmodesmata (PD) between a hypersensitive epidermal cell (EC) penetrated by the powdery mildew fungus and an underlying mesophyll cell (MC). H, haustorium. Arrows and numbers show pathways of vesicle trafficking. 1, Secretion of Golgi-derived vesicles containing newly synthesized materials; G, Golgi body; TGN, trans-Golgi network; 2, Endocytosis of cell surface materials from coated pits (coated open circles) via coated vesicles (coated circles) to multivesicular bodies (MVB); 3, Delivery of endocytosed materials for degradation inside the central vacuole (CV) via membrane fusion between MVBs and the tonoplast (T); small broken circles, vesicles in degradation; 4, Delivery of endocytosed materials for degradation inside the central vacuole via engulfment of MVBs by the tonoplast; large broken circles; MVB limiting membranes in degradation; 5, delivery of endocytosed materials into the extracellular space for deposition of cell wall appositions (asterisks) via membrane fusion between MVBs and the plasma membrane (PM). CW, cell wall; PMB, paramural body. PD0, 1, 2, 3 and 4 represent stages of plugging plasmodesmata. PD0, open plasmodesmata between two intact mesophyll cells (MC) subjacent to the hypersensitive epidermal cell (EC); PD1, constriction of plasmodesmata by callose (grey dots) deposition at plasmodesmal neck region; PD2, constricted plasmodesmata associated with plasmodesma-targeted secretion; PD3, further blocking of plasmodesmata by deposition of cell wall appositions; PD4, completely blocked plasmodesmata.Earlier than the discovery in animal cell systems,⁴ it was proposed in two independent papers in 1967 that the fusion of MVBs with the plasma membrane might result in the release of small vesicles into the extracellular space in fungi and in higher plants.^10,11 Several lines of evidence support the occurrence of MVB-mediated secretion of exosome-like vesicles in plants. First, vesicles of the same morphology as MVB internal vesicles have been observed in extracellular spaces or paramural spaces in various types of plant cells in various plant species by TEM.¹² An early study on endocytosis by soybean protoplasts also showed small extracellular vesicles attaching on the plasma membrane.⁸ Second, cooccurrence of MVBs and paramural vesicles has been observed in processes of cell proliferation, cell differentiation, and cell response to abiotic and biotic stress. Examples are cell plate formation,^13,14 secondary wall thickening,^15,16 cold hardness,^17,18 and deposition of cell wall appositions upon pathogen attack.^5,6,19–21 Third, identical molecular components, such as arabinogalactan proteins^22,23 and peroxidases,⁶ have been immunolocalized in both MVBs and paramural bodies. Despite these pieces of evidence, a conclusive demonstration of MVB-mediated secretion of exosomes in plants requires further exploration.The presently available experimental systems, approaches, and membrane markers may allow future demonstration of MVB-mediated secretion of exosomes in plants. Recent in vivo real-time observation and colocalization of cell surface and endosomal markers have already revealed that endosomes filled with endocytosed preexisting cell wall and plasma membrane materials are rapidly delivered to cytokinetic spaces to form cell plates in dividing tobacco, Arabidopsis, and maize cells.²⁴ Because TEM observed paramural bodies attaching to cell plates¹³ and MVBs in the vicinity of cell plates during all stages of cell plate formation,^14,25,26 MVBs and paramural bodies may participate in delivery of endocytosed building blocks to cell plates. Jiang''s and Robinson''s labs together developed a transgenic tobacco BY-2 cell line stably expressing a YFP-labeled vacuolar sorting receptor protein and antibodies against the vacuolar sorting receptor protein localized to the limiting membrane of MVBs.⁹ These tools together with live cell imaging and immunoelectron microscopy may allow visualization of MVB-fusion to the new plasma membrane, of vacuolar sorting receptors in both the limiting membrane of MVBs and the new plasma membrane, and of identical cell plate components in both internal vesicles of MVBs and paramural vesicles.In spite of obvious differences in plant and animal cytokinesis, the generation of cell plates by cell-plate-directed fusion of endosomes resembles the plugging of midbody canals by midbody-directed endosomes to separate daughter cells at the terminal phase of animal cytokinesis.²⁷ Likely, functional similarities of the fusion between endosomal MVBs and the plasma membrane to eliminate unwanted cell contents may also exist in maturation of mammalian red blood cells and plant sieve elements in the sense that the fusion of MVBs with the plasma membrane may occur during maturation of the latter.²⁸ On the other hand, although plant cells may secrete MVB-derived exosomes in defense response upon pathogen attack,^5,6 plant cell walls rule out the direct intercellular communication during the immune response mediated by exosomes in the circulation of mammals.³ In contrast, plasmodesma-directed secretion of exosomes would block the cell-to-cell communication between hypersensitive cells and their neighboring cells during hypersensitive response.⁵ Further exploration will lead us to a better understanding of similarities and differences of exosome secretion between plants and animals.     

Frasnian vertebrate taphonomy and sedimentology of macrofossil concentrations from the Langsēde Cliff,Latvia

Luk?evi?s, E., Ahlberg, P.E., Stinkulis, ?., Vasi?kova, J. & Zupi??, I. 2011: Frasnian vertebrate taphonomy and sedimentology of macrofossil concentrations from the Langsēde Cliff, Latvia. Lethaia, Vol. 45, pp. 356–370. The siliciclastic sequence of the Upper Devonian of Kurzeme, Western Latvia, is renowned for abundant vertebrate fossils, including the stem tetrapods Obruchevichthys gracilis and Ventastega curonica. During the first detailed taphonomic study of the vertebrate assemblage from the Ogre Formation cropping out at the Langsēde Cliff, Imula River, abundant vertebrate remains have been examined and identified as belonging to one psammosteid, two acanthodian and three sarcopterygian genera; the placoderm Bothriolepis maxima dominates the assemblage. Besides fully disarticulated placoderm and psammosteid plates, separate sarcopterygian scales and teeth, and acanthodian spines, partly articulated specimens including complete distal segments of Bothriolepis pectoral fins, Bothriolepis head shields and sarcopterygian lower jaws have been found. The size distribution of the placoderm bones demonstrates that the individuals within the assemblage are of approximately uniform age. Distinct zones have been traced within the horizontal distribution of the bones. These linear zones are almost perpendicular to the dominant dip azimuth of the cross‐beds and ripple‐laminae and most probably correspond to the depressions between subaqueous dunes. Concavity ratio varies significantly within the excavation area. The degree of fragmentation of the bones and disarticulation of the skeletons suggest that the carcasses were reworked and slightly transported before burial. Sedimentological data suggest deposition in a shallow marine environment under the influence of rapid currents. The fossiliferous bed consists of a basal bone conglomerate covered by a cross‐stratified sandstone with mud drapes, which is in turn overlain by ripple laminated sandstone, indicating the bones were buried by the gradual infilling of a tidal channel. All the Middle–Upper Devonian vertebrate bone‐beds from Latvia are associated with sandy to clayey deposits and have been formed in a sea‐coastal zone during rapid sedimentation episodes, but differ in fossil abundance and degree of preservation. □Agnathans, Devonian, facies analysis, fish, fossil assemblage, palaeoenvironment.     

Modeling depression in adult female cynomolgus monkeys (Macaca fascicularis)

Depressive disorders are prevalent, costly, and poorly understood. Male rodents in stress paradigms are most commonly used as animal models, despite the two-fold increased prevalence of depression in women and sex differences in response to stress. Although these models have provided valuable insights, new models are needed to move the field forward. Social stress-associated behavioral depression in adult female cynomolgus macaques closely resembles human depression in physiological, neurobiological, and behavioral characteristics, including reduced body mass, hypothalamic-pituitary-adrenal axis perturbations, autonomic dysfunction, increased cardiovascular disease risk, reduced hippocampal volume, altered serotonergic function, decreased activity levels, and increased mortality. In addition, behaviorally depressed monkeys also have low ovarian steroid concentrations, even though they continue to have menstrual cycles. Although this type of ovarian dysfunction has not been reported in depressed women and is difficult to identify, it may be the key to understanding the high prevalence of depression in women. Depressive behavior in female cynomolgus monkeys is naturally occurring and not induced by experimental manipulation. Different social environmental challenges, including isolation vs. subordination, may elicit the depression-like response in some animals and not others. Similarly, social subordination is stressful and depressive behavior is more common in socially subordinate monkeys. Yet, not all subordinates exhibit behavioral depression, suggesting individual differences in sensitivity to specific environmental stressors and enhanced risk of behavioral depression in some individuals. The behavior and neurobiology of subordinates is distinctly different than that of behaviorally depressed monkeys, which affords the opportunity to differentiate between stressed and depressed states. Thus, behaviorally depressed monkeys exhibit numerous physiological, neurobiological, and behavioral characteristics same as those of depressed human beings. The nonhuman primate model represents a new animal model of depression with great promise for furthering our understanding of this prevalent and debilitating disease and identifying novel therapeutic targets.     

Spatial and temporal population genetic structure of four northeastern Pacific littorinid gastropods: the effect of mode of larval development on variation at one mitochondrial and two nuclear DNA markers

We investigated the effect of development mode on the spatial and temporal population genetic structure of four littorinid gastropod species. Snails were collected from the same three sites on the west coast of Vancouver Island, Canada in 1997 and again in 2007. DNA sequences were obtained for one mitochondrial gene, cytochrome b ( Cyt b ), and for up to two nuclear genes, heat shock cognate 70 ( HSC70 ) and aminopeptidase N intron ( APN54 ). We found that the mean level of genetic diversity and long-term effective population sizes ( N _e) were significantly greater for two species, Littorina scutulata and L. plena , that had a planktotrophic larval stage than for two species, Littorina sitkana and L. subrotundata , that laid benthic egg masses which hatched directly into crawl-away juveniles. Predictably, two poorly dispersing species, L. sitkana and L. subrotundata , showed significant spatial genetic structure at an 11- to 65-km geographical scale that was not observed in the two planktotrophic species. Conversely, the two planktotrophic species had more temporal genetic structure over a 10-year interval than did the two direct-developing species and showed highly significant temporal structure for spatially pooled samples. The greater temporal genetic variation of the two planktotrophic species may have been caused by their high fecundity, high larval dispersal, and low but spatially correlated early survivorship. The sweepstakes-like reproductive success of the planktotrophic species could allow a few related females to populate hundreds of kilometres of coastline and may explain their substantially larger temporal genetic variance but lower spatial genetic variance relative to the direct-developing species.