Structure of pulmonary surfactant membranes and films: the role of proteins and lipid-protein interactions

The pulmonary surfactant system constitutes an excellent example of how dynamic membrane polymorphism governs some biological functions through specific lipid-lipid, lipid-protein and protein-protein interactions assembled in highly differentiated cells. Lipid-protein surfactant complexes are assembled in alveolar pneumocytes in the form of tightly packed membranes, which are stored in specialized organelles called lamellar bodies (LB). Upon secretion of LBs, surfactant develops a membrane-based network that covers rapidly and efficiently the whole respiratory surface. This membrane-based surface layer is organized in a way that permits efficient gas exchange while optimizing the encounter of many different molecules and cells at the epithelial surface, in a cross-talk essential to keep the whole organism safe from potential pathogenic invaders. The present review summarizes what is known about the structure of the different forms of surfactant, with special emphasis on current models of the molecular organization of surfactant membrane components. The architecture and the behaviour shown by surfactant structures in vivo are interpreted, to some extent, from the interactions and the properties exhibited by different surfactant models as they have been studied in vitro, particularly addressing the possible role played by surfactant proteins. However, the limitations in structural complexity and biophysical performance of surfactant preparations reconstituted in vitro will be highlighted in particular, to allow for a proper evaluation of the significance of the experimental model systems used so far to study structure-function relationships in surfactant, and to define future challenges in the design and production of more efficient clinical surfactants.     

Methods for assessing the burden of parasitic zoonoses: echinococcosis and cysticercosis

Cysticercosis and echinococcosis cause illness and productivity losses in human and agricultural animal populations. Recent studies suggest that these diseases have large societal impacts on endemic areas. Estimates of burden provide essential, evidence-based data for conducting cost-benefit and cost-utility analyses that will secure political will, and financial and technical resources. To evaluate the burden, the monetary and non-monetary impacts of these zoonoses on human health, agriculture and society must be considered comprehensively. In this article, we review the framework used to assess the burden of cysticercosis and echinococcosis, and the data needed to estimate the extent of the problem for societies.     

Characterization of tryptophan high affinity transport system in pinealocytes of the rat. Day-night modulation

Summary.  Tryptophan is required in the pineal gland for the formation of serotonin, precursor of melatonin biosynthesis. The level of this amino acid in the serum and in the pineal gland of the rat undergoes a circadian rhythm, and reduced plasma tryptophan concentration decreases secretion of melatonin in humans. Tryptophan is transported into the cells by the long chain neutral amine acid system T and by the aromatic amino acid system T. The high affinity component of [³H]tryptophan uptake was studied in pinealocytes of the rat. Inhibition was observed in the presence of phenylalanine or tyrosine, but not in the presence of neutral amino acids, alanine, glycine, serine, lysine or by 2-aminobicyclo[2,2,1]-heptane-2-carboxylic acid, a substrate specific for system L. The transport of tryptophan was temperature-dependent and trans-stimulated by phenylalanine and tyrosine, but was energy-, sodium-, chloride-, and pH-independent. In addition, the sulphydryl agent N-ethylmaleimide did not modify the high affinity transport of tryptophan in pinealocytes. The kinetic parameters were not significantly different at 12:00 as compared to 24:00 h. The treatment with the inhibitor of tryptophan hydroxylase, p-chlorophenylalanine, produced an increase in the maximal velocity of the uptake and a reduction in the affinity at 12:00, but not at 24:00 h, probably indicating that during the day, the formation of serotonin in the pineal gland is favoured by elevating the uptake of tryptophan, whereas at 24:00 h other mechanisms, such as induction of enzymes are taking place. High affinity tryptophan uptake in the rat pineal gland occurs through system T and is upregulated during the day when the availability of serotonin is reduced. Received March 15, 2001 Accepted July 8, 2002 Published online January 20, 2003 Acknowledgements This work was supported by the Grant S1-3490 from Consejo Nacional de Investigaciones Cientificas y Tecnológicas (CONICIT), Venezuela. We appreciate the secretarial assistance of Mrs. Isabel Otaegui. Carmen I. Gutiérrez is a PhD Student from Ciencias Fisiológicas, Facultad de Medicina, Universidad Central de Venezueta (UCV), Caracas, and supported by Universidad Francisco de Miranda, Coro, Falcón, Venezuela. Joseph Glykys is a Medical Student from Universidad de Carabobo, Valencia, Venezuela, and an Assistant Student of Centro de Estudios Avanzados, IVIC. Authors' address: Dr. Lucimey Lima, Laboratorio de Neuroquímica, Centro de Biofísica y Bioquímica, Instituto Venezolano de Investigaciones Científicas, Apdo. 21827, Caracas 1020-A, Venezuela, Fax: 58-212-504-1295, E-mail: llima@cbb.ivic.ve     

Characterization of Cyt2Bc toxin from Bacillus thuringiensis subsp. medellin

We cloned and sequenced a new cytolysin gene from Bacillus thuringiensis subsp. medellin. Three IS240-like insertion sequence elements and the previously cloned cyt1Ab and p21 genes were found in the vicinity of the cytolysin gene. The cytolysin gene encodes a protein 29.7 kDa in size that is 91.5% identical to Cyt2Ba from Bacillus thuringiensis subsp. israelensis and has been designated Cyt2Bc. Inclusions containing Cyt2Bc were purified from the crystal-negative strain SPL407 of B. thuringiensis. Cyt2Bc reacted weakly with antibodies directed against Cyt2Ba and was not recognized by an antiserum directed against the reference cytolysin Cyt1Aa. Cyt2Bc was hemolytic only upon activation with trypsin and had only one-third to one-fifth of the activity of Cyt2Ba, depending on the activation time. Cyt2Bc was also mosquitocidal against Aedes aegypti, Anopheles stephensi, and Culex quinquefasciatus, including strains resistant to the Bacillus sphaericus binary toxin. Its toxicity was half of that of Cyt2Ba on all mosquito species except resistant C. quinquefasciatus.     

Apoptosis in fresh and cryopreserved cardiac valves of pig samples

To analyse the influence of cold ischemic time (CIT) (2–24 h) and of cryopreservation (liquid phase) on the viability of the valvular fibroblasts and in the presence of apoptosis. Cardiac valves from 10 pigs were evaluated by anatomo-pathological study of the wall, muscle and leaflet. At the same time, the presence of cellular death due to apoptosis was investigated in two ways; directly on tissue by Apodetec system and by two-colour flow cytometry assay analyzing a suspension of fibroblast from valve leaflets using Anexina V and propidium iodure (PI). We established three groups of samples to compare different experimental conditions: 2 h of ischemia (group 1), 24 h of ischemia (group 2), and a programme of cryopreservation (−1°C/min) after 2 h of ischemia, followed by storage in liquid nitrogen during a week and thawing was performed (group 3). The analysis of viabilities showed slight differences between all three groups. The results indicated CIT of 24 h undergoing more structural affectation than CIT of 2 h. Flow cytometry analysis did not show important differences between groups; however cryopreserved samples (group 3) slightly less viability and a higher percentage of death by apoptosis than group 1 and 2 using flow cytometry. Apoptosis was confirmed on tissue from all valves but mainly in samples of group 2 and group 3. In summary, the viability of the valves in the case of ischemic times of 2 h, 24 h or after cryopreservation/thawing differs slightly. The death of the cells is mainly mediated by necrosis and not by apoptosis.     

Functional and Evolutionary Analysis of the CASPARIAN STRIP MEMBRANE DOMAIN PROTEIN Family

CASPARIAN STRIP MEMBRANE DOMAIN PROTEINS (CASPs) are four-membrane-span proteins that mediate the deposition of Casparian strips in the endodermis by recruiting the lignin polymerization machinery. CASPs show high stability in their membrane domain, which presents all the hallmarks of a membrane scaffold. Here, we characterized the large family of CASP-like (CASPL) proteins. CASPLs were found in all major divisions of land plants as well as in green algae; homologs outside of the plant kingdom were identified as members of the MARVEL protein family. When ectopically expressed in the endodermis, most CASPLs were able to integrate the CASP membrane domain, which suggests that CASPLs share with CASPs the propensity to form transmembrane scaffolds. Extracellular loops are not necessary for generating the scaffold, since CASP1 was still able to localize correctly when either one of the extracellular loops was deleted. The CASP first extracellular loop was found conserved in euphyllophytes but absent in plants lacking Casparian strips, an observation that may contribute to the study of Casparian strip and root evolution. In Arabidopsis (Arabidopsis thaliana), CASPL showed specific expression in a variety of cell types, such as trichomes, abscission zone cells, peripheral root cap cells, and xylem pole pericycle cells.Biological membranes are conceptually simple structures that may be generated in vitro according to simple physicochemical principles. In vivo, however, membranes are highly complex and host a plethora of proteins that mediate the transfer of molecules and communication across the membrane. Proteins may be trapped in membrane by their transmembrane domains, anchored by lipid tails, or attach to membrane-integral proteins. A further level of complexity is seen when membrane proteins are not equally distributed but occupy only a limited fraction of the available surface (i.e. when they are polarly localized or when they form small membrane subdomains in the micrometer range). The question of how membrane proteins are retained locally and prevented from diffusing freely is of high importance to cell biology. Polarly localized proteins may be retained in their respective domains by membrane fences; in such a situation, polarly localized proteins are mobile in their domains but cannot diffuse through tightly packed scaffold proteins forming a molecular fence within the membrane. Membrane fences delimiting polar domains have been described in different organisms. For example, diffusion between membrane compartments is prevented in budding yeast (Saccharomyces cerevisiae) at the level of the bud neck (Barral et al., 2000; Takizawa et al., 2000); in ciliated vertebrate cells, between ciliary and periciliary membranes (Hu et al., 2010); in epithelial cells, between apical and basolateral membranes (van Meer and Simons, 1986); in neurons, between axon and soma (Kobayashi et al., 1992; Winckler et al., 1999; Nakada et al., 2003); and in spermatozoa, at the level of the annulus (Myles et al., 1984; Nehme et al., 1993). The existence of membrane scaffolds that prevent free protein diffusion has also been described in bacteria (Baldi and Barral, 2012; Schlimpert et al., 2012). In plants, we have shown the existence of a strict membrane fence in the root endodermis, where a median domain splits the cell in two lateral halves occupied by different sets of proteins (Alassimone et al., 2010). The situation in the plant endodermis is analogous to the separation of animal epithelia into apical and basolateral domains; indeed, a parallel between epithelia and endodermal cells has been drawn, despite the different origin of multicellularity in plants and animals (Grebe, 2011).The protein complexes responsible for the formation of membrane fences have been identified. Septins are a family of proteins able to oligomerize and form filaments (Saarikangas and Barral, 2011); their role in the formation of membrane fences has been demonstrated in several organisms and cellular situations, including the yeast bud neck (Barral et al., 2000; Takizawa et al., 2000), animal cilia (Hu et al., 2010), and mammalian spermatozoa (Ihara et al., 2005; Kissel et al., 2005; Kwitny et al., 2010). At the axonal initial segment of neurons, AnkyrinG is necessary to establish and maintain a membrane scaffold where different membrane proteins are immobilized and stabilized (Hedstrom et al., 2008; Sobotzik et al., 2009). In Caulobacter crescentus, the stalk protein Stp forms a complex that prevents diffusion between the cell body and stalk and between stalk compartments. Claudins and occludin are the main components of epithelial tight junctions (Furuse et al., 1993, 1998). Occludins are four-membrane-span proteins and belong to the MARVEL protein family (Sánchez-Pulido et al., 2002), as do Tricellulin and MARVELD3, which are also tight junction-associated proteins (Furuse et al., 1993; Ikenouchi et al., 2005; Steed et al., 2009).In Arabidopsis (Arabidopsis thaliana), our group identified a family of proteins that form a membrane fence in the endodermis (Roppolo et al., 2011). These CASPARIAN STRIP MEMBRANE DOMAIN PROTEINS (CASP1 to CASP5) are four-transmembrane proteins that form a median domain referred to as the Casparian strip membrane domain (CSD). CASPs are initially targeted to the whole plasma membrane, then they are quickly removed from lateral plasma membranes and remain localized exclusively at the CSD; there, they show an extremely low turnover, although they are eventually removed (Roppolo et al., 2011). The membrane proteins NOD26-LIKE INTRINSIC PROTEIN5;1 and BORON TRANSPORTER1 are restricted from diffusing through the CSD and remain polarly localized in the outer and inner lateral membranes, respectively; a fluorescent lipophilic molecule, when integrated in the outer endodermal membrane, was blocked at the level of the CSD and could not diffuse into the inner membrane (Roppolo et al., 2011). Besides making a plasma membrane diffusion barrier, CASPs have an important role in directing the modification of the cell wall juxtaposing their membrane domain: by interacting with secreted peroxidases, they mediate the deposition of lignin and the building up of the Casparian strips (Roppolo et al., 2011; Naseer et al., 2012; Lee et al., 2013). The two CASP activities, making membrane scaffolds and directing a modification of the cell wall, can be uncoupled: indeed, (1) formation of the CASP domain is independent from the deposition of lignin, and (2) interaction between CASPs and peroxidases can take place outside the CSD when CASPs are ectopically expressed (Lee et al., 2013).As CASPs are currently the only known proteins forming membrane fences in plants and because of their essential role in directing a local cell wall modification, we were interested in characterizing the repertoire of a large number of CASP-like (CASPL) proteins in the plant kingdom. Our aim was to provide the molecular basis for the discovery of additional membrane domains in plants and for the identification of proteins involved in local cell wall modifications. We extended our phylogenetic analysis outside of the plant kingdom and found conservation between CASPLs and the MARVEL protein family. Conserved residues are located in transmembrane domains, and we provide evidence suggesting that these domains are involved in CASP localization. We explored the potential use of the CASPL module in plants by investigating CASPL expression patterns and their ability to form membrane domains in the endodermis. Moreover, we related the appearance of the Casparian strips in the plant kingdom to the emergence of a CASP-specific signature that was not found in the genomes of plants lacking Casparian strips.     

Callus induction, somatic embryogenesis and organogenesis in Narcissus confusus: correlation between the state of differentiation and the content of galanthamine and related alkaloids

In vitro cultures from two strains of Narcissus confusus (Amaryllidaceae) initiated from mature seeds were screened for their ability to produce alkaloids. Protocols for callus induction, somatic embryogenesis and organogenesis were established. The alkaloid contents were determined by HPLC. Undifferentiated calli produced small amounts of galanthamine, which increased with the degree of tissue differentiation. Scanning electron micrographs of the cultures at different stages of development were made. Embryogenic friable calli were maintained in culture for more than 2 years, retaining a high regeneration capability. All regenerated plants showed normal morphological characteristics. Received: 20 August 1997 / Revision received: 20 December 1997 / Accepted: 1 February 1998     

Squaramides as novel class I and IIB histone deacetylase inhibitors for topical treatment of cutaneous t-cell lymphoma

A series of squaramide-based hydroxamic acids were designed, synthesized and evaluated against human HDAC enzyme. Squaramides were found to be potent in the Hut78 cell line, but initially suffered from low solubility. Leads with improved solubility and metabolic profiles were shown to be class I, IIB and IV selective.     

P-selectin and CD63 use different mechanisms for delivery to Weibel-Palade bodies

The biogenesis of endothelial-specific Weibel-Palade bodies (WPB) is poorly understood, despite their key role in both haemostasis and inflammation. Biogenesis of specialized organelles of haemopoietic cells is often adaptor protein complex 3-dependent (AP-3-dependent), and AP-3 has previously been shown to play a role in the trafficking of both WPB membrane proteins, P-selectin and CD63. However, WPB are thought to form at the trans Golgi network (TGN), which is inconsistent with a role for AP-3, which operates in post-Golgi trafficking. We have therefore investigated in detail the mechanisms of delivery of these two membrane proteins to WPB. We find that P-selectin is recruited to forming WPB in the trans-Golgi by AP-3-independent mechanisms that use sorting information within both the cytoplasmic tail and the lumenal domain of the receptor. In contrast, CD63 is recruited to already-budded WPB by an AP-3-dependent route. These different mechanisms of recruitment lead to the presence of distinct immature and mature populations of WPB in human umbilical vein endothelial cells (HUVEC).