How do Hydrophilic Surfaces Determine Liposome Fate in Vivo?

Abstract

Changing liposome physical, properties by designing vesicles with a hydrophilic/ steric barrier at the liposome surface has resulted in altered pharmacokinetics of these liposomes leading to increased blood levels of drug-carrying liposomes and reduced uptake by the RES. This discovery opens up new therapeutic opportunities for liposome-based drug delivery using hydrophilic coatings. Unravelling the mechanism of action of such coatings is an exciting challenge that will facilitate optimization of liposome surfaces for specific drug delivery applications. This article puts forward a series of assumptions and hypotheses to characterize the way hydrophilic coatings extend the plasma half-life of sterically - coated liposomes, to begin to explain how a steric barrier at the surface of liposomes may act. These speculations are examined in the light of current experimental evidence including that from non-liposome systems, and a model for particle removal from the circulation is proposed.

Introduction

Since the days when liposomes were first conceived for drug delivery, ways have been sought to increase the length of time injected vesicles circulate in the body (1). In the mid-eighties, manipulation of the liposomal lipid composition increased the amount of time liposomes remained in the circulation for a well-defined but relatively limited design of     

Are different proteins synthesized in distinct domains in a neuron?

Are different messenger RNA species translated in distinct, limited domains within a cell? For the particular case of the giant R2 neuron from Aplysia californica an answer to this question is possible for the more abundantly synthesized proteins. After brief labeling with 35S-methionine, the R2 neuron soma was frozen and divided into two or three parts. The newly synthesized proteins were analyzed following two-dimensional polyacrylamide gel electrophoresis. No evidence for limited domains of synthesis for 26 abundantly synthesized polypeptides in the R2 neuron was found.     

Do X and Y spermatozoa differ in proteins?

This article reviews the current knowledge about X- and Y-chromosomal gene expression during spermatogenesis and possible differences between X- and Y-chromosome-bearing spermatozoa (X and Y sperm) in relation to whether an immunological method of separation of X and Y spermatozoa might some day be feasible. Recent studies demonstrated that X- and Y-chromosome-bearing spermatids do express X- and Y-chromosomal genes that might theoretically result in protein differences between X and Y sperm. Most, if not all, of these gene products, however, are expected to be shared among X and Y spermatids via intercellular bridges. Studies on aberrant mouse strains indicate that complete sharing might not occur for all gene products. This keeps open the possibility that X and Y sperm may differ in proteins, but until now, this has not been confirmed by comparative studies between flow-cytometrically sorted X and Y sperm for H-Y antigen or other membrane proteins.     

How do Rab proteins function in membrane traffic?

The Rabs are a group of GTP-binding proteins implicated for some time in the targeting of different transport vesicles within the cell, but it has been unclear how they function, or how they relate to a second group of targeting proteins, the SNAREs. Recent work, discussed in this review, has used biophysical, biochemical and genetic approaches to begin to answer these questions for Rab3, Rab5 and the yeast protein Sec4p. However, the results from these three Rabs lead to a surprising conclusion: the different Rabs seem to function via highly diverse target proteins.     

Does secondary structure determine tertiary structure in proteins?

Is highly approximate knowledge of a protein's backbone structure sufficient to successfully identify its family, superfamily, and tertiary fold? To explore this question, backbone dihedral angles were extracted from the known three‐dimensional structure of 2,439 proteins and mapped into 36 labeled, 60° × 60° bins, called mesostates. Using this coarse‐grained mapping, protein conformation can be approximated by a linear sequence of mesostates. These linear strings can then be aligned and assessed by conventional sequence‐comparison methods. We report that the mesostate sequence is sufficient to recognize a protein's family, superfamily, and fold with good fidelity. Proteins 2005. © 2005 Wiley‐Liss, Inc.     

Are membrane proteins "inside-out" proteins?

One of the central paradigms of structural biology is that membrane proteins are "inside-out" proteins, in that they have a core of polar residues surrounded by apolar residues. This is the reverse of the characteristics found in water-soluble proteins. We have decided to test this paradigm, now that sufficient numbers of transmembrane alpha-helical structures are accessible to statistical analysis. We have analyzed the correlation between accessibility and hydrophobicity of both individual residues and complete helices. Our analyses reveal that hydrophobicity of residues in a transmembrane helical bundle does not correlate with any preferred location and that the hydrophilic vector of a helix is a poor indicator of the solvent exposed face of a helix. Neither polar nor hydrophobic residues show any bias for the exterior or the interior of a transmembrane domain. As a control, analysis of water-soluble helical bundles performed in a similar manner has yielded clear correlations between hydrophobicity and accessibility. We therefore conclude that, based on the data set used, membrane proteins as "inside-out" proteins is an unfounded notion, suggesting that packing of alpha-helices in membranes is better understood by maximization of van der Waal's forces, rather than by a general segregation of hydrophobicities driven by lipid exclusion.     

A search method for homologs of small proteins. Ubiquitin-like proteins in prokaryotic cells?

The question of protein homology versus analogy arises when proteins share a common function or a common structural fold without any statistically significant amino acid sequence similarity. Even though two or more proteins do not have similar sequences but share a common fold and the same or closely related function, they are assumed to be homologs, descendant from a common ancestor. The problem of homolog identification is compounded in the case of proteins of 100 or less amino acids. This is due to a limited number of basic single domain folds and to a likelihood of identifying by chance sequence similarity. The latter arises from two conditions: first, any search of the currently very large protein database is likely to identify short regions of chance match; secondly, a direct sequence comparison among a small set of short proteins sharing a similar fold can detect many similar patterns of hydrophobicity even if proteins do not descend from a common ancestor. In an effort to identify distant homologs of the many ubiquitin proteins, we have developed a combined structure and sequence similarity approach that attempts to overcome the above limitations of homolog identification. This approach results in the identification of 90 probable ubiquitin-related proteins, including examples from the two prokaryotic domains of life, Archaea and Bacteria.     

A role for G proteins in plant hormone signalling?

The G protein signalling pathway is one of the most highly conserved mechanisms that enables cells to sense and respond to changes in their environment. Essential components of this are cell surface G protein-coupled receptors (GPCRs) that perceive extracellular ligands, and heterotrimeric G proteins (G proteins) that transduce information from activated GPCRs to down-stream effectors such as enzymes or ion channels. It is now clear from a range of biochemical and molecular studies that some potential G protein signalling components exist in plants. The best examples of these are the seven transmembrane receptor homologue GCR1 and the G_α (GPA1) and G_β (Gβ1) subunit homologues of heterotrimeric G proteins. G protein agonists and antagonists are known to influence a variety of signalling events in plants and have been used to implicate G proteins in a range of signalling pathways that include the plant hormones gibberellin and auxin. Furthermore, antisense suppression of GCR1 expression in Arabidopsis leads to a phenotype that supports a role for this receptor in cytokinin signalling. This review considers the current evidence for and against functional G protein signalling pathways in higher plants and questions whether or not these might be involved in the action of certain plant hormones.     

Polygalacturonase inhibiting proteins: players in plant innate immunity?

Polygalacturonase-inhibiting proteins (PGIPs) are extracellular leucine-rich repeat (LRR) proteins that recognize and inhibit fungal polygalacturonases (PGs). The PG-PGIP interaction favours the accumulation of elicitor-active oligogalacturonides and causes the activation of defence responses. Small gene families encode PGIP isoforms that differ in affinity and specificity for PGs secreted by different pathogens. The consensus motif within the LRR structure of PGIPs is the same as that of the extracellular receptors of the plant innate immune system. Structural and functional evidence suggest that PGIPs are versatile proteins involved in innate immunity and that they are capable of recognizing different surface motifs of functionally related but structurally variable PGs.     

Does conformational free energy distinguish loop conformations in proteins?

Limitations in protein homology modeling often arise from the inability to adequately model loops. In this paper we focus on the selection of loop conformations. We present a complete computational treatment that allows the screening of loop conformations to identify those that best fit a molecular model. The stability of a loop in a protein is evaluated via computations of conformational free energies in solution, i.e., the free energy difference between the reference structure and the modeled one. A thermodynamic cycle is used for calculation of the conformational free energy, in which the total free energy of the reference state (i.e., gas phase) is the CHARMm potential energy. The electrostatic contribution of the solvation free energy is obtained from solving the finite-difference Poisson-Boltzmann equation. The nonpolar contribution is based on a surface area-based expression. We applied this computational scheme to a simple but well-characterized system, the antibody hypervariable loop (complementarity-determining region, CDR). Instead of creating loop conformations, we generated a database of loops extracted from high-resolution crystal structures of proteins, which display geometrical similarities with antibody CDRs. We inserted loops from our database into a framework of an antibody; then we calculated the conformational free energies of each loop. Results show that we successfully identified loops with a "reference-like" CDR geometry, with the lowest conformational free energy in gas phase only. Surprisingly, the solvation energy term plays a confusing role, sometimes discriminating "reference-like" CDR geometry and many times allowing "non-reference-like" conformations to have the lowest conformational free energies (for short loops). Most "reference-like" loop conformations are separated from others by a gap in the gas phase conformational free energy scale. Naturally, loops from antibody molecules are found to be the best models for long CDRs (> or = 6 residues), mainly because of a better packing of backbone atoms into the framework of the antibody model.     

Phosphoryl transfer in Ras proteins,conclusive or elusive?

The chemical mechanism of GTP hydrolysis by GTP-binding proteins of the Ras superfamily continues to inspire both experimental and computational biologists. The debate centres on the nature of the transition state, with arguments for both dissociative and associative, and whether there is a common GTPase mechanism for these proteins. In a recent structural analysis of Rab11, the product P(i) was found in an unusual configuration. This finding indicates that substrate-assisted catalysis might operate as a mechanism to enable nucleophilic attack in the intrinsic GTPase reaction, and would thus favour a pentavalent phosphorane intermediate. Recent findings on the GAP-mediated reaction of different Ras proteins suggest that a common mechanism might not exist and that G proteins probably show a continuum of electronic configurations in the transition state.     

Carbamylation of proteins in 2-D electrophoresis--myth or reality?

Carbamylation is widely quoted as being a problem in 2-D gel analysis and the associated sample preparation steps. This modification occurs when iso-cyanate, a urea break-down product, covalently modifies lysine residues, thus inducing a change in isoelectric point. Urea is used at up to 9 M concentrations in sample preparation and 2-D gels because of its ability to disrupt protein structure and effect denaturation without the need for ionic surfactants such as SDS. We have studied carbamylation using 7 M urea and 2 M thiourea, under a range of experimental temperatures to establish when, and if, it occurs and what can be done to minimize the modification. The actual time required for protein extraction from a tissue is usually short compared to the time required for procedures such as reduction and alkylation and IPG rehydration and focusing. Therefore, it is the temperature during these post-extraction procedures that is the most critical factor. Our experiments have shown that carbamylation does not occur during electrophoresis in the presence of urea, even with prolonged run-times. However, under poorly controlled sample preparation and storage conditions, it can become a major event.     

Multiple Rieske proteins in prokaryotes: Where and why?

Many microbial genomes have been sequenced in the recent years. Multiple genes encoding Rieske iron-sulfur proteins, which are subunits of cytochrome bc-type complexes or oxygenases, have been detected in many pro- and eukaryotic genomes. The diversity of substrates, co-substrates and reactions offers obvious explanations for the diversity of the low potential Rieske proteins associated with oxygenases, but the physiological significance of the multiple genes encoding high potential Rieske proteins associated with the cytochrome bc-type complexes remains elusive. For some organisms, investigations into the function of the later group of genes have been initiated. Here, we summarize recent finding on the characteristics and physiological functions of multiple high potential Rieske proteins in prokaryotes. We suggest that the existence of multiple high potential Rieske proteins in prokaryotes could be one way of allowing an organism to adapt their electron transfer chains to changing environmental conditions.     

Are aromatic carbon donor hydrogen bonds linear in proteins?

Proteins fold and maintain structure through the collective contributions of a large number of weak, noncovalent interactions. The hydrogen bond is one important category of forces that acts on very short distances. As our knowledge of protein structure continues to expand, we are beginning to appreciate the role that weak carbon-donor hydrogen bonds play in structure and function. One property that differentiates hydrogen bonds from other packing forces is propensity for forming a linear donor-hydrogen-acceptor orientation. To ascertain if carbon-donor hydrogen bonds are able to direct acceptor linearity, we surveyed the geometry of interactions specifically involving aromatic sidechain ring carbons in a data set of high resolution protein structures. We found that while donor-acceptor distances for most carbon donor hydrogen bonds were tighter than expected for van der Waals packing, only the carbons of histidine showed a significant bias for linear geometry. By categorizing histidines in the data set into charged and neutral sidechains, we found only the charged subset of histidines participated in linear interactions. B3LYP/6-31G**++ level optimizations of imidazole and indole-water interactions at various fixed angles demonstrates a clear orientation dependence of hydrogen bonding capacity for both charged and neutral sidechains. We suggest that while all aromatic carbons can participate in hydrogen bonding, only charged histidines are able to overcome protein packing forces and enforce linear interactions. The implications for protein modeling and design are discussed.     

Viral proteins functioning in organelles: a cryptic origin?

Although mitochondria derive from alpha-proteobacteria, many proteins acting in this organelle did not originate from bacteria. In particular, phylogenetic evidence indicates that RNA polymerase, DNA polymerase and DNA primase--with homologues encoded by T3/T7-like bacteriophages--have replaced the ancestral proteins of bacterial origin. To date, there was no clear explanation for this puzzling observation. Bacterial genomics has now revealed the presence of cryptic prophages that are related to T3/T7 in several genomes of proteobacteria. We propose that such a prophage was present in the ancestral alpha-proteobacterium at the origin of mitochondria and that RNA polymerase, DNA polymerase and DNA primase encoded by this prophage replaced the original bacterial enzymes to function in mitochondria. Another T3/T7 viral-like RNA polymerase is functional in the chloroplast, indicating that a strong selection pressure has favored replacement of some cellular proteins by viral proteins in organelle evolution.     

Mud-puddling behavior in tropical butterflies: in search of proteins or minerals?

We experimentally investigated the attraction of adult butterflies to moist soil and dirt places (a behavior termed `mud-puddling') in two species-rich tropical communities on the island of Borneo. At a rain forest site, 227 individuals (46 species) were attracted to the baits, compared to 534 individuals (54 species) at a farmland site. With one single exception, all attracted butterflies were males. Of various salt and amino acid solutions, only sodium was accepted, but overall, albumin solutions turned out to be the most attractive puddling resource. Butterfly families differed consistently in their resource preferences. Representatives of the families Papilionidae and Pieridae more often visited NaCl solutions, but still accepted albumin, whereas representatives of the Nymphalidae, Hesperiidae and, in particular, Lycaenidae preferred the protein resource. In experiments using decoys prepared from pinned butterfly specimens, representatives of the Papilionidae and Pieridae were more strongly attracted to baits provided with decoys made from conspicuous, medium-sized yellow Eurema species (Pieridae), whereas dummies made from small, cryptically colored lycaenids (Prosotas and Caleta species) were ineffective. Decoys did not influence the attraction of lycaenid butterflies towards baits. Hence, visual cues play an important role in locating puddling resources for papilionids and pierids, while for lycaenid butterflies searching for nitrogen sources, olfactory cues emitted by decaying organic matter are more likely to be important. The strong attraction of male butterflies to nitrogen-rich resources suggests that, as in the case of sodium, these nutrients may increase reproductive success. Received: 5 October 1998 / Accepted: 7 December 1998     

What is the role of SNARE proteins in membrane fusion?

Soluble N-ethylmaleimide-sensitive factor activating protein receptor (SNARE) proteins have been at the fore-front of research on biological membrane fusion for some time. The subcellular localization of SNAREs and their ability to form the so-called SNARE complex may be integral to determining the specificity of intracellular fusion (the SNARE hypothesis) and/or serving as the minimal fusion machinery. Both the SNARE hypothesis and the idea of the minimal fusion machinery have been challenged by a number of experimental observations in various model systems, suggesting that SNAREs may have other functions. Considering recent advances in the SNARE literature, it appears that SNAREs may actually function as part of a complex fusion "machine." Their role in the machinery could be any one or a combination of roles, including establishing tight membrane contact, formation of a scaffolding on which to build the machine, binding of lipid surfaces, and many others. It is also possible that complexations other than the classic SNARE complex participate in membrane fusion.