The role of the cell cycle on the efficiency of photochemical gene transfection

The efficiency of gene transfection mediated by nonviral vectors is limited because of nonoptimal intracellular trafficking of transfecting DNA. Most nonviral vectors deliver transfecting DNA into a cell through endocytosis. However, poor escape from endocytic vesicles and inefficient transport of DNA into the nucleus often limits a success of gene transfection. Photochemical transfection is a new method, based on light-induced permeabilisation of endocytic vesicles, liberating transfecting DNA into the cytosol, concurrently increasing the chances for DNA to enter the nucleus.The aim of this study was to investigate the role of the cell cycle for the efficiency of photochemical transfection. It was demonstrated that in asynchronous human colon carcinoma HCT 116 cells photochemical treatment increased the transfection mediated by the nonviral vectors, the cationic polypeptide polylysine and the cationic lipid N-(2-aminoethyl)-N,N-dimethyl-2,3-bis(tetradecyloxy)-1-propanaminium bromide/dioleoylphosphatidylethanolamine (beta AE-DMRIE/DOPE), by 30- and 2.5-fold, respectively. In aphidicolin-synchronised cells, photochemical transfection mediated by polylysine was dependent on the cell cycle: transfection level was 4-fold higher when illumination, inducing photochemical reactions, was performed during the G2/M phase as compared to the G1/early-S phase. The cell cycle influence on photochemical transfection mediated by beta AE-DMRIE/DOPE was very low: only 20% difference between G2/M and the G1/S phase was observed. We suggest that transgenes, photochemically liberated close/during mitosis, perhaps have the highest opportunity to enter the nucleus and be expressed. However, the dependence of photochemical transfection on the cell cycle might be partially disguised by various factors induced by photochemical treatment.     

Quantifying the intracellular transport of viral and nonviral gene vectors in primary neurons

Real-time confocal particle tracking (CPT) was used to compare the transport and trafficking of polyethylenimine (PEI)/DNA nanocomplexes to that of efficient adenoviruses in live primary neurons. Surprisingly, the quantitative intracellular transport properties of PEI/DNA nonviral gene vectors are similar to that of adenoviral vectors. For example, the values of individual particle/virus transport rates and the distributions of particle/virus transport modes (i.e., the percentage undergoing active, diffusive, or subdiffusive transport) largely overlapped. In addition, both PEI/DNA vectors and adenoviruses rapidly accumulated near the cell nucleus in primary neurons despite our finding that PEI/DNA move slower in neurites than in the cell body, whereas adenoviruses move with equal rates in either location. The intracellular trafficking pathways of PEI/DNA and adenoviruses, however, were substantially different. The majority of PEI/DNA trafficked through the endolysosomal pathway so as to end up in late endosomes/lysosomes (LE/Lys), whereas adenoviruses efficiently escaped endosomes. This result suggests that the sequestration of nonviral gene vectors within acidic vesicles may be a critical barrier to gene delivery to primary neurons in the central nervous system (CNS).     

Metallohelix vectors for efficient gene delivery via cationic DNA nanoparticles

The design of efficient and safe gene delivery vehicles remains a major challenge for the application of gene therapy. Of the many reported gene delivery systems, metal complexes with high affinity for nucleic acids are emerging as an attractive option. We have discovered that certain metallohelices—optically pure, self-assembling triple-stranded arrays of fully encapsulated Fe—act as nonviral DNA delivery vectors capable of mediating efficient gene transfection. They induce formation of globular DNA particles which protect the DNA from degradation by various restriction endonucleases, are of suitable size and electrostatic potential for efficient membrane transport and are successfully processed by cells. The activity is highly structure-dependent—compact and shorter metallohelix enantiomers are far less efficient than less compact and longer enantiomers.     

Intramembranous particles are clustered on microvillus membrane vesicles

Many intramembranous particles in pig jejunal microvillus membranes cluster during cell disruption and membrane vesiculation with the MgCl2 aggregation technique (Hauser, H., Howell, K., Dawson, R.M.C. and Bowyer, D.E. (1980) Biochim. Biophys. Acta 602, 567-577). Isolated brush borders and purified microvillus membrane vesicles were jet-frozen and examined by freeze-fracture electron microscopy. From 30 to 60% of purified vesicles exhibited no intramembranous particles on their fracture face and 22-39% exhibited clustered or aggregated intramembranous particles. Only 6-15% of the vesicles exhibited the random distribution of intramembranous particles that is characteristic of intact enterocytes. Aggregation was not reversed after dialysis to remove divalent cations. Prior freezing of tissue or vesicles (-70 degrees C) gave the same results as fresh unfrozen material. Heterogeneity of microvillus vesicles may occur among the vesicles generated from a single microvillus.     

Low molecular weight polyethylenimine grafted N-maleated chitosan for gene delivery: properties and in vitro transfection studies

To develop chitosan-based efficient gene vectors, chitosans with different molecular weights were chemically modified with low molecular weight polyethylenimine. The molecular weight and composition of polyethylenimine grafted N-maleated chitosan (NMC-g-PEI) copolymers were characterized using gel permeation chromatography (GPC) and (1)H NMR, respectively. Agarose gel electrophoresis assay showed that NMC-g-PEI had good binding ability with DNA, and the particle size of the NMC-g-PEI/DNA complexes was 200-400 nm, as determined by a Zeta sizer. The nanosized complexes observed by scanning electron microscopy (SEM) exhibited a compact and spherical morphology. The NMC-g-PEI copolymers showed low cytotoxicity and good transfection activity, comparable to PEI (25 KDa) in both 293T and HeLa cell lines, except for NMC 50K-g-PEI. The results indicated that the molecular weight of NMC-g-PEI has an important effect on cytotoxicity and transfection activity, and low molecular weight NMC-g-PEI has a good potential as efficient nonviral gene vectors.     

Contributions of unfrozen fraction and of salt concentration to the survival of slowly frozen human erythrocytes: Influence of warming rate

The general belief is that slow freezing injury is either the result of exposure to high salt concentrations or the result of excessive cell shrinkage. Increased salt concentration arises as increasing amounts of pure ice precipitate out of solution during freezing and cause the liquid-filled channels in which the cells are sequestered to dwindle in size. Cell shrinkage is an osmotic response to the concentration of external solutes. The consensus has been that the injury is related to the composition of the solution in these channels and not to the amount of residual liquid.Ordinarily, salt concentration and the amount of liquid in the unfrozen channels are reciprocally related; but they can be separated within limits by varying the total concentration of solutes in the suspending medium while holding the mass ratio of additive to salt constant, and by then slowly freezing samples to various subzero temperatures, chosen to produce various molalities of salt, while holding the unfrozen fraction constant, or vice versa. We have recently reported (9) that when human red cells are frozen under these conditions and thawed rapidly, survival is more dependent on the unfrozen water fraction than it is on the salt concentration in that fraction. The present work compares these results with those obtained with slow thawing. While the general conclusion remains unaltered, slowly thawed cells were able to survive the freezing of a higher fraction of extracellular water than were rapidly thawed cells.Calculations were made of the changes in cell volume during the equilibration with glycerol and the subsequent freezing involved in these experiments. Cell size and cell solute concentration were found to be independent of the fraction of unfrozen extracellular water, but cell survival was strongly dependent on that fraction. If applicable to other than human red cells, this finding is likely to require major modifications in current views of slow-freezing injury and its prevention.     

阳离子聚合物在非病毒基因转染中的研究进展

基因治疗为治疗先天性遗传疾病和严重后天获得性疾病提供了一条新途径.目前,基因载体分为两类:病毒载体和非病毒载体.病毒载体转染效率高,但由于某些病毒载体存在免疫原性、致癌性、宿主DNA插入整合等缺点,从而限制了它们的应用.非病毒载体具有价格低、制备简单、安全有效、无免疫原性等优点,成为基因载体研究的热点.阳离子多聚物是非病毒载体的典型代表.文中综述近年来阳离子多聚物作为基因载体的研究现状和进展,重点介绍了阳离子多聚物基因载体的分类和与DNA的相互作用和传递机制.     

Influence of cell concentration on the contribution of unfrozen fraction and salt concentration to the survival of slowly frozen human erythrocytes

We have shown previously that the survival of human red blood cells during slow freezing at 2% hematocrit is dependent more on the magnitude of the unfrozen fraction than on the salt concentration in that unfrozen fraction. In parallel, first Nei and more recently Pegg and colleagues have shown that survival is affected by the hematocrit of the suspension. Freezing at hematocrits above 30% becomes increasingly damaging. The present studies were designed to see whether there is a link between the two phenomena. Cells were suspended at nominal hematocrits of 0.4, 2, 8, 40, or 60% in five test solutions of glycerol-NaCl. The test solutions were of such composition that when frozen to a specified temperature, the magnitude of the unfrozen fraction differed but the NaCl concentration (ms) remained constant. At low hematocrits (0.4 to 8%), red cell survival was dependent predominantly on the unfrozen fraction and was relatively independent of the salt concentration in that fraction. This we term the "rheological" effect because injury appears to be related to interaction with the ice walls and perhaps is due to shearing forces or cell deformation. But at high hematocrits (40 or 60%), cell survival became dependent on both the unfrozen fraction and the salt concentration in that fraction. When freezing occurs at high hematocrits, increasing numbers of cells are presumably brought into contact with their neighbors. Furthermore, they are increasingly shrunken cells, for the progressive removal of liquid water, which is responsible for the crowding, also causes a rise in ms and the consequent osmotic shrinkage of cells. Our data suggest that at unfrozen fractions above those producing injurious rheological forces, the tight packing of less shrunken cells (i.e., high hematocrit, low ms) and the extensive shrinking of loosely packed cells (high ms, low hematocrit) are both quite innocuous. Injury becomes substantial only when extensively shrunken cells are brought into close contact (i.e., high ms, high hematocrit). At high hematocrit the cells occupy a substantial fraction of the unfrozen space, and the water that they lose during slow freezing adds substantially to the volume of extracellular ice. Accordingly, we defined other measures of unfrozen fraction that include these perturbations. However, we found that the conclusions on the relation between survival, unfrozen fraction, and hematocrit were not affected by the method of expressing the unfrozen fraction. Freezing at high hematocrit to high ms and low values of unfrozen fraction is one way to produce contact between shrunken cells at low temperatures.(ABSTRACT TRUNCATED AT 400 WORDS)     

Caged DNA does not aggregate in high ionic strength solutions.

The assembly of DNA into compact particles that do not aggregate in physiologic salt solution occurs naturally in chromatin and viral particles but has been challenging to duplicate using artificial constructs. Cross-linking amino-containing polycations in the presence of DNA with bisimidoester cross-linker leads to the formation of caged DNA particles that are stable in salt solutions. This first demonstration of caged DNA provides insight into how natural condensation processes avoid aggregation and a promising avenue for developing nonviral gene therapy vectors.     

Freeze-etching study on membrane ultrastructural changes caused by freezing: cooling rate-dependent intramembrane particle aggregation in erythrocyte stripped ghosts

The changes of membrane ultrastructures by freezing stresses were examined on stripped ghosts which were made by removing almost all peripheral membrane proteins from human erythrocyte membranes. By freezing these stripped ghost membranes showed cooling rate-dependent intramembrane particle (IMP) aggregation. With the cooling rates at and faster than 30,000 degrees C/min, their IMPs were evenly distributed on the fracture faces. However, cooling rates at and slower than 8000 degrees C/min resulted in IMP aggregation. The degree of IMP aggregation increased in parallel with decreasing cooling rates. Without freezing, the IMP aggregation in stripped ghosts could be induced by exposing these ghosts to hypertonic salt solutions, but lowering the temperature did not affect IMP aggregation. The cooling rate-dependent IMP aggregation during freezing was suppressed by adding cryoprotective agents which were known to reduce the salt concentration of the medium during freezing. It is suggested that the IMP aggregation in stripped ghosts by freezing occurs by exposure to concentrated salt solutions during freezing. This result indicates the possibility that IMP aggregation may arise during slow freezing of some biomembranes as a result of an increase in salt concentration rather than as a result of reduction in temperature.     

The role of surface chemistry-induced cell characteristics on nonviral gene delivery to mouse fibroblasts

ABSTRACT: BACKGROUND: Gene delivery approaches serve as a platform to modify gene expression of a cell population with applications including functional genomics, tissue engineering, and gene therapy. The delivery of exogenous genetic material via nonviral vectors has proven to be less toxic and to cause less of an immune response in comparison to viral vectors, but with decreased efficiency of gene transfer. Attempts have been made to improve nonviral gene transfer efficiency by modifying physicochemical properties of gene delivery vectors as well as developing new delivery techniques. In order to further improve and understand nonviral gene delivery, our approach focuses on the cell-material interface, since materials are known to modulate cell behavior, potentially rendering cells more responsive to nonviral gene transfer. In this study, self-assembled monolayers of alkanethiols on gold were employed as model biomaterial interfaces with varying surface chemistries. NIH/3T3 mouse fibroblasts were seeded on the modified surfaces and transfected using either lipid- or polymer- based complexing agents. RESULTS: Transfection was increased in cells on charged hydrophilic surfaces presenting carboxylic acid terminal functional groups, while cells on uncharged hydrophobic surfaces presenting methyl terminations demonstrated reduced transfection for both complexing agents. Surface--induced cellular characteristics that were hypothesized to affect nonviral gene transfer were subsequently investigated. Cells on charged hydrophilic surfaces presented higher cell densities, more cell spreading, more cells with ellipsoid morphologies, and increased quantities of focal adhesions and cytoskeleton features within cells, in contrast to cell on uncharged hydrophobic surfaces, and these cell behaviors were subsequently correlated to transfection characteristics. CONCLUSIONS: Extracellular influences on nonviral gene delivery were investigated by evaluating the upregulation and downregulation of transgene expression as a function of the cell behaviors induced by changes in the cells' microenvronments. This study demonstrates that simple surface modifications can lead to changes in the efficiency of nonviral gene delivery. In addition, statistically significant differences in various surface-induced cell characteristics were statistically correlated to transfection trends in fibroblasts using both lipid and polymer mediated DNA delivery approaches. The correlations between the evaluated complexing agents and cell behaviors (cell density, spreading, shape, cytoskeleton, focal adhesions, and viability) suggest that polymer-mediated transfection is correlated to cell morphological traits while lipid-mediated transfection correlates to proliferative characteristics.     

Preparation and in vitro evaluation of novel lipopeptide transfection agents for efficient gene delivery

Gene therapy by delivery of nonviral expression vectors is highly desirable, due to their safety, stability, and suitability for production as bulk pharmaceuticals. However, low transfection efficiency remains a limiting factor in application on nonviral gene delivery. Despite recent advances in the field, there are still major obstacles to overcome. In an attempt to construct more efficient nonviral gene delivery vectors, we have designed a series of novel lipopeptide transfection agents, consisting of an alkyl chain, one cysteine, 1 to 4 histidine and 1 to 3 lysine residues. The lipopeptides were designed to facilitate dimerization (by way of the cysteine residues), DNA binding at neutral pH (making use of charged lysine residues), and endosomal escape (by way of weakly basic histidine residues). DNA/lipopeptide complexes were evaluated for their biophysical properties and transfection efficiencies. The number and identity of amino acids incorporated in the lipopeptide construct affected their DNA/lipopeptide complex forming capacity. As the number of lysine residues in the lipopeptide increased, the DNA complexes formed became more stable, had higher zeta potential (particle surface charge), and produced smaller mean particle sizes (typically 110 nm at a charge ratio of 5.0 and 240 nm at a charge ratio of 1.0). The effect of inclusion of histidines in the lipopeptide moiety had the opposite effect on complex formation to lysine, but was necessary for high transfection efficiency. In vitro transfection studies in COS-7 cells revealed that the efficiency of gene delivery of the luciferase encoding plasmid, pCMV-Luc, mediated by all the lipopeptides, was much higher than poly(L-lysine) (PLL), which has no endosomal escape system, and in two cases was slightly higher than that of branched polyethylenimine (PEI). Lipopeptides with at least two lysine residues and at least one histidine residue produced spontaneous transfection complexes with plasmid DNA, indicating that endosomal escape was achieved by incorporation of histidine residues. These low molecular weight peptides can be readily synthesized and purified and offer new insights into the mechanism of action of transfection complexes.     

The process of freezing and the mechanism of damage during hepatic cryosurgery

Experiments were performed to correlate the structures of liver tissue frozen during cryosurgery, liver frozen at various constant cooling rates, and unfrozen, dried normal liver. The results show that during freezing of tissue ice forms and propagates along the vascular system, expanding during freezing at low cooling rates. This expansion occurs over most of the region frozen during cryosurgery and may be one of the mechanisms of damage to tissue during cryosurgery.     

Nucleofection-based gene targeting in human pre-B cells

Electroporation is a powerful and convenient means for transfection of nonviral vectors into mammalian cells, providing an essential tool for numerous applications including gene targeting via homologous recombination. Recent evidence clearly suggests that high-efficiency gene transfer can be achieved in most cell lines by nucleofection, an electroporation-based transfection method that allows transfected vectors to directly enter the nucleus. In this paper, we analyze the effectiveness of nucleofection for gene targeting using human pre-B cells. For this, we tested 93 different transfection conditions, and found several conditions that gave high (~ 80%) transfection efficiency with low cytotoxicity (~ 70% survival rate). Remarkably, under the optimal nucleofection conditions, the gene-targeting efficiency was ~ 2-5-fold higher than that achieved with conventional electroporation methods. We also found that nucleofection conditions with high transfection efficiency and low cytotoxicity tend to provide high gene-targeting efficiency. Our results provide significant implications for gene targeting, and suggest that nucleofection-based nonviral gene transfer is useful for systematic generation of human gene-knockout cell lines.     

Polymer‐coated viral vectors: hybrid nanosystems for gene therapy

The advantages and critical aspects of nanodimensional polymer‐coated viral vector systems potentially applicable for gene delivery are reviewed. Various viral and nonviral vectors have been explored for gene therapy. Viral gene transfer methods, although highly efficient, are limited by their immunogenicity. Nonviral vectors have a lower transfection efficiency as a result of their inability to escape from the endosome. To overcome these drawbacks, novel nanotechnology‐mediated interventions that involve the coating or modification of virus using polymers have emerged as a new paradigm in gene therapy. These alterations not only modify the tropism of the virus, but also reduce their undesirable interactions with the biological system. Also, co‐encapsulation of other therapeutic agents in the polymeric coating may serve to augment the treatment efficacy. The viral particles can aid endosomal escape, as well as nuclear targeting, thereby enhancing the transfection efficiency. The integration of the desirable properties of both viral and nonviral vectors has been found beneficial for gene therapy by enhancing the transduction efficiency and minimizing the immune response. However, it is essential to ensure that these attempts should not compromise on the inherent ability of viruses to target and internalize into the cells and escape the endosomes.     

Effects of structure of polyamidoamine dendrimer on gene transfer efficiency of the dendrimer conjugate with alpha-cyclodextrin

To improve gene transfer activity of a new nonviral vector, a polyamidoamine dendrimer (G2) conjugate with alpha-cyclodextrin (alpha-CDE conjugate (G2)), we prepared alpha-CDE conjugates with dendrimer having different generations (G3 and G4), and their gene transfer activities were compared with those of alpha-CDE conjugate (G2) and TransFast, a novel transfection reagent. alpha-CDE conjugates (G2, G3, and G4) formed the complexes with pDNA, changing the zeta-potential and particle size of pDNA complexes and the protection of pDNA from DNase I in a charge ratio-dependent manner, although their differences at higher charge ratios (vector/pDNA) were small. The gene transfer activity of alpha-CDE conjugates (G2, G3, and G4) was higher than that of the corresponding dendrimer alone in NIH3T3 and RAW264.7 cells. Of these CDE conjugates, alpha-CDE conjugate (G3) had a superior gene transfer activity which was comparable to that of TransFast in NIH3T3 cells. The intracellular distribution of pDNA after application of the pDNA complex with alpha-CDE conjugate (G3) to NIH3T3 cells was different from that with dendrimer alone (G3), although the cellular association of pDNA was almost comparable among all vectors. alpha-CDE conjugate (G3) strongly interacted with a fluorescence probe, 2-(p-toluidinyl)-naphthalene-6-sulfonate (TNS), suggesting that the conjugate possesses the inclusion ability with biomembrane constituents such as phospholipids after transfection. These results suggest that alpha-CDE conjugates, particularly the G3 conjugate, could be novel nonviral gene transfer agents.     

Effect of particle size on the enzymatic hydrolysis of polysaccharides from ultrafine lignocellulose particles

The efficiency of the enzymatic hydrolysis of wood polysaccharides ground into ultrafine particles (UFPs) has been investigated. The content of reducing sugars (RS’s) in powdered raw materials and the yield of sugars during enzymatic hydrolysis have been shown to depend on the particle size. Laser interference microscopy and dynamic light scattering studies have shown that increasing the grinding time from 20 to 40 min resulted in the formation of particles ranging from 2 to 200 nm in size. Enzymatic hydrolyzates of UFPs mostly contained glucose and galactose. The grinding intensity (mill rotation rate) and time had a significant effect on the extent of the enzymatic hydrolysis of wood.     

Effect of particle size on the enzymatic hydrolysis of polysaccharides from ultrafine lignocellulose particles

The efficiency of the enzymatic hydrolysis of wood polysaccharides ground into ultrafine particles (UFPs) has been investigated. The content of reducing sugars (RS's) in powdered raw materials and the yield of sugars during enzymatic hydrolysis have been shown to depend on the particle size. Laser interference microscopy and dynamic light scattering studies have shown that increasing the grinding time from 20 to 40 min resulted in the formation of particles ranging from 2 to 200 nm in size. Enzymatic hydrolyzates of UFPs mostly contained glucose and galactose. The grinding intensity (mill rotation rate) and time had a significant effect on the extent of the enzymatic hydrolysis of wood.     

Synthesis and formulation of neoglycolipids for the functionalization of liposomes and lipoplexes

Novel carbohydrate-based agents for the stabilization of ternary liposome:mu:DNA (LMD) nonviral vector systems are described. LMD vector systems comprise plasmid DNA (pDNA; D,7.5 kb) expressing a reporter gene (in this instance beta-galactosidase expressing gene) that is precondensed with the adenoviral core peptide mu (mu, M; MRRAHHRRRRASHRRMRGG) and then further packaged by means of DC-Chol:DOPE (3:2; m/m) cationic liposomes. Final optimized lipid:mu:pDNA ratio is typically 12:0.6:1 (w/w/w). We report the synthesis of a series of nine neoglycolipids prepared by coupling completely unprotected sugar monomers or oligomers (mannose, glucose, galactose, glucuronic acid, maltose, lactose, maltotriose, maltotetraose, and maltoheptaose) through their reducing-residue termini to an aminoxy-functionalized cholesterol-based lipid. Characterization of these novel neoglycolipids by (1)H NMR reveals that the coupling reaction has a major configurational preference for the beta-anomer. Unusually, even mannose coupling results in a neoglycolipid product with a predominantly beta-anomeric conformation (>85%). Formulation of neoglycolipids into LMD vector systems by incubation of LMD particles with neoglycolipid micelles results in the formation of a range of potential stabilized-LMD (sLMD) vector systems. Those potential sLMD systems prepared with longer chain neoglycolipids are found to have enhanced stabilities, with respect to aggregation in high ionic strength buffers, and enhanced transfection efficacies in comparison to the transfection properties of the naked first generation LMD vector system (i.e., gene delivery and expression). By contrast, when LMD vector systems are incubated with poly(ethylene glycol) DSPE-PEG micelles, resulting PEG-LMD vector systems are very stable with respect to colloidal instablility and aggregation in high ionic strength buffers and in serum, but are completely refractory to transfection. These data suggest that oligosaccharides could represent an alternative to PEG as a stealth polymer able to stabilize synthetic nonviral vector systems in some fluids but without impairing transfection efficiency. Furthermore, sLMD systems prepared with longer chain neoglycolipids appear to have sufficient useful characteristics to form the basis of viable second-generation LMD vector systems after further development.     

The role of the maltodextrin-binding site in determining the transport properties of the LamB protein

We have examined by the liposome swelling technique the permeability properties of the modified LamB proteins isolated from mutants of Escherichia coli K12 with altered affinities toward starch and/or maltose (Ferenci, T., and Lee, K-S. (1982) J. Mol. Biol. 160, 431-444). The results revealed the following. A mutant strain exhibiting a markedly lowered affinity toward starch produced a LamB protein that has lost the ability to permeate longer maltodextrins. This protein retained a nonspecific pore for a wide variety of small sugars. A mutant strain with partially reduced affinity for starch produced a LamB protein which still permeated maltodextrins, maltose, and non-maltose sugars but had also gained an ability to permit the diffusion of sucrose and raffinose; in this strain sucrose and raffinose could now compete for the starch-binding site. A mutant with enhanced affinity for both maltose and starch produced a protein which exhibited elevated rates of diffusion for longer maltodextrins but still permeated other small sugars. Two other mutants with altered affinities showed relatively minor changes in the diffusion of maltose and non-maltose sugars. It could be concluded from these studies that the LamB proteins form pores allowing the diffusion of a wide variety of monosaccharides irrespective of the presence or the absence of affinity of a binding site for maltodextrins. However, the presence of a sugar-binding site is crucial in determining the rate of the diffusion of maltodextrins or other oligosaccharides.