Glycotargeting: Influence of the Sugar Moiety on Both the Uptake and the Intracellular Trafficking of Nucleic Acid Carried by Glycosylated Polymers

Nucleic acids (plasmids as well as oligonucleotides) used to specifically express or modulate the expression of a gene, must reach the cytosol and/or the nucleus. Several systems have been developed to increase their uptake and their efficiency. Glycosylated polylysines have been shown to specifically help nucleic acids to be taken up in cells expressing a given cell surface membrane lectin. However, it appeared that the efficiency of the imported nucleic acid was not directly related to the extent of the uptake. Indeed, some glycosylated polylysines bearing sugar moities which are poor ligands of the cell surface lectins of a given cell were found to be more efficient than those bearing better sugar ligands. The interpretation of this paradoxal result is discussed with regards to the nature of the compartment allowing the nucleic acid to cross the membrane and to be delivered in the cytosol on the one hand, and to the presence of intracellular lectins on the other hand.     

Endocytosis mediated by monocyte and macrophage membrane lectins — application to antiviral drug targeting

Sugar receptors, or membrane lectins, have been evidenced at the surface of various normal and tumour cells using fluoresceinylated neoglycoproteins (glycosylated bovine serum albumin (BSA)). By flow cytometry we have shown that macrophages bind and internalize mannosylated and 6-phosphomannosylated ligands in acidic compartments. Freshly isolated monocytes and U937, a promonocytic cell line, lack a mannose-specific receptor, but express mannose-6-phosphate (Man-6P) membrane lectin.Neoglycoproteins are potent drug carriers: muramyl dipeptide (MDP), an immunoactivator, when bound to Man-BSA or Man-6P-BSA, is 100 times more efficient than free MDP in activating macrophages; in vivo, it enables eradication of lung metastases in mice. Recently, neutral glycosylated biodegradable and non-immunogenic polymers, were synthesized and found to be as efficient as neoglycoproteins. Antiviral drug conjugates were more active than the free drug, inhibiting the multiplication of virus (herpes) in human macrophages in vitro.     

Lactosylated polyethylenimine for gene transfer into airway epithelial cells: role of the sugar moiety in cell delivery and intracellular trafficking of the complexes

BACKGROUND: As we have previously shown that lactosylated polyethylenimine (PEI) is the most efficient glycosylated PEI for gene transfer into human airway epithelial cells in primary culture, we have studied here the role of the lactose residue in the enhancement of gene transfer efficiency observed with lactosylated PEI as compared with unsubstituted PEI in immortalized (Sigma CFTE29o- cells) and primary human airway epithelial cells. METHODS AND RESULTS: After three transfections of 1 h performed daily, 60% of Sigma CFTE29o- cells were transfected with lactosylated PEI, whereas 25% of cells were transfected with unsubstituted PEI (p < 0.05). Cell viability was 1.8-fold greater with lactosylated PEI as compared with unsubstituted PEI (p < 0.05). As assessed by flow cytometry, the cellular uptake of lactosylated complexes was greater than that of complexes made with unsubstituted PEI (p < 0.05) and involved mostly a receptor-mediated endocytosis. The study of the intracellular trafficking in airway epithelial cells of complexes showed an endosomal and lysosomal accumulation of lactosylated complexes. In the presence of a proton pump inhibitor, the level of lactosylated and unsubstituted PEI-mediated gene expression was reduced more than 20-fold, whereas the cell viability increased to almost 100%. For both complexes, a nuclear localization was observed for less than 5% of intracellular complexes. CONCLUSIONS: Our results show that the greater gene transfer efficiency observed for lactosylated complexes may be attributed to a higher amount of lactosylated complexes incorporated by airway epithelial cells and a lower cytotoxicity that might be related to reduced endosomolytic properties. However, the lactose residues substituting the PEI did not promote the entry of the plasmid into the nucleus.     

Chain length of cationic alpha-helical peptide sufficient for gene delivery into cells.

To define the minimal peptide length needed for gene delivery into mammalian cells, we synthesized several peptides with shortened chain lengths from the amino-termini of the original amphiphilic peptides (4(6), Ac-LARL-LARL-LARL-LRAL-LRAL-LRAL-NH( 2,) and Hel 11-7, KLLK-LLLK-LWKK-LLKL-LK), which have been known to have gene transfer abilities into cells. Each synthetic peptide was studied for its ability to bind and aggregate with plasmid DNA and the structural change of the peptide caused by binding with the DNA to establish a relative in vitro gene transfection efficiency in COS-7 cells. As a result, the deletion of eight amino acid residues of 4(6) had little influence on their ability, whereas that of 12 amino acid residues remarkably reduced the abilities to make aggregates and transfer the DNA into the cell. In the case of the Hel 11-7 series peptides, deletion of amino acid residues caused a considerable reduction in abilities to bind and form aggregates with DNA and to transfer the DNA into cell in due order. In summary, 16 and 17 amino acid residues were sufficient to form aggregates with the DNA and transfer the DNA into the cells in the deletion series of 4(6) and Hel 11-7, respectively. Furthermore, it was indicated that reduction of membrane perturbation activity of the peptide-DNA complex due to deletion of the peptide chain length caused suppression of the transfection efficiency even if the complex was incorporated into the cells. Transfer of the complex to cytosol mediated by membrane perturbation activity of the peptide is an important step for efficient protein expression from its cDNA. The results of this study will make it easy to design and synthesize a functional gene carrier molecule such as a carbohydrate-modified peptide used in targeted gene delivery.     

胃癌细胞PHA、DBA、WGA受体的电镜定位

应用自制的Ｓｔｒｅｐｔａｖｉｄｉｎ－ｇｏｌｄ探针,在胃癌和非癌胃粘膜组织的超薄冰冻切片上,进行ＰＨＡ、ＤＢＡ、ＷＧＡ受体的电镜定位。结果显示,三种凝集素受体主要定位于胃癌细胞的粘液泡、细胞膜和内微囊腔面微绒毛,以及非癌胃粘膜细胞的膜相结构内。证实凝集素能与细胞内特定糖基结合,且胃癌细胞内某些凝集素受体结合位点明显多于非癌胃粘膜细胞。本文结果可为进一步探讨凝集素用于胃癌导向诊断和治疗的可行性,提供超微形态学依据。     

Characterization and biological implications of membrane lectins in tumor, lymphoid and myeloid cells

Complex carbohydrates and sugar receptors at the surface of eukaryotic cells are involved in recognition phenomena. Membrane lectins have been characterized, using biochemical, biological and cytological methods. Their biological activities have been assessed using labeled glycoproteins or neoglycoproteins. Specific glycoproteins or neoglycoproteins have been used to inhibit their binding capacity in both in vitro and in vivo experiments. In adults, lymphoid and myeloid cells as well as tumor cells grow in a given organ and eventually migrate and home in another organ; these phenomena are known as the homing process or metastasis, respectively. In specific cases, membrane lectins of endothelial cells recognize cell surface glycoconjugates of lymphocytes or tumor cells, while membrane lectins of lymphocytes and of tumor cells recognize glycoconjugates of extracellular matrices or of non-migrating cells. Therefore, membrane lectins are involved in cell-cell recognition phenomena. Membrane lectins are also involved in endocytosis and intracellular traffic of glycoconjugates. This property has been demonstrated not only in hepatocytes, fibroblasts, macrophages and histiocytes but also in tumor cells, monocytes, thyrocytes, etc. Upon endocytosis, membrane lectins are present in endosomes, whose luminal pH rapidly decreases. In cells such as tumor cells or macrophages, endosomes fuse with lysosomes; it is therefore possible to target cytotoxic drugs or activators, by binding them to specific glycoconjugates or neoglycoproteins through a linkage specifically hydrolyzed by lysosomal enzymes. In cells such as monocytes, the delivery of glycoconjugates to lysosomes is not active; in this case, it would be preferable to use an acid-labile linkage. Cell surface membrane lectins are developmentally regulated; they are present at given stages of differentiation and of malignant transformation. Cell surface membrane lectins usually bind glycoconjugates at neutral pH but not in acidic medium: their ligand is released in acidic specialized organelles; the internalized ligand may be then delivered into lysosomes, while the membrane lectin is recycled. Some membrane lectins, however, do bind their ligand in relatively acidic medium as in the case of thyrocytes. The presence of cell surface membrane lectins which recognize specific sugar moieties opens the way to interesting applications: for instance, isolation of cell subpopulations such as human suppressor T cells, targeting of anti-tumor or anti-viral drugs, targeting of immunomodulators or biological response modifiers.     

Glycosylphosphatidylinositol-anchored proteins are not required for crosslinking-mediated endocytosis or transfection of avidin bioconjugates into biotinylated cells

Even though glycosylphosphatidylinositol (GPI)-anchored proteins lack direct structural contact with the intracellular space, these ubiquitously expressed surface receptors activate signaling cascades and endocytosis when crosslinked by extracellular ligands. Such properties may be due to their association with membrane microdomains composed of glycosphingolipids, cholesterol and some signaling proteins. In this study, we hypothesize that GPI proteins may be required for crosslinking-mediated endocytosis of extracellular bioconjugates. To test this hypothesis, we first biotinylated the surface membranes of native K562 erythroleukemia cells versus K562 cells incapable of surface GPI protein expression. We then compared the entry of fluorescently labeled avidin or DNA condensed on polyethylenimine-avidin bioconjugates into the two biotinylated cell populations. Using fluorescence microscopy, nearly 100% efficiency of fluorescent avidin endocytosis was demonstrated in both cell types over a 24 h period. Surprisingly, plasmid DNA transfer was slightly more efficient among the biotinylated GPI-negative cells as measured by the expression of green fluorescence protein. Our findings that GPI proteins are not required for the endocytosis of avidin bioconjugates into biotinylated cells suggest that endocytosis associated with general membrane crosslinking may be due to overall reorganization of the membrane domains rather than GPI protein-specific interactions.     

Possible mechanism of polycation liposome (PCL)-mediated gene transfer

A novel gene transfer system utilizing polycation liposomes (PCLs), obtained by modifying liposomes with cetyl polyethylenimine (PEI), was previously developed (Gene Ther. 7 (2002) 1148). PCLs show notable transfection efficiency with low cytotoxicity. However, the mechanism of PCL-mediated gene transfer is still unclear. In this study, we examined the intracellular trafficking of PCL-DNA complexes by using HT1080 cells, fluorescent probe-labeled materials, and confocal laser scan microscopy. We found that the PCL-DNA complexes were taken up into cells by the endosomal pathway, since both cellular uptake of the complex and gene expression were blocked by wortmannin, an inhibitor of this pathway. We also observed that the plasmid DNA and cetyl PEI complex became detached from the PCL lipids and was preferentially transferred into the nucleus in the form of the complex, whereas the PCL lipids remained in the cytoplasmic area, possibly in the endosomes. In fact, nigericin, which dissipates the pH gradient across the endosomal membrane, inhibited the detachment of lipids from the PCL-DNA complex and subsequent gene expression. Taken together, our data indicate the following mechanism for gene transfer by PCLs: PCLs effectively transfer DNA to endosomes and release cetyl PEI-DNA complexes into the cytosol. Furthermore, cetyl PEI also contributes to gene entry into the nucleus.     

超正电荷绿荧光蛋白+36GFP作为核酸载体的细胞穿透性分析

旨在通过原核表达纯化超正电荷绿色荧光蛋白+36GFP,研究其与核酸的结合作用及作为核酸载体的细胞转导功能。将pET+36GFP-HA2质粒转化到大肠杆菌BL21(DE3)菌株中,然后表达纯化+36GFP蛋白。将得到的目的蛋白在特定浓度下分别转导293细胞、HepG2细胞、A549细胞和B16细胞,流式细胞仪检测+36GFP的转导效率;+36GFP蛋白(100 nmol/L)转导A549细胞,激光共聚焦显微镜观察结果;将+36GFP蛋白与质粒DNA按不同比例孵育,凝胶阻滞实验检测+36GFP与DNA的结合能力;激光共聚焦显微镜和流式细胞仪检测+36GFP蛋白携带质粒DNA转导细胞后报告基因的表达。结果显示,+36GFP蛋白具有较高的细胞转导效率,且随浓度升高转导效率增加,呈浓度依赖性。凝胶阻滞实验显示,+36GFP能够与质粒DNA结合,阻滞DNA在凝胶中迁移,且呈现一定的浓度依赖性。+36GFP包裹质粒转导细胞后,可高效携带质粒DNA转导进入细胞,使质粒报告基因得到表达。本研究成功表达纯化了+36GFP蛋白,证实该蛋白具有较高的细胞转导效率,可将外源核酸携带入细胞使外源基因得到表达。     

Gene transfer with poly-melittin peptides

The 26 amino acid hemolytic melittin peptide was converted into a gene transfer peptide that binds to DNA and polymerized through disulfide bond formation. Melittin analogues were synthesized by the addition of one to four Lys repeats at either the C- or the N-subterminal end along with terminal Cys residues. Melittin analogues were able to bind and polymerize on plasmids resulting in the formation of DNA condensates. In the absence of DNA, melittin analogues retained their red blood cell hemolytic potency but were inactive when bound to plasmid DNA. The in vitro gene transfer efficiency mediated by poly-melittin analogues was equivalent to PEI in HepG2 cells. Attempts to truncate portions of either of the two melittin alpha-helices resulted in concurrent loss of hemolytic potency and gene transfer efficiency. The results demonstrate the ability to transform melittin into a gene transfer peptide by transiently masking its membrane lytic activity by the addition of Lys and Cys residues to promote DNA binding and polymerization.     

Peptidoglycan recognition proteins kill bacteria by activating protein-sensing two-component systems

Mammalian peptidoglycan recognition proteins (PGRPs), similar to antimicrobial lectins, bind the bacterial cell wall and kill bacteria through an unknown mechanism. We show that PGRPs enter the Gram-positive cell wall at the site of daughter cell separation during cell division. In Bacillus subtilis, PGRPs activate the CssR-CssS two-component system that detects and disposes of misfolded proteins that are usually exported out of bacterial cells. This activation results in membrane depolarization, cessation of intracellular peptidoglycan, protein, RNA and DNA synthesis, and production of hydroxyl radicals, which are responsible for bacterial death. PGRPs also bind the outer membrane of Escherichia coli and activate the functionally homologous CpxA-CpxR two-component system, which kills the bacteria. We exclude other potential bactericidal mechanisms, including inhibition of extracellular peptidoglycan synthesis, hydrolysis of peptidoglycan and membrane permeabilization. Thus, we reveal a previously unknown mechanism by which innate immunity proteins that bind the cell wall or outer membrane exploit the bacterial stress defense response to kill bacteria.     

Glycoproteins of the Chromaffin Granule Membrane: Separation by Two-Dimensional Electrophoresis and Identification by Lectin Binding

The proteins of highly purified chromaffin-granule membranes were separated by one- or two-dimensional electrophoresis, then transferred to nitrocellulose sheets; glycosylation was investigated by binding of several different radioiodinated lectins. Over 20 different glycosylated components were identified; comparison with mitochondrial and microsomal fractions suggested that most of the major glycoproteins are genuine components of the chromaffin granule membrane, rather than contaminants originating in other organelles. Two-dimensional electrophoresis revealed heterogeneity within several of the glycoproteins, and this is ascribed to differences in the state of glycosylation, on the basis of shifts in electrophoretic mobility produced by treatment with neuraminidase. Neuraminidase treatment of chromaffin granule membranes also enhances the binding of many lectins. The identities of the lectin-binding bands are discussed: neither cytochrome b561 nor the F1-like ATPase appears to be glycosylated. Chromogranin A, although a glycoprotein, does not bind any of the lectins tested, but a number of concanavalin-A binding proteins, as well as dopamine beta-hydroxylase, are present in the chromaffin granule lysate.     

The Streptococcus gordonii platelet binding protein GspB undergoes glycosylation independently of export

The binding of bacteria and platelets may play a central role in the pathogenesis of infective endocarditis. Platelet binding by Streptococcus gordonii strain M99 is predominantly mediated by the 286-kDa cell wall-anchored protein GspB. This unusually large protein lacks a typical amino-terminal signal peptide and is translocated from the cytoplasm via a dedicated transport system. A 14-kb segment just downstream of gspB encodes SecA2 and SecY2, two components of the GspB-specific transport system. The downstream segment also encodes several putative glycosyl transferases that may be responsible for the posttranslational modification of GspB. In this study, we compared the abilities of M99 and two GspB(-) mutant strains to bind various lectins. GspB was found to have affinity for lectins that bind N-acetylglucosamine. We also examined variant forms of GspB that lack a carboxy-terminal cell wall-anchoring domain and thus are free of covalent linkage to cell wall peptidoglycan. Like native GspB, these truncated proteins appear to be heavily glycosylated, as evidenced by migration during sodium dodecyl sulfate-polyacrylamide gel electrophoresis with an apparent molecular mass >100 kDa in excess of the predicted mass, negligible staining with conventional protein stains, and reactivity with hydrazide following periodate oxidation. Furthermore, analysis of the carbohydrate associated with the GspB variants by high-pH anion-exchange chromatography revealed the presence of approximately 70 to 100 monosaccharide residues per GspB polypeptide (primarily N-acetylglucosamine and glucose). Analysis of GspB in protoplasts of secA2 or secY2 mutant strains, which do not export GspB, indicates that GspB is glycosylated in the cytoplasm of these strains. The combined data suggest that the native GspB is a glycoprotein and that it may be glycosylated prior to export.     

Endogenous lectins as mediators of tumor cell adhesion

Endogenous carbohydrate-binding proteins have been found in various normal tissues and cells. Although lectins with different sugar-binding specificities have been described, the most prevalent ones are those that bind beta-galactosides. The ability of some normal and malignant cells to bind exogenous carbohydrate-containing ligands suggested that lectinlike activity is associated with the cell surface and that carbohydrate-binding proteins might mediate intercellular recognition and adhesion. We found that extracts of various cultured murine and human tumor cells exhibit a galactoside-inhibitable hemagglutinating activity. This activity was associated with two proteins of molecular weights of 34,000 and 14,500 daltons, which were purified by affinity chromatography by using immobilized asialofetuin. That these lectins are present on the cell surface was indicated by the binding of monoclonal antilectin antibodies to the surface of various tumor cells and by the immunoprecipitation of 125I-labeled lectins from solubilized cell-surface iodinated cells by polyclonal antilectin antibodies. That these cell surface lectins are functional was demonstrated by the ability of the galactose-terminating asialofetuin to enhance cell aggregation and of asialofetuin glycopeptides to block this homotypic aggregation as well as to suppress cell attachment to substratum, and by the inhibition of both asialofetuin-induced cell aggregation and cell attachment to substratum by the binding of monoclonal antilectin antibodies to the cell surface. These findings implicate cell surface lectins as mediators of cell-cell and cell-substratum adhesion. Some of these cellular interactions might be important determinants of tumor cell growth and metastasis.     

Lectins of oil-seed flax plants exposed to abiotic stress

The seedlings of six cultivars of oil-seed flax (Linum humile Mill.) differing in the extent of adaptation to abiotic stresses (hypo- and hyperthermia, osmotic stress, and salinity) were used to assess hemag-glutination activity and carbohydrate specificity of total lectin preparations extracted from various cell compartments. In the course of adaptation of plants resistant to hyperthermia, osmotic stress and salinity, we observed a considerable rise in the coefficient of activity of membrane lectins, whereas the adaptation to hypothermia elevated the coefficient of activity of cell wall lectins. As to total soluble lectins, the adaptation of flax plants was associated with the changes in the range of their carbohydrate specificity. For instance, following the adaptation to hyperthermia, they were found to bind glucose and glucosamine, to osmotic stress—mannose and xylose, to salinity—galactose, glucose, and glucosamine; after cold resistance was developed, total soluble lectins were found to recognize lactose and fructose. It was concluded that lectins may participate in specific adaptation of flax plants to various abiotic stress factors.     

Human keratinocyte membrane lectins: characterization and modulation of their expression by cytokines

Summary— In an attempt to identify cell surface molecules involved in recognition phenomena between cells such as keratinocytes and melanocytes and putatively target biological responses modifiers to keratinocytes, we undertook the detection of cell surface sugar specific receptors: membrane lectins. Keratinocyte membrane lectins were found to bind synthetic glycoproteins (neoglycoproteins) carrying either α-l -fucosyl or α-l -rhamnosyl residues. Fluorescence microscopy observations indicate that cultured keratinocytes are able to bind these two neoglycoproteins while frozen sections of human skin labelled with neoglycoprotein-coated covaspheres show that the selectivity of the binding to keratinocytes is restricted to α-l -rhamnosyl-BSA. Keratinocytes were adapted to grow on collagen; harvesting conditions allowing the analysis of keratinocytes by flow cytometry are described. This technique allows the quantification of the binding at 4°C, and the estimation of the endocytosis of F-, neoglycoproteins: F-, α-l -Rha-BSA and F-, α-l -Fuc-BSA were efficiently internalized. Thereafter, α-l -rhamnose-substituted liposomes containing 5-(6)carboxyfluorescein were prepared in order to follow the delivery of the fluorescent dye into cells. This was measured both by flow cytometry and by spectrofluorimetry. The expression of surface lectins was checked upon action of cytokines (IL₁α, IL₁β, IL₂ and TNF) which are known as biological response modifiers of keratinocytes.     

Cationic lipid-mediated gene transfer: Analysis of cellular uptake and nuclear import of plasmid DNA

Cationic lipids are widely used for gene transfer in vitro and show promise as vectors for in vivo gene therapy applications. However, there is limited understanding of the cellular mechanisms involved in nonviral gene transfer. We investigated two major steps that could be limiting barriers to cationic lipid-mediated gene transfer in vitro. We used a fluorescent plasmid to study the cellular uptake and the intracellular fate of lipoplexes during in vitro transfection of fibroblast cells and found that 100% of the cells take up lipoplexes. The intracellular staining observed with lipoplexes was clearly different from that obtained with endocytosed fluorescent dextran. This suggests that cells readily take up lipoplexes by a mechanism that could be different from endocytosis in our conditions. However, the escape of DNA from intracellular vesicles could be a major limiting barrier to gene transfer. Direct injection of plasmid DNA into the nucleus and cytoplasm of cells indicated that DNA traffic from the cytoplasm to the nucleus might be also an important limiting step.     

Transfer of the Ti plasmid from Agrobacterium tumefaciens into Escherichia coli cells

We have screened strains of Agrobacterium tumefaciens for spontaneous mutants showing constitutive transfer of the nopaline Ti plasmid pTiC58 during conjugation. The Ti plasmid derivatives obtained could be transferred not only to A. tumefaciens but also to E. coli cells. The Ti plasmid cannot survive as a freely replicating plasmid in E. coli, but it can occasionally integrate into the E. coli chromosome. However, insertion in tandem of plasmids carrying fd replication origins (pfd plasmids) into the T-DNA provides an indicator for all transfer events into E. coli cells, providing fd gene 2 protein is present in these cells. This viral protein causes the excision of one copy of the pfd plasmid and allows its propagation in the host cell. By using this specially designed Ti plasmid, which was also made constitutive in transfer functions, we found plasmid exchange among A. tumefaciens strains and between A. tumefaciens and E. coli cells to be equally efficient. A Ti plasmid with repressed transfer functions was transferred to E. coli with a rate similar to the low frequency at which it was transferred to A. tumefaciens. The expression of transfer functions of plasmid RP4 either in A. tumefaciens or in E. coli did not increase the transfer of the Ti plasmid into E. coli cells, nor did the addition of acetosyringone, an inducer of T-DNA transfer to plant cells. The results show that A. tumefaciens can transfer the Ti plasmid to E. coli with the same efficiency as within its own species. Conjugational transmission of extrachromosomal DNA like the narrow-host-range Ti plasmid may often not only occur among partners allowing propagation of the plasmid, but also on a 'try-all' basis including hosts which do not replicate the transferred DNA.     

Lectin enhancement of the lipofection efficiency in human lung carcinoma cells

Poor transfection efficiency of human lung carcinoma cells by lipofection begs further development of more efficient gene delivery strategies. The purpose of this study was to determine whether lectins can improve the lipofection efficiency in lung carcinoma cells. A549, Calu3, and H292 cells grown to 90% confluence were transfected for 18 h with a plasmid DNA containing a beta-galactosidase reporter gene (pCMVlacZ) using lipofectin plus a lectin as the vector. Ten different lectins, which exhibit a wide range of carbohydrate-binding specificities, were examined for their abilities to enhance the efficiency of lipofection. The transfected cells were assessed for transfection efficiency by beta-galactosidase activity (units/microg protein) and % blue cells following X-Gal stain. Lipofectin supplemented with Griffonia simplicifolia-I (GS-I) yields largest enhancement of the lipofection efficiency in A549 and Calu3 cells (5.3- and 28-fold, respectively). Maackia amurensis gives the largest enhancement (6.5-fold) of lipofection efficiency in H292 cells. The transfection efficiency correlates with the amounts of DNA delivered to the nucleus. Binding of FITC-labeled GS-I and the enhancement of the lipofection efficiency by GS-I were inhibited by alpha-methyl-D-galactopyranoside, indicating an alpha-galactoside-mediated gene transfer to lung carcinoma cells. We conclude that lectin-facilitated lipofection is an efficient gene delivery strategy. Employment of cell type-specific lectins may allow for efficient cell type-specific gene targeting.     

From extracellular to intracellular: the establishment of a symbiosis.

The colonization of host cells by modern symbionts is surveyed. The morphological distinction between extracellular and intracellular symbionts is not sharp, and the various kinds of association can be arranged in a graded series of increasing morphological integration of the symbiont into the host cell. Apart from some aggressive parasitic infections, the great majority of symbionts are enclosed by a host membrane in a vacuole. Those not enclosed in a host vacuole usually cannot be cultivated outside the cell. It is therefore surmised that encirclement by a vacuolar membrane would only disappear, if at all, in the later stages of the evolution of intracellular symbiosis. Recognition mechanisms between host and symbiont occur, but have been little studied. In some associations, recognition at surface contact occurs, and there is evidence for the involvement of lectins in certain cases. In other associations, recognition may occur wholly or in part after the entry of symbiont into host cells. After entry, special mechanisms for the biotrophic transfer of nutrients from symbiont to host develop. Both the symbiont population size and its rate of increase are strictly regulated by the host cell; symbiont metabolism may be controlled likewise. Rates of evolution of intracellular symbionts are probably very rapid, owing in part to responses of the host cell to its symbiont.