Cinzia Della Giovampaola

Envelope glycosylation determined by lectins in microscopy sections of Acinetobacter venetianus induced by diesel fuel.

It was suggested in a previous study that cells of Acinetobacter venetianus VE-C3 adhere to diesel fuel by synthesizing a capsular polysaccharide containing glucose and/or mannose. To study the fine structure of cells and localization of bacterial polysaccharide in the presence of diesel fuel, two lectins were used: ConA, an agglutinin from Canavalia ensiformis specific for mannose and/or glucose residues, and PNA, an agglutinin from Arachis hypogaea, for terminal galactose residues. The lectins were conjugated with electron dense ferritin for transmission electron microscopy (TEM) and with fluorescein isothiocyanate (FITC) for scanning confocal laser microscopy (SCLM). Samples were prepared by freeze substitution, which allows glycosylation to be determined in situ in thin sections of specimens. The distribution of glycosylation was imaged with and without treatment of specimens with their specific hapten (glucose and galactose). The glycosylation activity produced a polysaccharide capsule. Emulsified diesel fuel nanodroplets were observed at the cell envelope perimeter. Fine structure of vesicles consisted of polysaccharide and diesel fuel nanodroplets. Lectin blotting analysis showed ConA-positive glycoprotein with an apparent molecular mass of 22 kDa in the outer membrane. Its production was induced by diesel fuel. This glycoprotein was probably responsible for bioemulsifying activity at the cell envelope. Several other glycoproteins were positive for PNA lectin, the main constituent migrating with an apparent molecular weight of 17.8 kDa. However, they were all constitutive and probably involved in cell biofilm formation at the oil surface.

A fucose-containing O-glycoepitope on bovine and human nucleolin

In this paper, we demonstrate the existence and localization of fucosyl-containing O-glycoforms of nucleolin in cultured bovine endothelial cells (CVEC) and malignant cultured human A431 cells. The tool for this discovery was an antibody raised against gp273, a glycoprotein ligand for the sperm-egg interaction in the mollusc bivalve Unio elongatulus. The function and immunological properties of gp273 mainly depend on clustered Lewis-like, fucose-containing O-glycans. Here an anti-gp273 antibody was used to evaluate whether glycoepitopes similar to those of gp273 are part of potential ligands of selectins in endothelial cells. We found that anti-gp273 strongly and exclusively interacted with a 110 kDa protein in CVEC and A431 tumor cells. After partial purification, mass spectrometry identified the protein as nucleolin. This was confirmed by comparing anti-gp273 and anti-nucleolin antibody immunoblotting after nucleolin depletion. We confirmed that anti-gp273 binding to nuclear and extranuclear nucleolin was against a fucose-containing O-glycoepitope by immunoblot analysis of the protein after chemically removing O-glycans and by lectin-blot analysis of control and nucleolin-depleted samples. Using anti-gp273 IgG, we detected nucleolin on the plasma membrane and cytoplasm. O-Glycosylation may regulate the plethora of functions in which nucleolin is involved.

Formulation of liposomes functionalized with Lotus lectin and effective in targeting highly proliferative cells

BACKGROUND Liposomes, used to improve the therapeutic index of new and established drugs, have advanced with the insertion of active targeting. The lectin from Lotus tetragonolobus (LTL), which binds glycans containing alpha-1,2-linked fucose, reveals surface regionalized glycoepitopes in highly proliferative cells not detectable in normally growing cells. In contrast, other lectins localize the corresponding glycoepitopes all over the cell surface. LTL also proved able to penetrate the cells by an unconventional uptake mechanism. METHODS We used confocal laser microscopy to detect and localize LTL-positive glycoepitopes and lectin uptake in two cancer cell lines. We then constructed doxorubicin-loaded liposomes functionalized with LTL. Intracellular delivery of the drug was determined in vitro and in vivo by confocal and electron microscopy. RESULTS We confirmed the specific localization of Lotus binding sites and the lectin uptake mechanism in the two cell lines and determined that LTL-functionalized liposomes loaded with doxorubicin greatly increased intracellular delivery of the drug, compared to unmodified doxorubicin-loaded liposomes. The LTL-Dox-L mechanism of entry and drug delivery was different to that of Dox-L and other liposomal preparations. LTL-Dox-L entered the cells one by one in tiny tubules that never fused with lysosomes. LTL-Dox-L injected in mice with melanoma specifically delivered loaded Dox to the cytoplasm of tumor cells. CONCLUSIONS Liposome functionalization with LTL promises to broaden the therapeutic potential of liposomal doxorubicin treatment, decreasing non-specific toxicity. GENERAL SIGNIFICANCE Doxorubicin-LTL functionalized liposomes promise to be useful in the development of new cancer chemotherapy protocols.

Beta-actin deficiency with oxidative posttranslational modifications in Rett syndrome erythrocytes: insights into an altered cytoskeletal organization.

Beta-actin, a critical player in cellular functions ranging from cell motility and the maintenance of cell shape to transcription regulation, was evaluated in the erythrocyte membranes from patients with typical Rett syndrome (RTT) and methyl CpG binding protein 2 (MECP2) gene mutations. RTT, affecting almost exclusively females with an average frequency of 1∶10,000 female live births, is considered the second commonest cause of severe cognitive impairment in the female gender. Evaluation of beta-actin was carried out in a comparative cohort study on red blood cells (RBCs), drawn from healthy control subjects and RTT patients using mass spectrometry-based quantitative analysis. We observed a decreased expression of the beta-actin isoforms (relative fold changes for spots 1, 2 and 3: −1.82±0.15, −2.15±0.06, and −2.59±0.48, respectively) in pathological RBCs. The results were validated by western blotting and immunofluorescence microscopy. In addition, beta-actin from RTT patients also showed a dramatic increase in oxidative posttranslational modifications (PTMs) as the result of its binding with the lipid peroxidation product 4-hydroxy-2-nonenal (4-HNE). Our findings demonstrate, for the first time, a beta-actin down-regulation and oxidative PTMs for RBCs of RTT patients, thus indicating an altered cytoskeletal organization.

Abnormal N-glycosylation pattern for brain nucleotide pyrophosphatase-5 (NPP-5) in Mecp2-mutant murine models of Rett syndrome.

Neurological disorders can be associated with protein glycosylation abnormalities. Rett syndrome is a devastating genetic brain disorder, mainly caused by de novo loss-of-function mutations in the methyl-CpG binding protein 2 (MECP2) gene. Although its pathogenesis appears to be closely associated with a redox imbalance, no information on glycosylation is available. Glycoprotein detection strategies (i.e., lectin-blotting) were applied to identify target glycosylation changes in the whole brain of Mecp2 mutant murine models of the disease. Remarkable glycosylation pattern changes for a peculiar 50kDa protein, i.e., the N-linked brain nucleotide pyrophosphatase-5 were evidenced, with decreased N-glycosylation in the presymptomatic and symptomatic mutant mice. Glycosylation changes were rescued by selected brain Mecp2 reactivation. Our findings indicate that there is a causal link between the amount of Mecp2 and the N-glycosylation of NPP-5.

Identification of a novel, alpha2-fucosylation-dependent uptake system in highly proliferative cells

In this paper we describe a new structure present in highly proliferative cells and absent in cells with normal growth potential. We used cultured bovine venular endothelial cells (CVEC) as examples of high proliferation, and dermal fibroblasts of a primary culture as examples of normal proliferation. The structure, consisting of tubules radiating from the nuclear region to the tips of cell protrusions, was revealed by its strong positivity to the fucose-binding lectin from Lotus (LTL) that prefers glycans with alpha-1,2-linked fucose. Another fucose-binding lectin that prefers glycans with alpha-1,6-linked fucose was instead found to localize glycans exclusively in Golgi complexes. LTL binding sites were also found at the surface of CVEC in a restricted region close to the nucleus. The role of alpha-1,2-linked fucose in forming or maintaining the tubules was confirmed by the fact that down-regulation of the fucosyltransferases FUT1 and FUT2 resulted in disappearance of the tubular structure. LTL also proved able to penetrate the cells through the tubular structures up to the nuclear region and to inhibit proliferation. Endostatin was also found to massively penetrate the cells in the tubular structures in control cells but not in FUT1/2 depleted cells. In cells of a first passage primary culture of dermal fibroblasts the tubular LTL-positive structure was absent as well as the LTL-positive sites at the external surface, and both fucose-binding lectins were found to exclusively localize glycans in Golgi complexes. Tubules were again found progressively in fibroblasts derived from repeated passages, where faster growing cells predominate. Disappearance of LTL-positivity in Golgi complexes paralleled appearance of LTL-positive tubules. The role of Golgi complexes in forming the tubules is discussed.