Yanina Ditamo

Interaction between Gonadal Steroids and Neuroimmune System in Acute Experimental Autoimmune Encephalomyelitis (EAE) in Wistar Rats

Experimental autoimmune encephalomyelitis (EAE) is an inflammatory disease of the CNS mediated by autoreactive T lymphocytes directed against myelin antigens. Since neuroendocrine-immune dysfunction appears to contribute to the pathogenesis of autoimmune diseases, the present work was designed to study the effect of changes in the endocrine system on the development of acute EAE and the immune response against myelin basic protein (MBP). Intact and sham males and intact female Wistar rats showed the most severe clinical symptoms (acute period) 12–14 days post-inoculation (dpi). Then, they began gradually to recover, regaining the total ability to walk by 15–17 dpi. Male Wistar rats with altered levels of gonadal hormones by surgical castration showed an onset of the symptoms retarded 2–3 days with respect to the other EAE groups, showing neuropathological symptoms up to 27–28 dpi, and remaining with lower body weight even at 40 dpi. The castrated animals exhibited a specific delay in MBP-stimulated DTH reactivity that correlates with the delay in the onset of the clinical symptoms. Also significant lymphocyte proliferation to MBP was still present at 35 dpi that was absent in the sham group. The distribution of the IgG subclasses indicated that at 35 dpi castrated animals have a higher IgG2b/IgG1 ratio (35.1) in comparison to that presented by sham rats (4.8). Considering that at this time the castrated animals were not completely recuperated, these results could indicate an ongoing inflammatory immune response associated with Th1 activity in these animals. Also castrated animals developed antibodies to a diversity of MBP epitopes in comparison to sham rats, which presented a dominance of antibodies to MBP peptide p96–128. These results indicate that sex hormones levels regulate cell-mediated immunity and the specificity of anti-MBP antibodies related to the induction and development of acute EAE.

Neuronal antigens modulate the immune response associated with experimental autoimmune encephalomyelitis

Rats primed with bovine myelin (BM) in complete Freunds adjuvant, develop acute experimental autoimmune encephalomyelitis (EAE). We have previously described that intraperitoneal administration prior to the active induction of the disease of a bovine synaptosomal fraction (BSF) and BM were effective ways of suppressing EAE. We found that both treatments diminish the incidence of the disease and reduced biochemical and histological alterations of the central nervous system (CNS). To characterize this suppression process, in this study we examined the antigen‐specific immune response in animals protected from EAE. Lymph node mononuclear cells derived from sick EAE rats, as well as from those protected by BM and BSF, showed strong myelin basic protein (MBP) proliferation. Analysis of the humoral response against MBP showed a significant diminution of IgG2b anti‐MBP titres in protected BM and BSF rats in contrast to sick EAE rats whose condition could be related to a diminished anti‐MBP Th1 response. Finally, cells from rats protected by BSF and BM reduced the incidence of EAE when they were adoptively transferred into animals prior to active induction of the disease. These results suggest that a mechanism based on the generation of regulatory cells and immune deviation could account for the EAE suppression mediated by myelin as well as synaptosomal antigens.

Extrinsic Functions of Lectin Domains in O-N-Acetylgalactosamine Glycan Biosynthesis

Glycan biosynthesis occurs mainly in Golgi. Molecular organization and functional regulation of this process are not well understood. We evaluated the extrinsic effect of lectin domains (β-trefoil fold) of polypeptide GalNAc-transferases (ppGalNAc-Ts) on catalytic activity of glycosyltransferases during O-GalNAc glycan biosynthesis. The presence of lectin domain T3lec or T4lec during ppGalNAc-T2 and ppGalNAc-T3 catalytic reaction had a clear inhibitory effect on GalNAc-T activity. Interaction of T3lec or T4lec with ppGalNAc-T2 catalytic domain was not mediated by carbohydrate. T3lec, but not T2lec and T4lec, had a clear activating effect on Drosophila melanogaster core 1 galactosyltransferase enzyme activity and a predominant inhibitory effect on in vivo human core 1 glycan biosynthesis. The regulatory role of the β-trefoil fold of ppGalNAc-Ts in enzymatic activity of glycosyltransferases involved in the O-glycan biosynthesis pathway, described here for the first time, helps clarify the mechanism of biosynthesis of complex biopolymers (such as glycans) that is not template-driven.

Glycan bioengineering in immunogen design for tumor T antigen immunotargeting.

Bioengineering of Galbeta3GalNAcalpha, known as Thomsen-Friedenreich disaccharide (TFD), is studied to promote glycan immunogenicity and immunotargeting to tumor T antigen (Galbeta3GalNAcalpha-O-Ser/Thr). Theoretical studies on disaccharide conformations by energy minimization of structures using MM2 energy function showed that pentalysine (Lys5) linker and benzyl (Bzl) residue enhance TFD rigidity of the glycosidic bond. Antibodies raised against BzlalphaTFD-Lys5 immunogen recognize tumor T antigen. Competitive assays confirm that TFD-related structures are the main glycan epitope. Antibodies produced by glycan bioengineering recognize HT29, T47D, MCF7, and CT26 epithelial tumor cells. Epithelial tumor cell adhesion to T antigen-binding lectins and endothelial cells was lower in the presence of antibodies raised against the engineered immunogen. The immune response directed to the bioengineered glycoconjugate inhibited CT26 tumor cell proliferation and reduced tumor growth in an in vivo mouse model. These results show that TFD bioengineering is a useful immunogenic strategy with potential application in cancer therapy. The same approach can be extended to other glycan immunogens for immunotargeting purposes.

Post-Translational Incorporation of L-Phenylalanine into the C-Terminus of α-Tubulin as a Possible Cause of Neuronal Dysfunction

α-Tubulin C-terminus undergoes post-translational, cyclic tyrosination/detyrosination, and L-Phenylalanine (Phe) can be incorporated in place of tyrosine. Using cultured mouse brain-derived cells and an antibody specific to Phe-tubulin, we showed that: (i) Phe incorporation into tubulin is reversible; (ii) such incorporation is not due to de novo synthesis; (iii) the proportion of modified tubulin is significant; (iv) Phe incorporation reduces cell proliferation without affecting cell viability; (v) the rate of neurite retraction declines as level of C-terminal Phe incorporation increases; (vi) this inhibitory effect of Phe on neurite retraction is blocked by the co-presence of tyrosine; (vii) microtubule dynamics is reduced when Phe-tubulin level in cells is high as a result of exogenous Phe addition and returns to normal values when Phe is removed; moreover, microtubule dynamics is also reduced when Phe-tubulin is expressed (plasmid transfection). It is known that Phe levels are greatly elevated in blood of phenylketonuria (PKU) patients. The molecular mechanism underlying the brain dysfunction characteristic of PKU is unknown. Beyond the differences between human and mouse cells, it is conceivable the possibility that Phe incorporation into tubulin is the first event (or among the initial events) in the molecular pathways leading to brain dysfunctions that characterize PKU.

Post‐translational incorporation of 3,4‐dihydroxyphenylalanine into the C terminus of α‐tubulin in living cells

The C‐terminal tyrosine (Tyr) of the α‐tubulin chain is subjected to post‐translational removal and readdition in a process termed the “detyrosination/tyrosination cycle”. We showed in previous studies using soluble rat brain extracts that l‐3,4‐dihydroxyphenylalanine (l‐Dopa) is incorporated into the same site as Tyr. We now demonstrate that l‐Dopa incorporation into tubulin also occurs in living cells. We detected such incorporation by determining the “tyrosination state” of tubulin before and after incubation of cells in the presence of l‐Dopa. The presence of a tubulin isospecies following l‐Dopa incubation that was not recognized by antibodies specific to Tyr‐ and deTyr‐tubulin was presumed to reflect formation of Dopa‐tubulin. l‐Dopa was identified by HPLC as the C‐terminal compound bound to α‐tubulin. l‐Dopa incorporation into tubulin was observed in Neuro 2A cells and several other cell lines, and was not due to de novo protein biosynthesis. Dopa‐tubulin had microtubule‐forming capability similar to that of Tyr‐ and deTyr‐tubulin. l‐Dopa incorporation into tubulin did not notably alter cell viability, morphology, or proliferation rate. CAD cells (a neuron‐like cell line derived from mouse brain) are easily cultured under differentiating and nondifferentiating conditions, and can be treated with l‐Dopa. Treatment of CAD cells with l‐Dopa and consequent increase in l‐Dopa‐tubulin resulted in reduction of microtubule dynamics in neurite‐like processes.

Nitric oxide mediates the suppressive effect of testosterone on cell proliferative response to myelin basic protein.

This study assessed whether the in vitro effect of testosterone on the proliferative response of mononuclear cells to myelin basic protein (MBP) could be mediated by nitric oxide (NO). Testosterone but not cholesterol supplementation specifically suppressed the proliferative response of rat mononuclear cells to MBP and in parallel increased the NO level. NG-monomethyl 1-l-arginine, an inhibitor of NO synthesis, reverted the suppression of the testosterone-induced proliferative response to MBP. These results indicate that changes in the production of NO by testosterone are able to alter the specific T cell proliferation induced by the encephalitogenic MBP and in this way; it could be one of the molecular mechanisms that modulate the development of experimental autoimmune encephalomyelitis (EAE).