Anti-alpha-galactosyl antibodies recognizing epitopes terminating with alpha1,4-linked galactose: human natural and mouse monoclonal anti-NOR and anti-P1 antibodies

The rare NOR erythrocytes, which are agglutinated by most human sera, contain unique glycosphingolipids (globoside elongation products) terminating with the sequence Galalpha1-4GalNAcbeta1-3Gal- recognized by common natural human antibodies. Anti-NOR antibodies were isolated from several human sera by affinity procedures, and their specificity was tested by inhibition of antibody binding to NOR-tri-polyacrylamide (PAA) conjugate (ELISA) by the synthetic oligosaccharides, Galalpha1-4GalNAcbeta1-3Gal (NOR-tri), Galalpha1-4GalNAc (NOR-di), Galalpha1-4Galbeta1-3Galbeta1-4Glc ((Gal)3Glc), and Galalpha1-4Gal (P1-di). Two major types of subspecificity of anti-NOR antibodies were found. Type 1 antibodies were found to react strongly with (Gal)3Glc and NOR-tri and weakly with P1-di and NOR-di, which indicated specificity for the trisaccharide epitope Galalpha1-4Gal/GalNAcbeta1-3Gal. Type 2 antibodies were specific to Galalpha1-4GalNAc, because they were inhibited most strongly by NOR-tri and NOR-di and were not (or very weakly) inhibited by (Gal)3Glc and P1-di. Monoclonal anti-NOR antibodies were obtained by immunizing mice with NOR-tri-human serum albumin (HSA) conjugate and were found to have type 2 specificity. All anti-NOR antibodies reacted specifically with NOR glycolipids on thin-layer plates. The cross-reactivity of type 1 anti-NOR antibodies with Galalpha1-4Gal drew attention to a possible antigenic relationship between NOR and blood group P system glycolipids. The latter glycolipids include Pk (Galalpha1-4Galbeta1-4Glc-Cer) present in all normal erythrocytes and P1 (Galalpha1-4Galbeta1-4GlcNAcbeta1-3Galbeta1-4Glc-Cer) present only in P1 erythrocytes. Sera of some P2 (P1-negative) persons contain natural anti-P1 antibodies. This prompted us to test the specificity of anti-P1 antibodies. Natural human anti-P1 isolated from serum of P2 individual and mouse monoclonal anti-P1 were best inhibited by Galalpha1-4Galbeta1-4GlcNAc (P1-tri) and did not react with NOR-tri and NOR-di. Monoclonal anti-P1 bound to Pk and P1 glycolipids and not to NOR glycolipids. These results indicated an entirely different specificity of anti-NOR and anti-P1 antibodies. Human serum samples differed in the content of anti-alpha-galactosyl antibodies, including both types of anti-NOR. In the sera of some individuals, type 1 or type 2 anti-NOR antibodies dominated, and other samples contained mixtures of both types of anti-NOR. The biological significance of these new abundant anti-alpha-galactosyl antibodies still awaits elucidation.     

Structures of unique globoside elongation products present in erythrocytes with a rare NOR phenotype

Rare polyagglutinable erythrocytes of NOR phenotype were found to contain two unique glycosphingolipids (designated NOR1 and NOR2). These components (not detected in normal erythrocytes) were reactive with Griffonia simplicifolia isolectin IB4 (GSL-IB4) and commonly present human anti-NOR antibodies. The NOR1 component has been reported to be a globoside containing a single galactose residue linked alpha1,4 to the terminal N-acetylgalactosamine. Here, we report the structural studies on a second glycolipid, NOR2, and a third novel component migrating in high-performance thin-layer chromatography (HPTLC) between NOR1 and NOR2. The structures were determined by a combination of ion trap sequential mass spectrometry (MALDI-QIT-TOF) and step-wise treatment with glycosidases, followed by identification of products on HPTLC plates with lectins and mouse monoclonal anti-NOR antibody. The NOR2 component was found to be a disaccharide extension of NOR1 with the following structure: Galalpha1-4GalNAcbeta1-3Galalpha1-4GalNAcbeta1-3Galalpha1-4Galbeta1-4Glcbeta1-Cer. Treatment of NOR2 with alpha-galactosidase gave a glycolipid migrating between NOR1 and NOR2, which did not react with either GSL-IB4 or anti-NOR antibodies but did react with GalNAc-specific soybean agglutinin. This intermediate glycolipid (now designated NOR(int)) was identified as a relatively abundant component of a neutral glycolipid fraction from NOR erythrocytes, suggesting its presence as a precursor to NOR2. The structure of NOR(int) was also confirmed by sequential mass spectrometry studies. These results indicate that polyagglutination in NOR subjects is due to unique erythrocyte glycolipids that are synthesized by sequential addition of Galalpha1,4 and GalNAcbeta1,3 to globoside.     

Study of RNA distribution in the nucleolar components of Ehrlich cell using RNase-gold method

The RNA distribution in Ehrlich tumour cell nucleoli has been investigated using RNase-gold method. This technique has been applied to sections of cells prepared under various fixation and embedding conditions. As expected, the specificity and intensity of labelling by gold particles have varied according to the experimental conditions used. Interestingly, however, it has been noted that the localization of gold particles does also vary and in particular within the fibrillar centre. This observation underlines the interest of assaying the RNase-gold complex under various conditions. The gold particles were particularly concentrated over the granular component and to a lesser extent, in the dense fibrillar component. In the latter constituent, it has been noted that the gold markers were preferentially localized at the edge of the dense fibrils. Surprisingly, a few gold particles have also been detected in the fibrillar centres. The weak labelling has persisted even after pepsin or DNase extraction but has completely disappeared after RNase extraction. Further, an inhibition of rRNA synthesis by a treatment with actinomycin D has not produced a significant decrease of the number of gold particles present in the fibrillar centre. These results suggest that fibrillar centres contain a small amount of RNA which would not correspond to pre-rRNA.     

Study of RNA distribution in the nucleolar components of Ehrlich cell using RNase-gold method

Summary The RNA distribution in Ehrlich tumour cell nucleoli has been investigated using RNase-gold method. This technique has been applied to sections of cells prepared under various fixation and embedding conditions. As expected, the specificity and intensity of labelling by gold particles have varied according to the experimental conditions used. Interestingly, however, it has been noted that the localization of gold particles does also vary and in particular within the fibrillar centre. This observation underlines the interest of assyying the RNase-gold complex under various conditions.The gold particles were particularly concentrated over the granular component and to a lesser extent, in the dense fibrillar component. In the latter constitutent, it has been noted that the gold markers were preferentially localized at the edge of the dense fibrils. Surprisingly, a few gold particles have also been detected in the fibrillar centres. The weak labelling has persisted even after pepsin or DNase extraction but has completely disappeared after RNase extraction. Further, an inhibition of rRNA synthesis by a treatment with actinomycin D has not produced a significant decrease of the number of gold particles present in the fibrillar centre. These results suggest that fibrillar centres contain a small amount of RNA which would not correspond to pre-rRNA.     

Ultrastructural study of the relationships between the various nucleolar components in Ehrlich tumour and HEp-2 cell nucleoli after acetylation

In the present study, we analysed the relationships between various nucleolar components in Ehrlich tumour and HEp-2 cells, using acetylation. Under these conditions, we found contacts between the condensed intranucleolar chromatin and the fibrillar centre, illustrating the continuity between the DNA present inside the fibrillar centre and that of condensed associated chromatin. We also found that although the dense fibrillar component is usually situated at the periphery of the fibrillar centre, it is sometimes found inside the centre. On the other hand, the layer of dense fibrils bordering the fibrillar centre is interrupted by nucleolar interstices. In addition, in HEp-2 cell nucleoli with a reticulated appearance, the numerous small fibrillar centres are bound together by strands of dense fibrillar component. These observations are discussed in terms of relationships between nucleolar ultrastructure and function(s).