Stephen Henry

Lewis histo-blood group system and associated secretory phenotypes

This review summarises present knowledge of the chemistry, immunology, genetics and clinical significance of antibodies in the Lewis and secretor histoblood group systems. Although red cell serology has laid the foundations for these systems, more recent advances have been made by studying Lewis and related glycoconjugates with monoclonal antibodies, determining structures by mass spectrometry and NMR spectroscopy, identifying enzymes and their specificities, and identifying the genes by molecular biology. The expression of Lewis system antigens is dependent on Lewis and secretor loci. Fucosyltransferases coded by genes at these loci compete and interact with each other and with other transferases to determine an individuals Lewis and secretor phenotype. Exocrine epithelial cells, mostly of endodermal origin, synthesise the Lewis antigens which, as plasma glycolipids, are secondarily acquired by cells of the peripheral circulation. Phenotyping red cells is often regarded as a simple way of determining the Lewis and sometimes the secretor status of an individual; however, the red cell phenotype is influenced by many factors and may not necessarily reflect someones Lewis and secretor genotypes. Two main red cell Lewis groups are usually found, Lewis negative and Lewis positive. In Lewis‐negative individuals, the secretor genotype does not affect the Lewis phenotype, but in Lewis‐positive individuals, the non‐secretor genotype generates the Le(a+b–) phenotype, the secretor genotype causes the Le(a–b+) phenotype, and the partial secretor genotype gives rise to the Le(a+b+) phenotype.

Blood group terminology 2004: from the International Society of Blood Transfusion committee on terminology for red cell surface antigens

1 Bristol Institute for Transfusion Sciences, Bristol, UK 2 Growing your Knowledge, Spit Junction, NSW, Australia 3 American Red Cross Blood Services, Los Angeles-Orange Counties Region, Los Angeles, CA, USA 4 Biotechnology Research Centre, Auckland University of Technology, Auckland, New Zealand 5 Regional Blood Transfusion Center, Department of Clinical Immunology, University Hospital, Arhus N, Denmark 6 Department of Pathology, University Hospitals UH-2G332, Ann Arbor, Michigan, USA 7 Reference Laboratory for Immunohematology and Blood Groups, National Blood Services Centre, Tel Hashomer, Israel 8 New York Blood Center, New York, NY, USA 9 Ortho-Clinical Diagnostics, Raritan, NJ, USA 10 Drexel University College of Medicine, Philadelphia, PA, USA 11 Gamma Biologicals Inc (subsidiary of Immunocor Inc), Houston, TX, USA 12 Central Laboratory of the Netherlands Red Cross Blood Transfusion Service, Amsterdam, the Netherlands 13 Centre national de Reference pour les Groupes sanguines (CNTS), Paris, France 14 International Blood Group Reference Laboratory, Bristol, UK 15 Finnish Red Cross Blood Transfusion Service, Helsinki, Finland 16 South African National Blood Service, East Coast Region, Pinetown, South Africa 17 Osaka Red Cross Blood Center, Osaka, Japan 18 Blood Bank, Hospital Sirio-Libanes, Sao Paulo, Brazil 19 Rh Laboratory, University of Manitoba, Winnipeg, Manitoba, Canada

Evolution of Fucosyltransferase Genes in Vertebrates

Cloning and expression of chimpanzee FUT3, FUT5, and FUT6 genes confirmed the hypothesis that the gene duplications at the origin of the present human cluster of genes occurred between: (i) the great mammalian radiation 80 million years ago and (ii) the separation of man and chimpanzee 10 million years ago. The phylogeny of fucosyltransferase genes was completed by the addition of the FUT8 family of α(1,6)fucosyltransferase genes, which are the oldest genes of the fucosyltransferase family. By analysis of data banks, a newFUT8 alternative splice expressed in human retina was identified, which allowed mapping the human FUT8 gene to 14q23. The results suggest that the fucosyltransferase genes have evolved by successive duplications, followed by translocations, and divergent evolution from a single ancestral gene.

Genomic characterization of the kidd blood group gene:different molecular basis of the Jk(a-b-) phenotype in Polynesians and Finns

BACKGROUND: The clinically important Kidd (JK) blood group antigens are carried by the urea transporter in red cells. The rare Jk(a–b–) phenotype can be caused by homozygosity at the JK locus for a silent allele, Jk. This phenotype has been recorded in many ethnic groups, but it is most abundant among people originating from the Polynesian Islands and Finland. The molecular basis for Jk(a–b–) is unknown in these populations.

Synthetic glycolipid modification of red blood cell membranes

BACKGROUND: Glycolipids have a natural ability to insert into red cell (RBC) membranes. Based on this concept the serology of RBCs modified with synthetic analogs of blood group glycolipids (KODE technology) was developed, which entails making synthetic glycolipid constructs engineered to have specific performance criteria. Such synthetic constructs can be made to express a potentially unlimited range of carbohydrate blood group determinants.

Terminology for red cell surface antigens

The Working Party met at Makuhari Messe, Japan on 31 March 1996. A few changes to the current classification, documented in Blood Group Terminology 1995 [1], were agreed and these are described below.

PEGylation of Vesicular Stomatitis Virus Extends Virus Persistence in Blood Circulation of Passively Immunized Mice

ABSTRACT We are developing oncolytic vesicular stomatitis viruses (VSVs) for systemic treatment of multiple myeloma, an incurable malignancy of antibody-secreting plasma cells that are specifically localized in the bone marrow. One of the presumed advantages for using VSV as an oncolytic virus is that human infections are rare and preexisting anti-VSV immunity is typically lacking in cancer patients, which is very important for clinical success. However, our studies show that nonimmune human and mouse serum can neutralize clinical-grade VSV, reducing the titer by up to 4 log units in 60 min. In addition, we show that neutralizing anti-VSV antibodies negate the antitumor efficacy of VSV, a concern for repeat VSV administration. We have investigated the potential use of covalent modification of VSV with polyethylene glycol (PEG) or a function-spacer-lipid (FSL)–PEG construct to inhibit serum neutralization and to limit hepatosplenic sequestration of systemically delivered VSV. We report that in mice passively immunized with neutralizing anti-VSV antibodies, PEGylation of VSV improved the persistence of VSV in the blood circulation, maintaining a more than 1-log-unit increase in VSV genome copies for up to 1 h compared to the genome copy numbers for the non-PEGylated virus, which was mostly cleared within 10 min after intravenous injection. We are currently investigating if this increase in PEGylated VSV circulating half-life can translate to increased virus delivery and better efficacy in mouse models of multiple myeloma.

Forssman expression on human erythrocytes: biochemical and genetic evidence of a new histo-blood group system

In analogy with histo-blood group A antigen, Forssman (Fs) antigen terminates with α3-N-acetylgalactosamine and can be used by pathogens as a host receptor in many mammals. However, primates including humans lack Fs synthase activity and have naturally occurring Fs antibodies in plasma. We investigated individuals with the enigmatic ABO subgroup A(pae) and found them to be homozygous for common O alleles. Their erythrocytes had no A antigens but instead expressed Fs glycolipids. The unexpected Fs antigen was confirmed in structural, serologic, and flow-cytometric studies. The Fs synthase gene, GBGT1, in A(pae) individuals encoded an arginine to glutamine change at residue 296. Gln296 is present in lower mammals, whereas Arg296 was found in 6 other primates, > 250 blood donors and A(pae) family relatives without the A(pae) phenotype. Transfection experiments and molecular modeling showed that Agr296Gln reactivates the human Fs synthase. Uropathogenic E coli containing prsG-adhesin-encoding plasmids agglutinated A(pae) but not group O cells, suggesting biologic implications. Predictive tests for intravascular hemolysis with crossmatch-incompatible sera indicated complement-mediated destruction of Fs-positive erythrocytes. Taken together, we provide the first conclusive description of Fs expression in normal human hematopoietic tissue and the basis of a new histo-blood group system in man, FORS.

International Society of Blood Transfusion working party on terminology for red cell surface antigens

G. L. Daniels (Chair), D. J. Anstee, J. P. Cartron, W. Dahr, A. Fletcher, G. Garratty, S. Henry, J. Jorgensen, W. J. Judd, L. K ornstad, C. Levene, M. Lin, C. Lomas-Francis, A. Lubenko, J. J. Moulds, J. M. Moulds, M. Moulds, M. Overbeeke, M. E. Reid, P. Rouger, M. Scott, P. Sistonen, E. Smart, Y. Tani, S. Wendel & T. Zelinski*

Fluorescein and radiolabeled Function-Spacer-Lipid constructs allow for simple in vitro and in vivo bioimaging of enveloped virions

Tools that can aid in vitro and in vivo imaging and also noninvasively determine half-life and biodistribution are required to advance clinical developments. A Function-Spacer-Lipid construct (FSL) incorporating fluorescein (FSL-FLRO4) was used to label vesicular stomatitis virus (VSV), measles virus MV-NIS (MV) and influenza virus (H1N1). The ability of FSL constructs to label these virions was established directly by FACScan of FSL-FLRO4 labeled VSV and MV, and indirectly following labeled H1N1 and MV binding to a cells. FSL-FLRO4 labeling of H1N1 was shown to maintain higher infectivity of the virus when compared with direct fluorescein virus labeling. A novel tyrosine (125)I radioiodinated FSL construct was synthesized (FSL-(125)I) from FSL-tyrosine. This was used to label VSV (VSV-FSL-(125)I), which was infused into the peritoneal cavity of laboratory mice. Bioscanning showed VSV-FSL-(125)I to localize in the liver, spleen and bloodstream in contrast to the free labels FSL-(125)I or (125)I, which localized predominantly in the liver and thyroid respectively. This is a proof-of-principle novel and rapid method for modifying virions and demonstrates the potential of FSL constructs to improve in vivo imaging of virions and noninvasively observe in vivo biodistribution.