Holt-Oram syndrome is a genetically heterogeneous disease with one locus mapping to human chromosome 12q.

Holt-Oram syndrome (HOS) is an autosomal dominant condition affecting the heart and upper limbs. We have sought to identify the location of this gene using microsatellite DNA markers in a linkage study. Of seven families analysed, five show linkage between HOS and markers on chromosome 12q. But the two remaining families, phenotypically indistinguishable from the others, do not show this linkage. Analysis with the computer program HOMOG indicates that HOS is a heterogeneous disease. Our analysis places one HOS locus in a 21 cM interval in the distal region of chromosome 12q. The localization of a gene for HOS, reported here, represents an important step towards a better understanding of limb and cardiac development.

Holt-Oram syndrome is caused by mutations in TBX5, a member of the Brachyury (T) gene family.

Holt-Oram syndrome is a developmental disorder affecting the heart and upper limb, the gene for which was mapped to chromosome 12 two years ago. We have now identified a gene for this disorder (HOS1). The gene (TBX5) is a member of the Brachyury (T) family corresponding to the mouse Tbx5 gene. We have identified six mutations, three in HOS families and three in sporadic HOS cases. Each of the mutations introduces a premature stop codon in the TBX5 gene product. Tissue in situ hybridization studies on human embryos from days 26 to 52 of gestation reveal expression of TBX5 in heart and limb, consistent with a role in human embryonic development.

Evolution of pulmonate gastropod mitochondrial genomes: comparisons of gene organizations of Euhadra, Cepaea and Albinaria and implications of unusual tRNA secondary structures.

Complete gene organizations of the mitochondrial genomes of three pulmonate gastropods, Euhadra herklotsi, Cepaea nemoralis and Albinaria coerulea, permit comparisons of their gene organizations. Euhadra and Cepaea are classified in the same superfamily, Helicoidea, yet they show several differences in the order of tRNA and protein coding genes. Albinaria is distantly related to the other two genera but shares the same gene order in one part of its mitochondrial genome with Euhadra and in another part with Cepaea. Despite their small size (14.1-14.5 kbp), these snail mtDNAs encode 13 protein genes, two rRNA genes and at least 22 tRNA genes. These genomes exhibit several unusual or unique features compared to other published metazoan mitochondrial genomes, including those of other molluscs. Several tRNAs predicted from the DNA sequences possess bizarre structures lacking either the T stem or the D stem, similar to the situation seen in nematode mt-tRNAs. The acceptor stems of many tRNAs show a considerable number of mismatched basepairs, indicating that the RNA editing process recently demonstrated in Euhadra is widespread in the pulmonate gastropods. Strong selection acting on mitochondrial genomes of these animals would have resulted in frequent occurrence of the mismatched basepairs in regions of overlapping genes.

Proteomic analysis of the cell-surface membrane in chronic lymphocytic leukemia: identification of two novel proteins, BCNP1 and MIG2B.

B-cell-specific plasma-membrane proteins are potential targets for either small molecule or antibody-based therapies. We have sought to annotate proteins expressed at the cell surface membrane in patients with chronic lymphocytic leukemia (CLL) using plasma-membrane-based proteomic analysis to identify previously uncharacterized and potentially B-cell-specific proteins. Proteins from plasma-membrane fractions were separated on one-dimensional gels and trypsinized fractions subjected to high-throughput MALDI-TOF mass spectrometry. Using this method, many known B-cell surface antigens were detected, but also known proteins not previously described in this disease or in this cellular compartment, including cell surface receptors, membrane-associated enzymes and secreted proteins, and completely unknown proteins. To validate the method, we show that BLK, a B-cell-specific kinase, is located in the CLL-plasma-membrane fraction. We also describe two novel proteins (MIG2B and B-cell novel protein #1, BCNP1), which are expressed preferentially in B cells. MIG2B is in a highly conserved and defined gene family containing two plasma-membrane-binding ezrin/radixin/moesin domains and a pleckstrin homology domain; the Caenorhabditis elegans homolog (UNC-112) is a membrane-associated protein that colocalizes with integrin at cell-matrix adhesion complexes. BCNP1 is a completely unknown protein with three predicted transmembrane domains, with three alternatively spliced final exons. Proteomic analysis may thus define new potential therapeutic targets.

Anti-human RP105 sera induces lymphocyte proliferation.

Cellular environment dictates whether antigen binding to the B lymphocyte receptor together with co-stimulatory molecules will result in proliferation, anergy, or apoptosis. Murine RP105 is a member of the leucine-rich repeat family of proteins, which is specifically expressed on mature B cells. Monoclonal antibodies to the murine RP105 induce proliferation and protect B cells from apoptosis, suggesting an important regulatory role in murine B lymphocyte function. We identified a human RP105 homolog and mapped the gene to chromosome 5q12.3-13.1. Tissue distribution analysis shows that the transcript is found predominately in lymphoid tissues including spleen, tonsils, appendix, and peripheral blood leukocytes. Polymerase chain reaction analysis of isolated primary human cell populations confirms that mRNA exists in spleen B lymphocytes and monocytes but not T lymphocytes. Western blot analysis demonstrates specific expression of human RP105 in human B lymphocytes. Murine anti-human RP105 sera was generated using DNA immunization. The antisera contained antibodies that recognized and bound to human B lymphocytes from both spleen and peripheral blood as assessed by flow cytometry. Assessment of biological function showed that human peripheral blood leukocytes incubated with anti-RP105 sera were induced to proliferate as measured by tritiated thymidine incorporation. Moreover, anti-CD40 and interleukin-4-treated cells but not those exposed to anti-RP105 sera produced soluble CD23, suggesting distinct functional roles. This is the first demonstration of both the existence of RP105 protein on human B lymphocytes and its role in the regulation of B lymphocyte activation.

Alternative Splicing of Human NrCAM in Neural and Nonneural Tissues.

Neural cell adhesion molecule NrCAM exists in a variety of isoforms as a result of alternative splicing of individual exons during RNA processing. In this report we demonstrate that many of the alternative splicing events described for chick are conserved in man and describe a novel variant of NrCAM cDNA. Furthermore, we show that NrCAM is expressed at significant levels outside the nervous system; in particular in pancreas, adrenal glands, and placenta and that expression in both brain and other tissues is accompanied by a very variable pattern of exon utilization in fetal and adult cells. Copyright 1998 Academic Press.

Characterization of a novel TNF-like ligand and recently described TNF ligand and TNF receptor superfamily genes and their constitutive and inducible expression in hematopoietic and non-hematopoietic cells.

A novel (TL1), a recently described (TL2) TNF-like, and three recently described TNF receptor-like (TR1, TR2, TR3) molecules were identified by searching a cDNA database. TL1 and TL2 are type-II membrane proteins. TR2 and TR3 are type-I membrane proteins whereas TR1 appears to be a secreted protein. TL1, TL2, TR2 and TR3 were expressed in hematopoietic cells, whereas TR1 was not. Northern blots hybridized with the cDNA probes revealed multiple forms of RNA as well as inducible expression of TL1, TL2, TR2 and TR3. TL2 and TR3, in particular, were highly induced in activated CD4+ T cells. Radiation hybrid mapping localized TR1 and TL2 to 8q24 and 3q26, respectively, which are not near any known superfamily members. TL1 was mapped to 9q32, near CD30L (9q33) and TR2 and TR3 mapped to the region of chromosome 1 that contains the TNFR-II, 4-1BB, OX40 and CD30 gene cluster at 1p36. Only TR3 in this cluster possesses a death domain. Southern blot analysis revealed the presence of TL and TR genes in different mammalian species. TL2, TR1, TR2 and TR3 were recently described by others as TRAIL/Apo-2L, OPG, HVEM and DR3/WSL-1/Apo-3/TRAMP/LARD, respectively.

Cloning, functional characterisation and population analysis of a variant form of the human glycine type 2 transporter.

Two forms of glycine transporter have been described to date, GlyT-1 and GlyT-2. The GlyT-2 form is expressed mainly in the spinal cord, brainstem and cerebellum. Here we describe the identification of a variant form of the human GlyT-2 (SC6), showing three amino acid changes to the previously reported protein. Population analysis identified the allele causing one of the polymorphisms, D463N, at 10% within the population with 3% being homozygous for the change. We also transfected our new variant into mammalian cells and compared it to the published cDNA, showing that the three amino acid changes present have no major effect on the biochemical properties of the transporter.

[Gene localisation in 12q12 in Holt-Oram atrio-digital syndrome]. / Localisation d'un gène du syndrome atrio-digital de Holt-Oram en 12q2.

The Holt-Oram syndrome, first described in 1960, consists of non-cyanotic congenital heart disease, usually an atrial septal defect, arrhythmias and malformations of the upper limbs affecting the radial segment. The transmission of the syndrome is autosomal dominant with almost complete penetrance. The authors report the localisation of a genetic abnormality of the Holt-Oram syndrome on the long arm of chromosome 12 (12q21-q3) by analysis of linkage in 9 multiplex families (Zmax = 8.19 at locus D12S354). Multipoint analysis showed a genetic interval of 7 centimorgans containing a gene of the Holt-Oram syndrome between loci D12S84 and D12S79 (multipoint lod score, 10 g base 10 = 8.96). In situ hybridization of artificial yeast chromosomes containing the surrounding markers showed that a gene of the Holt-Oram syndrome is located in 12q23-q24. The genetic heterogeneity was demonstrated in 3 families of the Holt-Oram syndrome with polydactyly or without cardiac disease (homog-test: chi 2 = 13.28; p = 0.0001). The localisation of a gene of the Holt-Oram syndrome is, to the authors' knowledge, the first chromosomal localisation of a cardiac malformation with septal defects in man. The identification of this gene should open wide perspectives for genetic research of cardiac morphogenesis and clarify the molecular mechanisms which govern cardiac septation during embryogenesis.

CD70 (TNFSF7) is expressed at high prevalence in renal cell carcinomas and is rapidly internalised on antibody binding.

In order to identify potential markers of renal cancer, the plasma membrane protein content of renal cell carcinoma (RCC)-derived cell lines was annotated using a proteomics process. One unusual protein identified at high levels in A498 and 786-O cells was CD70 (TNFSF7), a type II transmembrane receptor normally expressed on a subset of B, T and NK cells, where it plays a costimulatory role in immune cell activation. Immunohistochemical analysis of CD70 expression in multiple carcinoma types demonstrated strong CD70 staining in RCC tissues. Metastatic tissues from eight of 11 patients with clear cell RCC were positive for CD70 expression. Immunocytochemical analysis demonstrated that binding of an anti-CD70 antibody to CD70 endogenously expressed on the surface of A498 and 786-O cell lines resulted in the rapid internalisation of the antibody-receptor complex. Coincubation of the internalising anti-CD70 antibody with a saporin-conjugated secondary antibody before addition to A498 cells resulted in 50% cell killing. These data indicate that CD70 represents a potential target antigen for toxin-conjugated therapeutic antibody treatment of RCC.

Complete DNA sequence of the mitochondrial genome of Cepaea nemoralis (Gastropoda: Pulmonata).

The nucleotide sequence of a mitochondrial genome of the pulmonate gastropod mollusc Cepaea nemoralis has been determined. Contained within the 14,100 basepairs (bp) are the two ribosomal RNA genes and 13 protein coding genes typical of metazoan mitochondrial genomes. The Cepaea mtDNA does contain a gene for ATPase subunit 8, like the clausiliid pulmonate, Albinaria, and the chiton, Katharina, but unlike the bivalve mollusc, Mytilus. The mitochondrial genetic code of Cepaea is proposed to be the same as that of Mytilus, Katharina, and Drosophila. Only 14 putative tRNA genes are presented, although there is sufficient unassigned sequence to encode the remainder of the expected total of 22 tRNA genes. These 14 tRNA genes are a mixture of standard cloverleaf structures and nonstandard structures containing TV replacement loops as seen in nematode and mosquito mitochondrial genomes. If the eight unidentified tRNA genes are indeed present, very little unassigned sequence would remain to serve as a control region. Genes are transcribed from both strands of the molecule. Base composition is the least biased for any reported animal mitochondrial genome and is also very little skewed between strands using measures independent of base composition. The Cepaea mitochondrial gene order is quite unlike that of any other reported metazoan mtDNA, with the exception of the recently reported partial sequences of Albinaria. No gene boundaries are shared among all the reported molluscan taxa, demonstrating a complete lack of conservation of mitochondrial gene order across the phylum Mollusca.

New technologies and DNA resources for high throughput biology.

The rapid increase in DNA sequencing information is opening up new opportunities in genetics. The current methods for processing and analysing genetic data are, however, slow and labour intensive. The next wave of genetic analysis will rely on the analysis of DNA variation from large population based cohorts. These studies will provide important new data on population and disease genetics and have the potential to make a significant impact on our current healthcare practices. In order for these studies to deliver, we need to develop a new generation of ultra-rapid DNA technologies which will allow us to generate, capture and efficiently exploit these new data. This chapter describes the recent advances in DNA sequencing and genotyping technologies that will lead to 100-1000-fold increases in our ability to produce the DNA data we need to explore and exploit the new genetic opportunities to the full.

Alternative splicing of human NrCAM in neural and nonneural tissues.

Neural cell adhesion molecule NrCAM exists in a variety of isoforms as a result of alternative splicing of individual exons during RNA processing. In this report we demonstrate that many of the alternative splicing events described for chick are conserved in man and describe a novel variant of NrCAM cDNA. Furthermore, we show that NrCAM is expressed at significant levels outside the nervous system; in particular in pancreas, adrenal glands, and placenta and that expression in both brain and other tissues is accompanied by a very variable pattern of exon utilization in fetal and adult cells.

Identification, mapping, and phylogenomic analysis of four new human members of the T-box gene family: EOMES, TBX6, TBX18, and TBX19.

Brachyury(T) is a mouse mutation, first described over 70 years ago, that causes defects in mesoderm formation. Recently several related genes, the T-box gene family, that encode a similar N-terminal DNA binding domain, the T-box, and that play critical roles in human embryonic development have been identified. It has been shown that human TBX5 and TBX3, if mutated, cause developmental disorders, Holt-Oram syndrome (OMIM 142900) and ulnar-mammary syndrome (OMIM 181450), respectively. We have identified four new human members of the T-box gene family, EOMES, TBX6, TBX18, and TBX19, and these genes have been mapped to different chromosomal regions by radiation hybrid mapping. The four T-box genes were classified into four different subfamilies and have also been subjected to phylogenomic analysis. Human EOMES maps at 3p21.3-p21.2. This Tbr1-subfamily gene is likely to play a significant role in early embryogenesis similar to that described for Xenopus eomesodermin. Human TBX6 maps at 16p12-q12. This Tbx6-subfamily gene is likely to participate in paraxial mesoderm formation and somitogenesis in human embryo. TBX18 is a novel member of the Tbx1 subfamily that maps at 6q14-q15. Two subgroups, TBX1/10 and TBX15/18 subgroups, could be distinguished within the Tbx1 subfamily. TBX19 is an orthologue of chick TbxT and maps at 1q23-q24. The genomic organization of TBX19 is highly similar to that of human T(Brachyury), another human member of the same subfamily.

Cloning and expression profiling of Hpa2, a novel mammalian heparanase family member.

Heparan sulfate proteoglycans are important constituents of the extracellular matrix and basement membrane. Cleavage of heparan sulfate by heparanase, an endoglycosidase, is implicated in the extravasation of leukocytes and metastatic tumour cells, identifying this enzyme(s) as a target for anti-inflammatory and anti-metastatic therapies. The cloning of a cDNA encoding human heparanase (Hpa1) was reported recently, together with evidence indicating that the hpa1 gene is unique and unlikely to belong to a family of related genes. Here we report the cloning of a cDNA encoding a novel human protein, HPA2, with significant homology to Hpa1. Alternative splicing of the hpa2 transcript yields three different mRNAs, encoding putative proteins of 480, 534, and 592 amino acids. Sequence analyses predict that all three Hpa2 proteins are intracellular, membrane-bound enzymes. Hpa2 also shows a markedly different mRNA distribution to Hpa1 in both normal and cancer tissues. The difference in expression profiles and predicted cellular locations suggests that Hpa2 and Hpa1 proteins have distinct biological functions.

Molecular characterization of a human scavenger receptor, human MARCO.

Murine MARCO has been identified recently in subsets of macrophages located in the peritoneum, marginal zone of the spleen, and the medullary cord of lymph nodes, where it has been proposed that it serves as a bacteria-binding receptor. A scavenger receptor family member with an extended collagenous domain, murine MARCO has also been demonstrated in atherosclerotic lesions of susceptible mice. We report here the identification, tissue and chromosomal localization, and pharmacological characterization of human (h)MARCO. hMARCO was identified from a macrophage cDNA library by electronic screening with the murine MARCO sequence. Nucleotide sequence analysis confirmed that the full-length hMARCO clone encoded a 519-amino acid protein sharing 68.5% identity with murine MARCO. RNA blot analysis indicated that the hMARCO transcript is 2.0 kb in length and is predominantly expressed in human lung, liver, and lymph nodes. Radiation hybrid mapping localized hMARCO to chromosome 2q14. Ligand-binding studies of COS cells expressing hMARCO demonstrated significant specific binding of both Escherichia coli and Staphylococcus aureus. In contrast, the hMARCO receptor expressed in COS cells did not specifically bind the scavenger receptor ligand acetylated low-density lipoprotein (LDL), despite its similarity to the elongated collagen-like binding domain of the macrophage scavenger receptor. In addition, acetylated (Ac)LDL and oxidized (Ox)LDL did not inhibit E. coli binding to hMARCO. These data suggest that hMARCO may play an important role in host defense, but it has no obvious role in the accumulation of modified lipoproteins during atherogenesis.

Expression, purification and characterization of a human serine-dependent phospholipase A2 with high specificity for oxidized phospholipids and platelet activating factor.

Using expressed sequence tag (EST) homology screening, a new human serine dependent phospholipase A2 (HSD-PLA2) was identified that has 40% amino acid identity with human low density lipoprotein-associated phospholipase A2 (LDL-PLA2). HSD-PLA2 has very recently been purified and cloned from brain tissue but named PAF-AH II. However, because the homology with LDL-PLA2 suggested a broader substrate specificity than simply platelet activating factor (PAF), we have further characterized this enzyme using baculovirus-expressed protein. The recombinant enzyme, which was purified 21-fold to homogeneity, had a molecular mass of 44kDa and possessed a specific activity of 35 micromol min-1 mg-1 when assayed against PAF. Activity could also be measured using 1-decanoyl-2-(4-nitrophenylglutaryl) phosphate (DNGP) as substrate. Like LDL-PLA2, HSD-PLA2 was able to hydrolyse oxidatively modified phosphatidylcholines when supplemented to human LDL prior to copper-stimulated oxidation. A GXSXG motif evident from sequence information and inhibition of its activity by 3,4, dichloroisocoumarin, diisopropyl fluorophosphate (DFP) and diethyl p-nitrophenyl phosphate (DENP) confirm that the enzyme is serine dependent. Moreover, sequence comparison indicates the HSD-PLA2 probable active site triad positions are shared with LDL-PLA2 and a C. elegans homologue, suggesting that these sequences comprise members of a new enzyme family. Although clearly structurally related with similar substrate specificities further work reported here shows HSD-PLA2 and LDL-PLA2 to be different with respect to chromosomal localization and tissue distribution.

A first-generation whole genome-radiation hybrid map spanning the mouse genome.

We have assembled a first-generation anchor map of the mouse genome using a panel of 94 whole-genome-radiation hybrids (WG-RHs) and 271 sequence-tagged sites (STSs). This is the first genome-wide RH anchor map of a model organism. All of the STSs have been previously localized on the genetic map and are located 8.8 Mb apart on average. This mouse WG-RH panel, known as T31, has an average retention frequency of 27.6% and an estimated potential resolution of 145 kb, making it a powerful resource for efficient large-scale expressed sequence tag mapping. [All of the mapping data for the maps presented here have been deposited at the Research Genetics, Inc., web site and can be freely accessed and downloaded at http://www.resgen.com/.]

hAG-2 and hAG-3, human homologues of genes involved in differentiation, are associated with oestrogen receptor-positive breast tumours and interact with metastasis gene C4.4a and dystroglycan.

hAG-2 and hAG-3 are recently discovered human homologues of the secreted Xenopus laevis proteins XAG-1/2 (AGR-1/2) that are expressed in the cement gland, an ectodermal organ in the head associated with anteroposterior fate determination during early development. Although the roles of hAG-2 and hAG-3 in mammalian cells are unknown, both proteins share a high degree of protein sequence homology and lie adjacent to one another on chromosome 7p21. hAG-2 mRNA expression has previously been demonstrated in oestrogen receptor (ER)-positive cell lines. In this study, we have used real-time quantitative RT - PCR analysis and immunohistochemistry on tissue microarrays to demonstrate concordant expression of hAG-2 and hAG-3 mRNA and protein in breast tumour tissues. Tumour expression of both genes correlated with OR (hAG2, P=0.0002; hAG-3, P=0.0012), and inversely correlated with epidermal growth factor receptor (EGFR) (P=0.003). Yeast two-hybrid cloning identified metastasis-associated GPI-anchored C4.4a protein and extracellular alpha-dystroglycan (DAG-1) as binding partners for both hAG-2 and hAG-3, which if replicated in clinical oncology would demonstrate a potential role in tumour metastasis through the regulation of receptor adhesion and functioning. hAG-2 and hAG-3 may therefore serve as useful molecular markers and/or potential therapeutic targets for hormone-responsive breast tumours.

A translocation at 12q2 refines the interval containing the Holt-Oram syndrome 1 gene.

A gene for Holt-Oram syndrome (HOS) has been previously mapped to chromosome 12q2 and designated HOS1. We have identified a HOS patient with a de novo chromosomal rearrangement involving 12q. Detailed cytogenetic analysis of this case reveals three breaks on 12q, and two of these are within the HOS1 interval. By using a combination of chromosome painting and FISH with YACs and cosmids, it has been possible to map these breakpoints within the critical HOS1 interval and thus provide a focus for HOS gene-identification efforts.