Comparative studies of resistin expression and phylogenomics in human and mouse

Resistin is a newly identified adipocytokine that has been proposed to be a link between obesity and type 2 diabetes based on animal studies. However, the role of resistin in the pathogenesis of insulin resistance associated with obesity in humans remains unclear. We comparatively and quantitatively studied the tissue distributions of resistin mRNA between human and mouse. The expression level of resistin mRNA in human adipose tissue is extremely low but detectable by real-time PCR and is about 1/250 of that in the mouse. Remarkably, resistin mRNA is abundant in human primary acute leukemia cells and myeloid cell lines U937 and HL60, but not in the Raw264 mouse myeloid cell line. Resistin expression in U937 cells was not affected by lipopolysaccharide (LPS) or by ciglitazone, a PPARgamma ligand. Phylogenomics revealed that the human resistin gene is the ortholog of its murine counterpart and is located in a region of chromosome 19p13.3, which is syntenic to mouse chromosome 8A1. In addition to the resistin-like molecule (RELM) sequences already reported, bioinformatics analysis disclosed another RELM sequence in the vicinity of RELMbeta on human chromosome 3q13.1, but this sequence is unlikely to encode an expressed gene. Therefore, only two RELMs, resistin and RELMbeta, exist in humans, instead of the three RELMs, resistin, RELMalpha, and RELMbeta, that exist in mice. This finding provides a possible answer to the question of why only two RELMs have been cloned in humans and suggests that the RELM family is not well conserved in evolution and may function differently between species. Therefore, caution should be exercised in interpreting resistin as a link between obesity and insulin resistance in humans. The high expression of resistin in human leukemia cells suggests a hitherto unidentified biological function of resistin in leukocytes.     

Cloning of the murine homolog of the leukemia-associated PML gene

PML, a Ring-finger protein, participates in the disruption of normal myeloid differentiation when fused to the retinoic acid receptor alpha (RAR) by the translocation between Chromosomes (Chrs) 15 and 17 in acute promyelocytic leukemia (APL). As an initial step in the characterization of PML in species other than human, a murine cDNA clone of the PML gene was isolated and sequenced, and the intron/exon organization of the murine locus determined. The predicted amino acid sequence of the mouse PML protein shows 80% similarity to that of its human homolog. However, the mouse and human proteins show greater than 90% similarity in the proposed functional domains of the proteins. Despite its role in the etiology of APL, PML expression is not detectably altered during granulocytic differentiation in a murine in vitro system. Chromosomal localization of the Pml locus by somatic cell hybrids and by linkage analysis indicates that the gene maps to a region of mouse Chr 9 with known linkage homology to the region on human Chr 15q to which PML has been localized.     

Localization of human myeloid-associated surface antigen detected by a panel of 20 monoclonal antibodies to the q12-qter region of chromosome 11

Human x mouse myeloid cell hybrids were obtained after fusion of human leucocytes and the murine myeloid cell line WEHI-TG. The hybrids were tested for reactivity with a panel of monoclonal antibodies with a known myelocytic, monocytic, or myelomonocytic specificity. Twenty antibodies, all of which bind specifically to the surface of human myeloid cells, exhibited very similar reactivity patterns with the hybrid clones. Chromosomal analysis of hybrid cell metaphases revealed that the gene(s) involved in the expression of the antigen(s) recognized by these antibodies must be located on human chromosome 11 in the region q12-qter. These results are compatible with the evidence obtained from other studies that several, if not all, of the myeloid-specific antibodies used are reactive with a similar antigenic determinant present on human myeloid cells.     

Human EVI9, a homologue of the mouse myeloid leukemia gene, is expressed in the hematopoietic progenitors and down-regulated during myeloid differentiation of HL60 cells

Evi9, a common site of retroviral integration in BXH2 murine myeloid leukemias, encodes a C2H2 zinc finger protein and is overexpressed in these leukemic cells. To investigate a possible role of EVI9 in the human hematopoietic system, we isolated the cDNA clone of the human homologue. Human EVI9, located on the chromosome 2p13 region, contains an open reading frame of 797 amino acids that is 98.7% identical to the mouse protein. RT-PCR analysis of purified human hematopoietic cells showed that EVI9 is expressed in CD34-positive myeloid precursors, B cells, monocytes, and megakaryocytes, but only weakly in T lymphocytes, suggesting that EVI9 may play an important role in hematopoiesis. Furthermore, EVI9 was down-regulated during myeloid differentiation of HL60 cells induced by all-trans-retinoic acid, whereas the expression remained during monocytic differentiation induced by phorbol 12-myristate 13-acetate. These results indicate a distinct role for EVI9 in human hematopoietic cells and suggest that EVI9 may cause leukemia through inhibition of myeloid differentiation.     

Identification of a human gene (HCK) that encodes a protein-tyrosine kinase and is expressed in hemopoietic cells.

We have isolated cDNAs representing a previously unrecognized human gene that apparently encodes a protein-tyrosine kinase. We have designated the gene as HCK (hemopoietic cell kinase) because its expression is prominent in the lymphoid and myeloid lineages of hemopoiesis. Expression in granulocytic and monocytic leukemia cells increases after the cells have been induced to differentiate. The 57-kilodalton protein encoded by HCK resembles the product of the proto-oncogene c-src and is therefore likely to be a peripheral membrane protein. HCK is located on human chromosome 20 at bands q11-12, a region that is affected by interstitial deletions in some acute myeloid leukemias and myeloproliferative disorders. Our findings add to the diversity of protein-tyrosine kinases that may serve specialized functions in hemopoietic cells, and they raise the possibility that damage to HCK may contribute to the pathogenesis of some human leukemias.     

Cloning of the mouse homolog of the 126-kDa human C1q/MBL/SP-A receptor, C1qRp

Binding of C1q to cell surfaces has been shown to mediate a number of biological activities including enhancement of phagocytosis and stimulation of superoxide production. Several C1q binding proteins have been proposed as candidate receptors for these functions. The 126-kDa human C1q membrane receptor, termed C1qR_p, has recently been cloned. This molecule is believed to play a role in the enhancement of phagocytosis in monocytes and macrophages, and its expression has been shown to be restricted to cells of the myeloid lineage, endothelial cells, and platelets. Here we report the isolation and genomic characterization of the murine homolog of C1qR_p. Degenerate oligonucleotide primers based on the published human sequence were used to amplify a region of the murine homolog spanning from the carbohydrate recognition domain to the fourth epidermal growth factor (EGF) domain. This fragment was used as a probe to isolate the murine gene from a 129/Sv genomic λ library. The predicted primary protein sequence displayed 68.1% identity with the human homolog. All the major structural domains were conserved between the two molecules. The coding sequence of the murine gene was contained within two exons separated by a small intron of approximately 250 bp. The structure of the human gene was found to be similar, with the position of the intron conserved. Cloning of the murine C1qR_p will facilitate further investigation of the physiological function of this molecule. Received: 9 November 1998 / Accepted: 28 March 1999     

The isolation and characterization of the murine T cell antigen receptor zeta chain gene

The T cell antigen receptor (TCR) is a multisubunit complex which has a dual function of antigen recognition and signal transduction. One of its invariant subunits, the zeta chain, has been shown to have a significant role in the expression and function of the TCR on the cell surface. The mouse and human zeta cDNAs share significant homologies to each other but are distinct from all of the previously characterized TCR components. We now report the isolation and structural analysis of the complete murine zeta gene. This gene spans at least 31 kilobases and divides into eight exons. The first exon, which is located at least 20 kilobases upstream from the second exon, codes for the 5'-untranslated region and most of the signal peptide. The second exon codes for the remainder of the signal peptide, the extracellular domain, the transmembrane domain, and the first three amino acids of the intracytoplasmic domain. Exons 3-7 encode the majority of the intracytoplasmic domain. The eight exon encodes the carboxyl-terminal 21 amino acids and the 3'-untranslated region. Four groups of mRNA initiation sites have been identified at approximately 140 base pairs upstream to the AUG codon. No TATA-like box has been detected. The gene is localized to the distal part of chromosome 1 in a linkage group highly conserved between man and mouse.     

Molecular characterization of the mouse Tem1/endosialin gene regulated by cell density in vitro and expressed in normal tissues in vivo

Human tumor endothelial marker 1/endosialin (TEM1/endosialin) was recently identified as a novel tumor endothelial cell surface marker potentially involved in angiogenesis, although no specific function for this novel gene has been assigned so far. It was reported to be expressed in tumor endothelium but not in normal endothelium with the exception of perhaps the corpus luteum. Here we describe the cDNA and genomic sequences for the mouse Tem1/endosialin homolog, the identification and characterization of its promoter region, and an extensive characterization of its expression pattern in murine and human tissues and murine cell lines in vitro. The single copy gene that was mapped to chromosome 19 is intronless and encodes a 92-kDa protein that has 77.5% overall homology to the human protein. The remarkable findings are 1) this gene is ubiquitously expressed in normal human and mouse somatic tissues and during development, and 2) its expression at the mRNA level is density-dependent and up-regulated in serum-starved cells. In vitro, its expression is limited to cells of embryonic, endothelial, and preadipocyte origin, suggesting that the wide distribution of its expression in vivo is due to the presence of vascular endothelial cells in all the tissues. The ubiquitous expression in vivo is in contrast to previously reported expression limited to corpus luteum and highly angiogenic tissues such as tumors and wound tissue.     

CD14 is a member of the family of leucine-rich proteins and is encoded by a gene syntenic with multiple receptor genes.

We have isolated and characterized genomic and cDNA clones encoding the murine homolog of the human monocyte/granulocyte cell surface glycoprotein, CD14. As in man, the expression of murine CD14 is limited to the myeloid lineage. The murine and human CD14 genes are highly conserved in their intron-exon organization and nucleotide sequence. Their deduced protein sequences show 66% amino acid identity. In both mouse and man, the CD14 protein contains a repeating (10 times) leucine-rich motif (LXXLXLX) that is also found in a group of heterogeneous proteins from phylogenetically distant species. The CD14 gene has been mapped to mouse chromosome 18 which also contains at least five genes encoding receptors (Pdgfr, Adrb2r, li, Grl-1, Fms). Thus CD14 and the receptor genes form a conserved syntenic group localized on mouse chromosome 18 and human chromosome 5. The inclusion of CD14 in the family of leucine-rich proteins, its expression profile and the murine chromosomal localization support the hypothesis that CD14 may function as a receptor.     

An ADAM family member with expression in thymic epithelial cells and related tissues

We have analyzed the tissue-specific expression, mRNA isoforms, and genomic structure of murine ADAM28, an ADAM family member recently discovered in human and mouse. While human ADAM28 is expressed in lymphocytes (J. Biol. Chem. 274 (1999) 29251), we observe expression of murine ADAM28 in thymic epithelial cells and developmentally related tissues including the trachea, thyroid, stomach, and lung, but not in lymphocytes. The expression patterns in adult and day 15.5 embryos are similar. We have detected multiple mRNA isoforms varying in the cytoplasmic domain coding sequence and 3prime prime or minute untranslated region due to alternative polyadenylation and splicing events that occur in the final four exons and three introns. The entire ADAM28 gene spans 55 kb and contains 23 exons. The protein sequence contains all conserved residues required for metalloprotease activity, indicative of a role in ectodomain shedding and extracellular matrix modeling. Given its unique expression pattern and potential functions, murine ADAM28 may play a role in organogenesis and organ-specific functions such as thymic T cell development.     

HEX: a novel homeobox gene expressed during haematopoiesis and conserved between mouse and human.

We describe the cloning of a novel homeodomain-containing gene, which is highly conserved between mouse and human. The human cDNA was initially isolated from human haematopoietic tissue and denoted HEX (haematopoietically expressed homeobox). Sequence analysis of the coding sequences from mouse and the partial cDNA from human shows that the homeodomain is most closely related to those of the HIx and HOX11 proteins. The HEX gene is present as a single copy in the human genome. Analysis of murine genomic DNA shows, in addition to an intron-containing gene homologous to HEX, the presence of a processed copy of the gene which has arisen within the last few million years. Analysis of human and murine haematopoietic cells and cell lines, revealed expression of the HEX gene in multipotential progenitors, as well as cells of the B-lymphocyte and myeloid lineages. However HEX was not expressed in T-lymphocytes or erythroid cells. This pattern of HEX gene expression suggests that it may play a role in haematopoietic differentiation.     

Cloning and characterization of the mouse Interleukin Enhancer Binding Factor 3 (Ilf3) homolog in a screen for RNA binding proteins

In a screen for RNA-binding proteins expressed during murine spermatogenesis, we have identified a cDNA that encodes a protein of 911 amino acids that contains two copies of the double-stranded RNA-binding motif and has 80% identity with human Interleukin Enhancer Binding Factor 3 (ILF3). Linkage and cytogenetic analyses localized the Ilf3 cDNA to a portion of mouse Chr 9, which shows conserved synteny with a region of human Chr 19 where the human ILF3 gene had been previously localized, supporting that we had cloned the murine homolog of ILF3. Northern analysis indicated the Ilf3 gene is ubiquitously expressed in mouse adult tissues with high levels of expression in the brain, thymus, testis, and ovary. Polyclonal antibodies detected multiple protein species in a subset of the tissues expressing Ilf3 RNA. Immunoreactive species are present at high levels in the thymus, testis, ovary, and the spleen to a lesser extent. The high degree of sequence similarity between the mouse ILF3 protein and other dsRNA binding motif-containing proteins suggests a role in RNA metabolism, while the differential expression indicates the mouse ILF3 protein predominantly functions in tissues containing developing lymphocyte and germ cells. Received: 21 October 1998 / Accepted: 15 January 1999     

Human artificial chromosomes containing chromosome 17 alphoid DNA maintain an active centromere in murine cells but are not stable

Human artificial chromosomes (HACs) are autonomous molecules that can function and segregate as normal chromosomes in human cells. De novo HACs have successfully been used as gene expression vectors to complement genetic deficiencies in human cultured cells. HACs now offer the possibility of studying the regulation and expression of large genes in a variety of cell types from different tissues and correcting gene deficiencies caused by human inherited diseases. Complementary gene expression studies in mice, especially in mouse models of human genetic diseases, are also important in determining if large human transgenes can be expressed appropriately from artificial chromosomes. Toward this aim we are establishing artificial chromosomes in murine cells as novel gene expression vectors. Initially we transferred HAC vectors into murine cells, but were unable to generate de novo HACs at a reasonable frequency. We then transferred HACs previously established in human HT1080 cells to three different murine cell types by microcell fusion, followed by positive selection. We observed that the HACs in murine cells bound centromere protein C (CENP-C), a marker of active centromeres, and were detected under selection but rapidly lost when selection was removed. These results suggest that the HACs maintain at least a partially functional centromere complex in murine cells, but other factors are required for stability and segregation. Artificial chromosomes containing mouse centromeric sequences may be required for better stability and maintenance in murine cells.