The human homolog of Sex comb on midleg (SCMH1) maps to chromosome 1p34.

Polycomb group genes were originally identified in Drosophila as repressors required to maintain the silenced state of homeotic loci. About ten Polycomb group genes have been cloned in Drosophila, and mammalian homologs have been identified for most of these. Here, we isolate cDNAs encoding two isoforms of a human homolog of Drosophila Sex comb on midleg (Scm), named Sex comb on midleg homolog-1 (SCMH1). Overall, SCMH1 has 94% identity to its mouse counterpart Scmh1, and 41% identity to Scm, and contains two 1(3)mbt domains, and the SPM domain that are characteristic of Scm. SCMH1 is widely expressed in adult tissues, and maps to chromosome 1p34.     

A novel member of murine Polycomb-group proteins, Sex comb on midleg homolog protein, is highly conserved, and interacts with RAE28/mph1 in vitro

The Polycomb group of (PcG) genes were originally described in Drosophila, but many PcG genes have mammalian homologs. Genetic studies in flies and mice show that mutations in PcG genes cause posterior transformations caused by failure to maintain repression of homeotic loci, suggesting that PcG proteins have conserved functions. The Drosophila gene Sex comb on midleg (Scm) encodes an unusual PcG protein that shares motifs with the PcG protein polyhomeotic, and with a Drosophila tumor suppressor, lethal(3)malignant brain tumor (l(3)mbt). Expressed sequence tag (EST) databases were searched to recover putative mammalian Scm homologs, which were used to screen murine cDNA libraries. The recovered cDNA encodes two mbt repeats and the SPM domain that characterize Scm, but lacks the cysteine clusters and the serine/threonine-rich region found at the amino terminus of Scm. Accordingly, we have named the gene Sex comb on midleg homolog 1 (Scmh1). Like their Drosophila counterparts, Scmh1 and the mammalian polyhomeotic homolog RAE28/mph1 interact in vitro via their SPM domains. We analyzed the expression of Scmh1 and rae28/mph1 using northern analysis of embryos and adult tissues, and in situ hybridization to embryos. The expression of Scmh1 and rae28/mph1 is well correlated in most tissues of embryos. However, in adults, Scmh1 expression was detected in most tissues, whereas mph1/rae28 expression was restricted to the gonads. Scmh1 is strongly induced by retinoic acid in F9 and P19 embryonal carcinoma cells. Scmh1 maps to 4D1-D2.1 in mice. These data suggest that Scmh1 will have an important role in regulation of homeotic genes in embryogenesis and that the interaction with RAE28/mph1 is important in vivo.     

Structural and functional analyses of methyl-lysine binding by the malignant brain tumour repeat protein Sex comb on midleg

Sex comb on midleg (Scm) is a member of the Polycomb group of proteins involved in the maintenance of repression of Hox and other developmental control genes in Drosophila. The two malignant brain tumour (MBT) repeats of Scm form a domain that preferentially binds to monomethylated lysine residues either as a free amino acid or in the context of peptides, while unmodified or di- or trimethylated lysine residues are bound with significantly lower affinity. The crystal structure of a monomethyl-lysine-containing histone tail peptide bound to the MBT repeat domain shows that the methyl-lysine side chain occupies a binding pocket in the second MBT repeat formed by three conserved aromatic residues and one aspartate. Insertion of the monomethylated side chain into this pocket seems to be the main contributor to the binding affinity. Functional analyses in Drosophila show that the MBT domain of Scm and its methyl-lysine-binding activity are required for repression of Hox genes.     

A primate transfer RNA gene cluster and the evolution of human chromosome 1.

The localisation of tRNA(Asn) gene clusters in the karyotypes of primates has been studied by means of in situ hybridisation. In the human and orangutan (Pongo pygmaeus) karyotypes there are two such gene clusters, one each on the long and short arms of chromosome 1. Old World monkeys, however, contain both gene clusters on their equivalent of the human chromosome 1 short arm, which can be explained by a pericentric inversion which (amongst other chromosome changes) distinguishes the human and Old World monkey chromosomes 1. The capuchin (Cebus appella), however, a New World monkey, has only one tRNA(Asn) gene cluster, at least on the elements equivalent to human chromosome 1. This cluster is located proximal to the centromere on a chromosome that has been tentatively identified (by others) as the equivalent of the long arm of human chromosome 1. Should this prove to be correct, it would indicate that the large primate metacentric came into being in the form found today in the great apes, rather than in the form currently found in Old World monkeys. These data further show that the tRNA(Asn) gene cluster has been split in two since before the Old World monkeys and hominids diverged, i.e., over 30 million years ago, and also that the original transfer of these genes from one arm of chromosome 1 to the other was unlikely to have involved a pericentric inversion but, rather, some form of replicative transposition.     

Analysis of the spermine synthase gene region in Fugu rubripes, Tetraodon fluviatilis, and Danio rerio

A prerequisite to understanding the evolution of the human X chromosome is the analysis of synteny of X-linked genes in different species. We have focused on the spermine synthase gene in human Xp22. 1. We show that whereas the human gene spans a genomic region of 54 kb, the Fugu rubripes gene is encompassed in a 4.7-kb region. However, we could not find conserved synteny between this region of human Xp22 and the equivalent F. rubripes region. A cosmid clone containing the F. rubripes gene does not contain other X-linked genes. Instead we identified homologs of human genes that are autosomally localized: the ryanodine receptor type I (RYRI), which is implicated in malignant hyperthermia and central core disease, and the HE6 gene. Comparison of the F. rubripes, Tetraodon fluviatilis, mouse, human, and Danio rerio 5'UTRs of spermine synthase highlights conserved sequences potentially involved in regulation. Interestingly, pseudogenes of this gene that are present in the human and mouse genomes seem to be absent in the compact F. rubripes genome. Analysis of a D. rerio PAC clone containing spermine synthase shows an intermediate genomic size in this fish. Sequence analysis of this PAC clone did not reveal other known genes: neither the RYRI gene, nor the HE6 gene, nor other human Xp22 genes were identified.     

Comparative genomics of the keratin-associated protein (KAP) gene clusters in human,chimpanzee, and baboon

We have previously identified a cluster of 16 genes that encode hair-specific proteins, called keratin-associated proteins (KAPs), located on human Chromosome (Chr) 21q22.3. Here, we have identified similar KAP gene clusters in two primates, chimpanzee and baboon. DNA sequence comparison revealed the common cluster structure consisting of 16 KAP genes for these three primates, but a significant difference was found in the baboon. Baboon possesses a new KAP gene not found in human and chimpanzee, whereas one KAP gene (KRTAP18.12) that exists in human and chimpanzee was lost in baboon, making no change in the total number of KAP genes. Interestingly, the sequence for coding regions are highly variable among species owing to insertions and deletions, resulting in variation of gene size. On the contrary, the sequences for the 5 upstream region are highly conserved among species. These findings suggest that the ancestral KAP gene cluster was composed of 17 genes before the divergence of Old World monkeys (baboon) to the anthropoid (human and chimpanzee). The sequence data described in this paper have been submitted to the DDBJ/EMBL/GenBank data library under accession nos. AP006271–AP006274. (Shinsei Minoshima) Present address: Photon Medical Research Center, Hamamatsu University School of Medicine, 1-20-1 Handayama, Hamamatsu 431-3192, Japan.     

Maternal expression of genes that regulate the bithorax complex of Drosophila melanogaster

A relatively large number of genes have been described that are required for the normal spatial expression of the genes of the bithorax complex. Most of these regulators appear to act negatively and are required to prevent indiscriminate expression of bithorax complex (BX-C) functions. In this report we examine five negative BX-C regulators to determine whether these are maternally expressed in germ-line derived cells. The genes studied include Additional sex combs (Asx), Polycomblike (Pcl), Sex comb extra (Sce), Sex comb on midleg (Scm), and lethal(4)29 [l(4)29]. The maternal germ-line dependent expression of each of these genes is assessed by comparison of zygotes from mothers whose functional germ cells carry no wild-type alleles to zygotes from mothers whose germ cells contain one wild-type allele. Because mutant alleles of each of the genes studied are recessive lethals, mosaic females with homozygous or hemizygous mutant germ lines were produced by pole cell transplantation. The results demonstrate that all of the negative regulators tested are expressed in the maternal germ line and all play important roles in the regulation of BX-C activities during embryogenesis. The absence of maternally supplied products from all of the genes studied except l(4)29 can be largely or completely compensated for by the activity in the zygote of a paternally contributed wild-type allele. It is argued that, with the exception of l(4)29, the genes studied in this report are qualitatively similar in function to the previously described BX-C regulators Pc, esc, and sxc. The available evidence indicates that genes within this group have functions that are not restricted to the regulation of genes that control segmental identity.     

Evolutionary patterns of killer cell Ig-like receptor genes in Old World monkeys

Killer cell Ig-like receptors (KIRs) modulate the cytotoxic effects of Natural Killer cells. KIR genes are encoded in the Leucocyte Receptor Complex and are characterized by their high haplotypic diversity and polymorphism. The KIR system has been studied in only three species of Old World monkeys, the rhesus macaque, the cynomolgus macaque, and the sabaeus monkey, displaying a complexity rivaling that of hominids (human and apes). Here we analyzed bacterial artificial chromosome draft sequences spanning the KIR haplotype of three other Old World monkeys, the vervet monkey (Chlorocebus aethiops), the olive baboon (Papio anubis) and the colobus monkey (Colobus guereza). A total of 25 KIR gene models were identified in these species, predicted to encode receptors with 1, 2, and 3 extracellular Ig domains, all of them with long cytoplasmic domains having two putative ITIMs, although three had a positively charged residue in the transmembrane domain. Sequence and phylogenetic analyses showed that most Old World monkeys shared five classes of KIR loci: i) KIR2DL5/3DL20 in the most centromeric region, followed by ii) the single Ig domain-encoding locus KIR1D, iii) the pseudogene KIR2DP, iv) the conserved KIR2DL4, and v) the highly diversified KIR3DL/H loci in the telomeric half of the cluster. An exception to this pattern was the KIR haplotype of the colobus monkey that lacked the KIR1D, KIR2DP, and KIR2DL4 loci of the central region of the cluster. Thus, Old World monkeys display a broad spectrum of KIR haplotype variation that has been generated upon an ancestral haplotype architecture by gene duplication, gene deletion, and non-homologous recombination.     

The apolipoprotein L gene cluster has emerged recently in evolution and is expressed in human vascular tissue

We previously isolated APOL3 (CG12-1) cDNA and now describe the isolation of APOL1 and APOL2 cDNA from an activated endothelial cell cDNA library and show their endothelialspecific expression in human vascular tissue. APOL1-APOL4 are clustered on human chromosome 22q13.1, as a result of tandem gene duplication, and were detected only in primates (humans and African green monkeys) and not in dogs, pigs, or rodents, showing that this gene cluster has arisen recently in evolution. The specific tissue distribution and gene organization suggest that these genes have diverged rapidly after duplication. This has resulted in the emergence of an additional signal peptide encoding exon that ensures secretion of the plasma high-density lipoprotein-associated APOL1. Our results show that the APOL1-APOL4 cluster might contribute to the substantial differences in the lipid metabolism of humans and mice, as dictated by the variable expression of genes involved in this process.     

Evolution of the primate APOBEC3A cytidine deaminase gene and identification of related coding regions

The APOBEC3 gene cluster encodes six cytidine deaminases (A3A-C, A3DE, A3F-H) with single stranded DNA (ssDNA) substrate specificity. For the moment A3A is the only enzyme that can initiate catabolism of both mitochondrial and nuclear DNA. Human A3A expression is initiated from two different methionine codons M1 or M13, both of which are in adequate but sub-optimal Kozak environments. In the present study, we have analyzed the genetic diversity among A3A genes across a wide range of 12 primates including New World monkeys, Old World monkeys and Hominids. Sequence variation was observed in exons 1-4 in all primates with up to 31% overall amino acid variation. Importantly for 3 hominids codon M1 was mutated to a threonine codon or valine codon, while for 5/12 primates strong Kozak M1 or M13 codons were found. Positive selection was apparent along a few branches which differed compared to positive selection in the carboxy-terminal of A3G that clusters with A3A among human cytidine deaminases. In the course of analyses, two novel non-functional A3A-related fragments were identified on chromosome 4 and 8 kb upstream of the A3 locus. This qualitative and quantitative variation among primate A3A genes suggest that subtle differences in function might ensue as more light is shed on this increasingly important enzyme.     

Ten different Polycomb group genes are required for spatial control of the abdA and AbdB homeotic products.

Mutations in genes of the Polycomb (Pc) group cause abnormal segmental development due to ectopic expression of the homeotic products of the Antennapedia and bithorax complexes. Here the requirements for Pc group genes in controlling the abdA and AbdB products of the bithorax complex are described. Embryos containing mutations in the genes Polycomb (Pc), extra sex combs (esc), Enhancer of zeste [E(z)], polyhomeotic (ph), Sex comb on midleg (Scm), Polycomb-like (Pcl), Sex comb extra (Sce), Additional sex combs (Asx), Posterior sex combs (Psc) and pleiohomeotic (pho) were examined. In every case, both abdA and AbdB are expressed outside of their normal domains along the anterior-posterior (A-P) axis, consistent with these Pc group products acting in a single pathway or molecular complex. The earliest detectable ectopic expression is highest in the parasegments immediately adjacent to the normal expression boundary. Surprisingly, in the most severe Pc group mutants, the earliest ectopic AbdB is distributed in a pair-rule pattern. At all stages, ectopic abdA in the epidermis is highest along the anterior edges of the parasegments, in a pattern that mimics the normal abdA cell-specific pattern. These examples of highly patterned mis-expression show that Pc group mutations do not cause indiscriminate activation of homeotic products. We suggest that the ectopic expression patterns result from factors that normally activate abdA and AbdB only in certain parasegments, but that in Pc group mutants these factors gain access to regulatory DNA in all parasegments.     

Primate evolution of the alpha-globin gene cluster and its Alu-like repeats

The arrangement of alpha-globin genes in Old World and New World monkeys and a prosimian, galago, has been determined by restriction mapping. Recombinant DNAs containing galago and Old World monkey alpha-globin genes have been isolated and subjected to a partial sequence determination for comparison to alpha-globin genes in human, chimpanzee and non-primate mammals. The results of this extensive structural analysis are relevant to several topics concerning the evolution of primate alpha-globin genes and Alu family repeats. All orders of higher primates (i.e. Old and New World monkeys, chimpanzee and human) have the same arrangement of alpha-globin genes. In contrast, the arrangement and correction of galago alpha-globin genes differ from those of higher primates, but are similar to those of non-primate mammals. The 5' and 3'-flanking regions of the human alpha 1 gene are orthologous to the corresponding region in galago, identifying the human alpha 2 gene as the more recently duplicated gene. The human psi alpha 1 gene is found to be inactivated after divergence of the human and galago lineages but prior to the divergence of human and monkey. Orthologous Alu family members in human and monkey DNAs indicate that the dispersion of some Alu repeats occurred prior to the divergence of these lineages. However, the Alu-like repeats of prosimian and higher primates result from entirely independent events giving rise to different repeat elements inserted at distinct genomic positions.     

ZNF674: a new kruppel-associated box-containing zinc-finger gene involved in nonsyndromic X-linked mental retardation

Array-based comparative genomic hybridization has proven to be successful in the identification of genetic defects in disorders involving mental retardation. Here, we studied a patient with learning disabilities, retinal dystrophy, and short stature. The family history was suggestive of an X-linked contiguous gene syndrome. Hybridization of full-coverage X-chromosomal bacterial artificial chromosome arrays revealed a deletion of ~1 Mb in Xp11.3, which harbors RP2, SLC9A7, CHST7, and two hypothetical zinc-finger genes, ZNF673 and ZNF674. These genes were analyzed in 28 families with nonsyndromic X-linked mental retardation (XLMR) that show linkage to Xp11.3; the analysis revealed a nonsense mutation, p.E118X, in the coding sequence of ZNF674 in one family. This mutation is predicted to result in a truncated protein containing the Kruppel-associated box domains but lacking the zinc-finger domains, which are crucial for DNA binding. We characterized the complete ZNF674 gene structure and subsequently tested an additional 306 patients with XLMR for mutations by direct sequencing. Two amino acid substitutions, p.T343M and p.P412L, were identified that were not found in unaffected individuals. The proline at position 412 is conserved between species and is predicted by molecular modeling to reduce the DNA-binding properties of ZNF674. The p.T343M transition is probably a polymorphism, because the homologous ZNF674 gene in chimpanzee has a methionine at that position. ZNF674 belongs to a cluster of seven highly related zinc-finger genes in Xp11, two of which (ZNF41 and ZNF81) were implicated previously in XLMR. Identification of ZNF674 as the third XLMR gene in this cluster may indicate a common role for these zinc-finger genes that is crucial to human cognitive functioning.     

A new gene family (FAM9) of low-copy repeats in Xp22.3 expressed exclusively in testis: implications for recombinations in this region

Illegitimate recombinations between low-copy repetitive elements (LCR) have been implicated in the pathogenesis of various chromosomal rearrangements. Two such duplicons have been reported previously on Xp22.3, the CRI-S232 elements, involved in the generation of deletions in the steroidsulfatase gene and five members of the G1.3 (DXF22S) repetitive sequence family. By molecular characterization of an Xp22/10q24 translocation, we identified one duplicon of the G1.3 family in the breakpoint region in Xp22.3. We show that G1.3 elements harbor at least three expressed genes, FAM9A, FAM9B, and FAM9C, and three putative pseudogenes, all mapped to Xp22.33-p22.31. The deduced amino acid sequence of the three novel proteins shows homology to SYCP3, a component of the synaptonemal complex located along the paired chromosomes during meiosis. FAM9A, FAM9B, and FAM9C are expressed exclusively in testis; their proteins are located in the nucleus, and FAM9A localizes to the nucleolus. The presence of genes within duplicons may represent putative recombination-promoting factors for actively transcribed genes in meiotic cells, with the resulting open chromatin structure facilitating unequal crossing-over events and chromosomal rearrangements.