Localization of Shaw-related K+ channel genes on mouse and human chromosomes

Four related genes, Shaker, Shab, Shaw, and Shal, encode voltage-gated K⁺ channels in Drosophila. Multigene subfamilies corresponding to each of these Drosophila genes have been identified in rodents and primates; this suggests that the four genes are older than the common ancestor of present-day insects and mammals and that the expansion of each into a family occurred before the divergence of rodents and primates.In order to define these evolutionary relationships more precisely and to facilitate the search for mammalian candidate K⁺ channel gene mutations, we have mapped members of the Shaw-homologous gene family in humans and mice. Fluorescence in situ hybridization analysis of human metaphase chromosomes mapped KCNC2 (KShIIIA, KV3.2) and KCNC3 (KShIIID, KV3.3) to Chromosome (Chr) 19q13.3-q13.4. Inheritance patterns of DNA restriction fragment length variants in recombinant inbred strains of mice placed the homologous mouse genes on distal Chr 10 near Ms15-8 and Mdm-1. The mouse Kcnc1 (KShIIIB, NGK2-KV4, KV3.1) gene mapped to Chr 7 near Tam-1.These results are consistent with the hypothesis that the generation of the mammalian KCNC gene family included both duplication events to generate family members in tandem arrays (KCNC2, KCNC3) and dispersion of family members to unlinked chromosomal sites (KCNC1). The KNCN2 and KCNC3 genes define a new synteny group between humans and mice.     

Molecular Characterization and Evolution of the SPRR Family of Keratinocyte Differentiation Markers Encoding Small Proline-Rich Proteins

SPRR genes (formerly SPR) encode a novel class of polypeptides (small pr oline rich proteins) that are strongly induced during differentiation of human epidermal keratinocytes in vitro and in vivo. Recently we found that the N- and C-terminal domains of these proteins show strong sequence homology to loricrin and involucrin, suggesting that SPRR proteins constitute a new class of cornified envelope precursor proteins. Here we show that SPRR proteins are encoded by closely related members of a gene family, consisting of two genes for SPRR1, approximately seven genes for SPRR2, and a single gene for SPRR3. All SPRR genes are closely linked within a 300-kb DNA segment on human chromosome 1 band q21-q22, a region where the related loricrin and involucrin genes have also been mapped. The most characteristic feature of the SPRR gene family resides in the structure of the central segments of the encoded polypeptides that are built up from tandemly repeated units of either eight (SPRR1 and SPRR3) or nine (SPRR2) amino acids with the general consensus *K*PEP**. Sequencing data of the different members, together with their clustered chromosomal organization, strongly suggest that this gene family has evolved from a single progenitor gene by multiple intra- and intergenic duplications. Analysis of the different SPRR subfamilies reveals a gene-specific bias to either intra- or intergenic duplication. We propose that a process of homogenization has acted on the different members of one subfamily, whereas the different subfamilies appear to have diverged from each other, at the levels of both protein structure and gene regulation.     

Chromosomal mapping in the mouse of eight K-channel-genes representing the four Shaker-like subfamilies Shaker, Shab, Shaw, and Shal

The four Shaker-like subfamilies of Shaker-, Shab-,Shaw-, and Shal-related K⁺ channels in mammals have been defined on the basis of their sequence homologies to the corresponding Drosophila genes. Using interspecific backcrosses between Mus musculus and Mus spretus, we have chromosomally mapped in the mouse the Shaker-related K⁺-channel genes Kcna1, Kcna2, Kcna4, Kcna5, and Kcna6; the Shab-related gene Kcnb1; the Shaw-related gene Kcnc4; and the Shal-related gene Kcnd2. The following localizations were determined: Chr 2, cen-Acra-Kcna4-Pax-6-a-Pck-1-Kras-3-Kcnb1 (corresponding human Chrs 11p and 20q, respectively); Chr 3, cen-Hao-2-(Kcna2, Kcnc4)-Amy-1 (human Chr 1); and Chr 6, cen-Cola-2-Met-Kcnd2-Cpa-Tcrb-adr/Clc-1-Hox-1.1-Myk-103-Raf-1-(Tpi-1, Kcna1, Kcna5, Kcna6) (human Chrs 7q and 12p, respectively). Thus, there is a cluster of at least three Shaker-related K⁺-channel genes on distal mouse Chr 6 and a cluster on Chr 2 that at least consists of one Shaker-related and one Shaw-related gene. The three other K⁺-channel genes are not linked to each other. The map positions of the different types of K⁺-channel genes in the mouse are discussed in relation to those of their homologs in man and to hereditary diseases of mouse and man that might involve K⁺ channels.     

Ion channels and epilepsy in man and mouse

Inherited disorders of voltage-gated ion channels are a recently recognized etiology of epilepsy in the developing and mature central nervous system. Two human epilepsy syndromes, benign familial neonatal convulsions and generalized epilepsy with febrile seizures plus, represent K+ and Na+ channelopathies, and other newly defined syndromes have now been mapped to chromosomal regions that are rich in ion channel genes. Experimental mouse models promise a resolution of their intriguing pathophysiology, which includes a diverse array of cellular phenotypes consistent with the differential contributions of individual channels to excitability in neural networks.     

Chromosomal location of fifteen unique mouse KRAB-containing zinc finger loci

The mammalian genome contains hundreds if not thousands of zinc finger protein (Zfp) genes. While the function of most of these genes remains to be determined, it is clear that a few of them play important roles in gene regulation and development. In studies described here, we have used an interspecific mouse backcross mapping panel to determine the chromosomal location of 15 KRAB-containing zinc finger loci. These loci map to nine different mouse autosomes and the X Chromosome (Chr). Two Chrs, 7 and 9, contain cosegregating pairs of KRAB-containing Zfp genes, indicating that the KRAB-containing Zfp genes have evolved through processes involving regional as well as genome-wide duplication events. Received: 1 February 1996 / Accepted: 1 March 1996     

Molecular evolution of a multigene family in group A streptococci

The emm genes are members of a gene family in group A streptococci (GAS) that encode for antiphagocytic cell-surface proteins and/or immunoglobulin-binding proteins. Previously sequenced genes in this family have been named "emm," "fcrA," "enn," "arp," "protH," and "mrp"; herein they will be referred to as the "emm gene family." The genes in the emm family are located in a cluster occupying 3-6 kb between the genes mry and scpA on the chromosome of Streptococcus pyogenes. Most GAS strains contain one to three tandemly arranged copies of emm-family genes in the cluster, but the alleles within the cluster vary among different strains. Phylogenetic analysis of the conserved sequences at the 3' end of these genes differentiates all known members of this family into four evolutionarily distinct emm subfamilies. As a starting point to analyze how the different subfamilies are related evolutionarily, the structure of the emm chromosomal region was mapped in a number of diverse GAS strains by using subfamily-specific primers in the polymerase chain reaction. Nine distinct chromosomal patterns of the genes in the emm gene cluster were found. These nine chromosomal patterns support a model for the evolution of the emm gene family in which gene duplication followed by sequence divergence resulted in the generation of four major-gene subfamilies in this locus.      

Evolutionary dynamics of leucine-rich repeat receptor-like kinases and related genes in plants：A phylogenomic approach

Leucine-rich repeat （LRR） receptor-like kinases （RLKs）, evolutionarily related LRR receptor-like proteins （RLPs） and receptor-like cytoplasmic kinases （RLCKs） have important roles in plant signaling, and their gene subfamilies are large with a complicated history of gene duplication and loss. In three pairs of closely related lineages, including Arabidopsis thaliana and A. lyrata （Arabidopsis）, Lotus japonicus, and Medicago truncatula （Legumes）, Oryza sativa ssp. japonica, and O. sativa ssp. indica （Rice）, we find that LRR RLKs comprise the largest group of these LRR-related subfamilies, while the related RLCKs represent the smal est group. In addition, comparison of orthologs indicates a high frequency of reciprocal gene loss of the LRR RLK/LRR RLP/RLCK subfamilies. Furthermore, pairwise comparisons show that reciprocal gene loss is often associated with lineage-specific duplication（s） in the alternative lineage. Last, analysis of genes in A. thaliana involved in development revealed that most are highly conserved orthologs without species-specific duplication in the two Arabidopsis species and originated from older Arabidopsis-specific or rosid-specific duplications. We discuss＆amp;nbsp;potential pitfal s related to functional prediction for genes that have undergone frequent turnover （duplications, losses, and domain architecture changes）, and conclude that prediction based on phylogenetic relationships wil likely outperform that based on sequence similarity alone.     

Evolution of EF-hand calcium-modulated proteins. V. The genes encoding EF-hand proteins are not clustered in mammalian genomes

Summary The chromosomal assignments of genes belonging to the EF-hand family which have a common origin are compiled in this article. So far data are available from 27 human gene loci belonging to 6 subfamilies and 8 murine loci belonging to 4 subfamilies. Chromosomal localization has been obtained by somatic-cell hybrid analysis using the Southern blot technique or PCR amplification, metaphase spread in situ hybridization, or isolation of the particular genes from chromosome-specific libraries. Except for genes of the S-100 alpha proteins which are grouped on human chromosome 1q12-25 and mouse chromosome 3, no linkage has been found for genes encoding EF-hand proteins, indicating absence of selective pressure for maintaining chromosomal clustering. Six of these genes map to known syntenic groups conserved in the human and mouse genomes. This suggests that chromosomal translocations occurred before divergence of these species. The possible significance of chromosomal positioning with respect to nearby located known genes and genetic disease loci is discussed.     

Enhanced Closed-state Inactivation in a Mutant Shaker K+ Channel

Many mutations that shift the voltage dependence of activation in Shaker channels cause a parallel shift of inactivation. The I2 mutation (L382I in the Shaker B sequence) is an exception, causing a 45 mV activation shift with only a 9 mV shift of inactivation midpoint relative to the wildtype (WT) channel. We compare the behavior of WT and I2 Shaker 29-4 channels in macropatch recordings from Xenopus oocytes. The behavior of WT channels can be described by both simple and detailed kinetic models which assume that inactivation proceeds only from the open state. The behavior of I2 channels requires that they inactivate from closed states as well, a property characteristic of voltage-gated sodium channels. A detailed ``multiple-state inactivation' model is presented that describes both activation and inactivation of I2 channels. The results are consistent with the view that residue L382 is associated with the receptor for the inactivation particles in Shaker channels. Received: 16 December 1996/Revised: 5 February 1997     

Molecular cloning and characterization of LKv1, a novel voltage‐gated potassium channel in leech

We have cloned a novel voltage‐gated K channel, LKv1, in two species of leech. The properties of LKv1 expressed in transiently transfected HEK293 cells is that of a delayed rectifier current. LKv1 may be a major modulator of excitability in leech neurons, since antibody localization studies show that LKv1 is expressed in the soma and axons of all neurons in both the central and peripheral nervous systems. Comparison of the biophysical and pharmacological properties of LKv1 with native voltage‐gated conductances in leech neurons suggests that LKv1 may correspond to the previously characterized delayed rectifier current, I_K. Phylogenetic analysis of LKv1 shows that it is related to the Shaker subfamily of voltage‐gated K channels although it occupies a separate branch from that of the monophyletic Shaker clade composed of the flatworm, Aplysia, Drosophila, and mammalian Shaker homologs as well as from that of two recently identified Shaker‐related K channels in jellyfish. Thus, this analysis indicates that this group of voltage‐gated K channels contains several evolutionarily divergent lineages. © 1999 John Wiley & Sons, Inc. J Neurobiol 38: 287–299, 1999     

Determination of copy number and linkage relationships among five actin gene subfamilies in Petunia hybrida

The actin gene superfamily of Petunia hybrida cv. Mitchell contains greater than 100 gene members which have been divided into several highly divergent subfamilies [1]. Five subfamily-specific probes have been used to compare the actin genes among the Mitchell, Violet 23 (V23) and Red 51 (R51) cultivars of P. hybrida. The sum total of actin genes in these five subfamilies was estimated to be between 10 and 34 members in both V23 and R51. Restriction fragment length polymorphisms (RFLPs) between V23 and R51 were examined with these five probes and eleven different restriction endonucleases. Among the 55 comparisons, 87% exhibited RFLPs. These data indicate extreme divergence between V23 and R51 in DNA sequence and/or the presence of small insertions and deletions surrounding these actin gene subfamilies. This divergence suggests that V23 and R51, which have contrasting phenotypic marker loci on every chromosome, may be useful for the development of a complete RFLP linkage map of the Petunia genome. The segregation of Hind III RFLPs among the progeny of two backcrosses demonstrated that representatives of the five subfamilies of Petunia actin genes exist at four distinct genetic locations and suggested that two of these loci are tightly linked. Apparently, amplification of the numerous members of the Petunia actin gene superfamily occurred via gene dispersal of the original subfamily progenitors and not primarily as a result of amplification of a single chromosomal region.     

Identification of 18 mouse ABC genes and characterization of the ABC superfamily in Mus musculus

ATP-binding cassette (ABC) genes encode a family of transport proteins known to be involved in a number of human genetic diseases. In this study, we characterized the ABC superfamily in Mus musculus through in silico gene identification and mapping and phylogenetic analysis of mouse and human ABC genes. By querying dbEST with amino acid sequences from the conserved ATP-binding domains, we identified and partially sequenced 18 new mouse ABC genes, bringing the total number of mouse ABC genes to 34. Twelve of the new ABC genes were mapped in the mouse genome to the X chromosome and to 10 of the 19 autosomes. Phylogenetic relationships of mouse and human ABC genes were examined with maximum parsimony and neighbor-joining analyses that demonstrated that mouse and human ABC orthologs are more closely related than are mouse paralogs. The mouse ABC genes could be grouped into the seven previously described human ABC subfamilies. Three mouse ABC genes mapped to regions implicated in cholesterol gallstone susceptibility.     

Comparative sequence analysis of a single-gene conserved segment in mouse and human

Comparative mapping and sequencing of the mouse and human genomes have defined large, conserved chromosomal segments in which gene content and order are highly conserved. These regions span megabase-sized intervals and together comprise the vast majority of both genomes. However, the evolutionary relationships among the small remaining portions of these genomes are not as well characterized. Here we describe the sequencing and annotation of a 341-kb region of mouse Chr 2 containing nine genes, including biliverdin reductase A (Blvra), and its comparison with the orthologous regions of the human and rat genomes. These analyses reveal that the known conserved synteny between mouse Chromosome (Chr) 2 and human Chr 7 reflects an interval containing one gene (Blvra/BLVRA) that is, at most, just 34 kb in the mouse genome. In the mouse, this segment is flanked proximally by genes orthologous to human chromosome 15q21 and distally by genes orthologous to human Chr 2q11. The observed differences between the human and mouse genomes likely resulted from one or more rearrangements in the rodent lineage. In addition to the resulting changes in gene order and location, these rearrangements also appear to have included genomic deletions that led to the loss of at least one gene in the rodent lineage. Finally, we also have identified a recent mouse-specific segmental duplication. These finding illustrate that small genomic regions outside the large mouse–human conserved segments can contain a single gene as well as sequences that are apparently unique to one genome. The nucleotide sequence data reported in this paper have been submitted to GenBank and assigned the accession numbers AC074224 and AC074041.     

Phylogenetic Analysis of the Cytochrome P450 3 (CYP3) Gene Family

Cytochrome P450 genes (CYP) constitute a superfamily with members known from the Bacteria, Archaea, and Eukarya. The CYP3 gene family includes the CYP3A and CYP3B subfamilies. Members of the CYP3A subfamily represent the dominant CYP forms expressed in the digestive and respiratory tracts of vertebrates. The CYP3A enzymes metabolize a wide variety of chemically diverse lipophilic organic compounds. To understand vertebrate CYP3 diversity better, we determined the killifish (Fundulus heteroclitus) CYP3A30 and CYP3A56 and the ball python (Python regius) CYP3A42 sequences. We performed phylogenetic analyses of 45 vertebrate CYP3 amino acid sequences using a Bayesian approach. Our analyses indicate that teleost, diapsid, and mammalian CYP3A genes have undergone independent diversification and that the ancestral vertebrate genome contained a single CYP3A gene. Most CYP3A diversity is the product of recent gene duplication events. There is strong support for placement of the guinea pig CYP3A genes within the rodent CYP3A diversification. The rat, mouse, and hamster CYP3A genes are mixed among several rodent CYP3A subclades, indicative of a complex history involving speciation and gene duplication. Phylogenetic analyses suggest two CYP3A gene duplication events early in rodent history, with the rat CYP3A9 and mouse Cyp3a13 clade having a sister relationship to all other rodent CYP3A genes. In primate history, the human CYP3A43 gene appears to have a sister relationship to all other known primate CYP3A genes. Other, more recent gene duplications are hypothesized to have occurred independently within the human, pig, rat, mouse, guinea pig, and fish genomes. Functional analyses suggest that gene duplication is strongly tied to acquisition of new function and that convergent evolution of CYP3A function may be frequent among independent gene copies. Current address (Rachel L. Cox): Laboratory of Aquatic Biomedicine, Marine Biology Laboratory, Woods Hole, MA 02543, USA     

Genetic and physical mapping of the natural resistance-associated macrophage protein 1 (NRAMP1) in chicken

The chicken natural resistance-associated macrophage protein 1 (NRAMP1) gene has been mapped by linkage analysis by use of a reference panel to develop the chicken molecular genetic linkage map and by fluorescence in situ hybridization. The chicken homolog of the murine Nramp1 gene was mapped to a linkage group located on Chromosome (Chr) 7q13, which includes three genes (CD28, NDUSF1, and EF1B) that have previously been mapped either to mouse Chr 1 or to human Chr 2q. Physical mapping by pulsed-field gel electrophoresis revealed that NRAMP1 is tightly linked to the villin gene and that the genomic organization (gene order and presence of CpG islands) of the chromosomal region carrying NRAMP1 is well conserved between the chicken and mammalian genomes. The regions on mouse Chr 1, human Chr 2q, and chicken Chr 7q that encompass NRAMP1 represent large conserved chromosomal segments between the mammalian and avian genomes. The chromosome mapping of the chicken NRAMP1 gene is a first step in determining its possible role in differential susceptibility to salmonellosis in this species.     

Expanded Functional Diversity of Shaker K+ Channels in Cnidarians Is Driven by Gene Expansion

The genome of the cnidarian Nematostella vectensis (starlet sea anemone) provides a molecular genetic view into the first nervous systems, which appeared in a late common ancestor of cnidarians and bilaterians. Nematostella has a surprisingly large and diverse set of neuronal signaling genes including paralogs of most neuronal signaling molecules found in higher metazoans. Several ion channel gene families are highly expanded in the sea anemone, including three subfamilies of the Shaker K⁺ channel gene family: Shaker (Kv1), Shaw (Kv3) and Shal (Kv4). In order to better understand the physiological significance of these voltage-gated K⁺ channel expansions, we analyzed the function of 18 members of the 20 gene Shaker subfamily in Nematostella. Six of the Nematostella Shaker genes express functional homotetrameric K⁺ channels in vitro. These include functional orthologs of bilaterian Shakers and channels with an unusually high threshold for voltage activation. We identified 11 Nematostella Shaker genes with a distinct “silent” or “regulatory” phenotype; these encode subunits that function only in heteromeric channels and serve to further diversify Nematostella Shaker channel gating properties. Subunits with the regulatory phenotype have not previously been found in the Shaker subfamily, but have evolved independently in the Shab (Kv2) family in vertebrates and the Shal family in a cnidarian. Phylogenetic analysis indicates that regulatory subunits were present in ancestral cnidarians, but have continued to diversity at a high rate after the split between anthozoans and hydrozoans. Comparison of Shaker family gene complements from diverse metazoan species reveals frequent, large scale duplication has produced highly unique sets of Shaker channels in the major metazoan lineages.     

Chromosomal translocation and segmental duplication in Cryptococcus neoformans

Large chromosomal events such as translocations and segmental duplications enable rapid adaptation to new environments. Here we marshal genomic, genetic, meiotic mapping, and physical evidence to demonstrate that a chromosomal translocation and segmental duplication occurred during construction of a congenic strain pair in the fungal human pathogen Cryptococcus neoformans. Two chromosomes underwent telomere-telomere fusion, generating a dicentric chromosome that broke to produce a chromosomal translocation, forming two novel chromosomes sharing a large segmental duplication. The duplication spans 62,872 identical nucleotides and generated a second copy of 22 predicted genes, and we hypothesize that this event may have occurred during meiosis. Gene disruption studies of one embedded gene (SMG1) corroborate that this region is duplicated in an otherwise haploid genome. These findings resolve a genome project assembly anomaly and illustrate an example of rapid genome evolution in a fungal genome rich in repetitive elements.     

Evolution of Vertebrate Voltage-Gated Ion Channel α Chains by Sequential Gene Duplication

Phylogenetic analysis of alpha chains of voltage-gated ion channels revealed that extensive gene duplication has occurred among both Ca(2+) and Na(+)-channels since the origin of vertebrates. Rather than showing a pattern of gene duplication consistent with the hypothesis of polyploidization early in vertebrate history, both Ca(2+) and Na(+) channels showed patterns of sequential gene duplication associated with specialization of the gene products. In the case of Na(+) channels, the phylogeny supported the hypothesis that the ancestral vertebrate gene had an expression pattern including both central and peripheral nervous system cells and that duplication of vertebrate Na(+) channel genes has repeatedly been followed by specialization for the central nervous system, the peripheral nervous system, or muscle cells. Thus, cephalization in vertebrate evolution has been accompanied by specialization of this important family of neuromuscular proteins along the central-peripheral axis.