蓝狐-卫星DNA的克隆及序列分析

利用限制性内切酶酶切蓝狐基因组, 经琼脂糖凝胶电泳, 对特异性亮带进行克隆、测序及序列分析。结果获得42个卫星DNA序列, 该卫星DNA单体大小为737 bp, G+C含量为51.9%, 单体之间同源性为91%~97%; 每个单体由3个约245 bp的亚重复串联构成, 亚重复之间的同源性为49%~55%; 在物种进化过程中, 该卫星DNA有G+C含量逐渐降低而A+T含量逐渐上升的趋势; 该卫星DNA为犬科动物种属所特有, 与犬着丝粒相关卫星DNA为同类卫星DNA, 同源性为74%, 命名为α-卫星DNA。     

赤狐线粒体全基因组及系统发育分析

测定了赤狐的线粒体基因组全序列,总长度为16 723 bp,碱基组成为：31.3% A、26.1% C、14.8% G、27.8% T。和大多数哺乳动物一样,赤狐的线粒体全基因组包含13个蛋白质编码基因、2个核糖体RNA基因、22个转运RNA基因和1个控制区。除ND3基因起始密码子为不常见的ATT外,赤狐与北极狐、狼、家犬、郊狼的线粒体蛋白质编码遵循相同模式。在控制区的保守序列区段1和2之间发现一段较长的富含AC的随机重复序列。为了验证赤狐与其他犬科动物的系统发育关系,利用12个重链蛋白质编码基因,分别通过邻接法和最大简约法构建了系统发育树。结果表明：赤狐与北极狐是姐妹群,它们在犬科中都属于赤狐型分支,而灰狼、家犬和郊狼则属于狼型分支,与现有的系统进化研究结果一致。     

Origin and evolution of a major feline satellite DNA

A major satellite DNA has been cloned from the domestic cat (Felis catus) and characterized. The satellite monomer, termed FA-SAT, is 483 base-pairs in size, 64% G + C, and represents about 1 to 2% of the cat genome. A consensus sequence based upon partial sequence data from 21 independently isolated clones demonstrates: (1) FA-SAT is not composed of a series of shorter repeats, although about 25 copies, primarily imperfect, of the hexanucleotide TAACCC appear in the sequence; (2) there are many more CpG dinucleotides present in FA-SAT than expected for a random sequence of its size; and (3) 61% of all base substitutions in FA-SAT involve the replacement of G and C residues by A and T residues, indicating that FA-SAT is rapidly becoming A + T-rich. FA-SAT-related sequences are found in many mammals, where they appear to be scattered throughout the genome and not tandemly arranged as in the cat. An FA-SAT-related sequence was cloned from the domestic dog genome and sequenced, and shown to contain multiple copies of the same TAACCC hexanucleotide found in the cat satellite.     

Detection of satellite DNA in Palorus ratzeburgii: analysis of curvature profiles and comparison with Tenebrio molitor satellite DNA.

Very abundant and homogenous satellite DNA has been found in the flour beetle Palorus ratzeburgii, representing 40% of its genome. Sequencing of 14 randomly cloned satellite monomers revealed a conserved monomer length of 142 bp and an average A+T content of 68%. Sequence variation analysis showed that base substitutions, appearing with a frequency of 2.3%, are predominant differences among satellite monomers. The satellite sequence is unique without significant direct repeats and with only two potentially stable inverted repeats. After electrophoresis of satellite monomers on native polyacrylamide gel retarded mobilities characteristic for curved DNA molecules are observed. The curvature profiles and DNA helix axis trajectory are calculated on the basis of three different algorithms. These calculations predict that P ratzeburgii satellite DNA forms a left-handed solenoid superstructure. Comparison of described features with other satellite DNAs reveals some striking similarities with satellite DNA from related species Tenebrio molitor, which belongs to the same family of Tenebrionidae. Both satellites are very abundant and homogenous with the same, highly conserved monomer length, although there is no homology at the nucleotide level. Their monomers, as well as multimers, exhibit very similar retarded electrophoretic mobilities. The calculated curvature profiles predict two bend centers in monomers of each satellite, resulting in a model of left-handed solenoid superstructures of similar appearance.     

Complex organization of a cryptic satellite DNA in the genome of the marine invertebrate Rapana thomasiana Grosse (Gastropoda)

Isopicnic centrifugation in Cs2SO4-Ag+ gradients at pH 7.0 reveals that the genome of the marine snail Rapana thomasiana Grosse (Gastropoda) contains an AT-rich satellite fraction comprising 5% of the DNA. Restriction enzyme analysis shows that the satellite DNA is composed of a number of related subsets arranged in tandem arrays. They have evolved from the segmental amplification of an 1460 bp long monomer unit with a complex inner organization. Most probably, the present basic repeat originates from an ancestral 400-500 bp long sequence in which some insertions and/or deletions have occurred.     

A comparative analysis of MC4R gene sequence, polymorphism, and chromosomal localization in Chinese raccoon dog and Arctic fox

Numerous mutations of the human melanocortin receptor type 4 (MC4R) gene are responsible for monogenic obesity, and some of them appear to be associated with predisposition or resistance to polygenic obesity. Thus, this gene is considered a functional candidate for fat tissue accumulation and body weight in domestic mammals. The aim of the study was comparative analysis of chromosome localization, nucleotide sequence, and polymorphism of the MC4R gene in two farmed species of the Canidae family, namely the Chinese raccoon dog (Nycterutes procyonoides procyonoides) and the arctic fox (Alopex lagopus). The whole coding sequence, including fragments of 3'UTR and 5'UTR, shows 89% similarity between the arctic fox (1276 bp) and Chinese raccoon dog (1213 bp). Altogether, 30 farmed Chinese raccoon dogs and 30 farmed arctic foxes were searched for polymorphisms. In the Chinese raccoon dog, only one silent substitution in the coding sequence was identified; whereas in the arctic fox, four InDels and two single-nucleotide polymorphisms (SNPs) in the 5'UTR and six silent SNPs in the exon were found. The studied gene was mapped by FISH to the Chinese raccoon dog chromosome 9 (NPP9q1.2) and arctic fox chromosome 24 (ALA24q1.2-1.3). The obtained results are discussed in terms of genome evolution of species belonging to the family Canidae and their potential use in animal breeding.     

Detection of satellite DNA in Palorus ratzeburgii: Analysis of curvature profiles and comparison with Tenebrio molitor satellite DNA

Very abundant and homogenous satellite DNA has been found in the flour beetle Palorus ratzeburgii, representing 40% of its genome. Sequencing of 14 randomly cloned satelite monomers revealed a conserved monomer length of 142 bp and an average A+T content of 68%. Sequence variation analysis showed that base substitutions, appearing with a frequency of 2.3%, are predominant differences among satellite monomers. The satellite sequence is unique without significant direct repeats and with only two potentially stable inverted repeats. After electrophoresis of satellite monomers on native polyacrylamide gel retarded mobilities characteristic for curved DNA molecules are observed. The curvature profiles and DNA helix axis trajectory are calculated on the basis of three different algorithms. These calculations predict that P ratzeburgii satellite DNA forms a left-handed solenoid superstructure. Comparison of described features with other satellite DNAs reveals some striking similarities with satellite DNA from related species Tenebrio molitor, which belongs to the same family of Tenebrionidae. Both satellites are very abundant and homogenous with the same, highly conserved monomer length, although there is no homology at the nucleotide level. Their monomers, as well as multimers, exhibit very similar retarded electrophoretic mobilities. The calculated curvature profiles predict two bend centers in monomers of each satellite, resulting in a model of left-handed solenoid superstructures of similar appearance.     

Phylogenetic implications of the 38 putative ancestral chromosome segments for four canid species.

Chromosome homologies between the Japanese raccoon dog (Nectereutes procyonoides viverrinus, 2n = 39 + 2-4 B chromosomes) and domestic dog (Canis familiaris, 2n = 78) have been established by hybridizing a complete set of canine paint probes onto high-resolution G-banded chromosomes of the raccoon dog. Dog chromosomes 1, 13, and 19 each correspond to two raccoon dog chromosome segments, while the remaining 35 dog autosomes each correspond to a single segment. In total, 38 dog autosome paints revealed 41 conserved segments in the raccoon dog. The use of dog painting probes has enabled integration of the raccoon dog chromosomes into the previously established comparative map for the domestic dog, Arctic fox (Alopex lagopus), and red fox (Vulpes vulpes). Extensive chromosome arm homologies were found among chromosomes of the red fox, Arctic fox, and raccoon dog. Contradicting previous findings, our results show that the raccoon dog does not share a single biarmed autosome in common with the Arctic fox, red fox, or domestic cat. Comparative analysis of the distribution patterns of conserved chromosome segments revealed by dog paints in the genomes of the canids, cats, and human reveals 38 ancestral autosome segments. These segments could represent the ancestral chromosome arms in the karyotype of the most recent ancestor of the Canidae family, which we suggest could have had a low diploid number, based on comparisons with outgroup species.     

The longest (A+T) and (G+C) blocks in the human and other genomes

We analysed complete or almost complete nucleotide sequences of the human, chimp, mouse, rat, chicken, dog, and other genomes to find that they contain extremely long (A+T) a (G+C) blocks that do not occur at all in the corresponding randomized sequences. The longest is an (A+T) block containing 1040 consecutive AT pairs that occurs in the 16th human chromosome. The longest human (G+C) block has 261 bp in length. About a half of the longest blocks occur in introns. The (A+T) blocks are discrete units whereas the (G+C) blocks are diffuse. They are imbedded in the genome through connectors longer than 1 kilobase where the (G+C) content gradually decreases to the value of 50%. Remarkably, the (A+T) as well as (G+C) blocks are substantially shorter in the chimp genome. Chicken is characteristic by very long (G+C) blocks that are even longer than in the human genome. Though much shorter, long (G+C) and especially (A+T) blocks occur in lower organisms as well, which means that AT and GC pair clustering is an ancient property that has evolved into large scales in higher eukaryote genomes and the human genome in particular. Very long (A+T) and (G+C) blocks confer specific biophysical properties on DNA that are likely to influence genome folding in cell nuclei and its functional properties.     

Chromosomal evolution of the Canidae. II. Divergence from the primitive carnivore karyotype

The Giemsa-banding patterns of chromosomes from the arctic fox (Alopex lagopus), the red fox (Vulpes vulpes), the kit fox (Vulpes macrotis), and the raccoon dog (Nyctereutes procyonoides) are compared. Despite their traditional placement in different genera, the arctic fox and the kit fox have an identical chromosome morphology and G-banding pattern. The red fox has extensive chromosome arm homoeology with these two species, but has only two entire chromosomes in common. All three species share some chromosomes with the raccoon dog, as does the high diploid-numbered grey wolf (Canis lupus, 2n = 78). Moreover, some chromosomes of the raccoon dog show partial or complete homoeology with metacentric feline chromosomes which suggests that these are primitive canid chromosomes. We present the history of chromosomal rearrangements within the Canidae family based on the assumption that a metacentric-dominated karyotype is primitive for the group.     

Polymorphism of prion protein gene in Arctic fox (<Emphasis Type="Italic">Vulpes lagopus</Emphasis>)

Prion diseases are fatal neurodegenerative disorders of humans and certain other mammals. Prion protein gene (Prnp) is associated with susceptibility and species barrier to prion diseases. No natural and experimental prion diseases have been documented to date in Arctic fox. In the present study, coding region of Prnp from 135 Arctic foxes were cloned and screened for polymorphisms. Our results indicated that the Arctic fox Prnp open reading frame (ORF) contains 771 nucleotides encoding 257 amino acids. Four single nucleotide polymorphisms (SNPs) (G312C, A337G, C541T, and A723G) were identified. SNPs G312C and A723G produced silent mutations, but SNPs A337G and C541T resulted in a M–V change at codon 113 and R–C at codon 181, respectively. The Arctic fox Prnp amino acid sequence was similar to that of the dog (XM 542906). In short, this study provides preliminary information about genotypes of Prnp in Arctic fox.     

The Longest (A+T) and (G+C) Blocks in the Human and Other Genomes

Abstract

We analysed complete or almost complete nucleotide sequences of the human, chimp, mouse, rat, chicken, dog, and other genomes to find that they contain extremely long (A+T) a (G+C) blocks that do not occur at all in the corresponding randomized sequences. The longest is an (A+T) block containing 1040 consecutive AT pairs that occurs in the 16^th human chromosome. The longest human (G+C) block has 261 bp in length. About a half of the longest blocks occur in introns. The (A+T) blocks are discrete units whereas the (G+C) blocks are diffuse. They are embeeded in the genome through connectors longer than 1 kilobase where the (G+C) content gradually decreases to the value of 50%. Remarkably, the (A+T) as well as (G+C) blocks are substantially shorter in the chimp genome. Chicken is characteristic by very long (G+C) blocks that are even longer than in the human genome. Though much shorter, long (G+C) and especially (A+T) blocks occur in lower organisms as well, which means that AT and GC pair clustering is an ancient property that has evolved into large scales in higher eukaryote genomes and the human genome in particular. Very long (A+T) and (G+C) blocks confer specific biophysical properties on DNA that are likely to influence genome folding in cell nuclei and its functional properties.     

Evolution of Tribolium madens (Insecta,Coleoptera) Satellite DNA Through DNA Inversion and Insertion

Two different satellite DNAs from tenebrionid speciesTribolium madens (Insecta, Coleoptera) have been detected, cloned, and sequenced. Satellite I comprises 30% of the genome; it has a monomer size of 225 by and a high A + T content of 74%. Satellite 11, with a monomer size of 711 by and A + T content of 70%, is less abundant, making 4% of the total DNA. Sequence variability of the monomers relative to consensus sequence is 4.1% and 1.2% for satellite I and II, respectively. Both satellites are localized in the heterochromatic regions of all chromosomes. A search for internal motifs showed that both satellites contain a related subsequences, about 100 by long. The creation of satellite I monomer is explained by duplication of the basic subunit, followed by subsequent divergence by single point mutations, deletions, and gene conversion. Inversion of the subsequence in addition to its duplication has occurred in satellite II. The result of this inversion is possible formation of a long, stable dyad structure. The 408-bp sequence, inserted within satellite II monomer, shares no similarity with a basic subunit. Frequent direct repeats found within the inserted sequence point to its evolution by duplication of shorter motifs. It is proposed that both satellites have been derived from a common ancestral sequence whose duplication played a major role in the formation of satellite I monomer, while insertion of a new sequence together with inversion of an ancestral one induced the occurrence of satellite II. Correspondence to: D. Ugarković     

Heterogeneity of the Canidae Bsp-repeats family: discovery of the EcoRI subfamily]

A 1600 bp EcoRI fragment was cloned from genome of raccoon dog. The structure obtained is homologous to the Canidae Bsp-repeats family. Comparative blot hybridization of the EcoRI fragment and BamHI repeat from fox genome with restricted hydrolysates of the total of raccoon dog and fox DNAs revealed differences both in structure and genomic organization between these two Bsp-repeats versions. Evidently, the EcoRI fragment contains a sequence lacking from the BamHI fragment of the fox Bsp-repeats. Quantitative differences in contents of two Bsp versions in various canid genomes were revealed as well. The EcoRI version is most abundant in raccoon dog genome, while the BamHI fox version is most representative in polar fox genome. With other species studied, quantitative differences in version contents are not so dramatic, and the EcoRI fragment is always present in lower copy numbers. The discovery of the EcoRI subfamily of the Bsp-repeats is in accordance with the "library hypothesis" advanced by Salser in 1976. Connection of the Bsp-repeats' evolution with centric fusions and breaks characteristic of karyotype evolution of canids is being discussed. Comparative study of cloned EcoRI and BamHI fragments of Bsp-repeats in cytogenetical and molecular aspects may be useful, when investigating the role of tandem repeats in large chromosome rearrangements.     

Genetic variability in a family of satellite DNAs from tilapia (Pisces: Cichlidae).

We have cloned and sequenced members of a family of satellite DNAs from three genera of the tilapiine tribe of fishes: Oreochromis, Sarotherodon, and Tilapia. The satellite DNAs, visualized as intensely staining bands following electrophoretic separation of EcoRI-digested genomic DNA, consist of three size variants differentially distributed in the various tilapiine species. The sizes of the monomers are approximately 237 bp (type I), 230 bp (type II), and 209 bp (type III). Several cloned monomers were sequenced from Oreochromis niloticus (type III), Oreochromis placidus (types I and II), Sarotherodon galilaeus (type I), Tilapia zillii (type I), and Tilapia rendalli (type I). Comparison of derived consensus sequences for the monomer units of the satellite DNAs revealed sequence identities within and between species that ranged from 89 to 96%. The type II and type III size variants appear to have arisen by deletions of 9 and 29 bp, respectively, within different regions of the type I satellite. Hybridization of a cloned monomer satellite from O. niloticus (type III) to PalI digests of genomic DNA from all three genera detected polymorphic, high molecular weight restriction fragments that produced fingerprint-like patterns. The complexity of these DNA fingerprints varied from one species to another, suggesting a markedly different genomic organization for these polymorphic satellite DNAs.     

Cloning and characterization of a tandemly repeated DNA sequence in the crane family (Gruidae)

A tandemly repeated DNA sequence possessing a unique PstI site has been characterized in several species of the crane family. The "Pst family" comprises at least 8800 monomer units 187 base pairs (bp) in length and constitutes 0.14% of the genome of the sarus crane (Grus antigone). The array is located in the centromeric heterochromatin of chromosome 2 in the two species where in situ hybridizations of a cloned monomer to metaphase chromosome spreads were carried out. DNA sequence comparisons between five monomer units from G. antigone revealed a high degree of homology between four of the individual repeats, while the fifth was somewhat divergent. The G + C content deduced from the DNA sequence makes it likely that the Pst family constitutes part of a density satellite seen in profiles of crane DNA centrifuged to equilibrium in CsCl. The common occurrence of tandem arrays such as the Pst family, with repeat lengths close to 200 bp, leads us to an hypothesis implicating nucleosomes in the evolution of such families.     

A new AluI satellite DNA in the root-knot nematode Meloidogyne fallax: relationships with satellites from the sympatric species M. hapla and M. chitwoodi

A highly abundant satellite DNA comprising 20% of the Meloidogyne fallax (Nematoda, Tylenchida) genome was cloned and sequenced. The satellite monomer is 173 bp long and has a high A + T content of 72.3%, with frequent runs of A's and T's. The sequence variability of the monomers is 2.7%, mainly due to random distribution of single-point mutations. A search for evidence of internal repeated subunits in the monomer sequence revealed a 6-bp motif (AAATTT) for which five degenerated repeats, differing by just a single base pair, could be identified. Pairwise comparison of the M. fallax satellite with those from the sympatric species Meloidogyne chitwoodi and Meloidogyne hapla revealed a high sequence similarity (68.39%) with one satellite DNA subfamily in M. chitwoodi, which indicated an unexpected close relationship between them. Given the high copy number and the extreme sequence homogeneity among monomeric units, it may be assumed that the satellite DNA of M. fallax could have evolved through some recent and extensive amplification burst in the nematode genome. In this case, its relatively short life would not yet have allowed the accumulation of random mutations in independent amplified repeats. Considering the morphological resemblance between the two species and their ability to produce interspecific fertile hybrids under controlled conditions, these results indicate that M. fallax may share a common ancestor with M. chitwoodi, from which it could have diverged recently. All these data suggest that M. fallax could be the result of a recent speciation process and show that Meloidogyne satellite DNAs may be of interest to resolve phylogenetic relationships among closely related species from this genus.      

Non-concerted evolution of the RET76 satellite DNA family in Reticulitermes taxa (Insecta, Isoptera)

The evolutionary dynamics of satellite DNA is most often studied in canonical mating systems, where bisexuality and panmixis are the rule. In eusocial termites, the limited number of reproducers starting a new colony and the maintenance of the colony through few neotenics act as bottle-necks both in space and time. No data on repetitive DNA are available for Isoptera and for their peculiar reproductive strategy. Here we present the first satellite DNA family isolated in European Reticulitermes. RET76 is a G+C rich satellite embodying two sub-families with a 76 bp monomer. RET76 sequences are highly variable (sequence homology is lower than 80% within sub-families and lower than 68% in the entire family) and this variability is equally distributed among the eight analysed taxa, thus depicting a pattern of non-concerted evolution. The absence of variant fixation – together with the strict monomer length conservation – may be explained at the molecular level as due to functional constraints acting on these sequences, and/or at the organismic level by considering the involvement of eusociality in preventing or greatly reducing variant fixation, somehow mimicking an unisexual strategy.     

Sequence characteristics of a cervid DNA repeat family

The (G + C) distribution and the presence and amounts of repetitive sequence families in the white-tailed deer (Odocoileus virginianus) have been examined. The distribution ranges from 20 to 70% (G + C) and shows four distinct repeat families. A 0.7-kb family, DII, corresponds to satellite II in domestic bovids—ox, sheep, and goat—and was singled out for detailed characterization. DII has a prototypic repeat of 67% (G + C), consists of 25,000 tandem copies, and contributes 1.7% to the genomic DNA. Sequencing and electrophoretic analysis indicate a repeat length of 691 bp. These characteristics are similar to those of the bovid satellite II families as well as to those of other cervids that we have examined. The intraspecific sequence divergence within this family has a variance of only 2.5 ± 0.3%. Present address: ICRP, Room 533, Lincoln's Inn Fields, London WC2A 3PX, England. Correspondence to: R.D. Blake     

Complex organization of a cryptic satellite DNA in the genome of the marine invertebrate Rapana thomasiana Grosse (Gastropoda)

Isopicnic centrifugation in Cs₂SO₄-Ag⁺ gradients at pH 7.0 reveals that the genome of the marine snail Rapana thomasiana Grosse (Gastropoda) contains an AT-rich satellite fraction comprising 5% of the DNA. Restriction enzyme analysis shows that the satellite DNA is composed of a number of related subsets arranged in tandem arrays. They have evolved from the segmental amplification of an 1460 bp long monomer unit with a complex inner organization. Most probably, the present basic repeat originates from an ancestral 400–500 bp long sequence in which some insertions and/or deletions have occurred.