Karyological study of Amphisbaena ridleyi (Squamata, Amphisbaenidae), an endemic species of the Archipelago of Fernando de Noronha, Pernambuco, Brazil

The karyotype of Amphisbaena ridleyi, an endemic species of the archipelago of Fernando de Noronha, in State of Pernambuco, Brazil, is described after conventional staining, Ag-NOR impregnation and fluorescence in situ hybridization (FISH) with a telomeric probe. The diploid number is 46, with nine pairs of macrochromosomes (three metacentrics, four subtelocentrics and two acrocentrics) and 14 pairs of microchromosomes. The Ag-NOR is located in the telomeric region of the long arm of metacentric chromosome 2 and FISH revealed signals only in the telomeric region of all chromosomes. Further cytogenetic data on other amphisbaenians as well as a robust phylogenetic hypothesis of this clade is needed in order to understand the evolutionary changes on amphisbaenian karyotypes.     

黑眉锦蛇的有丝分裂染色体和减数分裂联会复合体的观察

本工作以C带、硝酸银染色、对黑眉锦蛇(Elaphe taeniura)的有丝分裂染色体进行了显微观察。其二倍体染色体数目2n=36,核型组成为16(8m+6sm+2t)大染色体+20微小染色体。C带显现于几乎所有染色体的着丝粒区,有一对插入型C带位于第6对端着丝粒染色体。一个银染核仁组织区(NORs)位于No.12小染色体。同时以界面铺张——硝酸银染色技术,对黑届锦蛇减数分裂精母细胞联会复合体(SC)的结构进行了亚显微观察。发现黑眉锦蛇的SC结构与其他动物的SC相似,是由两股平行的侧线组成,SC组型与有丝分裂染色体组型有较好的一致性。     

鹌鹑的核型及G带分析

分别采用外周血淋巴细胞培养法和胰酶处理法,对鹌鹑染色体的核型和G带进行了研究。结果表明,鹌鹑染色体数目为2n=78,有10对大染色体（包括Z、W）,29对小染色体。染色体形态分别为：NO.1染色体为sm型,NO.2、Z染色体为m型,其余染色体均为t型,这与前人研究结果存在一定差异。G带分析结果显示,鹌鹑的前9对大染色体及Z、W染色体G带可分为27个区,134带。     

红嘴鸥核型及C带和银带

本文以骨髓细胞常规空气干燥法和Sumner(1972)的方法(C带),Howell(1980)的方法(银带),对近年来昆明过冬的红嘴鸥的核型及其C带和银带进行了分析,结果显示出:红嘴鸥的2n应为68±。多数染色体的着丝粒区均显示出一个深浅不同的C带。Z染色体上有一个微小而模糊的C带,而W染色体大部分染色质被深染。其染色体经快速银染后表明,2对NORs均在微小染色体上。     

Somatic chromosomes of squirrel monkey (Saimiri sciureus)

The chromosome complement of 2 male and 15 female adult squirrel monkeys (Saimiri sciureus) have been studied in peripheral blood and kidney cultures and bone marrow preparations. The diploid chromosome number is 44. Six of the chromosome pairs are metacentric (isobrachial), 9 pairs submetacentric (heterobrachial) and the remaining 6 pairs are acrocentric (cephalobrachial). The X chromosome is the longest submetacentric (heterobrachial), ranking 5 in order of decreasing size. The Y chromosome is the smallest acrocentric (cephalobrachial) of the complement.A female and male karyotype is presented.Supported, in part, by Grant HDO 1952-03 from the United States Public Health Service.     

The somatic chromosome complements of 16 species of falconiformes (Aves) and the karyological relationships of the order

Using short term leucocyte culture techniques, the somatic chromosome complements of 16 species of diurnal birds of prey, belonging to four different families of the order Falconiformes were studied. The karyotypes are described and illustrated, and of some species idiograms are presented. In accordance with the family classification, four karyologically different groups can be distinguished in the Falconiformes: (1) Cathartidae, with karyotypes which show only 7 pairs of biarmed macrochromosomes and a considerable number of small acrocentrics and microchromosomes (the diploid numbers are approximately 80). This is the only group in which really large macrochromosomes are found (over 10% TCL); (2) Falconidae, the karyotypes of which include only a single pair of biarmed macrochromosomes, all other elements being acrocentrics of medium to small size or microchromosomes (diploid numbers of approximately 84 and 52); (3) the secretary bird (Sagittariidae), with 36 biarmed macrochromosomes and 44 small acrocentrics and microchromosomes (2n=80 approximately); (4) Accipitridae, the representatives of which never possess more than about 8 real microchromosomes, while their karyotypes show varying numbers of biarmed and acrocentric macrochromosomes of small to medium size (diploid numbers range from 78 to 60).The possible karyological relationships within each of these groups are briefly discussed, while a more extensive discussion is dedicated to the possible relationships between these groups, and those between them and other avian taxa.The variation in karyotypic structures found in the Falconiformes is much wider than that in other avian groups. However, it remains an unanswered question whether this karyological heterogenelty points to a polyphyletic origin of the diurnal birds of prey. Especially the chromosome complements of the Accipitridae are most uncommon among birds, because of their extremely low numbers of real microchromosomes. However, of all the Falconiformes only the karyotypes of the Cathartidae have clear counterparts outside the order, since nearly identical complements were found in representatives of the Phoenicopteriformes and Gruiformes.The present work was partially carried out at the Institute of Genetics and the Center for Clinical Cytogenetics (both in Utrecht).     

铺道蚁的染色体核型分析

以商丘地区的铺道蚁Tetramorium caespitum(L.)早期胚胎为材料,采用低渗处理—烘干法制备染色体标本,对其染色体组型进行研究。结果表明,铺道蚁染色体组型为n=22,2n=44,是由10条中央着丝粒染色体,3条亚中着丝粒染色体和9条亚端着丝粒染色体组成。     

棕黑锦蛇赤峰亚种染色体组型、C带和Ag-NORs研究

以骨髓细胞为材料研究了棕黑锦蛇赤峰亚种的染色体, 结果表明,该物种的2n=36,由8对大型的和10对微小的染色体组成,AF=50。No.4为性染色体(ZW型);所有大型染色体均显示端粒深染C带,但仅NO.2、3、5和Z染色体显示着丝粒浅染C带。W染色体为整条C带阳性;该物种一对NOR分布于微小染色体。锦蛇属核型可能经历过染色体间的着丝粒融合的罗伯逊易位。 Abstract:This paper reports the karyotype,C-bands and Ag-NORs of Elaphe schrenckii anomala(Boulenger).The diploid number,2n=36,comprising 8 pairs of macro- and 10 pairs of microchromosomes in the E.s.anomala.AF=50.The No.4 is sex chromosome,which belong to ZW type.The C-banding technique revealed telomeric constitutive heterochromatin in the whole macrochromosome.But the centromeric C band was only observed in No.2,3,5 and Z chromosome,while a whole W chromosome is constitutive heterochromatinization.Two NORs was observed in group of microchromosome.     

Mapping homology between human and black and white colobine monkey chromosomes by fluorescent in situ hybridization

We used in situ hybridization of chromosome specific DNA probes (“chromosome painting”) of all human chromosomes to establish homologies between the human and the white and black colobus (Colobus guereza 2n = 44). The 24 human paints gave 31 signals on the autosomes (haploid male chromosome set). Robertsonian translocations between chromosomes homologus to human 14 and 15, 21 and 22, form colobine chromosomes 6 and 16, respectively. Reciprocal translocations were found between human chromosomes 1 and 10, 1 and 17, as well as 3 and 19. The alternating hybridization signals between human 3 and 19 on Colobus chromosome 12 show that in this case a reciprocal translocation was followed by a pericentric inversion. The hybridization data show that in spite of the same diploid number and similar Fundamental Numbers, the black and white colobine monkey differs from Presbytis cristata, an Asian colobine, by 6 reciprocal translocations. Comparisons with the hybridization patterns in other primates show that some Asian colobines have a more derived karyotype with respect to African colobines, macaques, great apes, and humans. Chromosome painting also clearly shows that similarities in diploid number and chromosome morphology both between colobines and gibbons are due to convergence. Am. J. Primatol. 42:289–298, 1997. © 1997 Wiley-Liss, Inc.     

Cytogenetics of Alismatales s.s.: chromosomal evolution and C-banding

Ten species of Alismatales, five of Alismataceae, four of Limnocharitaceae and one of Hydrocharitaceae were studied with regard to chromosome number, chromosome morphology, and pattern of Giemsa C-bands. The genus Echinodorus had a diploid chromosome number of 22 for all species that were analyzed and a karyotypic formula of 2m + 20a. For the family Limnocharitaceae, Hydrocleys nymphoides had a diploid chromosome number of 16, Hydrocleys martii (4m + 2sm + 10a) had a diploid chromosome number of 16, Limnocharis flava had a diploid chromosome number of 20 and L. laforestii (4m + 16a) had a diploid chromosome number of 20. The only species of Hydrocharitaceae that was studied exhibited a karyotype that consisted of a diploid chromosome number of 28 and a karyotypic formula of 4m + 6sm + 4a. The distribution pattern of the C-banded karyotype in Echinodorus showed four blocks of constitutive heterochromatin in two smaller acrocentric pairs that corresponded to the heterochromatic NORs. In E. lanceolatus, 14 bands in the termini of the arms beyond the heterochromatic NORs of seven acrocentric pairs were also observed. Idiograms are presented and the karyotypic evolution patterns for the studied groups are discussed.     

Developments in avian cytotaxonomy: implications for Afro-avian Species

Ejere. VC. 2000. Developments in avian cytotaxonomy: implications for Afro-avian Species. Ostrich 71 (1 & 2): 40.

Karyological studies of the extant species of birds have progressed slower than those of other animal groups. To date, a paltry proportion of less than 20% of about an estimated 9 000 avian species have been karyotyped, such that for most orders, karyological information remains largely scanty. Data accumulated so far, has revealed a lot of interesting features of the typical avian karyotype. Essentially, the karyotype is dichotomous, containing several pairs of fairly big chromosomes (= macrochomosomes) and very small to minute chromosome elements (= microchromosmes). The diploid chromosome number is also variable, ranging from 2n = 40 to 2n = 92 with a mode of 2n = 80 chromosomes observed in a majority of species. Studies have further revealed that chromosomal evolution in birds is highly conservative especially with reference to the first 3 pairs of macrochromosomes. (Group A), while considerable variability in number and morphology occurs in the remaining groups of chromosome elements. These variabilities, as well as the homologies revealed by chromosome banding techniques, have aided the cytotaxonomy of various individual avian groups. In this review, the karyological as well as the phylogenetic relationships of the various avian species so far karyotyped, vis-a-vis the cytotaxonomic implications for the abundant Afro-avian fauna are highlighted. Similarly, the significance of the observed peculiarities in the avian karyotype is briefly discussed. Suggestions are proffered in respect of the application of karyotype analysis technique to bird conservation in Africa. This will focus mainly on the identification of the gender of birds for the singular purpose of breeding rare and endangered species for zoological gardens and related institutions.     

Karyotype of a Japanese salamander Hynobius katoi and its implication on breeding ecology (Amphibia: Caudata)

Karyotype of a Japanese small salamander, Hynobius katoi, was first described. All individuals examined had 2n=58 chromosomes, consisting of nine pairs of biarmed macrochromosomes, four pairs of biarmed medium-sized chromosomes, six pairs of biarmed microchromosomes, and 10 pairs of uniarmed microchromosomes, although distinction of the second and the third groups of chromosome pairs was not clear. All pairs appeared homologous and no sexual dimorphism was found. Possession of 2n=58 chromosomes in H. katoi strongly suggests its lotic-breeding habits as was expected from the number and size of eggs and adult morphology. When compared morphology of chromosomes among lotic-breeders with 2n=58 chromosomes, metacentric nature of No. 10 seems to characterize the karyotype of H. katoi.     

Chromosomes of tuatara, Sphenodon, a chromosome heteromorphism and an archaic reptilian karyotype

We examined karyotypes of the endemic New Zealand reptile genus Sphenodon (tuatara) from five populations, finding a karyotype unchanged for at least one million years. Animals karyotyped were from five geographically distinct populations, representing three groups, namely S. guntheri, S. punctatus (Cook Strait group), and S. punctatus (northeastern North Island group). All five populations have a diploid chromosome number of 2n = 36, consisting of 14 pairs of macrochromosomes and four pairs of microchromosomes. Chromosomal differences were not found between the five populations nor between female and male animals, except for one animal with a structural heteromorphism. Similarity between Sphenodon and Testudine karyotypes suggests an ancestral karyotype with a macrochromosome complement of 14 pairs and the ability to accumulate variable numbers of microchromosome pairs. Our research supports molecular phylogenies of the Reptilia.     

Chromosome studies in four species of Ratitae (Aves)

Chromosomes were studied in female specimens of the ostrich, Struthio camelus L., cassowary, Casuarius casuarius (L.), emu, Dromiceius novaehollandiae (Lath.) and rhea, Rhea americana L. by means of blood and feather pulp culture techniques. Male karyotypes were also studied in the emu and rhea. The diploid chromosome number was most likely 80 in the ostrich and rhea and 82 in the emu, while the exact number could not be determined in the cassowary. Karyotypes of the 4 species were strikingly similar and apparently interchangeable with one another with slight modifications of the centromeric position in one or two pairs of macrochromosomes. No heteromorphic macrochromosomal pair was found either in female specimens or in male ones of the ratite species so far examined, except for a female rhea. This specimen was found to possess an acrocentric chromosome which was evidently a member of nos. 4–6, but considerably smaller than any other chromosome of the group. ³H-thymidine autoradiography provided no more information than the straightforward morphological analysis with regard to the differentiation of the sex-chromosomes.Contributions from the Chromosome Research Unit, Hokkaido University. Dedicated to Emeritus Professor Sajiro Makino on the occasion of his retirement, in honor of his 40 years' service with the University. Supported by a grant from the Scientific Research Fund of the Ministry of Education (No. 584099).     

Cytogenetic characterization of the Zebra Mussel Dreissena polymorpha (Pallas) from Miedwie Lake, Poland

Cytogenetic characterization of D. polymorpha was carried out using banding techniques such as C-banding, fluorochrome CMA3 and silver nitrate treatment. The diploid chromosome number of both investigated D. polymorpha forms (typical and albinotic) was the same 2n = 32 (NF = 56). The karyotype consisted of 5 pairs of metacentric, 7 pairs of submetacentric and four pairs of subtelo-acrocentric chromosomes. Ag-NORs were located in the telomeric position on the largest subtelo-acrocentric chromosome pair. C banding patterns indicate many sites of constitutive heterochromatin mainly located in the telomeric regions and interstitially in some chromosomes. CMA3-sites were observed in almost all chromosomes; apart from the Ag-NORs sites, they were located terminally on the chromosome arms and interstitially on three chromosome pairs. Sixteen chromosomes could be counted at the diakinesis stage of meiosis. No differences in banding chromosome patterns were found neither between both analyzed forms of D. polymorpha nor between males and females.     

The chromosomes of the Canadian Beaver Castor canadensis.

A chromosome analysis of 24 Canadian beavers, Castor canadensis Kuhl (12 males and 12 females), captured in Laurentides Park, Qébec, has been performed from preparations of blood lymphocyte and skin cultures. The chromosome number was found to be 2n = 40. Measurements were made to determine relative lengths and arm ratios of chromosomes, which are metacentric or submetacentric. Results are in agreement with those already published regarding the chromosome number, but differ in the identification of the X chromosome, and in the morphology of the Y and some autosomes. C- ad G-banding techniques allowed the precise identification of individual chromosome pairs. A detailed idiogram of G-bands is presented.     

Identification of the linkage group of the Z sex chromosomes of the sand lizard (Lacerta agilis,Lacertidae) and elucidation of karyotype evolution in lacertid lizards

The sand lizard (Lacerta agilis, Lacertidae) has a chromosome number of 2n?=?38, with 17 pairs of acrocentric chromosomes, one pair of microchromosomes, a large acrocentric Z chromosome, and a micro-W chromosome. To investigate the process of karyotype evolution in L. agilis, we performed chromosome banding and fluorescent in situ hybridization for gene mapping and constructed a cytogenetic map with 86 functional genes. Chromosome banding revealed that the Z chromosome is the fifth largest chromosome. The cytogenetic map revealed homology of the L. agilis Z chromosome with chicken chromosomes 6 and 9. Comparison of the L. agilis cytogenetic map with those of four Toxicofera species with many microchromosomes (Elaphe quadrivirgata, Varanus salvator macromaculatus, Leiolepis reevesii rubritaeniata, and Anolis carolinensis) showed highly conserved linkage homology of L. agilis chromosomes (LAG) 1, 2, 3, 4, 5(Z), 7, 8, 9, and 10 with macrochromosomes and/or macrochromosome segments of the four Toxicofera species. Most of the genes located on the microchromosomes of Toxicofera were localized to LAG6, small acrocentric chromosomes (LAG11–18), and a microchromosome (LAG19) in L. agilis. These results suggest that the L. agilis karyotype resulted from frequent fusions of microchromosomes, which occurred in the ancestral karyotype of Toxicofera and led to the disappearance of microchromosomes and the appearance of many small macrochromosomes.     

A karyological study of three species of Scincidae (Reptilia)

In this paper the Authors decribe the karyogram of three species of Scincidae (Chalcides chalcides chalcides, Chalcides ocellatus tiligugu, and Mabuya striata). The diploid number of these species is 2n=28. It is not possible to subdivide the chromosome set in micro- and macrochromosomes or to recognize the heterochromosomes morphologically. Ch. ocellatus and M. striata have very similar karyograms; that of Ch. ch. chalcides is different in that chromosomes 6, 7, 8, 9, and 10 are acrocentric. Pericentric inversion is probably involved in the karyotypic evolution of these species.     

太平洋鳕染色体核型及银染分析

以野生太平洋鳕为材料,采用植物血球凝集素（PHA）及秋水仙素体内注射法,取头肾细胞经低渗、固定后,常规空气干燥法制备染色体标本,并对其染色体核型进行了分析。结果表明,太平洋鳕的二倍体染色体数目为2n=46,核型公式为:2n=8m+6sm+20st+12t,NF=60,即有4对中部着丝点染色体、3对亚中部着丝点染色体、10对亚端部着丝点染色体和6对端位着丝点染色体,染色体臂数为NF=60;染色体经银染后,Ag-NORs在不同间期细胞中表现出多态性,数目为13,其中2个Ag-NORs的频率最高（82%）;在分裂相中,具有1个Ag-NORs的频率最高（87.1%）,且在第12对亚端部着丝点染色体的一条带有明显的次缢痕,为Ag-NORs所在区域,并未发现Ag-NORs联合现象及性别相关的异型染色体。