Your search keyword '"Graphodatsky, Alexander S."' showing total 14 results

1. Maps of Constitutive-Heterochromatin Distribution for Four Martes Species (Mustelidae, Carnivora, Mammalia) Show the Formative Role of Macrosatellite Repeats in Interspecific Variation of Chromosome Structure

Author

Beklemisheva, Violetta R., primary, Lemskaya, Natalya A., additional, Prokopov, Dmitry Yu., additional, Perelman, Polina L., additional, Romanenko, Svetlana A., additional, Proskuryakova, Anastasia A., additional, Serdyukova, Natalya A., additional, Utkin, Yaroslav A., additional, Nie, Wenhui, additional, Ferguson-Smith, Malcolm A., additional, Yang, Fentang, additional, and Graphodatsky, Alexander S., additional

Published

2023

2. Genetic History of the Altai Breed Horses: From Ancient Times to Modernity.

Author

Kusliy, Mariya A., Yurlova, Anna A., Neumestova, Alexandra I., Vorobieva, Nadezhda V., Gutorova, Natalya V., Molodtseva, Anna S., Trifonov, Vladimir A., Popova, Kseniya O., Polosmak, Natalia V., Molodin, Vyacheslav I., Vasiliev, Sergei K., Semibratov, Vladimir P., Iderkhangai, Tumur-O., Kovalev, Alexey A., Erdenebaatar, Diimaajav, Graphodatsky, Alexander S., and Tishkin, Alexey A.

Subjects

HORSE breeding, HORSE breeds, MITOCHONDRIAL DNA, HYPERVARIABLE regions, MODERNITY, GENETIC markers

Abstract

This study focuses on expanding knowledge about the genetic diversity of the Altai horse native to Siberia. While studying modern horses from two Altai regions, where horses were subjected to less crossbreeding, we tested the hypothesis, formulated on the basis of morphological data, that the Altai horse is represented by two populations (Eastern and Southern) and that the Mongolian horse has a greater genetic proximity to Eastern Altai horses. Bone samples of ancient horses from different cultures of Altai were investigated to clarify the genetic history of this horse breed. As a genetic marker, we chose hypervariable region I of mitochondrial DNA. The results of the performed phylogenetic and population genetic analyses of our and previously published data confirmed the hypothesis stated above. As we found out, almost all the haplotypes of the ancient domesticated horses of Altai are widespread among modern Altai horses. The differences between the mitochondrial gene pools of the ancient horses of Altai and Mongolia are more significant than between those of modern horses of the respective regions, which is most likely due to an increase in migration processes between these regions after the Early Iron Age. [ABSTRACT FROM AUTHOR]

Published

2023

3. New Data on Comparative Cytogenetics of the Mouse-Like Hamsters (Calomyscus Thomas, 1905) from Iran and Turkmenistan

Author

Romanenko, Svetlana A., primary, Malikov, Vladimir G., additional, Mahmoudi, Ahmad, additional, Golenishchev, Feodor N., additional, Lemskaya, Natalya A., additional, Pereira, Jorge C., additional, Trifonov, Vladimir A., additional, Serdyukova, Natalia A., additional, Ferguson-Smith, Malcolm A., additional, Aliabadian, Mansour, additional, and Graphodatsky, Alexander S., additional

Published

2021

4. Traces of Late Bronze and Early Iron Age Mongolian Horse Mitochondrial Lineages in Modern Populations

Author

Kusliy, Mariya A., primary, Vorobieva, Nadezhda V., additional, Tishkin, Alexey A., additional, Makunin, Alexey I., additional, Druzhkova, Anna S., additional, Trifonov, Vladimir A., additional, Iderkhangai, Tumur-O., additional, and Graphodatsky, Alexander S., additional

Published

2021

5. Karyotype Evolution in 10 Pinniped Species: Variability of Heterochromatin versus High Conservatism of Euchromatin as Revealed by Comparative Molecular Cytogenetics

Author

Beklemisheva, Violetta R., primary, Perelman, Polina L., additional, Lemskaya, Natalya A., additional, Proskuryakova, Anastasia A., additional, Serdyukova, Natalya A., additional, Burkanov, Vladimir N., additional, Gorshunov, Maksim B., additional, Ryder, Oliver, additional, Thompson, Mary, additional, Lento, Gina, additional, O’Brien, Stephen J., additional, and Graphodatsky, Alexander S., additional

Published

2020

6. Complex Structure of Lasiopodomys mandarinus vinogradovi Sex Chromosomes, Sex Determination, and Intraspecific Autosomal Polymorphism

Author

Romanenko, Svetlana A., primary, Smorkatcheva, Antonina V., additional, Kovalskaya, Yulia M., additional, Prokopov, Dmitry Yu., additional, Lemskaya, Natalya A., additional, Gladkikh, Olga L., additional, Polikarpov, Ivan A., additional, Serdyukova, Natalia A., additional, Trifonov, Vladimir A., additional, Molodtseva, Anna S., additional, O’Brien, Patricia C. M., additional, Golenishchev, Feodor N., additional, Ferguson-Smith, Malcolm A., additional, and Graphodatsky, Alexander S., additional

Published

2020

7. Next Generation Sequencing of Chromosome-Specific Libraries Sheds Light on Genome Evolution in Paleotetraploid Sterlet (Acipenser ruthenus).

Author

Andreyushkova, Daria A., Makunin, Alexey I., Beklemisheva, Violetta R., Romanenko, Svetlana A., Druzhkova, Anna S., Biltueva, Larisa S., Serdyukova, Natalya A., Graphodatsky, Alexander S., and Trifonov, Vladimir A.

Subjects

STERLET, FISH genetics, FISH DNA, CHROMOSOMES, FLUORESCENCE in situ hybridization

Abstract

Several whole genome duplication (WGD) events followed by rediploidization took place in the evolutionary history of vertebrates. Acipenserids represent a convenient model group for investigation of the consequences of WGD as their representatives underwent additional WGD events in different lineages resulting in ploidy level variation between species, and these processes are still ongoing. Earlier, we obtained a set of sterlet (Acipenser ruthenus) chromosome-specific libraries by microdissection and revealed that they painted two or four pairs of whole sterlet chromosomes, as well as additional chromosomal regions, depending on rediploidization status and chromosomal rearrangements after genome duplication. In this study, we employed next generation sequencing to estimate the content of libraries derived from different paralogous chromosomes of sterlet. For this purpose, we aligned the obtained reads to the spotted gar (Lepisosteus oculatus) reference genome to reveal syntenic regions between these two species having diverged 360 Mya. We also showed that the approach is effective for synteny prediction at various evolutionary distances and allows one to clearly distinguish paralogous chromosomes in polyploid genomes. We postulated that after the acipenserid-specific WGD sterlet karyotype underwent multiple interchromosomal rearrangements, but different chromosomes were involved in this process unequally. [ABSTRACT FROM AUTHOR]

Published

2017

8. X Chromosome Evolution in Cetartiodactyla.

Author

Proskuryakova, Anastasia A., Kulemzina, Anastasia I., Perelman, Polina L., Makunin, Alexey I., Larkin, Denis M., Farré, Marta, Kukekova, Anna V., Johnson, Jennifer Lynn, Lemskaya, Natalya A., Beklemisheva, Violetta R., Roelke-Parker, Melody E., Bellizzi, June, Ryder, Oliver A., O'Brien, Stephen J., and Graphodatsky, Alexander S.

Subjects

X chromosome, CETACEA, BACTERIAL artificial chromosomes, HIPPOPOTAMUS, SEX chromosomes, FLUORESCENCE in situ hybridization

Abstract

The phenomenon of a remarkable conservation of the X chromosome in eutherian mammals has been first described by Susumu Ohno in 1964. A notable exception is the cetartiodactyl X chromosome, which varies widely in morphology and G-banding pattern between species. It is hypothesized that this sex chromosome has undergone multiple rearrangements that changed the centromere position and the order of syntenic segments over the last 80 million years of Cetartiodactyla speciation. To investigate its evolution we have selected 26 evolutionarily conserved bacterial artificial chromosome (BAC) clones from the cattle CHORI-240 library evenly distributed along the cattle X chromosome. High-resolution BAC maps of the X chromosome on a representative range of cetartiodactyl species from different branches: pig (Suidae), alpaca (Camelidae), gray whale (Cetacea), hippopotamus (Hippopotamidae), Java mouse-deer (Tragulidae), pronghorn (Antilocapridae), Siberian musk deer (Moschidae), and giraffe (Giraffidae) were obtained by fluorescent in situ hybridization. To trace the X chromosome evolution during fast radiation in specious families, we performed mapping in several cervids (moose, Siberian roe deer, fallow deer, and Pere David's deer) and bovid (muskox, goat, sheep, sable antelope, and cattle) species. We have identified three major conserved synteny blocks and rearrangements in different cetartiodactyl lineages and found that the recently described phenomenon of the evolutionary new centromere emergence has taken place in the X chromosome evolution of Cetartiodactyla at least five times. We propose the structure of the putative ancestral cetartiodactyl X chromosome by reconstructing the order of syntenic segments and centromere position for key groups. [ABSTRACT FROM AUTHOR]

Published

2017

9. Intrachromosomal Rearrangements in Rodents from the Perspective of Comparative Region-Specific Painting.

Author

Romanenko, Svetlana A., Serdyukova, Natalya A., Perelman, Polina L., Pavlova, Svetlana V., Bulatova, Nina S., Golenishchev, Feodor N., Stanyon, Roscoe, and Graphodatsky, Alexander S.

Subjects

CHROMOSOMAL rearrangement, BIOLOGICAL adaptation, MOLECULAR biology, CHROMOSOMES, DICROSTONYX, LABORATORY rodents, PHYSIOLOGY

Abstract

It has long been hypothesized that chromosomal rearrangements play a central role in different evolutionary processes, particularly in speciation and adaptation. Interchromosomal rearrangements have been extensively mapped using chromosome painting. However, intrachromosomal rearrangements have only been described usingmolecular cytogenetics in a limited number ofmammals, including a few rodent species. This situation is unfortunate because intrachromosomal rearrangements aremore abundant than interchromosomal rearrangements and probably contain essential phylogenomic information. Significant progress in the detection of intrachromosomal rearrangement is now possible, due to recent advances in molecular biology and bioinformatics. We investigated the level of intrachromosomal rearrangement in the Arvicolinae subfamily, a species-rich taxon characterized by very high rate of karyotype evolution. We made a set of region specific probes by microdissection for a single syntenic region represented by the p-arm of chromosome 1 of Alexandromys oeconomus, and hybridized the probes onto the chromosomes of four arvicolines (Microtus agrestis,Microtus arvalis,Myodes rutilus, and Dicrostonyx torquatus). These experiments allowed us to show the intrachromosomal rearrangements in the subfamily at a significantly higher level of resolution than previously described. We found a number of paracentric inversions in the karyotypes of M. agrestis and M. rutilus, as well as multiple inversions and a centromere shift in the karyotype of M. arvalis. We propose that during karyotype evolution, arvicolines underwent a significant number of complex intrachromosomal rearrangements that were not previously detected. [ABSTRACT FROM AUTHOR]

Published

2017

10. Comparative Chromosome Mapping of Musk Ox and the X Chromosome among Some Bovidae Species.

Author

Proskuryakova, Anastasia A., Kulemzina, Anastasia I., Perelman, Polina L., Yudkin, Dmitry V., Lemskaya, Natalya A., Okhlopkov, Innokentii M., Kirillin, Egor V., Farré, Marta, Larkin, Denis M., Roelke-Parker, Melody E., O'Brien, Stephen J., Bush, Mitchell, and Graphodatsky, Alexander S.

Subjects

X chromosome, GENE mapping, KARYOTYPES, CHROMOSOME structure, SPECIES, ANTELOPES

Abstract

Bovidae, the largest family in Pecora infraorder, are characterized by a striking variability in diploid number of chromosomes between species and among individuals within a species. The bovid X chromosome is also remarkably variable, with several morphological types in the family. Here we built a detailed chromosome map of musk ox (Ovibos moschatus), a relic species originating from Pleistocene megafauna, with dromedary and human probes using chromosome painting. We trace chromosomal rearrangements during Bovidae evolution by comparing species already studied by chromosome painting. The musk ox karyotype differs from the ancestral pecoran karyotype by six fusions, one fission, and three inversions. We discuss changes in pecoran ancestral karyotype in the light of new painting data. Variations in the X chromosome structure of four bovid species nilgai bull (Boselaphus tragocamelus), saola (Pseudoryx nghetinhensis), gaur (Bos gaurus), and Kirk's Dikdik (Madoqua kirkii) were further analyzed using 26 cattle BAC-clones. We found the duplication on the X in saola. We show main rearrangements leading to the formation of four types of bovid X: Bovinae type with derived cattle subtype formed by centromere reposition and Antilopinae type with Caprini subtype formed by inversion in XSB1. [ABSTRACT FROM AUTHOR]

Published

2019

11. Sequencing of Supernumerary Chromosomes of Red Fox and Raccoon Dog Confirms a Non-Random Gene Acquisition by B Chromosomes.

Author

Makunin, Alexey I., Beklemisheva, Violetta R., Romanenko, Svetlana A., Perelman, Polina L., Druzhkova, Anna S., Prokopov, Dmitry Yu., Graphodatsky, Alexander S., Trifonov, Vladimir A., Petrova, Kristina O., Chernyaeva, Ekaterina N., Johnson, Jennifer L., Kukekova, Anna V., Yang, Fengtang, and Ferguson-Smith, Malcolm A.

Subjects

RED fox, RACCOON dog, CELL cycle regulation, CHROMOSOME fragments, NUCLEOTIDE sequencing, CELL division, PROTO-oncogenes

Abstract

B chromosomes (Bs) represent a variable addition to the main karyotype in some lineages of animals and plants. Bs accumulate through non-Mendelian inheritance and become widespread in populations. Despite the presence of multiple genes, most Bs lack specific phenotypic effects, although their influence on host genome epigenetic status and gene expression are recorded. Previously, using sequencing of isolated Bs of ruminants and rodents, we demonstrated that Bs originate as segmental duplications of specific genomic regions, and subsequently experience pseudogenization and repeat accumulation. Here, we used a similar approach to characterize Bs of the red fox (Vulpes vulpes L.) and the Chinese raccoon dog (Nyctereutes procyonoides procyonoides Gray). We confirm the previous findings of the KIT gene on Bs of both species, but demostrate an independent origin of Bs in these species, with two reused regions. Comparison of gene ensembles in Bs of canids, ruminants, and rodents once again indicates enrichment with cell-cycle genes, development-related genes, and genes functioning in the neuron synapse. The presence of B-chromosomal copies of genes involved in cell-cycle regulation and tissue differentiation may indicate importance of these genes for B chromosome establishment. [ABSTRACT FROM AUTHOR]

Published

2018

12. The Case of X and Y Localization of Nucleolus Organizer Regions (NORs) in Tragulus javanicus (Cetartiodactyla, Mammalia).

Author

Kulemzina, Anastasia I., Serdukova, Natalia A., Proskuryakova, Anastasia A., Perelman, Polina L., Graphodatsky, Alexander S., and Ryder, Oliver A.

Subjects

NUCLEOLUS, TRAGULUS javanicus, MAMMALS, RECOMBINANT DNA, CHEVROTAINS

Abstract

There are differences in number and localization of nucleolus organizer regions (NORs) in genomes. In mammalian genomes, NORs are located on autosomes, which are often situated on short arms of acrocentric chromosomes and more rarely in telomeric, pericentromeric, or interstitial regions. In this work, we report the unique case of active NORs located on gonоsomes of a eutherian mammal, the Javan mouse-deer (Tragulus javanicus). We have investigated the position of NORs by FISH experiments with ribosomal DNA (rDNA) sequences (18S, 5.8S, and 28S) and show the presence of a single NOR site on the X and Y chromosomes. The NOR is localized interstitially on the p-arm of the X chromosome in close proximity with prominent C-positive heterochromatin blocks and in the pericentromeric area of mostly heterochromatic Y. The NOR sites are active on both the X and Y chromosomes in the studied individual and surrounded by GC enriched heterochromatin. We hypothesize that the surrounding heterochromatin might have played a role in the transfer of NORs from autosomes to sex chromosomes during the karyotype evolution of the Javan mouse-deer. [ABSTRACT FROM AUTHOR]

Published

2018

13. New Data on Comparative Cytogenetics of the Mouse-Like Hamsters (Calomyscus Thomas, 1905) from Iran and Turkmenistan

Author

Natalya A. Lemskaya, Vladimir G. Malikov, F. N. Golenishchev, Vladimir A. Trifonov, Svetlana A. Romanenko, Alexander S. Graphodatsky, Malcolm A. Ferguson-Smith, Mansour Aliabadian, Jorge C. Pereira, Natalia A. Serdyukova, Ahmad Mahmoudi, Romanenko, Svetlana A [0000-0002-0951-5209], Golenishchev, Feodor N [0000-0003-2889-4774], Pereira, Jorge C [0000-0002-1472-1613], Trifonov, Vladimir A [0000-0003-0454-8359], Ferguson-Smith, Malcolm A [0000-0001-9372-1381], Aliabadian, Mansour [0000-0002-3200-4853], Graphodatsky, Alexander S [0000-0002-8282-1085], Apollo - University of Cambridge Repository, Romanenko, Svetlana A. [0000-0002-0951-5209], Golenishchev, Feodor N. [0000-0003-2889-4774], Pereira, Jorge C. [0000-0002-1472-1613], Trifonov, Vladimir A. [0000-0003-0454-8359], Ferguson-Smith, Malcolm A. [0000-0001-9372-1381], and Graphodatsky, Alexander S. [0000-0002-8282-1085]

Subjects

0106 biological sciences, 0301 basic medicine, Systematics, medicine.medical_specialty, Calomyscus mystax, Karyotype, QH426-470, Iran, Biology, Synteny, 010603 evolutionary biology, 01 natural sciences, Evolution, Molecular, Molecular cytogenetics, Mice, 03 medical and health sciences, Chromosome painting, Painting Probes, Species Specificity, Genus, Cricetinae, Heterochromatin, Type locality, Genetics, medicine, Animals, Turkmenistan, In Situ Hybridization, Fluorescence, Genetics (clinical), Autosome, Cytogenetics, Chromosome, biology.organism_classification, Chromosomes, Mammalian, Chromosome Banding, Phylogeography, 030104 developmental biology, Banding, Evolutionary biology, Cytogenetic Analysis, fluorescent in situ hybridization, molecular cytogenetics

Abstract

The taxonomy of the genus Calomyscus remains controversial. According to the latest systematics the genus includes eight species with great karyotypic variation. Here, we studied karyotypes of 14 Calomyscus individuals from different regions of Iran and Turkmenistan using a new set of chromosome painting probes from a Calomyscus sp. male (2n = 46, XY, Shahr-e-Kord-Soreshjan-Cheshme Maiak Province). We showed the retention of large syntenic blocks in karyotypes of individuals with identical chromosome numbers. The only rearrangement (fusion 2/21) differentiated Calomyscus elburzensis, Calomyscus mystax mystax, and Calomyscus sp. from Isfahan Province with 2n = 44 from karyotypes of C. bailwardi, Calomyscus sp. from Shahr-e-Kord, Chahar Mahal and Bakhtiari-Aloni, and Khuzestan-Izeh Provinces with 2n = 46. The individuals from Shahdad tunnel, Kerman Province with 2n = 51–52 demonstrated non-centric fissions of chromosomes 4, 5, and 6 of the 46-chromosomal form with the formation of separate small acrocentrics. A heteromorphic pair of chromosomes in a specimen with 2n = 51 resulted from a fusion of two autosomes. C-banding and chromomycin A3-DAPI staining after G-banding showed extensive heterochromatin variation between individuals.

Published

2021

14. The Case of X and Y Localization of Nucleolus Organizer Regions (NORs) in Tragulus javanicus (Cetartiodactyla, Mammalia).

Author

Proskuryakova AA, Kulemzina AI, Perelman PL, Serdukova NA, Ryder OA, and Graphodatsky AS

Abstract

There are differences in number and localization of nucleolus organizer regions (NORs) in genomes. In mammalian genomes, NORs are located on autosomes, which are often situated on short arms of acrocentric chromosomes and more rarely in telomeric, pericentromeric, or interstitial regions. In this work, we report the unique case of active NORs located on gonоsomes of a eutherian mammal, the Javan mouse-deer ( Tragulus javanicus ). We have investigated the position of NORs by FISH experiments with ribosomal DNA (rDNA) sequences (18S, 5.8S, and 28S) and show the presence of a single NOR site on the X and Y chromosomes. The NOR is localized interstitially on the p-arm of the X chromosome in close proximity with prominent C-positive heterochromatin blocks and in the pericentromeric area of mostly heterochromatic Y. The NOR sites are active on both the X and Y chromosomes in the studied individual and surrounded by GC enriched heterochromatin. We hypothesize that the surrounding heterochromatin might have played a role in the transfer of NORs from autosomes to sex chromosomes during the karyotype evolution of the Javan mouse-deer.

Published

2018