Molecular characterisation and origin of the Coffea arabica L. genome

Restriction fragment length polymorphism (RFLP) markers were used in combination with genomic in situ hybridisation (GISH) to investigate the origin of the allotetraploid species Coffea arabica (2n = 44). By comparing the RFLP patterns of potential diploid progenitor species with those of C. arabica, the sources of the two sets of chromosomes, or genomes, combined in C. arabica were identified. The genome organisation of C. arabica was confirmed by GISH using simultaneously labelled total genomic DNA from the two putative genome donor species as probes. These results clearly suggest that C. arabica is an amphidiploid formed by hybridisation between C. eugenioides and C. canephora, or ecotypes related to these diploid species. Our results also indicate low divergence between the two constituent genomes of C. arabica and those of its progenitor species, suggesting that the speciation of C. arabica took place relatively recently. Precise localisation in Central Africa of the site of the speciation of C. arabica, based on the present distribution of the coffee species, appears difficult, since the constitution and extent of tropical forest has varied considerably during the late Quaternary period. Received: 6 June 1998 / Accepted: 10 November 1998     

Unusual occurrence of a ZZ/ZW sex-chromosome system and supernumerary chromosomes in Characidium cf. fasciatum (Pisces, Characiformes, Characidiinae)

Individuals of two populations of the fish Characidium cf. fasciatum were cytogenetically studied and showed a basic diploid number of 50 chromosomes. Some fishes were found to have 51 to 54 chromosomes due to the presence of one to four small subtelocentric/acrocentric supernumerary chromosomes. When analyzed by conventional Giemsa staining, male and female specimens of C. cf. fasciatum from the Quinta stream and Pardo River presented the same basic karyotypic macro- and microstructure, consisting of 32 metacentric and 18 submetacentric chromosomes. Ag-NORs were terminally located on the long arms of two submetacentric chromosome pairs. Constitutive heterochromatin was identified by C-banding as small pericentromeric blocks in the majority of the chromosomes, and B-chromosomes were found to be heterochromatic. The occurrence of one totally heterochromatic submetacentric chromosome restricted to females and considered as an unusual feature in fish karyotypes led to the identification of a ZZ/ZW sex-chromosome system. The implications of chromosomic differentiation observed in the genus Characidium are discussed. This revised version was published online in July 2006 with corrections to the Cover Date.     

Morphometric and morphological delineation of southern African species of Aethomys (Rodentia: Muridae)

Five species of African rock rats, Aethomys namaquensis, A. granti, A. silindensis, A. nyikae and A. chrysophilus, have to date been recognized in southern Africa. While the first three species are craniometrically well-delineated, morphometric analysis of cytogenetically known and other specimens of A. chrysophilus revealed that it comprises two sympatric, morphologically similar species, the nominate species and the newly recognized A. ineptus. This is in agreement with observations on cranial morphology and earlier investigations involving cytogenetics, protein electrophoresis, and gross sperm and bacular morphology. Contrary to published reports, the Central African A. nyikae does not extend into southern Africa, and the single previous record from eastern Zimbabwe is probably based on a misidentification.     

Chromosomal diversity in the genus Arvicanthis (Rodentia, Muridae) from East Africa: a taxonomic and phylogenetic evaluation

In this paper we discuss the contribution of cytogenetics to the systematics of Arvicanthis in East Africa, by reviewing all the known chromosomal cytotypes of the genus in the area. We also provide G‐ and C‐banding comparisons for two recently described karyotypes, provisionally named ANI‐5 (2n = 56, NFa = 62) and ANI‐6 (2n = 60, NFa = 72). This, therefore, brings the total number of known cytotypes in this area to 10. Five of these correspond to the species recognized by the latest rodent checklist, i.e. A. nairobae (2n = 62, NFa = 78), A. neumanni (2n = 52–53, NFa = 62), A. blicki (2n = 48, NFa = 62), A. abyssinicus (2n = 62, NFa = 64) and A. niloticus (2n = 62, NFa = 60–62). The taxonomic status of the remaining five cytotypes (A. cf. somalicus, 2n = 62 NFa = 62–63; ANI‐5, 2n = 56, NFa = 62; ANI‐6/6a 2n = 60, NFa = 72/76; ANI‐7, 2n = 56, NFa = 78; and ANI‐8, 2n = 44, NF = 72) is discussed. Finally, we reconstruct the phylogenetic relationships among all the known karyotypes on the basis of banding data available for the genus in Africa and show the occurrence of two main clades, each characterized by different types of chromosomal rearrangements. The times of the cladogenetic events, inferred by a molecular clock, indicate that karyotype evolution has accomplished almost all the dichotomic events from the end of the Miocene to the present day. The discovery of a large chromosomal differentiation between populations showing low genetic distances and intrapopulation chromosomal polymorphism suggests that the process of chromosomal differentiation in Arvicanthis is still ongoing and may possibly be responsible for speciation.     

Selected features of marsupial genetics

As a consequence of the ancient separation of the marsupial and eutherian lineages, comparative genetical studies of these two mammalian taxa can be particularly informative. The potential for marsupial genetical research has been enhanced by the development of laboratory colonies of three model species-Macropus eugenii, Monodelphis domestica andSminthopsis crassicaudata. In this paper two selected aspects of marsupial genetics are reviewed, one involving cytogenetics and the other linkage. Marsupials provide a spectacular example of karyotypic conservation. The so-called basic karyotype (2n=14) is probably ancestral in all extant marsupials. Karyotypes that do not conform to this basic arrangement are thought to have been derived from it. A notable feature of the basic karyotype is that it has been retained, possibly for as long as 150 million years, in morphologically, behaviourally and ecologically diverse species from at least five Australian and two American families; this suggests that selective forces, presently unknown, have acted to conserve the basic chromosome form and number in these species. With respect to genetic linkage, family studies inS. crassicaudata and more recentlyM. domestica have indicated extreme differences between the sexes with the recombination frequencies for linked loci being very much greater in males than in females, a situation that is strikingly different from that in eutherian mammals. These differences in linkage values are paralleled by differences in the number and distribution of chiasmata during male and female meiosis. Prospects for further research in marsupials, particularly research that builds upon the observations of karyotypic conservation and genetic linkage, are noted.     

Genomic relationships of theElymus parviglumis,E. semicostatus,andE. tibeticus groups (Triticeae: Poaceae)

In order to investigate genomic relationships of tetraploidElymus species (all containing the SY genomes) among three morphological groups, i.e. theE. parviglumis, E. semicostatus, andE. tibeticus groups, interspecific hybridizations were carried out among representative species from the three groups. Chromosome associations at metaphase I were analysed in the interspecific hybrids, and genomic relationships of the species within and among the three groups were estimated. Hybridizations among species of the three groups were fairly easy to perform, but no general pattern for crossabilities among certain species or groups was obtained. All the hybrids were completely sterile. Meiotic pairing was moderately high, but ranges of chiasmata were observed in different hybrid combinations. There is no tendency for genomic affinities to be higher within groups than between the groups. Therefore, the meiotic data do not support the division of the SY-genome species into the three groups. However, there is a clear tendency that the differentiation of the SY genomes in the tetraploids is associated with the geographic distribution of the species.     

Molecular cytogenetics of multiple drug resistance

The refractory nature of many human cancers to multi-agent chemotherapy is termed multidrug resistance (MDR). In the past several decades, a major focus of clinical and basic research has been to characterize the genetic and biochemical mechanisms mediating this phenomenon. To provide model systems in which to study mechanisms of multidrug resistance,in vitro studies have established MDR cultured cell lines expressing resistance to a broad spectrum of unrelated drugs. In many of these cell lines, the expression of high levels of multidrug resistance developed in parallel to the appearance of cytogenetically-detectable chromosomal anomalies resulting from gene amplification. This review describes cytogenetic and molecular-based studies that have characterized DNA amplification structures in MDR cell lines and describes the important role gene amplification played in the cloning and characterization of the mammalian multidrug resistance genes (mdr). In addition, this review discusses the genetic selection generally used to establish the MDR cell lines, and how drug selections performed in transformed cell lines generally favor the genetic process of gene amplification, which is still exploited to identify drug resistance genes that may play an important role in clinical MDR.     

Molecular cytogenetic analysis of Agropyron elongatum chromatin in wheat germplasm specifying resistance to wheat streak mosaic virus

Summary Three lines derived from wheat (6x) x Agropyron elongatum (10x) that are resistant to wheat streak mosaic virus (WSMV) were analyzed by chromosome pairing, banding, and in situ hybridization. Line CI15321 was identified as a disomic substitution line where wheat chromosome 1D is replaced by Ag. elongatum chromosome 1Ae-1. Line 87-94-1 is a wheat-Ag. elongatum ditelosomic addition 1Ae-1L. Line CI15322 contains an Ag. elongatum chromosome, 1Ae-2, that substitutes for chromosome 1D. The short arm of 1Ae-2 paired with the short arm of 1Ae-1 at metaphase I (MI) in 82% of the pollen mother cells (PMCs). However, the long arms of these two chromosomes did not pair with each other. In CI15322, the long arm of chromosome 4D has an Agropyron chromosome segment which was derived from the distal part of 1Ae-1L. This translocation chromosome is designated as T4DS·4DL-1L. T4DS·4DL-1Ae-1L has a 0.73 m distal part of the long arm of 4D replaced by a 1.31 m distal segment from 1Ae-1L. The major WSMV resistance gene(s) in these lines is located on the distal part of 1Ae-1L.Contribution No. 92-599-J from the Kansas Agricutural Experiment Station, Kansas State University, Manhattan, Kansas, USA     

Evolutionary relationships of Eastern Palearctic Brown Frogs, genus Rana: paraphyly of the 24-chromosome species group and the significance of chromosome number change

The Eurasian 'brown frogs' are a morphologically conservative assemblage consisting of the European Rana temporaria and a large number of similar species considered to be related. Although the chromosome number of the great majority of Rana species is 26, there are several species of brown frogs (including R. arvalis, R. chensinensis, R. omativentris and R. dybowskii ) which instead have 24 chromosomes. Yet comparative study of isozyme variation at 25 gene loci from these and seven other European, Caucasian, and east Asian species indicates that the 24-chromosome brown frogs are not a monophyletic group. To the exclusion of R. arvalis , the east Asian 24-chromosome species form a distinct clade related to the 26-chromosome species R. temporaria, R. dalmatina, R. japonica , and R. tagai more closely than to R. arvalis. This result is reinforced by the comparative position of the nucleolar organizer region (NOR) in the karyotypes of these frogs, as shown by NOR-banding of metaphase chromosomes. The NOR is on chromosome No. 2 in R. arvalis but on chromosome No. 10 in the other three 24-chromosome species. The systematic positions of the Causasian species A. camerani and R. macrocnemis relative to the other species are unclear except that these frogs are distinct enough to be considered part of an outgroup clade. However, in general, the systematics of the entire brown frog group remains unresolved due to great genetic divergences between species and the evident homoplasy of the brown frog morphotype. The parallel origins of reduced karyotypes among the brown frogs demonstrate that caution should be exercised when judging systematic relationships based upon gross karyology in the absence of more detailed information.     

A new chromosome race of Calycadenia pauciflora (Asteraceae: Heliantheae-Madiinae) from Butte County, California

We initiated a biosystematic study of a recently discovered population of Calycadenia pauciflora in order to evaluate its cytogenetic relationship to previously characterized chromosome races of that species. Cytogenetic analyses of six or more artificially produced individuals of each of the five possible interracial hybrid combinations indicated that the new race (designated Wurlitzer) is differentiated from the other races (Elegans, Healdsburg, Pauciflora, Ramulosa, and Tehama) by the equivalent of 2-4 reciprocal chromosome translocations and in one instance apparently a pericentric inversion. Mean pollen stainability in the hybrids ranged from 13 to 26%. The floral and vegetative features of the new race are very similar to those of races Pauciflora, Ramulosa, and Tehama of C. pauciflora. We ascribe the apparent lack of single-step cytogenetic events in the evolution of the races of C. pauciflora to one or more of the following: (1) (in some cases) the occurrence of saltational chromosome reorganization; (2) extinction of or failure to detect intermediate populations in C. pauciflora; and (3) an insufficient consideration of the possibility of the existence of intermediate races in the closely related species, C. fremontii. We conclude that the C. fremontii-C. pauciflora alliance is one of the most complex and potentially instructive examples of diploid chromosome evolution in plants.