Diploid-tetraploid relationship among old-world members of the fish family Cyprinidae

Evidence suggesting that the goldfish and the carp of the family Cyprinidae are tetraploid species in relation to other members of the same family were presented. The two barb species, Barbus tetrazona and Barbus jasciatus, were chosen as representatives of diploid members of the family Cyprinidae. These barbs had the diploid chromosome number of 50 and 52 and the DNA value 20–22% that of placental mammals, while the goldfish (Carassius auratus) and the carp (Cyprinus carpio) had the diploid chromosome number of about 104 and the DNA value 50–52% that of placental mammals.Supported in part by a grant (CA-05138) from the National Cancer Institute, U.S.Public Health Service, and in part by a research fund established in honor of General James H. Doolittle at Duarte, and by the British Empire Cancer Campaign for Research at Northwood. Contribution No. 11-67, Department of Biology, City of Hope Medical Center. Dr. Junichi Muramoto is a fellow of the Institute for Advanced Learning of the City of Hope Medical Center.     

Characterization of Mhc genes in a multigenerational family of ring-necked pheasants

Little is known about the major histocompatibility (Mhc) genes of birds in different taxonomic groups or about how Mhc genes may be organized in avian species divergent by evolution or habitat. Yet it seems likely that much might be learned from birds about the evolution, organization, and function of this intricate complex of polymorphic genes. In this study a close relative of the chicken, the ring-necked pheasant (Phasianus colchicus), was examined for the presence and organization of Mhc B-G genes. The patterns of restriction fragments revealed by chicken B-G probes in Southern hybridizations and the patterns of pheasant erythrocyte polypeptides revealed in immunoblots by antisera raised against chicken B-G polypeptides provide genetic, molecular, and biochemical data confirming earlier serological evidence for the presence of B-G genes in the pheasant, and hence, the presence of a family of B-G genes in at least a second species of birds. The high polymorphism exhibited by the pheasant B-G gene family allowed genetic differences among individuals within the small experimental population in this study to be detected easily by restriction fragment patterns. Further evidence was found for the organization of the pheasant Mhc class I and class II genes into genetically independent clusters. Whether these gene clusters are fully comparable to the B and Rfp-Y systems in the chicken or whether yet another organization of Mhc genes has been encountered in the pheasant remains to be determined.     

Autosomal determination of erythrocyte glucose 6-phosphate dehydrogenase in domestic chickens and ring-necked pheasants

Erythrocyte glucose 6-phosphate dehydrogenase isozymes of domestic chickens, ring-necked pheasants, and their hybrids were studied, using the starch gel zone electrophoresis technique. In domestic chickens G6PD isozymes were represented by two fast-moving bands and an indistinct third band, whereas in ring-necked pheasants a slow-moving broad band which seemed to consist of two closely apposed G6PD isozymes was observed. The F₁ hybrids showed three distinct bands combining the characteristic mobility pattern of the two parents, which seemed to indicate that both parental alleles are expressed in F₁ hybrids. Since both male and female hybrids exhibited strikingly similar isozyme patterns representing both sire and dam, it was assumed that the genes controlling the production of G6PD in chicken and pheasant red blood cells are located on the autosomes.This study was supported in part by a research grant from the National Research Council of Canada.     

Experimental alterations in the chromosome constitution of Sciara

Summary Using two reciprocal translocations between chromosomes X and IV in S. coprophila it has been possible to derive two kinds of aneuploid females. Both of the aneuploid complements are detrimental — one is lethal, the other may give rise to viable, fertile adults. Males with aneuploid somatic complements have not been obtained; three different aneuploid complements were tested but gave negative results. Males with euploid soma and aneuploid germ line have been produced in three separate instances; they are viable and fertile.Dedicated to Professor H. Bauer on the occasion of his sixtieth birthday.The studies reported here were supported by grant GB-42 from the National Science Foundation.     

Differences of Z chromosome and genomic expression between early- and late-feathering chickens

One duplicated segment on chicken Z chromosome is a causal mutation to the late-feathering phenotype. However, understanding biological process of the late-feathering formation is also of interest to chicken breeding and feather development theory. One hundred and thirty-seven valid single nucleotide polymorphisms (SNPs) from an SNP database were used to perform an association study of the Z chromosome in Xinghua chickens. Two SNPs, which were respectively on 9607480 bp and 10607757 bp, were significantly associated with feathering phenotypes. This result indicated the causal mutation of the late-feathering formation in Xinghua chickens was consistent with the previous report which showed the late-feathering locus ranged 9966364–10142688 bp on Z chromosome. Microarray expressions were implemented for six 1-day-old female Xinghua chicks. Compared to the early-feathering chicks, there were 249 and 83 upregulated and downregulated known genes in the late-feathering chicks. Forty-one genes were expressed in late-feathering chicks, but not in early-feathering ones. At least 14 significantly differentially expressed genes were directly related to keratin. In the region of the sex-linked feathering gene, only prolactin receptor (PRLR) gene was a significantly differentially expressed gene. Expression of PRLR in late-feathering chicks was 1.78-fold as that in early-feathering chicks. Late-feathering Wenchang chicks also had higher expression level of PRLR than early-feathering ones. This study suggested that increasing PRLR expression that resulted from the special variant on chicken Z chromosome caused the late-feathering phenotype.     

Presence of female-specific bent-repetitive DNA sequences in the genomes of turkey and pheasant and their interactions with W-protein of chicken

Two female-specific repetitive DNA units, the 0.4 kb PstI and 0.5 kb TaqI sequences, were detected in the genomic DNA of turkey and pheasant, respectively, by Southern blot hybridization under non-stringent conditions with the W chromosome-specific 0.7 kb XhoI repetitive unit of chicken as a probe. Cloning and sequencing of these two repetitive units revealed that they shared features with the XhoI family repetitive unit of chicken although the overall similarities of the nucleotide sequences were less than 60%. In common with the chicken XhoI family they consisted of tandem repeats of about 21 bp, the majority of which contained (A)_3–5 and (T)_3–5 clusters separated by six or seven relatively G+C-rich sequences, and they behaved as bent DNA molecules on polyacrylamide gel electrophoresis at room temperature. W-protein, purified from chicken liver nuclei and shown to bind with high affinity to the XhoI family repetitive unit, also bound with the cloned repetitive units from turkey and pheasant. DNase I footprint analysis suggested that the mode of interaction of W-protein with these units was similar to that with the 0.7 kb XhoI sequence. On the other hand, W-protein did not bind to the female-specific 0.4 kb BamHI repetitive unit from the Bobwhite quail. The 0.4 kb BamHI sequence contained some A and T clusters but these clusters did not appear in phase with the pitch of DNA helix and the repetitive unit did not show DNA bending.     

Karyotypic evolution in the Galliformes: an examination of the process of karyotypic evolution by comparison of the molecular cytogenetic findings with the molecular phylogeny

To define the process of karyotypic evolution in the Galliformes on a molecular basis, we conducted genome-wide comparative chromosome painting for eight species, i.e. silver pheasant (Lophura nycthemera), Lady Amherst's pheasant (Chrysolophus amherstiae), ring-necked pheasant (Phasianus colchicus), turkey (Meleagris gallopavo), Western capercaillie (Tetrao urogallus), Chinese bamboo-partridge (Bambusicola thoracica) and common peafowl (Pavo cristatus) of the Phasianidae, and plain chachalaca (Ortalis vetula) of the Cracidae, with chicken DNA probes of chromosomes 1-9 and Z. Including our previous data from five other species, chicken (Gallus gallus), Japanese quail (Coturnix japonica) and blue-breasted quail (Coturnix chinensis) of the Phasianidae, guinea fowl (Numida meleagris) of the Numididae and California quail (Callipepla californica) of the Odontophoridae, we represented the evolutionary changes of karyotypes in the 13 species of the Galliformes. In addition, we compared the cytogenetic data with the molecular phylogeny of the 13 species constructed with the nucleotide sequences of the mitochondrial cytochrome b gene, and discussed the process of karyotypic evolution in the Galliformes. Comparative chromosome painting confirmed the previous data on chromosome rearrangements obtained by G-banding analysis, and identified several novel chromosome rearrangements. The process of the evolutionary changes of macrochromosomes in the 13 species was in good accordance with the molecular phylogeny, and the ancestral karyotype of the Galliformes is represented.     

Occupancy of the majority of DNA in the chicken W chromosome by bent-repetitive sequences

Another family of repetitive sequences, designated the EcoRI family, was found in the DNA of the chicken W chromosome by hybridization with the W chromosome-specific XhoI family probe under conditions of low stringency. A 1.2 kb EcoRI fragment, the major repeating unit of the family, was cloned and sequenced. The 1.2 kb unit showed an overall sequence similarity of about 68% to the 0.7 kb XhoI family repeating unit and it consisted of tandem repeats of average length 21 bp, most of which contained (A)_3–5 and (T)_3–4 clusters separated by 6–8 G+C-rich sequences. These features and its behavior as a strongly bent molecule in solution were very similar to those found for other W chromosome-specific repetitive sequences in the order Galliformes: XhoI family of chicken, PstI family of turkey and TaqI family of pheasant. The cloned 1.2 kb unit contained 78 CpG dinucleotide sequences and those that were in HapII, HhaI and BstUI sites were shown to be extensively methylated in the genomic DNA. Repetition frequencies of the 1.2 kb unit among the female population of chicken fell into high- and low-level classes, which accounted for about 30% and 10%, respectively, of the DNa in the W chromosome. Thus, 70% to 90% of the DNA in the chicken W chromosome was shown to be occupied by bent-repetitive sequences. The EcoRI and XhoI family sequences were not intermingled over the short range but each family formed a unique domain ranging from one to several million base pairs.by H.C. Macgregor     

Assignment of the gene governing cellular ouabain resistance to Mus musculus chromosome 3 using human/mouse microcell hybrids

Human/mouse microcell hybrids were used to establish the assignment of the gene governing resistance to the cardiac glycoside ouabain (Oua-1) to Mus musculus chromosome 3. Microcells were prepared from primary mouse embryo fibroblasts and fused with HeLa S3 cells, and microcell hybrids were isolated and maintained in medium containing 10^–6 m ouabain. Resistance to ouabain was not expressed concordantly with any of 26 murine isozyme markers. Karyotypic analysis of five primary clones showed that one to five murine chromosomes had been transferred from donor to recipient in these experiments. Only mouse chromosome 3 was common to all ouabain-resistant primary clones. Both ouabain-resistant and -sensitive subclones were isolated from hybrids grown in the absence of selective pressure, and karyotyping showed that loss of resistance to ouabain was concordant with the loss of murine chromosome 3.These studies were supported by Grant GM9966 from the National Institutes of Health.     

On the cytotaxonomy of phasmids (Phasmatodea)

Summary A wide diversity in chromosome complement is found in two species of phasmids of the primitive group Prisopini—Prisopus ariadne Hebard and Prisopus berosus Westwood. P. ariadne has a diploid male complement of 28, comprising 13 pairs of relatively large mediokinetic autosomes and Neo XY sex chromosomes. P. berosus, 2n =49, has relatively small autosomes most of which are mediokinetic, and retains the XO—XX sex mechanism. Chromosomal polymorphism in this species is suggested by the presence of an unequal pair of autosomes and a structural differentiation in the X in one of two males studied.The relative amount of DNA per nucleus in male germ cells (Peulgen cytophotometry) shows a significant difference in total chromosomal content between the complements of the two species.These data are discussed with reference to the cytotaxonomy of phasmids.Supported in part by research grant G-4370 from the National Institutes of Health, Public Health Service.     

Molecular and biological aspects of early germ cell development in interspecies hybrids between chickens and pheasants

Interspecific hybrids provide insights into fundamental genetic principles, and may prove useful for biotechnological applications and as tools for the conservation of endangered species. In the present study, interspecies hybrids were generated between the Korean ring-necked pheasant (Phasianus colchicus) and the White Leghorn chicken (Gallus gallus domesticus). We determined whether these hybrids were good recipients for the production of germline chimeric birds. PCR-based species-specific amplification and karyotype analyses showed that the hybrids inherited genetic material from both parents. Evaluation of biological function indicated that the growth rates of hybrids during the exponential phase (body weight/week) were similar to those of the pheasant but not the chicken, and that the incubation period for hatching was significantly different from that of both parents. Primordial germ cells (PGCs) of hybrids reacted with a pheasant PGC-specific antibody and circulated normally in blood vessels. The peak time of hybrid PGC migration was equivalent to that of the pheasant. In late embryonic stages, germ cells were detected by the QCR1 antibody on 15 d male gonads and were normally localized in the seminiferous cords. We examined the migration ability and developmental localization of exogenous PGCs transferred into the blood vessels of 63 h hybrid embryos. Donor-derived PGCs reacted with a donor-specific antibody were detected on 7 d gonads and the seminiferous tubules of hatchlings. Therefore, germ cell transfer into developing embryos of an interspecies hybrid can be efficiently used for the conservation of threatened animals and endangered species, and many biotechnological applications.     

Comparative study of predator avoidance behaviour of pheasants (<Emphasis Type="Italic">Phasianus colchicus</Emphasis>) of different genetic origin

The aim of the study was to determine differences in the behaviour of chicks of three different pheasant subspecies. The timidity of the pheasant chicks was of special interest, therefore behaviour traits were analysed using an open-field test and a tonic immobility test. In total, 137 pheasant chicks were tested including the copper pheasant (Ph. c. colchicus; n = 87), the green pheasant (Ph. c. versicolor; n = 12) and the melanistic pheasant (Ph. c. tenebrosus; n = 38). In both tests, the chicks of the versicolor group showed the highest timidity, whereas the other two groups were similar in timidity. In the open-field test, the chicks of the colchicus group showed the lowest timidity, and in the tonic immobility test, the tenebrosus group showed the lowest values. Assuming a relationship between the test results and predator avoidance behaviour, it can be concluded that the chicks of the versicolor group show the best predator avoidance behaviour. Further investigations are needed to find out whether the differences in the analysed behaviour traits result in higher survival rates after releasing to the wild.     

Delimitation ofPelargonium sect.Glaucophyllum (Geraniaceae)

Pelargonium otaviense Knuth andP. spinosum Willd. are excluded from sect.Glaucophyllum, whileP. grandiflorum (Andr.)Willd.,P. patulum Jacq. andP. tabulare (Burm. f.)L'Hérit. of sect.Eumorpha are included. Sect.Glaucophyllum is characterized by green to glaucous vegetative organs and zygomorphic white to pink corolla with five narrow petals. All the species have an identical pollen and chromosome morphology, the same basic chromosome number (x = 11) and similar flavonoid patterns. A close relationship between sect.Glaucophyllum and sect.Pelargonium is indicated by the occurrence of natural hybrids and concordant characters. Isorhamnetin and luteolin have been detected in the genus for the first time.     

Allelic inhibition at the autosomally inherited gene locus for liver alcohol dehydrogenase in chicken-quail hybrids

At the gene locus for liver alcohol dehydrogenase (ADH) of the Japanese quail, three alleles which give electrophoretic variants, A, B, and C, exist. This enzyme is autosomally inherited. Allelic polymorphism was not observed in the chicken, but the wild-type ADH of the chicken can readily be distinguished from A, B, and C of the quail by starch gel electrophoresis. In the development of both species, ADH activity reached a near adult level at about the nineteenth day (a few days after hatching in the quail and a few days before hatching in the chicken). Chicken-quail hybrids at the day of hatching (nineteenth day) revealed the presence of maternally derived quail ADH only, and their ADH activities were about half that of both parental species. Those hybrids which received either A or C allele from the mother quail showed three bands of ADH at the third day after hatching. The chicken and quail alleles began to function in synchronous harmony. One 3-day-old and two adult hybrids which received B allele from the quail, however, still revealed complete absence of the paternally derived chicken ADH.This work was supported in part by a grant (CA-05138) from the National Cancer Institute, U.S. Public Health Service, and in part by a research fund established in honor of General James H. Doolittle. Contribution No. 20-67, Department of Biology, City of Hope Medical Center.Dr. Eduardo Castro-Sierra is a fellow of the Institute for Advanced Learning of the City of Hope Medical Center.     

Polymorphic microsatellites developed by cross-species amplifications in common pheasant breeds

Genetic variability was analysed in two common breeds of pheasant (Phasianus colchicus L. 1758) by means of cross-species amplifications of microsatellite loci: 154 chicken, Gallus gallus and 32 turkey, Meleagris gallopavo, primers were tested for amplification of pheasant DNA. Thirty-six primers (25 specific for chicken and 11 for turkey) amplified pheasant DNA. Fifteen markers yielded specific products and were tested for polymorphism. Eight of them (55%) were polymorphic, with an average polymorphism of two alleles per locus. Specific polymerase chain reaction (PCR) products were sequenced; repeats were found in 11 of the 15 markers, although only two loci showed the same repeat and could be homologous to chicken ones.     

Homology between avian oncornavirus RNAs and DNA from several avian species.

3H-labeled 35S RNA from avian myeloblastosis virus (AMV), Rous associated virus (RAV)-0, RAV-60, RAV-61, RAV-2, or B-77(w) was hybridized with an excess of cellular DNA from different avian species, i.e., normal or leukemic chickens, normal pheasants, turkeys, Japanese quails, or ducks. Approximately two to three copies of endogenous viral DNA were estimated to be present per diploid of normal chicken cell genome. In leukemic chicken myeloblasts induced by AMV, the number of viral sequences appeared to have doubled. The hybrids formed between viral RNA and DNA from leukemic chicken cells melted with a Tm 1 to 6 C higher than that of hybrids formed between viral RNA and normal chicken cell DNA. All of the viral RNAs tested, except RAV-61, hybridized the most with DNA from AMV-infected chicken cells, followed by DNA from normal chicken cells, and then pheasant DNA. RAV-61 RNA hybridized maximally (39%) with pheasant DNA, followed by DNA from leukemic (34%), and then normal (29%) chicken cells. All viral RNAs tested hybridized little with Japanese quail DNA (2 to 5%), turkey DNA (2 to 4%), or duck DNA (1%). DNA from normal chicken cells contained only 60 to 70% of the RAV-60 genetic information, and normal pheasant cells lacked some RAV-61 DNA sequences. RAV-60 and RAV-61 genomes were more homologous to the RAV-0 genome than to the genome of RAV-2, AMV, or B-77(s). RAV-60 and RAV-61 appear to be recombinants between endogenous and exogenous viruses.     

The phylogenetic relationships of immunoglobulin allotypes and 7S immunoglobulin isotypes of chickens and other phasianoids (turkey,pheasant, quail)

Pheasants, quail and turkeys from different geographical locations were surveyed for the presence of eight 7S Ig and four IgM chicken allotypes. No IgM and only two 7S Ig allotypes were detected. Chicken 7S Ig allotypic specificity G-1.7 cross-reacted with pheasant and turkey isotypic specificities, and was absent in quail. The other determinant (G-1.9) cross-reacted with an allotype found only in turkeys and golden pheasants. These data suggest that G-1.7 and G-1.9 are probably phylogenetically ancient determinants and that polymorphism of chicken immunoglobulins arose after divergence of chickens from other phasianoid birds. Based on the allotypic and isotypic analysis of the 7S Ig antigenic determinants, turkey 7S Ig was as closely related to chicken 7S Ig as was pheasant 7S Ig. Jungle fowl, the ancestor of chickens, had most of the chicken 7S Ig and IgM allotypes present as polymorphic markers.     

The phylogenetic relationships of immunoglobulin allotypes and 7S immunoglobulin isotypes of chickens and other phasianoids (turkey, pheasant, quail)

Pheasants, quail and turkeys from different geographical locations were surveyed for the presence of eight 7S Ig and four IgM chicken allotypes. No IgM and only two 7S Ig allotypes were detected. Chicken 7S Ig allotypic specificity G-1.7 cross-reacted with pheasant and turkey isotypic specificities, and was absent in quail. The other determinant (G-1.9) cross-reacted with an allotype found only in turkeys and golden pheasants. These data suggest that G-1.7 and G-1.9 are probably phylogenetically ancient determinants and that polymorphism of chicken immunoglobulins arose after divergence of chickens from other phasianoid birds. Based on the allotypic and isotypic analysis of the 7S Ig antigenic determinants, turkey 7S Ig was as closely related to chicken 7S Ig as was pheasant 7S Ig. Jungle fowl, the ancestor of chickens, had most of the chicken 7S Ig and IgM allotypes present as polymorphic markers.     

Interspecific hybridizations among species of theElymus semicostatus andElymus tibeticus groups (Poaceae)

Interspecific hybridizations were made between species of theE. semicostatus group, viz.,E. semicostatus (Nees exSteud.)Meld.,E. validus (Meld.)B. Salomon,E. abolinii (Drob.)Tzvel., andE. fedtschenkoi Tzvel., and species of theE. tibeticus group, viz.,E. pendulinus (Nevski)Tzvel.,E. tibeticus (Meld.)Singh,E. shandongensis B. Salomon, andE. gmelinii (Ledeb.)Tzvel., as well as among species within theE. tibeticus group. All species are tetraploid (2n = 4x = 28) and possess SY genomes. Meiotic pairing data from 24 hybrids involving 17 interspecific combinations are presented. The average number of chiasmata per cell ranged from 17.91 to 26.20 in hybrids within theE. tibeticus group, compared with 7.26 to 22.04 in hybrids between the two species groups. Despite the extensive collection of cytological data, there was no definite evidence for confirming or disproving the separate existence of the two groups.