Phylogenetic relationships among the polyploid and diploid Aegilops species inferred from the nuclear 5S rDNA sequences (Poaceae: Triticeae)

Genome ◽  
2012 ◽  
Vol 55 (3) ◽  
pp. 177-193 ◽  
Author(s):  
B.R. Baum ◽  
T. Edwards ◽  
M. Mamuti ◽  
D.A. Johnson
Keyword(s):  
Phylogenetic Relationships ◽  
5S Rdna ◽  
Reticulate Evolution ◽  
Evolutionary Relationships ◽  
Aegilops Species ◽  
Polyploid Species ◽  
Rdna Sequences ◽  
Unit Classes ◽  
Cytogenetic Analyses

Phylogenetic inferences of the polyploid Aegilops taxa were drawn based upon the analysis of 909 nuclear 5S rDNA sequences obtained from 15 Aegilops polyploid taxa (531 sequences new to this paper) and 378 sequences from our previous study on the diploid taxa. The 531 sequences can be split into two orthologous groups (unit classes), the long AE1 and short AE1 previously identified in the diploid set. An examination of the relationships between unit classes and their associated haplomes suggests that U haplome sequences found in Ae. umbellulata are the closest to the T sequences found in Amblyopyrum muticum and that sequences of the polyploid species expected to be the M type found in Ae. comos are more similar to the T haplome sequences, except in the three hexaploids Ae. glumiaristata, Ae. juvenalis, and Ae. vavilovii and the tetraploid Ae. crassa where they are found to be similar to the M haplome sequences. These three hexaploid taxa likely originated from the tetraploid Ae. crassa (DM), while the closest taxon to the fourth hexaploid, Ae. recta, is the tetraploid Ae. neglecta (UM). Based upon the distribution of the unit classes, several reticulate phylogenies depicting evolutionary relationships among diploid, tetraploid, and hexaploid taxa were constructed; however, none of these widely used methods could depict the expected reticulate relationship as previously drawn from cytogenetic analyses in this group of allopolyploid species. These results suggest that evolutionary relationships derived from models based upon the assumption of bifurcating species require careful interpretation when these same models are applied to species with reticulate evolution.

Codependence of repetitive sequence classes in genomes: phylogenetic analysis of 5S rDNA families in Hordeum (Triticeae: Poaceae)

Genome ◽  
2010 ◽  
Vol 53 (3) ◽  
pp. 180-202 ◽  
Author(s):  
Bernard R. Baum ◽  
Tara Edwards ◽  
Douglas A. Johnson
Keyword(s):  
Phylogenetic Analyses ◽  
5S Rdna ◽  
Rrna Gene ◽  
Consensus Sequences ◽  
Rdna Sequences ◽  
Unit Classes ◽  
Unit Class ◽  
Comprehensive Picture ◽  
Host Parasite

To complete our study of the genus Hordeum and to elaborate a phylogeny of species based upon 5S rDNA sequences, we have cloned and sequenced PCR amplicons from seven American polyploid species to generate 164 new 5S rRNA gene sequences. These sequences were analysed along with the more than 2000 5S rDNA sequences previously generated from the majority of species in Hordeum to provide a comprehensive picture of the distribution (presence or absence) of 5S rDNA unit classes (orthologous groups) in this genus as well as insights into the phylogeny of Hordeum. Testing of substitution models for each unit class based upon the consensus sequences of all the taxa as well as for each unit class within the genus found that the general best fit was TPM3uf+G, from which a maximum-likelihood tree was calculated. A novel application of cophylogenetic analysis, where relationships among unit classes were treated as host–parasite interactions, depicted some significant pair links under tests of randomness indicative of nonrandom codivergence among several unit classes within the same taxon. The previous classification of four genomic groups is reflected in combinations of unit classes, and it is proposed that current taxa developed from ancient diploidized paleopolyploids and that some were subjected to gene loss, i.e., unit class loss. Finally, separate phylogenetic analyses performed for the tetraploid and hexaploid species were used to derive a working model describing the phylogeny of the polyploid taxa from their putative diploid ancestry.

A comparison of the 5S rDNA diversity in the Hordeum brachyantherum–californicum complex with those of the eastern Asiatic Hordeum roshevitzii and the South American Hordeum cordobense (Triticeae: Poaceae)

2002 ◽  
Vol 80 (7) ◽  
pp. 752-762 ◽  
Author(s):  
Bernard R Baum ◽  
Douglas A Johnson
Keyword(s):  
Species Recognition ◽  
Cladistic Analysis ◽  
Strong Support ◽  
5S Rdna ◽  
Hordeum Spontaneum ◽  
Consensus Sequences ◽  
Rdna Sequences ◽  
Unit Classes ◽  
Unit Class ◽  
5S Dna

Amplification of the 5S rDNA gene by the polymerase chain reaction, followed by cloning and sequencing, was used to generate data from 23 seed accessions of Hordeum brachyantherum Nevski, Hordeum californicum Covas et Stebbins, Hordeum cordobense Bothmer, Jacobsen et Nicora, and Hordeum roshevitzii Bowden. One hundred and fourteen clones were analyzed, resulting in the detection of four different 5S DNA unit classes. Three of them, long H1, long H2, and long Y2, had been previously reported. The long H3 class, described for the first time, is present only in H. roshevitzii but can be grouped with previously unassigned units of Hordeum bulbosum L. and Hordeum spontaneum C. Koch. Based upon the analyses of 5S rDNA sequences, we found that (i) the long H2 unit class was not found in the Asiatic H. roshevitzii and therefore may be restricted to the American species, (ii) there is no strong support that H. brachyantherum and H. californicum are worthy of species recognition, and (iii) cladistic analysis of the consensus sequences of the four paralogous unit classes demonstrated that long Y2 is the most distant from the three long H classes.Key words: 5S DNA gene, Hordeum, unit classes.

Molecular diversity of the 5S rRNA gene and genomic relationships in the genus Avena (Poaceae: Aveneae)

Genome ◽  
2008 ◽  
Vol 51 (2) ◽  
pp. 137-154 ◽  
Author(s):  
Yuan-Ying Peng ◽  
Yu-Ming Wei ◽  
Bernard R. Baum ◽  
You-Liang Zheng
Keyword(s):  
Molecular Diversity ◽  
Diploid Species ◽  
5S Rdna ◽  
Rrna Gene ◽  
D Genome ◽  
Rdna Sequences ◽  
Unit Classes ◽  
Hexaploid Species ◽  
Unit Class ◽  
C Genome

The molecular diversity of the rDNA sequences (5S rDNA units) in 71 accessions from 26 taxa of Avena was evaluated. The analyses, based on 553 sequenced clones, indicated that there were 6 unit classes, named according to the haplomes (genomes) they putatively represent, namely the long A1, long B1, long M1, short C1, short D1, and short M1 unit classes. The long and short M1 unit classes were found in the tetraploid A. macrostachya , the only perennial species. The long M1 unit class was closely related to the short C1 unit class, while the short M1 unit class was closely related to the long A1 and long B1 unit classes. However, the short D1 unit class was more divergent from the other unit classes. There was only one unit class per haplome in Avena, whereas haplomes in the Triticeae often have two. Most of the sequences captured belonged to the long A1 unit class. Sequences identified as the long B1 unit class were found in the tetraploids A. abyssinica and A. vaviloviana and the diploids A. atlantica and A. longiglumis . The short C1 unit class was found in the diploid species carrying the C genome, i.e., A. clauda, A. eriantha , and A. ventricosa , and also in the diploid A. longiglumis, the tetraploids A. insularis and A. maroccana , and all the hexaploid species. The short D1 unit class was found in all the hexaploid species and two clones of A. clauda. It is noteworthy that in previous studies the B genome was found only in tetraploid species and the D genome only in hexaploid species. Unexpectedly, we found that various diploid Avena species contained the B1 and D1 units. The long B1 unit class was found in 3 accessions of the diploid A. atlantica (CN25849, CN25864, and CN25887) collected in Morocco and in 2 accessions of A. longiglumis (CIav9087 and CIav9089) collected in Algeria and Libya, respectively, whereas only 1 clone of A. clauda (CN21378) had the short D1 unit. Thus there might be a clue as to where to search for diploids carrying the B and D genomes. Avena longiglumis was found to be the most diverse species, possibly harboring the A, B, and C haplomes. The long M1 and short M1 are the unit classes typical of A. macrostachya. These results could explain the roles of A. clauda, A. longiglumis, and A. atlantica in the evolution of the genus Avena. Furthermore, one clone of the tetraploid A. murphyi was found to have sequences belonging to the short D1 unit class, which could indicate that A. murphyi might have been the progenitor of hexaploid oats and not, as postulated earlier, A. insularis. The evolution of Avena did not follow the molecular clock. The path inferred is that the C genome is more ancient than the A and B genomes and closer to the genome of A. macrostachya, the only existing perennial, which is presumed to be the most ancestral species in the genus.

Loss of 5S rDNA units in the evolution of Agropyron, Pseudoroegneria, and Douglasdeweya

Genome ◽  
2008 ◽  
Vol 51 (8) ◽  
pp. 589-598 ◽  
Author(s):  
B. R. Baum ◽  
T. Edwards ◽  
D. A. Johnson
Keyword(s):  
Single Unit ◽  
Gene Loss ◽  
5S Rdna ◽  
Lineage Sorting ◽  
Genomic Constitution ◽  
Rdna Sequences ◽  
Unit Classes ◽  
Unit Class ◽  
Tribe Triticeae

We have investigated relationships among the three closely related genera Agropyron , Pseudoroegneria , and Douglasdeweya. Based upon grouping of 330 5S rDNA sequences into unit classes, we found that Douglasdeweya, with the genomic constitution PPStSt, has 2 unit classes, the long P1 and short S1, and Pseudoroegneria, with the genomic constitution StSt or StStStSt, has the long S1 and short S1 unit classes. In contrast, only the long P1 unit class was found in species of the genus Agropyron (PP). Having a single unit class is unique among all the genera of the tribe Triticeae investigated so far and may reflect gene loss or lineage sorting during its genesis. The presence of the short S1 and long P1 unit classes confirms the amphiploid origin of Douglasdeweya.

The 5S rRNA gene diversity in Kengyilia rigidula (Keng and S.L. Chen) J.L. Yang, Yen, and Baum (Poaceae: Triticeae): Possible contribution of the H genome to the origin of Kengyilia

Genome ◽  
2000 ◽  
Vol 43 (1) ◽  
pp. 79-85 ◽  
Author(s):  
Bernard R Baum ◽  
L Grant Bailey
Keyword(s):  
Gene Diversity ◽  
5S Rdna ◽  
Rrna Gene ◽  
Chain Reaction ◽  
Rdna Sequences ◽  
Unit Classes ◽  
Unit Class ◽  
5S Dna ◽  
5S Rrna Gene ◽  
Polymerase Chain

Fifty-three units of 5S rDNA sequences from five accessions of Kengyilia rigidula, a member of the tribe Triticeae that also includes wheat, barley, rye, and their wild relatives, have been amplified by the polymerase chain reaction (PCR), cloned, and sequenced. The genome of K. rigidula consists of three haplomes, St, P, and Y. An evaluation of the aligned sequences of the diverse 53 different 5S DNA units yielded three 5S-unit classes. One unit class, Long S1, was assignable to the St haplome, one unit class, the Long P1, was assignable to the P haplome, and a third unit class, Long H1, was assignable to the H haplome. The last was expected to be assignable to the Y haplome, based on previous knowledge. Evolutionary scenarios are put forward to explain this finding. Among those possibilities is that the number of copies of units assignable to the Y haplome is very small and difficult to detect. Short units, reported earlier in K. alatavica, were not found in K. rigidula. Key words: 5S RNA gene, genomes, Triticeae, 5S DNA unit classes.

scholarly journals Karyotype and putative chromosomal inversion suggested by integration of cytogenetic and molecular data of the fungus-farming ant Mycetomoellerius iheringi Emery, 1888

2020 ◽  
Vol 14 (2) ◽  
pp. 197-210 ◽  
Author(s):  
Ricardo Micolino ◽  
Maykon Passos Cristiano ◽  
Danon Clemes Cardoso
Keyword(s):  
Phylogenetic Relationships ◽  
Pericentric Inversion ◽  
Phylogenetic Reconstruction ◽  
Chromosomal Evolution ◽  
Molecular Data ◽  
Chromosomal Inversion ◽  
Evolutionary Relationships ◽  
Congeneric Species ◽  
Cytogenetic Analyses ◽  
Species Evolution

Comparative cytogenetic analyses are being increasingly used to collect information on species evolution, for example, diversification of closely related lineages and identification of morphologically indistinguishable species or lineages. Here, we have described the karyotype of the fungus-farming ant Mycetomoellerius iheringi Emery, 1888 and investigated its evolutionary relationships on the basis of molecular and cytogenetic data. The M. iheringi karyotype consists of 2n = 20 chromosomes (2K = 18M + 2SM). We also demonstrated that this species has the classical insect TTAGG telomere organization. Phylogenetic reconstruction showed that M. iheringi is phylogenetically closer to M. cirratus Mayhé-Nunes & Brandão, 2005 and M. kempfi Fowler, 1982. We compared M. iheringi with other congeneric species such as M. holmgreni Wheeler, 1925 and inferred that M. iheringi probably underwent a major pericentric inversion in one of its largest chromosomes, making it submetacentric. We discussed our results in the light of the phylogenetic relationships and chromosomal evolution.

Phylogenetic relationships ofSphaerophoraceae (Ascomycetes) inferred from SSU rDNA sequences

1998 ◽  
Vol 209 (1-2) ◽  
pp. 75-83 ◽  
Author(s):  
Mats Wedin ◽  
Anders Tehler ◽  
Andrea Gargas
Keyword(s):  
Phylogenetic Relationships ◽  
Ssu Rdna ◽  
Rdna Sequences

scholarly journals Temporal ranges and ancestry in the hominin fossil record: The case of Australopithecus sediba

2018 ◽  
Vol 114 (3/4) ◽  
Author(s):  
Chris Robinson ◽  
Timothy L. Campbell ◽  
Susanne Cote ◽  
Darryl J. de Ruiter
Keyword(s):  
Phylogenetic Relationships ◽  
Fossil Record ◽  
Thought Experiment ◽  
Mammalian Species ◽  
Data Sources ◽  
Evolutionary Relationships ◽  
Temporal Data ◽  
Genus Homo ◽  
Using Data ◽  
Fossil Hominin

In attempting to resolve the phylogenetic relationships of fossil taxa, researchers can use evidence from two sources – morphology and known temporal ranges. For most taxa, the available evidence is stronger for one of these data sources. We examined the limitations of temporal data for reconstructing hominin evolutionary relationships, specifically focusing on the hypothesised ancestor–descendant relationship between Australopithecus sediba and the genus Homo. Some have implied that because the only known specimens of A. sediba are dated to later than the earliest fossils attributed to Homo, the former species is precluded from being ancestral to the latter. However, A. sediba is currently known from one site dated to 1.98 Ma and, thus, its actual temporal range is unknown. Using data from the currently known temporal ranges of fossil hominin species, and incorporating dating error in the analysis, we estimate that the average hominin species’ temporal range is ~0.97 Myr, which is lower than most figures suggested for mammalian species generally. Using this conservative figure in a thought experiment in which the Malapa specimens are hypothesised to represent the last appearance date, the middle of the temporal range, and first appearance date for the species, the first appearance date of A. sediba would be 2.95, 2.47 and 1.98 Ma, respectively. As these scenarios are all equally plausible, and 2.95 Ma predates the earliest specimens that some have attributed to Homo, we cannot refute the hypothesis that the species A. sediba is ancestral to our genus based solely on currently available temporal data.

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