Nuclear DNA Amounts in Angiosperms--583 New Estimates

The amount of DNA in the unreplicated haploid nuclear genome(itsC-value) varies over 600-fold between angiosperm species.Information regarding this character is used in a strikinglywide variety of plant biological fields. Moreover, recent studieshave noted a significant need for more information about thisimportant aspect of genome biodiversity. Bennett and co-authorshave published four collected lists of nuclear DNA amounts inangiosperm species, compiled primarily for reference purposes,including the most recent in 1995 (Annals of Botany76: 113–176).Together they list estimates for over 2500 species which representabout 1% of the global angiosperm flora. Interest in angiospermgenome size has remained high, as shown by the recent publicationof many new estimates, creating a need for a fifth compilation.This paper presents a supplementary list of nuclear DNAC-valuesfrom 37 sources for 471 angiosperm species not listed in theaforementioned compilations, plus additional estimates for 113species already listed by them. It contains estimates for palm,orchid and tropical hardwood species which significantly improvesrepresentation of the global flora. Work is in hand to combinethe genome size data compiled in this and the aforementionedpapers into a unified database, and to present the informationin separate lists, with species in alphabetical and systematicorders, respectively. Meanwhile, the availability of DNAC-valuesfor angiosperm species can be checked on the World Wide Web(http://www.rbgkew.org.uk/cval/database1.html). Angiosperm DNA amounts; DNAC-values; nuclear genome sizes; reference lists; plant DNA database     

Nuclear DNA Amounts in Angiosperms and their Modern Uses--807 New Estimates

The DNA amount in the unreplicated haploid nucleus of an organismis known as its C-value. C-values differ about 1000-fold amongangiosperms and are characteristic of taxa. The data are usedin many biological fields, so they should be easily available.Values for 2802 angiosperm species (1%) were estimated during1950–1997, and five collected lists of C-values were publishedfor reference purposes during 1976–1997. Numbers of newangiosperm C-values published recently remained high, necessitatinga further supplementary list. This paper lists DNA C-valuesfor 807 angiosperm species from 70 original sources, including520 (75.2%) from sources published after 1996, and 691 for speciesnot included in any of the previous five lists. There is a continuingneed to estimate accurate DNA C-values for plant taxa, as shownin a workshop on this biodiversity topic sponsored by Annalsof Botany and held at Kew in 1997. Its key aim was to identifymajor gaps in our knowledge of plant DNA amounts and to recommendtargets and priorities for new work to fill them. A target ofestimating first C-values for the next 1% of angiosperm speciesin 5 years was set. The proportion of such C-values in the presentwork (85.6%) is very high; and the number being published (approx.220 per annum) has never been exceeded. In 1997, C-values werestill unknown for most (68%) families, so a target of completecoverage was set. This paper includes first C-values for 12families, but as less than 2% of such values listed here targetednew families, the need to improve familial representation remains.Copyright 2000 Annals of Botany Company Angiosperm DNA amounts, DNA C-values, nuclear genome sizes, plant DNA database     

Nuclear dna amounts in angiosperms.

The number of angiosperm species for which nuclear DNA amount estimates have been made has nearly trebled since the last collected lists of such values were published, and therefore, publication of a more comprehensive list is over due. This paper lists absolute nuclear DNA amounts for 753 angiosperm species. The dats were assembled primarily for reference purposes, and so the species are listed in alphabetical order, as this was felt to be more helpful to cyto- and biochemists whom, it is anticipated, will be among its major users. The paper also reviews aspects of the history, nomenclature, methods, accuracy and problems of nuclear DNA estimation in angiosperms. No attempt is made to reconsider those aspects of nuclear DNA estimation which have been fully revised previously, although the bibliography of such aspects is given. Instead, the paper is intended as a source of basic information regarding the terminology, practice and limitations of nuclear DNA estimation, especially by Feulgen microdensitometry, as currently practiced.     

First Nuclear DNA C-values for 25 Angiosperm Families

DNA amount is a widely used biodiversity character. As knownDNA C-values represent the global angiosperm flora poorly, bettercoverage of taxonomic groups is needed, including at the familiallevel. A workshop, sponsored byAnnals of Botany , was held atthe Royal Botanic Gardens, Kew in 1997. Its key aim was to identifymajor gaps in our knowledge of plant DNA C-values and recommendtargets for new work to fill them by international collaboration.In 1997 C-values were known for approx. 150 families, meaningthere was no estimate for most angiosperm families (approx 68%).The workshop recommended a goal of complete familial representationby 2002, as a main target for angiosperms. Bennett et al. (Annalsof Botany86: 859–909, 2000) presented a fifth supplementarylist of angiosperm C-values from 70 original sources which includedfirst C-values for 691 species. Only 12 (1.7%) of these werefirst C-values for unrepresented families, so the need to improvefamilial representation was substantially unmet. We began newwork to address this in September 1999, and now report firstDNA C-values for 25 angiosperm families. Such targeting seemsessential to achieve the goal of familial coverage set by the1997 workshop within 5 years. 4C values range from 0.67 pg (similartoArabidopsis thaliana ) in Amoreuxia wrightii(Cochlospermaceae)to 7.49 pg in Deutzia prunifolia(Hydrangeaceae). These datasupport the view that ancestral angiosperms almost certainlyhad small genomes (defined as 1C     

First nuclear DNA amounts in more than 300 angiosperms

BACKGROUND AND AIMS: Genome size (DNA C-value) data are key biodiversity characters of fundamental significance used in a wide variety of biological fields. Since 1976, Bennett and colleagues have made scattered published and unpublished genome size data more widely accessible by assembling them into user-friendly compilations. Initially these were published as hard copy lists, but since 1997 they have also been made available electronically (see the Plant DNA C-values database http://www.kew.org/cval/homepage.html). Nevertheless, at the Second Plant Genome Size Meeting in 2003, Bennett noted that as many as 1000 DNA C-value estimates were still unpublished and hence unavailable. Scientists were strongly encouraged to communicate such unpublished data. The present work combines the databasing experience of the Kew-based authors with the unpublished C-values produced by Zonneveld to make a large body of valuable genome size data available to the scientific community. METHODS: C-values for angiosperm species, selected primarily for their horticultural interest, were estimated by flow cytometry using the fluorochrome propidium iodide. The data were compiled into a table whose form is similar to previously published lists of DNA amounts by Bennett and colleagues. KEY RESULTS AND CONCLUSIONS: The present work contains C-values for 411 taxa including first values for 308 species not listed previously by Bennett and colleagues. Based on a recent estimate of the global published output of angiosperm DNA C-value data (i.e. 200 first C-value estimates per annum) the present work equals 1.5 years of average global published output; and constitutes over 12 % of the latest 5-year global target set by the Second Plant Genome Size Workshop (see http://www.kew.org/cval/workshopreport.html). Hopefully, the present example will encourage others to unveil further valuable data which otherwise may lie forever unpublished and unavailable for comparative analyses.     

Nuclear DNA Content of 26 Orchid (Orchidaceae) Genera with Emphasis onDendrobium

2C DNA content values for 70 orchid species from 26 genera,including 37Dendrobiumspecies from eight taxonomic sections,were analysed using flow cytometry. The resulting nuclear DNAcontent values for species other thanDendrobiumranged from 1.91pg 2C^-1to 15.19 pg 2C^-1nuclei forCadetia tayloriandVanilla phaeantha,respectively.Dendrobiumnuclear DNA content values ranged from1.53 pg 2C^-1to 4.23 pg 2C^-1nuclei forD. cruentumandD. spectabile,respectively. DNA content measurements varied greatly withinDendrobiumsectionsLatouria and Spatulata. Nuclear DNA content values for the sixspecies analysed within Latouria ranged from 1.88 pg 2C^-1nucleiforD. macrophyllumto 4.23 pg 2C^-1nuclei forD. spectabile. NuclearDNA content values for the 16 species analysed within Spatulataranged from 1.69 pg 2C^-1nuclei forD. discolorto 4.05 pg 2C^-1nucleiforD. samoense. The least variation in DNA content was foundwithin the section Phalaenanthe, with nuclear DNA content valuesof 1.79 pg  2C^-1, 1.86 pg 2C^-1and 1.98 pg 2C^-1forD. bigibbum,D.affineandD. phalaenopsis, respectively.Copyright 1998 Annalsof Botany Company Orchidaceae,Dendrobium, flow cytometry, propidium iodide, nuclear DNA, genome size, 2C values.     

Nuclear DNA amounts in angiosperms: targets, trends and tomorrow

BACKGROUND AND AIMS: The amount of DNA in an unreplicated gametic chromosome complement is known as the C-value and is a key biodiversity character of fundamental significance with many practical and predictive uses. Since 1976, Bennett and colleagues have assembled eight compilations of angiosperm C-values for reference purposes and subsequently these have been pooled into the Angiosperm DNA C-values Database (http://data.kew.org/cvalues/). Since the last compilation was published in 2005, a large amount of data on angiosperm genome size has been published. It is therefore timely to bring these data together into a ninth compilation of DNA amounts. Scope The present work lists DNA C-values for 2221 species from 151 original sources (including first values for 1860 species not listed in previous compilations). Combining these data with those published previously shows that C-values are now available for 6287 angiosperm species. KEY FINDINGS: Analysis of the dataset, which is by far the largest of the nine compilations published since 1976, shows that angiosperm C-values are now being generated at the highest rate since the first genome sizes were estimated in the 1950s. The compilation includes new record holders for the smallest (1C = 0·0648 pg in Genlisea margaretae) and largest (1C = 152·23 pg in Paris japonica) genome sizes so far reported, extending the range encountered in angiosperms to nearly 2400-fold. A review of progress in meeting targets set at the Plant Genome Size meetings shows that although representation for genera, geographical regions and some plant life forms (e.g. island floras and parasitic plants) has improved, progress to increase familial representation is still slow. In terms of technique it is now clear that flow cytometry is soon likely to become the only method available for plant genome size estimations. Fortunately, this has been accompanied by numerous careful studies to improve the quality of data generated using this technique (e.g. design of new buffers, increased awareness and understanding of problems caused by cytosolic inhibitors). It is also clear that although the speed of DNA sequencing continues to rise dramatically with the advent of next-generation and third-generation sequencing technologies, 'complete genome sequencing' projects are still unable to generate accurate plant genome size estimates.     

Nuclear DNA amounts in angiosperms: progress, problems and prospects

BACKGROUND: The nuclear DNA amount in an unreplicated haploid chromosome complement (1C-value) is a key diversity character with many uses. Angiosperm C-values have been listed for reference purposes since 1976, and pooled in an electronic database since 1997 (http://www.kew.org/cval/homepage). Such lists are cited frequently and provide data for many comparative studies. The last compilation was published in 2000, so a further supplementary list is timely to monitor progress against targets set at the first plant genome size workshop in 1997 and to facilitate new goal setting. SCOPE: The present work lists DNA C-values for 804 species including first values for 628 species from 88 original sources, not included in any previous compilation, plus additional values for 176 species included in a previous compilation. CONCLUSIONS: 1998-2002 saw striking progress in our knowledge of angiosperm C-values. At least 1700 first values for species were measured (the most in any five-year period) and familial representation rose from 30 % to 50 %. The loss of many densitometers used to measure DNA C-values proved less serious than feared, owing to the development of relatively inexpensive flow cytometers and computer-based image analysis systems. New uses of the term genome (e.g. in 'complete' genome sequencing) can cause confusion. The Arabidopsis Genome Initiative C-value for Arabidopsis thaliana (125 Mb) was a gross underestimate, and an exact C-value based on genome sequencing alone is unlikely to be obtained soon for any angiosperm. Lack of this expected benchmark poses a quandary as to what to use as the basal calibration standard for angiosperms. The next decade offers exciting prospects for angiosperm genome size research. The database (http://www.kew.org/cval/homepage) should become sufficiently representative of the global flora to answer most questions without needing new estimations. DNA amount variation will remain a key interest as an integrated strand of holistic genomics.     

First Nuclear DNA C-values for Another 25 Angiosperm Families

Nuclear DNA C-value is an important genomic biodiversity characterwith many uses. An international workshop sponsored by Annalsof Botany and held at the Royal Botanic Gardens, Kew, UK, in1997 identified major gaps in our knowledge of plant DNA C-valuesand recommended targets for new work. Improved taxonomic coveragewas highlighted as a key need for angiosperms, especially atthe familial level. In 1997 C-values were known for only approx.32% of angiosperm families; a goal of complete familial representationby 2002 was recommended. A review published in 2000 (Bennettet al.;Annals of Botany86: 859–909) noted poor progresstowards this aim: of the 691 first C-values for species only12 (1.7%) were for unrepresented families. We began new workto address this in 1999, reporting first DNA C-values for 25angiosperm families in 2001 (Hanson et al.;Annals of Botany87:251–258). Here we report first DNA C-values for a further25 angiosperm families, increasing familial coverage in angiospermsto approx. 45%. Such targeting remains essential to approachthe goal set by the 1997 workshop of familial coverage for angiospermswithin 5 years. The 4C DNA amounts presented here range from0.76 pg (similar toArabidopsis thaliana ) in Roridula gorgonias(Roridulaceae)to 29.74 pg in Gunnera manicata(Gunneraceae). 1C values were< 3.5 pg in 23 of the 25 families; these data provide furthersupport for the view that ancestral angiosperms almost certainlyhad small genomes (defined as 1C     

Amounts of nuclear DNA in marine halophytes

The amount of nuclear DNA, expressed as the C-value, was estimated for 13 marine halophytic plant species from six families. Plant material was collected in the nature reserve of the Strunjan saltpan in the Northern Adriatic and comprised all halophytic species inside the investigated area. Reproductive region of the shoot or root tips of halophytes were dissected, nuclei were Feulgen stained and 2C-values were measured by DNA image cytometry as follows: Crithmum maritimum (4.38 pg DNA), Artemisia caerulescens (6.43 pg), Aster tripolium (21.43 pg), Inula crithmoides (3.63 pg), Atriplex portulacoides (1.83 pg), A. prostrata (1.51 pg), Salicornia europaea (2.75 pg), Salsola soda (2.62 pg), Sarcocornia fruticosa (5.91 pg), Suaeda maritima (2.11 pg), Limonium angustifolium (5.06 pg), Puccinellia palustris (8.15 pg) and Ruppia cirrhosa (4.65 pg). With the exception of the C-value estimate for A. caerulescens, which has been listed in the Plant DNA C-values Database, the C-values represent the first estimates for all the examined species. In addition, the C-value for R. cirrhosa is also the first report for the family Ruppiaceae. The investigated halophytes had a smaller genome size compared to other known C-values for species within a particular family and also when compared to the mean values of dicots and monocots. The study also showed that halophylic annuals have a smaller genome size (2.49 pg) than perennial ones (7.45 pg DNA).     

Allium cepa L. Cultivars from Four Continents Compared by Flow Cytometry show Nuclear DNA Constancy

In 1965 Van't Hof estimated the nuclear DNA amount of an unidentifiedAllium cepa L. cultivar as 2C = 33.55 pg (Experimental CellResearch39: 8–58). This value has been adopted by commonusage as the main calibration standard for angiosperm DNA C-valueestimations. However, different cultivars have been used whileassuming species DNA C-value constancy. Surprisingly this assumptionhas never been tested. A. cepa is an outbreeder with telomericheterochromatic segments, so intraspecific variation in C-value,possibly correlated with environmental factors as seen in Zeamays L., might be expected. We used laser flow cytometry tocompare nuclear DNA amounts in roots of six A. cepa cultivarsused as calibration standards or from different environments.Tissues from one cultivar, or similar volumes of tissue fromtwo cultivars, were run and the variance between nuclei in 2Cpeaks compared. Only one shoulderless 2C peak was seen for allpairs of co-chopped cultivars. Thus, no large differences inC-value between cultivars from different environments were found.Moreover, comparing cultivars run singly or as pairs showedno evidence for increased variation in 2C peaks in the latter,and hence of critical differences in DNA amounts between ‘AilsaCraig’ and another cultivar. Such variation was insufficientto make their use as alternative calibration standards, or thepractice of imputing Van't Hof's original C-value estimate tothem, unacceptable for most practical purposes. Given the mechanismsknown which can generate genome size variation, the degree ofconstancy in DNA C-value found seems remarkable. Copyright 2000Annals of Botany Company Allium cepa, onion cultivars, calibration standards, DNA C-value constancy, flow cytometry     

A Lack of Nuclear DNA Content Variability Among Wheat Near Isolines Differing in Aluminium Response

Nucleotypic variation has been speculated to play a role inthe adaptation of crop species to environmental stress. Theobjective of this study was to determine if nuclear DNA contentvariability was associated with aluminium (Al) tolerance inwheat. Six wheat (Triticum aestivumL.) near isolines (differingin Al response), two recurrent parents (Al sensitive), and onedonor parent (Al tolerant) were all analysed for nuclear DNAcontent using flow cytometry. A 1.7% variation in nuclear DNAcontent was observed among the nine wheat lines. No associationbetween Al response and nuclear DNA content was observed. Allof the wheat near isolines had a nuclear DNA content similarto their recurrent parent. The wheat genome appears to be stablewith no unusual inheritance of nuclear DNA content observed.Flow cytometric analysis proved to be sensitive enough to detectnuclear DNA content variability at the level of 0.5% variationamong wheat lines.Copyright 1999 Annals of Botany Company Genome size,Triticum,breeding, near isogenic.     

Nuclear genome size variation in fleshy-fruited Neotropical Myrtaceae

In Myrtaceae, reports regarding the nuclear DNA content are scarce. The aim of this study is to present genome size data for fleshy-fruited Myrteae, and to test their relation with chromosome number and ploidy, the available data for cytoevolutionary studies in Myrtaceae. Thirty species out of ten genera were investigated for chromosome number and genome size using flow cytometry. Twenty-eight species were diploid with 2n = 2x = 22 and two species were tetraploid with 2n = 4x = 44. All genome sizes measured are new. Among the diploid species, a gradual and small variation in 2C-values (0.486 pg in Gomidesia schaueriana to 0.636 pg in Eugenia multicostata) was observed, whereas the tetraploid genomes of Psidium acutangulum and P. cattleianum had about twice as much DNA (1.053 and 1.167 pg, respectively). The total interspecific variation of C-values was 2.45-fold. The fleshy-fruited Myrteae have smaller holoploid genomes than the capsular-fruited Eucalypteae and Melaleuceae.     

Mitochondrial DNA of Vitis vinifera and the issue of rampant horizontal gene transfer

The mitochondrial genome of grape (Vitis vinifera), the largestorganelle genome sequenced so far, is presented. The genomeis 773,279 nt long and has the highest coding capacity amongknown angiosperm mitochondrial DNAs (mtDNAs). The proportionof promiscuous DNA of plastid origin in the genome is also thelargest ever reported for an angiosperm mtDNA, both in absoluteand relative terms. In all, 42.4% of chloroplast genome of Vitishas been incorporated into its mitochondrial genome. In orderto test if horizontal gene transfer (HGT) has also contributedto the gene content of the grape mtDNA, we built phylogenetictrees with the coding sequences of mitochondrial genes of grapeand their homologs from plant mitochondrial genomes. Many incongruentgene tree topologies were obtained. However, the extent of incongruencebetween these gene trees is not significantly greater than thatobserved among optimal trees for chloroplast genes, the commonancestry of which has never been in doubt. In both cases, weattribute this incongruence to artifacts of tree reconstruction,insufficient numbers of characters, and gene paralogy. Thisfinding leads us to question the recent phylogenetic interpretationof Bergthorsson et al. (2003, 2004) and Richardson and Palmer(2007) that rampant HGT into the mtDNA of Amborella best explainsphylogenetic incongruence between mitochondrial gene trees forangiosperms. The only evidence for HGT into the Vitis mtDNAfound involves fragments of two coding sequences stemming fromtwo closteroviruses that cause the leaf roll disease of thisplant. We also report that analysis of sequences shared by bothchloroplast and mitochondrial genomes provides evidence fora previously unknown gene transfer route from the mitochondrionto the chloroplast.     

Amounts of nuclear DNA in marine halophytes

The amount of nuclear DNA, expressed as the C-value, was estimated for 13 marine halophytic plant species from six families. Plant material was collected in the nature reserve of the Strunjan saltpan in the Northern Adriatic and comprised all halophytic species inside the investigated area. Reproductive region of the shoot or root tips of halophytes were dissected, nuclei were Feulgen stained and 2C-values were measured by DNA image cytometry as follows: Crithmum maritimum (4.38 pg DNA), Artemisia caerulescens (6.43 pg), Aster tripolium (21.43 pg), Inula crithmoides (3.63 pg), Atriplex portulacoides (1.83 pg), A. prostrata (1.51 pg), Salicornia europaea (2.75 pg), Salsola soda (2.62 pg), Sarcocornia fruticosa (5.91 pg), Suaeda maritima (2.11 pg), Limonium angustifolium (5.06 pg), Puccinellia palustris (8.15 pg) and Ruppia cirrhosa (4.65 pg). With the exception of the C-value estimate for A. caerulescens, which has been listed in the Plant DNA C-values Database, the C-values represent the first estimates for all the examined species. In addition, the C-value for R. cirrhosa is also the first report for the family Ruppiaceae. The investigated halophytes had a smaller genome size compared to other known C-values for species within a particular family and also when compared to the mean values of dicots and monocots. The study also showed that halophylic annuals have a smaller genome size (2.49 pg) than perennial ones (7.45 pg DNA).     

Mitochondrial Ribosomal Protein L11 Gene of Dictyostelium discoideum Resides not in the Nuclear Genome but in the Mitochondrial Genome

During the course of analysis of the mitochondrial genome ofthe cellular slime mold, Dictyostelium discoideum, we founda gene (rpl11) for mitochondrial ribosomal protein L11 (RPL11),having 172 amino acid residues. Southern blot analysis revealedthat the gene resided in the mitochondrial DNA as a singlecopybut not in the nuclear DNA. From Northern blot experiments,one major mRNA (about 27 kb) and two minor mRNAs (about 4 and5 kb) for the gene were detected in the mitochondria. This isthe first report showing that the active gene for RPL11 stillresides in the mitochondrial genome and has not been transferredto the nuclear genome in D. discoideum.     

Variation of Nuclear DNA Content in the Biflorus Species of Lonchocarpus (Leguminosae)

This represents the first study of nuclear DNA content in alarge sample (135 spp.) from a tropical arboreal genus, in whicha large proportion of the species were examined (42 spp., 31.1%).Somatic chromosome numbers and 4C-DNA values for 51 taxa ofLonchocarpus are reported. All taxa were diploid with 2 n =22,but their DNA content ranged from 1.92 to 2.86 pg 4C nucleus,corresponding to a 48.95% variation in genome size. In the 74collections studied, no correlation was observed between DNAcontent and habitat altitude. Variation in nuclear DNA contentwas analysed at the level of genus, subgenus, section and subsection.Variation in genome size was also studied within some species,either among widely separated populations or among differentintraspecific taxa. Very little variation in genome size wasdetected between populations, subspecies, and varieties of thesame species. The taxonomic implications of variation in nuclearDNA content are discussed.Copyright 2000 Annals of Botany Company Lonchocarpus (Leguminosae), DNA content, chromosome number.     

Nuclear DNA Content Diversity in Chinese Soybean Introductions

Intraspecific nuclear DNA content has been documented in variousangiosperm species. The purpose of this study was to determinethe nuclear DNA content variation in soybean (Glycine max(L.)Merr.). Several studies have suggested that DNA content variationexists in soybean. Ninety soybean lines representing diversegeographic locations in China were analysed by flow cytometry.Nuclei were isolated and stained with either the fluorochromeDAPI or PI. After analysis, it was determined that PI stainednuclei more accurately assessed the total DNA content in soybean.A 12% variation in nuclear DNA content was observed among the90 lines. The amount of nuclear DNA in the lines was withinthe DNA range of United States cultivars previously examined.Nuclear DNA content variation in soybean is much less than thevariation reported in maize. These results could be due to thelack of polymorphism in large chromosomal elements containinglarge blocks of repetitive DNA. In addition, unlike maize, theamounts of DNA variation did not decrease as a result of moreintensive breeding in United States cultivars. Intraspecificnuclear DNA content variability is very different between thesetwo major agronomic species. Glycine max(L.) Merr.; germplasm; genome size     

Genome Size inAllium: In Quest of Reproducible Data

ComparingAlliumgenome size measurements of different authors,we noticed that the estimates for certain species diverge morestrongly than one would have expected in view of the methodologicaladvantages of the material. As the matter has theoretical significancefor explaining the biological role of genome size variation,we measured, by Feulgen densitometry, 28 species and altogether57 accessions or cultivars. Flow cytometric measurements supplementedthese data. The current hypothesis of a discontinuous and step-wisedistribution of DNA amounts inAlliumseems questionable, as mostof our DNA values did not appear in the corresponding DNA groupas proposed previously. On the other hand, we can confirm thatthere is a significant negative correlation between genome sizeof a species and its first month of flowering, but only in diploids,or in diploids and polyploids if only the basic genome size(2Cxlevel) is considered. We compared our results with thoseof nine other publications. Only 29 of 60 2C values publishedpreviously deviate less than 10% from our data, the others deviatemore strongly, from 0.44- to 1.44-fold. The more comprehensivedata sets of various authors were compared by correlation analysiswith our data. Positive and mostly significant correlationswere seen in all tests, but nevertheless the degree of incongruencebetween studies was unsatisfactory in view of the much betterintra-laboratory reproducibility of the present data. The presentwork highlights the need for generally agreed improvements instandardization and preparative procedures of cytophotometricgenome size determination.Copyright 1999 Annals of Botany Company Allium, genome size, Feulgen densitometry, flow cytometry, discontinuous DNA content variation, nucleotype hypothesis, flowering time, data reproducibility, correlation analysis.     

Identification of the Genomic Constitution ofMusaL. Lines (Bananas, Plantains and Hybrids) Using Molecular Cytogenetics

The genomic constitutions of someMusaL. lines (bananas, plantainsand artificial hybrids) were identified using molecular cytogenetictechniques. Double targetin situDNA:DNA hybridization to chromosomespreads using as probes, total genomic DNA isolated from diploidMusalinesof known AA (labelled with biotin-11-dUTP) and BB (labelledwith digoxigenin-11-dUTP) genome constitution was carried out.The use of 60% acetic acid combined with heating over a flamegave high quality chromosome spreads free of cytoplasm forinsituhybridization. Total genomic A DNA labelled broad centromericregions of all 22 chromosomes of the diploid line, Calcutta4 (M. acuminataColla. ssp.burmanniccoides; A genome) with somechromosomes showing stronger hybridization. Labelled DNA fromthe B genome hybridized strongly to the centromeric regionsof all 22 chromosomes of Butohan 2 (M. balbisianaColla; B genome).The two satellited chromosomes of genome B labelled stronglywith genomic A DNA.In situhybridization of labelled A and Bgenomic DNA to metaphase chromosomes of triploid AAB and ABBcultivars discriminated between A and B genome chromosomes.The plantains Agbagba, Obino l'Ewai and Mbi Egome showed 22genome A and 11 genome B chromosomes while the cooking bananasBluggoe and Fougamou showed 11 genome A and 22 genome B chromosomes.Hybridization of labelled A and B genomic DNA to chromosomesof the hybrids showed that TMP2x 2829-62 has all 22 genome Achromosomes while TMPx 4698-1 has 33 genome A and 11 genomeB chromosomes.In situhybridization of labelled total genomicDNA to chromosomes has immense potential for identificationof chromosome origin and can be used to characterize cultivarsand hybrids produced inMusabreeding.Copyright 1997 Annals ofBotany Company Genomicin situhybridization; banana; plantain; hybrids; plant breeding; genome organization; biodiversity