Ribosomal and chloroplast DNA restriction site mutations and the radiation ofRobinsonia (Asteraceae: Senecioneae) on the Juan Fernandez Islands

Restriction site mutations in the chloroplast (cpDNA) and ribosomal DNA (rDNA) were examined in 41 populations representing five of the seven recognized species of the genusRobinsonia, which is endemic to the Juan Fernandez Islands. No intraspecific variation was detected for cpDNA but one population of one of the species (R. evenia) had a restriction site mutation in rDNA not detected elsewhere. No restriction site mutations were unique to all species ofRobinsonia relative to the species ofSenecio used as outgroups. All 13 mutations (eight from cpDNA and five from rDNA) are restricted to single species, and thus provide no cladistically useful information within the genus. The distribution of mutations is concordant with the hypothesis of a rapid adaptive radiation ofRobinsonia subsequent to the dispersal of its ancestor to Masatierra.     

Ribosomal DNA variation within and among individuals ofLisianthius (Gentianaceae) populations

Restriction endonuclease fragment analysis of nuclear ribosomal DNA (rDNA) was completed on 25 individuals each from seven populations of theLisianthius skinneri (Gentianaceae) species complex in Panama. Seven restriction enzymes were used to determine the amount and type of rDNA variation within and among individuals of the populations. No restriction site variation was seen within populations or individuals although site differences were seen among populations. Spacer length variation within and among individuals of populations was mapped to the internal transcribed spacer (ITS) region between the 18S and 5.8S rRNA genes, a region inLisianthius rDNA that previously was shown to exhibit length differences among populations. This is the first reported case of such variation within and among individuals of populations for the ITS region. Presence or absence of ITS spacer length variation is not correlated with levels of isozymic heterozygosity within populations. No detectable length variation within individuals or populations was seen in the larger intergenic spacer (IGS). Although populations varied with respect to IGS length, all individuals of a given population had a single and equivalent IGS length.     

RAPD marker diversity within and divergence among species of Dendroseris (Asteraceae: Lactuceae)

Random Amplified Polymorphic DNA (RAPD) markers were used to measure genetic diversity within and divergence among species of Dendroseris (Asteraceae: Lactuceae), a genus endemic to the Juan Fernandez Islands, Chile. Results were compared to previous studies employing allozymes. For five of the species, RAPD banding patterns distinguished all individuals examined, and different mutilocus genotypes were found even in species exhibiting no allozyme diversity. RAPD band diversities ranged from 0.003 to 0.022 within species; >90% of total diversity was among species and <10% within them. Relative levels of allozyme and RAPD diversity were similar for some species, particularly those with highest and lowest diversities, but overall there was no significant correlation. Relationships inferred from a neighbor-joining tree generated from RAPD bands were similar to results obtained from morphology, chloroplast DNA (cpDNA) restriction site mutations, and sequences from the internal transcribed spacer regions of nuclear ribosomal DNA (ITS), but somewhat better resolution was achieved. Relationships shown by allozymes differed from trees based on other data; this ostensibly is a result of the sharing of ancestral alleles and the absence of alleles generated subsequent to speciation. Dendroseris represents an example where RAPD markers, because of their greater variability, provide a useful alternative to allozymes for assessing diversity in rare species endemic to oceanic islands and for resolving relationships among the species.     

Evolution and history of hummingbirds (Aves: Trochilidae) from the Juan Fernandez Islands, Chile

The Juan Fernandez Firecrown Sephanoides fernandensis is an endangered endemic hummingbird that inhabits the Juan Fernandez Islands, 667 km off the coast of Chile. Its population has decreased from several thousand in the early part of this century to approximately 250–400 individuals at present. The reasons for its decline include habitat degradation by anthropogenic forest clearance and the introduction of grazing mammals and rodents. Another hummingbird, the Green-backed Firecrown Sephanoides sephaniodes, inhabits the Juan Fernandez Islands but is also found on the Chilean mainland. It currently numbers several thousand on the Juan Fernandez Islands but was considered rare during the late 19th and early 20th centuries. The sister relationship between the two species has not been critically tested, and so their evolutionary histories on the Juan Fernandez Islands remain uncertain. With the use of mtDNA cytochrome b and ND2 phylogenetic reconstructions, our study supports the two species as sister taxa. Moreover, the molecular data suggest that the genus Sephanoides is closely related to the higher altitude Andean hummingbirds typical of the paramo and puna habitats. The molecular divergence between the two species of Sephanoides indicates they may have become isolated from each other less than 1 million years ago, suggesting that S. fernandensis evolved in situ on the Juan Fernandez Islands. We find no evidence of genetic subdivision between populations of S. sephaniodes from the Juan Fernandez Islands and the mainland. In addition, high genetic variation of the Juan Fernandez Islands population does not indicate a long period of isolation of a limited number of S. sephaniodes but instead suggests a recent colonization event, perhaps from several mainland populations. As a result of molecular, morphological and apparent ecological similarities, we suggest that competition by S. sephaniodes may be an additional factor stifling the recovery of S. fernandensis. Possible conservation strategies include habitat restoration and the removal of introduced mammals; immediate implementation of such conservation management plans are necessary to save this species from extinction.     

DNA evidence for multiple origins of intergeneric allopolyploids in annualMicroseris (Asteraceae)

Seventy populations of North American annualMicroseris, Stebbinsoseris, andUropappus species were examined for chloroplast and nuclear ribosomal DNA restriction site variability to determine the origin of the allotetraploid speciesS. heterocarpa andS. decipiens. Previously identified chloroplast DNA restriction site variants were used in concert with restriction site variation forNco I in the nuclear-encoded ribosomal DNA repeat. The presence of two, mutually exclusive restriction site gains were observed in diploid populations ofM. douglasii; these same variants were also found in populations of allotetraploidS. heterocarpa, indicating mutiple origins of this species from different maternal diploid populations ofM. douglasii. Variation in the rDNA repeat between the diploid annual species and the putative paternal genome ofU. lindleyi was found to be additive inS. heterocarpa. A similar relationship was observed for the origin ofS. decipiens; cpDNA restriction site variants found inM. bigelovii andM. douglasii were present inS. decipiens. The rDNANco I variants also were additive in this purported allotetraploid. These results confirm the reticulate evolutionary pattern inStebbinsoseris and provide another example of multiple origins of intergeneric allopolyploids.     

Ribosomal DNA spacer-length variation inSecale spp. (Poaceae)

Variation in ribosomal DNA spacer length was analysed in 23 populations of 12Secale spp. by restriction enzyme analysis. Digestion of rDNA with Taq I endonuclease enzyme yields spacer fragments that include the subrepeat array and the non-repetitive region downstream of the array. Extensive spacer length variation existed in most species with Taq I fragment lengths ranging from 0.9–3.1 kb. These length variants have been attributed to the differences in number of 134 bp spacer subrepeats within rDNA arrays.S. silvestre was the only species to exhibit a unique spacer length variant of 0.9 kb and this was shown to result from the presence of an extra Taq I site in the spacer. rDNA spacer length frequencies were determined for the species. These frequencies were used to derive phenetic relationships between the species by numerical taxonomic methods. In plots constructed fromGower's distance matrices,S. silvestre appeared well separated from the major cluster consisting of the other species. On the basis of morphological and cytogenetic criteria,S. silvestre is considered the most ancient species. The rDNA data is consistent with this interpretation as it shows a clear differentiation ofS. silvestre from all the other species based on length and nucleotide sequence composition of the spacer region.     

Ribosomal DNA variation and its phylogenetic implication in the genusBrachypodium (Poaceae)

The structure of ribosomal DNA ofBrachypodium and several other grass species was investigated using a heterologous rDNA probe from wheat. Several different rDNA families were present among perennial and annual species within the genus. In contrast to the annual species the perennial species exhibited a very low degree of repeat length variation. An extra Eco RI site and a Hin dIII site were observed in the IGS, which distinguishedBrachypodium from other grass genera. The restriction fragment length polymorphism and length variation of the repeat units have taxonomic value withinBrachypodium and are correlated with the classification ofBrachypodium derived from other data.     

Ribosomal DNA repeat unit polymorphism in 49 Vicia species

DNA restriction endonuclease fragment analysis was used to obtain new information on the genomic organization of Vicia ribosomal DNA (rDNA), more particularly among V. faba and its close relatives and the taxa within three (Narbonensis, Villosa, Sativa) species' complexes. Total genomic DNA of 90 accessions representing 49 Vicia species was restricted with 11 enzymes, and the restriction fragments were probed with three ribosomal clones. Twenty-eight repeat unit length classes were identified. The number of length classes (1–2) per accession did not correspond to the number of nucleolar organizing regions (NORs). The number of rRNA genes was independent of the 2C nuclear DNA amount present in the taxon. Each of the 90 accessions had 2 (rarely 1)-4 DraI sites. Those taxa with the same number of DraI sites generally could be distinguished from each other by different configurations. Probing of the DNA samples digested with tetranucleotide recognition restriction endonucleases emphasized differences between divergent spacer regions and enabled relative homologies between the coding regions to be established. Overall, rDNA restriction site variation among the species showed a good correlation with taxonomic classification. The rDNA analysis indicated evolutionary relatedness of the various taxa within the Narbonensis species complex. rDNA diversity within two other species complexes (Villosa, Sativa), on the other hand, was more extensive than expected. With few exceptions, data on the two complexes give evidence of taxon-specific divergences not seen with other approaches. The restriction site variability and repeat length heterogeneity in the rDNA repeat exhibited startling differences between V.faba and its close wild relatives included in the Narbonensis species complex. This analysis provides new evidence that none of the species within the complex can be considered to be putative allies of broad bean.     

Variation in the nuclear ribosomal DNA internal transcribed spacer (ITS) region of Pinus rzedowskii revealed by PCR-RFLP

 In the genus Pinus the internal transcribed spacers (ITS1 and ITS2) and the 5.8s region of the nuclear ribosomal DNA are approximately 3000 bp in length. ITS1 is considerably longer than ITS2 and partial sequences of ITS1 indicate that this region is evolving rapidly and exhibits intraspecific variation. The ITS2 and 5.8s regions are relatively conserved. We surveyed restriction fragment length variability of PCR-amplified fragments (PCR-RFLP) of the ITS region in four populations (86 individuals) of Pinus rzedowskii, a pine endemic to western Michoacán, Mexico. Five of the restriction endonucleases assayed revealed variation, with a total of 13 variants, most of which were length mutations of 300–900 bp. A moderate degree of population differentiation was detected. The average diversity (Shannon’s index) of ITS fragment size patterns was 1.19, with 34% of the variation due to differences among populations and 66% due to differences among individuals within populations. The same individuals were assayed for nine polymorphic isozymes, which gave diversity measures similar to those of each restriction endonuclease. Received: 25 August 1997 / Accepted: 19 September 1997     

Ribosomal Gene Structure, Variation and Inheritance in Maize and Its Ancestors

We have examined the structure of nuclear genes coding for ribosomal RNAs in maize and its wild relatives, the teosintes and Tripsacum. Digestion of the rDNA (genes coding for 18S, 5.8S and 26S RNAs) with 15 restriction endonucleases (with six base pair recognition sites) yields essentially a single map for the approximately 10,000 repeat units within an individual plant or species. Both length and site variation were detected among species and were concentrated in the intergenic spacer region of the rDNA repeat unit. This result is in agreement with patterns of rDNA change observed among wheat and its relatives (Triticeae), and among vertebrate species. Digestion of these nuclear DNAs with BamHI and subsequent hybridization with a 5S RNA gene-specific probe allowed determination of the size of the 5S gene repeat unit in maize, teosintes, and Tripsacum. Groupings in the genus Zea were characterized by distinct repeat unit types five Tripsacum species examined shared a 260 base pair major repeat unit type. Additionally, several other restriction endonuclease cleavage patterns differentiated among the 5S DNAs within the genus Zea. The rDNA and 5S DNA restriction site variation among the species can be interpreted phylogenetically and agrees with biochemical, karyotypic, and morphological evidence that places maize closest to the Mexican teosintes. For both gene arrays, contributions from each parental genome can be detected by restriction enzyme analysis of progeny from crosses between maize and two distantly related teosintes, Zea luxurians or Zea diploperennis, but certain teosinte arrays were underrepresented in some of the hybrids.     

Characterization of geographically isolated accessions in five Alstroemeria L. species (Chile) using FISH of tandemly repeated DNA sequences and RAPD analysis

In fifteen geographically isolated populations of five species of Alstroemeria L. (A. aurea, A. hookeri, A. ligtu, A. pelegrina and A. presliana) collected in Chile, karyotypes and variation of RAPD markers were investigated. Tandemly repeated DNA sequences - 5S and 18/25S rDNA genes and the sequence A001-1 (De Jeu et al. 1997) were used to characterize karyotypes by fluorescence in situ hybridization (FISH). Ten somatic metaphases per population were used for measurement of chromosome length. Differences in RAPD marker bands were used for characterization of populations, creating a similarity index. FISH with all three DNA probes shows a high degree of polymorphism between and sometimes also within accessions of A. aurea, A. hookeri and A. ligtu. The number of chromosome pairs showing 5S rDNA signals is more different for the investigated species A. aurea, A. hookeri, A. ligtu, A. pelegrina and A. presliana with 5, 7, 5, 3 and 7, respectively, than the number of 18/25S rDNA signals in this succession with 7, 7, 6, 5 and 7 chromosome pairs, showing a high evolutionary dynamics within the genus. Furthermore, among the four populations of A. hookeri, accession 4181 was different in arm length of chromosome 3. RAPD markers (index of similarity) also showed a greater genetic distance of accession 4181 from the other three accessions of A. hookeri. The possible evolutionary mechanisms providing these polymorphisms were discussed.     

Nuclear Ribosomal DNA as a Probe for Genetic Variability in the Japanese Pear Pathotype of Alternaria alternata

A restriction fragment length polymorphism analysis of nuclear ribosomal RNA genes (rDNA) was used to measure the amount and distribution of genetic variability in populations of the Japanese pear pathotype of Alternaria alternata on both micro- and macrogeographical scales. A total of 322 isolates were obtained from 13 areas in Aichi, Gifu, and Tottori Prefectures in central and western Japan. The restriction fragment length polymorphism analysis revealed that the pathogen populations contained at least eight rDNA variants. The eight variant types differed in the lengths and in the presence of the restriction sites in spacer DNA outside the coding regions for rRNAs. A total of 271 isolates were classified into the eight types. The remaining 51 isolates were determined to have mixed rDNA types. Single pear fields typically contained two to five types of rDNA variants. The frequencies of rDNA variants in 11 populations in Tottori Prefecture were compared; in this prefecture orchards containing the susceptible pear are common. Except for one collection site, there were no significant differences in the composition of the rDNA variants among the populations. This suggests that dispersal of inocula has occurred frequently in Tottori Prefecture. In contrast, significantly different distributions were observed in the three prefectures, indicating that gene flow between prefectures might be limited by geographical isolation. DNA fingerprints resulting from hybridization with a moderately repetitive DNA sequence of the fungus revealed greater genetic variability and geographical differences in genetic population structure even within the same rDNA type.     

Evolution of restriction sites of ribosomal DNA in natural populations of the field mouse,Apodemus speciosus

An analysis by restriction endonuclease digestion of ribosomal DNA (rDNA) was carried out in natural populations of Apodemus speciosus, a field mouse that is endemic to Japan. Two restriction sites, the EcoRI (E3) and DraI (D4) sites, in the nontranscribed spacer region downstream from the gene for 28S RNA showed polymorphism within and between individuals in the populations from the Japanese main islands. By contrast, populations from the small adjoining islands which are thought to have separated from the main islands 1–2 × 10⁴ years ago showed relatively low levels of polymorphism within and between individuals, i.e., one of the polymorphic bands in the case of each enzyme was predominant in these populations, irrespective of the variants. These results indicate that the rate of fixation of site variations depends on population size and that the direction of fixation is random. Furthermore, each polymorphic restriction site seems to be fixed independently.Correspondence to: H. Suzuki     

Ribosomal gene variation in soybean (Glycine) and its relatives

Summary The genes encoding the 18S25S ribosomal RNA gene repeat in soybean (Glycine max) and its relatives in the genus Glycine are surveyed for variation in repeat length and restriction enzyme site locations. Within the wild species of subgenus Glycine, considerable differences in repeat size occur, with a maximum observed in G. falcata. Repeat length and site polymorphisms occur in several species, but within individual plants only single repeat types are observed. The rDNA of the cultivated soybean and its wild progenitor, G. soja are identical at the level of this study, and no variation is found in over 40 accessions of the two species. Data from rDNA mapping studies are congruent with those of previous biosystematic studies, and in some instances give evidence of divergences not seen with other approaches.     

Molecular phylogeny in Indian Tinospora species by DNA based molecular markers

The phylogenetic relationships among the three species of Tinospora found in India are poorly understood. Morphology does not fully help to resolve the phylogeny and therefore a fast approach using molecular analysis was explored. Two molecular approaches viz Random Amplified Polymorphic DNA (RAPD) assay and restriction digestion of ITS1-5.8S-ITS2 rDNA (PCR-RFLP) were used to evaluate the genetic similarities between 40 different accessions belonging to three species. Of the 38 random primers used only six generated the polymorphism, while as three out of 11 restriction enzymes used gave polymorphic restriction patterns. The average proportion of polymorphic markers across primers was 95%, however restriction endonucleases showed 92% polymorphism. RAPD alone was found suitable for the species diversions. In contrast PCR- RFLP showed bias in detecting exact species variation. The correlation between the two markers was performed by Jaccard's coefficient of similarity. A significant (r= 0.574) but not very high correlation was obtained. Further to authenticate the results obtained by two markers, sequence analysis of ITS region of ribosomal DNA (ITS1 and ITS2, including 5.8S rDNA) was performed. Three independent clones of each species T. cordifolia, T. malabarica and T. crispa were sequenced. Phylogenetic relationship inferred from ITS sequences is in agreement with RAPD data.     

RAPD Profiling in Detecting Genetic Variation in Endemic Coelonema (Brassicaceae) of Qinghai-Tibet Plateau of China

Random amplified polymorphic DNA (RAPD) markers were used to measure genetic diversity of Coelonema draboides (Brassicaceae), a genus endemic to the Qilian Mountains of the Qinghai-Tibet Plateau. We sampled 90 individuals in 30 populations of Coelonema draboides from Datong and Huzhu counties of Qinghai Province in P.R. China. A total of 186 amplified bands were scored from the 14 RAPD primers, with a mean of 13.3 amplified bands per primer, and 87% (161 bands) polymorphic bands (PPB) was found. Analysis of molecular variance (AMOVA) shows that a large proportion of genetic variation (84.2%) resides among individuals within populations, while only 15.8% resides among populations. The species shows higher genetic diversity between individuals than other endemic and endangered plants. The RAPDs provide a useful tool for assessing genetic diversity of rare, endemic species and for resolving relationships among populations. The results show that the genetic diversity of this species is high, possibly allowing it to adapt more easily to environmental variations. The main factor responsible for the high level of differentiation within populations and the low level of diversity among populations is probably the outcrossing and long-lived nature of this species. Some long-distance dispersal, even among far separated populations, is also a crucial determinant for the pattern of genetic variation in the species. This distributive pattern of genetic variation of C. draboides populations provides important baseline data for conservation and collection strategies for the species. It is suggested that only populations in different habitats should be studied and protected, not all populations, so as to retain as much genetic diversity as possible.     

Chloroplast DNA Diversity among Trees, Populations and Species in the California Closed-Cone Pines (Pinus Radiata, Pinus Muricata and Pinus Attenuata)

The amount, distribution and mutational nature of chloroplast DNA polymorphisms were studied via analysis of restriction fragment length polymorphisms in three closely related species of conifers, the California closed-cone pines-knobcone pine: Pinus attenuata Lemm.; bishop pine: Pinus muricata D. Don; and Monterey pine: Pinus radiata D. Don. Genomic DNA from 384 trees representing 19 populations were digested with 9-20 restriction enzymes and probed with cloned cpDNA fragments from Douglas-fir [Pseudotsuga menziesii (Mirb.) Franco] that comprise 82% of the chloroplast genome. Up to 313 restriction sites were surveyed, and 25 of these were observed to be polymorphic among or within species. Differences among species accounted for the majority of genetic (haplotypic) diversity observed [G(st) = 84(+/-13)%]; nucleotide diversity among species was estimated to be 0.3(+/-0.1)%. Knobcone pine and Monterey pine displayed almost no genetic variation within or among populations. Bishop pine also showed little variability within populations, but did display strong population differences [G(st) = 87(+/-8)%] that were a result of three distinct geographic groups. Mean nucleotide diversity within populations was 0.003(+/-0.002)%; intrapopulation polymorphisms were found in only five populations. This pattern of genetic variation contrasts strongly with findings from study of nuclear genes (allozymes) in the group, where most genetic diversity resides within populations rather than among populations or species. Regions of the genome subject to frequent length mutations were identified; estimates of subdivision based on length variant frequencies in one region differed strikingly from those based on site mutations or allozymes. Two trees were identified with a major chloroplast DNA inversion that closely resembled one documented between Pinus and Pseudotsuga.     

Rapid genetic identification and mapping of enzymatically amplified ribosomal DNA from several Cryptococcus species.

Detailed restriction analyses of many samples often require substantial amounts of time and effort for DNA extraction, restriction digests, Southern blotting, and hybridization. We describe a novel approach that uses the polymerase chain reaction (PCR) for rapid simplified restriction typing and mapping of DNA from many different isolates. DNA fragments up to 2 kilobase pairs in length were efficiently amplified from crude DNA samples of several pathogenic Cryptococcus species, including C. neoformans, C. albidus, C. laurentii, and C. uniguttulatus. Digestion and electrophoresis of the PCR products by using frequent-cutting restriction enzymes produced complex restriction phenotypes (fingerprints) that were often unique for each strain or species. We used the PCR to amplify and analyze restriction pattern variation within three major portions of the ribosomal DNA (rDNA) repeats from these fungi. Detailed mapping of many restriction sites within the rDNA locus was determined by fingerprint analysis of progressively larger PCR fragments sharing a common primer site at one end. As judged by PCR fingerprints, the rDNA of 19 C. neoformans isolates showed no variation for four restriction enzymes that we surveyed. Other Cryptococcus spp. showed varying levels of restriction pattern variation within their rDNAs and were shown to be genetically distinct from C. neoformans. The PCR primers used in this study have also been successfully applied for amplification of rDNAs from other pathogenic and nonpathogenic fungi, including Candida spp., and ought to have wide applicability for clinical detection and other studies.     

EVOLUTION OF RIBOSOMAL DNA: FIFTY MILLION YEARS OF RECORDED HISTORY IN THE FROG GENUS RANA

Evolution of nuclear ribosomal DNA (rDNA) arrays of frogs of the genus Rana was examined among 32 species that last shared a common ancestor approximately 50 million years ago. Extensive variation in restriction sites exists within the transcribed and nontranscribed rDNA spacer regions among the species, whereas rDNA coding regions exhibit comparatively little interspecific variation in restriction sites. The most parsimonious phylogenetic hypothesis for the evolution of the group was constructed based on variation in restriction sites and internal spacer lengths among the 32 species of Rana and one species of Pyxicephalus (examined for outgroup comparison). This analysis suggests that R. sylvatica of North America is more closely related to the R. temporaria group of Eurasia than to other North American Rana. The hypothesized phylogeny also supports the monophyly of the R. boylii group, the R. catesbeiana group, the R. palmipes group, the R. tarahumarae group, and the R. pipiens complex. Furthermore, the restriction site data provide information about the evolution within and among these species groups. This demonstrates that restriction site mapping of rDNA arrays provides a useful molecular technique for the examination of historical evolutionary questions across considerable periods of time.     

Nontranscribed spacers in Drosophila ribosomal DNA

Ribosomal DNA nontranscribed spacers in Drosophila virilis DNA have been examined in some detail by restriction site analysis of cloned segments of rDNA, nucleic acid hybridizations involving unfractionated rDNA, and base composition estimates. The overall G+C content of the spacer is 27–28%; this compares with 39% for rDNA as a whole, 40% for main band DNA, and 26% for the D. virilis satellites. Much of the spacer is comprised of 0.25 kb repeats revealed by digestion with Msp I, Fnu DII or Rsd I, which terminate very near the beginning of the template for the ribosomal RNA precursor. The spacers are heterogeneous in length among rDNA repeats, and this is largely accounted for by variation among rDNA units in the number of 0.25 kb elements per spacer. Despite its high A+T content and the repetitive nature of much of the spacer, and the proximity of rDNA and heterochromatin in Drosophila, pyrimidine tract analysis gave no indication of relatedness between the spacer and satellite DNA sequences. Species of Drosophila closely related to D. virilis have rDNA spacers that are homologous with those in D. virilis to the extent that hybridization of a cloned spacer segment of D. virilis rDNA to various DNA is comparable with hybridization to homologous DNA, and distributions of restriction enzyme cleavage sites are very similar (but not identical) among spacers of the various species. There is spacer length heterogeneity in the rDNA of all species, and each species has a unique major rDNA spacer length. Judging from Southern blot hybridization, D. hydei rDNA spacers have 20–30% sequence homology with D. virilis rDNA spacers, and a repetitive component is similarly sensitive to Msp I and Fnu DII digestion, D. melanogaster rDNA spacers have little or no homology with counterparts in D. virilis rDNA, despite a similar content of 0.25 kb repetitive elements. In contrast, sequences in rDNA that encode 18S and 28S ribosomal RNA have been highly conserved during the divergence of Drosophila species; this is inferred from interspecific hybridizations involving ribosomal RNA and a comparison of distributions of restriction enzyme cleavage sites in rDNA.Dedicated to Professor Wolfgang Beermann on the occasion of his sixtieth birthday