Isozymes of Eleusine (Gramineae) and the origin of finger millet

The predominantly African grass genus Eleusine comprises nine species, including diploids and tetraploids based on n = 8, 9, and 10. Among the polyploids are the important crop finger millet, Eleusine coracana subsp. coracana, and its putative wild ancestor, E. coracana subsp. africana. Eleusine coracana is believed to be an allotetraploid derived by hybridization between E. indica and an unknown diploid. To evaluate this hypothesis, 16 isozyme loci coding nine enzymes were compared among seven of the nine Eleusine species (E. intermedia and E. semisterilis were unavailable). Genetic variability differed substantially among diploid species, ranging from P = 0.563, A = 1.6, H = 0.208 in E. indica to P = 0.188, A = 1.2, H = 0.042 in E. jaegeri. The diploids tended to be genetically distinct, with values of Rogers' Similarity ranging from S = 0.294 (E. jaegeri/floccifolia) to S = 0.794 (E. indica/tristachya). Both subspecies of the tetraploid E. coracana exhibited fixed heterozygosity at several loci, verifying their hypothesized allotetraploid status. Both tetraploids also possessed E. indica marker alleles at all loci, corroborating ancestry by this taxon. Genotypes of the non-indica ancestor, inferred separately for each tetraploid, differed substantially from all candidate diploids and also from each other. These data indicate that 1) none of the candidate diploids investigated is likely to have been the non-indica ancestor of E. coracana, and 2) the non-indica ancestor of the wild tetraploid may differ from that of the crop. The latter conclusion is inconsistent with the complete chromosomal homology exhibited between the two tetraploid subspecies, indicating the need for additional evidence bearing on their relationships.     

Quantitative nuclear DNA changes inEleusine (Gramineae)

2C nuclear DNA amounts were determined in 30 collections belonging to 10 species ofEleusine. About a 2.5-fold variation in genome size is evident in the genus. The 2C DNA amount in the diploid species ranged from 2.50 pg inE. verticillata to 3.35 pg inE. intermedia. In contrast, the tetraploid species showed a range from 4.95 pg inE. africana to 6.13 pg inE. floccifolia. At intraspecific level 10 collections ofE. coracana, 6 ofE. indica, 4 ofE. africana, 2 ofE. tristachya, and 2 ofE. kigeziensis did not show any significant variation. However, 2 collections ofE. floccifolia, connected with polyploidy, displayed about 90% variation. Polyploid species showed approximately double the genome size of that of their corresponding diploids. An evolutionary increase in DNA amount is evident inE. coracana during the course of its origin and domestication fromE. africana.     

基因组原位杂交鉴定牛筋草AA基因组在穇子染色体上的分布及探针长度优化方法

采用基因组原位杂交(Genomic in situ hybridization,GISH)方法研究了牛筋草(Eleusine indica)AA基因组在穇子(E.coracana)染色体上的分布,并探讨了AA、BB基因组的同源关系。用超声波破碎法进行预剪切,以缺口平移法标记的牛筋草总DNA为探针,BB基因组的E.floccifolia(Forssk.)Spreng.总DNA为封阻,与AABB基因组穇子的中期染色体进行杂交。结果表明,牛筋草AA基因组分布在穇子的18条染色体上。不加封阻或加过量封阻均不能鉴别AA基因组,说明AA和BB基因组间的分化程度不大,双方共享的重复序列较多。牛筋草与E.floccifolia总DNA分别用超声波破碎2 min和3 min后,可得到峰值为300-750 bp的DNA片段,这说明不同物种的超声波破碎时间需要调整,以获得合适长度的探针。     

The ‘A’ genome donor of Eleusine coracana (L.) Gaertn. (Gramineae)

Summary In an attempt to discover A and B genome donor(s) to finger millet, Eleusine coracana, or its progenitor species, E. africana (both allotetraploid 2n=4x=36), five diploid species, E. Indica, E. Floccifolia, E. multiflora, E. tristachya and E. intermedia, were crossed to finger millet and its progenitor taxon. Crosses were successful only with E. coracana. Three combinations of triploid hybrids E. coracana x E. indica, E. coracana x E. floccifolia, and E. coracana x E. multiflora were obtained and analysed. Meiotic behaviour was perfectly normal in parental species. The regular number of 18 bivalents in E. coracana, 9 bivalents in E. indica, E. intermedia, E. tristachya and E. floccifolia and 8 bivalents in E. multiflora were invariably noticed. In E. coracana x E. indica hybrids a mean chromosome pairing of 8.84_I+8.80_II+0.03_III+0.10_IV per cell was found. About 86.5% of the cells showed the typical 9_I+9_II configuration, suggesting that E. indica (AA) is one of the diploid genome donors to cultivated species E. coracana. A mean chromosome pairing of 11.08_I+7.63_II+0.16_III+0.04_IV per cell was found in E. coracana x E. floccifolia hybrids. Two to ten bivalents and varying numbers of univalents were seen in 55% of the cells. About 45% of the cells showed the 9_I+9_II configuration. Various evidence suggests that perennial E. floccifolia is a primitive member of the A genome group of Eleusine species, and it may not be a genome donor to E. coracana. In E. coracana x E. multiflora hybrids (2n=26) mean chromosome pairing of 21.45_I+1.97_II+0.13_III+0.04_IV per cell was found. About 91% of the cells were observed to have 20–26 univalents. Only a small percentage of the cells contained bivalents or multivalents. This pairing behaviour indicates that E. multiflora lacks genomic homology with the A or B genome of E. coracana. Genomically E. multiflora is a distinct species and a genomic symbol of C is assigned to it. Identification of the B genome donor species to cultivated millet. E. coracana remains elusive.     

Karyotype Analysis of Gossypium arboreum × G. bickii by Genome in situ Hybridization

By using genome in situ hybridization (GISH) on root somatic chromosomes of allotetraploid derived from the cross Gossypium arboreum × G. bickii with genomic DNA (gDNA) of G. bickii as a probe, two sets of chromosomes, consisting of 26 chromosomes each, were easily distinguished from each other by their distinctive hybridization signals. GISH analysis directly proved that the hybrid GarboreumxG. bickii is an allotetraploid amphiploid. The karyotype formula of the species was 2n = 4x = 52 = 46m (4sat) + 6sm (4sat). We identified four pairs of satellites with two pairs in each sub-genome. FISH analysis using 45S rDNA as a probe showed that the cross G. arboreumxG. bickii contained 14 NORs. At least five pairs of chromosomes in the G sub-genome showed double hybridization (red and blue) in their long arms, which indicates that chromatin introgression from the A sub-genome had occurred.     

Genomic relationships between the cultivated peanut (Arachis hypogaea, Leguminosae) and its close relatives revealed by double GISH

Arachis hypogaea is a natural, well-established allotetraploid (AABB) with 2n = 40. However, researchers disagree on the diploid genome donor species and on whether peanut originated by a single or multiple events of polyploidization. Here we provide evidence on the genetic origin of peanut and on the involved wild relatives using double GISH (genomic in situ hybridization). Seven wild diploid species (2n = 20), harboring either the A or B genome, were tested. Of all genomic DNA probe combinations assayed, A. duranensis (A genome) and A. ipaensis (B genome) appeared to be the best candidates for the genome donors because they yielded the most intense and uniform hybridization pattern when tested against the corresponding chromosome subsets of A. hypogaea. A similar GISH pattern was observed for all varieties of the cultigen and also for A. monticola. These results suggest that all presently known subspecies and varieties of A. hypogaea have arisen from a unique allotetraploid plant population, or alternatively, from different allotetraploid populations that originated from the same two diploid species. Furthermore, the bulk of the data demonstrated a close genomic relationship between both tetraploids and strongly supports the hypothesis that A. monticola is the immediate wild antecessor of A. hypogaea.     

GISH-based comparative genomic analysis in Urochloa P. Beauv.

The genus Urochloa P. Beauv. [syn. Brachiaria (Trin.) Griseb.] comprises species of great economic relevance as forages. The genomic constitution for the allotetraploid species Urochloa brizantha (cv. Marandu) and Urochloa decumbens (cv. Basilisk) and the diploid Urochloa ruziziensis was previously proposed as BBB¹B¹, B¹B¹B²B² and B²B², respectively. Evidence indicates U. ruziziensis as the ancestral donor of genome B² in U. decumbens allotetraploidy, but the origin of the genomes B and B¹ is still unknown. There are diploid genotypes of U. brizantha and U. decumbens that may be potential ancestors of the tetraploids. The aim of this study was to determine the genomic constitution and relationships between genotypes of U. brizantha (2x and 4x), U. decumbens (2x and 4x) and U. ruziziensis (2x) via genomic in situ hybridization (GISH). Additionally, chromosome number and genome size were verified for the diploid genotypes. The diploids U. brizantha and U. decumbens presented 2n?=?2x?=?18 chromosomes and DNA content of 1.79 and 1.44 pg, respectively. The GISH analysis revealed high homology between the diploids U. brizantha and U. decumbens, which suggests relatively short divergence time. The GISH using genomic probes from the diploid accessions on the tetraploid accessions’ chromosomes presented similar patterns, highlighting the genome B¹ present in both of the tetraploids. Based on GISH results, the genomic constitution was proposed for the diploid genotypes of U. brizantha (B¹B¹) and U. decumbens (B¹′B¹′) and both were pointed as donors of genome B¹ (or B¹′), present in the allotetraploid genotypes.

     

Genome organization and polyploid evolution in the genus Eleusine (Poaceae)

 Eleusine (Poaceae) includes six diploid and three polyploid species and has three basic chromosome numbers, x=8, 9 and 10. The species are annual as well as perennial and all are wild except E. coracana, which is cultivated for grain and fodder in Africa and the Indian subcontinent. Eleusine coracana and E. africana have the same genome and chromosome number (2n=36). Eleusine indica and E. floccifolia are identified as two genome donors to these polyploid species. Eleusine kigeziensis is the third polyploid species of the genus with 2n=38. Its genome may have come from E. jaegeri and from one of the species with x=9, most probably from E. indica. Eleusine indica, E. tristachya, E. floccifolia and E. intermedia with x=9 and two polyploid species, E. coracana and E. africana, are closely related and there is free genetic flow between them. Eleusine multiflora with x=8 is significantly different in morphology and at genomic level from other species. Eleusine jaegeri with x=10 is morphologically similar to E. indica, however, more information is needed to ascertain its position in the genus. Eleusine coracana, which is commonly called finger millet, is a potential and nutritious crop for the increasing population of the world, particularly in arid and semi-arid regions. It can also serve as a gene pool for various important characters and disease resistant genes. Received February 11, 2002; accepted May 27, 2002 Published online: October 14, 2002 Addresses of the authors: Madho Singh Bisht and Yasuhiko Mukai (e-mail: ymukai@cc.osaka-kyoiku.ac.jp), Laboratory of Plant Molecular Genetics, Division of Natural Science, Osaka Kyoiku University, 4-698-1 Asahigaoka, Kashiwara, Osaka 582-8582, Japan.     

The genetic map of finger millet, Eleusine coracana

Restriction fragment length polymorphism (RFLP), amplified fragment length polymorphism (AFLP), expressed-sequenced tag (EST), and simple sequence repeat (SSR) markers were used to generate a genetic map of the tetraploid finger millet (Eleusine coracana subsp. coracana) genome (2n = 4x = 36). Because levels of variation in finger millet are low, the map was generated in an inter-subspecific F₂ population from a cross between E. coracana subsp. coracana cv. Okhale-1 and its wild progenitor E. coracana subsp. africana acc. MD-20. Duplicated loci were used to identify homoeologous groups. Assignment of linkage groups to the A and B genome was done by comparing the hybridization patterns of probes in Okhale-1, MD-20, and Eleusine indica acc. MD-36. E. indica is the A genome donor to E. coracana. The maps span 721 cM on the A genome and 787 cM on the B genome and cover all 18 finger millet chromosomes, at least partially. To facilitate the use of marker-assisted selection in finger millet, a first set of 82 SSR markers was developed. The SSRs were identified in small-insert genomic libraries generated using methylation-sensitive restriction enzymes. Thirty-one of the SSRs were mapped. Application of the maps and markers in hybridization-based breeding programs will expedite the improvement of finger millet. Electronic supplementary material Supplementary material is available in the online version of this article at and is accessible for authorized users.     

Physical Mapping of rRNA Gene Loci and Inter-specific Relationships in Wild <Emphasis Type="Italic">Lilium</Emphasis> Distributed in Korea

Molecular cytogenetic analyses using fluorescence in situ hybridization (FISH) and genomic in situ hybridization (GISH) were carried out to elucidate inter-specific relationships among wild Lilium species distributed in Korea. FISH revealed four to eight 45S rRNA gene loci, which are located on chromosomes 1–7, 10, and 11 among the different species. In contrast, the 5S rRNA gene locus was conserved on the long arm of chromosome 3, occasionally with two adjacent sites on the same chromosome arm in a few species. The 5S rDNA site was located adjacent to the 45S rDNA site in only three species, Lilium distichum, Lilium hansonii, and Lilium tsingtauense. GISH analysis using genomic DNA probes detected strong hybridization of genomes between diploid and triploid Lilium lancifolium species, demonstrating that triploid plants were derived from diploid L. lancifolium and not from Lilium maximowiczii. Phylogenetic analysis of the ITS and NTS sequences supported the cytogenetic data as well as Comber’s classification of the genus Lilium.     

Flavonoid patterns and systematics in Eleusine

A survey of leaf flavonoids was conducted on Eleusine coracana ssp. coracana and ssp. africana, E. indica, E. multiflora, E. tristachya, E. floccifolia, and E. compressa. Twenty phenolic compounds were detected. Those identified were: orientin, isoorientin, vitexin, isovitexin, saponarin, violanthin, lucenin-1, and tricin. The study revealed a general generic flavonoid pattern except for E. compressa, which occupies an isolated position in Eleusine. Flavonoids of the perennial E. floccifolia and the annuals E. multiflora and E. tristachya are markedly different from those of cultivated E. coracana, suggesting that these species are only distantly related to the crop. The morphologically well defined E. coracana—africana—indica group also forms a unit in respect of flavonoids. Subspecies africana exhibits a higher flavonoid similarity to ssp. coracana (finger millet) than does E. indica. The weedy race of ssp. africana usually combines flavonoids of both the wild and domesticated subspecies. The flavonoid pattern of the dedza race of ssp.africana is identical to that of finger millet, suggesting either a direct origin of the crop from this race, or extensive introgression from the crop into ssp. africana. A lack of qualitative differences in flavonoids between cultivated races of finger millet is indicative of the genetic stability of these compounds. The flavonoid data confirms the domestication of finger millet from ssp. africana.     

In situ hybridization identifies the diploid progenitor species of Coffea arabica (Rubiaceae)

 The most important commercial coffee species, Coffea arabica, which is cultivated in about 70% of the plantations world-wide, is the only tetraploid (2n=4x=44) species known in the genus. Genomic in situ hybridization (GISH) and fluorescent in situ hybridization (FISH) were used to study the genome organization and evolution of this species. Labelled total genomic DNA from diploid species (C. eugenioides, C. congensis, C. canephora, C. liberica) closely related to C. arabica was separately used as a probe in combination with or without blocking DNA to the chromosome spreads of C. arabica. GISH discriminated between chromosomes of C. arabica only in the presence of an excess of unlabelled block DNA from the species not used as a probe. Among the range of different species combinations used, DNA from C. eugenioides strongly and preferentially labelled 22 chromosomes of the tetraploid C. arabica, while the remaining 22 chromosomes were labelled with C. congensis DNA. The similarity of observations between C. arabica and the two diploid species using two ribosomal genes with FISH with respect to metaphase chromosomes provided additional support to the GISH results. These results confirm the allopolyploid nature of C. arabica and show that C. congensis and C. eugenioides are the diploid progenitors of C. arabica. Received: 2 February 1998 / Accepted: 12 May 1998     

基因组原位杂交技术及其在园艺植物基因组研究中的应用

基因组原位杂交(GISH)技术可以鉴定植物多倍体物种起源、杂种亲本染色体来源和组成,分析栽培种与其近缘野生种的亲缘关系,研究减数分裂染色体行为等。基因组原位杂交包括多色基因组原位杂交、比较基因组原位杂交和自身基因组原位杂交等。基因组原位杂交技术的关键步骤是染色体制片、探针制备及长度优化、探针与封阻的浓度比例和杂交后洗脱强度。该文对近年来国内外有关基因组原位杂交技术的发展及其在园艺植物基因组研究中的应用现状进行了综述,并指出随着多种园艺植物全基因组的测定,未来应从基因组信息中寻找更多的染色体特异性标记,结合荧光显带及荧光原位杂交技术,为深入研究园艺植物的起源以及遗传关系鉴定等提供技术支持。     

亚比棉基因组原位杂交及核型分析

亚比棉异源四倍体是山西农业大学棉花育种组于上个世纪80年代用A染色体组亚洲棉(Gossypium.arboreum)(迁西小黑籽)与G染色体组野生棉比克氏棉(G.bickii)杂交成异源二倍体后,又经过加倍而获得的.亚比棉异源四倍体不仅育性得到恢复、结铃正常,而且成功地将比克氏棉的优异性状--种子腺体延缓形成转育到亚比棉中.这为实现棉花综合利用和提高抗虫性创育了新的育种材料.在随后的多年中,山西农业大学棉花育种组对亚比棉异源四倍体进行了广泛的细胞形态学研究,对其核型做了分析.然而,仅依据形态学和普通的核型图像,还不能确定该异源四倍体棉种中比克氏棉G染色体(亚)组在核型中的表现.该文以比克氏棉gDNA为探针,亚比棉异源四倍体根尖体细胞染色体为靶细胞染色体,封阻材料为亚洲棉(迁西小黑籽),进行亚比棉基因组原位杂交(Genome in situ hybridization,GISH)及核型分析.从获得的图像中可以清晰地发现有52条染色体,其中有/无杂交信号的各一半,这直观地证实了人工复合亚比棉杂交种确为异源四倍体,而且是双二倍体.A亚组与G亚组染色体长度存在交替排列.亚比棉异源四倍体基于GISH图像的核型公式为2n=4x=52=46m(4sat)+6sm(4sat).A亚组和G亚组染色体上各有2对随体.G亚组染色体中至少有5对双重显色明显的染色体,意味着可能有A亚组染色体的交换,而A亚组染色体中只观察到或多或少的探针红色荧光信号,由于分辨率不够而难于定量分析.进一步以45SrDNA为探针,以鲑鱼精DNA作为封阻DNA,对亚比棉异源四倍体进行45SrDNA-FISH,实验表明,亚比棉异源四倍体有14个NOR(核仁组织区)信号,说明亚比棉异源四倍体有14个随体,即7对随体.比克氏棉对亚洲棉的GISH结果显示,在有亚洲棉DNA封阻的条件下,亚洲棉靶细胞染色体无任何杂交信号,说明比克氏棉与亚洲棉染色体之间不存在较大的同源或相似序列.     

Mapping of rDNA on the chromosomes of Eleusine species by fluorescence in situ hybridization

Mapping of rDNA sites on the chromosomes of four diploid and two tetraploid species of Eleusine has provided valuable information on genome relationship between the species. Presence of 18S-5.8S-26S rDNA on the largest pair of the chromosomes, location of 5S rDNA at four sites on two pairs of chromosomes and presence of 18S-5.8S-26S and 5S rDNA at same location on one pair of chromosomes have clearly differentiated E. multiflora from rest of the species of Eleusine. The two tetraploid species, E. coracana and E. africana have the same number of 18S-5.8S-26S and 5S rDNA sites and located at similar position on the chromosomes. Diploid species, E. indica, E. floccifolia and E. tristachya have the same 18S-5.8S-26S sites and location on the chromosomes which also resembled with the two pairs of 18S-5.8S-26S rDNA locations in tetraploid species, E. coracana and E. africana. The 5S rDNA sites on chromosomes of E. indica and E. floccifolia were also comparable to the 5S rDNA sites of E. africana and E. coracana. The similarity of the rDNA sites and their location on chromosomes in the three diploid and two polyploid species also supports the view that genome donors to tetraploid species may be from these diploid species.     

DUPLICATE GENE EXPRESSION FOR ISOCITRATE DEHYDROGENASE AND 6-PHOSPHOGLUCONATE DEHYDROGENASE IN DIPLOID SPECIES OF ELEUSINE (GRAMINEAE)

In the course of a survey of isozyme variation in the grass genus Eleusine, complex band patterns were observed for the enzymes isocitrate dehydrogenase (IDH) and 6-phosphogluconate dehydrogenase (6PGD). These patterns were interpreted as the result of duplicate expression for one of the two genes that ordinarily codes subcellularly compartmentalized forms of each of these enzymes. The interpretation of IDH phenotypes was facilitated by intraspecific allelic variation at one of the putatively duplicated genes (Idh-2), and was verified by examining phenotype ratios in progeny arrays from selfed heterozygotes of E. indica. The lack of analogous intraspecific variation for 6PGD precluded genetic tests, but the duplicate nature of expression was supported by interspecific patterns of variation. Four out of the five diploid species of Eleusine studied (E. indica, E. jaegeri, E. multiflora, E. tristachya) exhibited both duplications; E. floccifolia appeared to lack the IDH duplication, but possessed the 6PGD duplication. Both enzymes showed evidence of hyperduplication in the tetraploid species E. coracana.     

Molecular characterisation and origin of the Coffea arabica L. genome

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

Genome discrimination by in situ hybridization in Icelandic species of Elymus and Elytrigia (Poaceae: Triticeae).

The genome constitution of Icelandic Elymus caninus, E. alaskanus, and Elytrigia repens was examined by fluorescence in situ hybridization using genomic DNA and selected cloned sequences as probes. Genomic in situ hybridization (GISH) of Hordeum brachyantherum ssp. californicum (diploid, H genome) probe confirmed the presence of an H genome in the two tetraploid Elymus species and identified its presence in the hexaploid Elytrigia repens. The H chromosomes were painted uniformly except for some chromosomes of Elytrigia repens which showed extended unlabelled pericentromeric and subterminal regions. A mixture of genomic DNA from H. marinum ssp. marinum (diploid, Xa genome) and H. murinum ssp. leporinum (tetraploid, Xu genome) did not hybridize to chromosomes of the Elymus species or Elytrigia repens, confirming that these genomes were different from the H genome. The St genomic probe from Pseudoroegneria spicata (diploid) did not discriminate between the genomes of the Elymus species, whereas it produced dispersed and spotty hybridization signals most likely on the two St genomes of Elytrigia repens. Chromosomes of the two genera Elymus and Elytrigia showed different patterns of hybridization with clones pTa71 and pAes41, while clones pTa1 and pSc119.2 hybridized only to Elytrigia chromosomes. Based on FISH with these genomic and cloned probes, the two Elymus species are genomically similar, but they are evidently different from Elytrigia repens. Therefore the genomes of Icelandic Elymus caninus and E. alaskanus remain as StH, whereas the genomes of Elytrigia repens are proposed as XXH.     

Genomic in situ hybridization (GISH) discriminates between the A and the B genomes in diploid and tetraploid Setaria species.

Genomic in situ hybridization (GISH) was used to investigate genomic relationships between different Setaria species of the foxtail millet gene pool (S. italica) and one interspecific F1 hybrid. The GISH patterns obtained on the two diploid species S. viridis (genome A) and S. adhaerans (genome B), and on their F1 hybrid showed clear differentiation between these two genomes except at the nucleolar organizing regions. Similar GISH patterns allowed differentiation of S. italica from S. adhaerans. However, GISH patterns did not distinguish between the genomes of S. italica and its putative wild ancestor S. viridis. GISH was also applied to polyploid Setaria species and enabled confirmation of the assumed allotetraploid nature of S. faberii and demonstration that both S. verticillata and S. verticillata var. ambigua were also allotetraploids. All these tetraploid species contained two sets of 18 chromosomes each, one from genome A and the other from genome B. Only one polyploid species, S. pumila, was shown to bear an unknown genomic composition that is not closely related either to genome A or to genome B.