Determination of copy number and linkage relationships among five actin gene subfamilies in Petunia hybrida

The actin gene superfamily of Petunia hybrida cv. Mitchell contains greater than 100 gene members which have been divided into several highly divergent subfamilies [1]. Five subfamily-specific probes have been used to compare the actin genes among the Mitchell, Violet 23 (V23) and Red 51 (R51) cultivars of P. hybrida. The sum total of actin genes in these five subfamilies was estimated to be between 10 and 34 members in both V23 and R51. Restriction fragment length polymorphisms (RFLPs) between V23 and R51 were examined with these five probes and eleven different restriction endonucleases. Among the 55 comparisons, 87% exhibited RFLPs. These data indicate extreme divergence between V23 and R51 in DNA sequence and/or the presence of small insertions and deletions surrounding these actin gene subfamilies. This divergence suggests that V23 and R51, which have contrasting phenotypic marker loci on every chromosome, may be useful for the development of a complete RFLP linkage map of the Petunia genome. The segregation of Hind III RFLPs among the progeny of two backcrosses demonstrated that representatives of the five subfamilies of Petunia actin genes exist at four distinct genetic locations and suggested that two of these loci are tightly linked. Apparently, amplification of the numerous members of the Petunia actin gene superfamily occurred via gene dispersal of the original subfamily progenitors and not primarily as a result of amplification of a single chromosomal region.     

Six actin gene subfamilies map to five chromosomes of Petunia hybrida

The Mitchell variety of Petunia hybrida possesses a superfamily of actin genes which contains between 100 and 200 members that can be divided into at least six highly divergent subfamilies. The segregation of restriction fragment length polymorphisms among 96 plants from two backcrosses between the Violet 23 and Red 51 Petunia varieties and the Violet 23 x Red 51 hybrid was examined using gene-specific probes from six Petunia actin gene subfamilies. These data were compared with the genotypes of each plant at 11 marker loci which are distributed among the seven chromosomes of Petunia and which determine flower, pollen, and isozyme phenotypes. From these analyses, members of these six actin gene subfamilies were mapped to five locations on five Petunia chromosomes: the PAc9, PAc1, PAc4, and PAc2 subfamilies are on chromosomes I, II, III, and VII respectively; the PAc3 and PAc7 subfamilies are tightly linked on chromosome IV. All members of the PAc4 subfamily cosegregated as a cluster of genes. These data are discussed regarding gene amplification in plants.     

Dramatic Number Variation of R Genes in Solanaceae Species Accounted for by a Few R Gene Subfamilies

Most disease resistance genes encode nucleotide-binding-site (NBS) and leucine-rich-repeat (LRR) domains, and the NBS-LRR encoding genes are often referred to as R genes. Using newly developed approach, 478, 485, 1,194, 1,665, 2,042 and 374 R genes were identified from the genomes of tomato Heinz1706, wild tomato LA716, potato DM1-3, pepper Zunla-1 and wild pepper Chiltepin and tobacco TN90, respectively. The majority of R genes from Solanaceae were grouped into 87 subfamilies, including 16 TIR-NBS-LRR (TNL) and 71 non-TNL subfamilies. Each subfamily was annotated manually, including identification of intron/exon structure and intron phase. Interestingly, TNL subfamilies have similar intron phase patterns, while the non-TNL subfamilies have diverse intron phase due to frequent gain of introns. Prevalent presence/absence polymorphic R gene loci were found among Solanaceae species, and an integrated map with 427 R loci was constructed. The pepper genome (2,042 in Chiltepin) has at least four times of R genes as in tomato (478 in Heinz1706). The high number of R genes in pepper genome is due to the amplification of R genes in a few subfamilies, such as the Rpi-blb2 and BS2 subfamilies. The mechanism underlying the variation of R gene number among different plant genomes is discussed.     

Evolution of EF-hand calcium-modulated proteins. V. The genes encoding EF-hand proteins are not clustered in mammalian genomes

Summary The chromosomal assignments of genes belonging to the EF-hand family which have a common origin are compiled in this article. So far data are available from 27 human gene loci belonging to 6 subfamilies and 8 murine loci belonging to 4 subfamilies. Chromosomal localization has been obtained by somatic-cell hybrid analysis using the Southern blot technique or PCR amplification, metaphase spread in situ hybridization, or isolation of the particular genes from chromosome-specific libraries. Except for genes of the S-100 alpha proteins which are grouped on human chromosome 1q12-25 and mouse chromosome 3, no linkage has been found for genes encoding EF-hand proteins, indicating absence of selective pressure for maintaining chromosomal clustering. Six of these genes map to known syntenic groups conserved in the human and mouse genomes. This suggests that chromosomal translocations occurred before divergence of these species. The possible significance of chromosomal positioning with respect to nearby located known genes and genetic disease loci is discussed.     

Analysis of the cytosolic hsp70 gene family inZea mays

In this study we have analysed the multigene family coding for the cytoplasmic heat shock 70 kDa proteins (hsp70) inZea mays. Fully degenerate primers were used in a polymerase chain reaction (PCR) to amplify selected regions of the hsp70 genes. Sequence and Southern blot analysis reveals that at least three highly conserved genes exist in maize. In addition, amplification reveals the presence of a conserved intron in all genes examined. Expression analysis shows that the hsp70 genes studied represent members of the inducible and constitutive families. The results obtained may indicate that there are subfamilies of cytoplasmic hsp70 genes expressed in higher plants.     

Genome-wide analysis of the Emigrant family of MITEs of Arabidopsis thaliana

Miniature inverted-repeat transposable elements (MITEs) are structurally similar to defective class II elements, but their high copy number and the size and sequence conservation of most MITE families suggest that they can be amplified by a replicative mechanism. Here we present a genome-wide analysis of the Emigrant family of MITEs from Arabidopsis thaliana. In order to be able to detect divergent ancient copies, and low copy number subfamilies with a different internal sequence we have developed a computer program to look for Emigrant elements based solely on the terminal inverted-repeat sequence. We have detected 151 Emigrant elements of different subfamilies. Our results show that different bursts of amplification, probably of few active, or master, elements, have occurred at different times during Arabidopsis evolution. The analysis of the insertion sites of the Emigrant elements shows that recently inserted Emigrant elements tend to be located far from open reading frames, whereas more ancient Emigrant subfamilies are preferentially found associated to genes.     

Comparative analysis of NBS domain sequences of NBS-LRR disease resistance genes from sunflower, lettuce, and chicory

Plant resistance to many types of pathogens and pests can be achieved by the presence of disease resistance (R) genes. The nucleotide binding site-leucine rich repeat (NBS-LRR) class of R-genes is the most commonly isolated class of R-genes and makes up a super-family, which is often arranged in the genome as large multi-gene clusters. The NBS domain of these genes can be targeted by polymerase chain reaction (PCR) amplification using degenerate primers. Previous studies have used PCR derived NBS sequences to investigate both ancient R-gene evolution and recent evolution within specific plant families. However, comparative studies with the Asteraceae family have largely been ignored. In this study, we address recent evolution of NBS sequences within the Asteraceae and extend the comparison to the Arabidopsis thaliana genome. Using multiple sets of primers, NBS fragments were amplified from genomic DNA of three species from the family Asteraceae: Helianthus annuus (sunflower), Lactuca sativa (lettuce), and Cichorium intybus (chicory). Analysis suggests that Asteraceae species share distinct families of R-genes, composed of genes related to both coiled-coil (CC) and toll-interleukin-receptor homology (TIR) domain containing NBS-LRR R-genes. Between the most closely related species, (lettuce and chicory) a striking similarity of CC subfamily composition was identified, while sunflower showed less similarity in structure. These sequences were also compared to the A. thaliana genome. Asteraceae NBS gene subfamilies appear to be distinct from Arabidopsis gene clades. These data suggest that NBS families in the Asteraceae family are ancient, but also that gene duplication and gene loss events occur and change the composition of these gene subfamilies over time.     

A complex gene superfamily encodes actin in petunia.

We have shown by several independent criteria that actin is encoded by a very large and complex superfamily of genes in Petunia. Several cDNA and genomic probes encoding actins from diverse organisms (Dictyostelium, Drosophila, chicken and soybean) hybridize to hundreds of restriction fragments in the petunia genome. Actin-hybridizing sequences were isolated from a petunia genomic library at a rate of at least 200 per genome equivalent. Twenty randomly selected actin-hybridizing clones were characterized in more detail. DNA sequence data from four representative and highly divergent clones, PAc2, PAc3, PAc4 and PAc7, demonstrate that these actin-like sequences are related to functional actin genes. Intron positions typical of other known plant actin genes are conserved in these clones. Four of six clones analyzed (PAc1, PAc2, PAc3, PAc4) hybridize to leaf mRNA of the same size (1.7 kb) as that reported for other plant actin mRNAs and to a slightly smaller mRNA species (1.5 kb). Five distinct subfamilies of actin-related genes were characterized which varied in size from a few members to several dozen members. It is clear from our data that other actin gene subfamilies must also exist within the genome. Possible mechanisms of actin gene amplification and genome turnover are discussed.     

Structural organization and classification of cytochrome P450 genes in flax (Linum usitatissimum L.)

Flax CYPome analysis resulted in the identification of 334 putative cytochrome P450 (CYP450) genes in the cultivated flax genome. Classification of flax CYP450 genes based on the sequence similarity with Arabidopsis orthologs and CYP450 nomenclature, revealed 10 clans representing 44 families and 98 subfamilies. CYP80, CYP83, CYP92, CYP702, CYP705, CYP708, CYP728, CYP729, CYP733 and CYP736 families are absent in the flax genome. The subfamily members exhibited conserved sequences, length of exons and phasing of introns. Similarity search of the genomic resources of wild flax species Linum bienne with CYP450 coding sequences of the cultivated flax, revealed the presence of 127 CYP450 gene orthologs, indicating amplification of novel CYP450 genes in the cultivated flax. Seven families CYP73, 74, 75, 76, 77, 84 and 709, coding for enzymes associated with phenylpropanoid/fatty acid metabolism, showed extensive gene amplification in the flax. About 59% of the flax CYP450 genes were present in the EST libraries.     

Complex evolutionary history and diverse domain organization of SET proteins suggest divergent regulatory interactions

? Plants and animals possess very different developmental processes, yet share conserved epigenetic regulatory mechanisms, such as histone modifications. One of the most important forms of histone modification is methylation on lysine residues of the tails, carried out by members of the SET protein family, which are widespread in eukaryotes. ? We analyzed molecular evolution by comparative genomics and phylogenetics of the SET genes from plant and animal genomes, grouping SET genes into several subfamilies and uncovering numerous gene duplications, particularly in the Suv, Ash, Trx and E(z) subfamilies. ? Domain organizations differ between different subfamilies and between plant and animal SET proteins in some subfamilies, and support the grouping of SET genes into seven main subfamilies, suggesting that SET proteins have acquired distinctive regulatory interactions during evolution. We detected evidence for independent evolution of domain organization in different lineages, including recruitment of new domains following some duplications. ? More recent duplications in both vertebrates and land plants are probably the result of whole-genome or segmental duplications. The evolution of the SET gene family shows that gene duplications caused by segmental duplications and other mechanisms have probably contributed to the complexity of epigenetic regulation, providing insights into the evolution of the regulation of chromatin structure.     

Length polymorphism of PCR-amplified genomic fragments of the Pregnancy-Associated Glycoprotein (PAG) gene family in the pig and some other domestic and wild mammals

Porcine pregnancy-associated glycoprotein genes (pPAG) are known as a multigene family, in which five members have been cloned and sequences of their cDNAs identified. Porcine PAG1 and pPAG3 genes, belonging to the pPAG1-like subfamily, both encode enzymatically inactive precursors. In contrast, cDNAs of pPAG2, pPAG4 and pPAG6 represent the pPAG2-like gene subfamily, encoding enzymatically active precursors. The objective of this study was to investigate the polymorphism of both pPAG-like gene subfamilies in the pig in comparison to other domestic species, including cattle, sheep and goat (Artiodactyla), their wild relatives (red deer and wild pig) and horse (Perissodactyla). This is the first paper indicating the polymorphism of the pPAG gene family, examined by lengths of amplified genomic fragments (PCR). Obtained PCR products were analysed in relation to five characterised cDNAs of pPAGs (pPAG1-like and/or pPAG2-like subfamilies) and according to one recognised structural exon-intron organisation of the pPAG2 gene, among at least eight pPAG2-like genes expected in the porcine genome. The highest polymorphism frequency of both pPAG1- and pPAG2-like gene subfamilies was found in the second region, exons 5 and 6 (with intron E). The length of PCR-amplified genomic fragments was approximately: 1043, 700, 600 and 193 bp. A high polymorphism frequency was found in the 3'-terminal fragment, corresponding to exons 7-9 (with introns G and H), more frequent the pPAG2-like gene subfamily. The length of PCR-amplified genomic fragments was approximately: 733, 650 and 356 bp. In contrast, PAG polymorphism was not detected in another region, encompassing exons 2-4 (with introns B and C). The length of PCR-amplified genomic fragments was approximately 279 bp in all examined genomes. In conclusion, amplification of various regions of the PAG gene family presents a relatively inexpensive PCR method of animal pre-selection with different genotypes. Such a pre-selection of animals is helpful for further gene number inquiry of the PAG gene family in each animal, then in related generations. The obtained results provide a useful background for a genetic marker preparation (by Southern analysis of the PAG family) that will presumably enable an economical early selection of young animals for effective reproduction.     

Evolution of the master Alu gene(s)

Summary A comparison of Alu sequences that comprise more recently amplified Alu subfamilies was made. There are 18 individual diagnostic mutations associated with the different subfamilies. This analysis confirmed that the formation of each subfamily can be explained by the sequential accumulation of mutations relative to the previous subfamily. Polymerase chain reaction amplification of orthologous loci in several primate species allowed us to determine the time of insertion of Alu sequences in individual loci. These data suggest that the vast majority of Alu elements amplified at any given time comprised a single Alu subfamily. We find that, although the individual divergence relative to a consensus sequence correlate reasonably well with sequence age, the diagnostic mutations are a more accurate measure of the age of any individual Alu family member. Our data are consistent with a model in which all Alu family members have been made from a single master gene or from a series of sequential master genes. This master gene(s) accumulated diagnostic base changes, resulting in the amplification of different subfamilies from the master gene at different times in primate evolution. The changes in the master gene(s) probably occurred individually, but their appearance is clearly punctuated. Ten of them have occurred within an 15-million-year time span, 40–25 million years ago, and 8 changes have occurred within the last 5 million years. Surprisingly, no changes appeared in the 20 milion years separating these periods.     

The dog and rat olfactory receptor repertoires

Background

Dogs and rats have a highly developed capability to detect and identify odorant molecules, even at minute concentrations. Previous analyses have shown that the olfactory receptors (ORs) that specifically bind odorant molecules are encoded by the largest gene family sequenced in mammals so far.

Results

We identified five amino acid patterns characteristic of ORs in the recently sequenced boxer dog and brown Norway rat genomes. Using these patterns, we retrieved 1,094 dog genes and 1,493 rat genes from these shotgun sequences. The retrieved sequences constitute the olfactory receptor repertoires of these two animals. Subsets of 20.3% (for the dog) and 19.5% (for the rat) of these genes were annotated as pseudogenes as they had one or several mutations interrupting their open reading frames. We performed phylogenetic studies and organized these two repertoires into classes, families and subfamilies.

Conclusion

We have established a complete or almost complete list of OR genes in the dog and the rat and have compared the sequences of these genes within and between the two species. Our results provide insight into the evolutionary development of these genes and the local amplifications that have led to the specific amplification of many subfamilies. We have also compared the human and rat ORs with the human and mouse OR repertoires.     

The chalcone synthase multigene family of Petunia hybrida (V30): sequence homology,chromosomal localization and evolutionary aspects

Chalcone synthase (CHS) genes in Petunia hybrida comprise a multigene family containing at least 7 complete members in the strain Violet 30 (V30). Based on a high sequence homology in both coding and non-coding sequence, a number of CHS genes can be placed into two subfamilies. By restriction fragment length polymorphism (RFLP) analysis it was shown that both chromosomes II and V carry one of these subfamilies, in addition to the other CHS genes identified so far. Members of a subfamily were found to be closely linked genetically. Analysis of the Petunia species that contributed to the hybrid nature of P. hybrida (P. axillaris, P. parodii, P. inflata and P. violacea) shows that none of the CHS gene clusters is specific for either one of the parents and therefore did not arise as a consequence of the hybridization. The number of CHS genes within a subfamily varies considerably among these Petunia species. From this we infer that the CHS subfamilies arose from very recent gene duplications.     

The chalcone synthase multigene family of Petunia hybrida (V30): sequence homology,chromosomal localization and evolutionary aspects

Chalcone synthase (CHS) genes in Petunia hybrida comprise a multigene family containing at least 7 complete members in the strain Violet 30 (V30). Based on a high sequence homology in both coding and non-coding sequence, a number of CHS genes can be placed into two subfamilies. By restriction fragment length polymorphism (RFLP) analysis it was shown that both chromosomes II and V carry one of these subfamilies, in addition to the other CHS genes identified so far. Members of a subfamily were found to be closely linked genetically. Analysis of the Petunia species that contributed to the hybrid nature of P. hybrida (P. axillaris, P. parodii, P. inflata and P. violacea) shows that none of the CHS gene clusters is specific for either one of the parents and therefore did not arise as a consequence of the hybridization. The number of CHS genes within a subfamily varies considerably among these Petunia species. From this we infer that the CHS subfamilies arose from very recent gene duplications.     

Dynamic gene copy number variation in collinear regions of grass genomes

A salient feature of genomes of higher organisms is the birth and death of gene copies. An example is the alpha prolamin genes, which encode seed storage proteins in grasses (Poaceae) and represent a medium-size gene family. To better understand the mechanism, extent, and pace of gene amplification, we compared prolamin gene copies in the genomes of two different tribes in the Panicoideae, the Paniceae and the Andropogoneae. We identified alpha prolamin (setarin) gene copies in the diploid foxtail millet (Paniceae) genome (490 Mb) and compared them with orthologous regions in diploid sorghum (730 Mb) and ancient allotetraploid maize (2,300 Mb) (Andropogoneae). Because sequenced genomes of other subfamilies of Poaceae like rice (389 Mb) (Ehrhartoideae) and Brachypodium (272 Mb) (Pooideae) do not have alpha prolamin genes, their collinear regions can serve as "empty" reference sites. A pattern emerged, where genes were copied and inserted into other chromosomal locations followed by additional tandem duplications (clusters). We observed both recent (species-specific) insertion events and older ones that are shared by these tribes. Many older copies were deleted by unequal crossing over of flanking sequences or damaged by truncations. However, some remain intact with active and inactive alleles. These results indicate that genomes reflect only a snapshot of the gene content of a species and are far less static than conventional genetics has suggested. Nucleotide substitution rates for active alpha prolamins genes were twice as high as for low copy number beta, gamma, and delta prolamin genes, suggesting that gene amplification accelerates the pace of divergence.     

Subfamily structure and evolution of the human L1 family of repetive sequences

Summary Comparative analysis of the available 3′-portions of the human L1 (LINE-1) family of repeated sequences indicates that all the sequences can be classified in two major subfamilies. The division is based on patterns of diagnostic bases shared within L1 subfamilies of sequences but differing between them. The overall ratio of replacement to synonymous positions, occupied by the diagnostic bases in the large open reading frame of the L1 sequence, is 1.15. This indicates that both subfamilies were obtained from genes coding for functional proteins. The L1 subfamilies appear to be of different ages and may represent a “fossil record” of the same active gene at different times in the history of primates. The younger subfamily can be split further into at least two closely related branches of sequences. The above facts combined with the recent data for the Alu subfamily structure show that LINE and SINE families of interspersed repeats share discontinuous patterns in their evolution. These data are consistent with the model that both Alu and L1 families, as well as other pseudogene families, contain active genes producing discrete layers of pseudogenes throughout the history of primates. Models of evolutionary processes that could generate these discontinuities are discussed together with the possible biological role of Alu and L1 genes.