Variation in lengths of introns and exons in genes of the Arabidopsis thaliana nuclear genome

In the nuclear genes of Arabidopsis thaliana, the length of introns and exons was shown to vary depending on the number of introns. With increasing number of introns per gene, the proportion of introns composed of 80-100 nucleotides increases whereas the proportion of introns with 400-nucleotide length decreases. Similar changes in exon length in genes result in predominance of exons of 60-120-nucleotides in length.     

Putative MADS-Box Retropseudogenes in Rye (Secale L.)

The fragments of MADS-box genes belonging to the agamous and agamous-like structural classes were isolated by direct amplification of genomic DNA from annual rye (Secale cereale L.) and perennial rye (Secale montanum Guss.). The characterized fragments (deposited in the Genbank as the accession nos. AF332885–AF332887 and AF346894) comprise the complete sequences of exons 1 to 5 and lack corresponding introns. Their nearest homologs are the maize genes zag1 and zag5 (the Genbank accession nos. L18924 and L46398). One more agamous-like fragment isolated from annual rye (AF362364) is similar to theTaMADS12 wheat gene (AB007505). The fragment comprises exons 3–5 and contains a 105-bp insert between the exons 3 and 4; this insert does not resemble any MADS-box introns presently known. We assume that all these fragments of MADS-box genes are retropseudogenes.     

Molecular cloning and expression in yeast of 2,3–oxidosqualene– triterpenoid cyclases from Arabidopsis thaliana

A vast array of triterpenes are found in living organisms in addition to lanosterol and cycloartenol, which are involved in sterol biosynthesis in non–photosynthetic and photosynthetic eukaryotes respectively. The chemical structure of these triterpenes is determined by a single step catalysed by 2,3–oxidosqualene–triterpene cyclases. The present study describes cloning and functional expression in yeast of several OS–triterpene cyclases. Three Arabidopsis thaliana cDNAs encoding proteins (ATLUP1, ATLUP2, ATPEN1) 57%, 58% and 49% identical to cycloartenol synthase from the same plant were isolated. Expression of these cDNAs in yeast showed that the recombinant proteins catalyse the synthesis of various pentacyclic triterpenes. Whereas ATLUP1 is essentially involved in the synthesis of lupeol, ATLUP2 catalyses the production of lupeol, – and –amyrin (in a 15:55:30 ratio). ATLUP2 is therefore a typical multifunctional enzyme. Under the same conditions, ATPEN1 did not lead to any product. Systematic sequencing of the Arabidopsis genome has led to genomic sequences encoding proteins identical to the above triterpene synthases. ATLUP1 and ATLUP2 are representative of a small subfamily (A) of at least five genes, whereas ATPEN1 is representative of a subfamily (B) of at least seven genes. The number of introns is characteristic of each subfamily. Whereas genes of family A possess 17 exons and 16 introns, genes of the subfamily B contain 14 exons and 13 introns. The size of each exon is remarkably conserved within each subfamily whereas that of each intron appears to be highly variable. Organization of the genes, sequences and functions of the deduced proteins are discussed in evolutionary terms.     

Cloning and characterization of a third type of human α-amylase gene, AMY2B

We have previously reported concerning the existence of a third type of human α-amylase gene, AMY3 [Emi et al., Gene 62 (1988) 229–235; Tomita et al., Gene 76 (1989) 11–18], which is expressed in a lung carcinoid tissue, and differs in nucleotide sequence from the two previously characterized human α-amylase genes coding for salivary and pancreatic isozymes, termed AMY1 and AMY2, respectively.Here, we rename this gene AMY2B to coincide with the designation by Gumucio et al. [Mol. Cell Biol. 8 (1988) 1197–1205] and describe its genetic properties as revealed by sequencing studies. It consists of ten major exons whose sequences are highly homologous to those of AMY1 and AMY2. Not only the exons, but also most of the introns seem to be highly conserved, as judged from physical mapping data. The AMY2B gene identified from mRNA in a lung carcinoid tissue has at least two additional untranslated exons in its 5′ region; hence the promoter lies far upstream relative to the other two AMY genes.     

A Gradient in the Distribution of Introns in Eukaryotic Genes

The majority of eukaryotic genes consist of exons and introns. Introns can be inserted either between codons (phase 0) or within codons, after the first nucleotide (phase 1) and after the second (phase 2). We report here that the frequency of phase 0 increases and phase 1 declines from the 5′ region to the 3′ end of genes. This trend is particularly noticeable in genomes of Homo sapiens and Arabidopsis thaliana, in which gains of novel introns in the 3′ portion of genes were probably a dominant process. Similar but more moderate gradients exist in Drosophila melanogaster and Caenorhabditis elegans genomes, where the accumulation of novel introns was not a prevailing factor. There are nine types of exons, three symmetric (0,0; 1,1; 2,2) and six asymmetric (0,1; 1,0; 1,2; 2,1; 2,0; 0,2). Assuming random distribution of different types of introns along genes, one can expect the frequencies of asymmetric exons such as 0,1 and 1,0 or 1,2 and 2,1 to be approximately equal, allowing for some variation caused by randomness. The gradient in intron distribution leads to a small but consistent and statistically significant bias: phase 1 introns are more likely at the 5′ ends and phase 0 introns are more likely at the 3′ ends of asymmetric exons. For the same reason, the frequency of 0,0 exons increases and the frequency of 1,1 exons decreases in the 3′ direction, at least in H. sapiens and A. thaliana. The number of introns per gene also affects the distribution and frequency of phase 0 and 1 introns. The gradient provides an insight into the evolution of intron-exon structures of eukaryotic genes. Electronic Supplementary Material Electronic Supplementary material is available for this article at and accessible for authorised users. [Reviewing Editor: Dr. Manyuan Long]     

Statistical characteristics of eukaryotic intron database

A database called eukaryotic intron database (EID) was developed based on the data from GenBank. Studies on the statistical characteristics of EID show that there were 103, 848 genes, 478,484 introns, and 582,332 exons, with an average of 4.61 introns and 5.61 exons per gene. Introns of 40–120 nt in length were abundant in the database. Results of the statistical analysis on the data from nine model species showed that in eukaryotes, higher species do not necessarily have more introns or exons in a gene than lower species. Furthermore, characteristics of EID, such as intron phase, distribution of different splice sites, and the relationship between genome size and intron proportion or intron density, have been studied. __________ Translated from Acta Scientiarum Naturalium Universitatis Sunyatseni, 2005, 44(6): 79–82 [译自: 中山大学学报, 2005, 44(6): 79–82]     

The nucleotide sequence of bovine MHC class IIDQB andDRB genes

The nucleotide sequences of most of the exons and parts of the introns of twoBoLA-DQB genes and twoBoLA-DRB genes have been determined. The structure of these genes is very similar to that of human major histocompatibility complex (MHC) class II genes. The twoDQB genes probably represent true alleles. Based on the exons sequenced, bothDQB genes and one of theDRB genes seem to be functional. The otherDRB gene is a pseudogene; stopcodons are found in the exons encoding the second and transmembrane domain and, furthermore, a 2 base pair (bp) deletion has occured in the leader exon which places the initiation start codon out of frame. Also in this pseudogene, an almost perfect inverted repeat of 200 bp is found flanking the exon encoding the first domain, which might have been the result of a duplication/inversion event. The sequences presented in this paper do not contain any repetitions. Therefore, DNA fragments containing these sequences can be used as homologous bovine probes in restriction fragment length polymorphism (RFLP) analysis to study disease association in cattle.The nucleotide sequence data reported in this paper have been submitted to the GenBank nucleotide sequence database and have been assigned the accession numbers M30002–M30014. Address correspondence and offprint requests to: M. A. M. Groenen.     

Complete Structural Organization of the Human α1(V) Collagen Gene (COL5A1): Divergence from the Conserved Organization of Other Characterized Fibrillar Collagen Genes

Genes that encode the vertebrate fibrillar collagen types I–III have previously been shown to share a highly conserved intron/exon organization, thought to reflect common ancestry and evolutionary pressures at the protein level. We report here the complete intron/exon organization ofCOL5A1,the human gene that encodes the α1 chain of fibrillar collagen type V. The structure ofCOL5A1is shown to be considerably diverged from the conserved structure of the genes for fibrillar collagen types I–III.COL5A1has 66 exons, which is greater than the number of exons found in the genes for collagen types I–III. The increased number of exons is partly due to the increased size of the pro-α1(V) N-propeptide, relative to the sizes of the N-propeptides of the types I–III procollagen molecules. In addition, however, the increased number of exons is due to differences in the intron/exon organization of the triple-helix coding region ofCOL5A1compared to the organization of the triple-helix coding regions of the genes for collagen types I–III. Of particular interest is the increase of 54 bp exons in this region ofCOL5A1,strongly supporting the proposal that the triple-helix coding regions of fibrillar collagen genes evolved from duplication of a 54 bp primordial genetic element. Moreover, comparison of the structure ofCOL5A1to the highly conserved structure of the genes of collagen types I–III provides insights into the probable structure of the ancestral gene that gave rise to what appears to be two classes of vertebrate fibrillar collagen genes.     

Comparative evolutionary rates of introns and exons in murine rodents

Analysis of DNA sequences of 132 introns and 140 exons from 42 pairs of orthologous genes of mouse and rat was used to compare patterns of evolutionary change between introns and exons. The mean of the absolute difference in length (measured in base pairs) between the two species was nearly five times as high in the case of introns as in the case of exons. The average rate of nucleotide substitution in introns was very similar to the rate of synonymous substitution in exons, and both were about three times the rate of substitution at nonsynonymous sites in exons. G+C content of introns and exons of the same gene were correlated; but mean G+C content at the third positions of exons was significantly higher than that of introns or positions 1–2 of exons from the same gene. G+C content was conserved over evolutionary time, as indicated by strong correlations between mouse and rat; but the change in G+C content was greatest at position 3 of exons, intermediate in introns, and lowest at positions 1–2 in introns. Received: 23 December 1996 / Accepted: 1 April 1997     

The Human CYP2C Locus: A Prototype for Intergenic and Exon Repetition Splicing Events

In human there are four known CYP2C genes that have been mapped to chromosome 10q24 with the order Cen–2C18–2C19–2C9–2C8–Tel. Previously we have shown that splicing events joining exons from the neighboring 2C18 and 2C19 genes occur in human liver and epidermis. Here evidence is presented that the terminal genes of this cluster, 2C18 and 2C8, are also involved in intergenic splicing. Most interestingly, several of these 2C18/2C8 RNAs were composed of all nine exons, thus conceivably having the potential for coding functional proteins. Moreover, chimeric RNA species consisting of exons originating not only from the CYP2C8 and CYP2C18 genes, but also from the CYP2C19 gene were detected. In all cases the exons from the different CYP2C genes were joined at the correct canonical splice sites. However, the closely linked RBP4 gene is not participating in intergenic splicing with the CYP2C genes. In addition, CYP2C8 gene expression was found to generate a variety of scrambled RNA molecules including species that contained repetitions of certain exons.     

Changes of introns and exons length in genes of arabidopsis, rice, nematode and human

Genes of Arabidopsis thaliana, Orysa sativa, Caenorhabditis elegans, Homo sapiens have been studied by computer analysis. The average intron and exon lengths in genes of these organisms decreases with increase of intron number in genes. The length of introns and exons in A. thaliana and O. sativa genes is change with increase of intron number in genes by high coefficient of correlation. Linear dependence between the sum of exon lengths and intron number in genes increased proportionally to number of gene introns. The average length of introns and genes of human depend on density of genes in DNA.     

The compositional properties of human genes

Summary The present work represents the first attempt to study in greater detail previously proposed compositional correlations in genomes, based on a body of additional data relating to gene localizations as well as to extended flanking sequences extracted from gene banks. We have investigated the correlations that exist between (1) the GC levels of exons of human genes, and (2) the GC levels of either intergenic sequences or introns associated with the genes under consideration. In both cases, linear relationships with slopes close to unity were found. The similarity of the linear relationships indicates similar GC levels in intergenic sequences and introns located in the same isochores. Moreover, both intergenic sequences and introns showed GC levels 5–10% lower than the corresponding exons. The above findings considerably strengthen the previously drawn conclusion that coding and noncoding sequences (both inter- and intragenic) from the same isochores of the human genome are compositionally correlated. In addition, we find linear correlations between the GC levels of codon positions and of the intergenic sequences or introns associated with the corresponding genes, as well as among the GC levels of codon positions of genes.     

Distributions of exons and introns in the human genome

The human genome is revisited using exon and intron distribution profiles. The 26,564 annotated genes in the human genome (build October, 2003) contain 233,785 exons and 207,344 introns. On average, there are 8.8 exons and 7.8 introns per gene. About 80% of the exons on each chromosome are < 200 bp in length. < 0.01% of the introns are < 20 bp in length and < 10% of introns are more than 11,000 bp in length. These results suggest constraints on the splicing machinery to splice out very long or very short introns and provide insight to optimal intron length selection. Interestingly, the total length in introns and intergenic DNA on each chromosome is significantly correlated to the determined chromosome size with a coefficient of correlation r = 0.95 and r = 0.97, respectively. These results suggest their implication in genome design.     

Cotranscriptional expression of mitochondrial genes for subunits of NADH dehydrogenase, nad5, nad4, nad2, in Marchantia polymorpha

Three genes for the subunits of the NADH dehydrogenase (nad5, nad4, and nad2) are tandemly clustered on the liverwort mitochondrial genome. Their gene products showed high levels of amino acid sequence identity with the corresponding subunits from higher plant mitochondria (82.8–84.4%), and significant levels of identity with those from liverwort chloroplast (32.0–33.5%), Podospora anserina mitochondria (21.4–45.9%), and human mitochondria (18.4–27.9%). In addition, these three subunits from liverwort mitochondria have conserved amino acid residues in their central regions. The gene nad5 is interrupted by a 672 by group I intron, while genes nad4 and nad2 are interrupted by group II introns of 899 by and 1418 bp, respectively. Northern blot analysis using exon-intron specific probes indicated that these three genes are transcribed as a single precursor mRNA of 9.6 kb in length and are processed into mature mRNA molecules in liverwort mitochondria. Several regions of this nad gene cluster are repeated in the liverwort mitochondrial genome.Communicated by R.G. Herrmann     

SURVEY AND SUMMARY: exon-intron organization of genes in the slime mold Physarum polycephalum

The slime mold Physarum polycephalum is a morphologically simple organism with a large and complex genome. The exon–intron organization of its genes exhibits features typical for protists and fungi as well as those characteristic for the evolutionarily more advanced species. This indicates that both the taxonomic position as well as the size of the genome shape the exon–intron organization of an organism. The average gene has 3.7 introns which are on average 138 bp, with a rather narrow size distribution. Introns are enriched in AT base pairs by 13% relative to exons. The consensus sequences at exon–intron boundaries resemble those found for other species, with minor differences between short and long introns. A unique feature of P.polycephalum introns is the strong preference for pyrimidines in the coding strand throughout their length, without a particular enrichment at the 3′-ends.