Periodicities in protein sequences

The correlation between various amino acid residues (either same or different), along the polypeptide chain have been studied using a large data base. A table of preference values for pairs having strong correlations has been constructed, which can be used to study any sequence and by calculating the weight of these sequences based on these preference values, a rough distinction between a “natural” and a “random” sequence can be made, One can further comment on the evolutionary status of proteins based on these weights.     

High-Resolution Measurement of Circadian Periodicities in Acetabularia

Well-expressed endogenous circadian rhythms in Acetabularia acetabulum were spectrally analyzed and recorded in time-period distributions. The stability of the circadian periods under constant conditions and their changes could be monitored continually in step sizes close to the circadian period length. The resolution of period estimates of the circadian component was increased by a factor of 4-10 by adapting analyzed interval lengths to full period sizes of the corresponding main component. Methodological aspects of the applied algorithms are discussed by means of examples that measure the temperature dependency of the circadian period.     

The antiquity of group I introns.

The recent discovery of self-splicing introns in cyanobacteria has given renewed interest to the question of whether introns may have been present in the ancestor of all living things. The properties of introns in genes of bacteria and bacteriophages are discussed in the context of their possible origin and biological function.     

Structural conventions for group I introns.

Conventions for nomenclature of structural elements and a standard secondary structure representation for group I introns have been established by workers in the field. These conventions are designed to facilitate effective communication of information concerning the structure and function of these self-splicing introns.     

Periodicities in coding and noncoding regions of the genes

Gene population statistical studies of protein coding genes and introns have identified two types of periodicities on the purine/pyrimidine alphabet: (i) the modulo 3 periodicity or coding periodicity (periodicity P3) in protein coding genes of eukaryotes, prokaryotes, viruses, chloroplasts, mitochondria, plasmids and in introns of viruses and mitochondria, and (ii) the modulo 2 periodicity (periodicity P2) in the eukaryotic introns. The periodicity study is herein extended to the 5' and 3' regions of eukaryotes, prokaryotes and viruses and shows: (i) the periodicity P3 in the 5' and 3' regions of eukaryotes. Therefore, these observations suggest a unitary and dynamic concept for the genes as for a given genome, the 5' and 3' regions have the genetic information for protein coding genes and for introns: (1) In the eukaryotic genome, the 5' (P2 and P3) and 3' (P2 and P3) regions have the information for protein coding genes (P3) and for introns (P2). The intensity of P3 is high in 5' regions and weak in 3' regions, while the intensity of P2 is weak in 5' regions and high in 3' regions. (2) In the prokaryotic genome, the 5' (P3) and 3' (P3) regions have the information for protein coding genes (P3). (3) In the viral genome, the 5' (P3) and 3' (P3) regions have the information for protein coding genes (P3) and for introns (P3). The absence of P2 in viral introns (in opposition to eukaryotic introns) may be related to the absence of P2 in 5' and 3' regions of viruses.     

Evidence that introns arose at proto-splice sites.

The unexpected discovery of introns raised many questions about gene evolution. We provide evidence that actin and tubulin introns were gained between the G and R of the conserved coding sequence C/AAGR that is known to flank introns in general and which we call a proto-splice site. We conclude that the tubulin and actin introns are less ancient than the coding sequence and so could not have been involved in the primary evolution of the tubulin and actin genes.     

The role of introns in evolution

What are the roles of 'classical' introns in the evolution of nuclear genes, and what was the origin of these introns? Exon shuffling has been important in the evolution of cell surface and extracellular proteins, but the evidence for it in respect of intracellular proteins is weak. Intron distributions imply that some introns have been removed while others have been inserted in the course of evolution: ancestral patterns of introns may thus have been obscured. Recent evidence on the self-splicing and reverse-splicing abilities of Group II introns supports the hypothesis that these could have been the ancestors of classical introns.     

Anticodons,Frameshifts, and Hidden Periodicities in tRNA Sequences

Abstract

Fourier analysis of the short-range periodicities for the complete set of sequences coding for tRNA genes in genome of Bacillus subtilis proves that periodicities with periods p = 2, 3, 4, and 6 sites are the inherent properties of tRNAs. The related periodicities should be understood in a broad statistical sense and their identifying needs the elaborate statistical methods. To improve the statistics, the analysis of significant periodicities was performed for the binary R-Y, S-W, and K-M sequences. Generally, such short-range periodicities are produced via biased positioning of particular nucleotides rather than via the tandem multiplication and subsequent modifications of repeats, though the latter mechanism may also be realized. Quasi-coherently piercing long segments of tRNA, the short-range periodicities create the effective long-range structural coupling between the acceptor stem and the anticodon loop and may participate in the mechanisms of molecular recognition. The periodicities with p = 2 and 4 provide the natural ground for the translation with spontaneous or programmed frameshifting and are present in tRNAs decoding the most frameshift-prone codons. The observation of short-range periodicities suggests that the mechanisms of amino-acylation of tRNAs and codon-anticodon pairing are not independent. Their study may also provide the important information related to the origin and evolution of the genetic code.     

Polymorphism of PCR-based markers targeting exons, introns, promoter regions, and SSRs in maize and introns and repeat sequences in oat.

Sequence databases could be efficiently exploited for development of DNA markers if it were known which gene regions reveal the most polymorphism when amplified by PCR. We developed PCR primer pairs that target specific regions of previously sequenced genes from Avena and Zea species. Primers were targeted to amplify 40 introns, 24 exons, and 23 promoter regions within 54 maize genes. We surveyed 48 maize inbred lines (previously assayed for simple-sequence repeat (SSR) polymorphism) for amplification-product polymorphism. We also developed primers to target 14 SSRs and 12 introns within 18 Avena genes, and surveyed 22 hexaploid oat cultivars and 2 diploid Avena species for amplification-product polymorphism. In maize, 67% of promoter markers, 58% of intron markers, and 13% of exon markers exhibited amplification-product polymorphisms. Among polymorphic primer pairs in maize, genotype diversity was highest for SSR markers (0.60) followed by intron markers (0.46), exon markers (0.42), and promoter markers (0.28). Among all Avena genotypes, 64% of SSR markers and 58% of intron markers revealed polymorphisms, but among the cultivars only, 21% of SSR markers and 50% of intron markers were polymorphic. Polymorphic-sequence-tagged sites for plant-breeding applications can be created easily by targeting noncoding gene regions.     

Identification of splicing signals in introns of yeast mitochondrial split genes: mutational alterations in intron bI1 and secondary structures in related introns.

Four mitochondrial mutations are known to block excision of intron I1 of the cob gene in S.cerevisiae. The nucleotide sequence alteration of one of them, M4873, has been determined. It is a deletion of 1 bp in a run of five G's at a distance of 30 to 34 bp upstream to the 3' splice point. Reversion is found to occur by restoration of the run of five G's either by insertion of 1 G (wild type reversion) or by transition A leads to G next to this run of G's (pseudo-wild type reversion). The effect of mutation and reversion on RNA splicing indicates that the run of five G's is of critical importance for intron I1 excision, possibly in participating in the formation of a splice signal with a helical structure. This presumption is confirmed by the observation that this sequence is part of a larger sequence of some 80 bp next to the 3' splice point which is conserved to some extend in the four mitochondrial introns (bI1, aI1, aI2, aI5) that survive after excision as circular RNAs. Most striking is the conservation of this sequence at the level of secondary structure.     

Origin and evolution of group I introns in cyanobacterial tRNA genes.

Many tRNA(Leu)UAA genes from plastids contain a group I intron. An intron is also inserted in the same gene at the same position in cyanobacteria, the bacterial progenitors of plastids, suggesting an ancient bacterial origin for this intron. A group I intron has also been found in the tRNA(fMet) gene of some cyanobacteria but not in plastids, suggesting a more recent origin for this intron. In this study, we investigate the phylogenetic distributions of the two introns among cyanobacteria, from the earliest branching to the more derived species. The phylogenetic distribution of the tRNA(Leu)UAA intron follows the clustering of rRNA sequences, being either absent or present in clades of closely related species, with only one exception in the Pseudanabaena group. Our data support the notion that the tRNA(Leu)UAA intron was inherited by cyanobacteria and plastids through a common ancestor. Conversely, the tRNA(fMet) intron has a sporadic distribution, implying that many gains and losses occurred during cyanobacterial evolution. Interestingly, a phylogenetic tree inferred from intronic sequences clearly separates the different tRNA introns, suggesting that each family has its own evolutionary history.     

Metal ion interaction with cosubstrate in self-splicing of group I introns.

The catalytic mechanism for self-splicing of the group I intron in the pre-mRNA from the nrdB gene in bacteriophage T4 has been investigated using 2'-amino- 2'-deoxyguanosine or guanosine as cosubstrates in the presence of Mg2+, Mn2+and Zn2+. The results show that a divalent metal ion interacts with the cosubstrate and thereby influences the efficiency of catalysis in the first step of splicing. This suggests the existence of a metal ion that catalyses the nucleophilic attack of the cosubstrate. Of particular significance is that the transesterification reactions of the first step of splicing with 2'-amino-2'-deoxyguanosine as cosubstrate are more efficient in mixtures containing either Mn2+or Zn2+together with Mg2+than with only magnesium ions present. The experiments in metal ion mixtures show that two (or more) metal ions are crucial for the self-splicing of group I introns and suggest the possibility that more than one of these have a direct catalytic role. A working model for a two-metal-ion mechanism in the transesterification steps is suggested.