Promoción del envejecimiento activo: efectos del programa «Vivir con vitalidad»® / Promoting active ageing: effects of the «Vital living» programme

Introducción: en las últimas décadas, el envejecimiento activo ha emergido como un nuevo paradigma en la Gerontología. El II Plan Internacional sobre Envejecimiento de Naciones Unidas y la Organización Mundial de la Salud enfatiza el envejecimiento activo como un concepto clave que ha de promocionarse mediante políticas adecuadas. El curso presencial «Vivir con vitalidad»® y la versión multimedia «Vital ageing»® se han desarrollado con el fin de promocionar el envejecimiento óptimo. Ambos programas se han valorado a través de un diseño experimental por el que se han comparado algunos de sus efectos. Método: participaron en el estudio 107 personas mayores de 60 años voluntarias: de ellas 44 recibieron el curso multimedia, 32 participaron en «Vivir con vitalidad»® presencial y 31 formaron parte del grupo de control. A todos los participantes se les administraron los mismos instrumentos antes y después (fases pre y post, respectivamente) de la implementación del programa y, tras el mismo intervalo, al grupo de control. Resultados: ambos programas producen cambios positivos y significativos en diversos indicadores conductuales. Se han observado cambios en el sentido esperado en los grupos experimentales (en comparación con el control) en la frecuencia de actividades, así como en las opiniones sobre el envejecimiento y la vejez. También se encontraron cambios significativos en la satisfacción con la vida, los hábitos nutricionales y de ejercicio físico regular en el grupo multimedia. No se encontraron cambios significativos en relaciones sociales y salud en ninguno de los 2 grupos experimentales. Los resultados se discuten a la luz de la investigación sobre envejecimiento saludable y activo

Introduction: during the last two decades, active ageing has emerged as a new paradigm in Gerontology. The II International Plan of Action on Ageing of the United Nations and the World Health Organisation emphasises active ageing as a key concept that should be promoted by suitable policies. The «Vivir con vitalidad»® (Vital Living) programme and its multimedia version «Vital ageing»®, constitute a program for optimal ageing. The present article reports an experimental evaluation of both programmes conducted to compare some of their effects. Method: a total of 107 volunteers aged more than 60 years old participated in this study: 44 received the multimedia course, 32 attended a «Vivir con vitalidad»® course taught by teachers, and 31 acted as control subjects. The same battery of tests was administered to all participants before and after receiving the course and to the control group at an identical interval. Results: both programmes produced positive and significant changes in several behavioural indicators. Changes in the expected direction were observed in the experimental groups (in comparison with the control group) in the frequency of activities, as well as in opinions on ageing and old age. Significant differences were found in life satisfaction, nutrition and regular physical exercise in the multimedia group. No significant changes were found in social relationships or in health in either of the experimental groups. The results of this study are discussed in light of research on active and healthy ageing published in the literature

Interaction of the Neurospora crassa mitochondrial tyrosyl-tRNA synthetase (CYT-18 protein) with the group I intron P4-P6 domain. Thermodynamic analysis and the role of metal ions.

The Neurospora crassa mitochondrial tyrosyl-tRNA synthetase (CYT-18 protein) functions in splicing group I introns by promoting the formation of the catalytically active structure of the intron's catalytic core. Previous studies suggested a model in which the protein binds first to the intron's P4-P6 domain, and then makes additional contacts with the P3-P9 domain to stabilize the two domains in the correct relative orientation to form the intron's active site. Here, we analyzed the interaction of CYT-18 with a small RNA (P4-P6 RNA) corresponding to the isolated P4-P6 domain of the N. crassa mitochondrial large subunit ribosomal RNA intron. RNA footprinting and modification-interference experiments showed that CYT-18 binds to this small RNA around the junction of the P4-P6 stacked helices on the side opposite the active-site cleft, as it does to the P4-P6 domain in the intact intron. The binding is inhibited by chemical modifications that disrupt base-pairing in P4, P6, and P6a, indicating that a partially folded structure of the P4-P6 domain is required. The temperature-dependence of binding indicates that the interaction is driven by a favorable enthalpy change, but is accompanied by an unfavorable entropy change. The latter may reflect entropically unfavorable conformational changes or decreased conformational flexibility in the complex. CYT-18 binding is inhibited at > or =125 mM KCl, indicating a strong dependence on phosphodiester-backbone interactions. On the other hand, Mg(2+) is absolutely required for CYT-18 binding, with titration experiments showing approximately 1.5 magnesium ions bound per complex. Metal ion-cleavage experiments identified a divalent cation-binding site near the boundary of P6 and J6/6a, and chemical modification showed that Mg(2+) binding induces RNA conformational changes in this region, as well as elsewhere, particularly in J4/5. Together, these findings suggest a model in which the binding of Mg(2+) near J6/6a and possibly at one additional location in the P4-P6 RNA induces formation of a specific phosphodiester-backbone geometry that is required for CYT-18 binding. The binding of CYT-18 may then establish the correct structure at the junction of the P4/P6 stacked helices for assembly of the P3-P9 domain. The interaction of CYT-18 with the P4-P6 domain appears similar to the TyrRS interaction with the D-/anticodon arm stacked helices of tRNA(Tyr).

RNA: versatility in form and function.

RNA performs a remarkable range of functions in all cells. In addition to its central role in information transfer from DNA to protein, it is essential for functions as diverse as RNA processing, chromosome end-maintenance and dosage compensation. The versatility of RNA derives from its unique ability to use direct readout via base-pairing for sequence specific targeting (or templating) in combination with its capacity to form elaborate three dimensional structures. Such structures can perform catalysis or serve as protein recognition surfaces. In this short review, we attempt to give a flavor for the diversity of functional RNAs in the cell and highlight, using selected examples, two quite distinct activities, catalysis and sequence specific targeting. Within each section, we discuss how the lessons we have learned from these systems may apply to other, less well understood, RNAs.

Characterization of Neurospora mitochondrial group I introns reveals different CYT-18 dependent and independent splicing strategies and an alternative 3' splice site for an intron ORF.

The Neurospora crassa mitochondrial tyrosyl-tRNA synthetase (CYT-18 protein) functions in splicing the N. crassa mitochondrial large rRNA intron by stabilizing the catalytically active structure of the intron core. Here, a comprehensive study of N. crassa mtDNA group I introns identified two additional introns, cob-I2 and the ND1 intron, that are dependent on CYT-18 for splicing in vitro and in vivo. The other seven N. crassa mtDNA group I introns are not CYT-18-dependent and include five that self-splice and two that do not splice under any conditions examined. Some of these introns may require maturases or other proteins for efficient splicing. All but one of the non-CYT-18-dependent introns contain large peripheral extensions of the P5 stem, related to the P5abc structure that blocks CYT-18 binding to the Tetrahymena large rRNA intron. The remaining non-CYT-18-dependent intron, cob-I1, contains a long, peripheral extension of the P9 stem, denoted P9.1, which also impedes CYT-18 binding. Detailed analysis of the CYT-18-dependent ND1 intron showed that two 3' splice sites are used in vitro and in vivo. The proximal, alternative 3' splice site brings the intron open reading frame, which potentially encodes a mobility endonuclease, in frame with the upstream exon, possibly providing a means of expression. Considered together, our results show that group I introns in N. crassa mitochondria use a variety of strategies involving different proteins and/or RNA structures to assist splicing, and they support the hypothesis that CYT-18 and the peripheral RNA structure P5abc are alternative evolutionary adaptations for stabilizing the active structure of the intron core.

A tyrosyl-tRNA synthetase recognizes a conserved tRNA-like structural motif in the group I intron catalytic core.

The Neurospora crassa mitochondrial (mt) tyrosyl-tRNA synthetase (CYT-18 protein) functions in splicing group I introns, in addition to aminoacylating tRNA(Tyr). Here, we compared the CYT-18 binding sites in the N. crassa mt LSU and ND1 introns with that in N. crassa mt tRNA(Tyr) by constructing three-dimensional models based on chemical modification and RNA footprinting data. Remarkably, superimposition of the CYT-18 binding sites in the model structures revealed an extended three-dimensional overlap between the tRNA and the group I intron catalytic core. Our results provide insight into how an RNA-splicing factor can evolve from a cellular RNA-binding protein. Further, the structural similarities between group I introns and tRNAs are consistent with an evolutionary relationship and suggest a general mechanism for the evolution of complex catalytic RNAs.

A tyrosyl-tRNA synthetase suppresses structural defects in the two major helical domains of the group I intron catalytic core.

The Neurospora crassa mitochondrial tyrosyl-tRNA synthetase, the CYT-18 protein, functions in splicing group I introns by promoting the formation of the catalytically active structure of the intron RNA. The group I intron catalytic core is thought to consist of two extended helical domains, one formed by coaxial stacking of P5, P4, P6, and P6a (P4-P6 domain) and the other consisting of P8, P3, P7, and P9 (P3-P9 domain). To investigate how CYT-18 stabilizes the active RNA structure, we used an Escherichia coli genetic assay based on the phage T4 td intron to systematically test the ability of CYT-18 to compensate for structural defects in three key regions of the catalytic core: J3/4 and J6/7, connecting regions that form parts of the triple-helical-scaffold structure with the P4-P6 domain, and P7, a long-range base-pairing interaction that forms the guanosine-binding site and is part of the P3-P9 domain. Our results show that CYT-18 can suppress numerous mutations that disrupt the J3/4 and J6/7 nucleotide-triple interactions, as well as mutations that disrupt base-pairing in P7. CYT-18 suppressed mutations of phylogenetically conserved nucleotide residues at all positions tested, except for the universally conserved G-residue at the guanosine-binding site. Structure mapping experiments with selected mutant introns showed that the CYT-18-suppressible J3/4 mutations primarily impaired folding of the P4-P6 domain, while the J6/7 mutations impaired folding of both the P4-P6 and P3-P9 domains to various degrees. The P7 mutations impaired the formation of both P7 and P3, thereby grossly disrupting the P3-P9 domain. The finding that the P7 mutations also impaired formation of P3 provides evidence that the formation of these two long-range pairings is interdependent in the td intron. Considered together with previous work, the nature of mutations suppressed by CYT-18 supports a model in which CYT-18 helps assemble the P4-P6 domain and then stabilizes the two major helical domains of the catalytic core in the correct relative orientation to form the intron's active site.

A tyrosyl-tRNA synthetase protein induces tertiary folding of the group I intron catalytic core.

The Neurospora crassa mitochondrial tyrosyl-tRNA synthetase (CYT-18 protein) functions in splicing group I introns. We have used chemical-structure mapping and footprinting to investigate the interaction of the CYT-18 protein with the N. crassa mitochondrial large subunit ribosomal RNA (mt LSU) and ND1 introns, which are not detectably self-splicing in vitro. Our results show that both these non-self-splicing introns form most of the short range pairings of the conserved group I intron secondary structure in the absence of CYT-18, but otherwise remain largely unfolded, even at high Mg2+ concentrations. The binding of CYT-18 promotes the formation of the extended helical domains P6a-P6-P4-P5 (P4-P6 domain) and P8-P3-P7-P9 (P3-P9 domain) and their interaction to form the catalytic core. In iodine-footprinting experiments, CYT-18 binding results in the protection of regions of the phosphodiester backbone expected for tertiary folding of the catalytic core, as well as additional protections that may reflect proximity of the protein. In both introns, most of the putative CYT-18 protection sites are in the P4-P6 domain, the region of the SU intron previously shown to bind CYT-18 as a separate RNA molecule, but additional sites are found in the other major helical domain in P8 and P9 in both introns and in L9 and P7.1/P7.1a in the mt LSU intron. Protease digestion of the CYT-18/intron RNA complexes results in the loss of CYT-18-induced RNA tertiary structure and splicing activity. Considered together with previous studies, or results suggest that CYT-18 binds initially to the P4-P6 region of group I introns to form a scaffold for the assembly of the P3-P9 domain, which may contain additional binding sites for the protein. A three-dimensional model structure of the CYT-18 binding site in group I introns indicates that CYT-18 interacts with the surface of the catalytic core on the side opposite the active-site cleft and may primarily recognize a specific three-dimensional geometry of the phosphodiester backbone of group I introns.

A tyrosyl-tRNA synthetase can function similarly to an RNA structure in the Tetrahymena ribozyme.

Group I introns are highly structured RNAs which catalyse their own splicing by guanosine-initiated transesterification reactions. Their catalytic core is generally stabilized by RNA-RNA interactions within the core and with peripheral RNA structures. Additionally, some group I introns require proteins for efficient splicing in vivo. The Neurospora CYT-18 protein, the mitochondrial tyrosyl-transfer RNA synthetase (mt TyrRS), promotes splicing of the Neurospora mitochondrial large ribosomal RNA (LSU) and other group I introns by stabilizing the catalytically active structure of the intron core. We report here that CYT-18 functions similarly to a peripheral RNA structure, P5abc, that stabilizes the catalytic core of the Tetrahymena LSU intron. The CYT-18 protein and P5abc RNA bind to overlapping sites in the intron core, inducing similar conformational changes correlated with splicing activity. Our results show that a protein can play the role of an RNA structure in a catalytic RNA, a substitution postulated for the evolution of nuclear pre-messenger RNA introns from self-splicing introns.

Deletion of P9 and stem-loop structures downstream from the catalytic core affects both 5' and 3' splicing activities in a group-I intron.

The P9 stem-loop is one of the conserved structural elements found in all group-I introns. Using two deletion mutants in this region of the Tetrahymena thermophilia large ribosomal subunit intron, we show that removal of the P9 element, either alone, or together with the non-conserved downstream P9.1 and P9.2 elements, results in an intron incapable of the first step of the splicing reaction at a low concentration of Mg2+. The mutant introns also require high concentrations of Mg2+ for the second step in splicing, as well as hydrolysis reactions, suggesting that P9, as well as P9.1 and P9.2, are important structural elements in the final folded form of the intron. In addition, RNase-T1-mediated-structure-probing experiments demonstrated that the loss of P9, P9.1 and P9.2 changes the structural context of the region binding the 5' splice site. The deletions lead to less efficient recognition of the 3' splice site and an accumulation of unligated exons. These observations support the view that the P9, P9.1 and P9.2 stem-loops play an important role in the binding of the 3' splice site.

Important 2'-hydroxyl groups within the core of a group I intron.

The catalytic activity of a group I intron is dependent on a core structure, much of which is not exposed to solvent. In order to study the structure of the core, an efficient bimolecular reaction has been developed: the 5'-component is a molecule of about 300 bases which contains the 5'-splice-site and terminates in the loop established by P8, and the 3'-component is a 24 base long oligoribonucleotide which includes the 3'-regions of the P8 and P7 helices with their joining region, J8/7. J8/7 is thought to play several roles including binding the helix containing the 5'-splice-site. P7 forms a major portion of the guanosine binding site required for splicing. We have modified the bimolecular system to make it amenable to kinetic analysis and have used it to study the role of the ribose sugars in the oligomer. Multiple deoxyribonucleotide substitution in the J8/7 region completely blocked 5'-splice-site cleavage even though the Kd was only reduced about 5-fold. This supports the idea that the ribose phosphate backbone in J8/7 plays a key role in catalysis. Individual substitutions at G303 and A306 reduced the rate of catalysis 5-10-fold. The G303 substitution blocked GTP-independent hydrolysis of the 5'-splice-site. The region spanning the junction of P8 and J8/7 was also highly sensitive to multiple deoxyribonucleotide substitution; however, only in the case of C298 did an individual substitution have any effect on cleavage. Deoxyribonucleotide substitution in the 3'-section of P7 was less severe, although kcat/Km in low GTP was down 70-fold.