Everyday technology use among older adults in Sweden and Japan: A comparative study.

BACKGROUND: As context may impact everyday technology (ET) use it is relevant to study this within different contexts. AIMS: To examine the usefulness of the Everyday Technology Use Questionnaire (ETUQ) in different contexts by investigating and comparing (1) the level of challenge of ETs in the ETUQ and (2) the relevance of and perceived ability to use ET in samples of Swedish and Japanese older adults. MATERIALS AND METHODS: The Swedish and the Japanese samples (n = 86/86) were interviewed using the ETUQ about relevance of and perceived ability to use ET. Data were analyzed using Rasch analysis, chi square and a general linear model. Moreover, Differential Item Functioning (DIF) was investigated. RESULTS: The hierarchy of ETs' level of challenge was generally stable in the two contexts. On group-level, the relevance was somewhat higher and the perceived ability to use ET significantly higher in the Swedish sample than in the Japanese. CONCLUSIONS AND SIGNIFICANCE: The similarities and differences between the technological landscapes of Sweden and Japan could be detected by ETUQ, demonstrating its usefulness in both countries. The potential causes to the differences in relevance of and perceived ability to use ET between older adults in Sweden and Japan need further exploration.

Cellular DBP and E4BP4 proteins are critical for determining the period length of the circadian oscillator.

The phenotypes of mice carrying clock gene mutations have been critical to understanding the mammalian clock function. However, behavior does not necessarily reflect cell-autonomous clock phenotypes, because of the hierarchical dominance of the central clock. We performed cell-based siRNA knockdown and cDNA overexpression and monitored rhythm using bioluminescent reporters of clock genes. We found that knockdown of DBP, D-box positive regulator, in our model led to a short-period phenotype, whereas overexpressing of DBP produced a long-period rhythm when compared to controls. Furthermore, knockdown and overexpressing of E4BP4, D-box negative regulator, led to an opposite effect of DBP. Our experiments demonstrated that D-box regulators play a crucial role in determining the period length of Per1 and Per2 promoter-driven circadian rhythms in Rat-1 fibroblasts.

Identification of functional clock-controlled elements involved in differential timing of Per1 and Per2 transcription.

It has been proposed that robust rhythmic gene expression requires clock-controlled elements (CCEs). Transcription of Per1 was reported to be regulated by the E-box and D-box in conventional reporter assays. However, such experiments are inconclusive in terms of how the CCEs and their combinations determine the phase of the Per1 gene. Whereas the phase of Per2 oscillation was found to be the most delayed among the three Period genes, the phase-delaying regions of the Per2 promoter remain to be determined. We therefore investigated the regulatory mechanism of circadian Per1 and Per2 transcription using an in vitro rhythm oscillation-monitoring system. We found that the copy number of the E-box might play an important role in determining the phase of Per1 oscillation. Based on real-time bioluminescence assays with various promoter constructs, we provide evidence that the non-canonical E-box is involved in the phase delay of Per2 oscillation. Transfection experiments confirmed that the non-canonical E-box could be activated by CLOCK/BMAL1. We also show that the D-box in the third conserved segment of the Per2 promoter generated high amplitude. Our experiments demonstrate that the copy number and various combinations of functional CCEs ultimately led to different circadian phases and amplitudes.

Occurrence of two functionally distinct proopiomelanocortin genes in all modern lampreys.

The lampreys (family Petromyzontidae) are divided into three subfamilies, the Petromyzontinae in the Northern Hemisphere and the Geotriinae and Mordaciinae in the Southern Hemisphere. We previously found two proopiomelanocortin subtypes, proopiocortin (POC) and proopiomelanotropin (POM) in sea lamprey, Petromyzon marinus (Petromyzontinae). POC encoding adrenocorticotropic hormone (ACTH) and beta-endorphin (beta-END) is expressed in the pars distalis of the pituitary, while POM encoding melanophore-stimulating hormone (MSH)-A and B together with a different beta-END is expressed in the pars intermedia of the pituitary. All these hormonal segments are encoded on the third exon in both POC and POM. Here, we demonstrate the presence of both POC and POM genes in Geotria australis (Geotriinae) and Mordacia mordax (Mordaciinae) by molecular cloning of the third exons with the polymerase chain reaction using genomic DNA or pituitary cDNA. Molecular phylogenetic analysis showed that the POC and POM are distinctly different for the Southern Hemisphere lampreys as they are for P. marinus. Moreover, the relationship of each hormonal segments in POC and POM between Geotria, Mordacia, and Petromyzon is inconsistent. Immunocytochemical studies showed that the distribution of POC and POM in the pituitaries of the Southern Hemisphere lampreys is the same as that in the Northern Hemisphere. Taken together, these findings suggest that the duplication event which generated the two genes may have occurred in a common ancestor of the three extant lamprey subfamilies.

Promoter activity of sea lamprey proopiocortin and proopiomelanotropin genes in AtT-20/D16v cells.

Adrenocorticotropic hormone (ACTH) and melanophore-stimulating hormone (MSH) are produced in the pars distalis and pars intermedia, respectively, throughout vertebrates. These hormones together with beta-endorphin are encoded on a single gene proopiomelanocortin (POMC) in gnathostomes, but in the sea lamprey, an agnathan, ACTH and MSH are encoded on two separate genes, proopiocortin (POC) and proopiomelanotropin (POM), respectively. Moreover, the nucleotide sequences of 5'-flanking regions of the POC and POM genes are significantly different from each other. To investigate the potential promoter activities of the POC and POM genes, we constructed promoter reporter plasmids by fusing the 5' flanking sequences (nucleotides -1151 to +31 and -2510 to +51, respectively) to a firefly luciferase gene. Transient transfection studies in AtT-20/D16v cells, which derived from a mouse pituitary tumor cell line, revealed that the 5'-flanking sequence of the POC gene did not exhibit promoter activity, whereas that of the POM gene showed the activity at high levels nearly equivalent to SV40 promoter. Analysis of a series of the 5'-deleted reporter for the POM gene in the AtT-20/D16v cells demonstrated that the 422 bp 5'-flanking sequence was sufficient for promoter activity, while the sequence from -853 to -574 may contain negatively acting regulatory elements. Because the POC and POM genes are supposed to have differentiated from a common ancestor, during evolution, the POC gene may lack essential element(s) for expression in the AtT-20/D16v cells.

Structures for the proopiomelanocortin family genes proopiocortin and proopiomelanotropin in the sea lamprey Petromyzon marinus.

Gnathostomes express a common proopiomelanocortin (POMC) gene in the pars distalis (PD) and the pars intermedia (PI) of the pituitary gland. In contrast, the sea lamprey Petromyzon marinus expresses one distinct gene in each lobe; proopiocortin (POC) encoding adrenocorticotropic hormone (ACTH) and beta-endorphin (END) is expressed in the PD and proopiomelanotropin (POM) encoding melanophore-stimulating hormone (MSH), and a different beta-END is expressed in the PI. We characterized the genomic structure of the sea lamprey POC and POM genes including their 5'-flanking regions. Both genes have two introns at positions similar to those of gnathostomes. Each exon encodes genetic information seen in the gnathostome POMC gene: exon 1 encodes an untranslated nucleotide sequence, exon 2 encodes a signal peptide and the N-terminal short part of POC or POM, and exon 3 encodes all other parts including ACTH, MSHs or beta-END. Intron-A of POM (2289 bp) is six times longer than that of POC (379 bp). The POM intron-A has three transposon-like sequences (TnL-1, -2, -3), the total length of which is 1781 bp, suggesting that it has expanded via the insertion of TnLs. The 5'-flanking region of the POC gene contains two TATA boxes, a CCAAT box, eight E boxes, STAT, RAIE, and one binding site each for Ptx1, Pit-1, and Tpit. The POM gene contains four TATA boxes, eight E boxes, three STATs, two RAIEs, two CRE-like elements, and one binding site for Pit1. However, there is virtually no similarity between the two genes in the distribution of the elements. The transcriptional regulation of POC and POM may have diverged with the functional differentiation of the two genes.