Aki Okada scite author profile

We report a simple method, using p53 suppression and nontransforming L-Myc, to generate human induced pluripotent stem cells (iPSCs) with episomal plasmid vectors. We generated human iPSCs from multiple donors, including two putative human leukocyte antigen (HLA)-homozygous donors who match ∼20% of the Japanese population at major HLA loci; most iPSCs are integrated transgene-free. This method may provide iPSCs suitable for autologous and allologous stem-cell therapy in the future.

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Variation in the safety of induced pluripotent stem cell lines

Miura

et al. 2009

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We evaluated the teratoma-forming propensity of secondary neurospheres (SNS) generated from 36 mouse induced pluripotent stem (iPS) cell lines derived in 11 different ways. Teratoma-formation of SNS from embryonic fibroblast-derived iPS cells was similar to that of SNS from embryonic stem (ES) cells. In contrast, SNS from iPS cells derived from different adult tissues varied substantially in their teratoma-forming propensity, which correlated with the persistence of undifferentiated cells.

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Derivation Conditions Impact X-Inactivation Status in Female Human Induced Pluripotent Stem Cells

et al. 2012

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SUMMARY Female human induced pluripotent stem cell (hiPSC) lines exhibit variability in X-inactivation status. The majority of hiPSC lines maintain one transcriptionally active X (Xa) and one inactive X (Xi) chromosome from donor cells. However, at low frequency, hiPSC lines with two Xas are produced, suggesting that epigenetic alterations of the Xi occur sporadically during reprogramming. We show here that X-inactivation status in female hiPSC lines depends on derivation conditions. hiPSC lines generated by the Kyoto method (retroviral or episomal reprogramming), which uses leukemia inhibitory factor (LIF)-expressing SNL feeders, frequently had two Xas. Early passage Xa/Xi hiPSC lines generated on non-SNL feeders were converted into Xa/Xa hiPSC lines after several passages on SNL feeders, and supplementation with recombinant LIF caused reactivation of some of X-linked genes. Thus, feeders are a significant factor affecting X-inactivation status. The efficient production of Xa/Xa hiPSC lines provides unprecedented opportunities to understand human X-reactivation and inactivation.

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Molecular basis of alanine discrimination in editing site

Sokabe

Okada

Yao

et al. 2005

Proc. Natl. Acad. Sci. U.S.A.

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AlaX is the homologue of the class II alanyl-tRNA synthetase editing domain and has been shown to exhibit autonomous editing activity against mischarged tRNA Ala . Here, we present the structures of AlaX from the archaeon Pyrococcus horikoshii in apo form, complexed with zinc, and with noncognate amino acid L-serine and zinc. Together with mutational analysis, we demonstrated that the conserved Thr-30 hydroxyl group located near the ␤-methylene of the bound serine is responsible for the discrimination of noncognate serine from cognate alanine, based on their chemical natures. Furthermore, we confirmed that the conserved Gln-584 in alanyl-tRNA synthetase, which corresponds to Thr-30 of AlaX, is also critical for discrimination. These observations strongly suggested conservation of the chemical discrimination among trans-and cis-editing of tRNA Ala .alanyl-tRNA synthetase ͉ class II tRNA synthetase ͉ crystal structure ͉ trans-editing A minoacyl-tRNA synthetases (aaRSs) establish the genetic code through aminoacylation of cognate tRNA (1). However, in some aaRSs, the affinity difference of the active site is not large enough to distinguish among similar amino acids with sufficient accuracy. Therefore, during evolution, an additional editing domain that specifically hydrolyzes mischarged tRNAs has assembled with the catalytic domain to comprise contemporary aaRSs (2). In accordance with this model, the genes that autonomously encode an editing domain were distributed in many organisms (3-5), and, indeed, some of them are shown to be responsible for the transediting activity of mischarged tRNAs (4, 5). AlaX is the one such protein that shows homology to the class II alanyl-tRNA synthetase (AlaRS) editing domain ( Fig. 1) and is widely scattered among all three kingdoms of life (3). The specific activities of the archaeal AlaXs from Methanosarcina barkeri and Sulfolobus solfataricus have recently been shown to specifically hydrolyze mischarged Ser-and Gly-tRNA Ala in vitro (4).In contrast to the well established class I aaRSs, information regarding editing of the evolutionarily distinct class II aaRSs (to which AlaRS belongs) has only recently begun to emerge. The editing mechanism of the threonyl system has been investigated by structural analyses of the bacterial threonyl-tRNA synthetase (ThrRS) editing domain (hereafter called ThrRS-N2) complexed with the serine product or with the substrate analogue seryl-3Ј-aminoadenosine (SerA76) (6). These analyses showed that (i) cognate threonine and noncognate serine are discriminated by steric exclusion of the additional ␥-methyl group of threonine by the conserved His-77, Tyr-104, and Asp-180, and (ii) the HXXXH and CXXXH motifs characteristic of ThrRS-N2 should not bind a zinc ion for catalysis, despite the capability to bind zinc (7). The AlaX͞AlaRS editing domains are evolutionarily related to ThrRS-N2 and share the characteristic HXXXH and CXXXH motifs (Fig. 1) (4, 8), which were also shown to be important for the deacylation activity of AlaRS (9). The inclusion of non...

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Transcriptional Regulation of ILT Family Receptors

Nakajima

Asai

Okada

et al. 2003

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Ig-like transcripts (ILT/leukocyte Ig-like receptor/monocyte/macrophage Ig-like receptor or CD85) are encoded on human chromosome 19q13.4, designated the human leukocyte receptor complex, and are predominantly expressed on myeloid lineage cells. We investigated the transcriptional regulation of ILT1, ILT2, and ILT4 genes to elucidate control mechanisms operating on the specific expression of ILT receptors. Inhibitory ILT2 and ILT4 both have a similar genomic structure, in which the ∼160-bp 5′-flanking regions function as core promoters with critically important PU.1 binding sites. However, an Sp1 family-binding GC-box is more influential in trans-activation of ILT2 than ILT4. Additionally, ILT4 transcription is tightly regulated by chromatin modifications accompanied by histone acetylation, which strictly controls expression within myeloid lineage cells. Activating ILT1 carries a core promoter corresponding to the intronic region of ILT2 and ILT4, where PU.1 and Runx1 binding sites are essential, but a downstream heat shock element also augments promoter activity. Thus, each ILT is regulated by a distinct transcriptional mechanism, although PU.1 acts as a common trans-acting factor. We also found that human CMV infection strongly trans-activates inhibitory ILT2 and ILT4 genes through the expression of immediate-early proteins.

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Aki Okada

A more efficient method to generate integration-free human iPS cells

Variation in the safety of induced pluripotent stem cell lines

Derivation Conditions Impact X-Inactivation Status in Female Human Induced Pluripotent Stem Cells

Molecular basis of alanine discrimination in editing site

Transcriptional Regulation of ILT Family Receptors

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