c-Src-induced activation of ceramide metabolism impairs membrane microdomains and promotes malignant progression by facilitating the translocation of c-Src to focal adhesions.

The proto-oncogenic tyrosine kinase c-Src is up-regulated in various human cancers, implicating its role in tumour progression. Upon activation, c-Src translocates to focal adhesions and initiates intracellular signalling cascades that promote malignant transformation, but the underlying mechanisms for c-Src translocation remain unclear. In the present study we show that c-Src up-regulation perturbs sphingolipid/cholesterol-enriched membrane microdomains by activating ceramide synthesis, resulting in promotion of c-Src translocation. Using an inducible c-Src expression system in Csk (C-terminal Src kinase)-deficient fibroblasts, we found that translocation of c-Src to focal adhesions/podosomes occurs in the later stages of cell transformation. Activated c-Src is liberated from microdomains and promotes the phosphorylation of FAK (focal adhesion kinase) and cortactin localized to focal adhesions/podosomes. In parallel with these events, anabolic metabolism of ceramides is activated by up-regulation of the de novo synthesis pathway. Inhibition of ceramide conversion into glucosylceramide promotes liberation of c-Src from microdomains, and inhibition of de novo ceramide synthesis restores the microdomain distribution of c-Src and suppresses malignant phenotypes such as increased cell motility and anchorage-independent cell growth. These results suggest that c-Src-induced activation of ceramide synthesis impairs the integrity of microdomains and contributes to malignant progression by promoting the translocation of c-Src to focal adhesions/podosomes.

Cohesin mediates transcriptional insulation by CCCTC-binding factor.

Cohesin complexes mediate sister-chromatid cohesion in dividing cells but may also contribute to gene regulation in postmitotic cells. How cohesin regulates gene expression is not known. Here we describe cohesin-binding sites in the human genome and show that most of these are associated with the CCCTC-binding factor (CTCF), a zinc-finger protein required for transcriptional insulation. CTCF is dispensable for cohesin loading onto DNA, but is needed to enrich cohesin at specific binding sites. Cohesin enables CTCF to insulate promoters from distant enhancers and controls transcription at the H19/IGF2 (insulin-like growth factor 2) locus. This role of cohesin seems to be independent of its role in cohesion. We propose that cohesin functions as a transcriptional insulator, and speculate that subtle deficiencies in this function contribute to 'cohesinopathies' such as Cornelia de Lange syndrome.

Generation of iPS cells using a BacMam multigene expression system.

Generation of iPS cells from mouse embryonic fibroblasts (MEF) was achieved using a BacMam transduction system containing a polycistronic plasmid expression vector for coincident and optimized expression of four defined reprogramming transcription factors. The sequences for Oct4, Klf4, Sox2 and c-Myc, were cloned as a fusion gene (OKSM) in a single open reading frame (ORF) via self-cleaving 2A peptides and expressed under the control of the CAG promoter. The transduction efficiency of primary MEF cells with BacMam particles carrying CAG-directed Venus reporter gene is 64-98%. After three successive transductions (at intervals of 3 days) of MEF cells with BacMam particles carrying a OKSM or OSKM cassette, the iPS cell colonies are observed in 15-24 days. A single transduction of MEF cells is also effective in generating sufficiently reprogrammed iPS cell lines. The iPS cell lines from colonies picked were positively stained by Nanog, SSEA-1 immunofluorescence and alkaline phosphatase substrate markers. The advantage of using the EOS-S(4+)-EmGFP reporter to identify sufficiently reprogrammed iPS cell lines is discussed by representing experimental results obtained with electroporated plasmids, such as a mixture of 2 tandem OS and KM plasmids and a polycistronic OKSM expression plasmid.

Human protein factory for converting the transcriptome into an in vitro-expressed proteome,.

Appropriate resources and expression technology necessary for human proteomics on a whole-proteome scale are being developed. We prepared a foundation for simple and efficient production of human proteins using the versatile Gateway vector system. We generated 33,275 human Gateway entry clones for protein synthesis, developed mRNA expression protocols for them and improved the wheat germ cell-free protein synthesis system. We applied this protein expression system to the in vitro expression of 13,364 human proteins and assessed their biological activity in two functional categories. Of the 75 tested phosphatases, 58 (77%) showed biological activity. Several cytokines containing disulfide bonds were produced in an active form in a nonreducing wheat germ cell-free expression system. We also manufactured protein microarrays by direct printing of unpurified in vitro-synthesized proteins and demonstrated their utility. Our 'human protein factory' infrastructure includes the resources and expression technology for in vitro proteome research.

Simultaneous single cell stable expression of 2-4 cDNAs in HeLaS3 using psiC31 integrase system.

An important consideration in the design of multigene delivery technology is the availability of suitable vectors to introduce multiple genes stably and stoichiometrically into living cells and co-express these genes efficiently. As a promising system for this purpose, we developed multi-cDNA expression constructs harboring two to three tandemly situated cDNAs in a single plasmid. The utility of this vector system is amplified by combining it with the psiC31 recombinase system which mediates site-specific integration of the genes into naturally occurring chromosomal sequences. By analyzing 55 psiC31-mediated integration events with five different constructs, each carrying one, two or three tandem cDNA expression cassettes, we identified 39 pseudo attP sites in the HeLaS3 chromosomes. All these sites share a common motif containing an inverted repeat and showing a similarity to the native psiC31 attP. The 36 integration events represented 27 different pseudo attP sites, suggesting the possibility of duplicate integration of the multigene expression plasmids into different genomic loci in a single cell. We demonstrated successive introduction of two different multi-cDNA expression plasmids into definite chromosomal pseudo attP sites, attaining integration of four cDNAs of known genomic constitution at precise genomic loci of a single HeLaS3 cell. The expression levels of these several transgenes were enhanced and made equally stable and robust by inserting the cHS4 insulator between genes.

Multi-gene gateway clone design for expression of multiple heterologous genes in living cells: modular construction of multiple cDNA expression elements using recombinant cloning.

Much attention has been focused on manipulating multiple genes in living cells for analyzing protein function. In order to perform high-throughput generation of multi-gene expression clones, gateway cloning technology (which represents a high-throughput DNA transfer from vector to vector) can be anticipated. In the conventional strategy for gateway cloning, the construction of two or more expression elements into tandem elements on a single plasmid requires the recombination of multiple entry clones with a destination vector in a single reaction mixture. Use of increasing numbers of entry clones in a single reaction is inefficient due to the difficulty in successfully recognizing multiple pairs of matched att signals simultaneously. To address this problem, a "Modular Destination" vector has been devised and constructed, whereby cDNA inserts are sequentially introduced, resulting in a tandem structure with multiple inserts. Whereas the standard destination vector contains only Cm(R) and ccdB genes flanked by two attR signals, this destination vector contains, in addition, one or two cDNA expression elements. Here, we show the rapid construction of expression vectors containing three or four tandemly arrayed cDNA expression elements and their expression in mammalian cells.

Multi-gene gateway clone design for expression of multiple heterologous genes in living cells: eukaryotic clones containing two and three ORF multi-gene cassettes expressed from a single promoter.

Two types of eukaryotic operon-type Expression clones were constructed using the Multisite Gateway system employing six types of att signals. These clones harbored a DNA cassette containing two heterologous ORFs (cDNAs) or three heterologous ORFs in tandem downstream of a single promoter. The most promoter-proximal ORF was translated via a Kozak signal and the downstream one or two ORF(s) were translated as directed by internal ribosome entry site(s) (IRES). These clones were observed to produce two or three different proteins at levels that depended on the activities of the translational initiation signals used. With the intention of modulating the expression level of the first ORF, the translational initiation signals including a Kozak sequence and 11 different IRESs were investigated for their efficiency using a single ORF. The translational activity of these signals varied within a 10-fold magnitude. Using these results, expression at pre-described relative levels was achieved from the optional IRES of the respective ORFs in the cassette. Controllable expression at desired levels of two different ORFs directed by optional IRESs on a bicistronic construct, transcribed from a single promoter, was demonstrated.

Two distinct human POM121 genes: requirement for the formation of nuclear pore complexes.

Pom121 is one of the integral membrane components of the nuclear pore complex (NPC) in vertebrate cells. Unlike rodent cells carrying a single POM121 gene, human cells possess multiple POM121 gene loci on chromosome 7q11.23, as a consequence of complex segmental-duplications in this region during human evolution. In HeLa cells, two "full-length" Pom121 are transcribed and translated by two distinct genetic loci. RNAi experiments showed that efficient depletion of both Pom121 proteins significantly reduces assembled NPCs on nuclear envelope. Pom121-depletion also induced clustering of NPCs, indicating its role on maintenance of NPC structure/organization.

Multi-gene gateway clone design for expression of multiple heterologous genes in living cells: conditional gene expression at near physiological levels.

Using Multisite Gateway five-DNA-fragment constructs vectors that enable expression of two tandemly situated cDNAs on a single plasmid were developed. Heterologous protein production in cells was achieved by modulating respective cDNA expression to pre-determined and different levels. Optimization of cDNA expression at near physiological protein levels was achieved using promoters from four cell cycle-dependent genes. In comparison with conventionally available promoters, EF-1alpha or CMV, the promoters used in this study were able to modulate cDNA expression levels over a magnitude of approximately 10 or 100-fold, respectively. In transiently transfected cells, two different proteins (CPalpha1 and CPbeta2), which form a heterodimer, each labeled with a different-colored fluorescent protein, were successfully synthesized at pre-determined levels from their respective cDNAs. The above vectors were designed to contain an FRT/Flp recombination site for integration onto chromosomes and for establishment of stable clones in HeLa cells by site-specific recombination. In the stable transformant cells produced only about 4% of the protein production levels measured in the transiently transformed cells. The biological significance of these observations is discussed.

Evidence for high specificity and efficiency of multiple recombination signals in mixed DNA cloning by the Multisite Gateway system.

Six types of recombination signal DNA sequences of the Multisite Gateway cloning system were investigated as to their specificity and efficiency in the LR and BP recombination reactions. In the LR reaction to generate an Expression clone by recombination between attL and attR signals which are contained in the Entry clone and the Destination vector, respectively, the cross-reactivity of various attL and attR pairs on six types of respective signal sequences was examined. In the BP reaction to create an Entry clone by transferring the target DNA segment in the Expression clone or the attB-flanked PCR product into a Donor vector, various combinations of attB and attP pairs were tested for their reactivities in recombination. The results obtained indicate a markedly higher specificity and efficiency of cross-reactivity with only the matched att signal pairs, such as attL3-attR3, attB5-attP5, and so on, compared to unmatched signal pairs, such as attL3-attR5, attB5-attP3, and so on, thus verifying a high-throughput production of the positive clones in the Gateway system in which multiple recombination signals exist together in one reaction system. Examples of rapid construction of a three or four DNA-fusion structure in the plasmid are shown.

Methods for constructing clones for protein expression in mammalian cells.

Multisite Gateway technology is a DNA cloning method based on in vitro site-specific recombination that is becoming increasingly popular because it allows quick and highly efficient assembly of multiple DNA fragments into a vector backbone. In the conventional Gateway Multisite strategy, cloning of multiple DNA fragments requires recombination of multiple entry clones with a single destination vector. The -limitation of this approach is that as the number of entry clones increases, the efficiency of the assembly reactions decreases due to difficulty in successfully recognizing multiple pairs of matched att signals simultaneously. To address this problem, we have devised methods to generate modular expression clones, modular entry clones, and modular destination vectors. These allow many DNA fragments to be -assembled stepwise into complex expression clones. We describe here how to construct these intermediate clones and vectors, and how to use these modules to construct expression clones comprising ten or more DNA -segments. These principles can be applied to make multicomponent DNAs for many applications.

The LC3 recruitment mechanism is separate from Atg9L1-dependent membrane formation in the autophagic response against Salmonella.

Salmonella develops into resident bacteria in epithelial cells, and the autophagic machinery (Atg) is thought to play an important role in this process. In this paper, we show that an autophagosome-like double-membrane structure surrounds the Salmonella still residing within the Salmonella-containing vacuole (SCV). This double membrane is defective in Atg9L1- and FAK family-interacting protein of 200 kDa (FIP200)-deficient cells. Atg9L1 and FIP200 are important for autophagy-specific recruitment of the phosphatidylinositol 3-kinase (PI3K) complex. However, in the absence of Atg9L1, FIP200, and the PI3K complex, LC3 and its E3-like enzyme, the Atg16L complex, are still recruited to Salmonella. We propose that the LC3 system is recruited through a mechanism that is independent of isolation membrane generation.

Nuclear pore formation but not nuclear growth is governed by cyclin-dependent kinases (Cdks) during interphase.

Nuclear volume and the number of nuclear pore complexes (NPCs) on the nucleus almost double during interphase in dividing cells. How these events are coordinated with the cell cycle is poorly understood, particularly in mammalian cells. We report here, based on newly developed techniques for visualizing NPC formation, that cyclin-dependent kinases (Cdks), especially Cdk1 and Cdk2, promote interphase NPC formation in human dividing cells. Cdks seem to drive an early step of NPC formation because Cdk inhibition suppressed generation of 'nascent pores', which we argue are immature NPCs under the formation process. Consistent with this, Cdk inhibition disturbed proper expression and localization of some nucleoporins, including Elys/Mel-28, which triggers postmitotic NPC assembly. Strikingly, Cdk suppression did not notably affect nuclear growth, suggesting that interphase NPC formation and nuclear growth have distinct regulation mechanisms.

Importin-beta and the small guanosine triphosphatase Ran mediate chromosome loading of the human chromokinesin Kid.

Nucleocytoplasmic transport factors mediate various cellular processes, including nuclear transport, spindle assembly, and nuclear envelope/pore formation. In this paper, we identify the chromokinesin human kinesin-like DNA binding protein (hKid) as an import cargo of the importin-alpha/beta transport pathway and determine its nuclear localization signals (NLSs). Upon the loss of its functional NLSs, hKid exhibited reduced interactions with the mitotic chromosomes of living cells. In digitonin-permeabilized mitotic cells, hKid was bound only to the spindle and not to the chromosomes themselves. Surprisingly, hKid bound to importin-alpha/beta was efficiently targeted to mitotic chromosomes. The addition of Ran-guanosine diphosphate and an energy source, which generates Ran-guanosine triphosphate (GTP) locally at mitotic chromosomes, enhanced the importin-beta-mediated chromosome loading of hKid. Our results indicate that the association of importin-beta and -alpha with hKid triggers the initial targeting of hKid to mitotic chromosomes and that local Ran-GTP-mediated cargo release promotes the accumulation of hKid on chromosomes. Thus, this study demonstrates a novel nucleocytoplasmic transport factor-mediated mechanism for targeting proteins to mitotic chromosomes.

cHS4 insulator-mediated alleviation of promoter interference during cell-based expression of tandemly associated transgenes.

Expression of multiple transgenes in cells or whole organisms is a powerful tool for basic research of various biological functions and potentially for clinical applications such as gene therapy. As a model system for this purpose, multi-cDNA expression clones were constructed harboring two tandemly situated fluorescent protein cDNAs as reporter genes on a single plasmid. When 293 cells were transfected transiently, the downstream gene displayed significantly lower expression when compared with the upstream cDNA. Such transcriptional interference was markedly alleviated by inserting an insulator cassette of cHS4 elements derived from the chicken beta-globin locus at a site between two neighboring cDNAs. The introduction of cHS4 resulted in a drastic increase of the expression level of the downstream cDNA, ensuring comparable expression levels of the tandem transgenes. Using a chromatin immunoprecipitation assay, we demonstrated that CTCF and USF1 that recruit histone-modifying complexes are bound to the cHS4 region. Depletion of CTCF or USF1 by siRNA resulted in relief of the diminished effect. Our data thus indicate that CTCF and histone modifiers recruited by USF1 cooperatively mediate the suppression of transcriptional interference between apposed genes, presumably by facilitating active chromatin conformation over the transgenes.

Cell-cycle-dependent dynamics of nuclear pores: pore-free islands and lamins.

Nuclear pores are sophisticated gateways on the nuclear envelope that control macromolecular transport between the cytoplasm and nucleoplasm. So far the structural and functional aspects of nuclear pores have been extensively studied, but their distribution and density, which might reflect nuclear organization and function, remain unknown. Here, we report the cell-cycle-dependent dynamics of nuclear pores. Large distinct subdomains lacking nuclear pores are present on the nuclear surface of HeLaS3 cells in early cell-cycle stages. Such ;pore-free islands' gradually become dispersed in G1-S phase. Surprisingly, the islands are enriched with inner nuclear membrane proteins lamin A/C and emerin, but exclude lamin B. Lamin-A/C-enriched pore-free islands were also observed in human normal diploid fibroblasts and several cell lines, showing the generality of this phenomenon. Knockdown and ectopic expression analyses demonstrated that lamin A/C, but not emerin, plays an essential structural and regulatory role in the nuclear pore distribution and the formation of pore-free islands. These data thus provide strong evidence that the dynamics of nuclear pores are regulated by the reorganization of inner nuclear structures.