Characterization of Constitutive Promoters for piggyBac Transposon-Mediated Stable Transgene Expression in Mesenchymal Stem Cells (MSCs)

Multipotent mesenchymal stem cells (MSCs) can undergo self-renewal and give rise to multi-lineages under given differentiation cues. It is frequently desirable to achieve a stable and high level of transgene expression in MSCs in order to elucidate possible molecular mechanisms through which MSC self-renewal and lineage commitment are regulated. Retroviral or lentiviral vector-mediated gene expression in MSCs usually decreases over time. Here, we choose to use the piggyBac transposon system and conduct a systematic comparison of six commonly-used constitutive promoters for their abilities to drive RFP or firefly luciferase expression in somatic HEK-293 cells and MSC iMEF cells. The analyzed promoters include three viral promoters (CMV, CMV-IVS, and SV40), one housekeeping gene promoter (UbC), and two composite promoters of viral and housekeeping gene promoters (hEFH and CAG-hEFH). CMV-derived promoters are shown to drive the highest transgene expression in HEK-293 cells, which is however significantly reduced in MSCs. Conversely, the composite promoter hEFH exhibits the highest transgene expression in MSCs whereas its promoter activity is modest in HEK-293 cells. The reduced transgene expression driven by CMV promoters in MSCs may be at least in part caused by DNA methylation, or to a lesser extent histone deacetlyation. However, the hEFH promoter is not significantly affected by these epigenetic modifications. Taken together, our results demonstrate that the hEFH composite promoter may be an ideal promoter to drive long-term and high level transgene expression using the piggyBac transposon vector in progenitor cells such as MSCs.     

Unstable expression of transgene is associated with the methylation of CAG promoter in the offspring from the same litter of homozygous transgenic mice

Transgenic animals have been established for studying gene function, improving animals’ production traits, and providing organ models for the exploration of human diseases. However, the stability of inheritance and transgene expression in transgenic animals has gained extensive attention. The unstable expression of transgene through DNA methyltransferase (DNMT) targeting to the methylation of transgenic DNA such as CAG promoter and Egfp coding region in homozygous transgenic animals is still unknown. In the present study, the offspring from the same litter of homozygous transgenic mice carrying ubiquitously expressed enhanced green fluorescence protein driven by CMV early enhancer/chicken β-actin (CAG) promoter was observed to have unstable expression of transgene Egfp, quantitative PCR, western blot and bisulfite sequencing were conducted to quantify the expressional characteristics and methylation levels in various tissues. The correlation between transgene expression and methylation was analyzed. We have found that transgene expression is dependent on the methylation of CAG promoter, but not Egfp coding region. We have also characterized the correlation between the methylation of CAG promoter and DNMT, and found that only Dnmt3b expression is correlated with the methylation of CAG promoter. In conclusion, Dnmt3b-related methylation of CAG promoter can inhibit the transgene expression and may result in the unstable expression of transgene in the offspring from the same litter of homozygous transgenic mice.     

Silencing of fat-1 transgene expression in sheep may result from hypermethylation of its driven cytomegalovirus (CMV) promoter

The fat-1 gene was isolated from roundworm Caenorhabditis elegans, and built into pIRES2-EGFP expression vectors driven by cytomegalovirus (CMV) promoter or cytomegalovirus enhancer and chickenβ-actin (CAG) promoter. Both CMV- and CAG-driven expression vectors were transfected to sheep fetal fibroblast cells. Positive transfected cells were used as donors for somatic cell nuclear transfer (SCNT) and the cloned embryos were transferred into the oviducts of synchronized recipient sheep. Two lambs derived from CMV vector and three lambs derived from CAG vector developed to term. Although Southern analyses using tissues from the two lambs derived from CMV vectors indicated integration of fat-1 gene into the genome, fat-1 mRNAs were not detected by RT-PCR. However, there was fat-1 expression (detected by RT-PCR) in tissues from transgenic lambs driven by CAG vectors. To investigate potential mechanisms involved in the two transgene models, methylation state of the vector promoters were examined. In CMV-driven transgenics, CMV promoters had almost no methylation in transfected cells and the resultant cloned embryos, whereas high methylations were detected in tissues and organs in transgenic lambs. In the CAG-driven transgenics, there were almost no methylations in transgenic cells and transgenic cloned embryos, and cloned lambs expressed fat-1 mRNA (detected by RT-PCR). Moreover, although SV40 promoters which drove neo/kan marker gene in CMV vectors were highly methylated in tissues from transgenic lambs, they were without methylation in cells and embryos. Therefore, we concluded that highly methylated CMV promoters induced the silence of fat-1 transgene expression in sheep. Furthermore, CAG promoter, but not CMV promoter was suitable for generation of fat-1 transgenic sheep.     

GUS expression driven by constitutive and phloem-specific promoters in citrus hybrid US-802

Transgenic solutions are being widely explored to develop huanglongbing (HLB) resistance in citrus. A critical component of a transgenic construct is the promoter, which determines tissue specificity and level of target gene expression. This study compares the characteristics of five promoters regulating the beta-glucuronidase (GUS) reporter gene in the trifoliate hybrid rootstock US-802. Two of the selected promoters direct high levels of constitutive transgene expression in other dicotyledonous plants: 2X35S, the tandem-repeat promoter of the cauliflower mosaic virus 35S gene and bul409S, a truncation of the potato polyubiquitin promoter. Because Candidatus Liberibacter, the Gram-negative bacterium associated with HLB, infects only the phloem tissue, it may be advantageous to limit transgene expression to the vascular tissue and reduce expression in the fruit. Thus, we also tested three promoters that demonstrate phloem specificity when transformed and expressed in other plants: WDV, from wheat dwarf geminivirus; AtSUC2, the sucrose-H+ symporter gene promoter from Arabidopsis; and CsSUS, the sucrose synthase promoter from citrus. Histochemical staining for GUS activity was observed throughout leaf and stem tissues for the constitutive promoters, while the three phloem-specific promoters largely showed the expected tissue-specific staining. Expression of GUS in some individual transformants with promoters CsSUS and WDV appeared leaky, with some laminar tissue staining. Relative quantification of qRT-PCR data revealed a wide range of mRNA abundance from transgenics with each of the five promoters. Fluorometry also revealed that GUS activity differed depending on the promoter used, but mRNA levels and enzyme activity were not highly correlated.     

The pEAQ vector series: the easy and quick way to produce recombinant proteins in plants

Promoter regions of six sugarcane Loading Stem Gene (ScLSG) alleles were analyzed using bioinformatic and transgenic approaches. Stable transgene expression analyses, on multiple independent lines per construct, revealed differences between ScLSG promoters in absolute levels and in tissue-selectivity of luciferase reporter activity. Four promoters drove peak expression in the sucrose-loading zone and maintained substantial expression throughout mature stems. One drove a pattern of gradual increase along the stem maturation profile. In general, stem: root expression ratio increased with plant age. The ScLSG5 promoter had the fewest light-enhanced and root-expression motifs in bioinformatic analysis, and drove the highest level and specificity of transgene expression in stems. This indicates the potential to further improve the stem specificity of ScLSG promoter sequences by eliminating enhancers of expression in other tissues. An intron in the 5′UTR was important for expression strength. The ScLSG promoters will be useful for research and biotechnology in sugarcane, where the tailored expression of transgenes in stems is important for enhanced accumulation of sugar or value-added products, and for development as a bioenergy feedstock.     

The T3(b) gene promoter directs intestinal epithelial cell-specific expression in transgenic mice

Although a few promoters that direct intestinal epithelial cell-specific expression in transgenic animals have been reported, they are not necessarily appropriate for transgenic studies in terms of activity and tissue specificity. Here, we examined the tissue specificity of transgene expression directed by the 2.8-kb promoter region of the T3(b) gene, which encodes one of the non-classical major histocompatibility complex class I molecules. The transgene was expressed exclusively in the epithelial cells of the small and large intestines at high levels. The results indicate that the T3(b) promoter is useful for directing transgene expression specifically in intestinal epithelial cells.     

Characterization of histone H2A.X expression in testis and specific labeling of germ cells at the commitment stage of meiosis with histone H2A.X promoter-enhanced green fluorescent protein transgene

To study the complex molecular mechanisms of mammalian spermatogenesis, it would be useful to be able to isolate cells at each stage of differentiation, especially at the stage in which the cells switch from mitosis to meiosis. Currently, no useful marker proteins or gene promoters specific to this important stage are known. We report here a transgenic mouse line that under the control of the promoter for a histone variant, H2A.X, expressed an enhanced green fluorescent protein (EGFP) in cells at the stage of the mitosis-meiosis switch. Endogenous H2A.X is expressed in type A spermatogonia through meiotic prophase spermatocytes in testis and in some somatic cells. However, despite the fact that its expression was driven by the H2A.X promoter, the EGFP expressed in the transgenic mice specifically labeled only the intermediate spermatogonia stage through the meiotic prophase spermatocyte stage in transgenic mice containing the -600-base pair H2A.X promoter/EGFP construct. Type A spermatogonia and somatic cells of other organs were not labeled. This expression pattern made it possible to isolate living cells from the testis of the transgenic mice at the stage of the mitosis-meiosis switch in spermatogenesis using EGFP fluorescence.     

Construction of Stress Responsive Synthetic Promoters and Analysis of Their Activity in Transgenic Arabidopsis thaliana

To obtain strong inducible promoters to drive abiotic stress-inducible transgene expression with minimal negative effects, we constructed three artificial synthetic promoters (EKCM, EKCRM, and ECCRM) comprising multiple cis-acting stress-response elements. Each promoter was fused independently to the β-glucuronidase (GUS) reporter gene, and GUS expression was analyzed in stable expression systems in Arabidopsis thaliana. T2 transgenic progenies showed integration of the promoter-GUS construct in their genome. RT-PCR assays and histochemical staining analysis showed that GUS expression driven by each promoter increased under desiccation, cold, and high salt conditions. The activity of synthetic promoters, assessed by fluorometric quantitative analysis of GUS enzyme activity, was significantly higher than that of the rd29A promoter under various stress treatments. The most powerful promoter, EKCM, allowed about 1.29-fold in GUS activity relative to the rd29A promoter, on average, under dehydration conditions. All three synthetic promoters could drive stress-inducible GUS expression in different organs of transgenic Arabidopsis. These synthetic promoters represent valuable tools for improving the stress tolerance of crops.     

Generation and characterization of transgenic zebrafish lines using different ubiquitous promoters

Two commonly used promoters to ubiquitously express transgenes in zebrafish are the Xenopus laevis elongation factor 1 α promoter (XlEef1a1) and the zebrafish histone variant H2A.F/Z (h2afv) promoter. Recently, transgenes utilizing these promoters were shown to be silenced in certain adult tissues, particularly the central nervous system. To overcome this limitation, we cloned the promoters of four zebrafish genes that likely are transcribed ubiquitously throughout development and into the adult. These four genes are the TATA box binding protein gene, the taube nuss-like gene, the eukaryotic elongation factor 1-gamma gene, and the beta-actin-1 gene. We PCR amplified approximately 2.5 kb upstream of the putative translational start site of each gene and cloned each into a Tol2 expression vector that contains the EGFP reporter transgene. We used these four Tol2 vectors to independently generate stable transgenic fish lines for analysis of transgene expression during development and in the adult. We demonstrated that all four promoters drive a very broad pattern of EGFP expression throughout development and the adult. Using the retina as a well-characterized component of the CNS, all four promoters appeared to drive EGFP expression in all neuronal and non-neuronal cells of the adult retina. In contrast, the h2afv promoter failed to express EGFP in the adult retina. When we examined EGFP expression in the various cells of the blood cell lineage, we observed that all four promoters exhibited a more heterogenous expression pattern than either the XlEef1a1 or h2afv promoters. While these four ubiquitous promoters did not express EGFP in all the adult blood cells, they did express EGFP throughout the CNS and in broader expression patterns in the adult than either the XlEef1a1 or h2afv promoters. For these reasons, these four promoters will be valuable tools for expressing transgenes in adult zebrafish.     

Pluripotent stem cells: Maintenance of genetic and epigenetic stability and prospects of cell technologies

Permanent lines of pluripotent stem cells can be obtained from humans and monkeys using different techniques and from different sources—inner cell mass of the blastocyst, primary germ cells, parthenogenetic oocytes, and mature spermatogonia—as well as by transgenic modification of various adult somatic cells. Despite different origin, all pluripotent lines demonstrate considerable similarity of the major biological properties: active self-renewal and differentiation into various somatic and germ cells in vitro and in vivo, similar gene expression profiles, and similar cell cycle structure. Ten years of intense studies on the stability of different human and monkey embryonic stem cells demonstrated that, irrespective of their origin, long-term in vitro cultures lead to the accumulation of chromosomal and gene mutations as well as epigenetic changes that can cause oncogenic transformation of cells. This review summarizes the research data on the genetic and epigenetic stability of different lines of pluripotent stem cells after long-term in vitro culture. These data were used to analyze possible factors of the genome and epigenome instability in pluripotent lines. The prospects of using pluripotent stem cells of different origin in cell therapy and pharmacological studies were considered.     

Plasmid vectors harboring cellular promoters can induce prolonged gene expression in hematopoietic and mesenchymal progenitor cells

Although prolonged transgene expression in progenitor cells might be desirable for modified cell therapy, the viral promoter-based expression vector tends to promote transgene expression only for a limited period. Here, we examined the ability of cellular promoters from elongation factor-1alpha (EF-1alpha) and ubiquitin C to drive gene expression in hematopoietic TF-1 and mesenchymal progenitor cells. We compared the expression levels and duration of a model gene, interleukin-2, generated by the cellular promoters to those by the cytomegalovirus (CMV) promoter. The EF-1alpha and ubiquitin C promoters drove prolonged gene expression in hematopoietic TF-1 and mesenchymal progenitor cells, whereas the CMV promoter did not. At day 7 after transfection in TF-1 cells, the mRNA expression levels of interleukin-2 driven by the EF-1alpha and ubiquitin C promoters were 118- and 56-fold higher, respectively, than those driven by the CMV promoter. Similarly, in mesenchymal progenitor cells, the expression levels of interleukin-2 driven by the EF-1alpha and ubiquitin C promoters were 98- and 20-fold higher, respectively, than that driven by the CMV promoter-encoding plasmid. Moreover, the ubiquitin C promoter directed higher levels of green fluorescence protein expression in mesenchymal progenitor cells than did the CMV promoter. These results indicate that the use of cellular promoters such as those for EF-1alpha and ubiquitin C might direct prolonged gene expression in hematopoietic and mesenchymal progenitor cells.     

Murine spermatogonial stem cells: targeted transgene expression and purification in an active state

A 400 bp fragment of the spermatogonia-specific Stra8 locus was sufficient to direct gene expression to the germinal stem cells in transgenic mice. A fractionation procedure was devised, based on immunomagnetic sorting of cells in which the promoter drives the expression of a surface functionally neutral protein tag. The purified cells expressed the known molecular markers of spermatogonia Rbm, cyclin A2 and EP-Cam, and the β₁- and α₆-integrins characteristic of the stem cell fraction. A 700-fold enrichment in stem cells was determined by the ability of the purified fractions to re-establish spermatogenesis in germ cell-depleted recipient testes.