Human Artificial Chromosome with a Conditional Centromere for Gene Delivery and Gene Expression

Human artificial chromosomes (HACs), which carry a fully functional centromere and are maintained as a single-copy episome, are not associated with random mutagenesis and offer greater control over expression of ectopic genes on the HAC. Recently, we generated a HAC with a conditional centromere, which includes the tetracycline operator (tet-O) sequence embedded in the alphoid DNA array. This conditional centromere can be inactivated, loss of the alphoid^tet-O (tet-O HAC) by expression of tet-repressor fusion proteins. In this report, we describe adaptation of the tet-O HAC vector for gene delivery and gene expression in human cells. A loxP cassette was inserted into the tet-O HAC by homologous recombination in chicken DT40 cells following a microcell-mediated chromosome transfer (MMCT). The tet-O HAC with the loxP cassette was then transferred into Chinese hamster ovary cells, and EGFP transgene was efficiently and accurately incorporated into the tet-O HAC vector. The EGFP transgene was stably expressed in human cells after transfer via MMCT. Because the transgenes inserted on the tet-O HAC can be eliminated from cells by HAC loss due to centromere inactivation, this HAC vector system provides important novel features and has potential applications for gene expression studies and gene therapy.     

A novel human artificial chromosome gene expression system using herpes simplex virus type 1 vectors

Human artificial chromosome (HAC) vectors are an important gene transfer system for expression and complementation studies. We describe a significant advance in HAC technology using infectious herpes simplex virus type 1 (HSV-1) amplicon vectors for delivery. This highly efficient method has allowed gene-expressing HACs to be established in glioma-, kidney- and lung-derived cells. We also developed an HSV-1 hypoxanthine phosphoribosyltransferase (HPRT) HAC vector, which generated functional HPRT-expressing HACs that complemented the genetic deficiency in human cells. The transduction efficiency of the HSV-1 HAC amplicons is several orders of magnitude higher than lipofection-mediated delivery. Studies on HAC stability between cell types showed important differences that have implications for HAC development and gene expression in human cells. This is the first report of establishing gene-expressing HACs in human cells by using an efficient, high-capacity viral vector and by identifying factors that are involved in cell-type-specific HAC instability. The work is a significant advance for HAC technology and the development of HAC gene expression systems in human cells.     

A novel transchromosomic system: stable maintenance of an engineered Mb-sized human genomic fragment translocated to a mouse chromosome terminal region

Transchromosomic (Tc) technology using human chromosome fragments (hCFs), or human artificial chromosomes (HACs), has been used for generating mice containing Mb-sized segments of the human genome. The most significant problem with freely segregating chromosomes with human centromeres has been mosaicism, possibly due to the instability of hCFs or HACs in mice. We report a system for the stable maintenance of Mb-sized human chromosomal fragments following translocation to mouse chromosome 10 (mChr.10). The approach utilizes microcell-mediated chromosome transfer and a combination of site-specific loxP insertion, telomere-directed chromosome truncation, and precise reciprocal translocation for the generation of Tc mice. Human chromosome 21 (hChr.21) was modified with a loxP site and truncated in homologous recombination-proficient chicken DT40 cells. Following transfer to mouse embryonic stem cells harboring a loxP site at the distal region of mChr.10, a ~4 Mb segment of hChr.21 was translocated to the distal region of mChr.10 by transient expression of Cre recombinase. The residual hChr.21/mChr.10ter fragment was reduced by antibiotic negative selection. Tc mice harboring the translocated ~4 Mb fragment were generated by chimera formation and germ line transmission. The hChr.21-derived Mb fragment was maintained stably in tissues in vivo and expression profiles of genes on hChr.21 were consistent with those seen in humans. Thus, Tc technology that enables translocation of human chromosomal regions onto host mouse chromosomes will be useful for studying in vivo functions of the human genome, and generating humanized model mice.     

Efficiency of de novo centromere formation in human artificial chromosomes

In a comparative study, we show that human artificial chromosome (HAC) vectors based on alpha-satellite (alphoid) DNA from chromosome 17 but not the Y chromosome regularly form HACs in HT1080 human cells. We constructed four structurally similar HAC vectors, two with chromosome 17 or Y alphoid DNA (17alpha, Yalpha) and two with 17alpha or Yalpha and the hypoxanthine guanine phosphoribosyltransferase locus (HPRT1). The 17alpha HAC vectors generated artificial minichromosomes in 32-79% of the HT1080 clones screened, compared with only approximately 4% for the Yalpha HAC vectors, indicating that Yalpha is inefficient at forming a de novo centromere. The 17alpha HAC vectors produced megabase-sized, circular HACs containing multiple copies of alphoid fragments (60-250 kb) interspersed with either vector or HPRT1 DNA.The 17alpha-HPRT1 HACs were less stable than those with 17alpha only, and these results may influence the design of new HAC gene transfer vectors.     

人类人工染色体构建及其作为基因治疗载体的价值

人类人工染色体(HAC)作为基因治疗载体将解决基因治疗存在的一些关键问题。本文探讨了在不完全了解着丝粒、复制起始点、端粒等人类染色体基本功能单位的情况下构建HAC的三种策略。利用染色体基本功能单位在细胞内构建成功的第一代HAC,解决了HAC构建的一些难题,同时也带来了某些新的问题。HAC作为基因治疗载体具有很多优势,但第一代HAC离它作为基因治疗载体还相距很远。为此,作者正在进行解决这些问题的尝试。     

Cloning of human centromeres by transformation-associated recombination in yeast and generation of functional human artificial chromosomes

Human centromeres remain poorly characterized regions of the human genome despite their importance for the maintenance of chromosomes. In part this is due to the difficulty of cloning of highly repetitive DNA fragments and distinguishing chromosome-specific clones in a genomic library. In this work we report the highly selective isolation of human centromeric DNA using transformation-associated recombination (TAR) cloning. A TAR vector with alphoid DNA monomers as targeting sequences was used to isolate large centromeric regions of human chromosomes 2, 5, 8, 11, 15, 19, 21 and 22 from human cells as well as monochromosomal hybrid cells. The alphoid DNA array was also isolated from the 12 Mb human mini-chromosome ΔYq74 that contained the minimum amount of alphoid DNA required for proper chromosome segregation. Preliminary results of the structural analyses of different centromeres are reported in this paper. The ability of the cloned human centromeric regions to support human artificial chromosome (HAC) formation was assessed by transfection into human HT1080 cells. Centromeric clones from ΔYq74 did not support the formation of HACs, indicating that the requirements for the existence of a functional centromere on an endogenous chromosome and those for forming a de novo centromere may be distinct. A construct with an alphoid DNA array from chromosome 22 with no detectable CENP-B motifs formed mitotically stable HACs in the absence of drug selection without detectable acquisition of host DNAs. In summary, our results demonstrated that TAR cloning is a useful tool for investigating human centromere organization and the structural requirements for formation of HAC vectors that might have a potential for therapeutic applications.     

Human artificial chromosomes constructed using the bottom-up strategy are stably maintained in mitosis and efficiently transmissible to progeny mice

Human artificial chromosomes (HACs) are alternative vectors that promise to overcome problematic transgene expression often occurring with conventional vectors in mammalian cells and bodies. We have successfully generated HACs by multimerization of a cloned long alphoid stretch in a human cell line, HT1080. Furthermore, we developed technologies for cloning large genomic regions into HACs by means of co-transfection of clones with the alphoid array and clones encoding the genomic region of interest. The purpose of this study was to investigate the mitotic and meiotic stability of such HACs in mouse cells and bodies. We transferred a circular HAC containing the guanosine triphosphate cyclohydrolase I gene (GCH1-HAC) and a linear HAC containing the human globin gene cluster (globin-HAC) from HT1080 cells into mouse embryonic stem (ES) cells by microcell-mediated chromosome transfer. The HACs were stably maintained in mouse ES cells for 3 months. GCH1-HACs in every ES cell line and globin-HACs in most ES cell lines maintained their structures without detectable rearrangement or acquisition of mouse genomic DNA except one globin-HAC in an ES cell line rearranged and acquired mouse-type centromeric sequences and long telomeres. Creation of chimeric mice using ES cells containing HAC and subsequent crossing showed that both the globin-HAC that had rearranged and acquired mouse type centromeric sequences/long telomeres and GCH1-HACs were retained in tissues of mice and transmitted to progeny. These results indicate that human artificial chromosomes constructed using the bottom-up strategy based on alphoid DNA are stable in mouse bodies and are transmissible.     

Heat-regulated production and secretion of insulin from a human artificial chromosome vector

Human artificial chromosomes (HACs) behave as independent minichromosomes and are potentially useful as a way to achieve safe, long-term expression of a transgene. In this study, we sought to elucidate the potential of HAC vectors carrying the human proinsulin transgene for gene therapy of insulin-dependent diabetes mellitus (IDDM) using non-beta-cells as a host for the vector. To facilitate the production of mature insulin in non-beta-cells and to safely regulate the level of transgene expression, we introduced furin-cleavable sites into the proinsulin coding region and utilized the heat shock protein 70 (Hsp70) promoter. We used Cre-loxP-mediated recombination to introduce the gene cassettes onto 21DeltapqHAC, a HAC vector whose structure is completely defined, present in human fibrosarcoma HT1080 cells. We observed long-term expression and stable retention of the transgene without aberrant translocation of the HAC constructs. As expected, the Hsp70 promoter allowed us to regulate gene expression with temperature, and the production and secretion of intermediates of mature insulin were made possible by the furin-cleavable sites we had introduced into proinsulin. This study can be an initial step on the application of HAC vectors on the gene delivery to non-beta-cells, which might provide a direction for future treatment for diabetes.     

Functional Complementation of a Genetic Deficiency with Human Artificial Chromosomes

We have shown functional complementation of a genetic deficiency in human cultured cells, using artificial chromosomes derived from cloned human genomic fragments. A 404-kb human-artificial-chromosome (HAC) vector, consisting of 220 kb of alphoid DNA from the centromere of chromosome 17, human telomeres, and the hypoxanthine guanine phosphoribosyltransferase (HPRT) genomic locus, was transferred to HPRT-deficient HT1080 fibrosarcoma cells. We generated several cell lines with low-copy-number, megabase-sized HACs containing a functional centromere and one or possibly several copies of the HPRT1 gene complementing the metabolic deficiency. The HACs consisted of alternating alphoid and nonalphoid DNA segments derived only from the input DNA (within the sensitivity limits of FISH detection), and the largest continuous alphoid segment was 158-250 kb. The study of both the structure and mitotic stability of these HACs offers insights into the mechanisms of centromere formation in synthetic chromosomes and will further the development of this human-gene-transfer technology.     

Generation of a conditionally self-eliminating HAC gene delivery vector through incorporation of a tTAVP64 expression cassette

Human artificial chromosome (HAC)-based vectors represent an alternative technology for gene delivery and expression with a potential to overcome the problems caused by virus-based vectors. The recently developed alphoid^tetO-HAC has an advantage over other HAC vectors because it can be easily eliminated from cells by inactivation of the HAC kinetochore via binding of chromatin modifiers, tTA or tTS, to its centromeric tetO sequences. This provides a unique control for phenotypes induced by genes loaded into the HAC. The alphoid^tetO-HAC elimination is highly efficient when a high level of chromatin modifiers as tetR fusion proteins is achieved following transfection of cells by a retrovirus vector. However, such vectors are potentially mutagenic and might want to be avoided under some circumstances. Here, we describe a novel system that allows verification of phenotypic changes attributed to expression of genes from the HAC without a transfection step. We demonstrated that a single copy of tTA^VP64 carrying four tandem repeats of the VP16 domain constitutively expressed from the HAC is capable to generate chromatin changes in the HAC kinetochore that are not compatible with its function. To adopt the alphoid^tetO-HAC for routine gene function studies, we constructed a new TAR-BRV- tTA^VP64 cloning vector that allows a selective isolation of a gene of interest from genomic DNA in yeast followed by its direct transfer to bacterial cells and subsequent loading into the loxP site of the alphoid^tetO-HAC in hamster CHO cells from where the HAC may be MMCT-transferred to the recipient human cells.     

An artificially constructed de novo human chromosome behaves almost identically to its natural counterpart during metaphase and anaphase in living cells

Human artificial chromosomes (HACs) are promising reagents for the analysis of chromosome function. While HACs are maintained stably, the segregation mechanisms of HACs have not been investigated in detail. To analyze HACs in living cells, we integrated 256 copies of the Lac operator into a precursor yeast artificial chromosome (YAC) containing alpha-satellite DNA and generated green fluorescent protein (GFP)-tagged HACs in HT1080 cells expressing a GFP-Lac repressor fusion protein. Time-lapse analyses of GFP-HACs and host centromeres in living mitotic cells indicated that the HAC was properly aligned at the spindle midzone and that sister chromatids of the HAC separated with the same timing as host chromosomes and moved to the spindle poles with mobility similar to that of the host centromeres. These results indicate that a HAC composed of a multimer of input alpha-satellite YACs retains most of the functions of the centromeres on natural chromosomes. The only difference between the HAC and the host chromosome was that the HAC oscillated more frequently, at higher velocity, across the spindle midzone during metaphase. However, this provides important evidence that an individual HAC has the capacity to maintain tensional balance in the pole-to-pole direction, thereby stabilizing its position around the spindle midzone.     

Advances in human artificial chromosome technology

Human artificial chromosome (HAC) technology has developed rapidly over the past four years. Recent reports show that HACs are useful gene transfer vectors in expression studies and important tools for determining human chromosome function. HACs have been used to complement gene deficiencies in human cultured cells by transfer of large genomic loci also containing the regulatory elements for appropriate expression. And, they now offer the possibility to express large human transgenes in animals, especially in mouse models of human genetic diseases.     

Artificial chromosome vectors and expression of complex proteins in transgenic animals

Artificial chromosome vectors are autonomous, replicating DNA sequences containing a centromere, two telomeres and origins of replication. Artificial chromosomes have been proposed as possible vectors for transferring very large sequences of DNA into animals. Our goal has been to insert the entire human heavy- and light-chain immunoglobulin loci into cattle as a step in developing a production system for large quantities of human therapeutic polyclonal antibodies. A mitotically stable fragment of chromosome 14, containing the human heavy-chain locus, was identified. A chromosome cloning system was used to transfer the human lambda locus from an unstable chromosome 22 fragment to the chromosome 14 fragment to create a human artificial chromosome (HAC) carrying both immunoglobulin loci. The HAC vector was introduced into bovine primary fibroblasts. Selected fibroblast clones were rejuvenated and expanded by producing cloned fetuses. Cloned fetal cells were selected and recloned to produce 21 healthy, transchromosomic (Tc) calves. Four were analyzed and shown to functionally rearrange both heavy- and light-chain human immunoglobulin loci and produce human polyclonal antibodies. These results demonstrate the feasibility of using HAC vectors for production of transgenic livestock. More importantly, Tc cattle containing human immunoglobulin genes may be used to produce novel human polyclonal therapeutics.     

Antigen-mediated growth control of hybridoma cells via a human artificial chromosome

Human artificial chromosome (HAC) vectors possess several characteristics sufficient for the requirements of gene therapy vectors, including stable episomal maintenance and mediation of long-term transgene expression. In this study, we adopted an antigen-mediated genetically modified cell amplification (AMEGA) system employing an antibody/cytokine receptor chimera that triggers a growth signal in response to a cognate non-toxic antigen, and applied it to growth control of HAC-transferred cells by adding an antigen that differed from cytokines that may manifest pleiotropic effects. We previously constructed a novel HAC vector, 21 Delta qHAC, derived from human chromosome 21, housed in CHO cells. Here, we constructed an HAC vector harboring an ScFv-gp130 chimera responsive to fluorescein-conjugated BSA (BSA-FL) as well as a model transgene, enhanced green fluorescent protein (EGFP), in CHO cells. The modified HAC was transferred into interleukin (IL)-6-dependent hybridoma 7TD1 cells by microcell-mediated chromosome transfer, and the cells were subsequently found to show BSA-FL-dependent cell growth and sustained expression of EGFP in the absence of IL-6. The AMEGA system in combination with HAC technology will be useful for increasing the efficacy of gene therapy by conferring a growth advantage on the genetically modified cells.     

A Novel System for Simultaneous or Sequential Integration of Multiple Gene-Loading Vectors into a Defined Site of a Human Artificial Chromosome

Human artificial chromosomes (HACs) are gene-delivery vectors suitable for introducing large DNA fragments into mammalian cells. Although a HAC theoretically incorporates multiple gene expression cassettes of unlimited DNA size, its application has been limited because the conventional gene-loading system accepts only one gene-loading vector (GLV) into a HAC. We report a novel method for the simultaneous or sequential integration of multiple GLVs into a HAC vector (designated as the SIM system) via combined usage of Cre, FLP, Bxb1, and φC31 recombinase/integrase. As a proof of principle, we first attempted simultaneous integration of three GLVs encoding EGFP, Venus, and TdTomato into a gene-loading site of a HAC in CHO cells. These cells successfully expressed all three fluorescent proteins. Furthermore, microcell-mediated transfer of HACs enabled the expression of those fluorescent proteins in recipient cells. We next demonstrated that GLVs could be introduced into a HAC one-by-one via reciprocal usage of recombinase/integrase. Lastly, we introduced a fourth GLV into a HAC after simultaneous integration of three GLVs by FLP-mediated DNA recombination. The SIM system expands the applicability of HAC vectors and is useful for various biomedical studies, including cell reprogramming.     

Human artificial chromosomes containing chromosome 17 alphoid DNA maintain an active centromere in murine cells but are not stable

Human artificial chromosomes (HACs) are autonomous molecules that can function and segregate as normal chromosomes in human cells. De novo HACs have successfully been used as gene expression vectors to complement genetic deficiencies in human cultured cells. HACs now offer the possibility of studying the regulation and expression of large genes in a variety of cell types from different tissues and correcting gene deficiencies caused by human inherited diseases. Complementary gene expression studies in mice, especially in mouse models of human genetic diseases, are also important in determining if large human transgenes can be expressed appropriately from artificial chromosomes. Toward this aim we are establishing artificial chromosomes in murine cells as novel gene expression vectors. Initially we transferred HAC vectors into murine cells, but were unable to generate de novo HACs at a reasonable frequency. We then transferred HACs previously established in human HT1080 cells to three different murine cell types by microcell fusion, followed by positive selection. We observed that the HACs in murine cells bound centromere protein C (CENP-C), a marker of active centromeres, and were detected under selection but rapidly lost when selection was removed. These results suggest that the HACs maintain at least a partially functional centromere complex in murine cells, but other factors are required for stability and segregation. Artificial chromosomes containing mouse centromeric sequences may be required for better stability and maintenance in murine cells.     

Construction of a novel expression system on a human artificial chromosome

Efficient regulation of transgene would greatly facilitate the analysis of gene function in biological systems for basic research and clinical applications. The tetracycline-regulatable system (TRS) has proven to be a promising tool for such purposes. Despite their widespread application, a number of challenges are still associated with the use of TRS, including clonal variability in the regulation and copy number. We have recently constructed a novel human artificial chromosome (HAC) called 21DeltaqHAC. By housing a TRS-based DNA-PKcs expression cassette in this HAC, we were able to circumvent the problems associated with conventional TRS-based vectors. We achieved tight control of DNA-PKcs expression and rescued the radiosensitive phenotype of DNA-PKcs-deficient CHO cells. The combined use of HAC and the TRS serves as a model for controllable and fixed copy number expression vectors. Our study also demonstrates the suitability of the HAC to accommodate multi-subunit constructs such as that of the TRS.     

产生人抗体的转染色体动物研究进展

现已证明,应用抗体治疗疾病是一种非常成功的方法。单克隆抗体的生产使免疫治疗达到一个新水平,但鼠源单抗在治疗人体疾病方面有很多问题,而人源化抗体可以解决这些问题。目前抗体人源化已由鼠嵌合抗体发展到了转基因动物表达完全人抗体阶段,而人类人工染色体(HAC)载体的发展和微细胞介导的转染色体技术使得产生携带人类免疫球蛋白基因位点的转染色体动物成为可能。通过HAC将人的免疫球蛋白基因转入后,这类转染色体动物可以产生大量人源化多克隆抗体,这对预防及治疗疾病,甚至防御生物武器都有很重要的作用。转染色体技术可以使动物携带大而复杂的人类基因或基因簇,这些转基因动物有助于研究人类基因组在体内的功能作用,并用于各种疾病研究和生产药物蛋白。     

A novel mouse model for Down syndrome that harbor a single copy of human artificial chromosome (HAC) carrying a limited number of genes from human chromosome 21

Down syndrome (DS), also known as Trisomy 21, is the most common chromosome aneuploidy in live-born children and displays a complicated symptom. To date, several kinds of mouse models have been generated to understand the molecular pathology of DS, yet the gene dosage effects and gene(s)-phenotype(s) correlation are not well understood. In this study, we established a novel method to generate a partial trisomy mice using the mouse ES cells that harbor a single copy of human artificial chromosome (HAC), into which a small human DNA segment containing human chromosome 21 genes cloned in a bacterial artificial chromosome (BAC) was recombined. The produced mice were found to maintain the HAC carrying human genes as a mini-chromosome, hence termed as a Trans-Mini-Chromosomal (TMC) mouse, and HAC was transmitted for more than twenty generations independent from endogenous mouse chromosomes. The three human transgenes including cystathionine β-synthase, U2 auxiliary factor and crystalline alpha A were expressed in several mouse tissues with various expression levels relative to mouse endogenous genes. The novel system is applicable to any of human and/or mouse BAC clones. Thus, the TMC mouse carrying a HAC with a limited number of genes would provide a novel tool for studying gene dosage effects involved in the DS molecular pathogenesis and the gene(s)-phenotype(s) correlation.