Trophoblast-specific gene manipulation using lentivirus-based vectors

The trophoblast layers of the mammalian placenta carry out many complex functions required to pattern the developing embryo and maintain its growth and survival in the uterine environment. Genetic disruption of many gene pathways can result in embryonic lethality because of placental failure, potentially confusing the interpretation of mouse knockout phenotypes. Development of tools to specifically and efficiently manipulate gene expression in the trophoblast lineage would greatly aid understanding of the relative roles of different genetic pathways in the trophoblast versus embryonic lineages. We show that short-term lentivirus-mediated infection of mouse blastocysts can lead to rapid expression of a green fluorescent protein (GFP) transgene specifically in the outer trophoblast progenitors and their later placental derivatives. Efficient trophoblast-specific gene knockdown can also be produced by lentivirus-mediated pol III-driven short hairpin RNA (shRNA) and efficient trophoblast-specific gene knockout by pol II-driven Cre recombinase lentiviral vectors. This lentivirus lineage-specific infection system thus facilitates both gain and loss of function studies during placental development in the mouse and potentially other mammalian species.     

Genetic manipulation of schistosomes

In contrast to the situations with model organisms and parasitic protozoa, progress with gene manipulation with schistosomes has been delayed by impediments that include our inability to maintain the life cycle in vitro, absence of immortalized cell lines, large genome sizes, unavailability of drug resistance markers and other difficulties. However, in the past few years, tangible progress has been reported towards development of tools for gene manipulation and transgenesis of schistosomes, and there is reason to believe that the field is on the verge of transformation into an era where genetic manipulation is routine. Recent reports dealing with approaches and tools to manipulate the genome and gene expression in schistosomes are reviewed here.     

Genetic manipulation of glycine decarboxylation

The glycine-serine interconversion, catalysed by glycine decarboxylase and serine hydroxymethyltransferase, is an important reaction of primary metabolism in all organisms including plants, by providing one-carbon units for many biosynthetic reactions. In plants, in addition, it is an integral part of the photorespiratory metabolic pathway and produces large amounts of photorespiratory CO(2) within mitochondria. Although controversial, there is significant evidence that this process, by the relocation of glycine decarboxylase within the leaves from the mesophyll to the bundle-sheath, contributed to the evolution of C(4) photosynthesis. In this review, some aspects of current knowledge about glycine decarboxylase and serine hydroxymethyltransferase and the role of these enzymes in metabolism, about the corresponding genes and their expression as well as about mutants and anti-sense plants related to these genes or processes will be summarized and discussed. From a comparison of the available information about the number and organization of GDC and SHMT genes in the genomes of Arabidopsis thaliana and Oryza sativa it appears that these and, possibly, other genes related to photorespiration, are similarly organized even in only very distantly related angiosperms.     

Genetic manipulation of Bacillus amyloliquefaciens.

Application of modern gene technology to strain improvement of the industrially important bacterium Bacillus amyloliquefaciens is reported. Several different plasmid constructions carrying the alpha-amylase gene (amyE) from B. amyloliquefaciens were amplified in this species either extrachromosomally or intrachromosomally. The amyE gene cloned on a pUB110-derived high copy plasmid pKTH10 directed the highest yields both in rich laboratory medium and in crude industrial medium. The alpha-amylase activity, when compared with the parental strain, was enhanced up to 20-fold in the pKTH 10 transformant. This strain showed decreased activities for other exoenzymes, such as proteases and beta-glucanase suggesting common limiting resources in the processing of these enzymes. Deletions were made in vitro in genes encoding neutral (nprE), alkaline (aprE) protease and beta-glucanase (bglA). The engineered genes were cloned into the thermosensitive plasmid pE194, and the resulting plasmids were used to replace the corresponding wild type chromosomal genes in B. amyloliquefaciens by integration-excision at non-permissive temperature. The double mutant deficient in the major proteases (delta nprE delta aprE) showed about a 2-fold further enhancement in alpha-amylase production in the industrial medium compared with the relevant wild type backgroud, both when plasmid-free and when transformed with pKTH10; this strain also produced elevated levels of the chromosomally-encoded beta-glucanase; pKTH10 was stably maintained both in the wild type strain and in the delta nprE delta aprE mutant. We suggest that the higher yields in alpha-amylase and beta-glucanase in the delta nprE delta aprE strain are primarily due to improved access to limiting resources, and that decreased proteolytic degradation may have had a secondary role in retaining the high activity obtained.     

枯草芽孢杆菌整合载体研究进展

芽孢杆菌质粒经常在复制时出现不稳定的单链(ssDNA)形式,从而导致质粒载体的丢失,而采用整合载体将克隆基因整合到宿主染色体,是克服枯草杆菌质粒不稳定性的一个有效途径。本综述了芽孢杆菌整合载体的研究历程、整合机理、整合类型及其应用和前景。     

Features of transformation of competent cells and Bacillus subtilis protoplasts by integrative vectors

The effect of structural peculiarities of DNAs from integrative plasmids on the transformation activity was studied. Monomeric forms of the plasmids can only transform B. subtilis competent cells, when plasmid selective marker is inserted into chromosomal fragment within the plasmid. Polymeric forms are needed for efficient transformation. Both single- and double-stranded DNAs of integrative plasmids transform no B.subtilis protoplasts, this being irrespective of plasmid structure.     

地衣芽孢杆菌感受态细胞的形成及高效电转化

芽孢杆菌在营养缺乏的饥饿状态下,细胞易产生感受态因子,处于生长芽孢时期的芽孢杆菌更容易产生感受态。基于此原则利用芽孢杆菌极限营养培养基通过体外处理诱导使地衣芽孢杆菌产生感受态性能,同时调整参数,建立了感受态细胞对质粒pAPR的高效电转化方法。当质粒DNA浓度为1．5μg/ml、转化时电压为1750V的时候,可以得到261个转化子,经鉴定均为阳性克隆子。而常规电转化的最高仅为20个转化子。为以芽孢杆菌为宿主进行高效电转化提供了模型,也为建立适合工业应用的分泌型表达载体的构建打下了一定基础。     

Genetic manipulation in vesicular-arbuscular mycorrhizal fungi

The symbiosis between vesicular-arbuscular mycorrhizal (VAM) fungi and host plants develops after successful interactions between both partners. These interactions probably involve signal molecules produced by the host plant, by the fungi, or by both. So far the biotrophic status of VAM fungi has hampered the understanding of the processes regulating their physiology. However, among different methods for co-cultivating VAM fungi, root organ cultures (ROC) appear to be a useful technique for studying VAM development. This system has been useful in defining the nutritional requirements of VAM fungi in the precolonization stage and in obtaining axenic fungal material in various developmental stages. The work discussed here focuses on the application of Polymerase Chain Reaction (PCR) technology and the potential of promoting hyphal growth in the absence of the plant. These techniques are being used to study VAM fungi in two main areas. The first concerns the determination of the DNA sequences coding for the SSU ribosomal RNA of two VAM fungi. This approach has allowed the design of specific primers for the rapid identification and quantification of VAM fungi. The second area of research concerns the potential use of PCR technology to study selective expression of specific genes during fungal spore development in defined in vitro conditions. The achievement of this future prospect depends on the ability to prepare PCR-based cDNA libraries from small amounts of fungal material after stimulation of hyphal growth with CO₂ and plant flavonols.     

Yeast vectors for integration at the HO locus

We have constructed new yeast vectors for targeted integration of desired sequences at the Saccharomyces cerevisiae HO locus. Insertion at HO has been shown to have no effect on yeast growth, and thus these integrations should be neutral. One vector contains the KanMX selectable marker, and integrants can be selected by resistance to G418. The other vector contains the hisG-URA3-hisG cassette, and integrants can be selected by uracil prototrophy. Subsequent growth on 5-FOA permits identification of colonies where recombination between the hisG tandem repeats has led to loss of the URA3 marker and return to uracil auxotrophy. We also describe several new bacterial polylinker vectors derived from pUC21 (ampicillin resistance) and pUK21 (kanamycin resistance).     

Genetic manipulation of microspores and microspore-derived embryos

Summary Recent advances in plant cell and molecular biology have furthered the genetic manipulation of many plant species and advanced the options for crop improvement. Among the many targets for genetic manipulation, microspores offer several unique advantages: they are haploid, single-celled, and highly synchronized. In many plant species microspores develop into haploid embryos, and eventually haploid and doubled haploid plants, after in vitro anther or microspore culture. This induced in vitro developmental pathway of microspores, termed microspore embryogenesis, can be used to recover individual homozygous plants from microspores and microspore-derived embryos after genetic manipulation such as mutagenesis and gene transfer. The highly efficient microspore embryogenesis system inBrassica napus has been used successfully to obtain various mutants after microspore mutagenesis, and to achieve gene transfer mediated byAgrobacterium tumefaciens. Presented in the Session-in-Depth In Vitro Gametophyte Biology at the 1991 World Congress on Cell and Tissue Culture held in Anaheim, California, June 16–20, 1991.     

Genetic manipulation of carotenoid biosynthesis and photoprotection

There are multiple complementary and redundant mechanisms to provide protection against photo-oxidative damage, including non-photochemical quenching (NPQ). NPQ dissipates excess excitation energy as heat by using xanthophylls in combination with changes to the light-harvesting complex (LHC) antenna. The xanthophylls are oxygenated carotenoids that in addition to contributing to NPQ can quench singlet or triplet chlorophyll and are necessary for the assembly and stability of the antenna. We have genetically manipulated the expression of the epsilon-cyclase and beta-carotene hydroxylase carotenoid biosynthetic enzymes in Arabidopsis thaliana. The epsilon-cyclase overexpression confirmed that lut2 (lutein deficient) is a mutation in the epsilon-cyclase gene and demonstrated that lutein content can be altered at the level of mRNA abundance with levels ranging from 0 to 180% of wild-type. Also, it is clear that lutein affects the induction and extent of NPQ. The deleterious effects of lutein deficiency on NPQ in Arabidopsis and Chlamydomonas are additive, no matter what the genetic background, whether npq1 (zeaxanthin deficient), aba1 or antisense beta-hydroxylase (xanthophyll cycle pool decreased). Additionally, increasing lutein content causes a marginal, but significant, increase in the rate of induction of NPQ despite a reduction in the xanthophyll cycle pool size.     

Genetic manipulation of polyamine catabolism in rodents

Activation of polyamine catabolism through the overexpression of spermidine/spermine N1-acetyltransferase (SSAT) in transgenic rodents does not only lead to distorted tissue polyamine homeostasis, manifested as striking accumulation of putrescine, appearance N1-acetylspermidine and reduction of tissue spermidine and/or spermine pools, but likewise creates striking phenotypic changes. The latter include loss of hair, lipoatrophy and female infertility. Forced expression of SSAT modulates skin, prostate and intestinal carcinogenesis, induces acute pancreatitis and blocks early liver regeneration. Although many of these features are directly attributable to altered tissue polyamine pools, some of them are more likely related to the greatly accelerated flux of the polyamines caused by activated catabolism and compensatorily enhanced biosynthesis.     

Yeast artificial chromosome vectors for efficient clone manipulation and mapping

The yeast artificial chromosome (YAC) cloning system allows the cloning of exogenous DNA several hundred kilobases in length. To enhance the usefulness of this technology, yeast artificial chromosome vectors have been designed for efficient clone characterization, manipulation, and mapping. The vectors contain a polylinker with unique EcoRI, BglII, NotI, EagI, SacII, SalI, NruI, NheI, and ClaI cloning sites and T7 bacteriophage promoters positioned to allow the generation of riboprobes from the exogenous DNA ends. Centric and acentric vector arms were constructed as separate plasmids to allow the recovery of both ends of the YAC insert DNA directly in Escherichia coli. In addition, YACs generated using this vector system contain a yeast gene (SUP 11) that allows visual monitoring of YAC stability and copy number.