Transgenic mammals and biotechnology

Biotechnology has begun to realize the enormous potential of transgenic technology: mice with human genes that produce human proteins of therapeutic value in their milk, pigs that express bovine genes that help them gain weight and lose backfat, animals with engineered gene defects that mimic human genetic diseases.     

Harnessing HIV for therapy, basic research and biotechnology

First described about a decade ago, lentiviral vectors ('lentivectors') have emerged as potent and versatile tools of gene transfer for basic and applied research and offer exciting perspectives for the field of gene therapy. In the clinic, HIV-based vectors are showing particular promise for delivering therapeutic genes to hematopoietic stem cells (HSCs) and terminally differentiated targets in the central nervous system (CNS). Their flexible design facilitates the accommodation of sophisticated elements of control for the precise tuning of transgene expression. The delivery of small interfering RNAs (siRNAs) and genomic or cDNA libraries and the creation of transgenic animals are the most recent and exciting applications of HIV-based vectors that will help to tackle fundamental issues across wide areas of biology.     

Advances in plant biotechnology and their implication for forestry research

Summary Over the past few years, techniques of cell biology, genetic screening, and gene manipulation have been developed to the extent that their impact on commercial development of improved plant varieties is predicted to have a measurable impact on agriculture by the year 2000 and beyond. A review will be given of progress that has been made in each of these areas toward the manipulation of crop plants for improved field performance and product quality. There are now several opportunities in which these techniques can be employed for the improvement of forestry species. In the light of the long-time scales involved in the generation of forestry products, it is important to focus on targets that are worthwhile pursuing commercially using appropriate technical routes. Selected examples will be given of the application of plant biotechnology techniques that promise potentially significant improvement for forestry species. Presented in the Keynote address Toward the Forest of Tomorrow at the 5th Meeting of the Conifer Biotechnology Working Group, Siltingbourne, England, July 8–13, 1990.     

The impact of Arabidopsis research on plant biotechnology

Arabidopsis thaliana, a small annual weed belonging to the mustard family, has become a widely used model in plant genetic research. It has a small genome, short life cycle, and is easy to mutagenize. Identification of genes based on phenotype alone, often a rather difficult part of molecular genetic research, is easiest in this plant. Laboratories working on the "model" plant Arabidopsis thaliana have created a network for sharing resources and ideas, so progress has been rapid. The importance of this plant to biotechnology is that genes isolated from Arabidopsis can be used to find their homologs in crop plants. Likewise, fundamental mechanisms can be understood in a model plant, and applied in crop plants.     

Autophagy: from basic research to its application in food biotechnology

Autophagy is a catabolic process by which the cytoplasm is sequestered into double-membrane vesicles and delivered to the lysosome/vacuole for breaking down and recycling of the low molecular weight degradation products. The isolation in the yeast Saccharomyces cerevisiae of many of the genes involved in autophagy constituted a milestone in understanding the molecular bases of this pathway. The identification of ortholog genes in other eukaryotic models revealed that the mechanism of autophagy is conserved among all eukaryotes. This pathway has been shown to be involved in a growing number of physiological processes and conversely, its deregulation may contribute to the development of several diseases. Recent reports have also shown that autophagy may play an important role in biotechnological processes related with the food industry. In this review we discuss current knowledge of the molecular mechanism of autophagy, including some applied aspects of autophagy in the field of food biotechnology.     

Transgenic animal production and animal biotechnology

Considerable progress has been made in methods for production of transgenic livestock; beginning with pronuclear microinjection over 20 years ago. New methods, including the use of viral vectors, sperm-mediated gene transfer and somatic cell cloning, have overcome many of the limitations of pronuclear microinjection. It is now possible to not only readily make simple insertional genetic modifications, but also to accomplish, more complex, homozygous gene targeting and artificial chromosome transfer in livestock.     

The role of plastids in plant speciation

Understanding the molecular basis of how new species arise is a central question and prime challenge in evolutionary biology and includes understanding how genomes diversify. Eukaryotic cells possess an integrated compartmentalized genetic system of endosymbiotic ancestry. The cellular subgenomes in nucleus, mitochondria and plastids communicate in a complex way and co-evolve. The application of hybrid and cybrid technologies, most notably those involving interspecific exchanges of plastid and nuclear genomes, has uncovered a multitude of species-specific nucleo-organelle interactions. Such interactions can result in plastome-genome incompatibilities, which can phenotypically often be recognized as hybrid bleaching, hybrid variegation or disturbance of the sexual phase. The plastid genome, because of its relatively low number of genes, can serve as a valuable tool to investigate the origin of these incompatibilities. In this article, we review progress on understanding how plastome-genome co-evolution contributes to speciation. We genetically classify incompatible phenotypes into four categories. We also summarize genetic, physiological and environmental influence and other possible selection forces acting on plastid-nuclear co-evolution and compare taxa providing molecular access to the underlying loci. It appears that plastome-genome incompatibility can establish hybridization barriers, comparable to the Dobzhansky-Muller model of speciation processes. Evidence suggests that the plastid-mediated hybridization barriers associated with hybrid bleaching primarily arise through modification of components in regulatory networks, rather than of complex, multisubunit structures themselves that are frequent targets.     

Concanavalin A-mediated agglutination of plant plastids

Cucumber (Cucumis sativus L.) and pear (Pyrus domestica Medik.) fruit proplastids, and pea (Pisum sativum L., cv. Meteor) leaf chloroplasts, extracted by osmotic rupture of protoplasts isolated after degradation of the cell walls by cellulase and pectinase, agglutinated in the presence of Con A. Agglutination of cucumber proplastids was inhibited by anti-Con A and by methyl D-gluco/manno pyranosides but not by methyl D-galactopyranoside. Fluorescein isothiocyanate-conjugated Con A (FITC-Con A) rendered agglutinated clumps fluorescent. If cellulase was omitted from the macerating medium, Con A-mediated agglutination did not occur even if proplatids were subsequently incubated with cellulase. Proplastids and chloroplasts extracted by conventional mechanical disruption methods were not agglutinated by Con A and did not acquire fluorescence with FITC-Con A. However, cucumber proplastids so extracted could be agglutinated by Con A if incubated with cellulase after preparation.Abbreviation Con A Concanavalin A (Jackbean phytohemagglutinin)     

Versatile roles of plastids in plant growth and development

Plastids, found in plants and some parasites, are of endosymbiotic origin. The best-characterized plastid is the plant cell chloroplast. Plastids provide essential metabolic and signaling functions, such as the photosynthetic process in chloroplasts. However, the role of plastids is not limited to production of metabolites. Plastids affect numerous aspects of plant growth and development through biogenesis, varying functional states and metabolic activities. Examples include, but are not limited to, embryogenesis, leaf development, gravitropism, temperature response and plant-microbe interactions. In this review, we summarize the versatile roles of plastids in plant growth and development.     

国内植物环境胁迫研究应注意的几个基本问题

根据作者多年从事植物逆境研究和教学的经验以及在近几年接触到的国内有关研究工作中发现的问题,为了提高今后研究工作的基础水平和学术期刊稿件的科学水平,特提出几个植物逆境研究中常见到的缺憾和对概念理解上的偏差予以讨论和澄清。问题包括：环境胁迫的定义和定量,植物对环境胁迫的“直接感受”,抗逆性和敏感性,耐逆性和避逆性,适应、驯化和锻炼,环境胁迫的剂量效应关系,伤害和死亡的判定,植物细胞膜的透性和植物自由基清除系统对环境胁迫的反应。     

Moral and ethical issues in plant biotechnology

Plant biotechnology has recently become the focus of heated controversy and media attention, particularly in the UK. The most obvious concerns have centred upon the possible effects of the technology on the environment and on human health, but a broader and more fundamental set of considerations has also been evident in much of the debate, these are usually referred to as 'moral' or 'ethical' concerns.     

Trehalose and its applications in plant biotechnology

Trehalose, a nonreducing disaccharide of glucose, is one of the most effective osmoprotectants. Several strategies leading to its accumulation have been envisaged in both model and crop plants using genes of bacterial, yeast and, more recently, plant origin. Significant levels of trehalose accumulation have been shown to cause abiotic stress tolerance in transgenic plants. In this review, we describe the most biologically relevant features of trehalose: chemical and biological properties; occurrence and metabolism in organisms with special reference to plants; protective role in stabilizing molecules; physiological role in plants with special reference to carbohydrate metabolism. The emphasis of this review, however, will be on manipulation of trehalose metabolism to improve abiotic stress tolerance in plants.     

Strengthening desert plant biotechnology research in the United Arab Emirates: a viewpoint

The biotechnology of desert plants is a vast subject. The main applications in this broad field of study comprises of plant tissue culture, genetic engineering, molecular markers and others. Biotechnology applications have the potential to address biodiversity conservation as well as agricultural, medicinal, and environmental issues. There is a need to increase our knowledge of the genetic diversity through the use of molecular genetics and biotechnological approaches in desert plants in the Arabian Gulf region including those in the United Arab Emirates (UAE). This article provides a prospective research for the study of UAE desert plant diversity through DNA fingerprinting as well as understanding the mechanisms of both abiotic stress resistance (including salinity, drought and heat stresses) and biotic stress resistance (including disease and insect resistance). Special attention is given to the desert halophytes and their utilization to alleviate the salinity stress, which is one of the major challenges in agriculture. In addition, symbioses with microorganisms are thought to be hypothesized as important components of desert plant survival under stressful environmental conditions. Thus, factors shaping the diversity and functionality of plant microbiomes in desert ecosystems are also emphasized in this article. It is important to establish a critical mass for biotechnology research and applications while strengthening the channels for collaboration among research/academic institutions in the area of desert plant biotechnology.     

Mobile reticular organization of plastids and mitochondria in plant cells

Results of confocal, fluorescent and video microscopy of plant cell organelles and of stromule network uniting them are reviewed. The vast information on the structure of stromules, their mobility, proposed functions and development has been analyzed, in addition to factors stimulating and suppressing this development. Structural similarity between the network of stromules in living cells, observed by confocal fluorescence microscopy, and the endoplasmic reticulum, seen on micrographs of preparations fixed for electron microscopy is discussed. As a result of this discussion, a conclusion is made with regard to the identity of these endomembranous networks. The intercellular symplastic organization is shown for both networks in plant tissues. The existence of a common transport and trophic compartment is proposed that includes organelles, intercellular endoplasmic reticulum and its derivatives, phloem and xylem. The trophic system development might have been induced in the course of endosymbiogenesis with some bacterial precursors of organelles.     

Applications of nanobodies in plant science and biotechnology

Key message

Present review summarizes the current applications of nanobodies in plant science and biotechnology, including plant expression of nanobodies, plant biotechnological applications, nanobody-based immunodetection, and nanobody-mediated resistance against plant pathogens.

Abstract

Nanobodies (Nbs) are variable domains of heavy chain-only antibodies (HCAbs) isolated from camelids. In spite of their single domain structure, nanobodies display many unique features, such as small size, high stability, and cryptic epitopes accessibility, which make them ideal for sophisticated applications in plants and animals. In this review, we summarize the current applications of nanobodies in plant science and biotechnology, focusing on nanobody expression in plants, plant biotechnological applications, determination of plant toxins and pathogens, and nanobody-mediated resistance against plant pathogens. Prospects and challenges of nanobody applications in plants are also discussed.