New roads towards chloroplast transformation in higher plants

The attempts to manipulate organelle DNA of higher plants have not yet been succesfull. Although some Agrobacterium mediated and direct gene transfer experi-ments suggested that chloroplasts of Nicotiana tabacum could be transformed, these experiments could not be reproduced. New transformation techniques have emerged: laser-injection, microinjection and high velocity microprojectiles. The biolistic ex-periments with Chlamydomonas made it clear that organelle DNA can support introduced DNA fragments by homologous recombination. In view of these devel-opments, we describe the parameters and new possibilities for chloroplast trans-formation of higher plants.     

Genetic analysis of chloroplast biogenesis in higher plants

The biogenesis of chloroplasts is genetically complex, involving hundreds of genes distributed between the nucleus and organelle. In higher plants, developmental parameters confer an added layer of complexity upon the genetic control of chloroplast biogenesis: the properties of plastids differ dramatically between different cell types. While the biochemistry and structure of different plastid types have been described in detail, factors that determine the timing and localization of chloroplast development and that mediate chloroplast assembly have remained elusive. To identify nuclear genes that play novel roles in chloroplast biogenesis, we are exploiting nuclear mutations that block the accumulation of subsets of chloroplast proteins. Detailed study of the mutant phenotypes provides clues concerning the primary defect in each mutant. Mutants with defects in chloroplast translation and mRNA metabolism have been identified. Other mutants defective in the accumulation of multiple thylakoid complexes show no apparent defect in the synthesis of the missing proteins. These may identify factors involved in the integration of proteins into the thylakoid membrane and their assembly into functional complexes.     

A chloroplast derived trnH gene is expressed in the mitochondrial genome of gramineous plants

We reported previously that the mitochondrial sequence that contains the chloroplast-derived trnH gene has been highly conserved in the region around one terminus of the junction between chloroplast-derived and mitochondrion-specific sequences in most of the gramineous plants analyzed [15]. The results of RT-PCR, northern hybridization, in vitro capping and ribonuclease protection experiments show that the chloroplast-derived trnH gene is transcribed from a putative promoter that is located in the mitochondrion-specific sequence. Gene expression in this region seems to be correlated with the conservation of the sequence at the junction between the chloroplast-derived fragment and the mitochondrion-specific sequence.     

Photocontrol of chloroplast and mitochondrial polypeptide levels in euglena

Two dimensional polyacrylamide gel electrophoresis resolved protein from intact chloroplasts of wild type Euglena gracilis Klebs var. bacillaris Cori into 185 polypeptides of which 55 were localized on the whole cell polypeptide map. Of these chloroplast polypeptides, the relative amounts of 49 increased, the relative amounts of two decreased, and the relative amounts of four polypeptides were unaltered by exposure of dark grown resting cells to light for 72 hours. Proteins from intact purified mitochondria obtained from a bleached mutant (W₁₀BSmL) lacking plastids were resolved into 193 polypeptides of which 44 were localized on the whole cell polypeptide map from wild type cells. Of these mitochondrial polypeptides, the relative amount of one increased, the relative amounts of 12 were unaltered, and the relative amounts of 31 decreased after exposure of the dark grown resting cells to light. Since it is known that the development of the chloroplast in Euglena occurs without a net increase in total cellular protein and without a change in the size of the cellular amino acid pools, the degradation of mitochondrial polypeptides represents a major source of amino acids for the synthesis of chloroplast polypeptides.     

The crosstalk between HIFs and mitochondrial dysfunctions in cancer development

Mitochondria are essential cellular organelles that are involved in regulating cellular energy, metabolism, survival, and proliferation. To some extent, cancer is a genetic and metabolic disease that is closely associated with mitochondrial dysfunction. Hypoxia-inducible factors (HIFs), which are major molecules that respond to hypoxia, play important roles in cancer development by participating in multiple processes, such as metabolism, proliferation, and angiogenesis. The Warburg phenomenon reflects a pseudo-hypoxic state that activates HIF-1α. In addition, a product of the Warburg effect, lactate, also induces HIF-1α. However, Warburg proposed that aerobic glycolysis occurs due to a defect in mitochondria. Moreover, both HIFs and mitochondrial dysfunction can lead to complex reprogramming of energy metabolism, including reduced mitochondrial oxidative metabolism, increased glucose uptake, and enhanced anaerobic glycolysis. Thus, there may be a connection between HIFs and mitochondrial dysfunction. In this review, we systematically discuss the crosstalk between HIFs and mitochondrial dysfunctions in cancer development. Above all, the stability and activity of HIFs are closely influenced by mitochondrial dysfunction related to tricarboxylic acid cycle, electron transport chain components, mitochondrial respiration, and mitochondrial-related proteins. Furthermore, activation of HIFs can lead to mitochondrial dysfunction by affecting multiple mitochondrial functions, including mitochondrial oxidative capacity, biogenesis, apoptosis, fission, and autophagy. In general, the regulation of tumorigenesis and development by HIFs and mitochondrial dysfunction are part of an extensive and cooperative network.Subject terms: Cancer metabolism, Cancer microenvironment     

高等植物叶绿体表达重组蛋白研究进展

近年来,基因工程技术发展迅速,许多重组蛋白得以表达。其中利用植物生物反应器表达特异药物蛋白为人类一些重要疾病的预防和治疗提供了新途径。植物叶绿体遗传转化和表达系统成为目前植物生物反应器的研究热点。因结构和遗传上的特殊性,高等植物叶绿体在重组蛋白表达方面具有独特优势,外源基因表达量高、定点整合,而且叶绿体母系遗传特性保证了生物安全性。很多重要药用蛋白质在植物叶绿体中表达成功。烟草作为高等植物叶绿体转化模式植物,在疫苗抗原、抗体等药物蛋白和其他重要重组蛋白表达方面取得显著进展。高等植物叶绿体遗传转化也为叶绿体基因的表达和调控机制的研究提供新的技术和方法。文中从叶绿体遗传转化原理、载体构建、重组蛋白和重要药物蛋白在叶绿体中的表达以及重组蛋白表达对植物代谢和性状影响等多个角度,对高等植物叶绿体遗传转化体系研究的新进展进行了综述,以期为叶绿体表达平台的开发和重要药用蛋白质的表达提供新思路。     

Protein translocation within chloroplast is similar in Euglena and higher plants

It is currently thought that chloroplasts of higher plants were derived from endosymbiont oxygenic photosynthetic bacteria (primary endosymbiosis), while Euglena, a photosynthetic protista, gained chloroplasts by secondary endosymbiosis (i.e., incorporation of a photosynthetic eukaryote into heterotrophic eukaryotic host). To examine if the protein transport inside chloroplasts is similar between these organisms, we carried out heterologous protein import experiments with Euglena precursor proteins and spinach chloroplasts. The precursor of a 30-kDa subunit of the oxygen-evolving complex (OEC30) from the thylakoid lumen of Euglena chloroplasts contained the N-terminal signal, stroma targeting, and thylakoid transfer domains. Truncated preOEC30s lacking the N-terminal domain were post-translationally imported into spinach chloroplasts, transported into the thylakoid lumen, and processed to a mature protein. These results showed that protein translocations within chloroplasts in Euglena and higher plants are similar and supported the hypothesis that Euglena chloroplasts are derived from the ancestral Chlorophyta.     

Regulation of expansin gene expression affects growth and development in transgenic rice plants

To investigate the in vivo functions of expansins, we generated transgenic rice plants that express sense and antisense constructs of the expansin gene OsEXP4. In adult plants with constitutive OsEXP4 expression, 12% of overexpressors were taller and 88% were shorter than the average control plants, and most overexpressors developed at least two additional leaves. Antisense plants were shorter and flowered earlier than the average control plants. In transgenic plants with inducible OsEXP4 expression, we observed a close correlation between OsEXP4 protein levels and seedling growth. Coleoptile and mesocotyl length increased by up to 31 and 97%, respectively, in overexpressors, whereas in antisense seedlings, they decreased by up to 28 and 43%, respectively. The change in seedling growth resulted from corresponding changes in cell size, which in turn appeared to be a function of altered cell wall extensibility. Our results support the hypothesis that expansins are involved in enhancing growth by mediating cell wall loosening.     

Divergence of tRNA genes in chloroplast DNA of higher plants

The saturation hybridization between spinach chloroplast (ct) DNA and spinach ¹²⁵I-labelled chloroplast tRNA has shown that about 1.1% of the spinach ctDNA codes for tRNAs. The observed hybridization is a result of specific base-pairing as shown by competition hybridization experiments and thermal stability of the ctDNA-tRNA hybrids. The amount of hybridization shows that spinach ctDNA contains about 40 tRNA genes. Similar hybridization studies have shown that corn ctDNA contains about 28 tRNA genes. The cross-hybridizations between ctDNA and tRNAs of corn, spinach and pea have shown that tRNAs in chloroplasts of higher plants have undergone significant divergence. The pea and spinach tRNAs have been found to have 50% of the base sequences in common. The corn tRNAs have been found to have only about 30% of the base sequences in common with pea and spinach. These data have been confirmed by extensive heterologous competition experiments and thermal stability of the heterologous DNA-tRNA hybrids. The experiments have also shown that the base sequences of tRNAs common in all three plants are the same.