Evidence that sigma factors are components of chloroplast RNA polymerase.

Plastid genes are transcribed by DNA-dependent RNA polymerase(s), which have been incompletely characterized and have been examined in a limited number of species. Plastid genomes contain rpoA, rpoB, rpoC1, and rpoC2 coding for alpha, beta, beta', and beta" RNA polymerase subunits that are homologous to the alpha, beta, and beta' subunits that constitute the core moiety of RNA polymerase in bacteria. However, genes with homology to sigma subunits in bacteria have not been found in plastid genomes. An antibody directed against the principal sigma subunit of RNA polymerase from the cyanobacterium Anabaena sp. PCC 7120 was used to probe western blots of purified chloroplast RNA polymerase from maize, rice, Chlamydomonas reinhardtii, and Cyanidium caldarium. Chloroplast RNA polymerase from maize and rice contained an immunoreactive 64-kD protein. Chloroplast RNA polymerase from C. reinhardtii contained immunoreactive 100- and 82-kD proteins, and chloroplast RNA polymerase from C. caldarium contained an immunoreactive 32-kD protein. The elution profile of enzyme activity of both algal chloroplast RNA polymerases coeluted from DEAE with the respective immunoreactive proteins, indicating that they are components of the enzyme. These results provide immunological evidence for sigma-like factors in chloroplast RNA polymerase in higher plants and algae.     

Competition between sigma factors for core RNA polymerase.

The switch of RNA polymerase specificity from early to late promoters of bacteriophage T4 is achieved by substitution of host sigma factor, sigma 70, with the T4 induced factor, sigma gp55. However, overproduction of sigma gp55 from an expression vector is not detrimental to Escherichia coli growth. Direct competition binding assays demonstrate that sigma 70 readily displaces sigma gp55 from RNA polymerase and thereby reverses the promoter specificity of the enzyme. The displacement also occurs with the core enzyme modified by bacteriophage T4 infection. We postulate that an antagonist of sigma 70 should be formed in T4-infected cells to aid sigma gp55 in the early/late switch.     

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.     

Metal‐responsive RNA polymerase extracytoplasmic function (ECF) sigma factors

In order to survive, bacteria must adapt to multiple fluctuations in their environment, including coping with changes in metal concentrations. Many metals are essential for viability, since they act as cofactors of indispensable enzymes. But on the other hand, they are potentially toxic because they generate reactive oxygen species or displace other metals from proteins, turning them inactive. This dual effect of metals forces cells to maintain homeostasis using a variety of systems to import and export them. These systems are usually inducible, and their expression is regulated by metal sensors and signal‐transduction mechanisms, one of which is mediated by extracytoplasmic function (ECF) sigma factors. In this review, we have focused on the metal‐responsive ECF sigma factors, several of which are activated by iron depletion (FecI, FpvI and PvdS), while others are activated by excess of metals such as nickel and cobalt (CnrH), copper (CarQ and CorE) or cadmium and zinc (CorE2). We focus particularly on their physiological roles, mechanisms of action and signal transduction pathways.     

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.     

A two-plasmid system for identification of promoters recognized by RNA polymerase containing extracytoplasmic stress response sigma(E) in Escherichia coli

We have previously established a two-plasmid system in Escherichia coli for identification of promoters recognized by RNA polymerase containing a heterologous sigma factor. Attempts to optimize this system for identification of promoters recognized by RNA polymerase containing E. coli extracytoplasmic stress response sigma(E) failed owing to high toxicity of the expressed rpoE. A new system for identification of sigma(E)-cognate promoters was established, and verified using the two known sigma(E)-dependent promoters, rpoEp2 and degPp. Expression of the sigma(E)-encoding rpoE gene was under the control of the AraC-dependent P(BAD) promoter. A low level of arabinose induced a non-toxic, however, sufficient level of sigma(E) to interact with the core enzyme of RNA polymerase. Such an RNA polymerase holoenzyme recognized both known sigma(E)-dependent promoters, rpoEp2 and degPp, which were cloned in the compatible promoter probe plasmid, upstream of a promoterless lacZ alpha reporter gene. This new system has proved to be useful for identification of E. coli sigma(E)-cognate promoters. Moreover, the system could be used for identification of ECF sigma-cognate promoters from other bacteria.     

Protein-protein interactions mapped by artificial proteases: where sigma factors bind to RNA polymerase

Interactions between proteins are important to understand but difficult to study. Conjugating a protein to a small artificial protease endows it with the ability to cut other proteins where it binds to them. Analysing the sites cut on the target proteins leads to new understanding of the structure of each complex. The binding of sigma factors to a common region on RNA polymerase provides an example.     

Roles of RNA polymerase IV in gene silencing

Eukaryotes typically have three multi-subunit enzymes that decode the nuclear genome into RNA: DNA-dependent RNA polymerases I, II and III (Pol I, II and III). Remarkably, higher plants have five multi-subunit nuclear RNA polymerases: the ubiquitous Pol I, II and III, which are essential for viability; plus two non-essential polymerases, Pol IVa and Pol IVb, which specialize in small RNA-mediated gene silencing pathways. There are numerous examples of phenomena that require Pol IVa and/or Pol IVb, including RNA-directed DNA methylation of endogenous repetitive elements, silencing of transgenes, regulation of flowering-time genes, inducible regulation of adjacent gene pairs, and spreading of mobile silencing signals. Although biochemical details concerning Pol IV enzymatic activities are lacking, genetic evidence suggests several alternative models for how Pol IV might function.     

高等植物叶绿体RNA编辑研究进展

RNA编辑普遍存在于陆生植物中,在高等植物叶绿体中以C→U的替换为主,可能是叶绿体产生功能蛋白的重要方式。近年来,使用体外分析、叶绿体转化和紫外交联等技术,使叶绿体RNA编辑机制的研究取得较大进展。本文对这些新的进展进行了概述,并对高等植物叶绿体RNA编辑研究中有待解决的问题进行了展望。