Phytochrome control of plastid mRNA in mustard (Sinapis alba L.)

The steady-state levels of plastid RNA sequences in dark-grown and light-grown mustard (Sinapis alba L.) seedlings have been compared. Total cellular RNAs were labeled in vitro with ³²P and hybridized to separated restriction fragments of plastid DNA. Cloned DNA fragments which encode the large subunit (LS) of ribulose-1,5-bisphosphate carboxylase [3-phospho-D-glycerate carboxylase (dimerizing), EC 4.1.1.39] and a 35,000 plastid polypeptide were used as probes to assess the levels of these two plastid mRNAs. The 1.22-kilobase-pair mRNA for the 35,000 polypeptide is almost undetectable in dark-grown seedlings, but is a major plastid mRNA in light-grown seedlings. The hybridization analysis of RNA from seedlings which were irradiated with red and far-red light indicates that the level of this mRNA, but not of LS mRNA, is controlled by phytochrome.Abbreviations LS large subunit - RuBP ribulose-1,5-bisphosphate - ptDNA plastid DNA     

Expression patterns of cotton chloroplast genes during development: implications for development of plastid transformation vectors

Although most plastid transformation studies have focused on chloroplast expression, plastid transformation can also be used to express genes in plastids of a wide variety of plant tissues by using appropriate plastid promoters. Based on the sequence of the Gossypium hirsutum chloroplast genome, we developed primers and amplified segments of 20 different plastid genes. The PCR products were labeled and used in filter dot blot hybridization studies to characterize their expression levels and patterns in total RNA isolated from light- and dark-grown cotton tissues at different developmental stages. A subset of 6 genes among these was further characterized by real time PCR. Highest expression levels were observed for rrn16 and psbA. Four genes were expressed in all samples at relatively constant levels: accD, atpA, matK and rrn16. Expression in root tissue was generally low. The results of our study can be used to predict which operons and promoters are most likely to be preferentially expressed in the plastids of tissues of interest at levels that would result in the desired phenotype, facilitating the development of plastid transformation vectors.     

PLASTID DEVELOPMENT IN IOJAP- AND CHLOROPLAST MUTATOR-AFFECTED MAIZE PLANTS

Plastids affected by either iojap or chloroplast mutator fail to green, and altered plastids are maternally transmitted to subsequent generations. The ultrastructure of iojap-affected plastids indicates that these plastids contain no ribosomes and are capable of supporting little internal membrane organization in either light or dark-grown plants. Chloroplast mutator-affected plastids of light-grown plants contain some organized internal membrane structures. In dark-grown plants, chloroplast mutator-aftected plastids contain a crystalline prolamellar body, numerous vesicles, and osmiophilic granules. The chloroplast mutator-affecled etioplasts display an abnormal distribution of lamellar membranes; these membranes, rather than radiating in a spokelike pattern from the prolamellar body, are condensed into a portion of the organelle. Light causes disruption of the prolamellar body in chloroplast mutator-affected plastids without promoting the organization of a normal thylakoid membrane system. The effects of iojap and chloroplast mutator are cell autonomous and apparently influence the individual plastid, as evidenced by the persistence of heteroplastidic cells containing normal and affected plastids.     

Nucleus‐encoded mRNAs for Chloroplast Proteins GapA,PetA, and PsbO are Trans‐spliced in the Flagellate Euglena gracilis Irrespective of Light and Plastid Function

Euglena gracilis is a fresh‐water flagellate possessing secondary chloroplasts of green algal origin. In contrast with organisms possessing primary plastids, mRNA levels of nucleus‐encoded genes for chloroplast proteins in E. gracilis depend on neither light nor plastid function. However, it remains unknown, if all these mRNAs are trans‐spliced and possess spliced leader sequence at the 5′‐end and if trans‐splicing depends on light or functional plastids. This study revealed that polyadenylated mRNAs encoding the chloroplast proteins glyceraldehyde‐3‐phosphate dehydrogenase (GapA), cytochrome f (PetA), and subunit O of photosystem II (PsbO) are trans‐spliced irrespective of light or plastid function.     

Dynamics of Galactolipids and Plastids in Nonphotosynthetic Cells of Glycine max Suspension Cultures : A Morphological and Biochemical Study

The age-dependent interrelationship of galactolipids and plastids in heterotrophic cell suspension cultures of Glycine max (soybean) was studied with regard to aging of nonphotosynthetic cells. Cells were propagated in the dark and under illumination with white light, and were harvested at days 7 (end of logarithmic phase), 14, and 21 (extended stationary phase). Electron microscopy revealed in dark-grown cells a proliferating decay of the amyloplast-type plastids, which could be correlated to a decrease of galactolipids. This trend was dramatically reversed in irradiated cultures, where the plastids of day 21 cells appeared rejuvenated. A concomitant increase of galactolipid content in the cells was observed, yet chlorophyll synthesis and photosynthetic activity were not induced. The dynamics of galactolipid contents did not correlate with total lipid contents in dark-grown as well as in irradiated cultures. [³H]Galactose served as a radioactive probe for the subcellular localization of galactolipids by electron microscopic autoradiography. Apart from plastids, galactolipids may also be constituents of the plasma membrane. The results render the heterotrophic cell suspension culture a suitable model to study the impact of senescence on plastids of nonphotosynthetic cells.