Localization of the genes coding for the 51 kDa PSII chlorophyll apoprotein,apocytochrome b6, the 65–70 kDa PSI chlorophyll apoproteins and the 44 kDa PSII chlorophyll apoprotein in pea chloroplast DNA

Summary DNA probes isolated from previously mapped spinach genes were used to locate 5 genes on pea ctDNA by heterologous hybridization. The genes mapped include psbC, psaA, psaB, psbB, and petB. PsbB and petB mapped to a 6.7 kbp XbaI DNA fragment adjacent to the petD gene. Northern probes from within the DNA which codes for psbB and petD hybridized to 6 RNAs ranging from 1.2 to 5.6 kbp. The psaA and psaB genes, which code for 65–70 kDa proteins of Photosystem I, were mapped to a 7.5 kbp. XbaI DNA fragment. A 5.8 kbp RNA is transcribed from the region which contains the psaA and psaB genes suggesting that these genes are co-transcribed. Finally the psbC gene which codes for a 44 kDa chlorophyll-protein of Photosystem II was mapped to a 12.3 kbp PstI DNA fragment. The pea psbC open reading frame overlaps the psbD coding sequence and this gene pair is within 3 kbp of the psaA-psaB genes. Overall, the organization of the 3 gene clusters analyzed in peas is similar to that reported for spinach.     

Nucleotide sequences of the continuous and separated petA, petB and petD chloroplast genes in Chlamydomonas reinhardtii

We have mapped and sequenced the petA (cytf), petB (cytb6) and petD (subunit IV) genes on the chloroplast genome of Chlamydomonas reinhardtii. At variance with the pet genes in higher plant chloroplasts, the petB and petD genes are continuous, not adjacent and not located next to the psbB gene. The corresponding polypeptide sequences are highly conserved when compared with their counterparts from other sources but have a few features specific of algal cytb6/f complexes. In particular the transit sequence of cytf displays unique characteristics when compared with those previously described for cytf in higher plants.     

Translational control during early development

Early development in many animals is programmed by maternally inherited messenger RNAs. Many of these mRNAs are translationally dormant in immature oocytes, but are recruited onto polysomes during meiotic maturation, fertilization, or early embryogenesis. In contrast, other mRNAs that are translated in oocytes are released from polysomes during these later stages of development. Recent studies have begun to define the cis and trans elements that regulate both translational repression and translational induction of maternal mRNA. The inhibition of translation of some mRNAs during early development is controlled by discrete sequences residing in the 3' and 5' untranslated regions, respectively. The translation of other RNAs is due to polyadenylation which, at least in oocytes of the frog Xenopus laevis, is regulated by a U-rich cytoplasmic polyadenylation element (CPE). Although similar, the CPE sequences of various mRNAs are sufficiently different to be bound by different proteins. Two of these proteins and their interactions are described here.     

Information relay from gene to protein: the mRNP connection

Eukaryotic messenger RNAs and their binding proteins are organized into structural units called ribonucleoprotein particles (mRNPs). Some mRNP proteins are ubiquitous, and might bind all mRNAs to ensure efficient translation. Other mRNA proteins, however, are cell-specific and bind only certain mRNAs that display regulated translation. This is particularly evident in early development, where some mRNP particles can be sequestered from the translational apparatus for months before they enter polysomes. Recent investigations suggest that these and other mRNP proteins bind specific sequences and regulate translation.