Effect of tagetitoxin on the levels of ribulose 1,5-bisphosphate carboxylase, ribosomes, and RNA in plastids of wheat leaves

Growth of wheat seedlings in the presence of the phytotoxin tagetitoxin produces pigment-deficient leaves of normal size and morphology whose cells contain only rudimentary plastids. We could not detect the accumulation of either the plastid-encoded large subunit or the nuclear-encoded small subunit of the chloroplast stromal enzyme ribulose 1,5-bisphosphate carboxylase (RuBPCase) in western blots of protein extracted from leaves of such seedlings. Sucrose gradient centrifugation profiles showed that plastid ribosomes were essentially absent in toxin-treated leaf tissue while cytoplasmic ribosomes were relatively unaffected. Northern blot analysis of RNA in toxin-treated leaves showed a deficiency of plastid ribosomal RNA (16S and 23S) as well as reduced levels of plastid mRNAs for the large subunit of RuBPCase and for the 32 kilodalton thylakoid Q_B polypeptide. Northern analysis also showed that the nuclear-encoded rbcS mRNA for the small subunit of RuBPCase is present in only trace amounts in toxin-treated leaves.     

Chloroplast photooxidation affects the accumulation of cytosolic mRNAs encoding chloroplast proteins in maize

Maize (Zea mays L.) seedlings were grown in the presence or absence of an herbicide, norflurazon (4-chloro-5-(methylamino)-2-(,,-trifluoro-m-tolyl)-pyridazinone), which prevents the accumulation of colored carotenoids. In the absence of carotenoids, plants grown in high light incur extensive photooxidative damage to their plastids, but relatively little damage elsewhere. Growth in very low light minimizes chlorophyll photooxidation and allows chloroplast development to proceed. We have previously reported that mRNA encoding light-harvesting chlorophyll a/b protein (LHCP) fails to accumulate in high-light-grown carotenoid-deficient seedlings, but accumulates normally in carotenoid-deficient seedlings grown in low light. Here we extend these results by examining the levels of translatable mRNAs encoding seven additional nuclear-encoded chloroplast proteins. When norflurazon-treated seedlings were grown in low light for 8 d and then transferred to high light for 24 h, three cytosolic mRNAs (plastocyanin, Rieske Fe–S protein, and the 33-kdalton (kDa) subunit of the photosystem II O₂-evolving complex) decreased to less than 1% the amount found in untreated seedlings. Two other mRNAs (NADP malic enzyme, EC 1.1.1.40, and the 23-kDa subunit of the photosystem II O₂-evolving complex) decreased significantly but not to levels as low as the first three. Levels of translatable mRNA for two other chloroplast proteins (pyruvate orthophosphate dikinase, EC 2.7.9.1, and ferredoxin NADP oxidoreductase, EC 1.18.1.2) were not reduced in nonflurazon-treated seedlings after 24 h in high light, but did not show the normal light-induced increase found in untreated plants. Photooxidative damage in the chloroplast thus affects the accumulation of a number of cytosolic mRNAs encoding proteins destined for the chloroplast.Abbreviations Da dalton - FNR ferredoxin NADP oxidoreductase - LHCP light-harvesting chlorophyll a/b-binding protein - poly(A)RNA polyadenylated RNA - PPDK pyruvate orthophosphate dikinase - PSII photosystem II - SDSPAGE sodium dodecyl sulfate-polyacrylamide gel electrophoresis - SSu small subunit (of ribulose-1,5-bisphosphate carboxylase)     

Chloroplast photooxidation inhibits the expression of a set of nuclear genes

Summary Mutations or herbicides which inhibit the accumulation of carotenoid pigments in higher plants also result in the arrest of chloroplast development at a very early stage. The cause is extensive photooxidative damage within the chloroplast in the absence of protective carotenoids. Because the extent of photooxidation is dependent upon light intensity, normal chloroplast development can occur when carotenoid-deficient seedlings are grown in very dim light. Normal accumulation of chloroplastic and cytosolic mRNAs encoding chloroplast proteins proceeds only under permissive dim light conditions. Illumination with higher intensity light causes rapid chlorophyll photooxidation and the loss of two cytosolic mRNAs coding for proteins destined for the chloroplast, but does not affect another light-regulated cytosolic mRNA encoding a cytosolic protein. This experimental system may have uncovered a mechanism which coordinates the expression of genes in different cellular compartments.Abbreviations LHCP light-harvesting chlorophyll a/b protein - SSu small subunit - RuBP fibulose 1,5-bisphoshate - PEP phosphoenolpyruvate     

The Role of Plastids in the Expression of Nuclear Genes for Thylakoid Proteins Studied with Chimeric [beta]-Glucuronidase Gene Fusions

We have analyzed plastid and nuclear gene expression in tobacco seedlings using the carotenoid biosynthesis inhibitor nor-flurazon. mRNA levels for three nuclear-encoded chlorophyll-binding proteins of photosystem I and photosystem II (CAB I and II and the CP 24 apoprotein) are no longer detectable in photobleached seedlings, whereas those for other components of the thylakoid membrane (the 33- and 23-kD polypeptides and Rieske Fe/S polypeptide) accumulate to some extent. Transgenic tobacco seedlings with promoter fusions from genes for thylakoid membrane proteins exhibit a similar expression behavior: a CAB-[beta]-glucuronidase (GUS) gene fusion is not expressed in herbicide-treated seedlings, whereas PC-, FNR-, PSAF-, and ATPC-promoter fusions are expressed, although at reduced levels. All identified segments in nuclear promoters analyzed that have been shown to respond to light also respond to photodamage to the plastids. Thus, the regulatory signal pathways either merge prior to gene regulation or interact with closely neighboring cis elements. These results indicate that plastids control nuclear gene expression via different and gene-specific cis-regulatory elements and that CAB gene expression is different from the expression of the other genes tested. Finally, a plastid-directing import sequence from the maize Waxy gene is capable of directing the GUS protein into the photodamaged organelle. Therefore, plastid import seems to be functional in photobleached organelles.     

Carotenoid-deficient young wheat etioplasts are able to bind precursor proteins on the plastid surface but are impaired in their translocation ability

Young carotenoid-deficient etioplasts, isolated from Norflurazon (NF)-treated wheat seedlings, were used to study the role of coloured carotenoids in the binding and import reactions of different nuclear-encoded plastid proteins. Plastids from control seedlings exhibited significantly higher import efficiencies than did plastids from NF-treated plants. Etioplasts containing normal levels of carotenoids imported approximately 2000 and 800 molecules per plastid of the precursors of the small Rubisco subunit (pSS) and the Rieske FeS protein (pFeS), respectively. Plastids from NF-treated plants imported approximately 100 and 70 pSS and pFeS molecules per plastid, respectively. In addition, a maximum binding capacity of NF-treated plastids of 1200 protein molecules per plastid was observed for both pSS and pFeS when assayed at 25°C: and a maximum binding capacity of approximately 1300 molecules per plastid was noted at 4°C. For control plastids, a similar amount of binding, or approximately 1400 protein molecules per plastid, could only be observed if import was inhibited by low ATP concentrations at 4°C. When these plastids were washed and transferred to conditions promoting import at 25°C and 10 mM Mg-ATP, close to 60% of the envelope-associated precursor protein molecules were imported. These results indicate that control and NF-treated young etioplasts contain similar amounts of binding sites for precursor proteins. However, only in the case of control plastids the binding was productive and lead to import and processing in the stroma upon transfer to conditions promoting import. Plastids isolated from wheat seedlings grown in weak red light and containing different amounts of carotenoids, were assayed for their ability to bind and import a protein with unusual import characteristics, the Chlamydomonas reinhardtii PsaF precursor of PSI (pPsaF) and transit peptide deletion constructs. The PsaF protein was imported in a transit peptide-dependent manner into control etioplasts, whereas import of pPsaF into young wheat etioplasts isolated from NF-treated plants was inhibited at low levels of plastid carotenoids.     

Carotenoid synthesis and pleiotropic effects in carotenoid-deficient seedlings of maize

Plastid-envelope membranes from seedlings ofZea mays L. made carotenoid-deficient by either norflurazon treatment or mutation lack an activity permitting conversion of phytoene to -carotene. This activity in membrane fractions was measured by coincubation in vitro with a soluble system from spinach chloroplasts capable of converting [¹⁴C]isopentenyl pyrophosphate into phytoene. When grown in light, the carotenoid-deficient seedlings lack many soluble chloroplast proteins, including NADP-dependent malic enzyme (EC 1.1.1.40), pyruvate phosphate dikinase (EC 2.7.9.1), and ribulose-1,5-bisphosphate carboxylase (EC 4.1.1.39), but apparently still contain the soluble activities permitting synthesis of phytoene.Abbreviations IPP isopentenyl pyrophosphate - LHCP light-harvesting chlorophylla/b-binding protein - norflurazon 4-chloro-5(methylamine)-2-(,,-trifluoro-m-tolyl)-3-(2H)-pyrazinone - TLC thin-layer chromatography - Tris 3-amino-2-(dihydroxymethyl)-1,3-propanediol     

Import of nuclear-encoded proteins into carotenoid-deficient young etioplasts

Young etioplasts with different carotenoid contents were assayed for their ability to import in vitro synthesized nuclear-encoded proteins. The plastids were isolated from the basal 1. 5cm of dark-grown wheat seedlings developed from seeds imbibed with 4 different concentrations of Norflurazon. an inhibitor of the carotenoid biosynthesis. Plastids isolated from plants treated with the two highest concentrations. 2. 8 and 28 mg l⁻¹, of Norflurazon contained approximately 10 and 5% of the carotenoid contents, respectively, compared to the control. The total amounts of proteins in these plastids were approximately 68 and 60% compared to control plastids. Translocation assays employing the precursors of the small subunit of ribulose 1. 5-bisphosphate carboxylase/oxygenase (pSS), and the non-Photosynthetic heat-shock protein 21 (pHSP21), showed that the rate of protein import was considerably lower in plastids with low carotenoid contents. The amounts of imported, processed SS were 11 and 10% after 2. 8 and 28 mg 1⁻¹, respectively, compared to the control, whereas the amounts of HSP21 at these herbicide concentrations were 20 and 18%, respectively. The low apparent import in plastids of Norflurazon-treated leaves was not an effect of intraorganellar degradation of imported proteins, nor were there any differences in the amounts of processed, protease-protected protein when Norflurazon was added to the import reaction using control plastids. The low import capabilities are therefore discussed in relation to the possible role of the carotenoids in the translocation of cytosolically synthesized proteins into the plastidic compartment.     

Effects of pigment-deficient mutants on the accumulation of photosynthetic proteins in maize

We have monitored the accumulation of photosynthetic proteins in developing pigment-deficient mutants of Zea mays. The proteins examined are the CO₂-fixing enzymes, phoshoenolpyruvate carboxylase (E.C. 4.1.1.31) and ribulose-1,5-bisphosphate carboxylase (E.C.4.1.1.39), and three thylakoid membrane proteins, the light-harvesting chlorophyll a/b binding protein (LHCP) of photosystem II, the 65 kilodalton chlorophyll a binding protein of photosystem I and the alpha subunit polypeptide of coupling factor I. Using a sensitive protein-blot technique, we have compared the relative quantities of each protein in mutants and their normal siblings. Carboxylase accumulation was found to be independent of chlorophyll content, while the amounts of the thylakoid proteins increase at about the same time as chlorophyll in delayed-greening mutants. The relative quantity of LHCP is closely correlated with the relative quantity of chlorophyll at all stages of development in all mutants. Because pigment-deficient mutants are arrested at early stages in chloroplast development, these findings suggest that the processes of chloroplast development, chlorophyll synthesis and thylakoid protein accumulation are coordinated during leaf development but that carboxylase accumulation is controlled by different regulatory mechanisms. A white leaf mutant was found to contain low levels of LHCP mRNA, demonstrating that the accumulation of LHCP mRNA is not controlled exclusively by phytochrome.     

Early events in the import/assembly pathway of an integral thylakoid protein

The light-harvesting chlorophyll a/b protein (LHCP) is nuclear-encoded and must traverse the chloroplast envelope before becoming integrally assembled into thylakoid membranes. Previous studies implicated a soluble stromal form of LHCP in the assembly pathway, but relied upon assays in which the thylakoid insertion step was intentionally impaired [Cline, K., Fulsom, D. R. and Viitanen, P. V. (1989) J. Biol. Chem. 264, 14225-14232]. Here we have developed a rapid-stopping procedure, based upon the use of HgCl2, to analyze early events of the uninhibited assembly process. With this approach, we have found that proper assembly of LHCP into thylakoids lags considerably behind trans-envelope translocation. During the first few minutes of import, two distinct populations of mature-size LHCP accumulate within the chloroplast. One is the aforementioned soluble stromal intermediate, while the other is a partially (or improperly) assembled thylakoid species. Consistent with precursor/product relationships, both species reach peak levels at a time when virtually none of the imported molecules are correctly assembled. These results confirm and extend our previous interpretation, that upon import, preLHCP is rapidly processed to its mature form, giving rise to a soluble stromal intermediate. They further suggest that the stromal intermediate initially inserts into the thylakoid bilayer in a partially assembled form, which eventually becomes properly assembled into the light-harvesting complex.     

GRAVITROPISM IN ABSCISIC-ACID DEFICIENT SEEDLINGS OF ZEA MAYS

We did not detect any abscisic acid (ABA) in roots or leaves of carotenoid-deficient mutants of Zea mays. Similarly, we did not detect any ABA in roots or leaves of seedlings treated with Fluridone (an inhibitor of carotenogenesis) even after subjecting them to polyethylene glycol (PEG)-induced moisture stress. Primary roots of untreated, Fluridone-treated, and mutant seedlings were strongly graviresponsive. These results suggest that 1) ABA is not necessary for positive gravitropism by primary roots of these cultivars of Z. mays, and 2) ABA is synthesized via the carotenoid pathway.     

Vir-115 gene product is required to stabilize D1 translation intermediates in chloroplasts

The nuclear gene mutant of barley, vir-115, shows a developmentally induced loss of D1 synthesis that results in inactivation of Photosystem II. Translation in plastids isolated from 1 h illuminated vir-115 seedlings is similar to wild type. In wild-type barley, illumination of plants for 16 to 72 h results in increased radiolabel incorporation into the D1 translation intermediates of 15–24 kDa. In contrast, these D1 translation intermediates were not observed in vir-115 plastids isolated from plants illuminated for 16–72 h. In addition, after 72 h of illumination, radiolabel incorporation into D1 was undetectable in vir-115 plastids. The level and distribution ofpsbA mRNA in membrane-associated polysomes was similar in wild-type and vir-115 mutant plastids isolated from plants illuminated for 16–72 h. Toeprint analysis showed similar levels of translation initiation complexes onpsbA mRNA in vir-115 and wild-type plastids. These results indicate that translation initiation and elongation of D1 is not significantly altered in the mutant plastids. Ribosome pausing onpsbA mRNA was observed in wild-type and vir-115 mutant plastids. Therefore, the absence of D1 translation intermediates in mutant plastids is not due to a lack of ribosome pausing onpsbA mRNA. Based on these results, it is proposed that vir-115 lacks or contains a modified nuclear-encoded gene product which normally stabilizes the D1 translation intermediates. In wild-type plastids, ribosome pausing and stabilization of D1 translation intermediates is proposed to facilitate assembly of cofactors such as chlorophyll will D1 allowing continued D1 synthesis and accumulation in mature chloroplasts.     

The Fate of Chloroplast Proteins during Photooxidation in Carotenoid-Deficient Maize Leaves

Maize seedlings, treated with the herbicide norflurazon to produce a deficiency in carotenoid pigments, were grown in low-fluence-rate light. Under these conditions, which induced chlorophyll biosynthesis while minimizing photooxidation, carotenoid-deficient seedlings showed identical patterns of chloroplast protein accumulation compared with normal seedlings. Carotenoid pigments thus play no direct role in regulating the accumulation of chloroplast proteins. When shifted to high-fluence-rate light, chlorophyll was rapidly photooxidized in carotenoid-deficient seedlings. Chloroplast proteins showed varying degrees of sensitivity to photooxidation. The P-700 apoprotein of photosystem I was rapidly degraded. Most stromal and thylakoid proteins either decreased progressively in photooxidative conditions or appeared to be unaffected. The relative quantity of the light-harvesting chlorophyll a/b-binding protein of photosystem II increased significantly in the first few hours of high-fluence-rate light. It then appeared to be only minimally affected 18 hours after complete photooxidation of chlorophyll.     

Molecular analysis of an aurea photosynthetic mutant (Su/Su) in tobacco: LHCP depletion leads to pleiotropic mutant phenotypes.

Su is a nuclear encoded, semi-dominant aurea mutation in Nicotiana tabacum L. The homozygous plants (Su/Su) are pale yellow and non-photosynthetic while the heterozygous (Su/+) are photosynthetically competent and have a yellow-green phenotype which is distinct from that of green wild-type plants (+/+). We have examined the RNA and protein levels for a number of nuclear and plastid encoded chloroplast proteins under high and low light plant growth conditions. Under high light conditions, the light-harvesting chlorophyll a/b binding proteins (LHCP) were undetectable in the homozygous Su/Su plants, and the large subunit (LSu) and the small subunit (SSu) of ribulose bisphosphate carboxylase (Rubisco) and cytochrome b559 were severely deficient. However, only the nuclear encoded cab and plastid encoded psbE mRNA (encoding LHCP and cytochrome b559 respectively) were reduced significantly. In heterozygous Su/+ plants, the level of LHCP was reduced to 25% of that in wild-type plants while cab and psbE mRNA, LSu, SSu and cytochrome b559 remained at normal levels, suggesting that LCHP is more immediately affected by the Su mutant gene product than the rest of the photosynthetic proteins and mRNA examined. Under low light conditions, the levels of cab and psbE mRNA, LSu, SSu and cytochrome b559 in homozygous Su/Su plants were equivalent to those in wild-type plants except LHCP which remained undetectable. Similarly, the LHCP level in low light grown Su/+ plants still remained at 25% of wild-type level. These results indicate that the decrease in LHCP is independent of light conditions and has not resulted from photooxidation, whereas the depletion of other proteins and mRNA examined under high light growth conditions is a consequence of photooxidative damage to Su/Su plastids. Furthermore, transgenic Su/Su and Su/+ plants with a cauliflower mosaic virus 35S (CaMV 35S)-cab construct constitutively maintained high levels of cab mRNA but displayed the same pattern of diminished LHCP accumulation as their non-transformed counterparts when grown under both high and low light conditions. These results indicate that the Su mutation primarily causes depletion of LHCP. The depletion of LHCP leads to photooxidative damage which results in decreased cab mRNA levels and other pleiotropic lesions in Su/Su plants.     

Capacity for RNA synthesis in 70S ribosome-deficient plastids of heat-bleached rye leaves

In the leaves of rye seedlings (Secale cereale L.) grown at an elevated temperature of 32°C the formation of plastidic 70S ribosomes is specifically prevented. The resulting plastid ribosome-deficient leaves, which are chlorotic in light, represent a system for the identification of translation products of the 80S ribosomes among the chloroplastic proteins. Searching for the primary heat-sensitive event causing the 70S ribosome-deficiency, the thermostability of the chloroplastic capacity for RNA synthesis was investigated. The RNA polymerase activity of isolated normal chloroplasts from 22°-grown rye leaves was not inactivated in vitro at temperatures between 30° and 40°C. The ribosome-deficient plastids purified from bleached 32°-grown leaf parts contained significant RNA polymerase activity which was, however, lower than in functional chloroplasts. After application of [³H]uridine to intact leaf tissues [³H]uridine incorporation was found in ribosome-deficient plastids of 32°C-grown leaves. The amount of incorporation was similar to that in the control chloroplasts from 22°C-grown leaves. According to these results, it is unlikely that the non-permissive temperature (32°C) causes a general inactivation of the chloroplastic RNA synthesis in rye leaves.     

Arabidopsis Mutants Lacking the 43- and 54-Kilodalton Subunits of the Chloroplast Signal Recognition Particle Have Distinct Phenotypes

The chloroplast signal recognition particle (cpSRP) is a protein complex consisting of 54- and 43-kD subunits encoded by the fifty-four chloroplast, which encodes cpSRP54 (ffc), and chaos (cao) loci, respectively. Two new null alleles in the ffc locus have been identified. ffc1-1 is caused by a stop codon in exon 10, while ffc1-2 has a large DNA insertion in intron 8. ffc mutants have yellow first true leaves that subsequently become green. The reaction center proteins D1, D2, and psaA/B, as well as seven different light-harvesting chlorophyll proteins (LHCPs), were found at reduced levels in the young ffc leaves but at wild-type levels in the older leaves. The abundance of the two types of LHCP was unaffected by the mutation, while two others were increased in the absence of cpSRP54. Null mutants in the cao locus contain reduced levels of the same subset of LHCP proteins as ffc mutants, but are distinguishable in four ways: young leaves are greener, the chlorophyll a/b ratio is elevated, levels of reaction center proteins are normal, and there is no recovery in the level of LHCPs in the adult plant. The data suggest that cpSRP54 and cpSRP43 have some nonoverlapping roles and that alternative transport pathways can compensate for the absence of a functional cpSRP.