Light-regulated gene expression during maize leaf development

We have established schedules of expression during maize leaf development in light and darkness for the messenger RNAs (mRNAs) and polypeptides for ribulose 1,5-bisphosphate carboxylase (RuBPCase) subunits, phosphoenolpyruvate carboxylase (PEPCase), and the light- harvesting chlorophyll a/b-binding protein (LHCP). Levels of mRNAs were measured by hybridization with cloned probes, and proteins were measured by immunodetection on protein gel blots. The initial synthesis in leaves of all four mRNAs follows a light-independent schedule; illumination influences only the level to which each mRNA accumulates. The synthesis of RuBPCase small and large subunits and of PEPCase polypeptides also follows a light-independent schedule which is modified quantitatively by light. However, the accumulation of LHCP polypeptides absolutely requires illumination. The accumulation of each protein closely follows the accumulation of its mRNA during growth in light. Higher ratios of PEPCase and RuBPCase protein to mRNA occur during dark growth.     

Translational regulation of light-induced ribulose 1,5-bisphosphate carboxylase gene expression in amaranth.

The regulation of the genes encoding the large and small subunits of ribulose 1,5-bisphosphate carboxylase was examined in amaranth cotyledons in response to changes in illumination. When dark-grown cotyledons were transferred into light, synthesis of the large- and small-subunit polypeptides was initiated very rapidly, before any increase in the levels of their corresponding mRNAs. Similarly, when light-grown cotyledons were transferred to total darkness, synthesis of the large- and small-subunit proteins was rapidly depressed without changes in mRNA levels for either subunit. In vitro translation or in vivo pulse-chase experiments indicated that these apparent changes in protein synthesis were not due to alterations in the functionality of the mRNAs or to protein turnover, respectively. These results, in combination with our previous studies, suggest that the expression of ribulose 1,5-bisphosphate carboxylase genes can be adjusted rapidly at the translational level and over a longer period through changes in mRNA accumulation.     

White Light Effects on the mRNA for the Light-Harvesting Chlorophyll a/b-Protein in Lemna gibba L. G-3

Translation products of poly(A) mRNA isolated from Lemna gibba L. G-3 include a major polypeptide of 32,000 daltons which is immunoprecipitated by antiserum to chlorophyll a/b-protein from Chlamydomonas. This 32,000 dalton polypeptide represents a precursor to the light-harvesting chlorophyll a/b-protein of molecular weight 28,000 found in the thylakoid membranes of Lemna gibba. The amount of this translatable mRNA decreases relative to other translatable mRNAs when green plants grown in continuous white light are placed in darkness. This decrease occurs rapidly. The most rapid decline occurs during the first day; after 4 days of darkness, only a low level of this mRNA can be detected by in vitro translation. When the plants are returned to white light there is an increase in the relative level of this mRNA which can be easily detected within two hours. The in vivo synthesis of this protein has been assayed under the different light conditions. The light effects on the in vivo synthesis of the chlorophyll a/b-protein reflect the light effects on the translatable mRNA for the polypeptide. The results indicate that light induced changes in the synthesis, processing, or degradation of chlorophyll a/b-protein mRNA could account for the light-induced changes observed in the effective synthesis rates for the chlorophyll a/b-protein in vivo.     

The organisation and expression of the genes encoding the mitochondrial glycine decarboxylase complex and serine hydroxymethyltransferase in pea (Pisum sativum)

Summary Restriction fragment length polymorphisms have been used to determine the chromosomal location of the genes encoding the glycine decarboxylase complex (GDC) and serine hydroxymethyltransferase (SHMT) of pea leaf mitochondria. The genes encoding the H subunit of GDC and the genes encoding SHMT both show linkage to the classical group I marker i. In addition, the genes for the P protein of GDC show linkage to the classic group I marker a. The genes for the L and T proteins of GDC are linked to one another and are probably situated on the satellite of chromosome 7. The mRNAs encoding the five polypeptides that make up GDC and SHMT are strongly induced when dark-grown etiolated pea seedlings are placed in the light. Similarly, when mature plants are placed in the dark for 48 h, the levels of both GDC protein and SHMT mRNAs decline dramatically and then are induced strongly when these plants are returned to the light. During both treatments a similar pattern of mRNA induction is observed, with the mRNA encoding the P protein of GDC being the most rapidly induced and the mRNA for the H protein the slowest. Whereas during the greening of etiolated seedlings the polypeptides of GDC and SHMT show patterns of accumulation similar to those of the corresponding mRNAs, very little change in the level of the polypeptides is seen when mature plants are placed in the dark and then re-exposed to the light.     

Multiple coordinate controls contribute to a balanced expression of ribulose-1,5-bisphosphate carboxylase/oxygenase subunits in rye leaves

In the leaves of rye (Secale cereale L.), control mechanisms acting at multiple molecular levels contribute to a coordinate expression of the subunit polypeptides of ribulose-1,5-bisphosphate carboxylase. The relevance and hierarchy of the different control steps were evaluated by comparing the time courses of changes in levels of translatable mRNA, rates of in vivo amino acid incorporation, and the turnover of subunit polypeptides after selective interference with translation at either cytoplasmic 80S ribosomes, or at the 70S ribosomes of the chloroplast, by compartment-specific inhibitors, or by the use of 70S-ribosome-deficient leaves. The latter were generated by growing the plants at a non-permissive elevated temperature of 32 degrees C. The rates of synthesis of the two ribulose-1,5-bisphosphate carboxylase subunits were most rapidly adapted to each other by translational controls. Within 0.5-2.5 h after selective inhibition of the synthesis of either subunit, that of the other subunit made in the unaffected compartment also declined by more than 90% without any marked change in its mRNA. After prolonged inhibition (24 h) of either cytoplasmic or chloroplast protein synthesis, the levels of mRNAs for both subunits were greatly diminished. In rye, the mRNA levels for both subunits changed under all experimental conditions tested in a closely parallel manner and appeared to be always maintained in a balanced, fairly constant ratio by strong coordinate controls. Even 70S-ribosome-deficient leaves contained mRNAs for both the small and the large subunits, although only in small amounts. The mRNAs for both subunits were also markedly further decreased in 70S-ribosome-deficient leaves after application of an inhibitor of cytoplasmic translation. MDMP [2-(4-methyl-2,6-dinitroanilino)-N-methylpropionamide], suggesting that the suppression of the large subunit mRNA in the plastids was not mediated through feedback effects of accumulating unassembled large subunits. Coordinate controls at both the mRNA and the translational level require a bidirectional exchange of regulatory signals between chloroplast and cytoplasm. However, these controls were not absolutely restrictive and allowed low rates of uncoupled synthesis of either large or small subunits. Large subunits made in the presence of MDMP were stable over 24 h. However, unassembled small subunits synthesized in 70S-ribosome-deficient leaves were degraded with a half-time of 10.5 h, in contrast to their behavior after integration into the holoprotein in normal leaves, where no turnover was detected. The proteolytic removal of surplus free small subunits is regarded as a final post-translational fine-tuning step to establish a balanced subunit stoichiometry in leaves.     

Photocontrol of the Accumulation of Plastid Polypeptides during Greening of Tomato Cotyledons : Potentiation by a Pulse of Red Light

A pulse of red light acting through phytochrome accelerates the formation of chlorophyll upon subsequent transfer of dark-grown seedlings to continuous white light. Specific antibodies were used to follow the accumulation of representative subunits of the major photosynthetic complexes during greening of seedlings of tomato (Lycopersicon esculentum). The time course for accumulation of the various subunits was compared in seedlings that received a red light pulse 4 h prior to transfer to continuous white light and parallel controls that did not receive a red light pulse. The light-harvesting chlorophyll-binding proteins of photosystem II (LHC II), the 33-kD extrinsic polypeptide of the oxygen-evolving complex (OEC1), and subunit II of photosystem I (psaD gene product) all increased in the light, and did so much faster in seedlings that received the inductive red light pulse. The red light pulse had no significant effect on the abundance of the small subunit of ribulose 1,5-bisphosphate carboxylase/oxygenase (Rubisco), nor on several plastid-encoded polypeptides: the large subunit of Rubisco, the β subunit of the CF₁ complex of plastid ATPase, and the 43- and 47-kD subunits of photosystem II (CP43, CP47). Subunits I (cytochrome b₆f) and III (Rieske Fe-S protein) of the cytochrome b₆f complex showed a small or no increase as a result of the red pulse. The potentiation of greening by a pulse of red light, therefore, is not expressed uniformly in the abundance of all the photosynthetic complexes and their subunits.     

Evidence for lack of turnover of ribulose 1,5-diphosphate carboxylase in barley leaves

Turnover of ribulose 1,5-diphosphate carboxylase in barley leaves (Hordeum vulgare L.) was followed over time in light and dark. The enzyme was degraded in prolonged darkness and was resynthesized after the plants were returned to light. Labeling with ¹⁴C showed that simultaneous synthesis and degradation (turnover) did not occur in light. In contrast, the remaining soluble protein was turned over rapidly in light. Although ribulose 1,5-diP carboxylase can be both degraded and synthesized, these processes seem not to occur simultaneously, but can be induced independently by changing environmental conditions.     

Synthesis of Chloroplast Proteins during Germination and Early Development of Cucumber

Cell-free protein synthesizing systems have been used to study the developmental changes in the synthesis of chloroplast proteins in the cotyledons of cucumber seedlings grown in the light or in the dark. Escherichia coli and wheat germ in vitro protein synthesizing systems have been used to assay the changes in the levels of the mRNA's coding for ribulose 1,5-bisphosphate carboxylase (RuBPCase). The large subunit of cucumber RuBPCase has been identified among the translation products of the E. coli system. The wheat germ system translates the cucumber mRNA coding for the small subunit of RuBPCase to produce a 25,000 molecular weight precursor polypeptide. Plastids isolated from light-grown cotyledons were used to study developmental changes in their capacity to synthesize protein. The data obtained indicate that in the light there is an initial 48-hour period of accumulation of the mRNA's coding for the large and small subunits of RuBPCase, coupled with an increase in the capacity of the isolated plastids to synthesize protein. This is followed by a decline. This decline is not reflected in the accumulation of RuBPCase in the cotyledons which remains constant over the period of study.     

Coordinate Expression of Rubisco Activase and Rubisco during Barley Leaf Cell Development

We have utilized the cellular differentiation gradient and photomorphogenic responses of the first leaf of 7-day-old barley (Hordeum vulgare L.) to examine the accumulation of mRNA and protein encoded by the ribulose-1,5-biphosphate carboxylase holoenzyme (rubisco) activase gene (rca). Previous studies have revealed a pattern of coordinate expression of rubisco subunit polypeptides during development. We compared the expression of rubisco polypeptides and mRNAs with those encoded by rca. The mRNAs encoding both rubisco activase and rubisco are expressed exclusively in leaf tissue of 7-day-old barley seedlings; mRNAs and polypeptides of rca accumulate progressively from the leaf base in a pattern that is qualitatively similar to that of rubisco subunit mRNAs and polypeptides. The parallel pattern of rca protein and mRNA accumulation indicate that a primary control of rca gene expression in this system lies at the level of mRNA production. Light-induced expression of rca in etiolated barley follows a different pattern from that of the acropetal barley leaf gradient, however. Etiolated, 7-day-old barley seedlings contain levels of rca mRNA near the limit of detection in Northern blot hybridization assays. White light induces a 50- to 100-fold accumulation of rca mRNA, which is detectable within 30 min after the onset of illumination. In contrast, steady state levels of mRNAs encoding the small rubisco subunit are affected little by light, and mRNAs encoding the large subunit accumulate about 5-fold in response to illumination. While rca mRNA levels are low in etiolated barley leaves, levels of the protein are approximately 50 to 75% of those found in fully green leaves.     

Synthesis and turnover of the light-harvesting chlorophylla/b-protein inLemna gibba grown with intermittent red light: possible translational control

Lemna gibba L. G-3 plants grown heterotrophically in the dark with intermittent red light (2 min every 8 h) contain a substantial amount of translatable mRNA encoding the light-harvesting chlorophyll (Chl)a/b-protein. However, very little [³⁵S]methionine is incorporated into the apoproteins during a 1-h labeling period in the dark in these plants compared to plants grown in continuous white light. The Chla/b-protein mRNA is found to be associated with functioning polysomes in plants grown in the dark with intermittent red illumination (R plants). The small amounts of the apoproteins which are synthesized by these plants are found in the membrane fraction; neither the mature apoproteins nor their precursor(s) can be detected immunologically in the soluble fraction. The protein does not accumulate in these plants. Pulse-chase experiments with the R plants demonstrate that the newly synthesized apoproteins have a half-life of about 10 h in the dark. This turnover is not sufficient to explain the observed 20-fold difference in [³⁵S]methionine incorporation into the apoprotein between white-light-grown and R plants. We therefore suggest that the synthesis of the Chla/b-apoproteins can be regulated by a light-dependent step at the level of translation, and that this regulation occurs after the initiation of translation.Abbreviations Chl chlorophyll - W Lemna plants grown in continuous white light - R plants grown heterotrophically in the dark with intermittent red light (2 min/8 h)     

Induction of a Carbon-Starvation-Related Proteolysis in Whole Maize Plants Submitted to Light/Dark Cycles and to Extended Darkness

Three-week-old maize (Zea mays L.) plants were submitted to light/dark cycles and to prolonged darkness to investigate the occurrence of sugar-limitation effects in different parts of the whole plant. Soluble sugars fluctuated with light/dark cycles and dropped sharply during extended darkness. Significant decreases in protein level were observed after prolonged darkness in mature roots, root tips, and young leaves. Glutamine and asparagine (Asn) changed in opposite ways, with Asn increasing in the dark. After prolonged darkness the increase in Asn accounted for most of the nitrogen released by protein breakdown. Using polyclonal antibodies against a vacuolar root protease previously described (F. James, R. Brouquisse, C. Suire, A. Pradet, P. Raymond [1996] Biochem J 320: 283–292) or the 20S proteasome, we showed that the increase in proteolytic activities was related to an enrichment of roots in the vacuolar protease, with no change in the amount of 20S proteasome in either roots or leaves. Our results show that no significant net proteolysis is induced in any part of the plant during normal light/dark cycles, although changes in metabolism and growth appear soon after the beginning of the dark period, and starvation-related proteolysis probably appears in prolonged darkness earlier in sink than in mature tissues.     

Proteolysis of endogenous substrates in senescing oat leaves : I. Specific degradation of ribulose bisphosphate carboxylase

Proteolysis of ribulose bisphosphate carboxylase (RuBPCase) during senescence was monitored using oat leaf segments (Avena sativa cv Victory), kept in the dark. We here report the development of a novel approach for measuring protein degradation of endogenous substrates both in situ and in vitro in crude extracts using specific antibodies against highly purified polypeptides. The proteolytic products were separated on sodium dodecyl sulfate-gels. They were then electrotransferred onto nitrocellulose paper and identified with specific antibodies to both the large and small subunits of RuBPCase. We could show differences in pH optima between two proteases degrading the subunits of RuBPCase. While both subunits were best hydrolyzed in acid and basic pH, they degraded differently at neutral pH. Furthermore, the large subunit displayed a different pattern of degradative products at the different pH levels. Older leaf segments, which were incubated in darkness, underwent enhanced proteolysis, as compared with young ones. These results show the advantages of the assay in demonstrating: (a) in situ proteolysis of specific substrates in crude extracts without further purification; (b) in vitro differential proteolysis of endogenous substrates during senescence.     

Immunological determination of phosphoenolpyruvate carboxylase and the large and small subunits of ribulose 1,5-bisphosphate carboxylase in leaves of the c(4) plant pearl millet

The light-dependent development of the photosynthetic apparatus in the first leaf of the C₄ plant pearl millet (Pennisetum americanum) was monitored by immunologically determining the concentration of phospho-enolpyruvate carboxylase and ribulose 1,5-bisphosphate carboxylase. A competitive enzyme-linked immunosorbent assay procedure using antibodies to the monomeric subunit of phosphoenolpyruvate carboxylase and the large and small subunit of ribulose 1,5-bisphosphate carboxylase was used to quantitate the amounts of these polypeptides in the first leaf of etiolated seedlings and etiolated seedlings exposed to light for varying periods of time. Phosphoenolpyruvate carboxylase was present in etiolated tissue; however, light stimulated its synthesis nearly 23-fold. Maximum accumulation of phosphoenolpyruvate carboxylase occurred approximately 4 days after etiolated plants were placed in the light. Both the large subunit and the small subunit of ribulose 1,5-bisphosphate carboxylase were present in leaves of etiolated seedlings. Light also stimulated the synthesis of both of these polypeptides, but at different rates. In etiolated leaves there was approximately a 3-fold molar excess of the small subunit to large subunit. Exposure of the etiolated leaves to light resulted in the molar ratio of the large subunit to the small subunit increasing to approximately 0.72. These data indicate that the net synthesis of these two polypeptides is not coordinately regulated at all times.