Evidence That an Internal Carbonic Anhydrase Is Present in 5% CO(2)-Grown and Air-Grown Chlamydomonas

Inorganic carbon (C_i) uptake was measured in wild-type cells of Chlamydomonas reinhardtii, and in cia-3, a mutant strain of C. reinhardtii that cannot grow with air levels of CO₂. Both air-grown cells, that have a CO₂ concentrating system, and 5% CO₂-grown cells that do not have this system, were used. When the external pH was 5.1 or 7.3, air-grown, wild-type cells accumulated inorganic carbon (C_i) and this accumulation was enhanced when the permeant carbonic anhydrase inhibitor, ethoxyzolamide, was added. When the external pH was 5.1, 5% CO₂-grown cells also accumulated some C_i, although not as much as air-grown cells and this accumulation was stimulated by the addition of ethoxyzolamide. At the same time, ethoxyzolamide inhibited CO₂ fixation by high CO₂-grown, wild-type cells at both pH 5.1 and 7.3. These observations imply that 5% CO₂-grown, wild-type cells, have a physiologically important internal carbonic anhydrase, although the major carbonic anhydrase located in the periplasmic space is only present in air-grown cells. Inorganic carbon uptake by cia-3 cells supported this conclusion. This mutant strain, which is thought to lack an internal carbonic anhydrase, was unaffected by ethoxyzolamide at pH 5.1. Other physiological characteristics of cia-3 resemble those of wild-type cells that have been treated with ethoxyzolamide. It is concluded that an internal carbonic anhydrase is under different regulatory control than the periplasmic carbonic anhydrase.     

Periplasmic Carbonic Anhydrase Structural Gene (Cah1) Mutant in Chlamydomonas reinhardtii

To survive in various conditions of CO₂ availability, Chlamydomonas reinhardtii shows adaptive changes, such as induction of a CO₂-concentrating mechanism, changes in cell organization, and induction of several genes, including a periplasmic carbonic anhydrase (pCA1) encoded by Cah1. Among a collection of insertionally generated mutants, a mutant has been isolated that showed no pCA1 protein and no Cah1 mRNA. This mutant strain, designated cah1-1, has been confirmed to have a disruption in the Cah1 gene caused by a single Arg7 insert. The most interesting feature of cah1-1 is its lack of any significant growth phenotype. There is no major difference in growth or photosynthesis between the wild type and cah1-1 over a pH range from 5.0 to 9.0 even though this mutant apparently lacks Cah1 expression in air. Although the presence of pCA1 apparently gives some minor benefit at very low CO₂ concentrations, the characteristics of this Cah1 null mutant demonstrate that pCA1 is not essential for function of the CO₂-concentrating mechanism or for growth of C. reinhardtii at limiting CO₂ concentrations.     

Mitochondrial carbonic anhydrases are needed for optimal photosynthesis at low CO2 levels in Chlamydomonas

Chlamydomonas reinhardtii can grow photosynthetically using CO₂ or in the dark using acetate as the carbon source. In the light in air, the CO₂ concentrating mechanism (CCM) of C. reinhardtii accumulates CO₂, enhancing photosynthesis. A combination of carbonic anhydrases (CAs) and bicarbonate transporters in the CCM of C. reinhardtii increases the CO₂ concentration at Ribulose 1,5-bisphosphate carboxylase oxygenase (Rubisco) in the chloroplast pyrenoid. Previously, CAs important to the CCM have been found in the periplasmic space, surrounding the pyrenoid and inside the thylakoid lumen. Two almost identical mitochondrial CAs, CAH4 and CAH5, are also highly expressed when the CCM is made, but their role in the CCM is not understood. Here, we adopted an RNAi approach to reduce the expression of CAH4 and CAH5 to study their possible physiological functions. RNAi mutants with low expression of CAH4 and CAH5 had impaired rates of photosynthesis under ambient levels of CO₂ (0.04% CO₂ [v/v] in air). These strains were not able to grow at very low CO₂ (<0.02% CO₂ [v/v] in air), and their ability to accumulate inorganic carbon (C_i = CO₂ + HCO3−) was reduced. At low CO₂ concentrations, the CCM is needed to both deliver C_i to Rubisco and to minimize the leak of CO₂ generated by respiration and photorespiration. We hypothesize that CAH4 and CAH5 in the mitochondria convert the CO₂ released from respiration and photorespiration as well as the CO₂ leaked from the chloroplast to HCO3- thus “recapturing” this potentially lost CO₂.

Mitochondrial carbonic anhydrases CAH4 and CAH5 in Chlamydomonas reinhardtii are involved in maintaining optimal photosynthesis.     

A New Chloroplast Protein Is Induced by Growth on Low CO(2) in Chlamydomonas reinhardtii

The biosynthesis of a 36 kilodalton polypeptide of Chlamydomonas reinhardtii was induced by photoautotrophic growth on low CO₂. Fractionation studies using the cell-wall-deficient strain of C. reinhardtii, CC-400, showed that this polypeptide was different from the low CO₂-induced periplasmic carbonic anhydrase. In addition, the 36 kilodalton polypeptide was found to be localized in intact chloroplasts isolated from low CO₂-adapting cultures. This protein may, in part, account for the different inorganic carbon uptake characteristics observed in chloroplasts isolated from high and low CO₂-grown C. reinhardtii cells.     

Complementation analysis of the inorganic carbon concentrating mechanism of Chlamydomonas reinhardtii

Summary Six independently isolated mutants of Chlamydomonas reinhardtii that require elevated CO₂ for photoautotrophic growth were tested by complementation analysis. These mutants are likely to be defective in some aspect of the algal concentrating mechanism for inorganic carbon as they exhibit CO₂ fixation and inorganic carbon accumulation properties different from the wild-type. Four of the six mutants defined a single complementation group and appear to be defective in an intracellular carbonic anhydrase. The other two mutations represent two additional complementation groups.Abbreviations HS high salt medium which has 13 mM phosphate at pH 6.8 - HSA high salt plus 36 mM acetate medium - YA high salt medium with 4 g yeast extract per L and 36mM acetate - Arg arginine - cia^- CO₂ accumulation mutants that cannot grow on low CO₂ - C_i inorganic carbon (CO₂+HCO _- ³ ) - CA carbonic anhydrase - mt mating type Supported in part by the McKnight Foundation and by NSF grant PCM 8005917 and published as journal article 11924 from the Michigan State Agriculatural Experiment Station     

Evidence for Inorganic Carbon Transport by Intact Chloroplasts of Chlamydomonas reinhardtii

Isolated intact chloroplasts from wall-less mutants of Chlamydomonas reinhardtii accumulate inorganic carbon (C_i) from the medium provided the cells had been adapted to low CO₂ photoautotrophic growth conditions. Chloroplasts from cultures grown on high (5%) CO₂ or photoheterotrophically with acetate did not accumulate inorganic carbon. Chloroplast C_i accumulation from low CO₂ grown cells was light dependent and was inhibited by uncouplers and inhibitors of electron transport. In a model for C_i accumulation by Chlamydomonas, it is proposed that CO₂ diffuses into the cell and C_i accumulation occurs in the chloroplast.     

Mutants of Synechocystis PCC6803 Defective in Inorganic Carbon Transport

Eighty mutants of Synechocystis PCC6803 that require high CO₂ for growth were examined with a mass spectrometer for their ability to take up CO₂ in the light. Two of these mutants (type A) did not show any CO₂ uptake while the rest of the mutants (type B) took up CO₂ actively. Type A mutants (RKa and RKb) and one type B mutant (RK11) were partially characterized. At 3% CO₂, growth rates of the mutants and the wild type (WT) were similar. Under air levels of CO₂, growth of RKa and RKb was very slow, and RK11 did not grow at all. The photosynthetic affinities for inorganic carbon (C_i) in these three mutants were about 100 times lower than the affinity in WT. The following characteristics of type A mutants indicated that the mutants have a defect in their CO₂-transport system: (a) the activity of ¹³C¹⁸O₂ uptake in RKa and RKb in the light was less than 5% the activity in WT, and (b) each mutant had only a low level of activity of ¹⁴CO₂ uptake as measured by the method of silicone oil-filtering centrifugation. The HCO₃⁻-transport system was also impaired in these mutants. The activity of H¹⁴CO₃⁻ uptake was negligibly low in RKb and was one-third the activity of WT in RKa. On the other hand, the type B mutant, RK11, transported CO₂ and HCO₃⁻ into the intracellular C_i pool as actively as WT but was unable to utilize it for photosynthesis. Complementation analysis of type A mutants indicated that RKa and RKb have mutations in different regions of the genome. These results suggested that at least two kinds of proteins are involved in the C_i-transport system.     

Changes in Photorespiratory Enzyme Activity in Response to Limiting CO(2) in Chlamydomonas reinhardtii

The activity of two photorespiratory enzymes, phosphoglycolate phosphatase (PGPase) and glycolate dehydrogenase (glycolate DH), changes when CO₂-enriched wild-type (WT) Chlamydomonas reinhardtii cells are transferred to air levels of CO₂. Adaptation to air levels of CO₂ by Chlamydomonas involves induction of a CO₂-concentrating mechanism (CCM) which increases the internal inorganic carbon concentration and suppresses oxygenase activity of ribulose-1,5-bisphosphate carboxylase/oxygenase. PGPase in cell extracts shows a transient increase in activity that reaches a maximum 3 to 5 hours after transfer and then declines to the original level within 48 hours. The decline in PGPase activity begins at about the time that physiological evidence indicates the CCM is approaching maximal activity. Glycolate DH activity in 24 hour air-adapted WT cells is double that seen in CO₂-enriched cells. Unlike WT, the high-CO₂-requiring mutant, cia-5, does not respond to limiting CO₂ conditions: it does not induce any known aspects of the CCM and it does not show changes in PGPase or glycolate DH activities. Other known mutants of the CCM show patterns of PGPase and glycolate DH activity after transfer to limiting CO₂ which are different from WT and cia-5 but which are consistent with changes in activity being initiated by the same factor that induces the CCM, although secondary regulation must also be involved.     

Adaptation of Chlamydomonas reinhardtii High-CO(2)-Requiring Mutants to Limiting CO(2)

Photosynthetic characteristics of four high-CO₂-requiring mutants of Chlamydomonas reinhardtii were compared to those of wild type before and after a 24-hour exposure to limiting CO₂ concentrations. The four mutants represent two loci involved in the CO₂-concentrating system of this unicellular alga. All mutants had a lower photosynthetic affinity for inorganic carbon than did the wild type when grown at an elevated CO₂ concentration, indicating that the genetic lesion in each is expressed even at elevated CO₂ concentrations. Wild type and all four mutants exhibited adaptive responses to limiting CO₂ characteristic of the induction of the CO₂-concentrating system, resulting in an increased affinity for inorganic carbon only in wild type. Although other components of the CO₂-concentrating system were induced in these mutants, the defective component in each was sufficient to prevent any increase in the affinity for inorganic carbon. It was concluded that the genes corresponding to the ca-1 and pmp-1 loci exhibit at least partially constitutive expression and that all components of the CO₂-concentrating system may be required to significantly affect the photosynthetic affinity for inorganic carbon.     

Identification of Extracellular Carbonic Anhydrase of Chlamydomonas reinhardtii

We have examined the induction of carbonic anhydrase activity in Chlamydomonas reinhardtii and have identified the polypeptide responsible for this activity. This polypeptide was not synthesized when the alga was grown photoautotrophically on 5% CO₂, but its synthesis was induced under low concentrations of CO₂ (air levels of CO₂). In CW-15, a mutant of C. reinhardtii which lacks a cell wall, between 80 and 90% of the carbonic anhydrase activity of air-adapted cells was present in the growth medium. Furthermore, between 80 and 90% of the carbonic anhydrase is released if wild type cells are treated with autolysin, a hydrolytic enzyme responsible for cell wall degradation during mating of C. reinhardtii. These data extend the work of Kimpel, Togasaki, Miyachi (1983 Plant Cell Physiol 24: 255-259) and indicate that the bulk of the carbonic anhydrase is located either in the periplasmic space or is loosely bound to the algal cell wall. The polypeptide associated with carbonic anhydrase activity has a molecular weight of approximately 37,000. Several lines of evidence indicate that this polypeptide is responsible for carbonic anhydrase activity: (a) it appears following the transfer of C. reinhardtii from growth on 5% CO₂ to growth on air levels of CO₂, (b) it is located in the periplasmic space or associated with the cell wall, like the bulk of the carbonic anhydrase activity, (c) it binds dansylamide, an inhibitor of the enzyme which fluoresces upon illumination with ultraviolet light, (d) antibodies which inhibit carbonic anhydrase activity only cross-react with this 37,000 dalton species.     

A Mutant of Arabidopsis thaliana that Exhibits Chlorosis in Air but Not in Atmospheres Enriched in CO(2)

A mutant of Arabidopsis thaliana (L.) Heynh. which requires a high concentration (2% by volume) of atmospheric CO₂ for growth has been isolated. Unlike previous mutants of this type, this line does not have any apparent defect in photosynthetic CO₂-fixation, photorespiration, or photosynthetic electron transport. The mutant is abnormally susceptible to pigment bleaching in air but not in 2% CO₂. The presence of normal or above-normal levels of antioxidants, carotenoids, and enzymes involved in reactive oxygen detoxification suggests that the mutant is equipped to detoxify activated oxygen species. Although it was not possible to establish a biochemical basis for the lesion, the properties of the mutant suggest the existence of a previously unidentified role for CO₂.     

The carbon concentrating mechanism in Chlamydomonas reinhardtii: finding the missing pieces

The photosynthetic, unicellular green alga, Chlamydomonas reinhardtii, lives in environments that often contain low concentrations of CO₂ and HCO₃ ^?, the utilizable forms of inorganic carbon (C_i). C. reinhardtii possesses a carbon concentrating mechanism (CCM) which can provide suitable amounts of C_i for growth and development. This CCM is induced when the CO₂ concentration is at air levels or lower and is comprised of a set of proteins that allow the efficient uptake of C_i into the cell as well as its directed transport to the site where Rubisco fixes CO₂ into biomolecules. While several components of the CCM have been identified in recent years, the picture is still far from complete. To further improve our knowledge of the CCM, we undertook a mutagenesis project where an antibiotic resistance cassette was randomly inserted into the C. reinhardtii genome resulting in the generation of 22,000 mutants. The mutant collection was screened using both a published PCR-based approach (Gonzalez-Ballester et al. 2011) and a phenotypic growth screen. The PCR-based screen did not rely on a colony having an altered growth phenotype and was used to identify colonies with disruptions in genes previously identified as being associated with the CCM-related gene. Eleven independent insertional mutations were identified in eight different genes showing the usefulness of this approach in generating mutations in CCM-related genes of interest as well as identifying new CCM components. Further improvements of this method are also discussed.     

Carbon allocation and element composition in four Chlamydomonas mutants defective in genes related to the CO2 concentrating mechanism

Four mutants of Chlamydomonas reinhardtii with defects in different components of the CO₂ concentrating mechanism (CCM) or in Rubisco activase were grown autotrophically at high pCO₂ and then transferred to low pCO₂, in order to study the role of different components of the CCM on carbon allocation and elemental composition. To study carbon allocation, we measured the relative size of the main organic pools by Fourier Transform Infrared spectroscopy. Total reflection X-ray fluorescence was used to analyze the elemental composition of algal cells. Our data show that although the organic pools increased their size at high CO₂ in all strains, their stoichiometry was highly homeostatic, i.e., the ratios between carbohydrates and proteins, lipid and proteins, and carbohydrates and lipids, did not change significantly. The only exception was the wild-type 137c, in which proteins decreased relative to carbohydrates and lipids, when the cells were transferred to low CO₂. It is noticeable that the two wild types used in this study responded differently to the transition from high to low CO₂. Malfunctions of the CCM influenced the concentration of several elements, somewhat altering cell elemental stoichiometry: especially the C/P and N/P ratios changed appreciably in almost all strains as a function of the growth CO₂ concentration, except in 137c and the Rubisco activase mutant rca1. In strain cia3, defective in the lumenal carbonic anhydrase (CA), the cell quotas of P, S, Ca, Mn, Fe, and Zn were about 5-fold higher at low CO₂ than at high CO₂. A Principle Components Analysis showed that, mostly because of its elemental composition, cia3 behaved in a substantially different way from all other strains, at low CO₂. The lumenal CA thus plays a crucial role, not only for the correct functioning of the CCM, but also for element utilization. Not surprisingly, growth at high CO₂ attenuated differences among strains.     

A Mutant of Arabidopsis thaliana Which Lacks Activation of RuBP Carboxylase In Vivo

A mutant of Arabidopsis thaliana has been isolated in which ribulose-1,5-bisphosphate carboxylase is present in a nonactivatable form in vivo. The mutation appears to affect carboxylase activation specifically, and not any other enzyme of the photosynthesis or photorespiratory cycles. The effect of the mutation on carboxylase activation is indirect, inasmuch as the properties of ribulose-1,5-bisphosphate carboxylase purified from the mutant are not distinguishable from those of the wild type enzyme. The mutant requires high levels of atmospheric CO₂ for growth because photosynthesis is severely impaired in atmospheres containing normal levels of CO₂, irrespective of the atmospheric O₂ concentration. In this respect, the mutant is distinguished from previously described high-CO₂ requiring mutants of Arabidopsis which have defects in photorespiratory carbon or nitrogen metabolism.     

Differential responses of the sunn4 and rdn1-1 super-nodulation mutants of Medicago truncatula to elevated atmospheric CO2

Background and AimsNitrogen fixation in legumes requires tight control of carbon and nitrogen balance. Thus, legumes control nodule numbers via an autoregulation mechanism. ‘Autoregulation of nodulation’ mutants super-nodulate are thought to be carbon-limited due to the high carbon-sink strength of excessive nodules. This study aimed to examine the effect of increasing carbon supply on the performance of super-nodulation mutants.MethodsWe compared the responses of Medicago truncatula super-nodulation mutants (sunn-4 and rdn1-1) and wild type to five CO₂ levels (300–850 μmol mol⁻¹). Nodule formation and nitrogen fixation were assessed in soil-grown plants at 18 and 42 d after sowing.Key ResultsShoot and root biomass, nodule number and biomass, nitrogenase activity and fixed nitrogen per plant of all genotypes increased with increasing CO₂ concentration and reached a maximum at 700 μmol mol⁻¹. While the sunn-4 mutant showed strong growth retardation compared with wild-type plants, elevated CO₂ increased shoot biomass and total nitrogen content of the rdn1-1 mutant up to 2-fold. This was accompanied by a 4-fold increase in nitrogen fixation capacity in the rdn1-1 mutant.ConclusionsThese results suggest that the super-nodulation phenotype per se did not limit growth. The additional nitrogen fixation capacity of the rdn1-1 mutant may enhance the benefit of elevated CO₂ for plant growth and N₂ fixation.     

Transposon Tn5-Generated Bradyrhizobium japonicum Mutants Unable To Grow Chemoautotrophically with H2

Twelve Tn5-induced mutants of Bradyrhizobium japonicum unable to grow chemoautotrophically with CO₂ and H₂ (Aut⁻) were isolated. Five Aut⁻ mutants lacked hydrogen uptake activity (Hup⁻). The other seven Aut⁻ mutants possessed wild-type levels of hydrogen uptake activity (Hup⁺), both in free-living culture and symbiotically. Three of the Hup⁻ mutants lacked hydrogenase activity both in free-living culture and as nodule bacteroids. The other two mutants were Hup⁻ only in free-living culture. The latter two mutants appeared to be hypersensitive to repression by oxygen, since Hup activity could be derepressed under 0.4% O₂. All five Hup⁻ mutants expressed both ex planta and symbiotic nitrogenase activities. Two of the seven Aut⁻ Hup⁺ mutants expressed no free-living nitrogenase activity, but they did express it symbiotically. These two strains, plus one other Aut⁻ Hup⁺ mutant, had CO₂ fixation activities 20 to 32% of the wild-type level. The cosmid pSH22, which was shown previously to contain hydrogenase-related genes of B. japonicum, was conjugated into each Aut⁻ mutant. The Aut⁻ Hup⁻ mutants that were Hup⁻ both in free-living culture and symbiotically were complemented by the cosmid. None of the other mutants was complemented by pSH22. Individual subcloned fragments of pSH22 were used to complement two of the Hup⁻ mutants.     

High light‐induced hydrogen peroxide production in Chlamydomonas reinhardtii is increased by high CO2 availability

The production of reactive oxygen species (ROS) is an unavoidable part of photosynthesis. Stress that accompanies high light levels and low CO₂ availability putatively includes enhanced ROS production in the so‐called Mehler reaction. Such conditions are thought to encourage O₂ to become an electron acceptor at photosystem I, producing the ROS superoxide anion radical () and hydrogen peroxide (H₂O₂). In contrast, here it is shown in Chlamydomonas reinhardtii that CO₂ depletion under high light levels lowered cellular H₂O₂ production, and that elevated CO₂ levels increased H₂O₂ production. Using various photosynthetic and mitochondrial mutants of C. reinhardtii, the chloroplast was identified as the main source of elevated H₂O₂ production under high CO₂ availability. High light levels under low CO₂ availability induced photoprotective mechanisms called non‐photochemical quenching, or NPQ, including state transitions (qT) and high energy state quenching (qE). The qE‐deficient mutant npq4 produced more H₂O₂ than wild‐type cells under high light levels, although less so under high CO₂ availability, whereas it demonstrated equal or greater enzymatic H₂O₂‐degrading capacity. The qT‐deficient mutant stt7‐9 produced the same H₂O₂ as wild‐type cells under high CO₂ availability. Physiological levels of H₂O₂ were able to hinder qT and the induction of state 2, providing an explanation for why under high light levels and high CO₂ availability wild‐type cells behaved like stt7‐9 cells stuck in state 1.     

Effect of red and blue light on acclimation of <Emphasis Type="Italic">Chlamydomonas reinhardtii</Emphasis> to CO<Subscript>2</Subscript>-limiting conditions

Effects of red (RL) and blue (BL) light on acclimation of the unicellular green alga Chlamydomonas reinhardtii to the low level of ambient CO₂ were studied. C. reinhardtii cells grown at 5% CO₂ and under white light (170 μmol/(m²s)) had a relatively low activity of extracellular carbonic anhydrase (CA), a low affinity for dissolved inorganic carbon, and a low rate of photosynthesis under CO₂-limiting conditions. These cells readily started acclimation to the low CO₂ concentration when they were exposed to atmospheric air (～ 0.03% CO₂) under RL or BL (150 μmol/(m² s) each). The acclimation was manifested in a significant increase in the CO₂-limited rate of photosynthesis, the affinity for dissolved inorganic carbon, and the extracellular CA activity with no difference between RL-and BL-cells. Independently of light quality, the acclimation was completed for 5–7 h after cell exposure to air. As is evident from RL-and BL-dependent changes in the sum of chlorophylls and chlorophyll a/b ratio, transfer of C. reinhardtii cells to air and RL or BL triggered also the process of algal photosynthetic adaptation to light quality. However, this process did not interfere with acclimation to low CO₂ because started 4 h later. On the basis of similarity in the low CO₂-induced changes under RL and BL, it is concluded that acclimation of C. reinhardtii to CO₂-limiting conditions does not depend on light quality.     

Isolation and Characterization of High CO(2)-Requiring-Mutants of the Cyanobacterium Synechococcus PCC7942 : Two Phenotypes that Accumulate Inorganic Carbon but Are Apparently Unable to Generate CO(2) within the Carboxysome

A total of 24 high CO₂-requiring-mutants of the cyanobacterium Synechococcus PCC7942 have been isolated and partially characterized. These chemically induced mutants are able to grow at 1% CO₂, on agar media, but are incapable of growth at air levels of CO₂. All the mutants were able to accumulate inorganic carbon (C_i) to levels similar to or higher than wild type cells, but were apparently unable to generate intracellular CO₂. On the basis of the rate of C_i release following a light (5 minutes) → dark transition two extreme phenotypes (fast and slow release mutants) and a number of `intermediate' mutants (normal release) were identified. Compared to wild-type cells, Type I mutants had the following characteristics: fast C_i release, normal internal C_i pool, normal carbonic anhydrase (CA) activity in crude extracts, reduced internal exchange of ¹⁸O from ¹⁸O-labeled CO₂, 1% CO₂ requirement for growth in liquid media, normal affinity of carboxylase for CO₂, and long, rod-like carboxysomes. Type II mutants had the following characteristics: slow C_i release, increased internal C_i pool, normal CA activity in crude extracts, normal internal ¹⁸O exchange, a 3% CO₂ requirement for growth in liquid media, high carboxylase activity, normal affinity of carboxylase for CO₂, and normal carboxysome structure but increased in numbers per cell. Both mutant phenotypes appear to have genetic lesions that result in an inability to convert intracellular HCO₃⁻ to CO₂ inside the carboxysome. The features of the type I mutants are consistent with a scenario where carboxysomal CA has been mistargeted to the cytosol. The characteristics of the type II phenotype appear to be most consistent with a scenario where CA activity is totally missing from the cell except for the fact that cell extracts have normal CA activity. Alternatively the type II mutants may have a lesion in their capacity for H⁺ import during photosynthesis.