Analysis of an Arabidopsis heat‐sensitive mutant reveals that chlorophyll synthase is involved in reutilization of chlorophyllide during chlorophyll turnover

Chlorophylls, the most abundant pigments in the photosynthetic apparatus, are constantly turned over as a result of the degradation and replacement of the damage‐prone reaction center D1 protein of photosystem II. Results from isotope labeling experiments suggest that chlorophylls are recycled by reutilization of chlorophyllide and phytol, but the underlying mechanism is unclear. In this study, by characterization of a heat‐sensitive Arabidopsis mutant we provide evidence of a salvage pathway for chlorophyllide a. A missense mutation in CHLOROPHYLL SYNTHASE (CHLG) was identified and confirmed to be responsible for a light‐dependent, heat‐induced cotyledon bleaching phenotype. Following heat treatment, mutant (chlg‐1) but not wild‐type seedlings accumulated a substantial level of chlorophyllide a, which resulted in a surge of phototoxic singlet oxygen. Immunoblot analysis suggested that the mutation destabilized the chlorophyll synthase proteins and caused a conditional blockage of esterification of chlorophyllide a after heat stress. Accumulation of chlorophyllide a after heat treatment occurred during recovery in the dark in the light‐grown but not the etiolated seedlings, suggesting that the accumulated chlorophyllides were not derived from de novo biosynthesis but from de‐esterification of the existing chlorophylls. Further analysis of the triple mutant harboring the CHLG mutant allele and null mutations of CHLOROPHYLLASE1 (CLH1) and CLH2 indicated that the known chlorophyllases are not responsible for the accumulation of chlorophyllide a in chlg‐1. Taken together, our results show that chlorophyll synthase acts in a salvage pathway for chlorophyll biosynthesis by re‐esterifying the chlorophyllide a produced during chlorophyll turnover.     

Yeast 5-aminolevulinate synthase provides additional chlorophyll precursor in transgenic tobacco

Synthesis of the tetrapyrrole precursor 5-aminolevulinate (ALA) in plants starts with glutamate and is a tRNA-dependent pathway consisting of three enzymatic steps localized in plastids. In animals and yeast, ALA is formed in a single step from succinyl CoA and glycine by aminolevulinate synthase (ALA-S) in mitochondria. A gene encoding a fusion protein of yeast ALA-S with an amino-terminal transit sequence for the small subunit of ribulose bisphosphate carboxylase was introduced into the genome of wild-type tobacco and a chlorophyll-deficient transgenic line expressing glutamate 1-semi-aldehyde aminotransferase (GSA-AT) antisense RNA. Expression of ALA-S in the GSA-AT antisense transgenic line provided green-pigmented co-transformants similar to wild-type in chlorophyll content, while transformants derived from wild-type plants did not show phenotypical changes. The capacity to synthesize ALA and chlorophyll was increased in transformed plants, indicating a contribution of ALA-S to the ALA supply for chlorophyll synthesis. ALA-S activity was detected in plastids of the transformants. Preliminary evidence is presented that succinyl CoA, the substrate for ALA-S, can be synthesized and metabolized in plastids. The transgenic plants formed chlorophyll in the presence of gabaculine, an inhibitor of GSA-AT. Steady-state RNA and protein levels and, consequently, the enzyme activity of GSA-AT were reduced in plants expressing ALA-S. In analogy to the light-dependent ALA synthesis attributed to feedback regulation, a mechanism at the level of intermediates or tetrapyrrole end-products is proposed, which co-ordinates the need for heme and chlorophyll precursors and restricts synthesis of ALA by regulating GSA-AT gene expression. The genetically engineered tobacco plants containing the yeast ALA-S activity demonstrate functional complementation of the catalytic activity of the plant ALA-synthesizing pathway and open strategies for producing tolerance against inhibitors of the C5 pathway.     

Overexpression of HEMA1 encoding glutamyl-tRNA reductase

5-Aminolevulinic acid (ALA) synthesis has been shown to be the rate limiting step of tetrapyrrole biosynthesis. Glutamyl-tRNA reductase (GluTR) is the first committed enzyme of plant ALA synthesis and is controlled by interacting regulators, such as heme and the FLU protein. Induced inactivation of the HEMA1 gene encoding GluTR by RNAi expression in tobacco resulted in a reduced activity of Mg chelatase and Fe chelatase indicating a feed-forward regulatory mechanism that links ALA synthesis posttranslationally with late enzymes of tetrapyrrole biosynthesis (Hedtke et al., 2007). Here, the regulatory impact of GluTR was investigated by overexpression of AtHEMA1 in Arabidopsis and tobacco plants. Light-dependent ALA synthesis cannot benefit from an up to 7-fold induced expression of GluTR in Arabidopsis. While constitutive AtHEMA1 overexpression in tobacco stimulates ALA synthesis by 50-90% during light-exposed growth of seedlings, no increase in heme and chlorophyll contents is observed. HEMA1 overexpression in etiolated and dark-grown Arabidopsis and tobacco seedlings leads to additional accumulation of protochlorophyllide. As excessive accumulation of GluTR does not correlate with increased ALA formation, it is hypothesized that ALA synthesis is additionally limited by other effectors that balance the allocation of ALA with the activity of enzymes of chlorophyll and heme biosynthesis.     

Influence of gabaculine on growth,chlorophyll synthesis,and δ-aminolevulinic acid synthase activity in Euglena gracilis

Euglena gracilis is capable of forming the heme and chlorophyll precursor δ-aminolevulinic acid (ALA) by two routes: from glutamate via the five-carbon path in the chloroplasts, and by ALA synthase-mediated condensation of succinyl-CoA and glycine, probably in the mitochondrion. 5-Amino-1,3-cyclohexadienyl carboxylic acid (gabaculine), a powerful inhibitor of ALA formation via the five-carbon path, was administered to E. gracilis Klebs strain Z Pringsheim cells growing in the light or dark, and its effects on growth, chlorophyll accumulation and extractable ALA synthase activity were measured. Gabaculine had no effect in vitro on ALA synthase or ALA dehydratase, even at 100 μM. Administration of 100 μM gabaculine to wild-type cells growing in the light slowed growth, inhibited chlorophyll accumulation, and induced an increase in extractable ALA synthase activity. Chlorophyll accumulation in the light was abolished by prior administration of the compound to growing cells for 6 h in the dark, whereas chlorophyll accumulation in cells without gabaculine began immediately after transfer to light. Extractable ALA synthase activity from gabaculine-pretreated dark-grown cells was initially lower than the activity from untreated cells, but it did not undergo a further decline after transfer of the cells to the light, whereas the activity from untreated cells dropped to less than one eighth the dark level after 2 h in the light, and by 4 h had fallen to a level five times lower than that extractable from gabaculine-treated cells. These results suggest that suppression of ALA synthase activity by light in untreated cells is related to light-induced activation of the five-carbon ALA biosynthetic pathway in the plastids, and may result from a contribution by a product of the five-carbon pathway to non-plastid tetrapyrrole pools in the light.     

The greening process in cress seedlings. I. Pigment accumulation and ultrastructure after application of 5-aminolevulinate and complexing agents

A reduced rate of greening after continuous illumination was observed in dark-grown cress seedlings ( Lepidium sativum L.) incubated with 5-aminolevulinate (ALA) or the complexing agents 2,2'-bipyridyl, 8-hydroxyquinoline or 1,10-phenanthroline. This effect cannot be explained merely by photodynamic damage caused by chlorophyll precursors which are accumulated in the dark under these conditions. Flash light experiments revealed that photoconversion of protochlorophyll(ide) to chlorophyllide was not influenced by chelator treatment. The next step in the chlorophyll pathway, the esterification of chlorophyllide, however, was inhibited. Simultaneously applicated ALA and complexing agents did not result in a synergistic reponse; on the contrary, ALA seemed to render cress plants less susceptible to the treatment with complexing agents upon subsequent irradiation. Ultrastructural studies demonstrated that grana formation in light was inhibited after pretreatment with ALA or complexing agents.     

delta-Aminolevulinic Acid Synthase of Euglena gracilis: Regulation of Activity

δ-Aminolevulinic acid (ALA), a key precursor of the tetrapyrroles heme and chlorophyll, is capable of being synthesized by two different routes in cells of the unicellular green alga Euglena gracilis: from the intact carbon skeleton of glutamate, and via the condensation of glycine and succinyl CoA, mediated by the enzyme ALA synthase. The regulatory properties of ALA synthase were examined in order to establish its role in Euglena.

Partially purified Euglena ALA synthase, unlike the case with the bacterial or animal-derived enzyme, does not exhibit allosteric inhibition by the tetrapyrrole pathway products heme, protoporphyrin IX, and porphobilinogen, at concentrations up to 100 micromolar.

In aplastidic mutant cells, extractable ALA synthase activity is constant during exponential growth, and decreases to low levels as the cells reach the stationary state. Rapid exponential decline of ALA synthase (t_1/2 = 55 min) occurs after administration of 43 micromolar cycloheximide, but not 6.2 millimolar chloramphenicol. These results suggest that, as in other eukaryotic cells, ALA synthase is synthesized on cytoplasmic ribosomes and is subject to rapid turnover in vivo.

Extractable ALA synthase activity increases 2.5-fold within 6 hours after administration of 100 millimolar ethanol, a stimulator of mitochondrial development, and 4.5-fold within 12 hours after administration of 1 millimolar 4,6-dioxoheptanoic acid, which blocks ALA utilization, suggesting that activity is controlled in vivo by a feedback induction-repression mechanism, coupled with rapid enzyme turnover.

In heterotrophically grown wild-type cells, low levels of ALA synthase rapidly increase 4.5-fold within 12 hours after cells are transferred from the light to the dark, and decrease exponentially (t_1/2 = 75 min) when cells are transferred from the dark to light. The dark levels are equal to those in light- or dark-grown aplastidic mutant cells. The low level occurring in light-grown wild-type cells is not altered by the presence of 10 micromolar 3-(3,4-dichlorophenyl)-1,1-dimethylurea, which blocks photosynthetic O₂ production. The decrease that occurs on dark-to-light transfer can be diminished by 12- or 24-hour prior incubation with 6.2 millimolar chloramphenicol, which also retards chlorophyll synthesis after the transfer to light.

The positive relationship of ALA synthase activity to degree of mitochondrial expression, and the inverse relationship to plastid development and chlorophyll synthesis, suggests that ALA synthase functions to provide precursors to nonplastid tetrapyrroles in Euglena. In light-grown, wild-type cells, the diminished levels of ALA synthase may be due to the ability of developing plastids to export heme or a heme precursor to other cellular regions, which thereby supplants the necessity for ALA formation via the ALA synthase route.

     

Studies on chlorophyll biosynthesis and other things

Our research on chlorophyll biosynthesis, over a period of approximately twenty years, has been described, emphasizing those areas in which our laboratory made significant and timely contributions. References to some of our most important articles are included. Portions of the chlorophyll biosynthetic pathway, in which our own laboratory was not involved, for example, the reduction of protochlorophyllide to chlorophyllide and the phytylation of the latter to yield chlorophyll a, have not been covered in this article. Those events which preceded my involvement with chlorophyll biosynthesis, but which contributed to the formation of my own scientific personality, are mentioned briefly in the Introduction. My non-scientific avocations have been included at the request of the reviewers and Govindjee.     

The effect of 2,4-dichlorophenoxyacetic acid and (2-chloroethyl)-trimethylammonium chloride on chlorophyll synthesis in barley leaves

Summary 2.4-dichlorophenoxyacetic acid (2.4-D) and (2-chloroethyl)-trimethylammonium chloride (CCC) inhibit chlorophyll synthesis and protochlorophyllide ₆₅₂ regeneration in 6–8 day old barley leaves whilst having little effect on the rates of protochlorophyll ₆₃₂ synthesis from exogenous -aminelevulinic acid (ALA) and ALA-dehydratase activity. Longer pretreatments with 2.4-D and CCC show it is only after 50 to 60 hr that the rates of P₆₃₂ production from exogenous ALA and ALA-dehydratase activity are affected. Similar response times were obtained for chloramphenicol (CAP). The results indicate that 2.4-D and CCC may act by directly inhibiting specific plastid-protein synthesis similar to CAP. Hence it seems that it is only those proteins (enzymes) having a rapid turnover that are affected first i.e. the enzymes necessary for ALA synthesis in the plastid.Abbreviations used ALA -aminolevulinic acid - CAP chloramphenicol - CCC (2-chloroethyl)-trimethylammonium chloride - 2.4-D 2-4-dichlorophenoxyacetic acid - P₆₅₂ prodochlorophyllide with maximum in-vivo absorption at 652 nm - P₆₈₄ chlorophyllide absorbing at 684 nm - P₆₇₀ chlorophyllide absorbing at 670 nm - P₆₃₂ pigment absorbing at 632 nm synthesised from exogenous ALA - PBG Porphobilinogen P. R. Shewry is in receipt of a Science Research Council Studentship award.     

With chlorophyll pigments from prolamellar bodies to light-harvesting complexes

The biosynthetic chain leading from 5-aminolevulinic acid to chlorophyll is localised to the plastid. Many of the enzymes are nuclear-encoded. NADPH-protochlorophyllide oxidoreductase (EC 1.3.1.33) is one such enzyme which is encoded by two different genes and can exist in an A and a B form. Its import into the plastid seems to be facilitated when protochlorophyllide is present in the chloroplast envelope. Within the plastid the reductase is assembled to thylakoids or prolamellar bodies. The specific properties of the reductase together with the specific properties of the lipids present in the etioplast inner membranes promote the formation of the three-dimensional regular network of the prolamellar bodies. The reductase forms a ternary complex with protochlorophyllide and NADPH that gives rise to different spectral forms of protochlorophyllide. Light transforms protochlorophyllide into chlorophyllide and this photoreaction induces a conformational change in the reductase protein which leads to a process of disaggregation of enzyme, pigment aggregates and membranes, which can be followed spectroscopically and with electron microscopy. The newly formed chlorophyllide is esterified by a membrane-bound nuclear-encoded chlorophyll synthase and the chlorophyll molecule is then associated with proteins into active pigment protein complexes in the photosynthetic machinery.     

Distribution of δ-aminolevulinic acid biosynthetic pathways among phototrophic bacterial groups

Two biosynthetic pathways are known for the universal tetrapyrrole precursor, -aminolevulinic acid (ALA). In the ALA synthase pathway which was first described in animal and some bacterial cells, the pyridoxal phosphate-dependent enzyme ALA synthase catalyzes condensation of glycine and succinyl-CoA to form ALA with the loss of C-1 of glycine as CO₂. In the five-carbon pathway which was first described in plant and algal cells, the carbon skeleton of glutamate is converted intact to ALA in a proposed reaction sequence that requires three enzymes, tRNA^Glu, ATP, Mg²⁺, NADPH, and pyridoxal phosphate. We have examined the distribution of the two ALA biosynthetic pathways among various genera, using cell-free extracts obtained from representative organisms. Evidence for the operation of the five-carbon pathway was obtained by the measurement of RNase-sensitive label incorporation from glutamate into ALA, using 3,4-[³H]glutamate or 1-[¹⁴C]glutamate as substrate. ALA synthase activity was indicated by RNase-insensitive incorporation of label from 2-[¹⁴C]glycine into ALA. The distribution of the two pathways among the bacteria tested was in general agreement with their previously established phylogenetic relationships and clearly indicates that the five-carbon pathway is the more ancient process, whereas the pathway utilizing ALA synthase probably evolved much later. The five-carbon pathway is apparently the more widely utilized one among bacteria, while the ALA synthase pathway seems to be limited to the subgroup of purple bacteria.Abbreviations ALA -aminolevulinic acid - DTT dithiothreitol - PALP pyridoxal phosphate - SDS sodium dodecyl sulfate - tricine N-tris-(hydroxymethyl)methylglycine     

Peroxidase-catalysed oxidation of chlorophyll by hydrogen peroxide

Chlorophyll is effectively bleached by H₂O₂ in the presence of certain phenols and peroxidase (EC 1.11.1.7) extracted from acetone powders of orange flavedo (Citrus sinensis). Optimal conditions for chlorophyll: hydrogen peroxide oxidoreductase include: pH, 5.9; [H₂O₂] 222 μM; ionic strength 0.11. A phenol is required and resorcinol is the most effective. Catechol and hydroquinone are inhibitory. Chlorophyll a, chlorophyllide a, and chlorophyll b all have similar V_max but K_m for chlorophyll a is about one-third that of chlorophyll b, while the K_m for chlorophyllide a is about one-half that of chlorophyll a. Pheophytin a was much less reactive than chlorophyll a, and Mg²⁺ included in the reaction system did not affect rates of pheophytin destruction.     

Effect of cadmium on chlorophyll biosynthesis and enzymes of nitrogen assimilation in greening maize leaf segments: role of 2-oxoglutarate

Supply of cadmium chloride (0.5 mM) inhibited chlorophyll formation in greening maize leaf segments, while lower concentration of Cd (0.01 mM) slightly enhanced it. Inclusion of 2-oxoglutarate (2-OG, 0.1-10 mM) in the incubation mixture increased chlorophyll content in the absence as well as presence of Cd. Substantial inhibition of chlorophyll formation by Cd was observed at longer treatment both in the absence and presence of 2-OG. When the tissue was pre-incubated with 2-OG or Cd, the inhibition (%) of chlorophyll formation by Cd was lowered in the presence of 2-OG. Treatment with Cd inhibited ALAD activity and ALA formation and the inhibition (%) of ALA formation by Cd was strongly reduced in the presence of 2-OG. Glutamate dehydrogenase (GDH) activity was increased by the supply of Cd both in the absence as well as presence of 2-OG. In the presence of 2-OG, Cd supply significantly increased glutamate synthase (GOGAT) activity and reduced inhibition (%) of glutamine synthetase (GS) activity. The results suggested the involvement of the glutamine synthetase/glutamate synthase (GS/GOGAT) pathway of ammonia assimilation to provide the precursor, glutamate, for ALA synthesis under Cd toxicity and 2-OG supplementation.     

Accumulation of the NON‐YELLOW COLORING 1 protein of the chlorophyll cycle requires chlorophyll b in Arabidopsis thaliana

Chlorophyll a and chlorophyll b are interconverted in the chlorophyll cycle. The initial step in the conversion of chlorophyll b to chlorophyll a is catalyzed by the chlorophyll b reductases NON‐YELLOW COLORING 1 (NYC1) and NYC1‐like (NOL), which convert chlorophyll b to 7‐hydroxymethyl chlorophyll a. This step is also the first stage in the degradation of the light‐harvesting chlorophyll a/b protein complex (LHC). In this study, we examined the effect of chlorophyll b on the level of NYC1. NYC1 mRNA and NYC1 protein were in low abundance in green leaves, but their levels increased in response to dark‐induced senescence. When the level of chlorophyll b was enhanced by the introduction of a truncated chlorophyllide a oxygenase gene and the leaves were incubated in the dark, the amount of NYC1 was greatly increased compared with that of the wild type; however, the amount of NYC1 mRNA was the same as in the wild type. In contrast, NYC1 did not accumulate in the mutant without chlorophyll b, even though the NYC1 mRNA level was high after incubation in the dark. Quantification of the LHC protein showed no strong correlation between the levels of NYC1 and LHC proteins. However, the level of chlorophyll fluorescence of the dark adapted plant (F_o) was closely related to the accumulation of NYC1, suggesting that the NYC1 level is related to the energetically uncoupled LHC. These results and previous reports on the degradation of chlorophyllide a oxygenase suggest that the a feedforward and feedback network is included in chlorophyll cycle.     

The SCO2 protein disulphide isomerase is required for thylakoid biogenesis and interacts with LHCB1 chlorophyll a/b binding proteins which affects chlorophyll biosynthesis in Arabidopsis seedlings

The process of chloroplast biogenesis requires a multitude of pathways and processes to establish chloroplast function. In cotyledons of seedlings, chloroplasts develop either directly from proplastids (also named eoplasts) or, if germinated in the dark, via etioplasts, whereas in leaves chloroplasts derive from proplastids in the apical meristem and are then multiplied by division. The snowy cotyledon 2, sco2, mutations specifically disrupt chloroplast biogenesis in cotyledons. SCO2 encodes a chloroplast-localized protein disulphide isomerase, hypothesized to be involved in protein folding. Analysis of co-expressed genes with SCO2 revealed that genes with similar expression patterns encode chloroplast proteins involved in protein translation and in chlorophyll biosynthesis. Indeed, sco2-1 accumulates increased levels of the chlorophyll precursor, protochlorophyllide, in both dark grown cotyledons and leaves. Yeast two-hybrid analyses demonstrated that SCO2 directly interacts with the chlorophyll-binding LHCB1 proteins, being confirmed in planta using bimolecular fluorescence complementation (BIFC). Furthermore, ultrastructural analysis of sco2-1 chloroplasts revealed that formation and movement of transport vesicles from the inner envelope to the thylakoids is perturbed. SCO2 does not interact with the signal recognition particle proteins SRP54 and FtsY, which were shown to be involved in targeting of LHCB1 to the thylakoids. We hypothesize that SCO2 provides an alternative targeting pathway for light-harvesting chlorophyll binding (LHCB) proteins to the thylakoids via transport vesicles predominantly in cotyledons, with the signal recognition particle (SRP) pathway predominant in rosette leaves. Therefore, we propose that SCO2 is involved in the integration of LHCB1 proteins into the thylakoids that feeds back on the regulation of the tetrapyrrole biosynthetic pathway and nuclear gene expression.     

Chlorophyllase activities and chlorophyll degradation during leaf senescence in non-yellowing mutant and wild type of Phaseolus vulgaris L

The activities of chlorophyllase, contents of pigments including chlorophyll a and b, chlorophyllide a and b, and phaeophorbide a during leaf senescence under low oxygen (0.5% O2) and control (air) were investigated in a non-yellowing mutant and wild-type leaves of snap beans (Phaseolus vulgaris L.). Chlorophyllase from leaf tissues had maximum activity when incubated at 40C in a mixture containing 50% acetone. In both mutant and wild type, chlorophyllase activity was the highest in freshly harvested non-senescent leaves and decreased sharply in the course of senescence, indicating that the loss of chlorophylls in senescing leaves is not directly related to the activity of chlorophyllase and that chlorophyllase activity is not altered in the mutant. The wild type had higher ratios of chlorophyll a to chlorophyll b than the mutant and chlorophyll a : b ratios increased during senescence in both types. In the senescent mutant leaves, accumulations of chlorophyllide a and chlorophyllide b were detected, but no phaeophorbide a was found. Chlorophyllide b had a greater accumulation than chlorophyllide a in the early stage of senescence. Low oxygen treatment not only delayed chlorophyll degradation but also enhanced the accumulations of chlorophyllide a and b and lowered the ratios of chlorophyll a to chlorophyll b.     

C-nuclear magnetic resonance studies of the biosynthesis of 5-aminolevulinic acid destined for chlorophyll formation in dark-grown Scenedesmus obliquus

The ¹³C-nuclear magnetic resonance (NMR) spectra of chlorophyll a formed in dark-grown Scenedesmus obliquus (Turp.) Kützing in the presence of [1-¹³C]glutamate, [2-¹³C]- and [1-¹³C]glycineshowed that the ¹³C of glutamate was specifically incorporated into the eight-carbon atoms in the tetrapyrrole macrocycles derived from C-5 of 5-aminolevulinic acid (ALA), while the C-2 of glycine was only incorporated into the methyl carbon of the methoxycarbonyl group attached to the isocyclic ring of chlorophyll a. No specific enrichment of these nine carbon atoms was observed in the spectrum of chlorophyll a formed in the presence of [1-¹³C]-glycine. These labeling patterns provide evidence for the operation of the C₅-pathway and against the operation of the ALA synthase pathway for chlorophyll formation in darkness.     

Regulation of haem biosynthesis in normoblastic erythropoiesis: role of 5-aminolaevulinic acid synthase and ferrochelatase

The development of haem biosynthetic enzyme activity during normoblastic human erythropoiesis was examined in seven patients. The first and last enzymes of the haem biosynthetic pathway, ALA synthase and ferrochelatase, were assayed by radiochemical/high performance liquid chromatographic (HPLC) methods. An assay for ferrochelatase activity in human bone marrow was developed. Enzyme substrates were protoporphyrin IX and ⁵⁹Fe²⁺ ions. ⁵⁹Fe-labelled haem was isolated by organic solvent extraction/sorbent extraction followed by reversed-phase HPLC. Optimal activity occurred at pH 7.3 in the presence of ascorbic acid, in darkness and under anaerobic conditions. Haem production was proportional to cell number and was linear with time to 30 min. The assay was sensitive to the picomolar range of haem production. ALA synthase and ferrochelatase activity was assayed in four highly purified age-matched erythroid cell populations. ALA synthase activity was maximal in the most immature erythoid cells and diminished as the cells matured with an overall five fold loss of activity from proerythroblast to late erythroblast development. Ferrochelatase activity was, however, more stable with less than a two fold change in activity observed during the same period of erythroid differentiation. Maximal activity occurred in erythroid fractions enriched with intermediate erythroblasts. These results support sequential rather than simultaneous appearance of these enzymes during normoblastic erythropoiesis. Quantitative analysis of relative enzyme activity however indicates that at all times during erythroid differentiation ferrochelatase activity is present in excess to that theoretically required relative to ALA synthase activity since ALA and haem are not produced in stoichiometric amounts. The lability of ALA synthase versus the stability and gross relative excess of ferrochelatase activity indicates a far greater role for ALA synthase in the regulation of erythroid haem biosynthesis than for ferrochelatase.