Changes in whole body concentrations of thyroid hormones and cortisol in metamorphosing conger eel

Summary To clarify the hormonal regulation of metamorphosis of the conger eel (Conger myriaster), changes in whole body concentrations of thyroid hormones, thyroxine (T₄) and triiodothyronine (T₃), and cortisol during metamorphosis were examined, as well as the changes in the histological activity of the thyroid gland. In larvae before metamorphosis, T₄ and T₃ levels were less than 5 and 0.15 ng·g^-1 respectively. Levels of T₄ increased to about 30 ng·g^-1 during early metamorphosis, and decreased subsequently. Levels of T₃ increased gradually in early metamorphosis, and then increased abruptly to about 2.0 ng·g^-1 in late metamorphosis. Before metamorphosis, cortisol levels of the leptocephali less than 11 cm in total length were greater than 200 ng·g^-1. Cortisol levels decreased rapidly in larger premetamorphic leptocephali, and low levels were maintained throughout the metamorphic period. Histological observation revealed an activation of the thyroid gland in early metamorphosis; thyroid follicle epithelial cells became columnar and their nuclei larger. Active uptake of colloid by these cells and intensive vascularization of the gland were also observed. By the end of metamorphosis, follicle epithelial cells became squamous, indicating a low level of glandular activity. These results suggest that thyroid hormone plays an important role in regulation of conger eel metamorphosis.Abbreviations AL anal length - TL total length - T ₃ triiodothyronine - T ₄ thyroxine     

Temporal and spatial expression of an intestinal Na+/PO43− cotransporter correlates with epithelial transformation during thyroid hormone-dependent frog metamorphosis

The amphibian intestine has two morphologically distinct structures during development. Early embryogenesis generates a simple tube-like intestine in the tadpole whereas after thyroid hormone (T₃)-dependent metamorphosis a newly remodeled adult intestine is formed similar to that of higher vertebrates. This change requires a drastic transformation of the epithelial layer. We have isolated a Na⁺/PO₄³⁻ cotransporter gene that may contribute to this transformation. The deduced amino acid sequence of this gene shows a high degree of homology to the mammalian renal NA⁺/PO₄³⁻ cotransporters, which have little or no expression in organs other than the kidney. The frog gene is highly expressed and regulated by T₃ in the intestine with little expression and/or regulation by T₃ in most other organs. Its mRNA is restricted to the differentiated epithelial cells both in tadpoles and postmetamorphic frogs. Interestingly, its expression is low in premetamorphic tadpoles, but up-regulated when metamorphosis is initiated by endogenous T₃. As the larval epithelium undergoes programmed cell death (apoptosis), the mRNA level drops to a minimum. Subsequently, the gene is reactivated at the tip region of the newly formed adult intestinal folds and a crest-trough polarity of expression is established by the end of metamorphosis. This temporal regulation profile is also reproduced when premetamorphic tadpoles are treated with T₃ to induce precocious intestinal remodeling. These results suggest a possible role of the Na⁺/PO₄³⁻ cotransporter during metamorphosis and demonstrate that the adult epithelial cell differentiation pattern is established in the direction of crest-to-trough of the intestinal fold, concurrent with the epithelial morphogenic process. Dev Genet 20:53–66, 1997. © 1997 Wiley-Liss, Inc.     

Variations in larval growth and metabolism of an estuarine shrimp Palaemonetes pugio during toxicosis by an insect growth regulator

1. Exposure of the estuarine shrimp, Palaemonetes pugio, to a juvenile hormone analogue (⩾8 μg methoprene 1⁻¹) throughout larval development inhibited successful completion of metamorphosis.2. Methoprene exposure retarded growth in early larval stages and postlarvae, but enhanced growth in premetamorphic larvae.3. Respiration rates of early larvae were elevated by methoprene exposure, but not so older larvae or post larvae.4. Lower net growth efficiency (K₂ values) in methoprene-exposed early larvae suggests that increased metabolic demands reduced assimilated energy available for growth.5. Modifications in O:N ratios of premetamorphic larvae and postlarvae suggest that methoprene altered substrate utilization patterns during metamorphosis.     

Hormonal regulation of ornithine aminotransferase biosynthesis in rat liver and kidney.

The relative rates of ornithine aminotransferase (OAT) synthesis in vivo were studied by pulse-labeling rats with [4,5-³H]leucine, isolating the mitochondrial enzyme protein by immunoprecipitation with a monospecific antibody, dissociating the immunoprecipitates on sodium dodecyl sulfate-acrylamide gels, and determining the radioactivity in OAT. After 4 days of treatment with triiodothyronine (T₃), both the enzyme activity level and the relative synthetic rate of OAT in rat kidney were elevated over twofold. The level of hepatic OAT activity was unaffected by this treatment. Thyroidectomy caused a 50% drop in the basal level of OAT activity and synthesis in kidney but not in liver. Although the basal levels of activity and synthesis of both renal and hepatic OAT were unaffected by adrenalectomy, the glucagon induction of the enzyme in liver was enhanced by about one-third and the T₃ induction in kidney was suppressed 50% by this operation. After 4 days of treatment with estrogen, both the enzyme activity level and the relative synthetic rate of OAT in male rat kidney were elevated nearly 10-fold. Hepatic OAT activity and synthesis were unaffected by this regimen. Thyroidectomy almost completely abolished the estrogen induction of OAT in kidney. OAT induction by estrogen could be restored by treating thyroidectomized rats with T₃. Simultaneous administration of T₃ plus estrogen to intact rats produced a multiple effect, resulting in a striking 20-fold induction of renal OAT. Although administration of either T₃ or estrogen causes an increase in the synthesis of immunoprecipitable OAT protein in rat kidney, each of these hormones may induce OAT by a different mechanism.     

Thyroid hormones are necessary for the metamorphosis of tarpon Megalops cyprinoides leptocephali

This study investigates the effects of thyroxine (T₄), triiodothyronine (T₃) and thiourea (TU) on the metamorphosis of tarpon Megalops cryprinoides leptocephali. TU is an anti-thyroid hormone drug that inhibits the production of T₄ and T₃ in the thyroid tissue. Fully grown tarpons leptocephali were collected at the river mouth and, in the laboratory, were immediately treated with 100 ppb T₄, 10 ppb T_3, or 300 ppm TU. The appropriate concentrations were validated in a preliminary dose response experiment. Morphological and physiological characteristics that indicate metamorphic processes were measured every 2 days. T₄ and T₃ slightly speeded up the metamorphosis of tarpons compared with the control group. The experimental treatments produced accelerated reductions in length, increases in head/body ratio, swimbladder development, and loss of body water and sodium. In contrast, TU treatment caused metamorphic stasis with complete inhibition of metamorphosis between days 6 and 8. Thyroid hormone treatment stimulated fast otolith growth while TU treatment stopped otolith growth between days 6 and 9. Leptocephali in T₄, T₃ and control groups completed metamorphosis in 10-14 days, but TU-treated tarpons remained in the metamorphic leptocephalus stage more than 22 days. In addition, the inhibition of leptocephalus metamorphosis by 300 ppm TU can be reversed in the presence of 10 ppb T₃. These results indicate that thyroid hormones are involved in regulating the metamorphosis of leptocephali.     

Thyroxine as a Mediator of Metamorphosis of Atlantic Halibut, Hippoglossus Hippoglossus

The response of morphological, histological and endocrinological development to exogenous 1-thyroxine (T₄) and to water depth during metamorphosis in Atlantic halibut, Hippoglossus hippoglossus, was investigated. Exogenous T₄ was given in daily doses of 0.1, 0.05 ppm or a control treatment to halibut larvae at 550 daydegrees (posthatch, premetamorphic) for 14 days. Water depths of 40 cm, 10 cm or 1.5 cm were used to rear halibut larvae from 590 daydegrees for 21 days. Halibut larvae given exogenous T₄ at 0.1 ppm had accelerated eye migration relative to MH in fish given 0.05 ppm and in control fish. Pigmentation was correlated with dosage after 14 days. The volume of thyroid tissue was expressed in a dose-dependent manner and exhibited a size-dependency within each treatment. However, the follicles were atypical with reduced colloid, increased lumen and low epithelial cells even in the control group. The results indicate that T₄ is a mediator in halibut metamorphosis. In the water depth experiment, only cortisol levels of larvae reared in 1.5 cm water were significantly affected after 21 days, but this was not correlated with metamorphic rate. Hormone profiles, morphological changes and size suggest the existence of a window of opportunity for metamorphosis in halibut extending from about 16 mm and tapering off about 21 mm SL. The pooled hormone profiles indicate the commencement of a hormonal cascade similar to that of other flatfishes during metamorphosis. The results indicate that growth, neural and skeletal transformation, and pigmentation are biochemically separate processes in the metamorphosis of Atlantic halibut.     

Effects of cyclic AMP on the kinetics of serum protein synthesis in cultured mouse hepatoma cells

The mouse hepatoma cell line, Hepa, was cultured in the presence of either 1 mM N⁶, O^2′-dibutyryl cyclic AMP (Bt₂cAMP), 0.5 mM 3-isobutyl-1-methylxanthine, or 1 μg/ml cholera toxin. The synthesis and secretion of albumin, α-fetoprotein, and transferrin were elevated above controls by 24 h reaching two- to fourfold stimulations within 72 h. These effects were reversible and were specific for the serum proteins. The stimulation of serum protein synthesis was accompanied by a decrease in the rate of cell proliferation. Protein synthetic parameters were analyzed in Hepa cells 72 h after exposure to N⁶,O^2′-dibutyryl cyclic AMP. The cellular rate of albumin synthesis was increased fourfold and the relative rate of albumin synthesis was increased approximately threefold. N⁶,O^2′-Dibutyryl cyclic AMP did not affect the size distribution of either total Hepa polyribosomes or of albumin-synthesizing polyribosomes. The elongation rate on total mRNA and on albumin mRNA was decreased by approximately 40%. These results indicate that the rate of initiation of total Hepa mRNA and of albumin mRNA also decreased by 40%. The nonspecific nature of the N⁶,O^2′-dibutyryl cyclic AMP effect on Hepa protein synthetic parameters must be due to an alteration in the level of a common substrate, perhaps ATP. The specific threefold increase in the relative rate of albumin synthesis with no alteration in polyribosome sizes requires a threefold increase in the relative amount of functional albumin mRNA in Hepa cells. This prediction was confirmed by cell-free translation of Hepa polyribosomes.     

Cell death: Are new proteins synthesized during hormone-induced tadpole tail regression?

The possibility that tadpole tail regression might be initiated by thyroid hormone-induced synthesis of new proteins was investigated. Changes in the newly-synthesized proteins of cultured Xenopus laevis tadpole tails treated with 1.5 × 10^?7 M tri-iodothyronine (T₃) were studied, using polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulphate for protein separation. After initial studies of unfractionated tail proteins, fractionated mixtures of [³H]methionine and [³⁵S]methionine labelled proteins derived from control and hormone-treated tails respectively were examined for hormone-induced changes. Using a new procedure developed to allow effective analysis of small differences in distribution of two isotopes within gel slices, it was shown that no significant changes in synthesis of fractionated tail proteins are induced by the hormone during the first 3–4 days in culture. The average detection limit was approx. 0.02% of total tail protein synthesis. Although no changes in the synthesis of the tissue structural or enzymic proteins are induced by the hormone this study still leaves open the possibility of changes in the synthesis of regulatory proteins. Based on the known method of activation of the tadpole tail collagenase (which is shown here directly for the first time to be involved in T₃-induced tail regression), it is suggested that many of the initial hormone-induced changes might result from T₃-induced activation of proteolytic “cascades”.     

T3-hydrocortisone synergism on adult-type erythroblast proliferation and T3-mediated apoptosis of larval-type erythroblasts during erythropoietic conversion in Xenopus laevis

 The conversion of an erythropoietic system from larval to adult type in anuran amphibia may possibly come about through cell replacement. The hormonal regulation of apoptosis of larval-type precursor cells and adult-type cell proliferation has yet to be examined in detail. In amphibians, corticoids synergize T₃ action during metamorphosis. In the present study, examination was made of the process of larval-to-adult conversion in the liver erythropoietic site of Xenopus laevis, with special attention to how these metamorphic hormones, T₃ and corticoid, regulate programmed cell death specific for larval erythroblasts and the proliferation of adult cells. Immunohistochemical analysis of liver sections indicates that the number of larval erythroblasts decreased to less than 50% at the early climax stage (stages 59–60) of metamorphosis. Overall liver morphology greatly changed subsequent to the climax stage from the three-lobe to the two-lobe shape. The addition of T₃ (10^-8 M) to premetamorphic tadpoles induced considerable liver morphological change and a 50% decrease in larval-type erythroblasts. These erythroblast decreases seem to take place through the apoptotic process, since double-staining experiments with in situ DNA nick-end labeling (TUNEL) and hemoglobin immunostaining revealed that DNA breakage of nuclei, a well-known feature of apoptosis, occured specifically in larval erythroblasts during prometamorphosis. Hydrocortisone (HC), which modulates T₃ action during metamorphosis, was found not to be a factor in larval cell decrease. But adult erythroblasts increased by 8 times as much through the action of T₃ and 32 times as much by the action of T₃ plus HC, indicating the important action of T₃–HC synergism. It thus follows that the erythropoietic system is converted during metamorphosis effectively by two distinct hormonal mechanisms, T₃–HC synergism on adult erythroblast proliferation and T₃-mediated programmed death of larval precursor cells. Accepted: 14 January 1999     

Theoretical study and rate constant calculations for the reactions of SiHX3 with CF3 and CH3 radicals (X = F, Cl)

Theoretical investigations were carried out on the multi-channel reactions CF₃ + SiHF₃, CF₃ + SiHCl₃, CH₃ + SiHF₃, and CH₃ + SiHCl₃. Electronic structures were calculated at the MP2/6-311+G(d,p) level, and energetic information further refined by the MC-QCISD (single-point) method. The rate constants for major reaction channels were calculated by the canonical variational transition state theory with small-curvature tunneling correction over the temperature range of 200–1,500 K. The theoretical rate constants were in good agreement with the available experimental data and were fitted to the three parameter expression: k _1a(T) = 2.93 × 10^?26 T ^4.25 exp (?318.68/T), and k _2a(T) = 3.67 × 10^?22 T ^2.72 exp (?1,414.22/T), k _3a (T) = 7.00 × 10^?24 T ^3.27 exp (?384.04/T), k _4a(T) = 6.35 × 10^?22 T ^2.59 exp (?603.18/T) (in unit of cm³molecule^?1s^?1) are given. Our calculations indicate that hydrogen abstraction channel is the major channel due to the smaller barrier height among four channels considered.

Effects of exogenous triiodothyronine on fast axonal transport during tadpole metamorphosis

Bullfrog tadpoles at metamorphic stages V, X and XVIII were immersed in 25 nM triiodothyronine (T₃) to assess whether the 4–5 fold increase in fast axonal transport (FAxT) previously observed during this span of spontaneous metamorphosis (1) could be mimicked by precocious application of thyroid hormone. The trend initially observed was for T₃ to stimulate [³⁵S]methionine incorporation into lumbar DRG and inhibit incorporation in tail DRG. Both effects, however, appeared to be exerted primarily on satellite cells rather than neurons since most of the T₃-induced changes in DRG were of a similar magnitude to those in the respective nerve trunks. Findings consistent with this observation resulted from use of the retrogradely transported lectin, ricin₁₂₀, to determine the proportion of DRG incorporation occurring in neurons. When incorporation of [³⁵S]methionine in lumbar DRG neurons was examined, T₃ had no stimulatory effect at any of the metamorphic stages examined. When FAxT was assessed as [³⁵S]protein accumulating proximal to a nerve trunk ligature, and expressed as a percentage of newly-synthesized protein in lumbar DRG neurons, no stimulatory effect of T₃ was detected. The question remains whether the changes in FAxT in peripheral neurons observed during spontaneous metamorphosis may be induced by circulating hormones other than T₃ or are secondary to changes in the target tissues. Special issue dedicated to Dr. Marion E. Smith.     

The significance of the latent period in thyroid hormone induced tissue regression during amphibian metamorphosis

Tail fin disks removed from tadpoles of Rana pipiens that were immersed in thyroxine or triiodothyronine for 3 days (referred to as donors) were fused to premetamorphic tail fin blocks that had never been exposed to this hormone (referred to as recipients) so that triplets were formed, consisting of one recipient tail block sandwiched between two donor tail fin blocks. Such recipient tail blocks responded with characteristic resorptive activity within 24 or 48 hr, instead of the minimum 72-hr latent period normally intervening in donor blocks, until shrinkage was initiated in response to triiodothyronine (T₃) or tetraiodothyronine (T₄). The presence of T₃ or T₄ hormone was not required continuously throughout the latent period. Hormone could be withdrawn after 30 hr contact in vivo and after 24 hr contact in vitro without interfering with the rate of tissue regression of tadpole tail fins, suggesting that the “latent period” probably does not coincide with the “critical period” during which subtle biochemical changes presumably occur that precede regression of the tadpole tail during metamorphosis. It is suggested that during the latent period active intermediates may be synthesized that are subsequently transferred from donor tail fins to recipients, thus reducing the latent period of the latter.     

Triiodothyronine regulated tubulin biosynthesis in oligodendrocytes during myelinogenesis

l-Triiodothyronine (T₃) is shown to stimulate the biosynthesis of tubulin in oligodendrocytes isolated from rat brains at different stages of myelinogenesis. The hormone sensitivity appears around day 11, reaches a maximum at day 15 and disappears by day 25 after birth. Dose response studies show that the optimal stimulation of tubulin in the oligodendrocytes from 15 day rat brain occurs with 0.045 nM T₃ in contrast to 4.5 nM T₃ that was previously shown to promote a similar age-dependent induction of tubulin in the astroglial cells from neonatal rat brain. Exposure of the oligodendrocytes to optimal dose of T₃ (0.045 nM) for 2 h elicits a marked and almost selective increase in the level of tubulin. Higher concentrations of T₃ induce additional proteins resulting in a loss of this sensitivity. Studies on the synthesis and turnover of ³⁵S-labeled tubulin show that the stimulation of tubulin by T₃ is primarily due to enhanced synthesis of the protein. Pulse chase experiments reveal that the half life of tubulin is about 5.5 h and that it remains unaffected by T₃. The crucial role of thyroid hormones and the possible function of tubulin in the two most critical phases of brain maturation viz. synaptogenesis and myelinogenesis is discussed.     

Stimulation of albumin synthesis in mouse hepatoma cells by Bt2cAMP: cell cycle specificity

Addition of 1 mm dibutyryl cyclic AMP (Bt₂cAMP) to cultures of mouse hepatoma cells, Hepa, specifically stimulates the synthesis of serum proteins including albumin. This stimulation is accompanied by an inhibition of cell proliferation. We have investigated these phenomena in synchronous cultures of Hepa. Proliferation of Hepa was arrested by isoleucine starvation. Synchronous growth was initiated by addition of complete growth medium or complete growth medium supplemented with 1 mm Bt₂cAMP. S phase and mitosis were estimated by determinations of [³H]thymidine incorporation and by cell numbers. The rate of albumin synthesis relative to total protein synthesis was measured by pulse labeling cultures for 30 min with [³H]leucine and comparing amounts of immunoprecipitable label with trichloroacetic acid-precipitable label. Treatment of synchronous cultures with Bt₂cAMP did not alter the duration of S phase or the onset of mitosis. The relative rate of albumin synthesis in Bt₂cAMP-treated culture began increasing after mitosis. The timing of the Bt₂cAMP stimulation of albumin synthesis was further investigated by adding Bt₂cAMP to cultures of Hepa at various times after the initiation of synchronous growth. The relative rate of albumin synthesis was then measured at a fixed postmitotic time. An increased relative rate of albumin synthesis was observed only in cultures exposed to Bt₂cAMP before or during S phase. Thus the postmitotic increase in the synthesis of albumin requires the presence of Bt₂cAMP during S phase.     

The role of triiodothyronine in the regulation of synthesis rate and translatable mRNA level of fatty acid synthetase in a preadipocyte cell line

Triiodothyronine (T₃) effects on the activity, rate of synthesis and mRNA content of the key lipogenic enzyme, fatty acid synthetase, were studied in differentiating ob₁₇ preadipocytes cloned from ob/ob mouse epididymal adipose tissue. During differentiation in the presence of insulin, a 6–10-fold increase in both fatty acid synthetase specific activity and synthesis rate were reproducibly observed and occurred concomitantly. The relative synthesis rate exhibited a progressive elevation from 0.5% at confluence to a maximum level of 2% in the presence of insulin. The rate of the enzyme degradation determined by pulse-chase experiments was similar in differentiating cells and insulin-untreated cells of the same age ($\text{t}{}_{\mathrm{<mtext>1</mtext><mtext>2</mtext>}}$, 40–42 h). Furthermore, the increase in the enzyme synthesis rate was preceded by a progressively elevating amount of mRNA encoding for this protein as detected by translation in a reticulocyte lysate cell-free system. It is thus suggested that the increment in total and neosynthesized fatty acid synthetase in essentially due to an increased enzyme synthesis, reflecting an increased relative content of its specific mRNA. T₃ included at a physiological concentration (1.5 nM) in the culture medium enhanced significantly both enzyme synthesis and its specific mRNA. The most important T₃ effect was an acceleration of both processes, a stimulation of the mRNA level being detected as early as day 3 post-confluence and maximum at day 5 when the effect on the synthetase synthesis rate and activity began to be enhanced. This suggests that T₃ would mainly affect fatty acid synthetase as a pretranslational level.     

Concanavalin A as a peripherally acting inhibitor of thyroxin-mediated metamorphosis in amphibians

Stimulated by reports that Concanavalin A (Con A), a plant protein and lectin from jack bean, has an inhibitory effect on thyroid activation induced by thyrotropin, we set out to test whether Con A inhibits thyroid action on hormone-sensitive target tissues in amphibians. We noted that premetamorphic tadpoles injected with 0.15 ml of thyroxin (T₄ 0.24 μM) responded by accelerating metamorphic change as indicated by precocious disappearance of the tail, and appreciable growth of the hind limbs and changes in mouth-part morphology. Tadpoles given an injection of thyroxin immediately followed by an injection of Con A (9.6 μM) showed no such metamorphic changes. In the second series of experiments tail fin discs obtained from premetamorphic tadpoles when placed in cultures supplemented with T₄ (0.24 μM) had completely shrunk within 96 hr. Tail fin discs that were raised in vitro in medium containing Con A as well as thyroxin failed to regress. In the third series of experiments tail discs were initially cultured in medium containing thyroxin and transferred within 48 hr to medium containing Con A. When Con A was added after this 48-hr exposure to thyroxin it was no longer effective in preventing tail fin disc resorption. We conclude tentatively (1) that Con A is a peripheral inhibitor of thyroxin and (2) this it somehow binds to the tissue or interacts with thyroxin rendering it ineffective before the hormone has a chance to act. The significance of finding a peripherally active inhibitor of thyroid hormone for studies of mechanism of action of this hormone on development and differentiation of hormone-sensitive target structures is obvious.     

Thyroid hormone inhibition of synaptosome amino acid uptake and protein synthesis.

Abstract— 3,3′,5-Triiodothyronine (T₃) inhibited L-[¹⁴C]leucine uptake into synaptosomes. Inhibition was competitive with a K_i of 3.1 × 10^?5m . Hofstee plot revealed an inverted hyperbolic curve suggestive of a two carrier or carrier plus diffusion mediated system for amino acid uptake. Both the carrier mediated and diffusional components were inhibited by thyroid analogues. l -Thyroxine and analogues inhibited the incorporation of l -[¹⁴C] leucine into cerebral synaptosome protein. At 50 μm , the triiodo-compounds were more inhibitory than tetraiodo->3,5-triiodo-l -thyronine >3,3′,5-triiodothyropro-pionic> l -thyroxine >3,5-diiodo-l -tyrosine. Thyroid analogue inhibition was not seen in liver or brain mitochondrial protein synthesis. 3,3′,5-Triiodothyronine had no effect on respiratory control or 2,4-DNP stimulated synaptosome respiration supported by malate plus pyruvate. Ouabain did not inhibit [¹⁴C]leucine uptake into adult synaptosomes. There was synergistic inhibition of synaptosome protein synthesis by thyroid analogues in the presence of 0.2 mm -ouabain. 3,3′,5-Triiodothyronine had no effect on synaptosome fraction ATPase or Na-K ATPase. Addition of T₃ induced further inhibition of synaptosome protein synthesis in the presence of either chloramphenicol (100μm ) or cycloheximide (50μg/ml). [¹⁴C]Glycine uptake and incorporation into synaptosome protein was inhibited by 3,3′,5-triiodothyronine. There was no inhibition of [¹⁴C]proline uptake or incorporation. The above evidence and kinetic data strongly favor a selective competitive block in amino acid transport at the synaptosome membrane leading to a decreased rate of protein synthesis.     

Glucose transport and metabolism in Gymnodinium breve

Florida's red tide organism, Gymnodinium breve, utilized exogenous glucose in the light for the synthesis of cellular components. Glucose was not taken up in the dark. Kinetic parameters for glucose uptake include a K_FD of 11 μM and a V_max of 1 × 10^?10 mol of glucose taken up/mg cellular protein/hr. Glucose uptake was competitively inhibited by phloridzin (K_i = 40 μM), mannose (K_i = 12O μM), and 2-deoxy-d-glucose (K_i = 190 μM) and non-competitively inhibited by galactose (K_i = 125 μM). Kinetics and inhibition of glucose uptake are consistent with a facilitated diffusion transport system.