Suppression of 5'-nucleotidase enzymes promotes AMP-activated protein kinase (AMPK) phosphorylation and metabolism in human and mouse skeletal muscle

The 5'-nucleotidase (NT5) family of enzyme dephosphorylates non-cyclic nucleoside monophosphates to produce nucleosides and inorganic phosphates. We hypothesized that gene silencing of NT5 enzymes to increase the intracellular availability of AMP would increase AMP-activated protein kinase (AMPK) activity and metabolism. We determined the role of cytosolic NT5 in metabolic responses linked to the development of insulin resistance in obesity and type 2 diabetes. Using siRNA to silence NT5C2 expression in cultured human myotubes, we observed a 2-fold increase in the AMP/ATP ratio, a 2.4-fold increase in AMPK phosphorylation (Thr(172)), and a 2.8-fold increase in acetyl-CoA carboxylase phosphorylation (Ser(79)) (p < 0.05). siRNA silencing of NT5C2 expression increased palmitate oxidation by 2-fold in the absence and by 8-fold in the presence of 5-aminoimidazole-4-carboxamide 1-β-d-ribofuranoside. This was paralleled by an increase in glucose transport and a decrease in glucose oxidation, incorporation into glycogen, and lactate release from NT5C2-depleted myotubes. Gene silencing of NT5C1A by shRNA injection and electroporation in mouse tibialis anterior muscle reduced protein content (60%; p < 0.05) and increased phosphorylation of AMPK (60%; p < 0.05) and acetyl-CoA carboxylase (50%; p < 0.05) and glucose uptake (20%; p < 0.05). Endogenous expression of NT5C enzymes inhibited basal lipid oxidation and glucose transport in skeletal muscle. Reduction of 5'-nucleotidase expression or activity may promote metabolic flexibility in type 2 diabetes.     

Failure of human spermatozoa to penetrate zona free mouse and rat ova in vitro

When incubated for 8 to 26 hours with zona-free mouse or rat ova, human spermatozoa failed to attach to or penetrate any of the ova. The ova were capable of being fertilized since both intra- and inter-species penetration of spermatozoa and formation of pronuclei occurred between rat and mouse gametes. When mouse spermatozoa were incubated for three to eight hours with rat ova, a high proportion of the ova were penetrated, formation of pronuclei occurred and in 9 out of 36 ova incubated for 40 hours after insemination, regular cleavage and formation of morphologically normal 2-cell embryos occurred. Human spermatozoa retained their morphological integrity and motility only when the culture medium contained purified bovine serum albumin (3 mg/ml) or human serum (5% v/v) and not when unpurified BSA from several different commercial sources was used as a protein source. In this latter medium, the ova of both rats and mice degenerated after 8-hour incubation in the presence of human spermatozoa but not when human spermatozoa were absent or in the presence of either rat or mouse spermatozoa. Electron microscopy indicated that the human spermatozoa incubated for eight hours in medium containing purified BSA had undergone an acrosome reaction. These spermatozoa also attached to and penetrated human oocytes which had been matured in vitro.     

Dynamic changes in mitochondrial biogenesis and antioxidant enzymes during the spontaneous differentiation of human embryonic stem cells

Embryonic cells before implantation are exposed to a hypoxic condition and dependent on anaerobic metabolism. Human embryonic stem cells (HESCs) derived from pre-implantation blastocyst also grow well in hypoxic conditions. Expecting that the differentiating HESCs might mimic anaerobic-to-aerobic metabolic transition of the early human life, we examined the mitochondria-related changes in these cells. We observed that mitochondrial mass and mitochondrial DNA content were increased with differentiation, which was accompanied by the increase of the amount of ATP (4-fold) and its by-product reactive oxygen species (2.5-fold). The expression of various antioxidant enzymes including mitochondrial and cytoplasmic superoxide dismutases, catalase, and peroxiredoxins showed a dramatic change during the early differentiation. In conclusion, HESC differentiation was followed by dynamic changes in mitochondrial mass, ATP and ROS production, and antioxidant enzyme expressions. Therefore, the HESCs would serve as a good model to examine the mitochondrial biology during the early human differentiation.     

Differences in Activities of the Enzymes Of Nucleotide Metabolism and its Implications for Cardiac Xenotransplantation

Xenotransplantation is one be possible solution for a severe shortage of human organs available for transplantation. However, only a few studies addressed metabolic compatibility of transplanted animal organs. Our aim was to compare activities of adenosine metabolizing enzymes in the heart of different species that are relevant to clinical or experimental xenotransplantation. We noted fundamental differences: ecto-5′nucleotidease (E5′N) activity was 4-fold lower in pig and baboon hearts compared to the human hearts while mouse activity was compatible with human and rat activity was three times higher than human. There also were significant differences in AMP-deaminase (AMPD), adenosine deaminase (ADA) and purine nucleoside phosphorylase (PNP) activities. We conclude that differences in nucleotide metabolism may contribute to organ dysfunction after xenotransplantation.     

Differences in activities of the enzymes of nucleotide metabolism and its implications for cardiac xenotransplantation

Xenotransplantation is one be possible solution for a severe shortage of human organs available for transplantation. However, only a few studies addressed metabolic compatibility of transplanted animal organs. Our aim was to compare activities of adenosine metabolizing enzymes in the heart of different species that are relevant to clinical or experimental xenotransplantation. We noted fundamental differences: ecto-5' nucleotidease (E5' N) activity was 4-fold lower in pig and baboon hearts compared to the human hearts while mouse activity was compatible with human and rat activity was three times higher than human. There also were significant differences in AMP-deaminase (AMPD), adenosine deaminase (ADA) and purine nucleoside phosphorylase (PNP) activities. We conclude that differences in nucleotide metabolism may contribute to organ dysfunction after xenotransplantation.     

Cell-type specificity of ectonucleotidase expression and upregulation by 2,3,7,8-tetrachlorodibenzo-p-dioxin

We report here that induction of ectoATPase by 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD) is cell-type specific and not a generalized response to aryl hydrocarbon (Ah) receptor activation. TCDD increased [14C]-ATP and -ADP metabolism in two mouse hepatoma lines, Hepa1c1c7 and Hepa1-6 cells, but not in human hepatoma HepG2 or HuH-7 cells, human umbilical vein endothelial cells (HUVEC), chick hepatoma (LMH) cells, or chick primary hepatocytes or cardiac myocytes, even though all of those cell types were Ah receptor-responsive, as evidenced by cytochrome P4501A induction. To determine whether the differences in ectonucleotidase responsiveness to TCDD might be related to differences in cell-type ectonucleotidase expression, ATP and ADP metabolite patterns, the products of several classes of ectonucleotidases including ectonucleoside triphosphate diphosphohydrolases (E-NTPDases), ectophosphodiesterase/pyrophosphatases (E-NPP enzymes) and ectoalkaline phosphatase activities were examined. Those patterns, together with results of enzyme assays, Western blotting, or semiquantitative RT-PCR show that NTPDase2 is the main ectonucleotidase for murine and human hepatoma cells, NTPDase3 for chick hepatocytes and LMH cells, and an E-NPP enzyme for chick cardiac myocytes. Evidence for NTPDase2 expression was lacking in all cells except the mouse and human hepatoma cells. TCDD increased expression of the NTPDase2 gene but only in the mouse and not in the human hepatoma cells. TCDD did not increase NTPDase3, NTPDase1, E-NPP, or alkaline phosphatase in any of the cell types examined. The failure of TCDD to increase ATP metabolism in HUVEC, chick LMH cells, hepatocytes, and cardiac myocytes can be attributed to their lack of NTPDase2 expression, while the increase in ATP metabolism by TCDD in the mouse but not the human hepatoma cells can be explained by differences in TCDD effects on mouse and human hepatoma NTPDase2 gene expression. In addition to characterizing effects of TCDD on ectonucleotidases, these studies reveal major differences in the complements of ectonucleotidases present in different cell types. It is likely that such differences are important for cell-specific susceptibility to extracellular nucleotide toxicity and responses to purinergic signaling.     

Developmental regulation of enzymes of sucrose and hexose metabolism in effective and ineffective soybean nodules

Soybean (Glycine max) nodules formed by inoculation with either an effective strain or an ineffective (noninvasive, nodule-forming) strain of Bradyrhizobium japonicum were assayed for changes in developmental patterns of carbon metabolic enzymes of the plant nodule cells. Of the enzyme activities measured, only sucrose synthase, glutamine synthetase, and alcohol dehydrogenase were altered in the ineffective nodules relative to the effective nodules. Sucrose synthase and glutamine synthetase activities were greatly reduced, whereas alcohol dehydrogenase activity was elevated. Dark-induced senescence severely affected sucrose synthase but had little, if any, effect on the other enzymes measured. The developmental patterns of the anaerobically induced enzymes, aldolase and alcohol dehydrogenase, were different from those expected, implying that their development is not regulated solely by oxygen deprivation. However, anaerobic treatment of nodules resulted in responses similar to those enzymes in maize. The developmental profiles of the carbon metabolic enzymes suggest that carbohydrates are metabolized via the sucrose synthase and pentose phosphate pathways. This route of carbon metabolism, compared to glycolysis, would reduce the requirement of ATP for carbohydrate catabolism, generate NADPH for biosynthetic reactions, and provide intermediates for plant secondary metabolism.     

Mammalian mismatches in nucleotide metabolism: implications for xenotransplantation

Acute humoral rejection (AHR) limits the clinical application of animal organs for xenotransplantation. Mammalian disparities in nucleotide metabolism may contribute significantly to the microvascular component in AHR; these, however remain ill-defined. We evaluated the extent of species-specific differences in nucleotide metabolism. HPLC analysis was performed on venous blood samples (nucleotide metabolites) and heart biopsies (purine enzymes) from wild type mice, rats, pigs, baboons, and human donors. Ecto-5′-nucleotidase (E5′N) activities were 4-fold lower in pigs and baboon hearts compared to human and mice hearts while rat activity was highest. Similar differences between pigs and humans were also observed with kidneys and endothelial cells. More than 10-fold differences were observed with other purine enzymes. AMP deaminase (AMPD) activity was exceptionally high in mice but very low in pig and baboon hearts. Adenosine deaminase (ADA) activity was highest in baboons. Adenosine kinase (AK) activity was more consistent across different species. Pig blood had the highest levels of hypoxanthine, inosine and adenine. Human blood uric acid concentration was almost 100 times higher than in other species studied. We conclude that species-specific differences in nucleotide metabolism may affect compatibility of pig organs within a human metabolic environment. Furthermore, nucleotide metabolic mismatches may affect clinical relevance of animal organ transplant models. Supplementation of deficient precursors or application of inhibitors of nucleotide metabolism (e.g., allopurinol) or transgenic upregulation of E5'N may overcome some of these differences.     

Carboxylesterases in lipid metabolism: from mouse to human

Mammalian carboxylesterases hydrolyze a wide range of xenobiotic and endogenous compounds, including lipid esters. Physiological functions of carboxylesterases in lipid metabolism and energy homeostasis in vivo have been demonstrated by genetic manipulations and chemical inhibition in mice, and in vitro through (over)expression, knockdown of expression, and chemical inhibition in a variety of cells. Recent research advances have revealed the relevance of carboxylesterases to metabolic diseases such as obesity and fatty liver disease, suggesting these enzymes might be potential targets for treatment of metabolic disorders. In order to translate pre-clinical studies in cellular and mouse models to humans, differences and similarities of carboxylesterases between mice and human need to be elucidated. This review presents and discusses the research progress in structure and function of mouse and human carboxylesterases, and the role of these enzymes in lipid metabolism and metabolic disorders.     

Short- and long-term enzymatic regulation secondary to metabolic insult in the rat retina

Changes in oxygen and/or glucose availability may result in altered levels of ATP production and amino acid levels, and alteration in lactic acid production. However, under certain metabolic insults, the retina demonstrates considerable resilience and maintains ATP production, and/or retinal function. We wanted to investigate whether this resilience would be reflected in alterations in the activity of key enzymes of retinal metabolism, or enzymes associated with amino acid production that may supply their carbon skeleton for energy production. Enzymatic assays were conducted to determine the activity of key retinal metabolic enzymes total ATPase and Na(+)/K(+)-ATPase, aspartate aminotransferase and lactate dehydrogenase. In vitro anoxia led to an increase in retinal lactate dehydrogenase activity and to a decrease in retinal aspartate aminotransferase activity, without significant changes in Na(+)/K(+)-ATPase activity. In vivo inhibition of glutamine synthetase resulted in a short-term significant decrease in retinal aspartate aminotransferase activity. An increase in retinal aspartate aminotransferase and lactate dehydrogenase activities was accompanied by altered levels of amino acids in neurons and glia after partial inhibition of glial metabolism, implying that short- and long-term up- and down-regulation of key metabolic enzymes occurs to supply carbon skeletons for retinal metabolism. ATPase activity does not appear to fluctuate under the metabolic stresses employed in our experimental procedures.     

Enzymatic and mitochondrial responses to 5 months of aerial exposure in the slender lungfish Protopterus dolloi

Mitochondrial respiration and activities of key metabolic enzymes from liver and white skeletal muscle were compared between control aquatic slender lungfish Protopterus dolloi , and those exposed to air for 5 months. Activities of citrate synthase, glycogen phosphorylase, phosphofructokinase and pyruvate kinase in liver were not affected by air-exposure. In muscle, air-exposure reduced citrate synthase and pyruvate kinase activities (relative to tissue wet mass) by 63 and 50%, respectively. Liver carnitine palmitoyl transferase activity (relative to mitochondrial protein) decreased by half following air-exposure, but there was no change in muscle. In mitochondria isolated from muscle, state 3 and state 4 respiration were reduced by 74 and 89%, respectively following air-exposure, but liver mitochondria were not affected. In liver, air-exposure increased activities of ornithine-urea cycle enzymes including glutamine synthase, carbamoyl-phosphate synthase III and arginase, by 1·9- to 4·2-fold. Carbamoyl-phosphate synthase III activity could not be detected in muscle, indicating that urea is not synthesized in this tissue. These data suggest that skeletal muscle metabolism is downregulated in air-exposure, conserving energy and protein during a period when the animals cannot forage. In contrast, ATP production capacities in the liver are maintained, and this may permit expensive urea biosynthesis to continue during aerial exposure.     

Inosine analogs. Their metabolism in mouse L cells and in Leishmania donovani

The growth of Leishmania donovani promastigotes and mouse L cells is differentially inhibited by several inosine analogs with modifications in the imidazole ring. The protozoal and mammalian cells also demonstrate differential metabolism of these analogs. 7-Deazainosine, 7-thia-7,9-dideazainosine, and formycin B were converted to their respective ATP analogs by both cell types. 8-Azainosine was converted to a GTP analog by mouse L cells; L. donovani did not metabolize this nucleoside. 9-Deazainosine and allopurinol riboside were metabolized only to their respective IMP analogs by L cells. L. donovani metabolized 9-deazainosine and allopurinol riboside to their ATP analogs and also metabolized 9-deazainosine to its GTP analog. All nucleosides studied were resistant to cleavage by either organism. From metabolism studies in the presence of a specific enzyme inhibitor, it was deduced that allopurinol riboside, formycin B, and 9-deazainosine were phosphorylated by at least two different routes in the mouse L cells. The metabolism of formycin B was inhibited 65% by the adenosine kinase inhibitor, 5-iodotubercidin, whereas the metabolism of allopurinol riboside (14% inhibition) and 9-deazainosine (0% inhibition) was only slightly affected by this inhibitor. The metabolism of allopurinol riboside and 9-deazainosine by L. donovani was not affected by 5-iodotubercidin. In contrast to the results of L cells, the metabolism of formycin B by L. donovani was also not affected by 5-iodotubercidin. The abilities of mouse L cells and L. donovani to metabolize these inosine analogs to the corresponding nucleotide analogs of ATP or GTP may be considered to be an activating step and correlates well with the respective cytotoxic effects of these compounds.     

Characterization of cytochrome P450 2A4 and 2A5-catalyzed 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanone (NNK) metabolism

The tobacco-specific nitrosamine, 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanone (NNK), is a potent lung carcinogen in the A/J mouse, and is believed to be a causative agent for human lung cancer. NNK requires metabolic activation by alpha-hydroxylation to exert its carcinogenic potential. The human P450, 2A6 is a catalyst of this reaction. There are two closely related enzymes in the mouse, P450 2A4 and 2A5, which differ from each other by only 11 amino acids. In the present study these two mouse P450s were expressed in Spodoptera frugiperda (Sf9) cells using recombinant baculovirus. The catalysis of NNK metabolism by Sf9 microsomal fractions containing either P450 2A4 or 2A5 was determined. Both enzymes catalyzed the alpha-hydroxylation of NNK but with strikingly different efficiencies and specificities. P450 2A5 preferentially catalyzed NNK methyl hydroxylation, while P450 2A4 preferentially catalyzed methylene hydroxylation. The KM and Vmax for the former were 1.5 microM and 4.0 nmol/min/nmol P450, respectively, and for the latter 3.9 mM and 190 nmol/min/nmol P450. The mouse coumarin 7-hydroxylase, P450 2A5 is a significantly better catalyst of NNK alpha-hydroxylation than is the closely related human enzyme, P450 2A6.     

通过改换大肠杆菌腺苷酸代谢途径来增加胞内能荷水平

原核生物细胞能量和物质代谢的途径是一个很复杂的网络,改变代谢途径中的基因会对能量和物质流产生怎样的影响,仍然不是很清楚.以往的文献和研究已经将大肠杆菌的腺嘌呤核苷酸补救合成途径研究的很透彻.使用HPLC对删除了add基因的大肠杆菌细胞内腺苷类核苷酸分析表明,在腺嘌呤核苷酸补救途径中单一基因的途径操作不能有效改变腺嘌呤类核苷酸的代谢流向.实验中通过删除大肠杆菌JM83株中的add基因(编码腺苷脱氨酶[EC:3.5.4.4][1,2]),deoD基因(编码嘌呤核苷磷酸酶[EC:2.4.2.1][3,4]),amn基因(编码AMP核苷酶[EC:3.2.2.4][5])并引入外源ado1基因(来自酵母编码腺苷激酶[EC:2.7.1.20][6,7,8]),构建了菌株J991 (add-,deoD-,amn-,ado1 ,JM83),将其在含腺苷的LB培养基培养,使用HPLC分析其胞内腺苷类能量物质发现,ATP,ADP,AMP胞内含量都有所增加,分别都比对照JM83菌株提高一倍左右,大大加强了腺苷转化AMP的代谢流量,实现了改变物质代谢流向并使ATP积累的目的.该菌种实现了高产ATP代谢通路的构建,为下游生物工程发酵提供了较野生菌更高效的菌种,有望通过发酵工程优化培养,大幅提高ATP产量.同时,"尝试改变AMP的浓度而非直接针对ATP调节代谢途径,达到ATP积累的目"这一思路为同类研究提供参考.最后也表明在腺嘌呤核苷酸补救代谢途径中,为达到物质代谢流改变的目的,多基因联合操作较之单基因敲除更为有效.     

Scaling of gill metabolic potential as a function of salinity in the euryhaline crab,Callinectes sapidus rathbun

The body-size scaling pattern of enzymes that are important in energy metabolism was examined in gills of the blue crab as a function of acclimation salinity. We hypothesized that the higher surface-area-to-volume ratio of small crabs would impose a greater metabolic cost for hyperosmoregulation, leading to an increase in the capacity for ATP production in gills. Postmetamorphic crabs spanning a 2,500-fold range in body mass were examined following a 7-d exposure to a salinity of 35, 17, or 5 ppt. The posterior gills, which are the principal site of osmoregulatory ion pumping, generally had higher activities than the anterior gills, which are primarily used for gas exchange, and this discrepancy was greatest in small crabs. A significant effect of salinity was found only for the enzyme citrate synthase, where the activity was highest at the lowest salinity. Although most enzymes scaled negatively with body mass, the activity was independent of size over a 250-fold size range that encompassed the body masses of juvenile crabs but decreased abruptly in the adult crabs. These data suggest that ion pumping associated with osmoregulation may represent a greater energetic challenge in smaller crabs, and this is reflected in the relatively higher metabolic potential of the posterior gills. However, acclimation to different salinity regimes does not lead to dramatic global changes in the capacity for energy metabolism.     

An integrated analysis of enzyme activities, cofactor pools and metabolic fluxes in baculovirus-infected Spodoptera frugiperda Sf9 cells

The scarcity of fundamental knowledge on the baculovirus-host cell interaction is a major drawback for the improvement of bioprocesses through Metabolic Engineering. After the first hours post-infection, the virus takes over the control of cellular machinery, leading to the repression of host gene expression and imposing a high metabolic burden to insect cells. Nevertheless, there is a lack of detailed data on the metabolic responses to infection, which are ultimately responsible for system productivity performance. In this work, a further insight into the central metabolism of Sf9 cells is achieved by a combined analysis of enzyme activities, cellular cofactors (ATP and NAD(P)(+)/NAD(P)H) and metabolic fluxes. Hexokinase and isocitrate dehydrogenase were identified as feasible limiting steps of metabolism; carbon and nitrogen metabolism enzymes were differentially regulated during batch cultures. Moreover, alterations occurring after infection demonstrated the importance of maintaining the energetic state of the cells for baculovirus replication, since ATP accumulated in a MOI-dependent way, and the glutamate dehydrogenase anaplerotic pathway was greatly activated. Altogether, cellular de-energization and stress responses are relevant factors in the metabolic burden imposed by infection. The implications for the improvement of bioprocess performance are discussed.     

Enzymatic capacities for beta-oxidation of fatty fuels are low in the gill of teleost fishes despite presence of fatty acid-binding protein.

A variety of circulating fuels can support the work of the teleost gill. Previous work indicates, however, that unlike other aerobic tissues from teleosts, the gill may have a limited capacity to oxidize fatty fuels. We determined capacities for catabolism of carbohydrate, fatty acids, and amino acids in four species of temperate marine or euryhaline teleosts representing distinct lineages. In addition, we assessed the capacity for fatty acid oxidation in the gill from an Antarctic species. Activities of rate-limiting or regulatory enzymes from pathways of energy metabolism were measured at physiological temperatures (15 degrees or 1 degrees C). In the temperate species, ATP yields from glucose are 3- to 30-fold greater (varying with species) than ATP yields from a monounsaturated fatty acid, while ATP generation from glutamate is 2-50 times greater than similar capacities for the lipid fuel. Like the temperate species, capacity for beta-oxidation of fatty acids is limited in the Antarctic species. A positive linear correlation between activities of citrate synthase (central pathway of oxidative metabolism) and hexokinase (glycolysis) adds further support to the hypothesis that glucose is a preferred metabolic fuel in gill. Our results also demonstrate that fatty acid-binding protein is present in the gill of teleost fishes. It is likely that this protein plays a more important role facilitating anabolic pathways in lipid metabolism rather than fatty acid oxidation in the gill of teleost fishes.     

Extramitochondrial tricarboxylic acid cycle in retinal rod outer segments

Vertebrate retinal rod Outer Segments (OS) are the site of visual transduction, an energy demanding process for which mechanisms of ATP supply are still poorly known. Glycolysis or diffusion of either ATP or phosphocreatine from the Inner Segment (IS) does not seem to display adequate timing to supply ATP for phototransduction. We have previously reported data suggesting an aerobic metabolism in OS, which would largely account for the light-stimulated ATP need of the photoreceptor.Here, by oxymetry and biochemical analyses we show that: (i) disks isolated by Ficoll flotation consume O₂ in the presence of physiological respiring substrates either in coupled or uncoupled conditions; (ii) OS homogenates contain the whole biochemical machinery for the degradation of glucose, i.e. glycolysis and the tricarboxylic acid cycle (TCA cycle), consistently with the results of our previous proteomic study. Activities of the 8 TCA cycle enzymes in OS were comparable to those in retinal mitochondria-enriched fractions. Disk and OS preparations were subjected to TEM analysis, and while they can be considered free of inner segment contaminants, immunogold with specific antibodies demonstrate the expression therein of both the visual pigment rhodopsin and F_oF₁-ATP synthase. Finally, double immunofluorescence on mouse retina sections demonstrated a colocalization of some respiratory complex mitochondrial proteins with rhodopsin in rod OS.Data, suggestive of the exportability of the mitochondrial machinery for aerobic metabolism, may shed light on those retinal pathologies related to energy supply impairment in OS and to mutations in TCA enzymes.     

Energy transport and cell polarity: relationship of phosphagen kinase activity to sperm function

The energy required for motility of sea urchin sperm is transported from the mitochondrion to the flagellum by a phosphocreatine shuttle involving diffusion of phosphocreatine (PCr) between isozymes of creatine kinase (CrK) localized at the two sites (Tombes and Shapiro, Cell, 41:325, '85; Tombes et al., Biophys. J., 52:75, '87). The present studies demonstrate that high sperm CrK (various echinoderms; sea squirt, bristle worm, salmon) or arginine kinase (molusc, barnacle, moth) activity is seen in several species with sperm of a primitive morphology (mitochondrion at the base of the head, relatively long flagellum). In contrast, CrK activity is 10-100-fold less abundant in sperm of other species (frog, mouse, rooster, rabbit, bull, and human) that either possess a modified morphology (mitochondria that extend along the flagellum) and/or utilize glycolytic metabolism. We interpret these findings as support for the use of phosphagen kinase-dependent energy transport in cells in which the production of adenosine triphosphate (ATP) by the mitochondrion is distant from its utilization, leading to a form of metabolic polarization. Two other cell types, frog photoreceptors and rabbit oviduct cells, whose morphology and function also suggest that they exhibit metabolic polarization, contain relatively high CrK activity. The presence of high phosphagen kinase activity in metabolically polarized gametes and somatic cells further substantiates the role of such enzymes in facilitating energy transport.