Clarithromycin pharmacokinetics in the desert tortoise (Gopherus agassizii)

Clarithromycin is a new, safe orally administered macrolide antibiotic active against Mycoplasma sp. in humans. Single-dose and multidose pharmacokinetic parameters were determined for clarithromycin in wild-caught desert tortoises (Gopherus agassizii) seropositive for M. agassizii. Clarithromycin blood levels were measured in three tortoises for up to 72 hr after a single oral dose of 7.5 mg/kg. In a second group of six tortoises, levels were measured after a dose of 15 mg/kg. Noncompartmental iterative two-stage Bayesian and nonparametric expectation maximization pharmacokinetic parameters were determined for each animal assuming first order rate constants. At 15 mg/kg, the maximum concentration was 1.37 microg/ml, the time to maximum concentration was 8.0 hr, and a plasma half-life of 11.69 hr was derived from the latter method. The absorption constant was 0.08/hr, the absorption half-life was 8.47 hr, and the weight-normalized volume of distribution was 5.30 L/kg. Predictions derived by the latter method suggested a dosage of 15 mg/kg p.o. every 24 hr to achieve maximal blood levels of > or =1 microg/ml for multiple dosing. However, results from a preliminary multidose study with three tortoises indicate that the drug is accumulated; therefore, the predicted dose may be closer to 15 mg/kg p.o. every 2-3 days to maintain blood levels of 2-7.5 microg/ml. (For n = 3, 2-point linear regression median estimates for the apparent elimination rate constant (K) and half-life are 0.0227/hr and 30.52 hr, respectively.) This multidose accumulation reflects a slower apparent elimination than that predicted in the eight single-dose tortoises (i.e., K = 0.0593/hr, t1/2 = 11.69 hr). This study highlights a potential pitfall of depending solely on single-dose studies and the potential value of oral administration in reptiles.

Pharmacokinetics of ceftazidime in loggerhead sea turtles (Caretta caretta) after single intravenous and intramuscular injections

The pharmacokinetics of ceftazidime in yearling loggerhead sea turtles (Caretta caretta) following single i.m and i.v. injections were studied. Eight juvenile 1.25+/-0.18 kg turtles were divided into two groups. Four animals received 20 mg/kg of ceftazidime i.v. and four received the same dose i.m. Plasma ceftazidime concentrations were analyzed by reverse-phase high-performance liquid chromatography. The i.v. and i.m. administration half-lives were 20.59+/-3.24 hr and 19.08+/-0.77 hr, respectively. The volume of distribution was 0.42+/-0.07 L/kg, and the systemic clearance was 0.217+/-0.005 ml/min/kg. Ceftazidime was detected in all blood samples and its concentration exceeded the minimum inhibitory concentration for Pseudomonas for 60 hr after i.m. and i.v. injections.

Maintenance of adenosine A1 receptor function during long-term anoxia in the turtle brain

It has been established that adenosine has a critical role in the extraordinary ability of the turtle brain to survive anoxia. To further investigate this phenomenon we compared rat and turtle brain adenosine A1 receptors using cyclopentyl-1,3-dipropylxanthine, 8-[dipropyl-2,3-3H(N)] ([3H]DPCPX) saturation binding analyses and determined the effects of prolonged anoxia (6, 12, and 24 h) on the adenosine A1 receptor of the turtle brain. The rat brain had a 10-fold greater density of A1 receptors compared with the turtle [rat cortex receptor density (Bmax) = 1,400 +/- 134.6 fmol/mg protein, turtle forebrain Bmax = 103.2 +/- 4.60 fmol/mg protein] and a higher affinity [dissociation constant (Kd) rat cortex = 0.328 +/- 0.035 nM, Kd turtle forebrain = 1.16 +/- 0.06 nM]. However, the turtle Kd is within the reported mammalian range, and the Bmax is similar to that reported for other poikilotherms. Unlike the mammal, in which A1 receptor function is rapidly compromised in anoxia, in the turtle forebrain no significant changes in the A1 receptor population were seen during 24-h anoxia. However, in the hindbrain, whereas the Bmax remained unchanged, the Kd significantly decreased from 2.1 to 0.5 nM after 6 h anoxia and this higher affinity was maintained at 12- and 24-h anoxia. These findings indicate that, unlike the GABAA receptor, the protective effectiveness of adenosine in the anoxic turtle brain is not related to an enhanced receptor number. Protection from a hypoxia-induced compromise in A1 receptor function and an increased A1 sensitivity in the hindbrain may be important factors for maintaining the adenosine-mediated downregulation of energy demand during long-term anoxia.

Identification and structural characterization of a novel member of the vitamin D binding protein family

The apparent high degree of homology of a blood protein with a unique dual binding affinity for two distinct hormones, thyroxin (T4) and vitamin D, isolated from a turtle, Trachemys scripta (Family Emydidae) and mammalian vitamin D binding protein (DBP) prompted further interspecific comparison to better understand the structure of functional binding sites. Using polymerase-chain reaction (PCR) with primers derived from the putative nucleotide sequences encoding peptides from the degradation of the T. scripta protein, we cloned the cDNA. The mature turtle protein contains 466 amino acids, about eight residues more than in mammalian DBP. The nucleotide sequence of the coding region showed 63% nucleotide and 73% amino acid homology (approximately 53% identity) to mammalian DBP (human, rat, mouse, and rabbit). However, there was no significant homology to mammalian T4-binding globulin (TBG) or transthyretin (TTR). Comparisons with mammals help define further the requirements for the vitamin D and actin binding sites. Northern blots of RNA isolated from turtle tissue probed with the 5' portion of cDNA established expression of the transcript in liver, kidney, and brain (in order of abundance), in contrast to mammal sequences in which expression of DBP is largely confined to the liver.

The marginal nuclei of the spinal cord in turtles: neuron assemblies in which gamma-aminobutyric acid and nitric oxide synthase are colocalized

Conspicuous nerve-cell assemblies, identified as the marginal nuclei described in other sauropsidans, were found all along the spinal cord of turtles. gamma-aminobutyric acid (GABA) and nitric oxide synthase (NOS) activities were colocalized within these neurons, which also reacted positively to reduced nicotinamide adenine dinucleotide phosphate-diaphorase stains. The marginal nuclei neurons may, thus, play an inhibitory function mediated by their GABA terminals and a long-distance modulatory function mediated by NO liberation.

Reversible decreases in ATP and PCr concentrations in anoxic turtle brain

A hallmark of anoxia tolerance in western painted turtles is relative constancy of tissue adenylate concentrations during periods of oxygen limitation. During anoxia heart and brain intracellular compartments become more acidic and cellular energy demands are met by anaerobic glycolysis. Because changes in adenylates and pH during anoxic stress could represent important signals triggering metabolic and ion channel down-regulation we measured PCr, ATP and intracellular pH in turtle brain sheets throughout a 3-h anoxic-re-oxygenation transition with 31P NMR. Within 30 min of anoxia, PCr levels decrease 40% and remain at this level during anoxia. A different profile is observed for ATP, with a statistically significant decrease of 23% occurring gradually during 110 min of anoxic perfusion. Intracellular pH decreases significantly with the onset of anoxia, from 7.2 to 6.6 within 50 min. Upon re-oxygenation PCr, ATP and intracellular pH recover to pre-anoxic levels within 60 min. This is the first demonstration of a sustained reversible decrease in ATP levels with anoxia in turtle brain. The observed changes in pH and adenylates, and a probable concomitant increase in adenosine, may represent important metabolic signals during anoxia.

Embryonic brain-gonadal axis in temperature-dependent sex determination of reptiles: a role for P450 aromatase (CYP19)

Sex determination in egg-laying amniotes may be fundamentally different from that of placental mammals. The mammalian ovary differentiates normally in the absence of estrogen, whereas estrogen seems to be crucial for proper ovarian development in birds, reptiles, and lower vertebrates. Estrogens are produced normally by the biosynthetic conversion of androgens by the enzyme aromatase (CYP19), which is the sole mediator of this reaction. Aromatase inhibitors are capable of reversing females to males in turtles and chickens; therefore, a role for aromatase as the female sex determinant has been postulated for species in which sex determination is temperature-dependent. The entire aromatase coding sequence (1,509 base pairs) from adult terrapin ovaries was cloned, and Northern analysis indicates a single transcript (2.4 kb) for adult ovaries, whereas male and female brains express a 2.4-kb as well as a 9.6-kb transcript. Using a sensitive (attomole sensitivity) competitive RT-PCR technique, aromatase transcript abundance was quantified during embryonic development for embryos treated with and without estrogen. Aromatase is transcribed, well before the temperature-sensitive, (stage 12), at both male and female temperatures in the brain. There is a switch to lower aromatase transcript abundance in the female brain concurrent with an exponential rise of aromatase transcript in the putative ovary. Transcripts remain below the detection limits in the putative testes but exhibit female levels of aromatase transcript when treated with estrogen. Aromatase mRNA levels are generally reduced in the brain by estradiol application. On the basis of these findings, we have postulated a model based on the competition between 5 alpha-reductase and P450 aromatase for androgen substrate in both the brain and the undifferentiated gonad to explain the TSD phenomenon in reptiles.

Sequence and expression analysis of WT1 and Sox9 in the red-eared slider turtle, Trachemys scripta

Temperature-dependent sex-determination (TSD) is a phenomenon that has been characterized at the ecological, morphological, and endocrinological levels in some reptilian species. We have begun to investigate TSD at the level of molecular development by cloning, sequencing, and analyzing the expression of two genes, WT1 and Sox9, in the red-eared slider turtle Trachemys scripta. We obtained almost full-length cDNA clones for WT1 and Sox9 that were greater than 73% identical to the human homologues at the nucleotide level. WT1 was expressed in urogenital tissue at all developmental stages examined (Yntema stages 12-20) at incubation temperatures that produce males (26 degrees C) or females (32 degrees C). Sox9 was also expressed throughout these same stages, but some differences were observed. At both 26 degrees C and 32 degrees C Sox9 was expressed in the mesonephroi and the undifferentiated gonads until Yntema stage 20, when only the gonad from the 26 degrees C embryos expressed a high level. In addition, there were two transcripts of Sox9 at all stages, but the relative proportion of the two transcripts differed at the two temperatures. Although the similarities in gene expression between a TSD species and other species with genotypically determined sex probably reflect the common features of organogenesis, differences may illustrate unique mechanisms for TSD.

Cytochromes P450 in liver of the turtle Chrysemys picta picta and the induction and partial purification of CYP1A-like proteins

Cytochromes P450 (CYP) in hepatic microsomes from the turtle Chrysemys picta picta and their response to inducers were examined. Freshly caught turtles had one protein (59 kDa) detected in western blot with monoclonal antibody 1-12-3 to scup CYP1A. That same band and a second band were detected with polyclonal anti-mouse Cyp1a1. Polyclonal anti-scup P450B (putative CYP2B) recognized three bands and anti-scup P450A (putative CYP3A), one band. TCB (3,3',4,4'-tetrachlorobiphenyl) at 5 mg kg-1 injected once induced EROD activity 3-fold. Repeated high-dose injections of TCB, 2,3,3',4,4'-pentachlorobiphenyl, Aroclor 1254 or beta-naphthoflavone induced CYP1A 20-fold and P450B-related proteins 2-3-fold. Rates of ethoxy- (EROD) methoxy- (MROD) and pentoxyresorufin O-dealkylases and benzo[a]pyrene (B[a]P) hydroxylase (AHH) were induced by these treatments, and were correlated with putative CYP1A content. Phenobarbital slightly elevated only MROD activity. Ethoxycoumarin (EC) O-deethylase rates were high, 1.6-2.2 nmol min-1 mg-1 in control and treated turtles, suggesting that EC is not a turtle CYP1A substrate. Highly induced EROD rates were 0.06 nmol min-1 mg-1, while AHH rates exceeded 4 nmol min-1 mg-1, suggesting that C. picta picta CYP1A may prefer PAH substrates. Induction of AHH was reflected in the formation of metabolites 3-OH-, 9-OH- and 7-OH-BP and BP-7,8-dihydrodiol (DHD). BP-4,5-DHD was not detected. Chromatographic procedures resolved the 59 kDa putative CYP1A from the second protein recognized by anti-Cyp1a1. The 59-kDa protein was also specifically and highly immunopurified by Mab 1-12-3. Thus, several CYP including two CYP1A-related proteins are expressed in turtle liver. Multiple CYP1A genes in reptiles may provide an insight into the origin of divergence in the CYP1A subfamily. Induction of a CYP1A may be a useful indicator of exposure to Ah receptor agonists in turtles.

Environmental occurrence and potential toxicity of planar, mono-, and di-ortho polychlorinated biphenyls in the biota

Four non-ortho-, eight mono-ortho-, and two di-ortho-chlorinated congeners have been determined in fresh water and salt water mussels, fish, snapping turtles, mallard, seals, and in human milk and adipose tissue. The planar PCB congeners are separated from the remainder of PCBs by activated carbon chromatography or HPLC on porous graphitic carbon followed by gas chromatography with electron capture detection. PCB toxic equivalency factors (TEFs) recommended by WHO [1] for 3 non-ortho, 8 mono-ortho, and 2 di-ortho PCBs and a TEF for congener 81 suggested by Harris et al. [2] were used for calculation of the contribution to dioxin-like toxicity to each life form. In all the biota examined, PCB congener IUPAC number 126 was the major contributor to PCB toxic equivalents. Congeners IUPAC number 118, 114, 105, 156, 157, 77, 81, and 170 also contributed significantly to PCB toxic equivalents. The ability to separate out planar PCBs from the majority of PCBs has allowed the use of TCDD toxicity equivalence to compare the relative dioxin-like potency of PCB residues in various species from different locations.

Reptile lysozyme: the complete amino acid sequence of soft-shelled turtle lysozyme and its activity

Soft-shelled turtle egg-white lysozyme was purified and sequenced. Lysozyme was reduced and carboxymethylated to fragment it with trypsin, V8 protease and CNBr. The peptides yielded were purified by RP-HPLC and sequenced. Every trypsin peptide was overlapped by V8 protease peptides and CNBr fragment. The amino acid sequence was compared with other lysozymes. This lysozyme has an extra Gly residue at N-terminus, which was found in pheasant lysozyme. Further, this lysozyme has an insertion of a Gly residue between 47 and 48 residues when compared with chicken lysozyme, as found in human lysozyme, therefore it proved that this lysozyme has the largest number of amino acids (131 aa) in chicken type lysozymes. The amino acid substitutions were found at subsites E and F. Namely Phe34, Arg45, Thr47, and Arg114 were replaced by His, Tyr, Arg, and Tyr, respectively. The time course using N-acetylglucosamine pentamer as a substrate showed a reduction of the rate constant for glycosidic cleavage and increase of binding free energy for subsites E and F, which proved the contribution of amino acids mentioned above for substrate binding at subsites E and F.

31P-NMR determinations of cytosolic phosphodiesters in turtle hearts

As part of our ongoing research on cardiac hypoxia tolerance we have conducted 31P nuclear magnetic resonance (NMR) studies of isolated, perfused, working hearts from freshwater turtles, animals that are well known for their ability to tolerate prolonged periods of anoxia. A striking feature of turtle heart spectra is an extremely high concentration of NMR visible phosphodiesters (PDEs). Cardiac spectra from mammals, on the other hand, typically exhibit only a small resonance in the PDE region. Our aim in this study was to compare myocardial PDE profiles between the highly hypoxia tolerant western painted turtle (Chrysemys picta bellii) and the relatively hypoxia sensitive softshelled turtle (Trionyx spinifer) in order to begin to rest the hypothesis that high constitutive levels of cytosolic PDEs may play a role in conferring hypoxia and ischemia tolerance on the myocardium. We also collected 31P-NMR spectra of PCA extracts of tissue from these species and from Kemp's ridley sea turtles (Lepidochelys kempi), as well as spectra from isolated hearts and PCA extracts of red-eared sliders (Trachemys [formerly Pseudemys] scripta]). Total NMR visible phosphodiesters make up 24 +/- 8.6% of the total NMR visible phosphorus in Chrysemys hearts, 20.7 +/- 5.9% in Trachemys hearts, but only 12.2 +/- 5.1% in Trionyx hearts (P < 0.05). We have identified three distinct PDEs in turtle hearts: glycerophosphorylcholine (GPC); glycerophosphorylethanolamine (GPE); and serine ethanolamine phosphodiester (SEP). SEP is the dominant compound in Chrysemys and Trachemys (79.3 +/- 10.2% and 84.7 +/- 3.7% of total PDE, respectively), while GPC is most abundant in Trionyx (74.0 +/- 4.3% of total PDE) and Lepidochelys (not quantitated). The function of this class of compounds is unclear but it has been suggested that cytosolic PDEs may function as lysophospholipase inhibitors, a role that would decrease the rate of membrane phospholipid turnover. Our comparative data suggest that cytosolic PDEs could play a role in phospholipid sparing during anoxic or ischemic stress in turtles but a direct test of this hypothesis awaits future experimentation.

The effect of the renal portal system on pharmacokinetic parameters in the red-eared slider (Trachemys scripta elegans)

The premise that drugs not be injected into the caudal body of reptiles because they will be carried by the renal portal system to the kidneys, where they may be nephrotoxic or rapidly excreted, was tested by comparing the pharmacokinetics of gentamicin (excreted via glomerular filtration in mammals) and carbenicillin (excreted partly via renal tubular secretion in mammals) following injection into the forelimb or hindlimb of red-eared sliders (Trachemys scripta elegans). Ten sliders received intramuscular gentamicin (10 mg/kg) in a forelimb (n = 5) or a hindlimb (n = 5), and plasma levels of the drug were assayed over time. Following drug clearance, the experiment was repeated with the site of injection reversed so that each animal acted as its own control. Another 10 sliders were similarly treated, using intramuscular carbenicillin (200 mg/kg). Injection site of gentamicin had no effect on any pharmacokinetic parameter (time to maximum plasma concentration, maximum plasma concentration, half-life, area under the curve, clearance, and volume of distribution). However, the area under the curve of plasma carbenicillin concentration vs. time was significantly lower following hindlimb injection, in comparison with forelimb injection, at 1, 4, and 8 hr, which may reflect reduced bioavailability of the drug, as would be expected with renal portal perfusion and tubular excretion on first pass through the kidney. This effect on carbenicillin likely is not clinically important because plasma levels remained above recommended minimum inhibitory concentrations. Because blood draining the caudal body of reptiles passes through the kidneys or the liver before reaching the central circulation, the effect on the pharmacokinetics of a drug injected in that region will vary with its renal or hepatic extraction rate. Generally, this effect is unlikely to be significant.

Brain Na+/K+-ATPase activity in two anoxia tolerant vertebrates: crucian carp and freshwater turtle

The crucian carp (Carassius carassius) and freshwater turtles (Trachemys scripta) are among the very few vertebrates that can survive extended periods of anoxia. The major problem for an anoxic brain is energy deficiency. In the brain, the Na+/K+-ATPase is the single most ATP consuming enzyme, being responsible for maintaining ion gradients. We here show that the Na+/K+-ATPase activity in the turtle brain is reduced by 31% in telencephalon and by 34% in cerebellum after 24 h of anoxia. Both changes were reversed upon reoxygenation. By contrast, the Na+/K+-ATPase activities were maintained in the anoxic crucian carp brain. These results support the notion that crucian carp and turtles use divergent strategies for anoxic survival. The fall in Na+/K+-ATPase activities displayed by the turtle is likely to be related to the strong depression of brain electric and metabolic activity utilized as an anoxic survival strategy by this species.

Overlapping distribution of receptors for atrial natriuretic peptide and angiotensin II in the kidney and the adrenal gland of the freshwater turtle, Amyda japonica

The distribution of receptors for atrial natriuretic peptide (ANP) and angiotensin II (ANG II) in the kidney and adrenal gland of the freshwater turtle, Amyda japonica, was examined by quantitative in vitro autoradiography using 125I-labeled rat (r)ANP1-28 and 125I-labeled human ANG II as labeled ligands. Receptor subtypes were characterized by competition with des[Gln18,Ser19,Gly20, Leu21, Gly22] ANP(4-23) (C-ANP) as a selective ligand of the clearance receptors to specific 125I-rANP(1-28) binding, and with DuP 753 and PD 123319 as nonpeptide antagonists for ANG II receptors type 1 (AT1) and type 2 (AT2) subtypes, respectively, to 125I-ANG II binding. Specific 125I-rANP(1-28) binding with a single binding site was found overlying glomeruli of the kidney and the outer zone of the adrenal gland with dissociation constants (Kd) of 4.39 +/- 0.33 and 6.07 +/- 1.36 nM, respectively. C-ANP (10 microM) inhibited about 90% of the glomerular and adrenal 125I-rANP(1-28) binding. Specific 125I-ANG II binding was also localized in the glomeruli of the kidney and the outer zone of the adrenal gland with Kd of 1.02 +/- 0.22 and 0.37 +/- 0.04 nM, respectively. DuP 753 (10 microM) potently inhibited about 80% of glomerular and 90% of adrenal 125I-ANG II binding, whereas PD 123319 (10 microM) was very weak in competing for specific 125I-ANG II binding in both tissues. Therefore, these results indicate that specific ANP and ANG II receptors with high affinities have an overlapping distribution in glomeruli of the kidney and the outer zone of the adrenal gland of the freshwater turtle. They also suggest that biological and clearance ANP receptor-like subtypes coexist in both tissues, and the predominant ANG II receptor subtype in these tissues is the AT1-like receptor. The overlapping distribution of specific receptors for both peptides in these tissues provides the basis for possible receptor interactions to exert a functional antagonism between ANP and ANG II in the freshwater turtle.

Release of adenosine and ATP in the brain of the freshwater turtle (Trachemys scripta) during long-term anoxia

Extracellular adenosine and ATP levels were monitored by microdialysis in the striatum of the freshwater turtle Trachemys scripta during long-term N2 respiration. After an initial rise in extracellular adenosine, a second peak of longer duration and higher in intensity, followed. The frequencies of these adenosine cycles varied considerably between individual turtles, such that the shortest time between the peaks was 80 min and the longest was 300 min (mean 151 min). After about 60 min anoxia, there was also a slow increase in extracellular ATP, rising from a normoxic concentration of 1.21 +/- 0.12 to 7.58 +/- 3.70 nmol l(-1) at 240 min anoxia. The results suggest that adenosine may continue to have a protective function in the turtle brain during long-term anoxia and that extracellular ATP might not function as an excitatory neurotransmitter in the anoxic turtle brain.

Specialized neuropeptide Y- and glucagon-like immunoreactive amacrine cells in the peripheral retina of the turtle

There are many regional differences in cell morphology and neurochemistry in the retina. This study examined a specialized population of neuropeptide Y- and glucagon-like immunoreactive amacrine cells in the peripheral retina of the turtle. Some of the dendritic processes from these peptidergic amacrine cells formed a dense circumferentially oriented nerve fiber plexus which ran parallel to the ora serrata. Collaterals from this plexus projected into and innervated the nonpigmented ciliary epithelium in the pars plana region of the ciliary body. Electron microscopy revealed that the neuropeptide Y- and glucagon-like immunoreactive processes in the ciliary epithelium contained many labeled, large dense-cored vesicles. Small crystals of lipid-soluble fluorescent dye were implanted in the retina near the ora serrata in fixed retinal tissue to search for other peripheral retinal specializations. Numerous thick and thin cell processes oriented parallel to the ora serrata were labeled in the retina by the dye. In addition, many dye-labeled somata with circumferentially oriented dendritic arborizations were seen in the extreme periphery of the retina. Many of these dye-labeled cells and processes were clearly not associated with the neuropeptide Y- and glucagon-like immunoreactive cells described above. This study has shown that some peptidergic neurons in the peripheral retina have a unique morphology in comparison to more centrally located cells. The function of these specialized peripheral cells is not established, but the innervation of the ciliary epithelium by peptidergic amacrine cells suggests that they may be involved in control of aqueous inflow.

Seasonal changes in gonadal activity and the effects of stress on reproductive hormones in the common snapping turtle, Chelydra serpentina

The seasonal gonadal cycle (including gonadal histology, sex steroids, and gonadotropins) was studied in freshly captured common snapping turtles, Chelydra serpentina, from Wisconsin, and the effects of capture stress were evaluated. The ovarian and testicular cycles are shorter than those reported in other freshwater turtles; the cycles commence in mid-May and terminate in early September, immediately after the completion of gonadal growth and maturation. In the female, testosterone (T), 17beta-estradiol (E2), and progesterone (Pro) were highly correlated with follicular growth and vitellogenesis. Ovulation in captivity and under natural conditions occurred after mid-May. In captivity, ovulation was a rapid process (24-48 hr); as the follicles descended into the uterine horns there was a significant increase in E2 and Pro and eggs were retained in the uterine horns for about 2 weeks before oviposition. In the male, T was significantly correlated with testicular growth and spermiation. Follicle-stimulating hormone (FSH) reached significantly higher levels (P < 0.01) in males (8.99 +/- 0.38 ng/ml) than in females (2.66 +/- 0.22 ng/ml), but luteinizing hormone was undetectable in both sexes. FSH was not correlated with the steroids in either sex. Sex steroids and FSH began to rise before spermiation and vitellogenesis and remained elevated until completion of gonadal growth and maturation. Leydig cells, the main source of plasma androgen in this species, became active shortly after emergence from hibernation and remained steroidogenically active for the rest of the cycle. Sertoli cells became active only after spermatogenesis was under way but also stayed active for the rest of the summer. Courtship and mating behaviors were observed in spring, summer, and fall. The snapping turtle is strictly aquatic with no basking behavior and limited behavioral thermoregulation so there is little daily fluctuation in body temperature. Environmental correlates indicate that the snapping turtle is temperature dependent: recrudesence occurs with a slight increase in water temperature during spring and early summer, while a dramatic drop in gonadal activity accompanies a slight decrease in temperature in fall. Changes in temperature may underlie changes in gonadal activity in the face of relatively stable FSH. Male turtles subjected to captivity and periodic blood sampling show a significant decline in T. The hormonal levels continued to decline whether the turtles are exposed to optimum or extreme temperatures. However, there is more rapid decline in T values in animals with regressed testes (June) than in those with well-developed testes (July). Male and female turtles kept in captivity at different phases of the cycle exhibit different patterns and degrees of response to stress, possibly related to the hormonal levels and the condition of the gonads.

Coexistence of alpha1 and beta adrenergic receptors in the liver of the frog Rana esculenta, the toad Bufo bufo, the lizard Podarcis sicula campestris, and the turtle Pseudemys picta elegans

In mammals and birds the characteristics of alpha1 adrenergic receptors and their biological role in liver metabolism have been clearly described, although the predominance of receptor subtypes varies with species. In contrast, the actual presence of hepatic alpha1 adrenergic receptors in fish, amphibians, and reptiles has been questioned. Only recently has their existence been demonstrated in some fish species and also in the wood frog Rana sylvatica. The present study assessed the presence of alpha1 adrenergic binding sites on hepatic membranes of frogs, toads, lizards, and turtles using the specific alpha1 adrenergic receptor antagonist [3H]prazosin; for comparison, the binding of the specific beta adrenergic receptor antagonist [3H]CGP-12177A was evaluated in the same preparations. alpha1 Adrenergic receptors are indeed present in the liver of the ectotherms examined. Specific binding is saturable, reversible, and linear as a function of tissue concentration. The binding data indicated the presence of two classes of binding sites displaying high and low affinities with Kds in the nanomolar and micromolar ranges, respectively. The present study provides the first evidence for the presence of alpha1 adrenergic receptors in the liver of toad, lizard, and turtle while confirming their existence in another species of frog, Rana esculenta.

Ca2+ activated myosin-ATPase in cardiac myofibrils of rainbow trout, freshwater turtle, and rat

The Ca(2+)-activated myosin-ATPase and its dependence on hypoxia were assessed in freshwater turtle, rainbow trout, and in some cases rat. At 20 degrees C and pH 7.3, the maximal ATPase activity was (mean +/- SEM): turtle 0.040 +/- 0.003, trout 0.090 +/- 0.005, and rat 0.12 +/- 0.004 mmol*min-1*g-1 myofibrillar dry weight. The turnover number was about three times lower for turtle than for trout. Trout is typically active at lower temperatures than turtle, and its myosin-ATPase activity was about three times lower at 10 degrees than at 20 degrees C. Addition of 12 mM phosphocreatine showed that the myosin-ATPase activity covered by myofibrillar creatine kinase was 22 +/- 2% for turtle, 14 +/- 2% for trout, and 69 +/- 5% for rat. At pH 6.8 relative to 7.3, the maximal M-ATPase activity was the same, whereas the Ca(2+)-sensitivity decreased, and more so for trout than for turtle. This difference disappeared, when trout myocardium was examined at 10 degrees C. P(i) (15 mM) affected neither maximal activity nor Ca(2+)-sensitivity. ADP, however, reduced maximal myosin-ATPase activity, and more so in trout than in turtle. In conclusion, the "slow"-type myosin, the low sensitivity of acidification and ADP, and the high creatine kinase/myosin-ATPase ratio in turtle relative to trout accord with the well-known ability of turtle myocardium to work during hypoxia. However, the difference in living temperature between turtle and trout obscures the situation (e.g. inclusion of rat data suggests that the creatine kinase/myosin-ATPase ratio is related to temperature.

Energy metabolism in liver of anoxia-tolerant turtle species (Pseudemys scripta): a model for studying hepatic tolerance to cold hypoxia

We have studied biochemical markers of energy metabolism and glycolysis by enzyme analyses and 1H NMR spectroscopy in livers of the freshwater turtle, Pseudemys scripta, after vascular flush and cold storage. Values for hepatic ATP content and energy charge remained unchanged for 24 h and showed only small declines between 24 and 48 h of cold hypoxia. Lactate and glucose levels increased over the 48-h period, demonstrating, respectively, progressive glycolysis and glycogenolysis. These observations are in contrast to those made in mammalian liver, where ATP levels fall precipitously during the first few hours of cold hypoxia and glycolysis is inhibited. Additional changes suggested by 1H NMR spectroscopy may indicate a role for other metabolic pathways. Isolated organs of species such as Pseudemys may be useful models for studying the biochemical basis of resistance to cold hypoxic damage.

Protein synthesis under conditions of anoxia and changing workload in ventricle strips from turtle heart

An earlier study determined that protein synthesis in isolated perfused turtle (Trachemys [= Pseudemys] scripta elegans) hearts was three-fold lower under conditions of anoxia than under conditions of normoxia. However, the earlier study did not attempt to define the role of work in the isolated perfused preparation. In this study, the effects of varying workload, as defined by changing frequency of contraction, and anoxia on protein synthesis were examined. The ventricle strip preparation allows for comparison of multiple strips from a single heart, which aids in eliminating the variability found between individuals chosen from wild populations. Ventricle strips forced to contract at 24 contractions.min-1 under anoxic conditions failed more rapidly than strips forced to contract at 24 contractions.min-1 under normoxic conditions. Protein synthesis decreased by 32% when compared to normoxic controls. When stimulation was terminated after 2 hr of contraction, the rate of protein synthesis in strips under anoxic conditions was similar to that in strips under normoxic conditions. Also, returning strips to normoxic conditions after 2 hr of anoxia restored protein synthesis to the level of the normoxic controls. A significant correlation between pacing rate and protein synthesis was found under normoxic conditions but not under anoxic conditions when strips were paced at 12, 18 and 24 contractions.min-1. Protein synthesis increased by 30% at the 18 contractions.min-1 frequency and 45% at the 24 contractions.min-1 frequency over the rate at 12 contractions.min-1 frequency. Force-frequency studies revealed that under normoxic conditions force generation did not change until above 24 contractions.min-1, but under anoxic conditions there was a significant negative inotropic effect (20% decrease in force) at 24 contractions.min-1 and fell to 50% of initial at 36 contractions.min-1. These studies indicate that, in the turtle heart, anoxia per se is not the only determinant of protein synthesis but rather that work plays an important role in protein synthesis, as in the mammalian heart.

Immunocytochemical and histochemical localization of nitric oxide synthase in the turtle retina

Recent interest in nitric oxide and its relationship to cGMP has produced many attempts to anatomically localize the enzyme synthesizing nitric oxide, nitric oxide synthase. In the retina, numerous previous studies have used the NADPH-diaphorase enzyme activity of nitric oxide synthase as a histochemical method to localize nitric oxide synthase. However, all NADPH-diaphorase activity is not necessarily nitric oxide synthase, because several enzymes have similar biochemical activity. Additionally, various histochemical methods have been used to demonstrate NADPH-diaphorase activity, which makes comparisons between studies difficult. The purpose of this study was twofold. First, we wanted to examine the histochemical labeling of NADPH-diaphorase in the turtle retina to allow comparisons to previous studies. Second, we wanted to compare the histochemical localization of NADPH-diaphorase activity to the immunocytochemical localization of nitric oxide synthase in the turtle retina. Our histochemical localization of NADPH-diaphorase activity and our localization of nitric oxide synthase-like immunoreactivity in the turtle retina both produced similar results. Both the histochemistry and immunocytochemistry consistently labeled photoreceptor inner segments, at least three amacrine cell types, and processes in the inner plexiform layer. In optimized double-labeled preparations, all cells with NADPH-diaphorase activity were also positive for nitric oxide synthase-like immunoreactivity, although some somata in the ganglion cell layer only had nitric oxide synthase-like immunoreactivity. The immunocytochemical localization of nitric oxide synthase in photoreceptors, amacrine cells, and putative ganglion cells indicates that nitric oxide may function at several levels of visual processing in the turtle retina.