Estrogen receptor mRNA expression patterns in the liver and ovary of female rainbow trout over a complete reproductive cycle.

Estrogens are critical hormones involved in reproduction and need to bind to estrogen receptors in target organs for biological activity. Fishes have two distinct estrogen receptor subtypes, alpha (α) and beta (ß), with variable combinations of additional isoforms of each subtype dependent on the history of genome duplication within a taxon. The comparative expression patterns of estrogen receptor isoforms during the female reproductive cycle will provide important insights into the unique function and importance of each. The purpose of this study was to measure the mRNAs for the four estrogen receptor isoforms (erα1, erα2, erß1, erß2) in the liver and ovary of adult, female rainbow trout over the course of an annual reproductive cycle. The expression of estrogen receptor mRNA isoforms was measured by quantitative real-time RT-PCR. Several reproductive indices (gonadosomatic index, maximum oocyte diameter, plasma estradiol-17ß, plasma vitellogenin, and ovulation) were also quantified for comparison and used in a correlation analysis to examine any inter-relationships. Of the four isoforms, the expression of erα1 was highest in the liver, and had a significant positive correlation with liver erß1 expression. Liver expression of erα2 mRNA was the lowest, but showed a significant positive correlation with maximum oocyte diameter in the ovary. The pattern of the erß isoforms in liver was one of initially elevated mRNA expression followed by a gradual decrease as reproductive development proceeded. In the ovary the erß1 isoform had the highest mRNA expression of all estrogen receptor isoforms, at the beginning of the reproductive cycle, but then decreased afterward. Both ovarian erß isoforms had a significant positive correlation with one another. In contrast, erα2 mRNA expression showed a high maximum level in the ovary near the end of the cycle along with a significant positive correlation with plasma estradiol-17ß levels; the highest gonadosomatic indices, maximum oocyte diameter, and vitellogenin levels occurred then too.

FcRn in the yolk sac endoderm of mouse is required for IgG transport to fetus.

In adults, the nonclassical MHC class I molecule, FcRn, binds both IgG and albumin and rescues both from a degradative fate, endowing both proteins with high plasma concentrations. FcRn also transports IgG from mother to young during gestation. Anticipating that a detailed understanding of gestational IgG transport in the mouse may give us a useful model to understand FcRn function in the human placenta, we have studied FcRn in the mouse yolk sac placenta in detail. Analyzing day 19-20 fetuses of the three FcRn genotypes resulting from matings of FcRn(+/-) parents, we found that FcRn(-/-) fetuses showed negligible IgG concentrations (1.5 microg/ml), whereas IgG concentrations in FcRn(+/-) fetuses were about a half (176 microg/ml) that of FcRn(+/+) fetuses (336 microg/ml), indicating that FcRn is responsible for virtually all IgG transport from mother to fetus. Immunofluorescence and immunoblotting studies indicated that FcRn is expressed in the endoderm of the yolk sac placenta but not in other cells of the yolk sac placenta or in the chorioallantoic placenta. IgG was found in the endoderm of both FcRn(+/+) and FcRn(-/-) yolk sac placentas and in the mesenchyme of FcRn(+/+) but was missing from the mesenchyme of FcRn(-/-) yolk sac placentas, indicating that IgG enters the endoderm constitutively but is moved out of the endoderm by FcRn. The similarities of these results to human placental FcRn expression and function are striking.

The major histocompatibility complex-related Fc receptor for IgG (FcRn) binds albumin and prolongs its lifespan.

The inverse relationship between serum albumin concentration and its half-life suggested to early workers that albumin would be protected from a catabolic fate by a receptor-mediated mechanism much like that proposed for IgG. We show here that albumin binds FcRn in a pH dependent fashion, that the lifespan of albumin is shortened in FcRn-deficient mice, and that the plasma albumin concentration of FcRn-deficient mice is less than half that of wild-type mice. These results affirm the hypothesis that the major histocompatibility complex-related Fc receptor protects albumin from degradation just as it does IgG, prolonging the half-lives of both.

Beta 2-microglobulin deficient mice catabolize IgG more rapidly than FcRn- alpha-chain deficient mice.

FcRn, a nonclassical MHC-I protein bound to beta 2-microglobulin (beta 2m), diverts IgG and albumin from an intracellular degradative fate, prolonging the half-lives of both. While knockout mouse strains lacking either FcRn-alpha-chain (AK) or beta 2m (BK) show much shorter half-lives of IgG and albumin than normal mice, the plasma IgG half-life in the BK and AK strains is different, being shorter in the BK strain. Since beta 2m does not affect the IgG production rate, we tested whether an additional beta 2m-associated mechanism protects IgG from catabolism. First, we compared the fractional disappearance rate in plasma of an intravenous dose of radioiodinated IgG in a mouse strain deficient in both FcRn-alpha-chain and beta 2m (ABK), in the two parental knockout strains (AK and BK), and in the background wild-type (WT) strain. We found that IgG survived longer in the beta 2m-expressing AK strain than in the beta 2m-lacking ABK and BK strains, whereas the IgG half-lives between the ABK and BK strains were identical. Then we compared endogenous concentrations of four typical plasma proteins among the four strains and found that steady-state plasma concentrations of both IgG and albumin were higher in the AK strain than in either the BK or the ABK strain. These results suggest that a beta 2m-associated effect other than FcRn prolongs the survival of both IgG and albumin, although leaky gene transcription in the AK strain cannot be ruled out.

Modeling the brain-pituitary-gonad axis in salmon.

To better understand the complexity of the brain-pituitary-gonad axis (BPG) in fish, we developed a biologically based pharmacodynamic model capable of accurately predicting the normal functioning of the BPG axis in salmon. This first-generation model consisted of a set of 13 equations whose formulation was guided by published values for plasma concentrations of pituitary- (FSH, LH) and ovary- (estradiol, 17alpha,20beta-dihydroxy-4-pregnene-3-one) derived hormones measured in Coho salmon over an annual spawning period. In addition, the model incorporated pertinent features of previously published mammalian models and indirect response pharmacodynamic models. Model-based equations include a description of gonadotropin releasing hormone (GnRH) synthesis and release from the hypothalamus, which is controlled by environmental variables such as photoperiod and water temperature. GnRH stimulated the biosynthesis of mRNA for FSH and LH, which were also influenced by estradiol concentration in plasma. The level of estradiol in the plasma was regulated by the oocytes, which moved along a maturation progression. Estradiol was synthesized at a basal rate and as oocytes matured, stimulation of its biosynthesis occurred. The BPG model can be integrated with toxico-genomic, -proteomic data, allowing linkage between molecular based biomarkers and reproduction in fish.

Flumequine in Atlantic salmon Salmo salar: disposition in fish held in sea water versus fresh water.

14C-labeled flumequine was administered as a single oral (5 mg kg(-1), 86 microCi kg(-1)) or intravenous (5 mg kg(-1), 82 microCi kg(-1)) dose to Atlantic salmon Salmo salar held in sea water or in fresh water. The absorption, tissue distribution and elimination were determined by means of liquid scintillation counting and whole-body autoradiography. The drug was rapidly absorbed and extensively distributed in all groups of fish. Radiolabeled compound was present in blood and muscle for more than 8 wk in the freshwater groups. In the seawater groups, however, no radioactivity was detected in the blood and muscle after 4 d and 2 wk, respectively. It was concluded that flumequine was eliminated at a substantially higher rate from Atlantic salmon in sea water than in fresh water.

IgG is transported across the mouse yolk sac independently of FcgammaRIIb.

While generally accepted that FcRn of the human syncytiotrophoblast and the mouse yolk sac endoderm is the major IgG transporter, the finding of a different Fc receptor FcgammaRIIb (RIIb) in the human placental endothelium has suggested the existence of an additional IgG transporter. Testing our hypothesis in mouse, we found that while RIIb is expressed in the yolk sac vasculature, IgG concentrations in fetuses of wild-type mice (RIIb(+/+)) and mice with a null mutation in the gene encoding RIIb (RIIb(-/-) mice) are not different, and we thus reject our hypothesis that yolk sac RIIb transports IgG in utero in the mouse. However, the capillary bed in the mouse yolk sac is structurally more complex than in human placenta, consisting of three types of cells: an RIIb-negative endothelium, a unique RIIb-bearing cell that also expresses 2 out of 4 macrophage markers but not endothelial cell or pericyte markers, and pericytes. As in the human placenta the b2 isoform of RIIb predominates in the mouse yolk sac. Remarkably only a single capillary channel rather than 2 channels with a loop is found in each yolk sac villus, which, along with intracapillary erythrocytes, suggests that blood flow is peristaltic, mediated by pericytes. It is not clear whether RIIb in the human placental villus might mediate an IgG transport function in light of the mouse yolk sac equivalent failing to do so.

Kinetics of FcRn-mediated recycling of IgG and albumin in human: pathophysiology and therapeutic implications using a simplified mechanism-based model.

The nonclassical MHC class-I molecule, FcRn, salvages both IgG and albumin from degradation. Here we introduce a mechanism-based kinetic model for human to quantify FcRn-mediated recycling of both ligands based on saturable kinetics and data from the literature using easily measurable plasma concentrations rather than unmeasurable endosomal concentrations. The FcRn-mediated fractional recycling rates of IgG and albumin were 142% and 44% of their fractional catabolic rates, respectively. Clearly, FcRn-mediated recycling is a major contributor to the high endogenous concentrations of these two important plasma proteins. While familial hypercatabolic hypoproteinemia is caused by complete FcRn deficiency, the hypercatabolic IgG deficiency of myotonic dystrophy could be explained, based on the kinetic analyses, by a normal number of FcRn with lowered affinity for IgG but normal affinity for albumin. A simulation study demonstrates that the plasma concentrations of IgG and albumin could be dynamically controlled by both FcRn-related and -unrelated parameters.

Kinetic modeling of nitric-oxide-associated reaction network.

PURPOSE: Nitric oxide and superoxide are the two important free radicals in the biological system. The coexistence of both free radicals in the physiological milieu gives rise to intricate oxidative and nitrosative reactions, which have been implicated in many physiological and/or pathophysiological conditions, such as vasodilatation and inflammation. It is difficult, if not impossible, to study the complexity of the nitric oxide/superoxide system using current experimental approaches. Computational modeling thus offers an alternative way for studying the problem. METHODS: In this present study, key reaction pathways related to the generation, reaction and scavenging of both nitric oxide and superoxide were integrated into a reaction network. The network dynamics was investigated by numerical simulations to a set of coupled differential equations and by dynamical analysis. Two specific questions pertaining to the reaction kinetics of the reactive chemical species in the nitric oxide/superoxide system were studied: (1) how does the system respond dynamically when the generation rate of nitric oxide and superoxide varies? (2) how would antioxidants such as glutathione modulate the system dynamics? RESULTS: While changing basal GSH levels does not alter the kinetics of nitric oxide, superoxide, and peroxynitrite, the kinetic profiles of N203, GSNO and GSH are sensitive to the variation of basal GSH levels. The kinetics of the potential nitrosative species, N203, is switch like, which is dependent on the level of GSH. CONCLUSIONS: The model predicts that concurrent high nitric oxide and superoxide generation--such as in the inflammatory conditions--may result in nonlinear system dynamics, and glutathione may serve as a dynamic switch of N203 mediated nitrosation reaction.

Albumin turnover: FcRn-mediated recycling saves as much albumin from degradation as the liver produces.

It is now understood that the nonclassical major histocompatibility complex-I molecule FcRn binds albumin and retrieves it from an intracellular degradative fate. Whether FcRn in the liver modulates albumin turnover through effects on biosynthesis and production is not known. Thus we quantified the appearance of biosynthetically labeled albumin in plasma after an intravenous bolus injection of [(3)H]leucine in FcRn-deficient mice. The production rates for both albumin (FcRn substrate) and transferrin (nonsubstrate) are increased by approximately 20% in FcRn-deficient mice compared with normal mice, likely compensating for the lowered plasma oncotic pressure caused by hypoalbuminemia in FcRn-deficient mice. Determining the magnitude of FcRn-mediated effects on albumin turnover, we then measured the steady-state plasma concentrations of biosynthetically labeled albumin and transferrin during [(3)H]leucine infusion. The concentration of albumin was approximately 40% lower in FcRn-deficient mice compared with normal mice. Furthermore, the approximately 40% lower plasma albumin concentration in FcRn-deficient mice along with the approximately 20% increase in albumin production indicate, by the mass-balance equation, that albumin degradation in FcRn-deficient mice is twice that of normal mice. These studies of biosynthetically labeled, and thus native, albumin support our previous finding that FcRn protects albumin from degradation. Permitting quantification of the magnitude of FcRn-mediated recycling, they further indicate that FcRn has extraordinary capacity: the amount of albumin saved from degradation by FcRn-mediated recycling is the same as that produced by the liver.

Accelerated transferrin degradation in HFE-deficient mice is associated with increased transferrin saturation.

HFE, a major histocompatibility complex class I-related protein, is implicated in the iron overload disease, hereditary hemochromatosis. Whereas patients with hereditary hemochromatosis have low serum transferrin levels, little is known about transferrin turnover in HFE deficiency states. We injected mice intravenously with radioiodinated transferrin and compared plasma transferrin decay and steady-state endogenous transferrin concentration in the plasma between HFE-deficient and wild-type C57BL/6 mouse strains. HFE-deficient mice degraded transferrin faster than normal (P < 0.001) and had lower plasma transferrin concentrations (P < 0.001). Both HFE-deficient and wild-type mice were then fed diets with 3 different iron concentrations that we designated deficient (2-5 mg/kg of iron), control (0.2 g/kg), and overload (20 g/kg) for 6 wk immediately after weaning to create a range of serum iron concentrations and resultant transferrin saturations ranging from 16 to 78%. We found an inverse correlation between transferrin saturation and transferrin half-life (P < 0.0001, r = -0.839) for both HFE-deficient and wild-type mice, which suggests that HFE does not have a direct effect on transferrin catabolism; rather, HFE may influence transferrin half-life indirectly through its effect on transferrin saturation, which in turn enhances transferrin decay in HFE-deficient mice.

Dynamic and biphasic modulation of nitrosation reaction by superoxide dismutases.

It has been shown that superoxide dismutase (SOD) can both potentiate and attenuate NO-mediated toxicity. This present study investigated the role of SOD and GSH in a sustained nitrosative and oxidative environment simulated by the nitric oxide (NO) and superoxide (O(2)(.-)) donor, 3-morpholinosydnonimine (SIN-1). We describe, for the first time, that SOD modulates nitrosative chemistry in a dynamic fashion that is both concentration and time-dependent. Specifically, our results show that SOD's effects on nitrosation are biphasic in nature i.e., while lower concentrations of SOD are pronitrosative, higher SOD concentrations inhibit nitrosation. However, even those initially inhibitory higher SOD concentrations became pronitrosative over time. In the presence of physiologically relevant levels of GSH, SOD predominantly exhibits a pronitrosative effect, with a complete loss of antinitrosative effects noted at higher levels of GSH. Our findings likely reflect the complex and dynamic nature of SOD interactions with oxidative and nitrosative species.