Your search keyword '"Galli, Gina"' showing total 8 results

1. Effects of Developmental Hypoxia on the Vertebrate Cardiovascular System.

Author

Galli, Gina L. J., Lock, Mitchell C., Smith, Kerri L. M., Giussani, Dino A., and Crossley, Dane A.

Subjects

*CARDIOVASCULAR system, *HYPOXEMIA, *VERTEBRATES

Abstract

Developmental hypoxia has profound and persistent effects on the vertebrate cardiovascular system, but the nature, magnitude, and long-term outcome of the hypoxic consequences are species specific. Here we aim to identify common and novel cardiovascular responses among vertebrates that encounter developmental hypoxia, and we discuss the possible medical and ecological implications. [ABSTRACT FROM AUTHOR]

Published

2023

2. Chronic developmental hypoxia alters mitochondrial oxidative capacity and reactive oxygen species production in the fetal rat heart in a sex‐dependent manner.

Author

Smith, Kerri L. M., Swiderska, Agnieszka, Lock, Mitchell C., Graham, Lucia, Iswari, Wulan, Choudhary, Tashi, Thomas, Donna, Kowash, Hager M., Desforges, Michelle, Cottrell, Elizabeth C., Trafford, Andrew W., Giussani, Dino A., and Galli, Gina L. J.

Subjects

FETAL heart, REACTIVE oxygen species, OXYGEN consumption, WEIGHT gain, HYPOXEMIA, MITOCHONDRIA, MATERNAL-fetal exchange

Abstract

Insufficient oxygen supply (hypoxia) during fetal development leads to cardiac remodeling and a predisposition to cardiovascular disease in later life. Previous work has shown hypoxia causes oxidative stress in the fetal heart and alters the activity and expression of mitochondrial proteins in a sex‐dependent manner. However, the functional effects of these modifications on mitochondrial respiration remain unknown. Furthermore, while maternal antioxidant treatments are emerging as a promising new strategy to protect the hypoxic fetus, whether these treatments convey similar protection to cardiac mitochondria in the male or female fetus has not been investigated. Therefore, using an established rat model, we measured the sex‐dependent effects of gestational hypoxia and maternal melatonin treatment on fetal cardiac mitochondrial respiration, reactive oxygen species (ROS) production, and lipid peroxidation. Pregnant Wistar rats were subjected to normoxia or hypoxia (13% oxygen) during gestational days (GDs) 6–20 (term ~22 days) with or without melatonin treatment (5 µg/ml in maternal drinking water). On GD 20, mitochondrial aerobic respiration and H2O2 production were measured in fetal heart tissue, together with lipid peroxidation and citrate synthase (CS) activity. Gestational hypoxia reduced maternal body weight gain (p <.01) and increased placental weight (p <.05) but had no effect on fetal weight or litter size. Cardiac mitochondria from male but not female fetuses of hypoxic pregnancy had reduced respiratory capacity at Complex II (CII) (p <.05), and an increase in H2O2 production/O2 consumption (p <.05) without any changes in lipid peroxidation. CS activity was also unchanged in both sexes. Despite maternal melatonin treatment increasing maternal and fetal plasma melatonin concentration (p <.001), melatonin treatment had no effect on any of the mitochondrial parameters investigated. To conclude, we show that gestational hypoxia leads to ROS generation from the mitochondrial electron transport chain and affects fetal cardiac mitochondrial respiration in a sex‐dependent manner. We also show that maternal melatonin treatment had no effect on these relationships, which has implications for the development of future therapies for hypoxic pregnancies. [ABSTRACT FROM AUTHOR]

Published

2022

3. Developmental programming of DNA methylation and gene expression patterns is associated with extreme cardiovascular tolerance to anoxia in the common snapping turtle.

Author

Ruhr, Ilan, Bierstedt, Jacob, Rhen, Turk, Das, Debojyoti, Singh, Sunil Kumar, Miller, Soleille, Crossley II, Dane A., and Galli, Gina L. J.

Subjects

DNA methylation, GENE expression, EPIGENOMICS, HYPOXEMIA, GENETIC regulation, TURTLES

Abstract

Background: Environmental fluctuation during embryonic and fetal development can permanently alter an organism's morphology, physiology, and behaviour. This phenomenon, known as developmental plasticity, is particularly relevant to reptiles that develop in subterranean nests with variable oxygen tensions. Previous work has shown hypoxia permanently alters the cardiovascular system of snapping turtles and may improve cardiac anoxia tolerance later in life. The mechanisms driving this process are unknown but may involve epigenetic regulation of gene expression via DNA methylation. To test this hypothesis, we assessed in situ cardiac performance during 2 h of acute anoxia in juvenile turtles previously exposed to normoxia (21% oxygen) or hypoxia (10% oxygen) during embryogenesis. Next, we analysed DNA methylation and gene expression patterns in turtles from the same cohorts using whole genome bisulfite sequencing, which represents the first high-resolution investigation of DNA methylation patterns in any reptilian species. Results: Genome-wide correlations between CpG and CpG island methylation and gene expression patterns in the snapping turtle were consistent with patterns observed in mammals. As hypothesized, developmental hypoxia increased juvenile turtle cardiac anoxia tolerance and programmed DNA methylation and gene expression patterns. Programmed differences in expression of genes such as SCN5A may account for differences in heart rate, while genes such as TNNT2 and TPM3 may underlie differences in calcium sensitivity and contractility of cardiomyocytes and cardiac inotropy. Finally, we identified putative transcription factor-binding sites in promoters and in differentially methylated CpG islands that suggest a model linking programming of DNA methylation during embryogenesis to differential gene expression and cardiovascular physiology later in life. Binding sites for hypoxia inducible factors (HIF1A, ARNT, and EPAS1) and key transcription factors activated by MAPK and BMP signaling (RREB1 and SMAD4) are implicated. Conclusions: Our data strongly suggests that DNA methylation plays a conserved role in the regulation of gene expression in reptiles. We also show that embryonic hypoxia programs DNA methylation and gene expression patterns and that these changes are associated with enhanced cardiac anoxia tolerance later in life. Programming of cardiac anoxia tolerance has major ecological implications for snapping turtles, because these animals regularly exploit anoxic environments throughout their lifespan. [ABSTRACT FROM AUTHOR]

Published

2021

4. The Long-Term Effects of Developmental Hypoxia on Cardiac Mitochondrial Function in Snapping Turtles.

Author

Galli, Gina L. J., Ruhr, Ilan M., Crossley, Janna, and Crossley II, Dane A.

Subjects

REACTIVE oxygen species, TURTLES, MITOCHONDRIA, HYPOXEMIA, OXYGEN consumption, TURTLE eggs, BREATH holding

Abstract

It is well established that adult vertebrates acclimatizing to hypoxic environments undergo mitochondrial remodeling to enhance oxygen delivery, maintain ATP, and limit oxidative stress. However, many vertebrates also encounter oxygen deprivation during embryonic development. The effects of developmental hypoxia on mitochondrial function are likely to be more profound, because environmental stress during early life can permanently alter cellular physiology and morphology. To this end, we investigated the long-term effects of developmental hypoxia on mitochondrial function in a species that regularly encounters hypoxia during development—the common snapping turtle (Chelydra serpentina). Turtle eggs were incubated in 21% or 10% oxygen from 20% of embryonic development until hatching, and both cohorts were subsequently reared in 21% oxygen for 8 months. Ventricular mitochondria were isolated, and mitochondrial respiration and reactive oxygen species (ROS) production were measured with a microrespirometer. Compared to normoxic controls, juvenile turtles from hypoxic incubations had lower Leak respiration, higher P:O ratios, and reduced rates of ROS production. Interestingly, these same attributes occur in adult vertebrates that acclimatize to hypoxia. We speculate that these adjustments might improve mitochondrial hypoxia tolerance, which would be beneficial for turtles during breath-hold diving and overwintering in anoxic environments. [ABSTRACT FROM AUTHOR]

Published

2021

5. Mitochondria from anoxia-tolerant animals reveal common strategies to survive without oxygen.

Author

Galli, Gina and Richards, Jeffrey

Subjects

*MITOCHONDRIAL physiology, *HYPOXEMIA, *CALCIUM in the body, *CELLULAR signal transduction, *PHYLOGENY, *IN vitro studies

Abstract

The mitochondrion plays a critical role in the development of Oxygen (O)-related diseases. While research has predominantly focused on hypoxia-sensitive mammals as surrogates for humans, the use of animals which have naturally evolved anoxia tolerance has been largely ignored. Remarkably, some animals can live in the complete absence of O for days, months and even years, but surprisingly little is currently known about mitochondrial function in these species. In contrast to mammals, mitochondrial function in anoxia-tolerant animals is relatively insensitive to in vitro anoxia and reoxygenation, suggesting that anoxia tolerance transcends to the level of the mitochondria. Furthermore, long-term anoxia is associated with marked changes in the intrinsic properties of the mitochondria from these species, which may afford protection against anoxia-related damage. In the present review, we highlight some of the strategies anoxia-tolerant animals possess to preserve mitochondrial function in the absence of O. Specifically, we review mitochondrial Ca regulation, proton leak, redox signaling and mitochondrial permeability transition, in phylogenetically diverse groups of anoxia-tolerant animals. From the strategies they employ, these species emerge as model organisms to illuminate novel interventions to mitigate O-related mitochondrial dysfunction in humans. [ABSTRACT FROM AUTHOR]

Published

2014

6. Beating oxygen: chronic anoxia exposure reduces mitochondrial F1FO-ATPase activity in turtle (Trachemys scripta) heart.

Author

Galli, Gina L. J., Lau, Gigi Y., and Richards, Jeffrey G.

Subjects

*HYPOXEMIA, *TRACHEMYS scripta, *TURTLES, *NECROSIS, *APOPTOSIS, *ELECTRON transport, *PHYSIOLOGY

Abstract

The freshwater turtle Trachemys scripta can survive in the complete absence of O2 (anoxia) for periods lasting several months. In mammals, anoxia leads to mitochondrial dysfunction, which culminates in cellular necrosis and apoptosis. Despite the obvious clinical benefits of understanding anoxia tolerance, little is known about the effects of chronic oxygen deprivation on the function of turtle mitochondria. In this study, we compared mitochondrial function in hearts of T. scripta exposed to either normoxia or 2?weeks of complete anoxia at 5°C and during simulated acute anoxia/reoxygenation. Mitochondrial respiration, electron transport chain activities, enzyme activities, proton conductance and membrane potential were measured in permeabilised cardiac fibres and isolated mitochondria. Two weeks of anoxia exposure at 5°C resulted in an increase in lactate, and decreases in ATP, glycogen, pH and phosphocreatine in the heart. Mitochondrial proton conductance and membrane potential were similar between experimental groups, while aerobic capacity was dramatically reduced. The reduced aerobic capacity was the result of a severe downregulation of the F1FO-ATPase (Complex V), which we assessed as a decrease in enzyme activity. Furthermore, in stark contrast to mammalian paradigms, isolated turtle heart mitochondria endured 20 min of anoxia followed by reoxygenation without any impact on subsequent ADP-stimulated O2 consumption (State III respiration) or State IV respiration. Results from this study demonstrate that turtle mitochondria remodel in response to chronic anoxia exposure and a reduction in Complex V activity is a fundamental component of mitochondrial and cellular anoxia survival. [ABSTRACT FROM AUTHOR]

Published

2013

7. Cardiac survival in anoxia-tolerant vertebrates: An electrophysiological perspective

Author

Stecyk, Jonathan A.W., Galli, Gina L., Shiels, Holly A., and Farrell, Anthony P.

Subjects

*VERTEBRATE physiology, *HYPOXEMIA, *HEART physiology, *HEART beat, *ACTION potentials, *TRACHEMYS scripta, *CRUCIAN carp, *COLD adaptation

Abstract

Abstract: Certain vertebrates, such as freshwater turtles of the genus Chrysemys and Trachemys and crucian carp (Carassius carassius), have anoxia-tolerant hearts that continue to function throughout prolonged periods of anoxia (up to many months) due to successful balancing of cellular ATP supply and demand. In the present review, we summarize the current and limited understanding of the cellular mechanisms underlying this cardiac anoxia tolerance. What emerges is that cold temperature substantially modifies cardiac electrophysiology to precondition the heart for winter anoxia. Intrinsic heart rate is slowed and density of sarcolemmal ion currents substantially modified to alter cardiac action potential (AP) characteristics. These changes depress cardiac activity and reduce the energetic costs associated with ion pumping. In contrast, anoxia per se results in limited changes to cardiac AP shape or ion current densities in turtle and crucian carp, suggesting that anoxic modifications of cardiac electrophysiology to reduce ATP demand are not extensive. Additionally, as knowledge of cellular physiology in non-mammalian vertebrates is still in its infancy, we briefly discuss the cellular defense mechanisms towards the acidosis that accompanies anoxia as well as mammalian cardiac models of hypoxia/ischemia tolerance. By examining if fundamental cellular mechanisms have been conserved during the evolution of anoxia tolerance we hope to have provided a framework for the design of future experiments investigating cardiac cellular mechanisms of anoxia survival. [Copyright &y& Elsevier]

Published

2008

8. Sex-dependent effects of developmental hypoxia on cardiac mitochondria from adult murine offspring.

Author

Hellgren, Kim T., Premanandhan, Hajani, Quinn, Callum J., Trafford, Andrew W., and Galli, Gina L.J.

Subjects

*FETAL anoxia, *MYOCARDIAL reperfusion, *AEROBIC capacity, *HYPOXEMIA, *REACTIVE oxygen species, *MITOCHONDRIA

Abstract

Insufficient oxygen supply (hypoxia) during fetal and embryonic development can lead to latent phenotypical changes in the adult cardiovascular system, including altered cardiac function and increased susceptibility to ischemia reperfusion injury. While the cellular mechanisms underlying this phenomenon are largely unknown, several studies have pointed towards metabolic disturbances in the heart of offspring from hypoxic pregnancies. To this end, we investigated mitochondrial function in the offspring of a mouse model of prenatal hypoxia. Pregnant C57 mice were subjected to either normoxia (21%) or hypoxia (14%) during gestational days 6–18. Offspring were reared in normoxia for up to 8 months and mitochondrial biology was assessed with electron microscopy (ultrastructure), spectrophotometry (enzymatic activity of electron transport chain complexes), microrespirometry (oxidative phosphorylation and H 2 0 2 production) and Western Blot (protein expression). Our data showed that male adult offspring from hypoxic pregnancies possessed mitochondria with increased H 2 0 2 production and lower respiratory capacity that was associated with reduced protein expression of complex I, II and IV. In contrast, females from hypoxic pregnancies had a higher respiratory capacity and lower H 2 0 2 production that was associated with increased enzymatic activity of complex IV. From these results, we speculate that early exposure to hypoxia has long term, sex-dependent effects on cardiac metabolic function, which may have implications for cardiovascular health and disease in adulthood. Image 1 • Fetal hypoxia causes sex-dependent programming of cardiac mitochondrial function. • Males from hypoxic pregnancies have decreased aerobic capacity and increased reactive oxygen species (ROS). • Females from hypoxic pregnancies have increased aerobic capacity and decreased ROS. [ABSTRACT FROM AUTHOR]

Published

2021