Differential response to CoCl2-stimulated hypoxia on HIF-1α, VEGF, and MMP-2 expression in ligament cells

The adult human anterior cruciate ligament (ACL) has a poor functional healing response, whereas the medial collateral ligament (MCL) does not. The difference in intrinsic properties of these ligament cells can be due to their different response to their located microenvironment. Hypoxia is a key environmental regulator after ligament injury. In this study, we investigated the differential response of ACL and MCL fibroblasts to hypoxia on hypoxia-inducible factor-1α, vascular endothelial growth factor, and matrix metalloproteinase-2 (MMP-2) expression. Our results show that ACL cells responded to hypoxia by up-regulating the HIF-1α expression significantly as compared to MCL cells. We also observed that in MCL fibroblasts response to hypoxia resulted in increase in expression of VEGF as compared to ACL fibroblasts. After hypoxia treatment, mRNA and protein levels of MMP-2 increased in both ACL and MCL. Furthermore we found in ACL pro-MMP-2 was converted more into active form. However, hypoxia decreased the percentage of wound closure for both ligament cells and had a greater effect on ACL fibroblasts. These results demonstrate that ACL and MCL fibroblasts respond differently under the hypoxic conditions suggesting that these differences in intrinsic properties may contribute to their different healing responses and abilities.     

Endothelial cells downregulate expression of the 70 kDa heat shock protein during hypoxia

Hsp70 is induced by hypoxia in most mammalian cell types and contributes to their ability to survive hypoxic episodes. However, little is known about Hsp70 expression in the hypoxia-tolerant endothelial cells (ECs). We investigated the effect of hypoxia on Hsp70 in human microvascular endothelial HMEC-1 cells. Reduction of pO(2) to 2.5% of normal for 20 h stimulated lactate production and the activity of glycolytic enzymes. This metabolic adaptation to hypoxia was accompanied by a remarkable reduction of Hsp70 on the protein level and on the mRNA level. Approximately 12 h after the hypoxic period Hsp70 expression reached pre-hypoxia levels again. Since ECs are adapted to the low oxygen tension of the vasculature they are confronted with a supraphysiological oxygen level during in vitro culture. We suppose that the high Hsp70 under these conditions reflects a stress response which disappears at the more physiological reduced oxygen tension during hypoxia.     

Hyperoxia and recovery from hypoxia alter collagen in peripheral pulmonary arteries similarly

Chronic hypoxia causes pulmonary hypertension, the mechanism of which includes altered collagen metabolism in the pulmonary vascular wall. This chronic hypoxic pulmonary hypertension is gradually reversible upon reoxygenation. The return to air after the adjustment to chronic hypoxia resembles in some aspects a hyperoxic stimulus and we hypothesize that the changes of extracellular matrix proteins in peripheral pulmonary arteries may be similar. Therefore, we studied the exposure to moderate chronic hyperoxia (FiO2 = 0.35, 3 weeks) in rats and compared its effects on the rat pulmonary vasculature to the effects of recovery (3 weeks) from chronic hypoxia (FiO2 = 0.1, 3 weeks). Chronically hypoxic rats had pulmonary hypertension (Pap = 26 +/- 3 mm Hg, controls 16 +/- 1 mm Hg) and right ventricular hypertrophy. Pulmonary arterial blood pressure and right ventricle weight normalized after 3 weeks of recovery in air (Pap = 19 +/- 1 mm Hg). The rats exposed to moderate chronic hyperoxia also did not have pulmonary hypertension (Pap = 18 +/- 1 mm Hg, controls 17 +/- 1 mm Hg). Collagenous proteins isolated from the peripheral pulmonary arteries (100-300 microm) were studied using polyacrylamide gel electrophoresis. A dominant low molecular weight peptide (approx. 76 kD) was found in hypoxic rats. The proportion of this peptide decreases significantly in the course of recovery in air. In addition, another larger peptide doublet was found in rats recovering from chronic hypoxia. It was localized in polyacrylamide gels close to the zone of alpha2 chain of collagen type I. It was bound to anticollagen type I antibodies. An identically localized peptide was found in rats exposed to moderate chronic hyperoxia. The apparent molecular weight of this collagen fraction suggests that it is a product of collagen type I cleavage by a rodent-type interstitial collagenase (MMP-13). We conclude that chronic moderate hyperoxia and recovery from chronic hypoxia have a similar effect on collagenous proteins of the peripheral pulmonary arterial wall.     

Effect of surplus amount of oxygen on the cerebrocortical microcirculatory reactions associated to moderate arterial hypotension

The aim of the present study was to clarify whether tissue hypoxia is involved in the autoregulatory dilatation of cerebrocortical vessels occurring at moderate arterial hypotension. In order to avoid hypoxia that may occur during arterial hypotension, in one part of the experiments the brain cortices were superfused with oxygen saturated (pO2, approximately 500 mm Hg) artificial cerebrospinal fluid (mock CSF). In the other part of the experiments arterial hypotension was induced without superfusing the brain cortices (closed skull). Mean arterial blood pressure (MABP) was decreased in both experimental groups by bleeding to 75-85 mm Hg for approximately 5 min, then the shed blood was reinfused. Changes in cortical vascular volume (CVV), mean transit time of cortical blood flow (tm), and blood flow (CBF) were measured through a cranial window with a microscope reflectometer. Although CSF pO2 differed markedly between the superfused and nonsuperfused experimental groups, arterial hypotension led to similar changes in CVV and tm in both groups. Due to the proper dilatation of the cerebrocortical arterioles, CBF was not altered by arterial hypotension in either of the groups. These results suggest that the brain cortex does not become hypoxic at moderate arterial hypotension and, consequently, incipient tissue hypoxia has no role in the autoregulatory dilatation of the cerebrocortical arterial network.     

Kvbeta1.2 subunit coexpression in HEK293 cells confers O2 sensitivity to kv4.2 but not to Shaker channels.

Voltage-gated K+ (KV) channels are protein complexes composed of ion-conducting integral membrane alpha subunits and cytoplasmic modulatory beta subunits. The differential expression and association of alpha and beta subunits seems to contribute significantly to the complexity and heterogeneity of KV channels in excitable cells, and their functional expression in heterologous systems provides a tool to study their regulation at a molecular level. Here, we have studied the effects of Kvbeta1.2 coexpression on the properties of Shaker and Kv4.2 KV channel alpha subunits, which encode rapidly inactivating A-type K+ currents, in transfected HEK293 cells. We found that Kvbeta1.2 functionally associates with these two alpha subunits, as well as with the endogenous KV channels of HEK293 cells, to modulate different properties of the heteromultimers. Kvbeta1.2 accelerates the rate of inactivation of the Shaker currents, as previously described, increases significantly the amplitude of the endogenous currents, and confers sensitivity to redox modulation and hypoxia to Kv4.2 channels. Upon association with Kvbeta1.2, Kv4.2 can be modified by DTT (1,4 dithiothreitol) and DTDP (2,2'-dithiodipyridine), which also modulate the low pO2 response of the Kv4.2+beta channels. However, the physiological reducing agent GSH (reduced glutathione) did not mimic the effects of DTT. Finally, hypoxic inhibition of Kv4.2+beta currents can be reverted by 70% in the presence of carbon monoxide and remains in cell-free patches, suggesting the presence of a hemoproteic O2 sensor in HEK293 cells and a membrane-delimited mechanism at the origin of hypoxic responses. We conclude that beta subunits can modulate different properties upon association with different KV channel subfamilies; of potential relevance to understanding the molecular basis of low pO2 sensitivity in native tissues is the here described acquisition of the ability of Kv4. 2+beta channels to respond to hypoxia.     

Hypoxia Causes Aggregation of Serine Palmitoyltransferase followed by Non-Apoptotic Death of Human Lymphocytes

In the central nervous system chronic hypoxia has been suggested to cause neurodegenerations and protein aggregation, as in Alzheimer’s disease. Here we have shown protein aggregation during acute hypoxia in human primary cells. Clinically relevant acute hypoxia (pO2 = 25 mmHg) was produced by incubation of venous blood in vitro, where 18-hour incubation resulted in raise of pCO2 to 90 mmHg, accumulation of lactate and acidosis (pH 7.06). In hypoxic samples the number of necrotic, but not apoptotic, white blood cells increased to 9.6%. Viable cells displayed hypoxia-related changes such as a drop of mitochondrial membrane potential and changes in the plasma membrane. These changes coincided with the 2.6-fold increase in immunoreactivity of serine palmitoyltransferase subunit 1 (SPT1), which is the enzyme involved in HSN1-type neurodegeneration. SPT1 immunoreactivity was presented as large cytosolic aggregates, which appeared in viable hypoxic cells and remained in dead cells. SPT-positive aggregates were also found in cell nuclei. This data suggests that SPT1 aggregation preceded cell death in hypoxia and represents the first evidence of acute protein aggregation during hypoxia.     

Action of hypoxia on different types of calcium channels in hippocampal neurons

Whole-cell patch clamp and polarographic oxygen partial pressure (pO2) measurements were used to establish the sensitivity of high-voltage-activated (HVA) Ca2+ channel subtypes of CA1 hippocampal neurons of rats to hypoxic conditions. Decrease of pO2 to 15-30 mm Hg induced a potentiation of HVA Ca2+ currents by 94%. Using selective blockers of N- and L-types of calcium channels, we found that inhibition of L-type channels decreased the effect by 54%, whereas N-type blocker attenuated the effect by 30%. Taking into account the ratio of currents mediated by these channel subtypes in CA1 hippocampal neurons, we concluded that both types of HVA Ca2+ channels are sensitive to hypoxia, however, L-type was about 3.5 times more sensitive to oxygen reduction.     

Brain hypoxia and the role of active forms of oxygen and of energy deficit in the neuron degeneration

The concepts about physiological mechanisms of oxygen transport to the brain have recently changed substantially. Precise data on the capillary blood flow rate, on a substantial dispersion of corresponding values, on the influence of the capillary blood flow rate on pO2 in the capillaries and tissues have evolved. Krog's paradigm about an exclusive role of capillaries in the gas exchange between the blood and tissues amounting to almost 100 years was abandoned. All these data also changed the concepts about the development of various types of hypoxia in the brain tissues. The study of pO2 in the brain at normoxia showed that pO2 exhibits the fluctuations from 1-2 to 80-85 mm Hg. This means, in particular, that hypoxic phenomena take place in the normal healthy brain. During hypoxia the mass adhesion of leukocytes to the walls of microvessels was shown to hamper the capillary blood flow and can become one of the reasons for the death of the brain during hypoxia. The brain hypoxia is not an occasional pathologic process. It exists in an intact brain owing to physiological fluctuations of pO2 in various microregions of the brain. It occurs during various physiological states in the norm and also during various illnesses associated with the changes and disruptions in the oxygen transport. The final stage of hypoxia is the destruction of the cells. The development of this process and its particular reasons are nowadays the subject of multiple physiological and biochemical studies. Certain changes are introduced into modern ideas about the reasons for the degradation of the nervous cells upon hypoxia. The degradation of the neurons during hypoxia or anemia is postulated to be associated not only with the cell generation of active forms of oxygen (AFO), but also with the energy deficiency. This means a deficient synthesis or a complete absence of ATP in a cell during hypoxia, anemia, and ishemia.     

Effect of maternal chronic hypoxic exposure during gestation on apoptosis in fetal rat heart

Chronic hypoxia during pregnancy is one of the most common insults to fetal development. We tested the hypothesis that maternal hypoxia induced apoptosis in the hearts of near-term fetal rats. Pregnant rats were divided into two groups, normoxic control and continuous hypoxic exposure (10.5% O2) from day 15 to 21 of gestation. Hearts were isolated from fetal rats of 21-day gestational age. Maternal hypoxia increased hypoxia-inducible factor-1alpha protein in fetal hearts. Chronic hypoxia significantly increased the percentage and size of binucleated myocytes and increased apoptotic cells from 1.4 +/- 0.14% to 2.7 +/- 0.3% in the fetal heart. In addition, the active cleaved form of caspase 3 was significantly increased in the hypoxic heart, which was associated with an increase in caspase 3 activity. There was a significant increase in Fas protein levels in the hypoxic heart. Chronic hypoxia did not change Bax protein levels but significantly decreased Bcl-2 proteins. In addition, chronic hypoxia significantly suppressed expression of heat shock protein 70. However, chronic hypoxia significantly increased expression of the anti-apoptotic protein 14-3-3, among other 14-3-3 isoforms. Chronic hypoxia differentially regulated beta-adrenoreceptor (beta-AR) subtypes with an increase in beta1-AR levels but no changes in beta2-AR. The results demonstrate that maternal hypoxia increases apoptosis in fetal rat heart, which may be mediated by an increase in Fas and a decrease in Bcl-2 proteins. Chronic hypoxia-mediated increase in beta1-AR and decrease in heat shock proteins may also play an important role in apoptosis in the fetal heart.     

A Ca(2+)-dependent protein kinase with characteristics of protein kinase C in leaves and mesophyll cell protoplasts from Digitaria sanguinalis: possible involvement in the C(4)-phosphoenolpyruvate carboxylase phosphorylation cascade

We have shown previously that fibroblasts derived from fat or dermal tissue differ in their functional properties, such as proliferation rate and contractile properties. To study these differences further, two-dimensional electrophoresis (2D PAGE) was performed on proteins isolated from cultured subcutaneous fat and dermal fibroblasts. The 2D gels were screened for proteins that were differentially expressed in all donors (n = 5). Five protein spots were subjected to further analysis by mass spectrometry. Two proteins could be identified: brain acid soluble protein 1 (BASP1) and cellular retinoic acid binding protein-II (CRABP-II). CRABP-II is of interest in terms of re-epithelialisation and was clearly expressed in dermal fibroblasts but not in fat fibroblasts. Real time PCR was performed to confirm the 2D data on CRABP-II. The CRABP-II mRNA level was significantly increased in dermal tissue and cultured dermal fibroblasts compared to fat tissue and cultured fat-derived fibroblasts, respectively. The mode of action of CRABP-II in skin is to mediate retinoic acid activity. Retinoic acid is known to inhibit migration and to stimulate differentiation of keratinocytes. The expression of CRABP-II by dermal fibroblasts implicates a role for these fibroblasts in wound re-epithelialisation, in contrast to subcutaneous fat-derived fibroblasts.     

The effect of serum withdrawal on the protein profile of quiescent human dermal fibroblasts in primary cell culture

The effect of serum deprivation on proliferating cells is well known, in contrast its role on primary cell cultures, at confluence, has not been deeply investigated. Therefore, in order to explore the response of quiescent cells to serum deprivation, ubiquitous mesenchymal cells, as normal human dermal fibroblasts, were grown, for 48 h after confluence, in the presence or absence of 10% FBS. Fibroblast behaviour (i.e. cell morphology, cell viability, ROS production and elastin synthesis) was evaluated morphologically and biochemically. Moreover, the protein profile was investigated by 2-DE and differentially expressed proteins were identified by MS. Serum withdrawal caused cell shrinkage but did not significantly modify the total cell number. ROS production, as evaluated by the dihydroethidium (DH2) probe, was increased after serum deprivation, whereas elastin synthesis, measured by a colorimetric method, was markedly reduced in the absence of serum. By proteome analysis, 41 proteins appeared to significantly change their expression, the great majority of protein changes were related to the cytoskeleton, the stress response and the glycolytic pathway. Data indicate that human dermal fibroblasts in primary cell culture can adapt themselves to environmental changes, without significantly altering cell viability, at least after a few days of treatment, even though serum withdrawal represents a stress condition capable to increase ROS production, to influence cell metabolism and to interfere with cell behaviour, favouring the expression of several age-related features.     

Does bradycardia or hypertension enhance gas transfer in rainbow trout (Oncorhynchus mykiss)?

Experiments were conducted to test the hypothesis that branchial gas transfer is enhanced in rainbow trout during hypoxia or hypercarbia by bradycardia and systemic vasoconstriction. Gas transfer was indirectly assessed by continuous monitoring of arterial blood gases, PaO2 and PaCO2. Cardiac frequency was maximally decreased by 34.9+/-4.3 and 8.6+/-3.2 bpm in hypoxic and hypercarbic fish, respectively. Pre-treating fish with atropine (1micromol kg(-1)) attenuated or abolished the bradycardia during hypoxia and hypercarbia, respectively. However, there were no significant differences in the arterial blood gases between the control and atropinized fish. Dorsal aortic blood pressure was increased maximally by 11.3+/-2.8 and 17.7+/-2.0mm Hg in the hypoxic and hypercarbic fish. Pre-treatment of fish with prazosin (2.4micromol kg(-1)) prevented these increases in blood pressure. Blood gases were unaltered by prazosin treatment in the hypercarbic fish. However, in the hypoxic fish, gas transfer appeared to be impaired by prazosin on the basis of lowered PaO2 (by approximately 35 mm Hg compared to control fish) and increased PaCO2 (by approximately 0.3mm Hg). Because the normal hyperventilatory response to hypoxia was prevented by prazosin, it is possible that the impairment of gas transfer was related to inadequate ventilation rather than to any differences in the pressor response. The present results provide no evidence that gas transfer in rainbow trout is enhanced by bradycardia nor do they reveal any obvious benefit associated with the increases in blood pressure that accompany hypoxia and hypercarbia.     

Effects of regional hypoxia and acidosis on Rb(+) uptake and energetics in isolated pig hearts: (87)Rb MRI and (31)P MR spectroscopic study.

The study compared the effects of regional hypoxia and acidosis on Rb(+) uptake and energetics in isolated pig hearts perfused by the Langendorff method. The left anterior descending artery (LAD) was cannulated and the LAD bed was perfused with the same specific flow as the whole heart. Following equilibration with normal Krebs-Henseleit buffer (KHB, pO(2) 568 mm Hg, pH 7.42) the perfusate was switched to one that contained Rb(+) (Rb-KHB). Simultaneously, perfusion through the LAD was carried out with hypoxic (pO(2)=31 mm Hg), an acidemic (pH 7.12) or normal (pO(2)=550 mm Hg) Rb-KHB for 120 min. (87)Rb images of the entire heart or localized (31)P spectra from the left ventricular anterior wall were acquired. Hypoxia decreased the maximal (87)Rb image intensity and Rb(+) flux in the anterior wall to 79+/-9% and 85+/-7%, respectively, of that in the posterior wall. Extracellular acidosis did not affect (87)Rb image intensity and reduced Rb(+) flux (83+/-10%). During hypoxia phosphocreatine and ATP decreased to 36+/-10 and 50+/-15% of baseline, respectively and intracellular pH (pHi) decreased to 6.90+/-0.05. Extracellular acidosis did not affect the phosphocreatine or ATP levels but reduced pHi (7.06+/-0.18 vs. 7.26+/-0.06 in control). We suggest that intracellular acidosis plays a role in the inhibition of Rb(+) uptake during hypoxia.     

Nitric oxide in the human respiratory cycle

Interactions of nitric oxide (NO) with hemoglobin (Hb) could regulate the uptake and delivery of oxygen (O(2)) by subserving the classical physiological responses of hypoxic vasodilation and hyperoxic vasconstriction in the human respiratory cycle. Here we show that in in vitro and ex vivo systems as well as healthy adults alternately exposed to hypoxia or hyperoxia (to dilate or constrict pulmonary and systemic arteries in vivo), binding of NO to hemes (FeNO) and thiols (SNO) of Hb varies as a function of HbO(2) saturation (FeO(2)). Moreover, we show that red blood cell (RBC)/SNO-mediated vasodilator activity is inversely proportional to FeO(2) over a wide range, whereas RBC-induced vasoconstriction correlates directly with FeO(2). Thus, native RBCs respond to changes in oxygen tension (pO2) with graded vasodilator and vasoconstrictor activity, which emulates the human physiological response subserving O(2) uptake and delivery. The ability to monitor and manipulate blood levels of NO, in conjunction with O(2) and carbon dioxide, may therefore prove useful in the diagnosis and treatment of many human conditions and in the development of new therapies. Our results also help elucidate the link between RBC dyscrasias and cardiovascular morbidity.     

Physiologic bases of the method to increase nonspecific resistance of the organism by adaptation to intermittent normobaric hypoxia]

Impulse biorhythm of cyclic pO2 change in the uterus tissues and intrauterine fetus of rats, guinea pigs and dogs is regarded as evolution-fixed, physiological mechanism aimed at increasing nonspecific resistance of the fetus. Modeling of this mechanism by adaptation to intermittent normobaric hypoxia under impulse conditions permits more significantly increasing nonspecific resistance of the organism than application of hypoxic effect under constant conditions.     

Hypoxia inhibition of apoptosis induced by tumor necrosis factor-related apoptosis-inducing ligand (TRAIL)

Hypoxia is a common environmental stress. Particularly, the center of rapidly growing solid tumors is easily exposed to hypoxic conditions. Thus, tumor cell response to hypoxia plays an important role in tumor progression as well as tumor therapy. However, little is known about hypoxic effect on apoptotic cell death. To examine the effects of hypoxia on TRAIL-induced apoptosis, human lung carcinoma A549 cells were exposed to hypoxia and treated with TRAIL protein. Hypoxia significantly protected A549 cells from apoptosis induced by TRAIL. Western blotting analysis demonstrated that hypoxia increased expression of antiapoptotic proteins such as Bcl-2, Bcl-XL, and IAP family members. The increase of these antiapoptotic molecules is believed to play an hypoxia-mediated protective role in TRAIL-induced apoptosis. Our findings suggest that an increase of antiapoptotic proteins induced by hypoxia may regulate the therapeutic activity of TRAIL protein in cancer therapy.     

Secretion Pores in Human Endothelial Cells during Acute Hypoxia

Weibel-Palade bodies (WPB) are endothelial vesicles that store von Willebrand factor (vWF), involved in the early phase of hemostasis. In the present study we investigated the morphodynamics of single WPB plasma membrane fusion events upon hypoxic stimulation by using atomic force microscopy (AFM). Simultaneously, we measured vWF release from endothelial cells to functionally confirm WPB exocytosis. Exposing human endothelial cells to hypoxia (pO2 = 5 mm Hg) we found an acute (within minutes) release of vWF. Despite acute vWF release, potential cellular modulators of secretion, such as intracellular pH and cell volume, remained unchanged. We only detected a slight instantaneous increase of cytosolic Ca2+ concentration. Although overall cell morphology remained virtually unchanged, high resolution AFM images of hypoxic endothelial cells disclosed secretion pores, most likely the loci of WPB exocytosis on luminal plasma membrane. We conclude that short-term hypoxia barely alters overall cell morphology and intracellular milieu. However, at nanometer scale, hypoxia instantaneously switches the smooth luminal plasma membrane to a rough activated cell surface, covered with secretion pores that release vWF to the luminal cell surface.