Project description:Hemoglobin (Hb) released from red blood cells during hemolysis is a trigger of oxidative vascular damage with endothelial cells being a primary target. The Hb and heme scavenger proteins haptoglobin (Hp) and hemopexin (Hx) have been characterized as a sequential defense system with Hp as the primary protector and Hx as a backup when all Hp is depleted during more severe or prolonged hemolysis. The paradigm of sequential protection by the two scavengers is based on observational patient data proposed by Mueller-Eberhardt. In this study we present a mechanistic rationale for these clinical observations using a novel in vitro model of Hb triggered endothelial damage. We identified oxyHb(Fe2+) transformation to ferric Hb(Fe3+), free heme transfer from ferric Hb(Fe3+) to lipoprotein and subsequent oxidative reactions in the lipophilic phase. The accumulation of toxic lipid peroxidation products liberated during oxidation reactions lead to endothelial damage characterized by a specific gene expression pattern, reduced cellular ATP and monolayer disintegration. Quantitative analysis of key biochemical and functional parameters allowed us to precisely define the mechanisms and concentrations required for Hp and Hx to prevent this toxicity. In the case of Hp we defined an exponential relationship between Hp availability relative to oxyHb(Fe2+) and related protective activity. This exponential relationship demonstrates that large Hp quantities are required to prevent Hb toxicity. In contrast, the linear relationship between Hx concentration and protective activity allows for significant protection by the backup scavenger during conditions of large excess of free oxyHb(Fe2+) that occurs when all Hp is consumed. The diverse protective function of Hp and Hx in this model can be explained by the different target specificities of the two proteins.

Project description:Haptoglobin and Hemopexin are plasma acute phase proteins that bind with high affinity hemoglobin and heme, respectively. Several studies have demonstrated that they have a key role in the protection against oxidative stress and inflammation. However, little is known about the functional modules in which they are involved. To gain insights into this issue, we integrated bioinformatic and experimental approaches to identify genes coexpressed with Haptoglobin or Hemopexin and modulated in Haptoglobin and/or Hemopexin knock-out mice. These genes have a high probability to be functionally related to Haptoglobin and/or Hemopexin. We performed a gene expression analysis of the livers of Hp- and/or Hx-null mice compared to wild-type controls. The mice used in the following experiments, i.e. wild-type (Hp+/Hx+/), Hp-null (Hp-/-Hx+/), Hx-null (Hp+/Hx-/-), and HpHx-null (Hp-/-Hx-/-), were littermates derived by breeding F1 double heterozygous Hp+/-Hx+/- mice in the mixed genetic background C57/BLJ6 X 129Sv. We have three experimental points: Hx-null mice, Hp-null mice and HpHx-null mice. At least 5 adult mice per genotype were perfused via aorta with PBS, sacrificed and their liver pooled. Thirty microgram of total RNA were subjected to direct labeling reaction by incorporation of cyanin 3 (Cy3) or cyanin 5 (Cy5) fluorescent dyes into the cDNA by priming with oligo(dT). Four replicates were set up for each experimental point. In order to exclude artifacts resulting from different dye usage, we employed the dye-swap approach.

Project description:Haptoglobin and Hemopexin are plasma acute phase proteins that bind with high affinity hemoglobin and heme, respectively. Several studies have demonstrated that they have a key role in the protection against oxidative stress and inflammation. However, little is known about the functional modules in which they are involved. To gain insights into this issue, we integrated bioinformatic and experimental approaches to identify genes coexpressed with Haptoglobin or Hemopexin and modulated in Haptoglobin and/or Hemopexin knock-out mice. These genes have a high probability to be functionally related to Haptoglobin and/or Hemopexin. Keywords: haptoglobin, hemopexin, microarray, bioinformatics

Project description:Extracellular hemoglobin (Hb) has been recognized as a disease trigger in hemolytic conditions such as sickle cell disease, malaria and blood transfusion. In vivo, many of the adverse effects of free Hb can be attenuated by the Hb scavenger acute phase protein haptoglobin (Hp). The primary physiologic disturbances that can be caused be free Hb are found within the cardiovascular system and Hb triggered oxidative toxicity towards the endothelium has been promoted as a potential mechanism. The molecular mechanisms of this toxicity as well as of the protective activities of Hp are not yet clear. Within this study we systematically investigated the structural, biochemical and cell biologic nature of Hb toxicity in an endothelial cell system under peroxidative stress. We identified two principal mechanisms of oxidative Hb toxicity that are mediated by globin degradation products and by modified lipoprotein species, respectively. The two damage pathways trigger diverse and discriminative inflammatory and cytotoxic responses. Hp provides structural stabilization of Hb and shields Hb’s oxidative reactions with lipoproteins providing dramatic protection against both pathways of toxicity. By these mechanisms Hp shifts Hb’s destructive pseudo-peroxidative reaction into a potential anti-oxidative function during peroxidative stress. HPAEC: A two color common reference design was chosen with 4-8 independent biological replicates of each condition. Each experimental sample (Cy5 labeled) was hybridized against a non-treated reference sample (Cy3 labeled). HUVEC: A two color common reference design was chosen with 3-4 independent biological replicates of each condition. Each experimental sample (Cy5 labeled) was hybridized against a non-treated reference sample (Cy3 labeled).

Project description: Not available

Project description: Not available

Project description: Not available

Project description:Extracellular hemoglobin (Hb) has been recognized as a disease trigger in hemolytic conditions such as sickle cell disease, malaria and blood transfusion. In vivo, many of the adverse effects of free Hb can be attenuated by the Hb scavenger acute phase protein haptoglobin (Hp). The primary physiologic disturbances that can be caused be free Hb are found within the cardiovascular system and Hb triggered oxidative toxicity towards the endothelium has been promoted as a potential mechanism. The molecular mechanisms of this toxicity as well as of the protective activities of Hp are not yet clear. Within this study we systematically investigated the structural, biochemical and cell biologic nature of Hb toxicity in an endothelial cell system under peroxidative stress. We identified two principal mechanisms of oxidative Hb toxicity that are mediated by globin degradation products and by modified lipoprotein species, respectively. The two damage pathways trigger diverse and discriminative inflammatory and cytotoxic responses. Hp provides structural stabilization of Hb and shields Hb’s oxidative reactions with lipoproteins providing dramatic protection against both pathways of toxicity. By these mechanisms Hp shifts Hb’s destructive pseudo-peroxidative reaction into a potential anti-oxidative function during peroxidative stress.

Project description: Not available

Project description: Not available