[Alpha-1 antitrypsin deficiency: A model of alteration of protein homeostasis or proteostasis]. / Le déficit en alpha-1 antitrypsine: modèle d'altération de l'homéostasie protéique ou protéostasie.

Chronic obstructive pulmonary disease (COPD) is currently the ninth leading cause of death in France and is predicted to become the third leading cause of worldwide morbidity and mortality by 2020. Risk factors for COPD include exposure to tobacco, dusts and chemicals, asthma and alpha-1 antitrypsin deficiency. This genetic disease, significantly under-diagnosed and under-recognized, affects 1 in 2500 live births and is an important cause of lung and, occasionally, liver disease. Alpha-1 antitrypsin deficiency is a pathology of proteostasis-mediated protein folding and trafficking pathways. To date, there are only palliative therapeutic approaches for the symptoms associated with this hereditary disorder. Therefore, a more detailed understanding is required of the folding and trafficking biology governing alpha-1 antitrypsin biogenesis and its response to drugs. Here, we review the cell biological, biochemical and biophysical properties of alpha-1 antitrypsin and its variants, and we suggest that alpha-1 antitrypsin deficiency is an example of cell autonomous and non-autonomous challenges to proteostasis. Finally, we review emerging strategies that may be used to enhance the proteostasis system and protect the lung from alpha-1 antitrypsin deficiency.

[DEFI-ALPHA cohort and POLYGEN DEFI-ALPHA clinical research hospital programme. A study about clinical, biological and genetics factors associated with the occurrence and the evolution of hepatic complications in children with alpha-1 antitrypsin deficiency]. / Cohorte DEFI-ALPHA et projet hospitalier de recherche clinique POLYGEN DEFI-ALPHA. Étude des facteurs cliniques, biologiques et génétiques associés à l'apparition et à l'évolution de complications hépatiques chez les enfants présentant un déficit en alpha-1 antitrypsine.

INTRODUCTION: The alpha-1 antitrypsin (α1-AT) deficiency, most frequently caused by homozygosity for the Z variant (SERPINA1: c.1096 G>A; Glu342Lys), can give rise to two clinical patterns: (i) respiratory impairment with emphysema (mainly in adulthood) because of a pulmonary quantitative defect in anti-elastase activity; (ii) hepatic impairment (mainly in childhood) due to the misfolding of the PiZ protein which accumulates in hepatocytes thus providing cytotoxicity. CURRENT KNOWLEDGE: To date, the clinical and genetic factors responsible for the development of major hepatic injuries (fibrosis and portal hypertension) during childhood in PiZ patients are not known. METHODS: The DEFI-ALPHA cohort, created in 2008, aims to inventory and prospectively study all α1-AT deficient children diagnosed and included after occurrence of a hepatic sign. The POLYGEN DEFI-ALPHA PHRC has recently (2013) been added to the project to identify modifiers genes by two complementary approaches: (i) the candidate genes strategy with the SERPINA1, CFTR (cystic fibrosis gene), MAN1B1 and SORL1 genes, these two latter being implied in the degradation of misfolding proteins; (ii) the whole exome sequencing (WES) strategy in families in which the PiZ proband has a PiZ brother or sister free of any hepatic sign. EXPECTED RESULTS: The clinical parameter we want to explain is the apparition of a portal hypertension in PiZ children. In the DEFI-ALPHA project, three criteria will be tested: (i) age of inclusion in the cohort, (ii) the way of inclusion (neo-natal icterus or later hepatic impairment) and (iii) treatment or not with ursodesoxycholic acid and, if so, its duration. Genetically, polymorphisms on the SERPINA1 and MAN1B1 genes have already been associated in the literature with different clinical evolutions of the A1ATD but very inconstantly. Our study thus aims to confirm or not this association. The CFTR and SORL1 genes have never been studied in the α1-AT deficiency. Finally, the whole exome sequencing strategy could allow the discovery of new unexpected modifiers genes in this disease.

Proteostasis, an emerging therapeutic paradigm for managing inflammatory airway stress disease.

Airways stress diseases (ASDs), including chronic obstructive pulmonary disease (COPD), emphysema and asthma, are predicted to become the third leading cause of morbidity and mortality by 2020. An understanding and the treatment of these diseases will have a high impact on human health and the health system. An emerging area of heathspan impact is the link between ASDs and proteome homeostasis or 'proteostasis', a biological system comprised of > 2000 components that direct the generation, maintenance and removal of proteins to achieve normal function. Alpha-1 antitrypsin deficiency (αA1TD) aggregates activating extracellular folding stress pathways, dysregulation of nuclear factor erythroid 2-related factor 2 (Nrf2) and misprocessing by histone acetyltransferase (HAT)/histone deacetylase (HDAC) pathways represent key examples of proteostasis imbalance involved in ASDs. Common to these events in the lung is a chronic inflammatory response in response to nuclear factor-κB (NF-κB) signaling and protein folding stress associated with an excess of mucus secretion, tissue remodeling, peribronchiolar fibrosis, bronchoconstriction and aveolar destruction. All of these emergent properties of disease are a consequence of imbalance in the proteostasis system. Herein, we discuss the role of proteostasis and its consequences on lung pathophysiology in inflammatory ASDs, and suggest how manipulating the proteostasis network through pharmacological intervention of proteostasis pathways could provide multiple routes for the restoration of lung physiology.

The cytoprotective drug amifostine modifies both expression and activity of the pro-angiogenic factor VEGF-A.

BACKGROUND: Amifostine (WR-2721, delivered as Ethyol) is a phosphorylated aminothiol compound clinically used in addition to cis-platinum to reduce the toxic side effects of therapeutic treatment on normal cells without reducing their efficacy on tumour cells. Its mechanism of action is attributed to the free radical scavenging properties of its active dephosphorylated metabolite WR-1065. However, amifostine has also been described as a potent hypoxia-mimetic compound and as a strong p53 inducer; both effects are known to potently modulate vascular endothelial growth factor (VEGF-A) expression. The angiogenic properties of this drug have not been clearly defined. METHODS: Cancer cell lines and endothelial cells were used in culture and treated with Amifostine in order to study (i) the expression of angiogenesis related genes and proteins and (ii) the effects of the drug on VEGF-A induced in vitro angiogenesis. RESULTS: We demonstrated that the treatment of several human cancer cell lines with therapeutical doses of WR-1065 led to a strong induction of different VEGF-A mRNA isoforms independently of HIF-1alpha. VEGF-A induction by WR-1065 depends on the activation of the eIF2alpha/ATF4 pathway. This up-regulation of VEGF-A mRNA was accompanied by an increased secretion of VEGF-A proteins fully active in stimulating vascular endothelial cells (EC). Nevertheless, direct treatment of EC with amifostine impaired their ability to respond to exogenous VEGF-A, an effect that correlated to the down-regulation of VEGFR-2 expression, to the reduction in cell surface binding of VEGF-A and to the decreased phosphorylation of the downstream p42/44 kinases. CONCLUSIONS: Taken together, our results indicate that amifostine treatment modulates tumour angiogenesis by two apparently opposite mechanisms - the increased VEGF-A expression by tumour cells and the inhibition of EC capacity to respond to VEGF-A stimulation.