Minimal lung and systemic responses to TNF-alpha in preterm sheep

TNF-alpha has been associated with chorioamnionitis and the subsequent development of bronchopulmonary dysplasia in preterm infants. We asked whether bioactive recombinant ovine TNF-alpha could induce chorioamnionitis, lung inflammation, lung maturation, and systemic effects in fetal sheep. We compared the responses to IL-1alpha, a cytokine known to induce these responses in preterm sheep. Intra-amniotic TNF-alpha caused no chorioamnionitis, no lung maturation, and a very small increase in inflammatory cells in the fetal lung after 5 h, 2 days (d), and 7 d. In contrast, IL-1alpha induced inflammation and lung maturation. TNF-alpha given into the airways at birth increased granulocytes in the bronchoalveolar lavage fluid of ventilated preterm lungs and decreased the mRNA for surfactant protein C but did not adversely effect postnatal lung function. An intravascular injection of IL-1alpha caused a systemic inflammatory response in fetal sheep, whereas there was no fetal response to intravascular TNF-alpha. Fetal and newborn preterm sheep are minimally responsive to TNF-alpha. Therefore, the presence of a mediator such as TNF-alpha in a developing animal does not necessarily mean that it is causing the responses anticipated from previous results in adult animals.     

Roles of ferritin and iron in ischemic preconditioning of the heart

Iron and copper play major roles in biological systems, catalyzing free radical production and consequently causing damage. The relatively high levels of these metals, which are mobilized into the coronary flow following prolonged ischemia, have been incriminated as key players in reperfusion injury to the heart. In the present communication we investigated other roles of iron - providing protection to the ischemic heart via preconditioning (PC). PC was accomplished by subjecting isolated rat hearts to three episodes of 2 min ischemia separated by 3 min of reperfusion. Prolonged ischemia followed the PC phase. PC hearts (group I) were compared to hearts subjected to normal perfusion (group II, no ischemia) and to ischemia without PC (group III). Group I showed a marked improvement in the recovery of hemodynamic function vs. group III. Biochemical parameters further substantiated the PC protection provided to group I against prolonged ischemia. Correspondingly, group I presented markedly lower re-distribution and mobilization of iron and copper into the coronary flow, following prolonged ischemia, as evinced from the decrease in total levels, and in the 'free' fraction of iron and copper. During the PC phase no loss of cardiac function was observed. A small wave of re-distribution and mobilization of iron (typically less than 4-8% of the value of 35 min ischemia) was recorded. The cellular content of ferritin (Ft) measured in the heart was significantly higher in group I than in group III (0.90 and 0.54 microg/mg, respectively). Also, iron-saturation of Ft was significantly lower for PC hearts, compared to both groups II and III (0.22 vs. 0.32 and 0.31 microg/mg, for 35 min ischemia, respectively). These findings are in accord with the proposal that intracellular re-distribution and mobilization of small levels of iron, during PC, cause rapid accumulation of ferritin - the major iron-storage protein. It is proposed that iron play a dual role: (i) It serves as a signaling pathway for the accumulation of Ft following the PC phase. This iron is not involved in cardiac injury, but rather prepares the heart against future high levels of 'free' iron, thus reducing the degree of myocardial damage after prolonged ischemia. (ii) High levels of iron (and copper) are mobilized following prolonged ischemia and cause tissue damage.     

A novel stable polyalanine [poly(A)] expansion in the <Emphasis Type="Italic">HOXA13</Emphasis> gene associated with hand-foot-genital syndrome: proper function of poly(A)-harbouring transcription factors depends on a critical repeat length?

Hand-foot-genital syndrome (HFGS) is a dominantly inherited congenital malformation affecting the distal limbs and genitourinary tract. Here, we describe the phenotype and its molecular basis in a family that presented with HFGS. Genetic analysis revealed that the condition is caused by an 18-bp in-frame duplication within a cryptic trinucleotide repeat sequence encoding an 18-residue polyalanine tract in the homeoboxgene ( HOX) A13. This mutation expands the stretch with six extra alanine residues. Similar types of mutation (plus eight alanines) have recently been found in another HFGS family and also in the human HOXD13 gene (plus seven up to plus 14 residues) where it leads to synpolydactyly (SPD), a further congenital limb malformation rarely associated with genital abnormalities. As observed in our family, all the expanded tracts encoding polyalanine, either reported for HOXA13 or HOXD13, are quite stable when transmitted within affected families. Unlike disorders with unstable expansions of perfect trinucleotide repeats the molecular mechanism underlying these polyalanine expansions should be unequal crossing-over rather than replication slippage. The alanine tract elongation may prevent protein-protein interactions of the mutant HOXA13, thereby inducing a localized heterochrony in the sequence of distal limb and genitourinary development.     

Amisyn,a novel syntaxin-binding protein that may regulate SNARE complex assembly

The regulation of SNARE complex assembly likely plays an important role in governing the specificity as well as the timing of membrane fusion. Here we identify a novel brain-enriched protein, amisyn, with a tomosyn- and VAMP-like coiled-coil-forming domain that binds specifically to syntaxin 1a and syntaxin 4 both in vitro and in vivo, as assessed by co-immunoprecipitation from rat brain. Amisyn is mostly cytosolic, but a fraction co-sediments with membranes. The amisyn coil domain can form SNARE complexes of greater thermostability than can VAMP2 with syntaxin 1a and SNAP-25 in vitro, but it lacks a transmembrane anchor and so cannot act as a v-SNARE in this complex. The amisyn coil domain prevents the SNAP-25 C-terminally mediated rescue of botulinum neurotoxin E inhibition of norepinephrine exocytosis in permeabilized PC12 cells to a greater extent than it prevents the regular exocytosis of these vesicles. We propose that amisyn forms nonfusogenic complexes with syntaxin 1a and SNAP-25, holding them in a conformation ready for VAMP2 to replace it to mediate the membrane fusion event, thereby contributing to the regulation of SNARE complex formation.     

Complete reconstitution of the human coenzyme A biosynthetic pathway via comparative genomics

The biosynthesis of CoA from pantothenic acid (vitamin B5) is an essential universal pathway in prokaryotes and eukaryotes. The CoA biosynthetic genes in bacteria have all recently been identified, but their counterparts in humans and other eukaryotes remained mostly unknown. Using comparative genomics, we have identified human genes encoding the last four enzymatic steps in CoA biosynthesis: phosphopantothenoylcysteine synthetase (EC ), phosphopantothenoylcysteine decarboxylase (EC ), phosphopantetheine adenylyltransferase (EC ), and dephospho-CoA kinase (EC ). Biological functions of these human genes were verified using a complementation system in Escherichia coli based on transposon mutagenesis. The individual human enzymes were overexpressed in E. coli and purified, and the corresponding activities were experimentally verified. In addition, the entire pathway from phosphopantothenate to CoA was successfully reconstituted in vitro using a mixture of purified recombinant enzymes. Human recombinant bifunctional phosphopantetheine adenylyltransferase/dephospho-CoA kinase was kinetically characterized. This enzyme was previously suggested as a point of CoA biosynthesis regulation, and we have observed significant differences in mRNA levels of the corresponding human gene in normal and tumor cells by Northern blot analysis.     

Mining the Plasmodium genome database to define organellar function: what does the apicoplast do?

Apicomplexan species constitute a diverse group of parasitic protozoa, which are responsible for a wide range of diseases in many organisms. Despite differences in the diseases they cause, these parasites share an underlying biology, from the genetic controls used to differentiate through the complex parasite life cycle, to the basic biochemical pathways employed for intracellular survival, to the distinctive cell biology necessary for host cell attachment and invasion. Different parasites lend themselves to the study of different aspects of parasite biology: Eimeria for biochemical studies, Toxoplasma for molecular genetic and cell biological investigation, etc. The Plasmodium falciparum Genome Project contributes the first large-scale genomic sequence for an apicomplexan parasite. The Plasmodium Genome Database (http://PlasmoDB.org) has been designed to permit individual investigators to ask their own questions, even prior to formal release of the reference P. falciparum genome sequence. As a case in point, PlasmoDB has been exploited to identify metabolic pathways associated with the apicomplexan plastid, or 'apicoplast' - an essential organelle derived by secondary endosymbiosis of an alga, and retention of the algal plastid.     

MAP kinase cascade signaling and endocytic trafficking: a marriage of convenience?

A hallmark of many signaling pathways is the spatial separation of activation and deactivation of signaling proteins. Quantitative analysis demonstrates that the spatial separation of a membrane-bound kinase and a cytosolic phosphatase potentially results in precipitous gradients of target phosphoproteins. Hypothetically, such gradients in the mitogen-activated protein kinase (MAPK) cascade would result in a strong attenuation of the phosphorylation signal towards the nucleus. When effective signal transduction is hampered by slow protein diffusion and rapid dephosphorylation, phosphoprotein trafficking within endocytic vesicles might be an efficient way to propagate the signals. Additional mechanisms facilitating information transfer could involve the assembly of MAP kinases on a scaffolding protein and active transport of signaling complexes by molecular motors. The proposed mechanism explains recent observations that MAPK activation can be strongly suppressed by various inhibitors of endocytosis.     

Injury,inflammation, and remodeling in fetal sheep lung after intra-amniotic endotoxin

Chorioamnionitis is frequent in preterm labor and increases the risk of bronchopulmonary dysplasia. We hypothesized that intra-amniotic endotoxin injures the lung in utero, causing a sequence of inflammation and tissue injury similar to that which occurs in the injured adult lung. Preterm lamb lungs at 125 days gestational age were evaluated for indicators of inflammation, injury, and repair 5 h, 24 h, 72 h, and 7 days after 4 mg of intra-amniotic endotoxin injection. At 5 h, the epithelial cells in large airways expressed heat shock protein 70, and alveolar interleukin-8 was increased. Surfactant protein B (SP-B) decreased in alveolar type II cells at 5 h, and SP-B in lung tissue and alveolar lavage fluid increased by 72 h. By 24 h, neutrophils were recruited into the large airways, and cell death was the highest. Alveolar type II cells decreased by 25% at 24 h, and proliferation was highest at 72 h, consistent with tissue remodeling. Intra-amniotic endotoxin caused surfactant secretion, inflammation, cell death, and remodeling as indications of lung injury. The recovery phase was accompanied by maturational changes in the fetal lung.     

Effects of long duration +2G hypergravity on MHC distribution and maximal tension of rat m.soleus fibers

Effects of long duration hypergravity on skeletal muscles are much less studied than effects of microgravity. For instance, it was revealed that hypergravity of 2 week duration induces decrease in cross sectional area (CSA) of slow fibers (SF), while their size remains constant, or increases. Exposure to +2G of 14 day duration results in decreased number of type I fibers, and in changed myosin heavy chain (MHC) profiles of rat hindlimb extensor muscle. It is interesting that gravitational unloading also decreases number of type I fibers. However, while effects of microgravity on relationship between the structural and functional characteristics of skeletal muscles are studied in detail, similar characteristics of skeletal muscles under conditions of gravitational overloading are very much understudied. The aim of our work was to follow dynamics of MHC in rat m.soleus after exposure to 19 and to 33 days of +2G acceleration, and to compare content of contractile proteins in muscle fibers, and their contractile properties.