Engineering of Thiamin Pyrophosphate Fluorescent Biosensors Based on Ribozyme Switches in Mammalian Cells / 分析化学

Thiamin pyrophosphate (TPP) is a thiamine (vitamin B1) derivative and an essential cofactor in oxidative metabolism of the sugars,fatty acids and amino acids in living cells.By now,numerous TPP-dependent artificial riboswitch systems have been developed to regulate target gene expression but limited in bacteria,fungi or plant cells.Herein,the activating (switch-on) and inhibiting (switch-off) TPP-depended hammerhead ribozyme switches,which are from previous reported structures of prokaryotes screening,were investigated in mammalian cells.These ribozyme switches were inserted into the 3'UTR of the enhanced green fluorescence protein (EGFP) gene to construct the efficient ribozyme-based artificial switches through overlap extension PCR cloning.The HEK293 cells were transfected with the engineered ribozyme switches at increasing concentration of TPP.The EGFP gene-regulatory ability was analyzed with fluorescent microscope and flow cytometry.These TPP-inducible gene regulation devices showed the obvious ligand dose-dependency and excellent specificity.Two switch-on and one switch-off constructs demonstrated 3.1-fold or 1.9-fold increment and 2.3-fold reduction of EGFP level respectively with 150 μ mol/L TPP.The ligand-responsive ribozyme switches,by tuning the change of TPP concentration into the visual reporter genetic expression in cells,enable an efficient development of label-free,noninvasive and high-specific biosensors in living mammalian cells.

Parámetros productivos y sanguíneos en pollos de carne suplementados con cocarboxilasa / Productive and blood performance of broiler supplemented with cocarboxylase

El objetivo de este estudio fue evaluar el efecto de la cocarboxilasa sobre los parámetros productivos y niveles sanguíneos de glucosa y lipídos en pollos de carne. Fueron utilizados 11004 pollos machos de 1 día de edad los cuales fueron distribuidos al azar en 3 tratamientos con 4 repeticiones (917 pollos por cada repetición) y criados de forma convencional por 42 días. Los grupos formados fueron T1 (Dieta convencional), T2 (Dieta modificada, reducción del porcentaje de aceite de soya y la adición de cocarboxilasa) y T3 (Dieta modificada, reducción del porcentaje de aceite de soya y sin cocarboxilasa). El grupo tratado con cocarboxilasa (T2) obtuvo mayor peso final y ganancia de peso comparado con los otros dos tratamientos. La inclusión de cocarboxilasa tuvo influencia positiva en el peso por lo que podria ser utilizada como reemplazo parcial del aceite de soya utilizado en la dieta de pollos de carne.

The aim of this study was to evaluate the effect of cocarboxylase on productive performance, blood glucose and lipid profile in broilers. A total of 11004 one-day-old male broiler chickens were randomly allocated into 1 of 3 treatments with 4 replicates per treatment (917 chickens per replicate) and conventionally reared until 42 days old. The treatments were T1 (Conventional diet), T2 (Modified diet, reducing a percentage soybean oil and the addition of cocarboxylase) and T3 (Modified diet, reducing a percentage soybean oil without cocarboxylase). Broilers supplemented with cocarboxylase (T2) resulted in higher final weight and weight gain compared with the others treatments. The inclusion of cocarboxylase had positive influence on weight, which suggests its usefulness as a partial replacement of the oil used in chicken diets.

Can thiamine pyrophosphate prevent desflurane induced hepatotoxicity in rats?

ABSTRACT PURPOSE : To investigate the effects of thiamine pyrophosphate (TPP) against desflurane induced hepatotoxicity. METHODS : Thirty experimental animals were divided into groups as healthy (HG), desflurane control (DCG) , TPP and desflurane group (TDG). 20 mg/kg TPP was injected to intraperitoneally TDG. After one hour of TPP administration, desflurane was applied for two hours. After 24 hours, liver tissues of the animals killed with decapitation were removed. The oxidant/antioxidant levels and ALT, AST and LDH activities were measured. The histopathological examinations were performed in the liver tissues for all rats. RESULTS : Notwithstanding the levels of oxidants and liver enzymes were significantly increased (p<0.0001), antioxidant levels were significantly decreased in DCG (p<0.0001). On contrary to the antioxidant parameters were increased (p<0.05) the oxidant parameters and liver enzymes were decreased in TDG (p<0.0001). Whereas multiple prominent, congestion, hemorrhage and dilatation were observed in sinusoids and lymphocyte-rich inflammation results in the centrilobular and portal areas of liver tissue in DCG, these findings were observed less frequently in TDG. CONCLUSİON : Thiamine pyrophosphate prevented liver oxidative damage induced with desflurane and may be useful in prophylaxis of desflurane induced hepatotoxicity.

El pirofosfato de tiamina reduce el daño celular inducido por hipoxia en el cerebro de ratas neonatas / Thiamine pyrophosphate reduces hypoxia-induced cellular damage in neonatal rat brain

La encefalopatía por hipoxia es causa de discapacidad y requiere de nuevas estrategias terapéuticas. El pirofosfato de tiamina (PPT) es un cofactor esencial de enzimas fundamentales en el metabolismo de la glucosa, cuya disminución puede conducir a la falla en la síntesis de ATP y a la muerte celular. El objetivo de este estudio fue determinar si la administración de PPT, puede reducir el daño celular en un modelo de hipoxia neonatal en ratas. Animales de 11 días de edad fueron tratados con PPT (130 mg/kg) en dosis única o solución salina, una hora antes del protocolo de hipoxia o al término de ésta. Los cerebros fueron colectados para la evaluación del daño celular. Además, se tomaron muestras sanguíneas para evaluar los indicadores gasométricos de presión de dióxido de carbono (PaCO2) y de oxígeno (PaO2) en sangre arterial y pH. Los resultados muestran que la administración de PPT previa a la inducción de hipoxia, reduce el daño celular y restablece los indicadores gasométricos. Estos datos indican que el uso de PPT reduce el daño inducido por la hipoxia en animales neonatos.

Hypoxic encephalopathy is a leading cause of disability and requires new therapeutic strategies. Thiamine pyrophosphate (TPP) is an essential cofactor of fundamental enzymes involved in glucose metabolism. TPP reduction may lead to ATP synthesis failure and cell death. The objective of this study was to determine if TPP administration can reduce cellular damage in a model of neonatal hypoxia in rats. Eleven day old animals were treated with TPP (130 mg/kg) as a single dose or with saline solution one hour before the hypoxia protocol or after ending the protocol. The brains were collected to evaluate cellular damage. Blood samples were also collected to evaluate arterial oxygen tension (PaO2), carbon dioxide tension (PaCO2) and acidity (pH). The results showed that TPP administration previous to hypoxia induction reduces cellular damage and reestablishes arterial blood gases. These data indicate that TPP use reduces the damage induced by hypoxia in neonatal animals.

An Interesting Case of Disappearing Murmur

Cardiovascular manifestations in a patient with congestive heart failure, which disappeared in short course of time, ignited the idea to think of unusuality from common rheumatic heart disease (RHD). Cardiac events that reversed within 2 days of admission in a chronic alcoholic, whose diagnosis puzzled us, are presented here. A retrospective conclusion of wet beri-beri is made, as all the haemodynamic sequelae vanished with thiamine replacement.

A Korean Female Patient with Thiamine-responsive Pyruvate Dehydrogenase Complex Deficiency Due to a Novel Point Mutation (Y161C)in the PDHA1 Gene

Pyruvate dehydrogenase complex (PDHC) deficiency is mostly due to mutations in the X-linked E1alpha subunit gene (PDHA1). Some of the patients with PDHC deficiency showed clinical improvements with thiamine treatment. We report the results of biochemical and molecular analysis in a female patient with lactic acidemia. The PDHC activity was assayed at different concentrations of thiamine pyrophosphate (TPP). The PDHC activity showed null activity at low TPP concentration (1 x 10(-3) mM), but significantly increased at a high TPP concentration (1 mM). Sequencing analysis of PDHA1 gene of the patient revealed a substitution of cysteine for tyrosine at position 161 (Y161C). Thiamine treatment resulted in reduction of the patient's serum lactate concentration and dramatic clinical improvement. Biochemical, molecular, and clinical data suggest that this patient has a thiamine-responsive PDHC deficiency due to a novel mutation, Y161C. Therefore, to detect the thiamine responsiveness it is necessary to measure activities of PDHC not only at high but also at low concentration of TPP.

Regulation of mammalian pyruvate dehydrogenase complex by phosphorylation: complexity of multiple phosphorylation sites and kinases

This review summarizes the recent developments on the regulation of human pyruvate dehydrogenase complex (PDC) by site-specific phosphorylation by four kinases. Mutagenic analysis of the three phosphorylation sites of human pyruvate dehydrogenase (E1) showed the site-independent mechanism of phosphorylation as well as site-independent dephosphorylation of the three phosphorylation sites and the importance of each phosphorylation site for the inactivation of E1. Both the negative charge and size of the group introduced at site 1 were involved in human E1 inactivation. Mechanism of inactivation of E1 was suggested to be site-specific. Phosphorylation of site 1 affected E1 interaction with the lipoyl domain of dihydrolipoamide acetyltransferase, whereas phosphorylation site 3 appeared to be closer to the thiamine pyrophosphate (TPP)-binding region affecting coenzyme interaction with human E1. Four isoenzymes of pyruvate dehydrogenase kinase (PDK) showed different specificity for the three phosphorylation sites of E1. All four PDKs phosphorylated sites 1 and 2 in PDC with different rates, and only PDK1 phosphorylated site 3. PDK2 was maximally stimulated by the reduction/acetylation of the lipoyl groups of E2. Presence of the multiple phosphorylation sites and isoenzymes of PDK is important for the tissue-specific regulation of PDC under different physiological conditions.