Protocol for the study of hepatic bilirubin uptake in the isolated perfused rat liver

We present a protocol for the study of bilirubin uptake in the isolated and perfused rat liver. The liver is perfused with an albumin-free saline buffered solution supplemented with glucose, pyruvate and lactate, in the absence of oxygen, at a physiologically low flow rate. Fractions of the venous effluent are collected and analyzed for bilirubin, bilirubin glucuronide and biomarkers of liver integrity. The liver preparation is viable and intact for 1 h after isolation from the general circulation, with constant levels of both bilirubin and bilirubin glucuronide (< 2 nM) in the effluent. Up to 12 boli of 10 nmol bilirubin can be sequentially injected into the portal vein without and with molecules that target sinusoidal membrane transporters of organic anions. Selective inhibition of bilirubin or bilirubin glucuronide uptake is detected as transient peaks in the effluent (Cmax up 6 to 60 nM). This protocol allows collecting repeated observations in the same liver, thus reducing the animal number by a factor of 10.

Selective Inhibition of 2-Oxoglutarate and 2-Oxoadipate Dehydrogenases by the Phosphonate Analogs of Their 2-Oxo Acid Substrates

Phosphonate analogs of pyruvate and 2-oxoglutarate are established specific inhibitors of cognate 2-oxo acid dehydrogenases. The present work develops application of this class of compounds to specific in vivo inhibition of 2-oxoglutarate dehydrogenase (OGDH) and its isoenzyme, 2-oxoadipate dehydrogenase (OADH). The isoenzymes-enriched preparations from the rat tissues with different expression of OADH and OGDH are used to characterize their interaction with 2-oxoglutarate (OG), 2-oxoadipate (OA) and the phosphonate analogs. Despite a 100-fold difference in the isoenzymes ratio in the heart and liver, similar Michaelis saturations by OG are inherent in the enzyme preparations from these tissues (KmOG = 0.45 ± 0.06 and 0.27 ± 0.026 mM, respectively), indicating no significant contribution of OADH to the OGDH reaction, or similar affinities of the isoenzymes to OG. However, the preparations differ in the catalysis of OADH reaction. The heart preparation, where OADH/OGDH ratio is ≈ 0.01, possesses low-affinity sites to OA (KmOA = 0.55 ± 0.07 mM). The liver preparation, where OADH/OGDH ratio is ≈ 1.6, demonstrates a biphasic saturation with OA: the low-affinity sites (Km,2OA = 0.45 ± 0.12 mM) are similar to those of the heart preparation; the high-affinity sites (Km,1OA = 0.008 ± 0.001 mM), revealed in the liver preparation only, are attributed to OADH. Phosphonate analogs of C5-C7 dicarboxylic 2-oxo acids inhibit OGDH and OADH competitively to 2-oxo substrates in all sites. The high-affinity sites for OA are affected the least by the C5 analog (succinyl phosphonate) and the most by the C7 one (adipoyl phosphonate). The opposite reactivity is inherent in both the low-affinity OA-binding sites and OG-binding sites. The C6 analog (glutaryl phosphonate) does not exhibit a significant preference to either OADH or OGDH. Structural analysis of the phosphonates binding to OADH and OGDH reveals the substitution of a tyrosine residue in OGDH for a serine residue in OADH among structural determinants of the preferential binding of the bulkier ligands to OADH. The consistent kinetic and structural results expose adipoyl phosphonate as a valuable pharmacological tool for specific in vivo inhibition of the DHTKD1-encoded OADH, a new member of mammalian family of 2-oxo acid dehydrogenases, up-regulated in some cancers and associated with diabetes and obesity.

Examination of Conditions for Optimized Decellularized Liver Preparation

Aims: The main aim of our study was to examine the concentration of surfactant that can cause significant disruption of the resulting decellularized liver structure. Furthermore, it is our goal to determine the suitable solvent that can boost the potential of each surfactant. Methodology: The porcine liver discs of 8-mm diameter and 2-mm thickness were prepared. These were soaked in aqueous solution of either sodium dodecyl sulfate (SDS) or Triton X-100 (TX), and placed on a rotational shaking machine (100 rpm). Results: TX was unable to completely remove the cellular components under any of our experimental conditions. The salt concentration did not affect the decellularization in TX. The pH buffer, however, was found to affect the decellularization. Also, in the solvent study, the conditions under which SDS effectively exerted power were not the salt concentration and pH, but the condition that was close to water. We also confirmed that the shrinkage of tissue occurred when decellularization with 0.1% SDS in CMF-PBS. However, 0.1% SDS in distilled water didn't cause the deformation of tissue. This is considered to be due to the low salt concentration of solvent. Conclusion: This work establishes the concentration range of the surfactant that causes the collapse of the cellular structure during decellularization. In addition, the solvent suitable for each surfactant has also been established.