Adaptive Kupffer cell alterations after femur fracture trauma in rats

Because Kupffer cells constitute the largest fixed macrophage population and reside at a strategic position in hepatic sinusoids, interacting with hepatocytes, circulating cells, and mediators from the gut, they may be important in the inflammatory response after injury. This study examined the effect of remote tissue injury on Kupffer cell function. Femurs of Sprague-Dawley rats were fractured under anesthesia. Subsequently, their livers were perfused for measurement of oxygen consumption and the isolation and culture of Kupffer cells. At 2 and 48 h after femur fracture, hepatic oxygen consumption increased 17 and 19%, respectively. Gadolinium chloride pretreatment to ablate Kupffer cells blocked this increase of hepatic oxygen consumption after femur fracture but had no effect in sham-operated animals. In Kupffer cells isolated and cultured 2 h after femur fracture, superoxide formation stimulated by phorbol ester increased eightfold, phagocytosis increased fourfold, and lipopolysaccharide (LPS)-stimulated prostaglandin E2 increased sixfold in comparison to sham-operated controls. In contrast, LPS-stimulated tumor necrosis factor-alpha and nitric oxide production decreased 50 and 60%, respectively. These data show that peripheral trauma rapidly induces changes in hepatic macrophages characterized by adaptation to a more antimicrobial and less proinflammatory phenotype.

Rapid stimulation of hepatic oxygen consumption by 3,5-di-iodo-l-thyronine

Tri-iodothyronine (T3) and thyroxine (T4) as well as 3,5-di-iodothyronine (T2) stimulated O2 consumption by isolated perfused livers from hypothyroid rats at a concentration as low as 1 pM by about 30% within 90 min. Application of T2 resulted in a faster stimulation than with application of T3 or T4. Inhibition of iodothyronine monodeiodinase by propylthiouracil, thereby blocking the degradation of T4 to T3 and of T3 to T2, demonstrated that only T2 is the active hormone for the rapid stimulation of hepatic O2 consumption: T3 and T4 lost all of their stimulative activity, whereas T2 was as potent as in the absence of propylthiouracil. Perfusion experiments with thyroid-hormone analogues confirmed the specificity of the T2 effect. The nucleus is unlikely to contribute to the rapid T2 effect, as can be deduced from perfusion experiments with cycloheximide and lack of induction of malic enzyme by T2. In conclusion, a new scheme of regulation of mitochondrial activity is proposed: T2 acts rapidly and directly via a mitochondrial pathway, whereas T3 exerts its long-term action indirectly by induction of specific enzymes.