Review: Mammalian Target of Rapamycin (mTOR) Pathway Is Critical in Developing Most Renal Cell Tumors.

OBJECTIVE: Various renal cell carcinomas (RCC) are derived from different segments of the renal tubular origin, which determines their morphological and immunohistochemical phenotype and their molecular signaling pathway as a therapeutic target. Most of these tumors utilize the mammalian target of rapamycin (mTOR) pathway to activate pathways involving metabolic and nutritional supplies. METHODS: Overexpressed mTOR signals are reported in more than 90% of the most common types of RCC. Many new renal tumor entities have been reported in recent years. RESULTS: Among them, somatic mutations in tuberous sclerosis complex (TSC) result in loss of its normal inhibitory control over mTOR, thus promoting mTOR-associated proliferative activities in several new renal neoplastic entities including RCC with fibromyomatous stroma (RCCFMS), eosinophilic vacuolated tumor, eosinophilic solid & cystic RCC, and low-grade oncocytic tumor. CONCLUSIONS: This short review provides a comprehensive correlation of tumor morphology and immunohistochemical phenotype with renal tubular differentiation and their shared mTOR. These essential pieces of knowledge are vital in the diagnosis and clinical management of renal cell neoplasms.

Functionalized resorcinarenes effectively disrupt the aggregation of αA66-80 crystallin peptide related to cataracts.

Cataracts, an eye lens clouding disease, are debilitating and while operable, remain without a cure. αA66-80 crystallin peptide abundant in cataracted eye lenses contributes to aggregation of αA-crystallin protein leading to cataracts. Inspired by the versatility of macrocycles and programmable guest selectivity through discrete functionalizations, we report on three water-soluble ionic resorcinarene receptors (A, B, and C) that disrupt the aggregation of αA66-80 crystallin peptide. A and B each possess four anionic sulfonate groups, while C includes four cationic ammonium groups with four flexible extended benzyl groups. Through multiple non-covalent attractions, these receptors successfully disrupt and reverse the aggregation of αA66-80 crystallin peptide, which was studied through spectroscopic, spectrometric, calorimetric, and imaging techniques. The αA66-80·receptor complexes were also explored using molecular dynamics simulation, and binding energies were calculated. Even though each of the three receptors can bind with the peptide, receptor C was characterized by the highest binding energy and affinity for three different domains of the peptide. In effect, the most efficient inhibitor was a cationic receptor C via extended aromatic interactions. These results highlight the potential of versatile and tunable functionalized resorcinarenes as potential therapeutics to reverse the aggregation of α-crystallin dominant in eye cataracts.