Clinicopathological significance of tumor-infiltrating lymphocytes and programmed death-1 expression in cutaneous melanoma: a comparative study on clinical subtypes.

Interactions between immune cells and tumor cells play an important role in tumor progression. We evaluated patterns of tumor-infiltrating lymphocytes (TILs) and programmed death-1 (PD-1) expression in acral and nonacral cutaneous melanoma, and determined their effects on clinicopathological characteristics and biologic responses. We identified 122 cases of cutaneous melanoma, of which 39 were cases of non-nail unit acral melanoma (NNUAM), 35 were cases of nail unit melanoma (NUM), and 48 were cases of nonacral melanoma. Clinicopathological features and survival outcomes were analyzed according to the scores for TILs and PD-1 expression in intratumoral and peritumoral compartments. The effects of the presence of TILs and PD-1 expression on various clinicopathological factors differed according to the clinical subtypes of cutaneous melanoma. The frequency of intratumoral TILs and PD-1 expression were lower in NUM than in the other two subtypes. The density of peritumoral PD-1 was significantly higher in NNUAM. In NUM and nonacral melanoma, a low density of intratumoral TILs and PD-1 was associated with a deeper Breslow thickness and the presence of a vertical growth phase. In NNUAM, a high density of peritumoral TILs and PD-1 was associated with a shallower Breslow thickness and less frequent extracutaneous dissemination. In NNUAM, a high density of peritumoral PD-1 was associated with a better prognosis. This study suggests that the effects of PD-1+ TILs on biological activity differ according to the clinical subtypes of cutaneous melanoma.

Identification of a novel organic anion transporter mediating carnitine transport in mouse liver and kidney.

This study identifies a novel organic anion transporter Oat9 expressed in mouse liver and kidney. Two variants were detected by screening a mouse liver cDNA library; these varients consist of 1815 (designated Oat9S) and 2165 (Oat9L) base pairs which encode 443 and 551 amino acid proteins, respectively. Oat9S has a predicted structure containing eight transmembrane domains (TMD); whereas, Oat9L possesses twelve TMD. Oat9 mRNA expression was detected in kidney and liver. This transporter was located at the apical side of the late portion of proximal tubules and at the sinusoidal side of hepatocytes. When expressed in Xenopus oocytes, Oat9S mediated the transport of L-carnitine (Km = 2.9 microM), a representative zwitterion, as well as cimetidine (Km = 16.1 microM) and salicylic acid (Km = 175.5 microM), while Oat9L did not show any transport activity. Oat9S-mediated L-carnitine uptake was inhibited by D-carnitine, acetylcarnitine, octanoylcarnitine, betaine, and other organic compounds, suggesting that quaternary ammonium cation bulkiness and relative hydrophobicity are important factors for Oat9S-substrate interactions. Among OATs, Oat9S appears to be the first member to mediate the transport of carnitine and possesses eight TMD. Overall, these new results provide added insight into the structure-activity relationship comprising the organic ion-permeation pathway.