BACKGROUND & AIMS: Mathematical modeling of hepatitis C virus (HCV) kinetics indicated that cellular immune responses contribute to interferon (IFN)-induced clearance of HCV. We investigated a potential role of natural killer (NK) cells in this process. METHODS: Phenotype and function of blood and liver NK cells were studied during the first 12 weeks of treatment with pegylated IFN-alfa and ribavirin, the time period used to define the early virological response. RESULTS: Within hours of treatment initiation, NK cells of patients that had an early virological response increased expression of activating receptors NKG2D, NKp30, and CD16 and decreased expression of NKG2C and 2B4, along with inhibitory receptors SIGLEC7 and NKG2A, resulting in NK cell activation. NK cell cytotoxicity, measured by degranulation and tumor necrosis factor-related apoptosis-inducing ligand production, peaked after 24 hours (P<.01), concomitant with an increase in alanine aminotransferase levels (P<.05), whereas IFN-γ production decreased within 6 hours and did not recover for more than 4 weeks (P<.05). NK cells from liver biopsies taken 6 hours after treatment initiation had increased numbers of cytotoxic CD16+NK cells (P<.05) and a trend toward increased production of tumor necrosis factor-related apoptosis-inducing ligand. Degranulation of peripheral blood NK cells correlated with treatment-induced, first-phase decreases in viral load (P<.05) and remained higher in early virological responders than in nonresponders for weeks. CONCLUSIONS: IFN activates NK cells early after treatment is initiated. Their cytotoxic function, in particular, is strongly induced, which correlates to virologic response. Therefore, NK cell activation indicates responsiveness to IFN-α-based treatment and suggests the involvement of the innate immune cells in viral clearance.
BACKGROUND & AIMS:Mathematical modeling of hepatitis C virus (HCV) kinetics indicated that cellular immune responses contribute to interferon (IFN)-induced clearance of HCV. We investigated a potential role of natural killer (NK) cells in this process. METHODS: Phenotype and function of blood and liver NK cells were studied during the first 12 weeks of treatment with pegylated IFN-alfa and ribavirin, the time period used to define the early virological response. RESULTS: Within hours of treatment initiation, NK cells of patients that had an early virological response increased expression of activating receptors NKG2D, NKp30, and CD16 and decreased expression of NKG2C and 2B4, along with inhibitory receptors SIGLEC7 and NKG2A, resulting in NK cell activation. NK cell cytotoxicity, measured by degranulation and tumor necrosis factor-related apoptosis-inducing ligand production, peaked after 24 hours (P<.01), concomitant with an increase in alanine aminotransferase levels (P<.05), whereas IFN-γ production decreased within 6 hours and did not recover for more than 4 weeks (P<.05). NK cells from liver biopsies taken 6 hours after treatment initiation had increased numbers of cytotoxic CD16+NK cells (P<.05) and a trend toward increased production of tumor necrosis factor-related apoptosis-inducing ligand. Degranulation of peripheral blood NK cells correlated with treatment-induced, first-phase decreases in viral load (P<.05) and remained higher in early virological responders than in nonresponders for weeks. CONCLUSIONS:IFN activates NK cells early after treatment is initiated. Their cytotoxic function, in particular, is strongly induced, which correlates to virologic response. Therefore, NK cell activation indicates responsiveness to IFN-α-based treatment and suggests the involvement of the innate immune cells in viral clearance.
Authors: Megan M Dring; Maria H Morrison; Brian P McSharry; Kieran J Guinan; Richard Hagan; Cliona O'Farrelly; Clair M Gardiner Journal: Proc Natl Acad Sci U S A Date: 2011-03-14 Impact factor: 11.205
Authors: S Norris; C Collins; D G Doherty; F Smith; G McEntee; O Traynor; N Nolan; J Hegarty; C O'Farrelly Journal: J Hepatol Date: 1998-01 Impact factor: 25.083
Authors: M A Cooper; T A Fehniger; S C Turner; K S Chen; B A Ghaheri; T Ghayur; W E Carson; M A Caligiuri Journal: Blood Date: 2001-05-15 Impact factor: 22.113
Authors: Salim I Khakoo; Chloe L Thio; Maureen P Martin; Collin R Brooks; Xiaojiang Gao; Jacquie Astemborski; Jie Cheng; James J Goedert; David Vlahov; Margaret Hilgartner; Steven Cox; Ann-Margeret Little; Graeme J Alexander; Matthew E Cramp; Stephen J O'Brien; William M C Rosenberg; David L Thomas; Mary Carrington Journal: Science Date: 2004-08-06 Impact factor: 47.728
Authors: Claire Dunn; Maurizia Brunetto; Gary Reynolds; Theodoros Christophides; Patrick T Kennedy; Pietro Lampertico; Abhishek Das; A Ross Lopes; Persephone Borrow; Kevin Williams; Elizabeth Humphreys; Simon Afford; David H Adams; Antonio Bertoletti; Mala K Maini Journal: J Exp Med Date: 2007-03-12 Impact factor: 14.307
Authors: Anna Mania; Mariusz Kaczmarek; Paweł Kemnitz; Katarzyna Mazur-Melewska; Magdalena Figlerowicz; Jan Sikora; Wojciech Służewski; Jan Żeromski Journal: Med Microbiol Immunol Date: 2017-11-08 Impact factor: 3.402