Anaerobic treatment processes in wastewater treatment industries discharge methane in gaseous as well as in aqueous form. Methane is considered a powerful greenhouse gas that has a global warming potential 25 times greater than carbon dioxide over a 100-year period. While methane in the gaseous phase can be easily collected and purified, dissolved methane is difficult to recover. Therefore, a post-treatment process is needed in anaerobic systems to oxidize dissolved methane, thereby reducing greenhouse gas emissions and making anaerobic wastewater treatment a more eco-friendly technology. Nitrate dependent anaerobic methane oxidation (Nitrate-DAMO) use nitrate as electron acceptor and methane as electron donor to produce nitrite and carbon dioxide. Whereas, nitrite dependent methane anaerobic oxidation (Nitrite-DAMO) use nitrite as electron acceptor and convert nitrite and methane to nitrogen gas and carbon dioxide. Anammox process consume ammonium and nitrite to produce nitrogen gas and nitrate. Nitrate-DAMO can interact with Nitrite-DAMO and Anammox. These three processes might play vital role in connecting nitrogen cycle with carbon cycle. In this study, we try to combine these three processes together to simultaneously remove nitrogen as well as carbon pollutant from the wastewater stream. These three processes occurred in the packed-bed reactor simultaneously with the influent concentration of ammonium, nitrite and nitrate of 1 mM, 0.5 mM and 5 mM, respectively. Hydraulic retention time (HRT) of the reactor is 3 days. The reactor is operated over 5 months. The nitrogen removal rates are over 90 %. The oxidation reduction potential (ORP) in the reactor maintains at 130 mV after the 210th day. In the activity test, the methane consumption rate of the nitrate-DAMO and nitrite-DAMO are 1.28x10-3 mmole mg-1-VSS d-1 and 1.12x10-3 mmole mg-1-VSS d-1, respectively. Those are 10 times higher than initial sludge. It means that it is successful to enrich denitrifying anaerobic methane oxidation (DAMO) in the packed-bed reactor.