Machine-to-Machine (M2M) communications have emerged as a new communication paradigm to support Internet of Things (IoT) applications. With little or even no human intervention, the interconnection among a large amount of machines enables highly autonomous and intelligent applications. Undoubtedly, the most promising M2M application is ``real-time monitoring", the goal of which is to ensure continuous surveillance via region-based M2M communications networks. One major issue for real-time monitoring is the energy-validity tradeoff, i.e., the tradeoff between the energy efficiency for machines and the validity of sensing reports. To deal with the energy-validity tradeoff for real-time monitoring applications, in this thesis, we propose energy-efficient reporting mechanisms, including Energy-efficient Distributed Reporting (EDR) and Energy-efficient Centralized Reporting (ECR), to mitigate energy consumption for machines while keeping the sensing data valid. We propose analytical models and simulation experiments to investigate the performance for the proposed mechanisms in terms of the power saving and the report validity. Furthermore, we develop a prototyping real-time monitoring system, namely the- Air Pollution Sensing (APS) system, to monitor the air quality in the urban environment. The APS system has been deployed in the campus of National Taiwan University for small-scale testing.