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An animal's immune function is vital for survival and potentially metabolically expensive, but some pathogens could manipulate their hosts’ immune and metabolic responses. One example is Mycoplasma gallisepticum (MG), which infects both the respiratory system and conjunctiva of the eye in house finches (Haemorhous mexicanus). MG has been shown to exhibit immune- and metabolic-suppressive properties, but the physiological mechanisms are still unknown. Recent studies demonstrated that mitochondria could serve as powerhouses for both ATP production and immunity, notably inflammatory processes, through regulating complex II and its metabolites. Consequently, in this study, we investigate the short-term (3d post-inoculation) and long-term (34d post-inoculation) effects of MG infection on the hepatic mitochondrial respiration of house finches from two populations infected with two different MG isolates. After short-term infection, MG-infected birds had significantly lower state 2 and state 4 respiration, but only when using complex II substrates. After long-term infection, MG-infected birds exhibited lower state 3 respiration with both complex I and II substrates, resulting in lower respiratory control ratio compared to uninfected controls, which aligned with the hypothesized metabolic-suppressive properties of MG. Interestingly, there were limited differences in mitochondrial respiration regardless of house finch population of origin, MG isolate, and whether birds recovered from infection or not. We propose that MG may target mitochondrial complex II for its immune-suppressive properties during the early stages of infection and inhibit mitochondrial respiration for its metabolic-suppressive properties at later stage of infection, both of which should delay recovery of the host and extend infectious periods.