Moderate anemia is associated with increased mortality and morbidity, including acute kidney injury (AKI), in surgical patients. A red blood cell (RBC)-specific antibody model was utilized to determine if moderate subacute anemia could result in tissue hypoxia as a potential mechanism of injury. Cardiovascular and hypoxic cellular responses were measured in transgenic mice capable of expressing hypoxia-inducible factor-1α (HIF-1α)-luciferase activity in vivo. Antibody-mediated anemia was associated with mild intravascular hemolysis (6 hours) and splenic RBC sequestration (day 4), resulting in a nadir hemoglobin concentration of 89{plus minus}13 g/L at day 4. At this time point, renal tissue oxygen tension (PtO2) was decreased in anemic mice relative to controls (13.1{plus minus}4.3 vs. 20.8{plus minus}3.7 mmHg; p<0.001). Renal tissue hypoxia was associated with an increase in HIF-luciferase expression in vivo (p=0.04), and a 20-fold relative increase in renal erythropoietin mRNA transcription (p<0.001), but no increase in renal blood flow (p=0.67). By contrast, brain PtO2 was maintained in anemic mice relative to controls (22.7{plus minus}5.2 vs. 23.4{plus minus}9.8 mmHg, p=0.59), in part due to an increase in internal carotid artery blood flow (80%; p<0.001) and preserved cerebrovascular reactivity. Despite these adaptive changes, an increase in brain HIF-dependent mRNA levels was observed (erythropoietin: p<0.001, heme oxygenase-1: p=0.01), providing evidence for subtle cerebral tissue hypoxia in anemic mice. These data demonstrate that moderate subacute anemia causes significant renal tissue hypoxia, while adaptive cerebrovascular responses limit the degree of cerebral tissue hypoxia. Further studies are required to assess whether hypoxia is a mechanism for acute kidney injury associated with anemia.