Comparative Proteomic Analysis of Erythropoiesis Tissue Head Kidney Among three Antarctic Fish Species

Antarctic icefish is the only known vertebrate species that lacks oxygen-carrying hemoglobin and functional erythrocytes. To reveal the unique hematopoietic process of icefish, we used an integrated approach including tandem mass tag (TMT) labeling and liquid chromatography-tandem mass spectrometry (LC-MS/MS) to quantify the dynamic changes in the head kidney whole proteome of a white-blooded icefish, Chionodraco hamatus, compared to those in two other red-blooded Antarctic fish, Trematomus bernacchii and Notothenia coriiceps. Of the 4,672 identified proteins, in the Antarctic ice fish head kidney, 123 proteins were significantly up-regulated and 95 proteins were down-regulated. The functional grouping of differentially expressed proteins based on KEGG pathway analysis shows that white blood fish and red blood fish have significant differences in erythropoiesis, heme biogenesis, leucocyte and platelet cell development. The proteins involved in the hematopoietic process in icefish showed a clear trend of downregulation of erythroid lineage marker proteins and upregulation of lymphoid and megakaryocytic lineage marker proteins, including CD9, ITGB2, and MTOR, which suggests a shift in hematopoiesis in the icefish head kidney due to the loss of erythrocytes. The results of the present study not only provide basic datasets for the head kidney proteins of Antarctic fishes, but also provide important references for studies on immunity and hematopoiesis in various species.

Vascular Expression of Hemoglobin Alpha in Antarctic Icefish Supports Iron Limitation as Novel Evolutionary Driver

Frigid temperatures of the Southern Ocean are known to be an evolutionary driver in Antarctic fish. For example, many fish have reduced red blood cell (RBC) concentration to minimize vascular resistance. Via the oxygen-carrying protein hemoglobin, RBCs contain the vast majority of the body’s iron, which is known to be a limiting nutrient in marine ecosystems. Since lower RBC levels also lead to reduced iron requirements, we hypothesized that low iron availability was an additional evolutionary driver of Antarctic fish speciation. Antarctic Icefish of the family Channichthyidae are known to have extreme alteration of iron metabolism due to loss of two iron-binding proteins, hemoglobin and myoglobin, and no RBCs. Loss of hemoglobin is considered a maladaptive trait allowed by relaxation of predator selection, since extreme adaptations are required to compensate for the loss of oxygen-carrying capacity. However, iron dependency minimization may have driven hemoglobin loss instead of a random evolutionary event. Given the variety of functions that hemoglobin serves in the endothelium, we suspected the protein corresponding to the 3’ truncated Hbα fragment (Hbα-3’f) that was not genetically excluded by icefish, may still be expressed as a protein. Using whole mount confocal microscopy, we show that Hbα-3’f is expressed in the vascular endothelium of icefish retina, suggesting this Hbα fragment may still serve an important role in the endothelium. These observations support a novel hypothesis that iron minimization could have influenced icefish speciation with the loss of the iron-binding portion of Hbα in Hbα-3’f, as well as hemoglobin β and myoglobin.