Metabolic interplay

fimmu-08-00248-g001
Renner K et al. Front Immunol. (2017)

I recently came across this figure that shows the key metabolic processes that dictates an immune cell behavior and function. Biochemists and pharmacologists sometimes focus on one or two key pathways in a disease model and forget that proteins don’t function in isolation. Protein networks are complex pathways with many overlays. A drug designed to inhibit or activate a specific protein can also affect other proteins in the connected pathways. This figure is focussed on an immune cell (natural killer cell) and its interaction with a tumor cell. The interplay between the different metabolic pathways applies to all kinds of cells in the body.

This figure is also quite interesting to me because I have been studying the arginase-1 (Arg1) pathway in microglial cells and this gives me a brief overview of where my study lies in the spectrum of key cellular metabolic pathways. Arg1 is an enzyme that metabolizes L-arginine to L-ornithine and urea in the urea cycle. With the help of ornithine decarboxylase (ODC), L-ornithine further makes polyamines that are important (? – it depends) for cell growth and survival (? – it depends). I think it is quite interesting to see how Arg1 and ODC would dictate the phenotypes of the microglial cells in the brain. Microglia are the brain’s resident immune cells – they chew up all the toxic stuff and get rid of them (this is known as phagocytosis). We have always studied these cells based on their two active states (M1 or M2). There has been evidence in the recent years to show that these cells in fact may exhibit multiple activated states (not just M1 and M2). Just like many immune cells in the body that exhibit a heterogenous phenotype, microglia in the brain may be no different. I’m curious if Arg1 and ODC may be involved in regulating a similar mechanism in microglial cells during neurodegeneration..

Source: Renner K., Singer K., et al. Metabolic Hallmarks of Tumor and Immune Cells in the Tumor Microenvironment. Front Immunol. 2017; 8: 248.

 

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It’s brain awareness week!

Hello all!  I wanted to take a few minutes to write something for the brain awareness week. This is important to me because my research focusses on understanding the role of the immune system in the brain. For a very long time, the brain was thought to be an “immune privileged” organ i.e., it was thought that the brain is protected from all the peripheral insults and that it is “divorced” from the rest of the body. In 2015, it was shown that there exists certain lymphatic vessels that connect the CNS to the rest of the body (1). The lymphatic system carries immune cells through a network of vessels and tissues; it connects the bloodstream and tissues in order to remove dead cells and other debris. The discovery of the new “glymphatic system” has opened new avenues to study the connection between the brain and the rest of the body. This is especially helpful in understanding the role of the peripheral immune system on the CNS during infections, injury, and other disease insults.

glymphatic system
Old lymphatic system (left) and newly discovered lymphatic system in the CNS (right). Source: University of Virginia Health System

My work focusses on a specific cell type in the brain known as microglia which are are the resident macrophages of the CNS (they eat up and clear out the bad stuff in the brain like dead cells and mis-folded proteins). Microglia are the only known immune cells of the brain. Compared to all that’s known about the cells of our body’s immune system (B cells, T cells, NK cells, neutrophils, basophils, Treg cells, MDSCs, TH1, TH2, and many many more with several subtypes of each cell), it is safe to say that cells of the CNS are poorly understood. My efforts are focussed towards understanding the role of microglial cells in neurodegenerative diseases such as Alzheimer’s Diseases (AD) , Parkinson’s Disease (PD), Multiple Sclerosis (MS), etcetera. These diseases are characterized by mis-folded proteins that aggregate in the different regions of the brain tissues causing the neurons to degenerate and eventually die. The microglial cells in these disorders play a major role in disease progression by regulating many pathways involved in cell-cell communication, cell survival, and cell death. This is a relatively new and an exciting area of study with many missing links and questions to be answered. I will try my best to keep this space alive with updates and stories! In the meantime, here’s a fun read on Leonardo da Vinci’s contributions to neuroscience: http://www.sciencedirect.com/science/article/pii/S0166223600021214

And here’s a 1504-1506 drawing of the human brain by da Vinci:

Leonardo da Vinci's contributions to neuroscience
In the upper figure, the three ventricles are labeled imprensiva (anterior ventricle, corresponding to the paired lateral ventricles), senso comune (third ventricle), and memoria (posterior or fourth ventricle). Below the ventricles, seven pairs of cranial nerves are shown. The lower figure shows a human head in an exploded view, with the skull raised over the brain and from the head. Source: 

Sources:

  1. Louveau A, et al. Structural and functional features of central nervous system lymphatic vessels. Nature. 2015;523(7560):337–341. doi: 10.1038/nature14432.