p53 Direct Mechanisms In Immunity

Never in the field of molecular oncology have so many sites of posttranslational modification in one protein (p53) been modified by so many different enzymes, but direct response mechanisms that increase immune receptors are rarely discovered and have important implications.  

In the tumor microenvironment (TME), cancer associated fibroblasts (CAFs) display an activated phenotype and can physically remodel the extracellular matrix (ECM). Silencing p53 in the CAFs strongly compromised this activity, implicating p53 as a key contributor to a distinctive CAF feature. Here, the non-autonomous, tumor-suppressive activity of non-mutant p53 cDNA is rewired to become a significant contributor to the CAFs’ tumor-supportive activities. This surprising role for p53 in CAFs suggests that, during tumor progression p53 functionality is altered, not only in the cancer cells, but also in their adjacent stroma.

Although p53 is not mutated in the human placenta, it has become functionally incompetent. Why and how p53 is functionally incompetent in cytotrophoblast cells might well be the key to understanding trophoblast invasion. Vascular remodeling for placentation is controlled by small populations of conventional Natural Killer cells, distinct from much larger populations of uterine NK cells, that acidify the ECM with a2V-ATPase, that activates MMP9, degrades the ECM and releases stored pro-angiogenesis growth factors. Similarly hypoxic TME's that in NK cells sustain excessive mitochondrial fission resulting in fragmentation could cause a2V-ATP activated MMP9 to similarly degrade ECM and promote angiogenesis in the early TME.  

Another MMP protein, MMP2 is a ligand for the Toll-like receptor 2 (Tlr2). Expression of Tlr2 and Tlr4 in the TME is important for the promotion of tumor growth, and when both of these receptors are absent, growth is compromised. Furthermore, the expression of Tlr2 and Tlr4 in both hematopoietic and stromal compartments appears to support MMP2-driven tumor growth.

The integration of the TLR gene family into the p53 regulatory network is unique to primates. p53 promoter response elements that are targeted by this DNA damage and stress-responsive regulator suggest a general p53 role in the control of human TLR gene expression. TLR genes show responses to DNA damage, and most are p53-mediated. TLR's mediate innate immunity to a wide variety of threats through recognition of conserved pathogen-associated molecular motifs. Expression of all TLR genes, in blood lymphocytes and alveolar macrophages from healthy volunteers can be induced by DNA metabolic stressors with considerable inter-individual variability. Most TLR genes respond to p53 via canonical as well as noncanonical promoter binding sites.

A polymorphism in a TLR8 response element provided the first human example of a p53 target sequence specifically responsible for endogenous gene induction. These findings—demonstrating that the human innate immune system, including downstream induction of cytokines, can be modulated by DNA metabolic stress—have many implications for health and disease, as well as for understanding the evolution of DNA damage and p53 responsive networks. That p53 can directly increase an inflammatory response differs from the generally held view relating to the antagonistic affect of p53 on inflammation directed by NF-κB. However, the direct mechanism here is different in that it involves another p53-mediated increase in a receptor that translates ligand interactions into cytokine responses.

p53 Convergence and Immunity

Renewed interest in Bradykinin and its inactivation, by Angiotensin Converting Enzyme (ACE), during Covid infection reconfirmed RAS and KKS (Kallikrein-Kinin, Bradykinin) as the major systems of vasodilation and constriction contributing to blood pressure and disease. ACE2, a molecule of focus in Covid, reduces the Bradykinin product des-Arg9 bradykinin to inactive metabolites.

In pre-eclampsia reduced Kallikrein (KLK) generation and Bradykinin's activation, via its BK1 and BK2 receptor, modulates stress response through NF-κB and p53 pathways. These are the major cellular stress response pathways that promote or oppose apoptosis and influence cell fate. Two functionally divergent p53-responsive elements were discovered in the rat BK2 receptor promoter, which interact with ACE, play a significant role regulating vascular tone and blood pressure and in the cross-talk between RAS and KKS. 

In uterine immune cells RAS proteins AT1, AT2, and ANP are expressed and ANP co-localizes to uterine Natural Killer (uNK) cells between pregnancy day 10 and 12, immediately before spiral arterial modification. In mice this suggested that uNK contributes to the physiological changes in blood pressure between days 5 and 12.

During the first trimester the uNK cells dramatically increase, from around 15% to 70% of immune cells in the Decidua of the Uterus. Expressed RAS-KKS proteins during this time may be solely responsible for amplified stimulation of the plasma contact system at least via p53-mediated transcription and activation of the BK2 promoter.

In myocytes stretch-mediated release of angiotensin II (AngII) induced apoptosis by activating p53 that enhanced local RAS and decreased the Bcl-2-to-Bax protein ratio in the cell. In endothelial cells mechanical stretch interconnected innate and adaptive immune response in hypertension. This suggests that mechanical forces, such as those experienced in hypertension, can influence the immune system and contribute to inflammation, vascular damage associated with high blood pressure and vascular remodeling.

MYADAM and PRPF31 were the only genes from a meta-analysis that linked diastolic, systolic blood pressure and hypertension. These are located on Chromosome 19 between 50-55,000,000 bps, which includes all Killer immunoglobulin like receptors (KIR's), Kallikrein related peptidases (KLK's) and c19MC MiRNA's, in a region characterized by a 2X background deletion rate. During different trimesters it was found that NK cells, in pre-eclampsia, directly incorporate c19MC MiRNA's that are important to placental development and their deregulation could lead to the development of pre-eclampsia. 

It adds up that the massively disproportionate uNK activity in pregnancy and its impact on the mechanics of blood pressure could amplify sensitivities for p53 mediated stress response. It’s known that uNK cells contribute to the remodeling of spiral arteries and regulation of blood pressure, which are critical for fetal development. Similarly, on a cellular scale, abnormal cell growth and expansion of NK cells, may also amplify conditions that direct NK education and licensing to support growth, as in solid tumors and micro-vascular remodeling, or trigger inflammation, through cytokine expression and/or granulocyte killing of expanded missing-self cells. 

Indispensable Mitochondria - Cancers back door?

Immediately prior to fertilization spermatozoa are devoid of Mitochondrial DNA (mtDNA), potentially explaining an aspect about selection that may serve the legacy for maternal immune tolerance. Post fertilization, on day 11-13, outermost trophoblasts of the blastocyst dock with the decidual lining as it embeds in the uterine wall. Then, maternal vascular remodeling and placental formation begin toward successful implantation. 

Higher quality trophoblasts are associated with lower mtDNA content. Moreover, euploid blastocysts with higher mtDNA content had a lower chance to implant and mtDNA replication is strictly downregulated between fertilization and the implantation. What is it about absent or reduced mtDNA that may also relate to the mechanics of immune tolerance and vascular remodeling, which are also features of solid tumors.

The initial absence or downregulation of MtDNA, may relate an immune tolerance by uterine Natural Killer (NK) cells. As mtDNA upregulates, after day 12, it may initiate NK auto-reactivity required for maternal microvascular remodeling. This auto-immune paradox is a prerequisite for vascular remodeling, which is also seen in localized hypertension, and the likely basis of successful blastocyst implantation. Acutely, micro-hypertension induced mechanical stretch, on endothelial cells, interconnects innate and adaptive immune responses. 

The dominant cell in the decidua is an NK subset (dNK), they express low levels of IFN-γ and express proteins of Renin Angiotensin System (RAS). At day 12 RAS peptide ANP colocalizes to dNK’s suggesting that dNK RAS infers localized responsiveness.  When TFAM, required for transcription of mtDNA, was deleted from cardiomyocytes, after 32 days, animals developed cardiomyopathy and Nppa (gene encoding ANP) and Nppb expression was elevated. 

In monocytes increased endothelial stretch activates STAT3, which is involved in driving almost all pathways that control NK cytolytic activity and reciprocal regulatory interactions between NK cells and other components of the immune system. The crosstalk between STAT3 and p53/RAS signaling controls cancer cell metastasis. p53, Stat3, and, potentially, the estrogen receptor are thought to act as co-regulators, affecting mitochondrial gene expression through protein-protein interactions. Co-immunoprecipitation of p53 with TFAM suggests it may regulate mitochondrial DNA-damage repair.

Like initial trophoblasts with low level mtDNA, mature cells, like cardiomyocytes that prolong low level mtDNA may also aggravate autoimmune sponsored hypertension that remodels microvascular networks providing nutrients for growth of reduced mtDNA stem cell replicas. Indeed, mitochondrial dysfunction (from depleted mtDNA) does not affect pluripotent gene expression, but results in severe defects in lineage differentiation.

During severe sepsis, intense, on-going mtDNA damage and mitochondrial dysfunction could overwhelm the capacity for mitochondrial biogenesis, leading to a gradual decline in mtDNA levels over time. This may contribute to monocyte immune deactivation, which is associated with adverse clinical outcomes and could be reversed by IFN-γ. 

Identifying cells that optimally educate cocultured NK cells for precision IFN-γ and cytolytic responsiveness is part of the ongoing work by the Codondex team.

Angiogenic Growth Factor Flood

A previous series, about p53 culminated with "Blastocyst Development - A Perfected Cancer Model" that focused on the parallels in angiogenesis, triggered by blastocyst implantation and progression of tumors beyond ~1mm. Now, a recent study has found that conventional Natural Killer cells (cNK) control vascular remodeling in the uterus during pregnancy by acidifying the extracellular matrix (ECM) with a2V-ATPase that activates MMP-9 that degrades the ECM. Ablation of a2V-ATPase decreases Bax and p53 expression in testis and leads to implantation failure in the female mouse. The degrading ECM releases bound pro-angiogenic growth factors that contribute to Uterine artery (UtA) remodeling characterized by the loss of vascular smooth muscle cells (VSMCs) and dilation of the vessels. Without cNK, the UtA never lose VSMCs and UtA resistance remains high often leading to implantation failure.

Its logical that a timely flood of angiogenic growth factors, previously stored in the ECM would provide instant availability, but whether this explains the maternal-embryonic immune paradox remains to be determined? In the immune paradox maternal NK cells invade and maternal blood vessels are remodeled just before the arrival of trophoblasts, the external cells of the blastocyst, that carry male antigens during formation of the fetal placenta. A sudden flood of angiogenic factors preceding invading trophoblasts could provide the perfect environment required for maternal arterial/vascular remodeling.

Lymphocytes in the uterine lining (decidua) are dominated by a unique decidual natural killer (dNK) cell population. The dNK cell surface phenotype CD56bright CD16− CD3− and macrophages CD14+ CD206+(dMac) support a model whereby dNK cells, capable of killing extra-villous cytotrophoblasts (CTB), are prevented from doing so by neighboring macrophages thus protecting the fetal cells from NK cell attack. Existing research has centered on the function of the abundant and diverse sets of dNK, but now that cNK cells have been identified to play a more significant role, our understanding of the remodeling are likely to change.

In CTB exogenous p53 is able to down-regulate MMP-9 promoter activity, but endogenous p53 is not able to regulate MMP-9 expression in first trimester CTB cells. Inactivation of p53 through mutation is the most common trait in cancer. By loosing its onco-suppressive activity, p53 becomes oncogenic in almost all malignant tumors (Soussi and Lozano, 2005). Although p53 is not mutated in the human placenta, it has become functionally incompetent. Understanding why and how p53 is functionally incompetent in CTB might well be the key to understanding trophoblast invasion.

Downregulation of EMMPRIN (BSG,CD147) by p53 leads to a decrease in the activity of MMP-9 and an inhibition of tumor cell invasion. Upregulation of EMMPRIN seen in many cancers can be attributed to, at least in part, to the dysfunction of p53 and thus provides new evidence for the roles of p53 in tumor development and progression. Epithelial derived MMP-9 exhibits a novel defensive role of tumor suppressor in colitis associated cancer by activating MMP9-Notch1-ARF-p53 axis. MMP-9 mediates Notch1 signaling via p53 to regulate apoptosis, cell cycle arrest, and inflammation. 

The inter-activity of p53, cNK and MMP-9 are complexed, but this novel research may lead to the mechanisms by which arterial remodeling occurs after release of angiogenic factors from ECM. If that shares characteristics of NK invasion into developing tumor micro environment's a new therapeutic approach may arise.