PFKFB3 explained

PFKFB3 is a gene that encodes the 6-phosphofructo-2-kinase/fructose-2,6-biphosphatase 3 enzyme in humans.[1] [2] [3] It is one of 4 tissue-specific PFKFB isoenzymes identified currently (PFKFB1-4).[4]

Gene

The PFKFB3 gene is mapped to single locus on chromosome 10 (10p15-p14). It spans a region of 32.5kb with an open reading frame that is 5,675bp long. It is estimated to consist of 19 exons, of which 15 are regularly expressed. Alternative splicing of the variable, COOH-terminal domain has been observed, leading to 6 different isoforms termed UBI2K1 to UBI2K6 in humans.[5] Different nomenclature also recognizes two broad categories of PFKFB3 isoforms, termed ‘inducible’ and ‘ubiquitous’.[6] The inducible protein isoform, iPFK2, is named as such because its expression has been shown to be induced by hypoxic conditions.

The PFKFB3 promoter is predicted to contain multiple binding sites, including Sp-1 and AP-2 binding sites. It also contains motifs for the binding of E-box, nuclear factor-1 (NF-1), and progesterone response element. Expression of the promoter is shown to be induce by phorbol esters and cyclic-AMP-dependent protein kinase signaling.

Structure

The four PFKFB isoforms share high (85%) ‘2-Kase/2-Pase core’ sequence homology, but have different properties based on variable N- and C- terminal regulatory domains and variation in residues surrounding the active sites.[7] The PFKFB3 inducible isoform has higher ‘2-Kase’ (kinase) activity than other isoforms, due to phosphorylation of Ser-460 by PKA or AMP-dependent protein kinase. The high ‘2-Kase’ activity of PFKFB3 is also due to the lack of a specific Ser that is phosphorylated in the other PFKFB isoforms to decrease kinase activity.[8]

The primary protein encoded by PFKFB3, iPFK2, consists of 590 amino acids. It has a predicted molecular weight of 66.9 kDa and an isoelectric point of 8.64. The crystal structure was determined in 2006:

Function

iPFK2 converts fructose-6-phosphate to fructose-2,6-bisP (F2,6BP). F2,6BP is a ‘potent’ allosteric activator of 6-phosphofructokinase-1 (PFK-1), stimulating glycolysis. Click to see image of PFFKB3 function.

Role in neuronal excitotoxicity

In neurons, glucose metabolism via glycolysis is usually low when compared to astrocytes. According Astrocyte-to-Neuron Lactate Shuttle Hypothesis, glucose uptake by the brain parenchyma occurs predominantly into astrocytes which subsequently release lactate for the use of neurons.[9] In neurons, glucose is mainly metabolized through the pentose–phosphate pathway (PPP), which is required for NADPH(H+) regeneration and maintenance of neuronal redox status. This neuronal metabolic switch is dictated by the PFKFB3 activity. In neurons, PFKFB3 protein abundance is negligible due to the continuous proteasomal degradation of the enzyme.[10] However, overexcitation of N-methyl-D-aspartate subtype of glutamate receptors (NMDAR), known as excitotoxicity, stabilizes PFKFB3 protein in neurons, resulting in a redirection of glucose flux from PPP to glycolysis, followed by low NADPH(H+) availability for proper GSH regeneration; this ultimately leads to oxidative stress and neuronal death. Silencing of PFKFB3 with small interfering RNA in neurons in vitro prevents the increase in ROS and apoptotic death induced by excitotoxic stimulus.[11] Pharmacological inhibition of PFKFB3 in vitro also protects neurons from apoptosis induced by NMDAR overexcitation as well as from amyloid-ß peptide-induced neurotoxicity. When used in vivo in a mouse model of ischaemic stroke, PFKFB3 inhibitor alleviates motor discoordination and brain infarct injury [12]

Cancer Connections

Warburg Effect

The Warburg effect, proposed by Otto Warbug in 1956,[13] describes the upregulation of glycolysis in most cancer cells, even in the presence of oxygen. The high rate of glycolysis is accompanied by increased lactic acid fermentation, providing additional nutrients for cancer cell growth and tumorigenesis.

PFKFB3 is associated with the Warburg effect because its activity increases the rate of glycolysis. PFKFB3 has been found to be upregulated in numerous cancers, including colon, breast, ovarian, and thyroid.[14] Reduced methylation of PFKFB3 is also found in some cancers, triggering the shift to the glycolytic pathway that supports cancerous growth.[15]

Hypoxia Signaling Pathway

PFKFB3 expression is induced by hypoxia.[16] The promoter of PFKFB3 contains binding sites, called hypoxia response elements (HREs), that recruit the binding of hypoxia-inducible factor-1 (HIF-1).[17]

Hypoxia signaling via HIF-1α stabilization upregulates the transcription of genes that permit survival in low oxygen conditions. These genes include glycolysis enzymes, like PFKFB3, that permit ATP synthesis without oxygen, and vascular endothelial growth factor (VEGF), which promotes angiogenesis.

Cell Cycle & Apoptosis

It was more recently discovered that PFKFB3 promotes cell cycle progression (cell proliferation) and suppresses apoptosis by regulating cyclin-dependent kinase 1 (Cdk-1). PFKFB3's synthesis of F2,6BP in the nucleus was found to regulate Cdk-1, whereas cytosolic PFKFB3 activates PFK-1. Nuclear PFKFB3 activates Cdk1 to phosphorylate the Thr-187 site of p27, causing decreased levels of p27.[18] [19] Reduced p27 causes protection against apoptosis and progression of cells through the G1/S phase checkpoint These findings established a significant link between PFKFB3 cancer cell survival and proliferation.

Circadian Clock

Circadian clocks dysregulation is associated with many types of cancer.[20] PFKFB3 expression exhibits circadian rhythmicity that is different between cancerous and non-cancerous cells.[21] It was specifically found that the circadian-driven transcription factor ‘CLOCK’ binds to the PFKFB3 promoter at a genuine ‘E-box’ site to increase transcription in cancer cells.

Additional Cancer Connections

Anti-cancer Therapeutic Strategy

Inhibition of PFKFB3 is being analyzed as a potential anti-cancer therapy. The most notable example is clinical trial by Advanced Cancer Therapeutics (ACT) with PFK158, an improved version of 3PO, a PFKFB3 inhibitor.[25] It appears, however, that further development has been discontinued following disappointing Phase I results (see also the discussion of ACT compounds in).[26]

Small molecule inhibitors of PFKFB3

Several small-molecule inhibitors of PFKFB3 are currently in development.

For a long time a small molecule 3-(3-pyridinyl)-1-(4-pyridinyl)-2-propen-1-one (3PO) was believed to be an inhibitor of PFKFB3 and used as PFKFB3 inhibitor in many scientific publications. 3PO decreases glucose uptake and increases autophagy.[27] Research is currently exploring various 3PO derivatives (i.e. PFKF15)[28] in an effort to increase their efficacy as anti-cancer therapies, but the data on 3PO derivatives being actually PFKFB3 inhibitors are also unavailable.

Recent research of one of the leading pharmaceuticals companies AstraZeneca and CRT Discovery Laboratories of world's largest independent cancer research charity Cancer Research UK showed that 3PO was inactive in a kinase PFKFB3 inhibition assay (IC50 > 100 μM).[22] The crystal structures of 3PO, as well as its analogues PFK15 and PFK158, with the PFKFB3 enzyme are also not available. The findings of AstraZeneca and Cancer Research UK regarding to 3PO remain unchallenged neither by 3PO developers since April 7, 2015.

The efficacy of two known PFKFB3 inhibitors, namely AZ67 (from AstraZeneca and CRT Discovery Laboratories [22]), and PFK158, an improved but structurally close derivative of 3PO, were recently investigated for their ability to reduce F2,6BP production in A549 cells. Both compounds (AZ67 and PFK158) were able to reduce the cellular levels of F2,6BP in a dose-dependent manner, with IC50 of 0.51 μM and 5.90 μM, respectively. To see if the reduction of cellular F2,6BP levels was a result of direct PFKFB3 inhibition, both compounds were tried in the enzymatic cell-free assay. The study revealed that AZ67 inhibited the enzymatic activity of PFKFB3 with an IC50 of 0.018 μM, a value that is in accordance with previously published results. However, PFK158 had no effect on PFKFB3 enzymatic activity at any of the concentrations tested (up to 100 μM). Accordingly, although PFK158 is able to decrease F2,6BP and glycolytic flux, the experiments show that these effects are not due to PFKFB3 enzymatic inhibition.

Together, these findings put into question the range of scientific research and publications where 3PO and its derivatives (such as PFKF158) was used as a PFKFB3 inhibitor.

In 2018 Kancera reported development and characterization of KAN0438241 (and its pro-drug KAN0438757) as a potent and highly selective PFKFB3 inhibitor and a radiosensitizer.[29]

Other pathways involving PFKFB3

Autophagy

Enhanced activity of PFKFB3 accelerates ROS production as an end product of glycolysis, and thus increases autophagy. Likewise, inhibition of PFKFB3 has been found to induce autophagy.[30] [31]

Autophagy can prolong cellular survival during low energy conditions. This finding was discovered in relation to rheumatoid arthritis.[32] It was found that RA T cell fail to upregulate autophagy, and knockout experiments placed PFKFB3 as an upstream regulator of this process.

Insulin Signaling Pathway

PFKFB3 was identified in a kinome screen as a regulator of insulin/IGF-1. Suppression of PFKFB3 was found to decrease insulin-stimulated glucose uptake, GLUT4 translocation, and Akt signaling in 3T3-L1 adipocytes. Overexpression caused the insulin-dependent phosphorylation of Akt and Akt substrates.[33]

PFKFB3 expression increases in fat tissues during adipogenesis, but prolonged insulin exposure has been shown to decrease the expression of PFKFB3. This is thought to occur due to a negative feedback mechanism involving insulin.[34]

p38/MK2 Stress Signaling Pathway

p38 MAPK have been found to increase PFKFB3 activity through (1) the transcriptional activation of PFKFB3 in response to stress stimuli and (2) the post-translational phosphorylation of iPFK2 at Ser-461.[35] [36]

Further reading

Notes and References

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  2. Manzano A, Rosa JL, Ventura F, Pérez JX, Nadal M, Estivill X, Ambrosio S, Gil J, Bartrons R . 6 . Molecular cloning, expression, and chromosomal localization of a ubiquitously expressed human 6-phosphofructo-2-kinase/ fructose-2, 6-bisphosphatase gene (PFKFB3) . Cytogenetics and Cell Genetics . 83 . 3–4 . 214–7 . Mar 1999 . 10072580 . 10.1159/000015181 . 23221556 .
  3. Web site: Entrez Gene: PFKFB3 6-phosphofructo-2-kinase/fructose-2,6-biphosphatase 3.
  4. Mahlknecht U, Chesney J, Hoelzer D, Bucala R . Cloning and chromosomal characterization of the 6-phosphofructo-2-kinase/fructose-2,6-bisphosphatase-3 gene (PFKFB3, iPFK2) . International Journal of Oncology . 23 . 4 . 883–91 . October 2003 . 12963966 . 10.3892/ijo.23.4.883 .
  5. Kessler R, Eschrich K . Splice isoforms of ubiquitous 6-phosphofructo-2-kinase/fructose-2,6-bisphosphatase in human brain . Brain Research. Molecular Brain Research . 87 . 2 . 190–5 . March 2001 . 11245921 . 10.1016/s0169-328x(01)00014-6 .
  6. Navarro-Sabaté A, Manzano A, Riera L, Rosa JL, Ventura F, Bartrons R . The human ubiquitous 6-phosphofructo-2-kinase/fructose-2,6-bisphosphatase gene (PFKFB3): promoter characterization and genomic structure . Gene . 264 . 1 . 131–8 . February 2001 . 11245987 . 10.1016/S0378-1119(00)00591-6 .
  7. Kim SG, Manes NP, El-Maghrabi MR, Lee YH . Crystal structure of the hypoxia-inducible form of 6-phosphofructo-2-kinase/fructose-2,6-bisphosphatase (PFKFB3): a possible new target for cancer therapy . The Journal of Biological Chemistry . 281 . 5 . 2939–44 . February 2006 . 16316985 . 10.1074/jbc.M511019200 . free .
  8. Sakakibara R, Kato M, Okamura N, Nakagawa T, Komada Y, Tominaga N, Shimojo M, Fukasawa M . 6 . Characterization of a human placental fructose-6-phosphate, 2-kinase/fructose-2,6-bisphosphatase . Journal of Biochemistry . 122 . 1 . 122–8 . July 1997 . 9276680 . 10.1093/oxfordjournals.jbchem.a021719 .
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