Lazaros C. Foukas

Critical role for the p110α phosphoinositide-3-OH kinase in growth and metabolic regulation

The eight catalytic subunits of the mammalian phosphoinositide-3-OH kinase (PI(3)K) family form the backbone of an evolutionarily conserved signalling pathway; however, the roles of most PI(3)K isoforms in organismal physiology and disease are unknown. To delineate the role of p110α, a ubiquitously expressed PI(3)K involved in tyrosine kinase and Ras signalling, here we generated mice carrying a knockin mutation (D933A) that abrogates p110α kinase activity. Homozygosity for this kinase-dead p110α led to embryonic lethality. Mice heterozygous for this mutation were viable and fertile, but displayed severely blunted signalling via insulin-receptor substrate (IRS) proteins, key mediators of insulin, insulin-like growth factor-1 and leptin action. Defective responsiveness to these hormones led to reduced somatic growth, hyperinsulinaemia, glucose intolerance, hyperphagia and increased adiposity in mice heterozygous for the D933A mutation. This signalling function of p110α derives from its highly selective recruitment and activation to IRS signalling complexes compared to p110β, the other broadly expressed PI(3)K isoform, which did not contribute to IRS-associated PI(3)K activity. p110α was the principal IRS-associated PI(3)K in cancer cell lines. These findings demonstrate a critical role for p110α in growth factor and metabolic signalling and also suggest an explanation for selective mutation or overexpression of p110α in a variety of cancers.

Activity of any class IA PI3K isoform can sustain cell proliferation and survival

Small molecule inhibitors of PI3K for oncology mainly target the class I PI3Ks, comprising the p110α, β, γ, and δ isoforms, of which only p110α is mutated in cancer. To assess the roles of class I PI3K isoforms in cell proliferation and survival, we generated immortalized mouse leukocyte and fibroblast models in which class I PI3Ks were inactivated by genetic and pharmacological approaches. In IL3-dependent hemopoietic progenitor cells (which express all four class I PI3K isoforms), genetic inactivation of either p110α or p110δ did not affect cell proliferation or survival or sensitize to p110β or p110γ inactivation. Upon compound inactivation of p110α and p110δ, which removed >90% of p85-associated PI3K activity, remarkably, cells continued to proliferate effectively, with p110β assuming an essential role in signaling and cell survival. Furthermore, under these conditions of diminished class I PI3K activity, input from the ERK pathway became important for cell survival. Similar observations were made in mouse embryonic fibroblasts (which mainly express p110α and p110β) in which p110α or p110β could sustain cell proliferation as a single isoform. Taken together, these data demonstrate that a small fraction of total class I PI3K activity is sufficient to sustain cell survival and proliferation. Persistent inhibition of selected PI3K isoforms can allow the remaining isoform(s) to couple to upstream signaling pathways in which they are not normally engaged. Such functional redundancy of class IA PI3K isoforms upon sustained PI3K inhibition has implications for the development and use of PI3K inhibitors in cancer.

Comparison of the kinetic properties of the lipid- and protein-kinase activities of the p110alpha and p110beta catalytic subunits of class-Ia phosphoinositide 3-kinases.

Growth factors regulate a wide range of cellular processes via activation of the class-Ia phosphoinositide 3-kinases (PI 3-kinases). We directly compared kinetic properties of lipid- and protein-kinase activities of the widely expressed p110alpha and p110beta isoforms. The lipid-kinase activity did not display Michaelis-Menten kinetics but modelling the kinetic data demonstrated that p110alpha has a higher V(max) and a 25-fold higher K(m) for PtdIns than p110beta. A similar situation occurs with PtdIns(4,5)P(2), because at low concentration of PtdIns(4,5)P(2) p110beta is a better PtdIns(4,5)P(2) kinase than p110alpha, although this is reversed at high concentrations. These differences suggest different functional roles and we hypothesize that p110beta functions better in areas of membranes containing low levels of substrate whereas p110alpha would work best in areas of high substrate density such as membrane lipid rafts. We also compared protein-kinase activities. We found that p110beta phosphorylated p85 to a lower degree than did p110alpha. We used a novel peptide-based assay to compare the kinetics of the protein-kinase activities of p110alpha and p110beta. These studies revealed that, like the lipid-kinase activity, the protein-kinase activity of p110alpha has a higher K(m) (550 microM) than p110beta (K(m) 8 microgM). Similarly, the relative V(max) towards peptide substrate of p110alpha was three times higher than that of p110beta. This implies differences in the rates of regulatory autophosphorylation in vivo, which are likely to mean differential regulation of the lipid-kinase activities of p110alpha and p110beta in vivo.

Regulation of Phosphoinositide 3-Kinase by Its Intrinsic Serine Kinase Activity In Vivo

ABSTRACT One potentially important mechanism for regulating class Ia phosphoinositide 3-kinase (PI 3-kinase) activity is autophosphorylation of the p85α adapter subunit on Ser608 by the intrinsic protein kinase activity of the p110 catalytic subunit, as this downregulates the lipid kinase activity in vitro. Here we investigate whether this phosphorylation can occur in vivo. We find that p110α phosphorylates p85α Ser608 in vivo with significant stoichiometry. However, p110β is far less efficient at phosphorylating p85α Ser608, identifying a potential difference in the mechanisms by which these two isoforms are regulated. The p85α Ser608 phosphorylation was increased by treatment with insulin, platelet-derived growth factor, and the phosphatase inhibitor okadaic acid. The functional effects of this phosphorylation are highlighted by mutation of Ser608, which results in reduced lipid kinase activity and reduced association of the p110α catalytic subunit with p85α. The importance of this phosphorylation was further highlighted by the finding that autophosphorylation on Ser608 was impaired, while lipid kinase activity was increased, in a p85α mutant recently discovered in human tumors. These results provide the first evidence that phosphorylation of Ser608 plays a role as a shutoff switch in growth factor signaling and contributes to the differences in functional properties of different PI 3-kinase isoforms in vivo.

Long‐term p110α PI3K inactivation exerts a beneficial effect on metabolism

The insulin/insulin‐like growth factor‐1 signalling (IIS) pathway regulates cellular and organismal metabolism and controls the rate of aging. Gain‐of‐function mutations in p110α, the principal mammalian IIS‐responsive isoform of PI 3‐kinase (PI3K), promote cancer. In contrast, loss‐of‐function mutations in p110α impair insulin signalling and cause insulin resistance, inducing a pre‐diabetic state. It remains unknown if long‐term p110α inactivation induces further metabolic deterioration over time, leading to overt unsustainable pathology. Surprisingly, we find that chronic p110α partial inactivation in mice protects from age‐related reduction in insulin sensitivity, glucose tolerance and fat accumulation, and extends the lifespan of male mice. This beneficial effect of p110α inactivation derives in part from a suppressed down‐regulation of insulin receptor substrate (IRS) protein levels induced by age‐related hyperinsulinemia, and correlates with enhanced insulin‐induced Akt signalling in aged p110α‐deficient mice. This temporal metabolic plasticity upon p110α inactivation indicates that prolonged PI3K inhibition, as intended in human cancer treatment, might not negatively impact on organismal metabolism.

Gene-targeting reveals physiological roles and complex regulation of the phosphoinositide 3-kinases

Phosphoinositide 3-kinases (PI3Ks) are represented by a family of eight distinct enzymes that can be divided into three classes based on their structure and function. The class I PI3Ks are heterodimeric enzymes that are regulated by recruitment to plasma membrane following receptor activation and which control numerous cellular functions, including growth, differentiation, migration, survival, and metabolism. New light has been shed on the biological role of individual members of the class I PI3Ks and their regulatory subunits through gene-targeting experiments. In addition, these experiments have brought the complexity of how PI3K activation is regulated into focus.

Developmental defects and rescue from glucose intolerance of a catalytically-inactive novel Ship2 mutant mouse

The function of the phosphoinositide 5-phosphatase Ship2 was investigated in a new mouse model expressing a germline catalytically-inactive Ship2(∆/∆) mutant protein. Ship2(∆/∆) mice were viable with defects in somatic growth and in development of muscle, adipose tissue and female genital tract. Lipid metabolism and insulin secretion were also affected in these mice, but glucose tolerance, insulin sensitivity and insulin-induced PKB phosphorylation were not. We expected that the expression of the catalytically inactive Ship2 protein in PI 3-kinase-defective p110α(D933A/+) mice would counterbalance the phenotypes of parental mice by restoring normal PKB signaling but, for most of the parameters tested, this was not the case. Indeed, often, the Ship2(∆/∆) phenotype had a dominant effect over the p110α(D933A/+) phenotype and, sometimes, there was a surprising additive effect of both mutations. p110α(D933A/+)Ship2(∆/∆) mice still displayed a reduced PKB phosphorylation in response to insulin, compared to wild type mice yet had a normal glucose tolerance and insulin sensitivity, like the Ship2(∆/∆) mice. Together, our results suggest that the Ship2(∆/∆) phenotype is not dependent on an overstimulated class I PI 3-kinase-PKB signaling pathway and thus, indirectly, that it may be more dependent on the lack of Ship2-produced phosphatidylinositol 3,4-bisphosphate and derived phosphoinositides.

Phosphoinositide Signalling Pathways in Metabolic Regulation

The Insulin Receptor/PI 3-kinase (INSR/PI3K) signalling pathway is a key regulator of cell and organismal metabolism. Phosphoinositides generated by PI 3-kinases following insulin and other metabolic hormone receptor activation give rise to signalling cascades involving a multitude of effector molecules. The physiological roles of these molecules have been dissected with the use of both pharmacological and genetic tools. Furthermore, tissue-specific mutagenesis has revealed the extent to which individual insulin-target organs and signalling molecules contribute to whole-body carbohydrate and lipid homeostasis. These studies have generated important information with respect to the function of these molecules in normal physiology and their implication in the development of metabolic diseases such as type-2 diabetes and obesity.

Direct Interaction of Major Histocompatibility Complex Class II-derived Peptides with Class Ia Phosphoinositide 3-Kinase Results in Dose-dependent Stimulatory Effects

Peptides corresponding to residues 65–79 of human lymphocyte antigen class II sequence (DQA*03011) are cell-permeable and at high concentrations block activation of protein kinase B/Akt and p70-S6 kinase in T-cells, effects attributed to inhibition of phosphoinositide (PI) 3-kinase activity. To understand the molecular basis of this, we analyzed the effect this peptide had on activity of class I PI 3-kinases. Although there was no effect on the activity of class Ib PI 3-kinase or on the protein kinase activity of class I PI 3-kinases, there was a biphasic effect on lipid kinase activity of the class Ia enzymes. There was an inhibition of activity at higher peptide concentrations because of a formation of insoluble complexes between peptide and enzyme. Conversely, at lower peptide concentrations there was a profound activation of PI 3-kinase activity of class Ia PI 3-kinases. Studies of peptide variants revealed that all active peptides conform to heptad repeat motifs characteristic of coiled-coil helices. Surface plasmon resonance studies confirmed direct sequence-specific binding of active peptide to the p85α adapter subunit of class Ia PI 3-kinase. Active peptides also activated protein kinase B and extracellular signal-regulated kinase (ERK) in vivo in a wortmannin-sensitive manner while reducing recoverable cellular p85 levels. These results indicate that the human lymphocyte antigen class II-derived peptides regulate PI 3-kinase by direct interaction, probably via the coiled-coil domain. These peptides define a novel mechanism of regulating PI 3-kinase and will provide a useful tool for specifically dissecting the function of class Ia PI 3-kinase in cells and for probing structure-function relationships in the class Ia PI 3-kinase heterodimers.

Growth factor, energy and nutrient sensing signalling pathways in metabolic ageing

The field of the biology of ageing has received increasing attention from a biomedical point of view over the past decades. The main reason has been the realisation that increases in human population life expectancy are accompanied by late onset diseases. Indeed, ageing is the most important risk factor for a number of neoplastic, neurodegenerative and metabolic pathologies. Advances in the knowledge of the genetics of ageing, mainly through research in model organisms, have implicated various cellular processes and the respective signalling pathways that regulate them in cellular and organismal ageing. Associated with ageing is a dysregulation of metabolic homeostasis usually manifested as age-related obesity, diminished insulin sensitivity and impaired glucose and lipid homeostasis. Metabolic deterioration contributes to the ageing phenotype and metabolic pathologies are thought to be one of the main factors limiting the potential for lifespan extension. Great efforts have been directed towards identifying pharmacological interventions with the potential to improve healthspan and a number of natural and synthetic compounds have shown promise in achieving beneficial metabolic effects.