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significant and clinically relevant worsening of insulin sensitivity with an isoenergetic plant-based high-protein diet

healthy humans that are exposed to amino acid infusions rapidly develop insulin resistance

longer term high-protein intake has been shown to result in whole-body insulin resistance [68, 118], associated with upregulation of factors involved in the mammalian target of rapamycin (mTOR)/S6K1 signalling pathway [68], increased stimulation of glucagon and insulin within the endocrine pancreas, high glycogen turnover [118] and stimulation of gluconeogenesis [68, 118].

it was recently shown in a large prospective cohort with 10 years followup that consuming 5% of energy from both animal and total protein at the expense of carbohydrates or fat increases diabetes risk by as much as 30% [69]. This reinforces the theory that high-protein diets can have adverse effects on glucose metabolism.

Another recent study showed that low-carbohydrate high-protein diets, used on a regular basis and without consideration of the nature of carbohydrates or the source of proteins, are also associated with increased risk of cardiovascular disease [70], thereby indicating a potential link between high-protein Western diets, T2DM, and cardiovascular risk.

the amount of BCAAs supplied in the various studies is extremely variable

malnutrition progressing to cachexia is another common manifestation of cirrhosis

Malnutrition can be mitigated with BCAA supplementation

Studies show that administration of amino acid formulas enriched with BCAAs can reduce protein loss, support protein synthesis, and improve nutritional status of patients with chronic liver disease

Leucine has been shown to be the most effective of the BCAAs because it acts via multiple pathways to stimulate protein synthesis

BCAAs metabolites inhibit proteolysis

Patients with cirrhosis have both insulin deficiency and insulin resistance

BCAAs (particularly leucine) help to reverse the catabolic, hyperglucagonemic state of cirrhosis both by stimulating insulin release from the pancreatic β cells and by decreasing insulin resistance allowing for better glucose utilization

Coadministration of BCAAs and glucose has been found to be particularly useful

BCAA supplementation improves protein-energy malnutrition by improving utilization of glucose, thereby diminishing the drive for proteolysis, inhibiting protein breakdown, and stimulating protein synthesis

Cirrhotic patients have impaired immune defense, characterized by defective phagocytic activity and impaired intracellular killing activity

another effect of BCAA supplementation is improvement of phagocytic function of neutrophils and possibly improvement in natural killer T (NKT) cell lymphocyte activity

BCAA supplementation may reduce the risk of infection in patients with advanced cirrhosis not only through improvement in protein-energy malnutrition but also by directly improving the function of the immune cells themselves

BCAA administration has also been shown to have a positive effect on liver regeneration

A proposed mechanism for improved liver regeneration is the stimulatory effect of BCAAs (particularly leucine) on the secretion of hepatocyte growth factor by hepatic stellate cells

BCAAs activate rapamycin signaling pathways which promotes albumin synthesis in the liver as well as protein and glycogen synthesis in muscle tissue

Chemical improvement with BCAA treatment is demonstrated by recovery of serum albumin and lowering of serum bilirubin levels

long-term oral BCAA supplementation was useful in staving off malnutrition and improving survival by preventing end-stage fatal complications of cirrhosis such as hepatic failure and gastrointestinal bleeding

The incidence of death by any cause, development of liver cancer, rupture of esophageal varices, or progression to hepatic failure was decreased in the group that received BCAA supplementation

Patients receiving BCAA supplementation also have a lower average hospital admission rate, better nutritional status, and better liver function tests

patients taking BCAA supplementation report improved quality of life

BCAAs have been shown to mitigate hepatic encephalopathy, cachexia, and infection rates, complications associated with the progression of hepatic cirrhosis

BCAAs make up 20-25% of the protein content of most foods

Highest levels are found in casein whey protein of dairy products and vegetables, such as corn and mushrooms. Other sources include egg albumin, beans, peanuts and brown rice bran

In addition to BCAAs from diet, oral supplements of BCAAs can be used

Oral supplementation tends to provide a better hepatic supply of BCAAs for patients able to tolerate PO nutrition as compared with IV supplementation, especially when treating symptoms of hepatic encephalopathy

Coadministration of BCAAs with carnitine and zinc has also been shown to increase ammonia metabolism further reducing the encephalopathic symptoms

Cirrhotic patients benefit from eating frequent, small meals that prevent long fasts which place the patient in a catabolic state

the best time for BCAA supplementation is at bedtime to improve the catabolic state during starvation in early morning fasting

A late night nutritional snack reduces symptoms of weakness and fatigability, lowers postprandial hyperglycemia, increases skeletal muscle mass,[25] improves nitrogen balance, and increases serum albumin levels.[26] Nocturnal BCAAs even improve serum albumin in cirrhotic patients who show no improvement with daytime BCAAs

Protein-energy malnutrition (PEM), with low serum albumin and low muscle mass, occurs in 65-90% of cases of advanced cirrhosis

hyperglucagonemia results in a catabolic state eventually producing anorexia and cachexia

BCAAs are further depleted from the circulation due to increased uptake by skeletal muscles that use the BCAAs in the synthesis of glutamine, which is produced in order to clear the ammonia that is not cleared by the failing liver

patients with chronic liver disease, particularly cirrhosis, routinely have decreased BCAAs and increased aromatic amino acids (AAAs) in their circulation

Maintaining a higher serum albumin in patients with cirrhosis is associated with decreased mortality and improved quality of life

the serum BCAA concentration is strongly correlated with the serum albumin level

Niclosamide blocked TNFα-induced IκBα phosphorylation, translocation of p65, and the expression of NF-κB-regulated genes

Niclosamide also inhibited the DNA binding of NF-κB to the promoter of its target genes

niclosamide has two independent effects: NF-kB activation and ROS elevation

The Wnt signaling pathway plays fundamental roles in directing tissue patterning in embryonic development, in maintaining tissue homeostasis in differentiated tissue, and in tumorigenesis

niclosamide is a potent inhibitor of the Wnt/β-catenin pathway

The Notch signaling pathway plays important roles in a variety of cellular processes such as proliferation, differentiation, apoptosis, cell fate decisions, and maintenance of stem cells

niclosamide potently suppresses the luciferase activity of a CBF-1-dependent reporter gene in both a dose-dependent and a time-dependent manners in K562 leukemia cells

niclosamide treatment abrogated the epidermal growth factor (EGF)-stimulated dimerization and nuclear translocation and transcriptional activity of Stat3, and induced cell growth inhibition and apoptosis in several types of cancer cells (e.g. Du145, Hela, A549) that exhibit relatively higher levels of Stat3 constitutive activation

niclosamide can rapidly increase autophagosome formation

niclosamide induced autophagy and inhibited mammalian target of rapamycin complex 1 (mTORC1)

Niclosamide has low toxicity in mammals (oral median lethal dose in rats >5000 mg/kg

Niclosamide is active against cancer cells such as AML and colorectal cancer cells, not only as a monotherapy but also as part of combination therapy, in which it has been found to be synergistic with frontline chemotherapeutic agents (e.g., oxaliplatin, cytarabine, etoposide, and daunorubicin)

Because niclosamide targets multiple signaling pathways (e.g., NF-κB, Wnt/β-catenin, and Notch), most of which are closely involved with cancer stem cells, it holds promise in eradicating cancer stem cells

IR also indirectly induces DNA damage by stimulating reactive oxygen species (ROS) production

IR is known to induce EMT in vitro

p53 is activated in response to IR-induced DNA damage

IR paradoxically also promotes tumour recurrence and metastasis

DNA double-strand breaks (DSBs)

cancer cells undergoing EMT acquire invasive and metastatic properties

changes in the tumour microenvironment (TME)

IR seems to induce EMT and CSC phenotypes by regulating cellular metabolism

EMT, stemness, and oncogenic metabolism are known to be associated with resistance to radiotherapy and chemotherapy

Hanahan and Weinberg proposed ten hallmarks of cancer that alter cell physiology to enhance malignant growth: 1) sustained proliferation, 2) evasion of growth suppression, 3) cell death resistance, 4) replicative immortality, 5) evasion of immune destruction, 6) tumour-promoting inflammation, 7) activation of invasion and metastasis, 8) induction of angiogenesis, 9) genome instability, and 10) alteration of metabolism

EMT is a developmental process that plays critical roles in embryogenesis, wound healing, and organ fibrosis

IR is known to induce stemness and metabolic alterations in cancer cells

transforming growth factor-β [TGF-β], epidermal growth factor [EGF]) and their associated signalling proteins (Wnt, Notch, Hedgehog, nuclear-factor kappa B [NF-κB], extracellular signal-regulated kinase [ERK], and phosphatidylinositol 3-kinase [PI3K]/Akt

activate EMT-inducing transcription factors, including Snail/Slug, ZEB1/δEF1, ZEB2/SIP1, Twist1/2, and E12/E47

Loss of E-cadherin is considered a hallmark of EMT

IR has been shown to induce EMT to enhance the motility and invasiveness of several cancer cells, including those of breast, lung, and liver cancer, and glioma cells

IR may increase metastasis in both the primary tumour site and in normal tissues under some circumstance

sublethal doses of IR have been shown to enhance the migratory and invasive behaviours of glioma cells

ROS are known to play an important role in IR-induced EMT

High levels of ROS trigger cell death by causing irreversible damage to cellular components such as proteins, nucleic acids, and lipids, whereas low levels of ROS have been shown to promote tumour progression—including tumour growth, invasion, and metastasis

hypoxia-inducible factor-1 (HIF-1) is involved in IR-induced EMT

Treatment with the N-acetylcysteine (NAC), a general ROS scavenger, prevents IR-induced EMT, adhesive affinity, and invasion of breast cancer cells

Snail has been shown to play a crucial role in IR-induced EMT, migration, and invasion

IR activates the p38 MAPK pathway, which contributes to the induction of Snail expression to promote EMT and invasion

NF-κB signalling that promotes cell migration

ROS promote EMT to allow cancer cells to avoid hostile environments

HIF-1 is a heterodimer composed of an oxygen-sensitive α subunit and a constitutively expressed β subunit.

Under normoxia, HIF-1α is rapidly degraded, whereas hypoxia induces stabilisation and accumulation of HIF-1α

levels of HIF-1α mRNA are enhanced by activation of the PI3K/Akt/mammalian target of rapamycin (mTOR)

IR is known to increase stabilisation and nuclear accumulation of HIF-1α, since hypoxia is a major condition for HIF-1 activation

IR induces vascular damage that causes hypoxia

ROS is implicated in IR-induced HIF-1 activation

IR causes the reoxygenation of hypoxic cancer cells to increase ROS production, which leads to the stabilisation and nuclear accumulation of HIF-1

IR increases glucose availability under reoxygenated conditions that promote HIF-1α translation by activating the Akt/mTOR pathway

The stabilised HIF-1α then translocates to the nucleus, dimerizes with HIF-1β, and increases gene expression— including the expression of essential EMT regulators such as Snail—to induce EMT, migration, and invasion

TGF-β signalling has been shown to play a crucial role in IR-induced EMT

AP-1 transcription factor is involved in IR-induced TGF-β1 expression

Wnt/β-catenin signalling is also implicated in IR-induced EMT

Notch signalling is known to be involved in IR-induced EMT

IR also increases Notch-1 expression [99]. Notch-1 is known to induce EMT by upregulating Snail

PAI-1 signalling is also implicated in IR-induced Akt activation that increases Snail levels to induce EMT

EGFR activation is known to be associated with IR-induced EMT, cell migration, and invasion by activating two downstream pathways: PI3K/Akt and Raf/MEK/ERK

ROS and RNS are also implicated in IR-induced EGFR activation

IR has also been shown to activate Hedgehog (Hh) signalling to induce EMT

IR has been shown to induce Akt activation through several signalling pathways (EGFR, C-X-C chemokine receptor type 4 [CXCR4]/C-X-C motif chemokine 12 [CXCL12], plasminogen activator inhibitor 1 [PAI-1]) and upstream regulators (Bmi1, PTEN) that promote EMT and invasion

CSCs possess a capacity for self-renewal, and they can persistently proliferate to initiate tumours upon serial transplantation, thus enabling them to maintain the whole tumour

Conventional cancer treatments kill most cancer cells, but CSCs survive due to their resistance to therapy, eventually leading to tumour relapse and metastasis

identification of CSCs, three types of markers are utilised: cell surface molecules, transcription factors, and signalling pathway molecules

CSCs express distinct and specific surface markers; commonly used ones are CD24, CD34, CD38, CD44, CD90, CD133, and ALDH

Transcription factors, including Oct4, Sox2, Nanog, c-Myc, and Klf4,

signalling pathways, including those of TGF-β, Wnt, Hedgehog, Notch, platelet-derived growth factor receptor (PDGFR), and JAK/STAT

microRNAs (miRNAs), including let-7, miR-22, miR-34a, miR-128, the miR-200 family, and miR-451

Non-CSCs can be reprogrammed to become CSCs by epigenetic and genetic changes

EMT-inducing transcription factors, such as Snail, ZEB1, and Twist1, are known to confer CSC properties

Signalling pathways involved in EMT, including those of TGF-β, Wnt, and Notch, have been shown to play important roles in inducing the CSC phenotype

TGF-β1 not only increases EMT markers (Slug, Twist1, β-catenin, N-cadherin), but also upregulates CSC markers (Oct4, Sox2, Nanog, Klf4) in breast and lung cancer cells

some CSC subpopulations arise independently of EMT

IR has been shown to induce the CSC phenotype in many cancers, including breast, lung, and prostate cancers, as well as melanoma

Genotoxic stress due to IR or chemotherapy promotes a CSC-like phenotype by increasing ROS production

IR has been shown to induce reprogramming of differentiated cancer cells into CSCs

In prostate cancer patients, radiotherapy increases the CD44+ cell population that exhibit CSC properties

IR also induces the re-expression of stem cell regulators, such as Sox2, Oct4, Nanog, and Klf4, to promote stemness in cancer cells

EMT-inducing transcription factors and signalling pathways, including Snail, STAT3, Notch signalling, the PI3K/Akt pathway, and the MAPK cascade, have been shown to play important roles in IR-induced CSC properties

STAT3 directly binds to the Snail promoter and increases Snail transcription, which induces the EMT and CSC phenotypes, in cisplatin-selected resistant cells

Other oncogenic metabolic pathways, including glutamine metabolism, the pentose phosphate pathway (PPP), and synthesis of fatty acids and cholesterol, are also enhanced in many cancers

metabolic reprogramming

HIF-1α, p53, and c-Myc, are known to contribute to oncogenic metabolism

metabolic reprogramming

tumour cells exhibit high mitochondrial metabolism as well as aerobic glycolysis

occurring within the same tumour

CSCs can be highly glycolytic-dependent or oxidative phosphorylation (OXPHOS)-dependen

mitochondrial function is crucial for maintaining CSC functionality

cancer cells depend on mitochondrial metabolism and increase mitochondrial production of ROS that cause pseudo-hypoxia

HIF-1 then enhances glycolysis

CAFs have defective mitochondria that lead to the cells exhibiting the Warburg effect; the cells take up glucose, and then secrete lactate to 'feed' adjacent cancer cells

lactate transporter, monocarboxylate transporter (MCT)

nutrient microenvironment

Epithelial cancer cells express MCT1, while CAFs express MCT4. MCT4-positive, hypoxic CAFs secrete lactate by aerobic glycolysis, and MCT1-expressing epithelial cancer cells then uptake and use that lactate as a substrate for the tricarboxylic acid (TCA) cycle

MCT4-positive cancer cells depend on glycolysis and then efflux lactate, while MCT1-positive cells uptake lactate and rely on OXPHOS

metabolic heterogeneity induces a lactate shuttle between hypoxic/glycolytic cells and oxidative/aerobic tumour cells

bulk tumour cells exhibit a glycolytic phenotype, with increased conversion of glucose to lactate (and enhanced lactate efflux through MCT4), CSC subsets depend on oxidative phosphorylation; most of the glucose entering the cells is converted to pyruvate to fuel the TCA cycle and the electron transport chain (ETC), thereby increasing mitochondrial ROS production

the major fraction of glucose is directed into the pentose phosphate pathway, to produce redox power through the generation of NADPH and ROS scavengers

HIF-1α, p53, and c-Myc, are known to contribute to oncogenic metabolism

regulatory molecules involved in EMT and CSCs, including Snail, Dlx-2, HIF-1, STAT3, TGF-β, Wnt, and Akt, are implicated in the metabolic reprogramming of cancer cells

HIF-1 induces the expression of glycolytic enzymes, including the glucose transporter GLUT, hexokinase, lactate dehydrogenase (LDH), and MCT, resulting in the glycolytic switch

HIF-1 represses the expression of pyruvate dehydrogenase kinase (PDK), which inhibits pyruvate dehydrogenase (PDH), thereby inhibiting mitochondrial activity

STAT3 has been implicated in EMT-induced metabolic changes as well

TGF-β and Wnt play important roles in the metabolic alteration of cancer cells

Akt is also implicated in the glycolytic switch and in promoting cancer cell invasiveness

EMT, invasion, metastasis, and stemness

pyruvate kinase M2 (PKM2), LDH, and pyruvate carboxylase (PC), are implicated in the induction of the EMT and CSC phenotypes

decreased activity of PKM2 is known to promote an overall shift in metabolism to aerobic glycolysis

LDH catalyses the bidirectional conversion of lactate to pyruvate

High levels of LDHA are positively correlated with the expression of EMT and CSC markers

IR has been shown to induce metabolic changes in cancer cells

IR enhances glycolysis by upregulating GAPDH (a glycolysis enzyme), and it increases lactate production by activating LDHA, which converts pyruvate to lactate

IR enhances glycolysis by upregulating GAPDH (a glycolysis enzyme), and it increases lactate production by activating LDHA, which converts pyruvate to lactate

IR also elevates MCT1 expression that exports lactate into the extracellular environment, leading to acidification of the tumour microenvironment

IR increases intracellular glucose, glucose 6-phosphate, fructose, and products of pyruvate (lactate and alanine), suggesting a role for IR in the upregulation of cytosolic aerobic glycolysis

Lactate can activate latent TGF-

lactate stimulates cell migration and enhances secretion of hyaluronan from CAF that promote tumour metastasis

promote tumour survival, growth, invasion, and metastasis; enhance the stiffness of the ECM; contribute to angiogenesis; and induce inflammation by releasing several growth factors and cytokines (TGF-β, VEGF, hepatocyte growth factor [HGF], PDGF, and stromal cell-derived factor 1 [SDF1]), as well as MMP

tumours recruit the host tissue’s blood vessel network to perform four mechanisms: angiogenesis (formation of new vessels), vasculogenesis (de novo formation of blood vessels from endothelial precursor cells), co-option, and modification of existing vessels within tissues.

immunosuppressive cells such as tumour-associated macrophages (TAM), MDSCs, and regulatory T cells, and the immunosuppressive cytokines, TGF-β and interleukin-10 (IL-10)

immunosuppressive cells such as tumour-associated macrophages (TAM), MDSCs, and regulatory T cells, and the immunosuppressive cytokines, TGF-β and interleukin-10 (IL-10)

intrinsic immunogenicity or induce tolerance

cancer immunoediting’

three phases: 1) elimination, 2) equilibrium, and 3) escape.

The third phase, tumour escape, is mediated by antigen loss, immunosuppressive cells (TAM, MDSCs, and regulatory T cells), and immunosuppressive cytokines (TGF-β and IL-10).

IR can elicit various changes in the TME, such as CAF activity-mediated ECM remodelling and fibrosis, cycling hypoxia, and an inflammatory response

IR activates CAFs to promote the release of growth factors and ECM modulators, including TGF-β and MMP

TGF-β directly influences tumour cells and CAFs, promotes tumour immune escape, and activates HIF-1 signalling

MMPs degrade ECM that facilitates angiogenesis, tumour cell invasion, and metastasis

IR also promotes MMP-2/9 activation in cancer cells to promote EMT, invasion, and metastasis

IR-induced Snail increases MMP-2 expression to promote EMT

Radiotherapy has the paradoxical side-effect of increasing tumour aggressiveness

IR promotes ROS production in cancer cells, which may induce the activation of oncogenes and the inactivation of tumour suppressors, which further promote oncogenic metabolism

Metabolic alterations

oncogenic metabolism

elicit various changes in the TME

Although IR activates an antitumour immune response, this signalling is frequently suppressed by tumour escape mechanisms