Technical articles

Composition, Activation Mechanisms, and Biological Effects of the AKT Pathway

The AKT pathway is one of the most central signaling networks governing cell growth, metabolism, survival, and stress adaptation. Its research value does not lie in explaining a single phosphorylation event in isolation, but in revealing how cells integrate receptor tyrosine kinases, PI3K, lipid second messengers, protein kinase cascades, and metabolic regulation into unified biological outputs. Aberrant activation or suppression of the AKT pathway can simultaneously affect tumorigenesis, insulin responsiveness, cardiovascular homeostasis, neurodevelopment, and drug resistance.

 

Keywords: AKT; PKB; PI3K; PTEN; PDK1; mTORC2; FOXO; GSK3; cell survival; metabolic regulation

 

1 Basic Framework of the AKT Pathway

1.1 Pathway Positioning

(1) Core functional position

The AKT pathway is positioned between receptor-proximal signaling and terminal cellular functions, serving as a major hub that links growth factor stimulation, nutrient status, energy sensing, and transcriptional regulation.

(2) Types of upstream inputs

The most typical upstream inputs of the AKT pathway include receptor tyrosine kinases, the insulin receptor, IGF receptors, selected G protein-coupled receptors, and integrin-associated signaling. Although these upstream stimuli originate from different entry points, most ultimately converge on the PI3K-PIP3 module to drive AKT activation.

(3) Scope of downstream outputs

AKT does not regulate cell survival alone. Its downstream outputs also include mTORC1 activation, glucose metabolism, protein synthesis, cell cycle progression, inhibition of transcription factors, cell migration, and anti-apoptotic programs.

 

1.2 Core Components

(1) Lipid signaling layer

PI3K converts the membrane lipid PIP2 into PIP3, and PIP3 serves as the key lipid second messenger that recruits AKT to the plasma membrane.

(2) Kinase layer

AKT itself is not a receptor-proximal kinase. Instead, after PIP3-mediated membrane recruitment, it is activated through phosphorylation at key sites by PDK1 and mTORC2.

(3) Negative regulatory layer

PTEN, SHIP, PP2A, and PHLPP together constitute the negative regulatory network of the AKT pathway and restrict both signaling duration and intensity.

 

2 Structure and Isoforms of AKT

2.1 Molecular Structure

(1) PH domain

The N-terminus of AKT contains a PH domain that specifically recognizes PIP3 or related phospholipids, thereby allowing AKT to be recruited to the plasma membrane upon pathway activation.

(2) Kinase domain

The central region is a serine/threonine kinase domain responsible for phosphorylation of downstream substrates and represents the catalytic core of AKT.

(3) Regulatory tail

The C-terminal regulatory region contains key phosphorylation sites, among which Ser473 is particularly important for full activation of AKT.

 

2.2 Isoform Composition

(1) AKT1

AKT1 is most closely associated with cell growth, proliferation, and general survival support, and is the isoform most frequently discussed in tumor biology.

(2) AKT2

AKT2 is more closely linked to metabolic regulation, especially insulin signaling, glucose uptake, and lipid metabolism, and therefore carries greater methodological weight in metabolic disease research.

(3) AKT3

AKT3 is more commonly associated with nervous system development, brain growth, and selected tumor types.


Table 1. Major Functional Biases of AKT Isoforms

 

Isoform

Major functional bias

Common research settings

AKT1

Growth, proliferation, survival

Tumors, cell cycle, drug resistance

AKT2

Metabolism, insulin response, glucose uptake

Glucose metabolism, lipid metabolism, insulin resistance

AKT3

Neurodevelopment, brain-related regulation

Nervous system development, brain tumors

 

3 Classical Activation Mechanism of the AKT Pathway

3.1 Receptor-Proximal Activation

(1) Initiation by receptor tyrosine kinases

After ligands such as insulin, IGF, EGF, and PDGF bind to their receptors, receptor autophosphorylation occurs and adaptor proteins such as IRS and Gab are recruited, thereby providing a docking platform for PI3K.

(2) PI3K activation

Following recruitment to the membrane, Class I PI3K converts PIP2 into PIP3. Enrichment of PIP3 on the inner leaflet of the plasma membrane is one of the decisive events that drives the AKT pathway into an activated state.

 

3.2 Membrane Recruitment of AKT and Dual-Site Phosphorylation

(1) Membrane recruitment process

AKT recognizes PIP3 through its PH domain and translocates from the cytosol to the plasma membrane, a step that brings AKT into spatial proximity with its upstream activating kinases.

(2) Phosphorylation at Thr308

PDK1 phosphorylates Thr308 within the activation loop of AKT, and this is the key step by which AKT acquires catalytic activity.

(3) Phosphorylation at Ser473

mTORC2 generally mediates phosphorylation of AKT at Ser473. This modification enhances the completeness of the AKT substrate spectrum and the overall activation level. In most cases, concurrent phosphorylation at Thr308 and Ser473 is a more reliable indicator of full AKT activation.

 

3.3 Spatial Translocation After Activation

(1) Transfer from membrane to cytosol

After activation at the membrane, AKT can leave the membrane compartment and phosphorylate multiple cytosolic substrates related to metabolism and survival.

(2) Nuclear translocation

A portion of activated AKT can enter the nucleus and regulate transcription factors such as FOXO as well as nuclear substrates associated with cell cycle control.

 

4 Negative Regulatory Mechanisms of the AKT Pathway

4.1 Negative Regulation at the Lipid Level

(1) PTEN

PTEN dephosphorylates PIP3 back to PIP2 and is one of the most central negative regulators of the AKT pathway. Loss of PTEN can lead to PIP3 accumulation and sustained AKT activation.

(2) SHIP family

SHIP phosphatases dephosphorylate PIP3 at different positions, thereby regulating the persistence of PIP3 signaling and cell type-specific responses.

 

4.2 Negative Regulation at the Protein Level

(1) PP2A

PP2A can dephosphorylate AKT and some of its downstream substrates, thereby reducing pathway strength.

(2) PHLPP

PHLPP directly dephosphorylates AKT at Ser473 and is an important protein phosphatase that limits full AKT activation.

 

4.3 Feedback Inhibition

(1) mTORC1-S6K negative feedback

Following AKT-mediated activation of mTORC1, S6K can impose negative feedback on IRS proteins, thereby weakening upstream insulin/IGF input. This feedback loop is easily overlooked in AKT pathway studies but is highly important.

(2) Drug-induced feedback remodeling

When mTORC1 is inhibited, the above negative feedback is attenuated, which may instead cause reactivation of upstream AKT signaling. Accordingly, inhibition of the downstream branch alone does not always suppress the entire pathway.

 

5 Major Downstream Modules of the AKT Pathway

5.1 mTORC1 Axis

(1) Inhibition of TSC2

AKT can phosphorylate TSC2, thereby relieving its inhibitory effect on the Rheb-mTORC1 axis and promoting protein synthesis and cell growth.

(2) Enhancement of protein translation

Activation of S6K and 4E-BP1 downstream of mTORC1 enhances ribosome biogenesis and mRNA translation efficiency, thereby supporting increases in cell size and anabolic activity.

 

5.2 GSK3 Axis

(1) Inhibition of GSK3

Phosphorylation of GSK3α/β by AKT suppresses its activity and thereby affects glycogen synthesis, cell cycle regulation, and selected transcriptional programs.

(2) Effects on metabolism and differentiation

Following GSK3 inhibition, cells can enhance glycogen synthesis and alter differentiation-related signaling outputs.

 

5.3 FOXO Axis

(1) Nuclear export of FOXO

After AKT phosphorylates FOXO family transcription factors, FOXO is translocated from the nucleus to the cytoplasm and loses transcriptional activity.

(2) Biological consequences

This process reduces expression of genes involved in cell cycle inhibition, antioxidant responses, and apoptosis promotion. Accordingly, AKT activation is commonly accompanied by enhanced cell survival and altered stress thresholds.

 

5.4 Apoptosis-Regulatory Axis

(1) Phosphorylation of BAD

AKT can weaken the pro-apoptotic activity of BAD through phosphorylation, thereby increasing cellular tolerance to death-inducing stimuli.

(2) Indirect suppression of the caspase program

AKT does not directly block all caspases, but it globally increases the anti-apoptotic background by regulating BAD, FOXO, and mTOR-associated networks.

 

5.5 Metabolic Axis

(1) GLUT4 translocation

In the insulin response, AKT promotes GLUT4 translocation through substrates such as AS160/TBC1D4, thereby enhancing glucose uptake.

(2) Integration of glucose and lipid metabolism

AKT also influences glycogen synthesis, lipid synthesis, and suppression of hepatic gluconeogenesis, making it a key node in metabolic homeostasis.


Table 2. Major Downstream Modules and Functional Outputs of AKT

 

Downstream module

Key substrates/nodes

Major outputs

mTORC1 axis

TSC2, S6K, 4E-BP1

Protein synthesis, cell growth

GSK3 axis

GSK3α/β

Glycogen metabolism, regulation of cell cycle and differentiation

FOXO axis

FOXO1/3/4

Enhanced survival, transcriptional suppression

Anti-apoptotic axis

BAD and others

Increased cell death threshold

Glucose metabolism axis

AS160/GLUT4

Enhanced glucose uptake

 

6 Biological Functions of the AKT Pathway

6.1 Cell Growth and Proliferation

(1) Control of cell size

Through mTORC1, AKT enhances protein synthesis and biosynthetic metabolism and is therefore an important upstream driver of cell size increase and growth program progression.

(2) Cell cycle progression

AKT promotes the transition from growth arrest to proliferation by suppressing programs associated with cell cycle inhibitory factors.

 

6.2 Cell Survival and Stress Adaptation

(1) Anti-apoptotic support

After AKT activation, cells show increased tolerance to nutrient deprivation, oxidative stress, and certain pro-apoptotic stimuli.

(2) Regulation of stress thresholds

AKT does not simply increase survival in all contexts. Rather, it jointly alters cellular stress response patterns through coordinated regulation of transcription, metabolism, and translation.

 

6.3 Metabolic Regulation

(1) Insulin response

In liver, skeletal muscle, and adipose tissue, AKT is one of the most central effector kinases in insulin signaling.

(2) Anabolic bias

AKT activation is generally accompanied by enhanced glucose utilization, increased glycogen synthesis, and reprogramming of lipid synthesis.

 

6.4 Migration and Invasion

(1) Cytoskeletal regulation

AKT can influence cytoskeletal remodeling and adhesion status through multiple downstream branches.

(2) Significance in pathological remodeling

In tumors and injury repair, the AKT pathway commonly participates in cell migration, invasion, and tissue remodeling.

 

7 AKT Pathway and Disease

7.1 Tumors

(1) Sustained pathway activation

PIK3CA mutation, PTEN loss, and excessive RTK activation can all result in persistent AKT hyperactivation and represent major molecular features in multiple solid tumors and hematologic malignancies.

(2) Drug resistance and survival advantage

High AKT activity can enhance tumor cell survival, metabolic adaptation, and therapeutic tolerance, and therefore also constitutes an important background for resistance to targeted therapies and chemotherapy.

 

7.2 Metabolic Diseases

(1) Insulin resistance

Insufficient AKT pathway responsiveness impairs glucose uptake and metabolic regulation and is one of the major mechanistic layers underlying insulin resistance.

(2) Lipid metabolic disorders

AKT abnormalities can also affect adipogenesis, hepatic lipid accumulation, and systemic metabolic reprogramming.

 

7.3 Cardiovascular and Nervous System Disorders

(1) Cardiomyocyte survival and stress responses

AKT plays important roles in cardioprotection during ischemia, vascular endothelial function, and cardiac compensation.

(2) Neurodevelopment and neuroprotection

AKT3 is particularly associated with brain development, while overall AKT signaling also contributes to neuronal survival and post-injury adaptation.

 

8 Experimental Investigation and Interpretation of the AKT Pathway

8.1 Common Readouts

(1) Upstream-layer indicators

PI3K activation, PIP3 levels, RTK phosphorylation, and IRS status can be used to determine whether upstream AKT input has been triggered.

(2) Indicators of intrinsic AKT activation

p-AKT Thr308 and p-AKT Ser473 are the most commonly used indicators of AKT activation. In most cases, combined observation of both sites is more informative than analysis of a single site alone.

(3) Downstream functional indicators

p-GSK3β, p-FOXO, p-S6K, p-4E-BP1, and GLUT4 translocation can serve as functional readouts at different output levels.

 

8.2 Common Experimental Strategies

(1) Growth factor stimulation models

Rapid AKT activation models can be established by stimulating cells with insulin, IGF-1, or EGF.

(2) Inhibitors and genetic interventions

PI3K inhibitors, AKT inhibitors, mTOR inhibitors, or PTEN overexpression/knockdown can be used to dissect hierarchical relationships within the pathway.

(3) Time-course analysis

The AKT pathway displays marked time dependence. Early responses are mainly reflected by AKT phosphorylation itself, whereas later phases gradually transition to transcriptional and functional outputs.

 

8.3 Common Biases in Result Interpretation

(1) Equating isolated elevation of Ser473 with full AKT activation

An increase in Ser473 does not always indicate complete enhancement of overall AKT function, and interpretation still requires consideration of Thr308 and downstream substrates.

(2) Simplifying AKT activation as equivalent to mTORC1 output

AKT and mTORC1 are closely related, but they are not always fully synchronous. Under some conditions, AKT activation is obvious while mTORC1 output is limited, or vice versa.

(3) Neglecting feedback regulation

If only a single time point is examined, AKT reactivation after feedback remodeling can easily be misinterpreted as drug failure or as an abnormal model phenotype.


Table 3. Key Readouts for Experimental Analysis of the AKT Pathway

 

Observation level

Common indicators

Methodological significance

Upstream input layer

RTK, IRS, PI3K, PIP3

Determines whether receptor-proximal activation has occurred

AKT intrinsic layer

p-AKT Thr308, p-AKT Ser473

Determines whether AKT has entered an activated state

Metabolic output layer

p-AS160, GLUT4, glycogen synthesis

Determines metabolic effects

Growth output layer

p-S6K, p-4E-BP1, mTORC1

Determines anabolic growth programs

Transcription/survival layer

p-FOXO, p-GSK3, BAD

Determines survival and transcriptional regulatory outcomes

 

9 Product Tables Related to the AKT Pathway

Table 4. Small-Molecule Modulator Product Table for the AKT Pathway

 

Product type

Catalog No.

Name

CAS No.

Grade and Purity

Suitable research direction/use

AKT inhibitor

A655285

(E)-Akt inhibitor-IV

959841-49-7

10mM in DMSO

Suitable for AKT pathway inhibition and functional blockade studies

AKT inhibitor

A648083

(E)-Akt inhibitor-IV

959841-49-7

≥99%

Suitable for AKT pathway inhibition studies

AKT inhibitor

B274636

3-BrB-PP1

956025-99-3

 

Suitable for small-molecule AKT inhibition studies

AKT1/2 inhibitor

C169278

3CAI

28755-03-5

≥95%(HPLC)

Suitable for inhibition studies of AKT1/AKT2 branches

AKT inhibitor

A126060

A-443654

552325-16-3

Moligand™, ≥98%

Suitable for AKT inhibition and pathway function validation

AKT kinase inhibitor

A648039

AKT Kinase Inhibitor

842148-40-7

≥99%

Suitable for studies on inhibition of AKT kinase activity

AKT kinase inhibitor

A655267

AKT Kinase Inhibitor

842148-40-7

10mM in DMSO

Suitable for AKT kinase inhibition experiments

AKT kinase inhibitor

A1493542

AKT Kinase Inhibitor hydrochloride

3026697-00-4

Moligand™, 10 mM in DMSO

Suitable for AKT kinase inhibition experiments

AKT kinase inhibitor

A1448469

AKT Kinase Inhibitor hydrochloride

3026697-00-4

≥99%

Suitable for AKT kinase inhibition studies

AKT inhibitor

A1498745

AKT-IN-1

1357158-81-6

Moligand™, 10 mM in DMSO

Suitable for AKT pathway inhibition studies

AKT inhibitor

A1447169

AKT-IN-2

1295514-91-8

 

Suitable for AKT pathway inhibition studies

AKT inhibitor

A647070

AKT-IN-3

2374740-21-1

≥99%

Suitable for AKT pathway inhibition studies

AKT inhibitor

A1495772

AKT-IN-3

2374740-21-1

Moligand™, 10 mM in DMSO

Suitable for AKT pathway inhibition experiments

AKT inhibitor

A1498961

AKT-IN-6

1430056-54-4

Moligand™, 10 mM in DMSO

Suitable for AKT pathway inhibition studies

AKT inhibitor

A425076

AKT Inhibitor VIII

612847-09-3

Moligand™, 10mM in DMSO

Suitable for AKT pathway inhibition experiments

AKT inhibitor

B304138

AKT Inhibitor VIII

612847-09-3

Moligand™, ≥97%

Suitable for AKT pathway inhibition studies

Akt/PKB inhibitor

A287100

API-1

36707-00-3

≥96%(HPLC)

Suitable for Akt/PKB inhibition studies

Pan-AKT inhibitor

A128036

AZD5363

1143532-39-1

Moligand™, ≥98%

Suitable for global inhibition of AKT1/2/3

Akt1 translocation inhibitor

C276237

CAY10567

32387-96-5

Moligand™, ≥98%

Suitable for studies on Akt1 membrane translocation

AKT2 inhibitor

C127073

CCT128930

885499-61-6

≥98%

Suitable for AKT2-specific inhibition studies

Akt1/2/3 inhibitor

G127588

GDC-0068

1001264-89-6

Moligand™, ≥98%

Suitable for inhibition studies across all AKT isoforms

Pan-Akt kinase inhibitor

G127527

GSK-690693

937174-76-0

Moligand™, ≥98%

Suitable for global inhibition studies of the AKT pathway

AKT inhibitor

I174181

INCB-047775

1430056-54-4

≥97%

Suitable for AKT inhibition studies

Akt allosteric inhibitor

M275392

Miransertib

1313881-70-7

Moligand™, ≥98%

Suitable for allosteric inhibition studies of AKT

PDK1/Akt/Flt dual-pathway inhibitor

P335686

PDK1/Akt/Flt Dual Pathway inhibitor

331253-86-2

Moligand™

Suitable for studies on PDK1-coupled upstream regulation of AKT

AKT inhibitor

P650945

PF-AKT400

1004990-28-6

≥98%

Suitable for AKT inhibition studies

AKT inhibitor

P656474

PF-AKT400

1004990-28-6

10mM in DMSO

Suitable for AKT inhibition experiments

Dual Akt and PDK1 inhibitor

P127286

PHT-427

1191951-57-1

Moligand™, ≥98%

Suitable for studies on the PI3K/PDK1/AKT axis

PI3K/AKT inhibitor

P659144

PI3K/AKT-IN-1

 

≥99%

Suitable for inhibition studies of the PI3K-AKT axis

PI3K/AKT inhibitor

P661661

PI3K/AKT-IN-1

 

10mM in DMSO

Suitable for inhibition experiments of the PI3K-AKT axis

PI3K/AKT inhibitor

P1420619

PI3K/AKT-IN-2

2684412-41-5

≥98%

Suitable for inhibition studies of the PI3K-AKT axis

PI3K/AKT inhibitor

P1497398

PI3K/AKT-IN-2

2684412-41-5

Moligand™, 10 mM in DMSO

Suitable for inhibition experiments of the PI3K-AKT axis

PI3K/Akt/CREB activator

P656344

PI3K/Akt/CREB activator 1

2708177-73-3

10mM in DMSO

Suitable for PI3K-AKT activation studies

PI3K/Akt/CREB activator

P650618

PI3K/Akt/CREB activator 1

2708177-73-3

≥99%

Suitable for PI3K-AKT activation studies

PI3K/Akt/mTOR inhibitor

P646779

PI3K/Akt/mTOR-IN-2

2757804-89-8

≥99%

Suitable for combined inhibition studies of the PI3K-AKT-mTOR axis

PI3K/Akt/mTOR inhibitor

P654740

PI3K/Akt/mTOR-IN-2

2757804-89-8

10mM in DMSO

Suitable for combined inhibition experiments of the PI3K-AKT-mTOR axis

Akt inhibitor

P124979

Perifosine (KRX-0401)

157716-52-4

Moligand™, ≥99%

Suitable for AKT inhibition and membrane localization interference studies

Akt activator

S275934

SC79

305834-79-1

≥98%

Suitable for AKT pathway activation studies

Specific Akt inhibitor

S275226

SH-5

701976-54-7

≥98%

Suitable for AKT-specific inhibition studies

PI3K/Akt activator

Y125277

YS-49

132836-42-1

≥98%

Suitable for activation studies of the PI3K-AKT axis

 

Table 5. Antibody, Recombinant Protein, and Readout Product Table for the AKT Pathway

 

Product type

Catalog No.

Name

Grade and Purity

Suitable research direction/use

p-AKT antibody

Ab087899

AKT(phospho S473) Antibody

Validated, ExactAb™, See COA

Suitable for detection of AKT Ser473 phosphorylation, a core readout of AKT activation

AKT1 antibody

Ab087937

AKT1 Mouse mAb

ExactAb™, Validated, Carrier Free, 1.0mg/mL

Suitable for AKT1 protein detection

AKT2 antibody

Ab183882

AKT2 Mouse mAb

Animal Free,Carrier Free,ExactAb™,Azide Free,Validated,PBS Only,≥95%(SDS-PAGE),0.5 mg/mL

Suitable for AKT2 protein detection

Pan-AKT1/2/3 antibody

Ab087925

Recombinant AKT1/AKT2/AKT3 Antibody

Recombinant,ExactAb™,Validated,See COA

Suitable for total AKT protein detection

AKT1 recombinant protein

rp183598

Recombinant Human AKT1 Protein

Carrier Free,His Tag,≥70%(SDS-PAGE),See COA

Suitable for AKT1 enzymology and functional studies

AKT1 recombinant protein

rp224961

Recombinant Human AKT1 Protein

Carrier Free,His Tag,≥70%(SDS-PAGE),See COA

Suitable for AKT1 enzymology and functional studies

AKT2 recombinant protein

rp183727

Recombinant Human AKT2 Protein

Carrier Free,His Tag,≥80%(SDS-PAGE)

Suitable for AKT2 enzymology and functional studies

AKT3 recombinant protein

rp184884

Recombinant Human AKT3 Protein

Carrier Free,His Tag,≥80%(SDS-PAGE),See COA

Suitable for AKT3 enzymology and functional studies

AKT substrate peptide

A409328

AKTide-2T TFA

≥98%

Suitable for AKT kinase activity assays

Akt substrate peptide

A287763

Akt/SKG Substrate Peptide TFA

≥98%

Suitable for AKT substrate phosphorylation assays

AKT protein ELISA

EJ1513410

Human AKT Protein (AKT) ELISA Kit

BioReagent

Suitable for quantitative detection of total human AKT protein

p-AKT ELISA

EJ1514437

Human Phosphorylated AKT Protein (p-AKT) ELISA Kit

BioReagent

Suitable for quantitative detection of human p-AKT

AKT2 ELISA

EJ1514808

Human Protein Kinase B Beta (PKBb/AKT2) ELISA Kit

BioReagent

Suitable for quantitative detection of human AKT2

AKT protein ELISA

EJ1511851

Rat AKT Protein (AKT) ELISA Kit

BioReagent

Suitable for quantitative detection of total rat AKT protein

AKT1 ELISA

EJ1512453

Mouse Protein Kinase B Alpha (AKT1) ELISA Kit

BioReagent

Suitable for quantitative detection of mouse AKT1

AKT protein ELISA

EJ1512454

Mouse AKT Protein (AKT) ELISA Kit

BioReagent

Suitable for quantitative detection of total mouse AKT protein

p-AKT ELISA

EJ1512962

Mouse Phosphorylated AKT Protein (p-AKT) ELISA Kit

BioReagent

Suitable for quantitative detection of mouse p-AKT

 

Table 6. Gene Intervention and Knockout Validation Product Table for the AKT Pathway

 

Product type

Catalog No.

Name

Grade and Purity

Suitable research direction/use

siRNA

A1462588

AKT1 Human Pre-designed siRNA Set A

 

Suitable for AKT1 gene silencing studies

siRNA

A1478576

AKT2 Human Pre-designed siRNA Set A

 

Suitable for AKT2 gene silencing studies

siRNA

A1479714

AKT3 Human Pre-designed siRNA Set A

 

Suitable for AKT3 gene silencing studies

siRNA

A1485204

Akt1 Mouse Pre-designed siRNA Set A

 

Suitable for mouse Akt1 gene silencing studies

siRNA

A1471926

Akt1 Rat Pre-designed siRNA Set A

 

Suitable for rat Akt1 gene silencing studies

siRNA

A1485370

Akt2 Mouse Pre-designed siRNA Set A

 

Suitable for mouse Akt2 gene silencing studies

siRNA

A1464812

Akt2 Rat Pre-designed siRNA Set A

 

Suitable for rat Akt2 gene silencing studies

siRNA

A1461415

Akt3 Mouse Pre-designed siRNA Set A

 

Suitable for mouse Akt3 gene silencing studies

siRNA

A1479206

Akt3 Rat Pre-designed siRNA Set A

 

Suitable for rat Akt3 gene silencing studies

Knockout validation lysate

P743723

pLenti-AKT1-sgRNA

 

Suitable for AKT1 knockout validation and protein detection controls

Knockout validation lysate

P743724

pLenti-AKT1-sgRNA

 

Suitable for AKT1 knockout validation and RNA detection controls

Knockout validation lysate

P743725

pLenti-AKT2-sgRNA

 

Suitable for AKT2 knockout validation and protein detection controls

Knockout validation lysate

P743726

pLenti-AKT2-sgRNA

 

Suitable for AKT2 knockout validation and RNA detection controls

Knockout validation lysate

P743727

pLenti-AKT3-sgRNA

 

Suitable for AKT3 knockout validation and protein detection controls

Knockout validation lysate

P743728

pLenti-AKT3-sgRNA

 

Suitable for AKT3 knockout validation and RNA detection controls

Recombinant AKT1 antibody

Ab325816

Recombinant AKT1 Antibody

KD Validation

Suitable for AKT1 protein detection and knockdown validation

Recombinant AKT1 antibody

Ab325647

Recombinant AKT1 Antibody

KO Validation

Suitable for AKT1 protein detection and knockout validation

 

The core significance of the AKT pathway lies in its ability to integrate receptor stimulation, lipid signaling, protein kinase cascades, and metabolic regulation into a unified cellular adaptation program. Its biological relevance is not limited to promoting survival, but extends to determining the overall state transitions of cells in growth, metabolism, stress, and disease contexts.

 

For more related articles, please see below:

[1] Ras-Raf-MEK-ERK Signaling

[2] Wnt/β-Catenin Signaling Pathway

[3] How to Map the NF-κB Pathway and Choose Inhibitors: Bringing Inflammatory Transcriptional Output into a “Controllable Range” (Tables A–F)

[4] Metabolic signaling pathway

[5] Wnt Signaling

[6] Hedgehog Signaling

[7] JAK-STAT Cell Signaling Pathway

[8] PD-1/PD-L1 Signaling Pathway

Categories: Technical articles

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Cite this article

Aladdin Scientific. "Composition, Activation Mechanisms, and Biological Effects of the AKT Pathway" Aladdin Knowledge Base, updated 28 abr 2026. https://www.aladdinsci.com/us_es/faqs/composition-activation-mechanisms-and-biological-effects-of-the-akt-pathway-en.html
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