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==Anaplastic Lymphoma Kinase Extracellular Region==
==Anaplastic Lymphoma Kinase Extracellular Region==
<StructureSection load='7N00' size='500' side='right' caption=' Structure of Anaplastic Lymphoma Kinase [https://www.rcsb.org/structure/7N00 7N00]' scene='90/904331/Alk_full/1'>
<StructureSection load='7N00' size='350' side='right' caption=' Structure of Anaplastic Lymphoma Kinase [https://www.rcsb.org/structure/7N00 7N00]' scene='90/904331/Alk_full/1'>
== Background ==
== Background ==
Anaplastic Lymphoma Kinase (ALK) is a [https://en.wikipedia.org/wiki/Transmembrane_protein transmembrane] receptor and a member of the family of [https://proteopedia.org/wiki/index.php/Receptor_tyrosine_kinases Receptor Tyrosine Kinases (RTKs)], a family of biomolecules that are primarily responsible for biosignaling pathways such as the insulin signaling pathway. It was discovered as a novel tyrosine phosphoprotein in 1994 in an analysis of [https://lymphoma.org/aboutlymphoma/nhl/alcl/ Anaplastic Large-Cell Lymphoma], the protein's namesake. A full analysis and characterization of ALK was completed in 1997, properly identifying it as a RTK, and linking it closely to [https://en.wikipedia.org/wiki/Leukocyte_receptor_tyrosine_kinase Leukocyte Tyrosine Kinase] (LTK).  
Anaplastic Lymphoma Kinase (ALK) is a [https://en.wikipedia.org/wiki/Transmembrane_protein transmembrane] receptor and a member of the family of [https://proteopedia.org/wiki/index.php/Receptor_tyrosine_kinases Receptor Tyrosine Kinases (RTKs)]<ref name="Iwahara">PMID:9053841</ref>. RTKs are a family of biomolecules that are primarily responsible for biosignaling pathways such as the insulin signaling pathway.<ref name="Huang" /> ALK was identified as a novel tyrosine phosphoprotein in 1994 in an analysis of [https://lymphoma.org/aboutlymphoma/nhl/alcl/ Anaplastic Large-Cell Lymphoma], the protein's namesake.<ref name ="Huang" /> A full analysis and characterization of ALK was completed in 1997, properly identifying it as an RTK, and linking it closely to [https://en.wikipedia.org/wiki/Leukocyte_receptor_tyrosine_kinase Leukocyte Tyrosine Kinase] (LTK).<ref name ="Huang" /> ALK's normal activity as a receptor tyrosine kinase is to transfer a gamma-phosphate group from adenosine triphosphate (ATP) to a tyrosine residue on its substrate.<ref name ="Huang" /> ALK is one of more than 50 RTKs encoded within the human genome, <ref name ="Huang" /> and its tyrosine kinase activity seems to be especially important in the developing nervous system. <ref name ="Huang" /> The ALK extracellular domain is becoming well characterized, as it is the primary binding site of ALK ligands that end up triggering the kinase activity, as ALK autophosphorylates itself.<ref name="Reshetnyak" /> There are four well-characterized domains on the ALK extracellular domain that are involved in binding the two main ligands of ALK.<ref name="Reshetnyak" /> ALK is most commonly associated with oncogenesis, as various factors, including overstimulation, lead to extreme cell proliferation.<ref name="Della Corte" /> It is primarily found in the fetal and infant developing nervous system, however when associated with cancer it can be found in systems other than the nervous system.<ref name="Carpenter" /> Examples of these include colon and prostate cancer, where ALK is not normally expressed.<ref name="Chen" /> This particular protein is interesting in part due to its unique structure, of that it shares the most similarity with LTKs and its association with devastating cancers.<ref name="DeMunck" />
== Structure ==
== Structure ==
As previously mentioned, ALK is a close homolog of LTK, and together these two homologous proteins create a subgroup within the superfamily of [https://proteopedia.org/wiki/index.php/Insulin_receptor insulin receptors] (IR). ALK is composed of 1620 amino acids in total, with three primary domains. ALK is described as showing the "classic structural features of RTKs, with an extracellular ligand-binding domain, a transmembrane-spanning region, and an intracellular kinase domain." As displayed in Figure 1,[[Image:ALK Structure Overview.PNG|300 px|right|thumb|Figure 1. Overview of Anaplastic Lymphoma Kinase Structure]] the intracellular tyrosine kinase domain ranges from residues 1116-1392, and features the [https://en.wikipedia.org/wiki/C-terminus C-terminal end]. The [https://en.wikipedia.org/wiki/Transmembrane_domain transmembrane helical domain] (TMH) bridges the gap between the intracellular and extracellular regions from residues 1039-1116. The final section of ALK is the extracellular region, which spans from residues 1025 to 1, and contains 8 domains. Of these 8 domains, two regions of the extracellular region can be found; one containing the ligand-binding site of the protein, and another lesser-known subregion. This lesser-known subregion contains 4 domains from residues 1-626; an [https://en.wikipedia.org/wiki/N-terminus N-terminal Region] (NTR), two [https://en.wikipedia.org/wiki/Meprin_A meprin–A-5] protein–receptor protein tyrosine phosphatase μ (MAM), and a [https://en.wikipedia.org/wiki/Low-density_lipoprotein low-density lipoprotein] receptor class A (LDL) domain sandwiched between the two MAM domains. The presence of an LDL domain sandwiched by two MAM domains is a unique feature that ALK does not share with other RTKs. The purpose behind this unique difference is still unclear. The ligand-binding extracellular subregion is the most well-characterized of the two subregions, containing 4 distinct domains from residues 673-1025; a triple helix bundle (THB) domain, a glycine-rich domain (GlyR) that is also referred to as the poly-Glycine domain, a tumor necrosis factor-like (TNF-like), and an epidermal growth factor-like domain (EGF-like). All four domains of this subregion of the extracellular region contribute to ligand-binding <ref name ="Huang" />
ALK is a close homolog of LTK, and together these two homologs constitute a subgroup within the superfamily of [https://proteopedia.org/wiki/index.php/Insulin_receptor insulin receptors]<ref name="Della Corte" />. ALK is composed of three primary regions: the extracellular region, the transmembrane region, and the intracellular region.<ref name="Reshetnyak" /> [[Image:Full ALK Structure Graphic.PNG|600 px|right|thumb|Figure 1. Overview of Anaplastic Lymphoma Kinase Structure with domains where known structures are color coordinated and other domains are grayed out. The abbreviations are as follows: NTR-N-terminal Region, MAM-Meprin-A-5 protein-receptor protein tyrosine phosphatase μ, LDL-low-density lipoprotein receptor class A, THB-three helix bundle-like, GlyR-poly-glycine region, TNF-tumor necrosis factor-like domain, EGF-epidermal growth factor-like, TMH-transmembrane helix]] The extracellular region of ALK contains 8 total domains within 2 fragments.<ref name="Reshetnyak" /> A Three Helix Bundle-like domain (THB-like), a Poly-Glycine domain (GlyR), a Tumor Necrosis Factor-like domain (TNF-like), and an Epidermal Growth Factor-like domain (EGF-like) make up the ligand binding fragment while an N-terminal domain, two [https://en.wikipedia.org/wiki/Meprin_A meprin–A-5] protein–receptor protein tyrosine phosphatase μ (MAM) domains and a [https://en.wikipedia.org/wiki/Low-density_lipoprotein low-density lipoprotein] receptor class A (LDL) domain sandwiched between the two MAM domains make up the second fragment.<ref name="Reshetnyak" /> All four domains of the ligand binding fragment of the extracellular region contribute to ligand-binding <ref name ="Huang" />. The presence of an LDL domain sandwiched by two MAM domains is a unique feature that ALK does not share with other RTKs. The purpose behind this unique difference is still unclear, but the MAM region has been hypothesized to play a role in cell-cell signaling<ref name="Palmer">PMID:19459784</ref>. The [https://en.wikipedia.org/wiki/Transmembrane_domain transmembrane helical region] (TMH) bridges the gap between the intracellular and extracellular regions.<ref name="Reshetnyak" /> The intracellular tyrosine kinase region features the Kinase domain and the C-terminal end (Figure 1). <ref name="Reshetnyak" />  
=== Domains ===
=== Known Extracellular Domains ===
==== Three Helix Bundle-like Domain ====
==== Three Helix Bundle-like Domain ====
The <scene name='90/904331/Thb_like_domain/1'>Three Helix Bundle-like Domain</scene> mainly has a structural function overall as it interacts with the tumor necrosis factor-like domain upon ligand binding. The three helix bundle-like domain's α-helix interacts with the helix α-1' and β strand A-1' on the Tumor Necrosis Factor-like domain. This outermost region of the extracellular ligand-binding domain undergoes rigorous structural reorientation upon ligand binding. THB is primarily involved in the dimerization motif of ALK, which dimerizes upon ligand binding. <ref name="Reshetnyak" />
The <scene name='90/904332/Thb-like_domain/1'>Three Helix Bundle-like Domain</scene> performs a structural function by interacting with the TNF-like domain upon ligand binding.<ref name="Reshetnyak" /> The THB-like domain's α-helix interacts with the helix α-1' and β strand A-1' on the TNF-like domain.<ref name="Reshetnyak" /> This outermost region of the extracellular ligand-binding domain undergoes substantial structural reorientation upon ligand binding.<ref name="Reshetnyak" /> The THB-like is primarily involved in the <scene name='90/904332/Thb-like_tnf-like_interface/1'>dimerization motif</scene> of ALK and interacts with the TNF-like domain, which causes dimerization of ALK. <ref name="Reshetnyak" />
''To return to Structure of ALK with ALKAL2 bound scene click here: <scene name='90/904331/Alk_full/1'>ALK bound to ALKAL2</scene>''
==== Poly-Glycine Domain ====
==== Poly-Glycine Domain ====
[[Image:Honeycomb.png|300 px|right|thumb|Figure 2. Rare Glycine helices on Anaplastic Lymphoma Kinase]]Located between the three helix bundle-like domain and the tumor necrosis factor-like domain, the <scene name='90/904331/Polyg_region1/1'>Poly-Glycine Region</scene> has an important structural role. The poly-Glycine domain also has a rare and unique structure of left-handed glycine helices with hexagonal hydrogen bonding shown in Figure 2. These 14 glycine helices are unique to ALK's function among other tyrosine kinases, as these types of structures on the binding domain are not present. These helices are rigid structures, providing a strong anchor for the ligand binding site while the other domains undergo drastic conformational rearrangements.<ref name="Reshetnyak" />
[[Image:glycinehelicesorange.png|300 px|right|thumb|Figure 2. Rare Glycine helices on Anaplastic Lymphoma Kinase; The structure of extracellular ALK is shown in a perpendicular, cross-sectional way, highlighted in orange. In black, hydrogen bonds are structured in a hexagonal-like way. Made using [https://www.rcsb.org/structure/7N00 7N00]]]Located between the THB-like domain and the TNF-like domain, the <scene name='90/904332/Glyr_domain/1'>Poly-Glycine Domain</scene> has an important structural role.<ref name="Reshetnyak" /> The GlyR domain also has a rare and unique structure of left-handed glycine helices with hexagonal hydrogen bonding (Figure 2).<ref name="Reshetnyak" /> These 14 glycine helices are unique to ALK's function among other tyrosine kinases.<ref name="Reshetnyak" /> These helices are rigid structures, providing a strong anchor for the ligand binding site while the other domains undergo conformational rearrangements.<ref name="Reshetnyak" />
''To return to Structure of ALK with ALKAL2 bound scene click here: <scene name='90/904331/Alk_full/1'>ALK bound to ALKAL2</scene>''
==== Tumor-Necrosis Factor-like Domain ====
==== Tumor-Necrosis Factor-like Domain ====
The <scene name='90/904331/Tnf_like_domain/1'>Tumor Necrosis Factor-like Domain</scene> interacts with the three helix bundle-like domain to begin the conformational changes associated with ligand binding. It is located in approximately the midregion of the extracellular region, bridging the gap between the poly-glycine domain and the epidermal growth factor-like domain. This domain also assists in mediating ligand binding with the epidermal growth factor-like domain. In ligand-binding, as previously stated, this domain interacts heavily with the THB to undergo critical conformation changes necessary for dimerization and ligand recognition. <ref name="Reshetnyak" />
The <scene name='90/904331/Tnf-like_domain/2'>Tumor Necrosis Factor-like Domain</scene> interacts with the THB-like domain to begin the conformational changes associated with ligand binding.<ref name="Reshetnyak" /> Located in approximately the mid-region of the extracellular region, the TNF-like domain bridges the gap between the GlyR domain and the EGF-like domain. The TNF-like domain also assists in mediating ligand binding with the EGF-like domain<ref name="Reshetnyak" /> by interacting with the THB-like domain to facilitate the critical conformation changes required for dimerization and ligand recognition.<ref name="Reshetnyak" />
''To return to Structure of ALK with ALKAL2 bound scene click here: <scene name='90/904331/Alk_full/1'>ALK bound to ALKAL2</scene>''
==== Epidermal Growth Factor-like Domain ====
==== Epidermal Growth Factor-like Domain ====
The <scene name='90/904331/Egf_like_domain/1'>Epidermal Growth Factor-like Domain</scene> is very malleable and repositioning of this domain is essential for activation of the protein. This domain is able to undergo conformational changes with the ligand bound and when in contact with the tumor necrosis factor-like domain. The interface between the EGF-like and TNF-like domains are primarily hydrophobic residues, which enable their flexibility with regards to one another. The main motifs that are apart of the EGF-like domain are major and minor β-hairpins, which are stabilized by 3 conserved disulfide bridges. <ref name="Reshetnyak" />
Unlike the poly-Glycine helices, the <scene name='90/904331/Egf_like_domain/3'>Epidermal Growth Factor-like Domain</scene> is malleable and repositioning of this domain is essential for activation of the protein.<ref name="Reshetnyak" /> This domain undergoes conformational changes upon ligand binding and when in contact with the TNF-like domain.<ref name="Reshetnyak" /> The <scene name='90/904332/Tnf_egf_interface/3'>interface between the EGF-like and TNF-like domains</scene> consists of primarily hydrophobic residues, which enables their flexibility with regards to one another.<ref name="Reshetnyak" /> The EGF-like domain is essential in binding, and thus this ability of the EGF-like to be very malleable in its interactions with the TNF-like domain is important. <ref name="Reshetnyak" /> Without these interactions, ligand binding does not occur. <ref name="Reshetnyak" />  Hydrogen bonding occurs mostly between residues on the TNF-like domain.<ref name="Reshetnyak" /> There is only one hydrogen bond between the domains that are between residues Y734 on the TNF-like interface and Y984 on the EGF-interface.<ref name="Reshetnyak" /> Major motifs in the EGF-like domain are major and minor β-hairpins, which are stabilized by 3 conserved disulfide bridges. <ref name="Reshetnyak" /> The major β-hairpins in the EGF-like domain interact with the ALKAL2 helices after ALKAL2 binding <ref name="Reshetnyak" />.
=== Binding Site ===
''To return to Structure of ALK with ALKAL2 bound scene click here: <scene name='90/904331/Alk_full/1'>ALK bound to ALKAL2</scene>''
This site doesn't start out surrounding the [https://en.wikipedia.org/wiki/Ligand_(biochemistry) ligand], instead the proximity of the ligand allows [https://en.wikipedia.org/wiki/Conformational_change conformational changes] across the protein. The ligands for ALK both have highly positively charged faces that interact with the TNF-like region, the primary ligand-binding site on the extracellular region<ref name="Li" />. [https://en.wikipedia.org/wiki/Salt_bridge_(protein_and_supramolecular) Salt bridges] between the positively charged residues on the ligand and negatively charged residues on the receptor form are formed as the ligand approaches connecting the ligand with the receptor. These strong ionic interactions allow the drastic conformational changes in the extracellular domain that induce the signaling pathway. <ref name="Reshetnyak" />
== Extracellular Domain Binding ==
=== Ligands ===
=== Ligands ===
The extracellular ligands of Anaplastic Lymphoma Kinase are ALKAL2 and ALKAL1.  
The extracellular ligands of ALK are Anaplastic Lymphoma Kinase Ligand 2 (ALKAL 2) and Anaplastic Lymphoma Kinase Ligand 1 (ALKAL 1) which are polypeptides of 76 and 70 lengths respectively.  
==== ALKAL2 ====
==== ALKAL2 ====
ALKAL2 (Anaplastic Lymphoma Kinase Ligand 2) is a ligand of ALK as well as LTK located in the extracellular region. The full-length ALKAL2 (dimeric) and ALKAL2-AD (monomeric) can both induce dimerization of ALK <ref name="Reshetnyak">PMID:34819673</ref>. Structurally, ALKAL2 has a N-termical variable region and a conserved augmentor domain and tends to aggregate in the cell <ref name="Reshetnyak" />. Overexpression of ALKAL2 has been linked to high-risk [https://en.wikipedia.org/wiki/Neuroblastoma neuroblastoma] in absence of an ALK mutation <ref name="Borenas">PMID:33411331</ref> and could potentially have therapeutic opportunities.  
<scene name='90/904331/Alkal2/3'>ALKAL2</scene> is a shared ligand of ALK and LTK. Dimeric ALKAL2 and monomeric ALKAL2-AD both induce dimerization of ALK <ref name="Reshetnyak">PMID:34819673</ref>. Structurally, ALKAL2 has an N-terminal variable region, a conserved augmentor domain, and tends to aggregate in the cell <ref name="Reshetnyak" />. ALKAL2, as it binds as a dimer, contains a higher potency of binding to the ALK receptor than the other primary ligand, ALKAL1.<ref name="Reshetnyak2" /> Overexpression of ALKAL2 is linked to high-risk [https://en.wikipedia.org/wiki/Neuroblastoma neuroblastoma] in absence of an ALK mutation <ref name="Borenas">PMID:33411331</ref>.
''To return to Structure of ALK with ALKAL2 bound scene click here: <scene name='90/904331/Alk_full/1'>ALK bound to ALKAL2</scene>''
==== ALKAL1 ====
==== ALKAL1 ====
ALKAL1 (Anaplastic Lymphoma Kinase Ligand 1) is a monomeric ligand of ALK, in addition to ALKAL2. Structurally, ALKAL1 and ALKAL2 contain an N-terminal variable region and a conversed C-terminal augmentor domain <ref name="Reshetnyak" />. However, in ALKAL1, this N-terminal variable region is shorter, and shares no similar sequences to ALKAL2. Nevertheless, ALKAL1 shares a 91% sequence similarity with ALKAL2. Both ligands include a three helix bundle domain in their structures, with an extended positively charged surface which is used in ligand binding <ref name="Reshetnyak" />.
<scene name='90/904331/Alkal1/5'>ALKAL1</scene> is a monomeric ligand of ALK. Structurally, ALKAL1 shares the same architecture as ALKAL2 with an N-terminal variable region and a conserved C-terminal augmentor domain <ref name="Reshetnyak" />. However, in ALKAL1, the N-terminal variable region is shorter and has limited sequence similarity to ALKAL2. Overall, ALKAL1 still shares 91% sequence similarity with ALKAL2. Both ligands include a three helix bundle domain in their structures, with an extended positively charged surface for ligand binding to the TNF-like domain<ref name="Reshetnyak" />. ALKAL1 as a monomer, however, binds to ALK with poor stability<ref name ="Chen">PMID:33391411</ref> and was only found to stimulate ALK dimerization at much higher concentrations than ALKAL2.<ref name="Reshetnyak2">PMID:26630010</ref>
=== Dimerization of Anaplastic Lymphoma Kinase ===
''To return to Structure of ALK with ALKAL2 bound scene click here: <scene name='90/904331/Alk_full/1'>ALK bound to ALKAL2</scene>''
After binding to one of its ligands, Anaplastic Lymphoma Kinase undergoes <scene name='90/904331/Alk_full_dimerization/1'>ligand-induced dimerization</scene> <ref name="Huang">PMID:30400214</ref>. The [https://en.wikipedia.org/wiki/Dimer_(chemistry) dimerization] causes trans-phosphorylation of specific [https://en.wikipedia.org/wiki/Tyrosine tyrosine] residues which in turn amplifies the signal. It has been presumed that the [https://en.wikipedia.org/wiki/Phosphorylation_cascade phosphorylation cascade] activates ALK kinase activity <ref name="Huang" />.
=== Binding Site ===
The binding site is located in the TNF-like region. <ref name="DeMunck">PMID:34646012</ref> This site doesn't start out surrounding the [https://en.wikipedia.org/wiki/Ligand_(biochemistry) ligand], instead the ligand binding initiates [https://en.wikipedia.org/wiki/Conformational_change conformational changes] across the extracellular region of the protein. The ligands for ALK have highly positively charged faces that interact with the TNF-like region, the primary ligand-binding site on the extracellular region<ref name="Li" />. [https://en.wikipedia.org/wiki/Salt_bridge_(protein_and_supramolecular) Salt bridges] between the positively charged residues on the ligand and negatively charged residues on the receptor are stabilized by ligand binding. Three of these <scene name='90/904331/Salt_bridge_overview/1'>salt bridges</scene> occur between <scene name='90/904331/Salt_bridge_859_140/3'>E859 and R140</scene>, <scene name='90/904331/Salt_bridge_974_136/4'>E974 and R136</scene>, and <scene name='90/904331/Salt_bridge_978_123_133/3'>E978 with both R123 and R133</scene>. These strong ionic interactions also induce the conformational changes in the extracellular domain that induce the signaling pathway which include an 80-degree bending of the TNF-like and GlyR domains toward the membrane with the link acting as a hinge and a 160-degree rotation across the z-axis across the TNF-like and GlyR domains. <ref name="Reshetnyak" />  
''To return to Structure of ALK with ALKAL2 bound scene click here: <scene name='90/904331/Alk_full/1'>ALK bound to ALKAL2</scene>''
=== Dimerization of ALK ===
After binding to one of its ligands, ALK undergoes <scene name='90/904331/Alk_full_dimerization/3'>ligand-induced dimerization</scene> <ref name="Huang">PMID:30400214</ref>. <scene name='90/904332/Thb-like_tnf-like_interface/1'>ALK receptor dimerization</scene> is mediated mostly by weak Van der Waals interactions and main chain hydrogen bonding between the TNF-like domain on one monomer and the THB-like domain on the other. <ref name ="Reshetnyak" /> The [https://en.wikipedia.org/wiki/Dimer_(chemistry) dimerization] causes trans-phosphorylation of specific [https://en.wikipedia.org/wiki/Tyrosine tyrosine] residues located in the extracellular region in the activation loop which in turn transmits a signal downstream<ref name="Huang" />. It has been presumed that the [https://en.wikipedia.org/wiki/Phosphorylation_cascade phosphorylation cascade] activates ALK kinase activity <ref name="Huang" />.
== Function ==
== Function ==
Anaplastic Lymphoma Kinase plays a role in [https://en.wikipedia.org/wiki/Cell_signaling cellular communication] and in the normal development and function of the [https://en.wikipedia.org/wiki/Nervous_system nervous system] It is present largely in the developing nervous system of a fetus and newborn, and overtime the expression of ALK dwindles with age. In addition to being expressed heavily in the brain, ALK has been shown to be present in the small intestine, testis, prostate, and colon <ref name="Della Corte">PMID:29455642</ref>.  
ALK plays a role in [https://en.wikipedia.org/wiki/Cell_signaling cellular communication] and in the normal development and function of the [https://en.wikipedia.org/wiki/Nervous_system nervous system]<ref name ="Huang" />. ALK is present in the developing nervous system of a fetus and newborn. ALK expression dwindles with age.<ref name ="Huang" /> In addition to being heavily expressed in the brain, ALK is present in the small intestine, testis, prostate, and colon <ref name="Della Corte">PMID:29455642</ref>.  
== Disease and Medical Relevance ==
== Disease and Medical Relevance ==
=== Cancer ===
=== Cancer ===
In ALK fusion proteins, the ALK fusion partner may cause dimerization independent of ligand binding, causing oncogenic ALK activation <ref name="Huang" />.  
In ALK [https://en.wikipedia.org/wiki/Fusion_protein fusion proteins], the ALK fusion partner may cause dimerization independent of ligand binding, leading to oncogenic ALK activation <ref name="Huang" />.  
The regulation of ALK dimerization by ALKAL points to clear ways to inhibit ALK activity and may offer new therapeutic strategies in multiple disease settings <ref name="Li">PMID:34819665</ref>. Studies have shown that approximately 70-80% of all patients who have Anaplastic Large Cell Lymphoma (ALCL) contain the genetic complex of the ALK gene and the nucleolar phosphoprotein B23, also called numatrin (NPM) gene translocation, creating the NPM-ALK complex. This chimeric protein is expressed from the NPM promoter, leading to the overexpression of the ALK catalytic domain. This overexpression of ALK is characteristic of most cancers that are linked to tyrosine kinases, as the overexpression of these proteins leads to uncontrollable growth <ref name="Della Corte">PMID:29455642</ref>.
Approximately 70-80% of all patients who have Anaplastic Large Cell Lymphoma (ALCL) contain the genetic complex of the ALK gene and the nucleolar phosphoprotein B23. This complex is also called the numatrin (NPM) gene translocation and creates the NPM-ALK complex. This chimeric protein is expressed from the NPM promoter, leading to the overexpression of the ALK catalytic domain. This overexpression of ALK is characteristic of most cancers that are linked to tyrosine kinases, as the overexpression of these proteins leads to uncontrollable growth <ref name="Della Corte" />.
==== Pediatric Neuroblastoma ====
==== Pediatric Neuroblastoma ====
Mutations in Anaplastic Lymphoma Kinase have been shown to produce oncogenic activity and be a leading factor in some pediatric neuroblastoma cases. 8-10% of primary [neuroblastoma] patients are ALK positive <ref name="Borenas" /> meaning that the overstimulation of the ALK is thought to be the primary factor in propagating the growth of neuroblastoma. This overstimulation of ALK works in concert with the neural MYC oncogene, and uses the ALKAL2 ligand in these specific cases. Its thought that tyrosine kinase inhibitors would be useful methods to stop the growth of further neuroblastoma cells, creating a potential pathway of treatment. <ref name="Borenas" />  
Mutations in ALK can produce oncogenic activity and are a leading factor in the development of some pediatric neuroblastoma cases<ref name="Borenas" />. 8-10% of primary neuroblastoma patients are ALK positive<ref name="Borenas" /> suggesting that ALK overstimulation is a primary factor in propagating the growth of neuroblastoma. This overstimulation of ALK works in concert with the neural MYC oncogene and uses the ALKAL2 ligand. Tyrosine kinase inhibitors are proposed to inhibit the growth of further neuroblastoma cells, creating a potential pathway of treatment<ref name="Borenas" />.
</StructureSection>
== Inhibition and Regulation ==
The regulation of ALK dimerization by ALKAL points to one clear way of inhibiting ALK activity and may offer new therapeutic strategies in multiple disease settings <ref name="Li">PMID:34819665</ref>. As the dimerization of ALK is essential for the activation of this protein, the inhibition of this activation is a potent way of inhibiting further ALK activity.<ref name ="Li" /> The inhibition and regulation of this extracellular region of ALK are actively being explored, as this part of ALK is part of what distinguishes it from other RTKs, like LTK. Researchers are currently exploring the use of [https://proteopedia.org/wiki/index.php/Antibody antibodies] and more specifically [https://proteopedia.org/wiki/index.php/Monoclonal_Antibody#:~:text=Monoclonal%20antibodies%20are%20immunoglobulins%20produced,pure%20homogeneous%20type%20of%20antibody. monoclonal antibodies]<ref name="Carpenter">PMID: 22266870</ref> as a means of inhibiting the activity of ALK through the extracellular domain. It is hypothesized that these monoclonal antibodies act by binding to the binding site of ALK, thus preventing ALKAL from binding<ref name="Li"/>, and inducing cytotoxicity to the cancerous cell itself.<ref name ="Carpenter"/>
In colorectal cancer specifically, it has been found that gene silencing for ALKAL1 is a method of stopping tumorigenesis as in those cell lines there was an upregulation of ALKAL1, stimulating the overexpression of the ALK gene.<ref name="Chen" /> This gene silencing method was shown to stop the [https://en.wikipedia.org/wiki/Hedgehog_signaling_pathway Sonic Hedgehog signaling pathway], which is important in initial neural development and is an important signaling pathway in some cancerous cell lines when misregulated.<ref name="Chen" /> These methods of ALK dimerization inhibition show extensive promise in the field of cancer research, and demonstrate ways that ligand binding can be inhibited.
</StructureSection>.
== References ==
== References ==
<references/>
<references/>

Latest revision as of 19:28, 21 April 2022

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Anaplastic Lymphoma Kinase Extracellular RegionAnaplastic Lymphoma Kinase Extracellular Region

Background

Anaplastic Lymphoma Kinase (ALK) is a transmembrane receptor and a member of the family of Receptor Tyrosine Kinases (RTKs)[1]. RTKs are a family of biomolecules that are primarily responsible for biosignaling pathways such as the insulin signaling pathway.[2] ALK was identified as a novel tyrosine phosphoprotein in 1994 in an analysis of Anaplastic Large-Cell Lymphoma, the protein's namesake.[2] A full analysis and characterization of ALK was completed in 1997, properly identifying it as an RTK, and linking it closely to Leukocyte Tyrosine Kinase (LTK).[2] ALK's normal activity as a receptor tyrosine kinase is to transfer a gamma-phosphate group from adenosine triphosphate (ATP) to a tyrosine residue on its substrate.[2] ALK is one of more than 50 RTKs encoded within the human genome, [2] and its tyrosine kinase activity seems to be especially important in the developing nervous system. [2] The ALK extracellular domain is becoming well characterized, as it is the primary binding site of ALK ligands that end up triggering the kinase activity, as ALK autophosphorylates itself.[3] There are four well-characterized domains on the ALK extracellular domain that are involved in binding the two main ligands of ALK.[3] ALK is most commonly associated with oncogenesis, as various factors, including overstimulation, lead to extreme cell proliferation.[4] It is primarily found in the fetal and infant developing nervous system, however when associated with cancer it can be found in systems other than the nervous system.[5] Examples of these include colon and prostate cancer, where ALK is not normally expressed.[6] This particular protein is interesting in part due to its unique structure, of that it shares the most similarity with LTKs and its association with devastating cancers.[7]

Structure

ALK is a close homolog of LTK, and together these two homologs constitute a subgroup within the superfamily of insulin receptors[4]. ALK is composed of three primary regions: the extracellular region, the transmembrane region, and the intracellular region.[3]

Figure 1. Overview of Anaplastic Lymphoma Kinase Structure with domains where known structures are color coordinated and other domains are grayed out. The abbreviations are as follows: NTR-N-terminal Region, MAM-Meprin-A-5 protein-receptor protein tyrosine phosphatase μ, LDL-low-density lipoprotein receptor class A, THB-three helix bundle-like, GlyR-poly-glycine region, TNF-tumor necrosis factor-like domain, EGF-epidermal growth factor-like, TMH-transmembrane helix

The extracellular region of ALK contains 8 total domains within 2 fragments.[3] A Three Helix Bundle-like domain (THB-like), a Poly-Glycine domain (GlyR), a Tumor Necrosis Factor-like domain (TNF-like), and an Epidermal Growth Factor-like domain (EGF-like) make up the ligand binding fragment while an N-terminal domain, two meprin–A-5 protein–receptor protein tyrosine phosphatase μ (MAM) domains and a low-density lipoprotein receptor class A (LDL) domain sandwiched between the two MAM domains make up the second fragment.[3] All four domains of the ligand binding fragment of the extracellular region contribute to ligand-binding [2]. The presence of an LDL domain sandwiched by two MAM domains is a unique feature that ALK does not share with other RTKs. The purpose behind this unique difference is still unclear, but the MAM region has been hypothesized to play a role in cell-cell signaling[8]. The transmembrane helical region (TMH) bridges the gap between the intracellular and extracellular regions.[3] The intracellular tyrosine kinase region features the Kinase domain and the C-terminal end (Figure 1). [3]

Known Extracellular Domains

Three Helix Bundle-like Domain

The performs a structural function by interacting with the TNF-like domain upon ligand binding.[3] The THB-like domain's α-helix interacts with the helix α-1' and β strand A-1' on the TNF-like domain.[3] This outermost region of the extracellular ligand-binding domain undergoes substantial structural reorientation upon ligand binding.[3] The THB-like is primarily involved in the of ALK and interacts with the TNF-like domain, which causes dimerization of ALK. [3]

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Poly-Glycine Domain

Figure 2. Rare Glycine helices on Anaplastic Lymphoma Kinase; The structure of extracellular ALK is shown in a perpendicular, cross-sectional way, highlighted in orange. In black, hydrogen bonds are structured in a hexagonal-like way. Made using 7N00

Located between the THB-like domain and the TNF-like domain, the has an important structural role.[3] The GlyR domain also has a rare and unique structure of left-handed glycine helices with hexagonal hydrogen bonding (Figure 2).[3] These 14 glycine helices are unique to ALK's function among other tyrosine kinases.[3] These helices are rigid structures, providing a strong anchor for the ligand binding site while the other domains undergo conformational rearrangements.[3]

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Tumor-Necrosis Factor-like Domain

The interacts with the THB-like domain to begin the conformational changes associated with ligand binding.[3] Located in approximately the mid-region of the extracellular region, the TNF-like domain bridges the gap between the GlyR domain and the EGF-like domain. The TNF-like domain also assists in mediating ligand binding with the EGF-like domain[3] by interacting with the THB-like domain to facilitate the critical conformation changes required for dimerization and ligand recognition.[3]

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Epidermal Growth Factor-like Domain

Unlike the poly-Glycine helices, the is malleable and repositioning of this domain is essential for activation of the protein.[3] This domain undergoes conformational changes upon ligand binding and when in contact with the TNF-like domain.[3] The consists of primarily hydrophobic residues, which enables their flexibility with regards to one another.[3] The EGF-like domain is essential in binding, and thus this ability of the EGF-like to be very malleable in its interactions with the TNF-like domain is important. [3] Without these interactions, ligand binding does not occur. [3] Hydrogen bonding occurs mostly between residues on the TNF-like domain.[3] There is only one hydrogen bond between the domains that are between residues Y734 on the TNF-like interface and Y984 on the EGF-interface.[3] Major motifs in the EGF-like domain are major and minor β-hairpins, which are stabilized by 3 conserved disulfide bridges. [3] The major β-hairpins in the EGF-like domain interact with the ALKAL2 helices after ALKAL2 binding [3].

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Extracellular Domain Binding

Ligands

The extracellular ligands of ALK are Anaplastic Lymphoma Kinase Ligand 2 (ALKAL 2) and Anaplastic Lymphoma Kinase Ligand 1 (ALKAL 1) which are polypeptides of 76 and 70 lengths respectively.

ALKAL2

is a shared ligand of ALK and LTK. Dimeric ALKAL2 and monomeric ALKAL2-AD both induce dimerization of ALK [3]. Structurally, ALKAL2 has an N-terminal variable region, a conserved augmentor domain, and tends to aggregate in the cell [3]. ALKAL2, as it binds as a dimer, contains a higher potency of binding to the ALK receptor than the other primary ligand, ALKAL1.[9] Overexpression of ALKAL2 is linked to high-risk neuroblastoma in absence of an ALK mutation [10].

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ALKAL1

is a monomeric ligand of ALK. Structurally, ALKAL1 shares the same architecture as ALKAL2 with an N-terminal variable region and a conserved C-terminal augmentor domain [3]. However, in ALKAL1, the N-terminal variable region is shorter and has limited sequence similarity to ALKAL2. Overall, ALKAL1 still shares 91% sequence similarity with ALKAL2. Both ligands include a three helix bundle domain in their structures, with an extended positively charged surface for ligand binding to the TNF-like domain[3]. ALKAL1 as a monomer, however, binds to ALK with poor stability[6] and was only found to stimulate ALK dimerization at much higher concentrations than ALKAL2.[9]

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Binding Site

The binding site is located in the TNF-like region. [7] This site doesn't start out surrounding the ligand, instead the ligand binding initiates conformational changes across the extracellular region of the protein. The ligands for ALK have highly positively charged faces that interact with the TNF-like region, the primary ligand-binding site on the extracellular region[11]. Salt bridges between the positively charged residues on the ligand and negatively charged residues on the receptor are stabilized by ligand binding. Three of these occur between , , and . These strong ionic interactions also induce the conformational changes in the extracellular domain that induce the signaling pathway which include an 80-degree bending of the TNF-like and GlyR domains toward the membrane with the link acting as a hinge and a 160-degree rotation across the z-axis across the TNF-like and GlyR domains. [3]

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Dimerization of ALK

After binding to one of its ligands, ALK undergoes [2]. is mediated mostly by weak Van der Waals interactions and main chain hydrogen bonding between the TNF-like domain on one monomer and the THB-like domain on the other. [3] The dimerization causes trans-phosphorylation of specific tyrosine residues located in the extracellular region in the activation loop which in turn transmits a signal downstream[2]. It has been presumed that the phosphorylation cascade activates ALK kinase activity [2].

Function

ALK plays a role in cellular communication and in the normal development and function of the nervous system[2]. ALK is present in the developing nervous system of a fetus and newborn. ALK expression dwindles with age.[2] In addition to being heavily expressed in the brain, ALK is present in the small intestine, testis, prostate, and colon [4].

Disease and Medical Relevance

Cancer

In ALK fusion proteins, the ALK fusion partner may cause dimerization independent of ligand binding, leading to oncogenic ALK activation [2].

Approximately 70-80% of all patients who have Anaplastic Large Cell Lymphoma (ALCL) contain the genetic complex of the ALK gene and the nucleolar phosphoprotein B23. This complex is also called the numatrin (NPM) gene translocation and creates the NPM-ALK complex. This chimeric protein is expressed from the NPM promoter, leading to the overexpression of the ALK catalytic domain. This overexpression of ALK is characteristic of most cancers that are linked to tyrosine kinases, as the overexpression of these proteins leads to uncontrollable growth [4].

Pediatric Neuroblastoma

Mutations in ALK can produce oncogenic activity and are a leading factor in the development of some pediatric neuroblastoma cases[10]. 8-10% of primary neuroblastoma patients are ALK positive[10] suggesting that ALK overstimulation is a primary factor in propagating the growth of neuroblastoma. This overstimulation of ALK works in concert with the neural MYC oncogene and uses the ALKAL2 ligand. Tyrosine kinase inhibitors are proposed to inhibit the growth of further neuroblastoma cells, creating a potential pathway of treatment[10].

Inhibition and Regulation

The regulation of ALK dimerization by ALKAL points to one clear way of inhibiting ALK activity and may offer new therapeutic strategies in multiple disease settings [11]. As the dimerization of ALK is essential for the activation of this protein, the inhibition of this activation is a potent way of inhibiting further ALK activity.[11] The inhibition and regulation of this extracellular region of ALK are actively being explored, as this part of ALK is part of what distinguishes it from other RTKs, like LTK. Researchers are currently exploring the use of antibodies and more specifically monoclonal antibodies[5] as a means of inhibiting the activity of ALK through the extracellular domain. It is hypothesized that these monoclonal antibodies act by binding to the binding site of ALK, thus preventing ALKAL from binding[11], and inducing cytotoxicity to the cancerous cell itself.[5]

In colorectal cancer specifically, it has been found that gene silencing for ALKAL1 is a method of stopping tumorigenesis as in those cell lines there was an upregulation of ALKAL1, stimulating the overexpression of the ALK gene.[6] This gene silencing method was shown to stop the Sonic Hedgehog signaling pathway, which is important in initial neural development and is an important signaling pathway in some cancerous cell lines when misregulated.[6] These methods of ALK dimerization inhibition show extensive promise in the field of cancer research, and demonstrate ways that ligand binding can be inhibited.

Structure of Anaplastic Lymphoma Kinase 7N00

Drag the structure with the mouse to rotate

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ReferencesReferences

  1. Iwahara T, Fujimoto J, Wen D, Cupples R, Bucay N, Arakawa T, Mori S, Ratzkin B, Yamamoto T. Molecular characterization of ALK, a receptor tyrosine kinase expressed specifically in the nervous system. Oncogene. 1997 Jan 30;14(4):439-49. doi: 10.1038/sj.onc.1200849. PMID:9053841 doi:http://dx.doi.org/10.1038/sj.onc.1200849
  2. 2.00 2.01 2.02 2.03 2.04 2.05 2.06 2.07 2.08 2.09 2.10 2.11 2.12 Huang H. Anaplastic Lymphoma Kinase (ALK) Receptor Tyrosine Kinase: A Catalytic Receptor with Many Faces. Int J Mol Sci. 2018 Nov 2;19(11). pii: ijms19113448. doi: 10.3390/ijms19113448. PMID:30400214 doi:http://dx.doi.org/10.3390/ijms19113448
  3. 3.00 3.01 3.02 3.03 3.04 3.05 3.06 3.07 3.08 3.09 3.10 3.11 3.12 3.13 3.14 3.15 3.16 3.17 3.18 3.19 3.20 3.21 3.22 3.23 3.24 3.25 3.26 3.27 3.28 3.29 3.30 3.31 3.32 Reshetnyak AV, Rossi P, Myasnikov AG, Sowaileh M, Mohanty J, Nourse A, Miller DJ, Lax I, Schlessinger J, Kalodimos CG. Mechanism for the activation of the anaplastic lymphoma kinase receptor. Nature. 2021 Dec;600(7887):153-157. doi: 10.1038/s41586-021-04140-8. Epub 2021, Nov 24. PMID:34819673 doi:http://dx.doi.org/10.1038/s41586-021-04140-8
  4. 4.0 4.1 4.2 4.3 Della Corte CM, Viscardi G, Di Liello R, Fasano M, Martinelli E, Troiani T, Ciardiello F, Morgillo F. Role and targeting of anaplastic lymphoma kinase in cancer. Mol Cancer. 2018 Feb 19;17(1):30. doi: 10.1186/s12943-018-0776-2. PMID:29455642 doi:http://dx.doi.org/10.1186/s12943-018-0776-2
  5. 5.0 5.1 5.2 Carpenter EL, Haglund EA, Mace EM, Deng D, Martinez D, Wood AC, Chow AK, Weiser DA, Belcastro LT, Winter C, Bresler SC, Vigny M, Mazot P, Asgharzadeh S, Seeger RC, Zhao H, Guo R, Christensen JG, Orange JS, Pawel BR, Lemmon MA, Mosse YP. Antibody targeting of anaplastic lymphoma kinase induces cytotoxicity of human neuroblastoma. Oncogene. 2012 Nov 15;31(46):4859-67. doi: 10.1038/onc.2011.647. Epub 2012 Jan, 23. PMID:22266870 doi:http://dx.doi.org/10.1038/onc.2011.647
  6. 6.0 6.1 6.2 6.3 Chen S, Wang B, Fu X, Liang Y, Chai X, Ye Z, Li R, He Y, Kong G, Lian J, Li X, Chen T, Zhang X, Qiu X, Tang X, Zhou K, Lin B, Zeng J. ALKAL1 gene silencing prevents colorectal cancer progression via suppressing Sonic Hedgehog (SHH) signaling pathway. J Cancer. 2021 Jan 1;12(1):150-162. doi: 10.7150/jca.46447. eCollection 2021. PMID:33391411 doi:http://dx.doi.org/10.7150/jca.46447
  7. 7.0 7.1 De Munck S, Provost M, Kurikawa M, Omori I, Mukohyama J, Felix J, Bloch Y, Abdel-Wahab O, Bazan JF, Yoshimi A, Savvides SN. Structural basis of cytokine-mediated activation of ALK family receptors. Nature. 2021 Oct 13. pii: 10.1038/s41586-021-03959-5. doi:, 10.1038/s41586-021-03959-5. PMID:34646012 doi:http://dx.doi.org/10.1038/s41586-021-03959-5
  8. Palmer RH, Vernersson E, Grabbe C, Hallberg B. Anaplastic lymphoma kinase: signalling in development and disease. Biochem J. 2009 May 27;420(3):345-61. doi: 10.1042/BJ20090387. PMID:19459784 doi:http://dx.doi.org/10.1042/BJ20090387
  9. 9.0 9.1 Reshetnyak AV, Murray PB, Shi X, Mo ES, Mohanty J, Tome F, Bai H, Gunel M, Lax I, Schlessinger J. Augmentor alpha and beta (FAM150) are ligands of the receptor tyrosine kinases ALK and LTK: Hierarchy and specificity of ligand-receptor interactions. Proc Natl Acad Sci U S A. 2015 Dec 29;112(52):15862-7. doi:, 10.1073/pnas.1520099112. Epub 2015 Nov 16. PMID:26630010 doi:http://dx.doi.org/10.1073/pnas.1520099112
  10. 10.0 10.1 10.2 10.3 Borenas M, Umapathy G, Lai WY, Lind DE, Witek B, Guan J, Mendoza-Garcia P, Masudi T, Claeys A, Chuang TP, El Wakil A, Arefin B, Fransson S, Koster J, Johansson M, Gaarder J, Van den Eynden J, Hallberg B, Palmer RH. ALK ligand ALKAL2 potentiates MYCN-driven neuroblastoma in the absence of ALK mutation. EMBO J. 2021 Feb 1;40(3):e105784. doi: 10.15252/embj.2020105784. Epub 2021 Jan 7. PMID:33411331 doi:http://dx.doi.org/10.15252/embj.2020105784
  11. 11.0 11.1 11.2 11.3 Li T, Stayrook SE, Tsutsui Y, Zhang J, Wang Y, Li H, Proffitt A, Krimmer SG, Ahmed M, Belliveau O, Walker IX, Mudumbi KC, Suzuki Y, Lax I, Alvarado D, Lemmon MA, Schlessinger J, Klein DE. Structural basis for ligand reception by anaplastic lymphoma kinase. Nature. 2021 Dec;600(7887):148-152. doi: 10.1038/s41586-021-04141-7. Epub 2021, Nov 24. PMID:34819665 doi:http://dx.doi.org/10.1038/s41586-021-04141-7

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