Hubbry Logo
Somatostatin receptor 2Somatostatin receptor 2Main
Open search
Somatostatin receptor 2
Community hub
Somatostatin receptor 2
logo
8 pages, 0 posts
0 subscribers
Be the first to start a discussion here.
Be the first to start a discussion here.
Somatostatin receptor 2
Somatostatin receptor 2
Somatostatin receptor 2
View on Wikipedia
from Wikipedia

SSTR2
Identifiers
AliasesSSTR2, Somatostatin receptor 2
External IDsOMIM: 182452; MGI: 98328; HomoloGene: 37427; GeneCards: SSTR2; OMA:SSTR2 - orthologs
Orthologs
SpeciesHumanMouse
Entrez

6752

20606

Ensembl

ENSG00000180616

ENSMUSG00000047904

UniProt

P30874

P30875

RefSeq (mRNA)

NM_001050

NM_001042606
NM_009217

RefSeq (protein)

NP_001041

NP_001036071
NP_033243

Location (UCSC)Chr 17: 73.17 – 73.18 MbChr 11: 113.51 – 113.52 Mb
PubMed search[3][4]
Wikidata
View/Edit HumanView/Edit Mouse

Somatostatin receptor type 2 is a protein that in humans is encoded by the SSTR2 gene.[5]

The SSTR2 gene is located on chromosome 17 on the long arm in position 25.1 in humans.[6] It is also found in most other vertebrates.[7]

The somatostatin receptor 2 (SSTR2), which belongs to the G-protein coupled receptor family, is a protein which is most highly expressed in the pancreas (both alpha- and beta-cells), but also in other tissues such as the cerebrum and kidney and in lower amount in the jejunum, colon and liver.[8][9][10] In the pancreas, after binding to somatostatin, it inhibits the secretion of peptide hormones from pancreatic islets.[8] During development, it stimulates neuronal migration and axon outgrowth.[8]

The somatostatin receptor 2 is expressed in most tumors.[11] Patients with neuroendocrine tumors that over-express the somatostatin receptor 2 have an improved prognosis.[12] The over expression of SSTR2 in tumors can be exploited to selectively deliver radio-peptides to tumors to either detect or destroy them.[13] Somatostatin receptor 2 also has the ability to stimulate apoptosis in many cells including cancer cells.[14] The somatostatin receptor 2 is also being looked at as a possible target in cancer treatment for its ability to inhibit tumor growth.[15]

Function

[edit]

The gene for somatostatin receptor 2, SSTR2 for short, is responsible for making a receptor for the signalling peptide, somatostatin (SST). Production occurs in the central nervous system, especially the hypothalamus, as well as the digestive system, and pancreas.[16] SSTR2 is a receptor for somatostatin-14 and -28 respectively. The numbers 14 and 28 represent the amount of amino acids in each protein sequence.[16] All somatostatin receptors including SSTR2 may have different specific functions, but all fall under the same receptor super family, the G-protein binding family and all of which are a major inhibitor for other hormones.[17] For all somatostatin inhibitors, somatostatin-14 and -28 work by binding to the receptor with the help of a G-protein. This inhibits adenylyl cyclase and calcium channels. These proteins are released in various parts of the human body and vary in the amount emitted from each organ system. In secretory cells this protein is in a greater volume compared to amount released from activated immune and inflammatory cells. These proteins have a tendency of being emitted in response to items such as: ions, nutrients, neuropeptides, neurotransmitters, hormones, growth factors, and cytokines.[18]

In general, somatostatin can put a cell in cycle arrest using the phosphotyrosine phosphatase dependent regulation of nitrogen-activated protein kinase, this process can lead to a halt in the cell cycle or apoptosis of the cell and is used as a tumor suppressor in the genome. This hormone is also known to perform agonist-dependent endocytosis, which allows a cell to take in receptors, ions, and other molecules.[18]

Because this protein is found in multiple organs, it has a different specific role in each organ or organ system. A major function of the protein made by the gene SSTR2 is pancreatic interaction with the alpha and beta cells. In the delta cells of the pancreas, this hormone inhibits the secretion of both glucagon and insulin in the alpha and beta cells when stimulated by basic nutrients like sugars, proteins, and fats.[19] In fact, this protein, is the dominant one out of all of the somatostatins in the pancreas. In the stomach, it reduces activity of the digestive tract by inhibiting secretion of gastric acid, pepsin, bile, and colonic acid when in the presence of luminal nutrients; all of these secretions are needed for proper digestion. It also represses motor activity in the gut by blocking segmentation of the intestines, gallbladder contraction, and emptying of the bowels. This inhibition by somatostatin allows the body to uptake the maximum amount of nutrients in the digestive system.[20] Along with the gut and pancreas, SSTR2 also inhibits secretion of neurotransmitters in the central and peripheral nervous system. These hormones include dopamine, norepinephrine, thyrotropin-releasing hormone, and corticotropin-releasing hormone. Many of these hormones help the body maintain homeostasis or react properly to a stimulus such as something pleasurable or a stress in the environment. Because of which, the receptors for somatostatin type 2 impact the body's locomotor, sensory, autonomic, and cognitive functions.

Interactions

[edit]

Somatostatin receptor 2 has been shown to interact with SHANK2.[21]

Clinical significance

[edit]

The somatostatin hormone itself can negatively affect the uptake of hormones in the body and may play a role in some hormonal conditions. Somatostatin 2 receptors have been found in concentration on the surface of tumor cells, particularly those associated with the neuroendocrine system where the overexpression of somatostatin can lead to many complications[22][23] Due to this, these receptors are considered a prospective aid for the detection of tumors, especially in patients who present with conditions like hypothyroidism and Cushing's syndrome.[24] A synthetic version of the somatostatin hormone, octreotide, has been successfully used in combination with radio-peptide tracers to locate adrenal gland tumors through scintigraphic imaging.[25] A similar method may be utilized to carry and more accurately administer radioactive treatments to tumors.[25] Octreotide and other analogs are preferred for this use due to their possessing of an extended half life compared to the naturally occurring hormone allowing for more flexibility when used for such treatments.[24]

The association of somatostatin 2 receptors on tumors has also led to the suggestion of possible alternatives to current tumor treatment methods. The binding of synthetic somatostatin hormones such as octreotide to receptors has been seen to reduce the production of hormones and is now being considered for use in the treatment of some pituitary tumors.

SSTR2 is also being investigated for its potential use as a reporter gene for the visualization of regional gene expression. One study tested this by comparing the PET/CT and light imaging results of laboratory rats' musculature obtained through the use of a human somatostatin receptor 2 vector and a control luciferase vector.[25] The study suggests that somatostatin receptor genes could be an effective substitute for the current viral-based vectors since the sstr genes elicits less of an immune response and has overall been well tolerated by the trial patients' bodies. This form of treatment may be especially useful for the study of gene expression in larger mammals whose larger body mass may obstruct clear visualization of deep tissue areas.[25] The use of sstr2 and sstr5 as biomarkers to track the progress of and treat neuroendocrine tumors displaying circulating tumor cells is also being investigated due to these cells' somatostatin receptor gene expressivity.[23]

Therapeutic targeting

[edit]

Most pituitary adenomas express SSTR2, but other somatostatin receptors are also found.[26] Somatostatin analogs (i.e. Octreotide, Lanreotide ) are used to stimulate these receptors, and thus to inhibit further tumor proliferation.[27] Paltusotine is a promising selective oral once-daily nonpeptide SSTR2 agonist in development as long-term maintenance therapy of acromegaly in adults.

Discovery

[edit]

There is a group of somatostatin receptors called the somatostatin receptor family. All of the members of the somatostatin receptor family are proteins that sit on the surface of the cell membrane and are responsible for the communication between cells.[28] In 1972,[29] scientists were on the trek to discover more information on the hypothalamus and its "release factors."[29] Studies showed patterns of inhibitory activity of the hypothalamus release factors which led scientists in the direction to discover somatostatin, known as the somatropin release-inhibiting factor, or SRIF. We now know that the SRIF is located at 3q28 (long arm of the third chromosome at the twenty-eighth position) in humans.[29] Peering into location 3q28, the majority of proteins code for the pancreas, ovaries, and prostate along with other components of the endocrine system and nervous system,[30] so it can be drawn that the receptor family has great influence among these systems. The family was first discovered in a segment of a rat's pituitary gland known as the tumor cell line.[31] A cell line is grown as a culture under controlled conditions, so the first discovery was found by culturing these cells in controlled conditions and in an environment outside of its norm. There, researchers found that the tumor cell line expresses a cell dividing inhibitor known as the transforming growth factor beta (TGF-beta)[32] and also acts as an inhibitor to the milk producing hormone in female mammals, prolactin, and growth hormones. Researchers studied the activity of the receptors by conducting an assay with Ligand binding studies,[31] which basically means they were conducting studies to see how prevalent the binding of the receptors occurred.[33][31] Differences in how prevalently they receptors bonded revealed the existence of multiple receptors.[31] Based on the ligand binding affinity and the receptors' signaling mechanisms, the receptor family was divided into 2 different groups, and within those groups, 5 subgroups. The group with a high affinity binding were classified under the SRIF1 group with sst2, sst3, and sst5 in the subgroup, while the receptors with low affinity binding were classified under the SRIF2 group with sst1 and sst4 in the subgroup. Manipulations with the somatostatin receptors are used for many therapies in both the endocrine and nervous system, and now that we know the groups and subgroups of the receptor family, therapy treatment is much more efficient and effective. For example, as you continue reading the article, you will notice the importance and advancements of oncology and tumor treatments, as well as other ways the somatostatin receptors are working and advancing the world of medicine.[34]

The somatostatin receptor 2 is found on the chromosome 17.[35] Information was gathered and determined from a sample of individuals, and conclusions were drawn upon location and other information regarding the SSRT2 protein.[35]

Gene: SSTR2
Title: somatostatin receptor 2
Location: 73,165,021..73,171,955
Length: 6,935 nt
[Positional Info]
NC_000017.11 position: 73,168,608
Gene position: 3,588

Isoforms

[edit]

Like other proteins, the somatostatin receptor 2 also has variants. Somatostatin receptor 2 exists in two isoforms that are different in carboxy-terimini compositions and size. Alternative splicing of the somatostatin receptor 2 mRNA resulted in two variants, somatostatin receptor 2a (SSTR2A) and somatostatin receptor 2b (SSTR2B). In a rodent, somatostatin receptor 2a is longer compared to the shorter somatostatin receptor 2b. Isoform a and isoform b sequences are different, beginning at the C-terminal regulatory domains.[36] Studies have shown that carboxy-terminal splicing has occurred in many other transmembrane receptors, along with prostaglandin E receptor (EP3).[37] These variants, SST2A receptor and SST2B receptor are seen in some brain and spinal cord areas in a rodent.[38] Somatostatin receptor 2a has a shorter transcript, but is longer than somatostatin receptor 2b and has a unique C- terminus compared to Somatostatin Receptor 2b.[37] SSTRB receptor has approximately 300 nucleotides between carboxyl terminus and transmembrane segments fewer than the original Somatostatin receptor 2. SST2A receptor is made up of 369 amino acids and 346 amino acids make up the SST2B receptor.[39] Somatostatin receptor 2a and somatostatin receptor 2b were found in the medulla oblongata, mesencephalon, testis, cortex, hypothalamus, hippocampus and pituitary of a rodent, using reverse transcription polymerase chain reaction (RT-PCR).[36] Somatostatin receptor 2a is highly evident in the cortex, but the somatostatin receptor 2b is not seen as much. The medulla oblongata shows equal amounts of the two variants being expressed. The Somatostatin receptor 2a was found mostly in far down layers of the cerebral cortex, in the human brain. This variant of the Somatostatin receptor was found with the use of immunohistochemistry.[40] The difference in ratios of the isoforms imply a tissue-specific control of transcription. Somatostatin receptor 2b is not shown expressed without somatostatin receptor 2a in the brain.[36]

References

[edit]

Further reading

[edit]
[edit]
Revisions and contributorsEdit on WikipediaRead on Wikipedia

Somatostatin receptor 2

View on Grokipedia
from Grokipedia
Somatostatin receptor 2 (SSTR2), also known as sst2, is a (GPCR) that belongs to the family of five somatostatin receptors (SSTR1–5) and primarily mediates the inhibitory effects of , a , on the secretion of various hormones such as , insulin, , and , as well as on and neurotransmission. Encoded by the SSTR2 gene on 17q25.1, SSTR2 features a classic seven-transmembrane domain structure typical of class A GPCRs, with two main isoforms—SSTR2A and SSTR2B—generated through ; the SSTR2A isoform predominates in humans and couples primarily to Gi/o proteins to inhibit , thereby reducing intracellular levels and modulating downstream signaling pathways involved in endocrine regulation. SSTR2 is widely expressed in the (particularly in the cortex, hippocampus, and ), , , , and various endocrine tissues, with notably high levels in neuroendocrine tumors (NETs), making it a key for these malignancies. Functionally, SSTR2 activation suppresses hormone hypersecretion in conditions like and , inhibits tumor growth in well-differentiated NETs, and plays roles in neurological processes such as pain modulation and , though its dysregulation is implicated in diseases including Alzheimer's and certain cancers. Therapeutically, SSTR2 serves as a primary target for analogs like and , which are used for medical management of , symptom control in NETs, and peptide receptor radionuclide therapy (PRRT) with radiolabeled analogs such as [177Lu], offering both diagnostic imaging via (PET) and targeted tumor ablation. Recent structural insights from cryo-electron (cryo-EM) studies, resolving SSTR2 complexes with agonists at near-atomic resolution (e.g., 3.2–3.7 Å), have elucidated the ligand-binding pocket involving key residues in transmembrane helices, facilitating the design of more selective and potent therapeutics to overcome issues like receptor desensitization.

Molecular Biology

Gene Structure and Location

The SSTR2 , which encodes somatostatin receptor 2, is located on the long arm of human chromosome 17 at cytogenetic band 17q25.1. This positioning places it within a region associated with various genetic studies on neuroendocrine functions, though no direct disease linkages are established solely through location. The gene spans approximately 11.6 kb of genomic DNA, with coordinates from 73,165,010 to 73,176,633 on the GRCh38, oriented on the forward strand. The of SSTR2 consists of two exons separated by a single , a structure that contrasts with intronless designs in some other family members. Exon 1 is non-coding and comprises solely the (UTR), while exon 2 contains the complete encoding the 369-amino-acid protein along with the 3' UTR. The intron-exon boundaries are highly conserved between human and orthologs, featuring canonical GT-AG splice sites that facilitate precise splicing. This compact architecture supports efficient transcription and processing of the mature mRNA. Upstream of the transcription start site, the SSTR2 promoter region harbors key regulatory elements, including two CpG islands situated about 3.8 kb upstream, which play a critical role in transcriptional control through epigenetic modifications like . These CpG-rich sequences are implicated in silencing in certain pathological contexts, such as neuroendocrine tumors, where hypermethylation correlates with reduced promoter activity. No additional core promoter motifs, such as TATA boxes, have been prominently identified, emphasizing reliance on CpG-driven regulation. Evolutionarily, the SSTR2 gene exhibits strong conservation across vertebrate species, with orthologs present in mammals, birds, reptiles, amphibians, and teleost fish, reflecting its ancient origin predating the teleost-specific whole-genome duplication. Within the somatostatin receptor family, SSTR2 shares 40-60% sequence identity with paralogous genes (SSTR1, SSTR3, SSTR4, SSTR5), arising from tandem duplications in early ancestors that expanded the family to five functional members in mammals. This homology underscores shared features while allowing subtype-specific ligand affinities. Syntenic conservation with neighboring genes further supports the stability of the SSTR2 locus across jawed vertebrates.

Isoforms and Expression Patterns

Somatostatin receptor 2 (SSTR2) is transcribed from a single gene but undergoes to produce two primary isoforms: the full-length SSTR2A and the C-terminally truncated SSTR2B. SSTR2A consists of 369 , while SSTR2B comprises 346 , featuring a C-terminal that differs by 23 and is generated through at the 3' end of exon 2. This splicing event alters the intracellular C-terminal , which is critical for receptor regulation. SSTR2 exhibits tissue-specific expression, with high levels observed in the , regions such as the cortex and hippocampus, the , and the , whereas expression is lower in the liver and . Isoform distribution shows predominance of SSTR2A across most tissues, while SSTR2B is more selectively expressed in the and . These patterns have been characterized using techniques including (RT-PCR) for mRNA quantification and for protein localization in tissue sections. The structural divergence in the C-terminal domain of SSTR2B compared to SSTR2A influences receptor behavior, particularly in terms of intracellular trafficking and agonist-induced desensitization, with SSTR2B displaying modified internalization dynamics due to the absence of certain phosphorylation sites present in SSTR2A.

Protein Structure

Overall Architecture

Somatostatin receptor 2 (SSTR2) is classified as a member of the class A (rhodopsin-like) subfamily of G protein-coupled receptors (GPCRs), characterized by a canonical seven-transmembrane (7TM) helical bundle topology embedded in the plasma membrane. This architecture consists of seven α-helical segments (TM1 through TM7) that traverse the lipid bilayer, connected by three extracellular loops (ECL1–3) and three intracellular loops (ICL1–3), with an extracellular N-terminal domain and an intracellular C-terminal tail. The TM helices form a compact bundle that defines the core receptor fold, with the N-terminus extending into the extracellular space and the C-terminus available for interactions with intracellular signaling partners. Like other class A GPCRs, SSTR2 features conserved sequence motifs, including the DRY motif (Asp-Arg-Tyr) at the cytoplasmic end of TM3, which plays a role in stabilizing the inactive conformation by forming an ionic lock with residues in TM6. Recent high-resolution structural studies have provided detailed insights into SSTR2's three-dimensional arrangement. A cryo-EM structure of the active-state SSTR2 in complex with somatostatin-14 and Gi3 heterotrimer (PDB ID: 7T10) was determined at 2.5 Å resolution, revealing an outward displacement of TM6 by approximately 10 Å relative to the inactive state, along with transverse shifts in TM5 and inward movement of TM7 to accommodate coupling. In contrast, a of the inactive SSTR2 bound to the peptide CYN154806 (PDB ID: 7XNA) at 2.65 Å resolution shows a more constricted helical bundle, with ECL2 forming short antiparallel β-strands stabilized by a conserved bond between Cys3.25 and CysECL2. These structures highlight the helical bundle's overall similarity to rhodopsin-like GPCRs, such as the μ-opioid receptor, while noting SSTR2-specific plasticity in ECL2 that influences conformational dynamics. The orthosteric binding pocket in SSTR2, formed by the TM helices, extends deeply into the receptor core, enabling recognition of peptide ligands like . In the active conformation, subtle tilt adjustments in the TM helices—such as a ~2 tilt of the Gαi α5 helix toward TM6—facilitate , underscoring the receptor's evolutionary conservation within class A GPCRs.

Ligand Binding and Functional Domains

The orthosteric binding pocket of somatostatin receptor 2 (SSTR2) is formed by transmembrane helices TM2, TM3, TM5, TM6, TM7, and extracellular loop 2 (ECL2), creating a deep cavity at the extracellular entrance that accommodates ligands. This architecture enables precise recognition of the conserved Trp-Lys motif in somatostatin-14 (SST-14), where the side chain forms a with Asp122^{3.32} in TM3, and the engages a hydrophobic subpocket involving Phe272^{6.51} in TM6, Phe208^{5.38} in TM5, and Ile177^{4.60} in TM4. Additional hydrogen bonding occurs between Gln126^{3.36} in TM3 and the ligand's , while Phe294^{7.39} in TM7 contributes to aromatic stacking interactions, stabilizing the ligand in an extended conformation. SSTR2 exhibits high binding affinity for both SST-14 and SST-28, with dissociation constants (K_d) in the subnanomolar range (approximately 1-2 nM), reflecting the sufficiency of the shared C-terminal 14-residue of SST-28 for receptor engagement. This affinity profile underscores SSTR2's selectivity for these endogenous ligands over synthetic analogs that prefer other subtypes, such as those optimized for SSTR1 or SSTR5. Beyond the orthosteric site, an extracellular vestibule involving ECL2 and ECL3 facilitates binding of analogs like , where residues such as Ile284 in ECL3 and Pro286 provide additional van der Waals contacts to extend ligand . Allosteric modulation is evident in non-peptide analogs like paltusotine, which occupies a minor pocket adjacent to the orthosteric site, interacting with Leu99^{2.60}, Gln102^{2.63}, and Val103^{2.64} in TM2, thereby influencing subtype selectivity and biased signaling. Functional domains of SSTR2 include the intracellular loop 2 (ICL2), which mediates G-protein coupling by interfacing with the α5 helix of G_{i1}, particularly through Ile148 in ICL2 to stabilize the active conformation and promote inhibitory signaling. The C-terminal tail features multiple serine and threonine phosphorylation sites (e.g., Ser341, Ser343, Thr353, Thr354, Thr360), which, upon agonist stimulation, recruit β-arrestins to induce receptor desensitization and internalization, limiting prolonged signaling.

Physiological Function

Roles in Hormone Regulation

Somatostatin receptor 2 (SSTR2) plays a pivotal role in the by inhibiting the release of (GH) from somatotroph cells and (TSH) from thyrotroph cells. Activation of SSTR2 by suppresses both basal and stimulated GH secretion, primarily through mechanisms that reduce calcium influx and promote membrane hyperpolarization in somatotrophs, thereby fine-tuning the growth axis under normal physiological conditions. Similarly, SSTR2 mediates the inhibition of TSH release, responding to hypothalamic to regulate function and prevent excessive output. This dual inhibitory action helps maintain endocrine , with SSTR2's involvement alongside SSTR5 in pituitary cells. In the pancreas, SSTR2 dominantly suppresses the secretion of insulin from β-cells and glucagon from α-cells, contributing to coordinated regulation of glucose . By activating G protein-gated inwardly rectifying potassium (GIRK) channels and inhibiting P/Q-type calcium currents, SSTR2 reduces in these cells, with selective agonists mimicking 's effects to decrease insulin and glucagon release by over 70%. In the gastrointestinal (GI) tract, SSTR2 further supports nutrient absorption control by inhibiting secretion from parietal cells and modulating intestinal , which slows gastric emptying and prolongs transit time to optimize nutrient uptake without overload. This receptor's expression in mucosal D-cells and the ensures paracrine inhibition of exocrine functions, as evidenced by somatostatin analogs prolonging intestinal transit time in experimental models. Within the , SSTR2 modulates neurotransmitter release in the hippocampus and , influencing and seizure susceptibility. In hippocampal CA1 synapses, SSTR2 activation presynaptically inhibits glutamate release via G-protein signaling, reducing excitatory postsynaptic currents and attenuating in models, where agonists like prevent seizures in up to 67% of cases. In the cortex, SSTR2 is involved in modulating synaptic activity supporting cognitive functions such as . Additionally, SSTR2 exerts autocrine and paracrine control over in epithelial tissues, including the GI mucosa, by arresting growth in response to local signaling and preventing unchecked expansion under physiological stress.

Cellular Signaling Pathways

Somatostatin receptor 2 (SSTR2) primarily couples to pertussis toxin-sensitive Gi/o proteins upon ligand binding, initiating multiple inhibitory signaling cascades. This coupling inhibits adenylyl cyclase activity, leading to decreased intracellular cyclic AMP (cAMP) levels, which suppresses protein kinase A (PKA) activation and downstream effects on hormone secretion and cell proliferation. In pituitary cells, this pathway involves Gαi1 and Gαi2 subunits, effectively reducing cAMP accumulation in response to somatostatin analogs. SSTR2 activation also recruits phosphotyrosine phosphatases (PTPs), such as SHP-1 and SHP-2, which dephosphorylate key signaling molecules to exert anti-proliferative effects. SHP-2 binds directly to tyrosine residues (Y228 and Y312) on the receptor's intracellular motifs, facilitated by transient Src activation via Gβγ subunits, ultimately leading to SHP-1 activation. This PTP activity inhibits the (MAPK)/extracellular signal-regulated (ERK) pathway, thereby arresting the and promoting in responsive cells like those in neuroendocrine tumors. Regarding calcium signaling, SSTR2 modulates intracellular calcium levels through both indirect and direct mechanisms. Activation can stimulate (PLC) via Gβγ subunits, generating inositol 1,4,5-trisphosphate (IP3) that releases calcium from stores, while also inhibiting voltage-sensitive calcium channels (e.g., L- and N-type) through Gαi/o to reduce influx. Isoform-specific differences arise primarily with SSTR2A, the predominant human variant, which forms stable complexes with β-arrestin-2 upon by G protein-coupled receptor kinase 2 (GRK2), facilitating receptor internalization and signal desensitization without lysosomal degradation. In contrast, the rarely expressed SSTR2B isoform exhibits altered trafficking due to its truncated , potentially impacting β-arrestin recruitment efficiency. Cross-talk with the (PI3K)/Akt pathway occurs in a context-dependent manner, particularly in tumor cells. In small cell lung cancer, SSTR2 signaling promotes tumor survival and growth, with loss of SSTR2 leading to increased despite elevated pAkt levels.

Molecular Interactions

Protein-Protein Interactions

Somatostatin receptor 2 (SSTR2), a (GPCR), primarily interacts with heterotrimeric s of the Gi/o family, specifically the α and βγ subunits, to mediate its signaling effects. These interactions occur predominantly through the receptor's intracellular loops (ICLs), particularly the second and third ICLs, which facilitate the exchange of GDP for GTP on the Gα subunit upon binding, leading to dissociation of the complex. Additionally, SSTR2 recruits β-arrestins, such as β-arrestin-1 and β-arrestin-2, following stimulation; this binding promotes receptor desensitization and is essential for clathrin-mediated and subsequent internalization, though β-arrestin involvement in desensitization predominates over internalization in certain cellular contexts like CHO cells. SSTR2 also associates with the cytoskeletal protein filamin A (FLNA), which binds directly to the receptor's C-terminal tail and regulates its trafficking dynamics. This interaction is crucial for efficient receptor internalization via Rab5-dependent pathways and through Rab4, thereby influencing the receptor's localization and resensitization at the plasma membrane. In parallel, SSTR2 modulates insulin signaling by interfering with the (IRS-1) pathway, where activation of SSTR2 leads to dephosphorylation of IRS-1 tyrosine residues through recruitment of phosphatases like SHP-1, thereby inhibiting downstream PI3K/Akt activation and in insulin-responsive cells. Dimerization represents another key aspect of SSTR2's protein interactions, enabling both homo- and heterodimer formation that can alter receptor function. SSTR2 forms homodimers and heterodimers with other subtypes, such as SSTR5, which can destabilize β-arrestin binding and affect trafficking efficiency; coupling further promotes these dimerization events. Moreover, SSTR2 engages in heterodimerization with unrelated GPCRs, including the D2 receptor, as evidenced by co-immunoprecipitation and fluorescence resonance energy transfer studies, potentially allowing cross-talk in regions of co-expression like the and pituitary. Phosphorylation of SSTR2 by G protein-coupled receptor kinases (GRKs), particularly GRK2, occurs rapidly upon agonist stimulation and is concentrated on serine/threonine residues in the C-terminal tail and third ICL. This GRK-mediated phosphorylation is a primary mechanism for acute desensitization, as it reduces G protein coupling efficiency and facilitates β-arrestin recruitment, with specific sites like Ser341/343 contributing to both desensitization and internalization processes. These interactions collectively fine-tune SSTR2 responsiveness, with brief impacts on inhibitory signaling pathways such as adenylyl cyclase suppression.

Ligand Binding Specificity

Somatostatin receptor 2 (SSTR2) exhibits high-affinity binding to the native peptide ligands somatostatin-14 (SST-14) and somatostatin-28 (SST-28), which are the primary endogenous regulators of its activity. SST-14 binds to SSTR2 with an IC50 of approximately 0.2–1 nM, while SST-28 shows comparable affinity (IC50 ~0.3–1 nM), reflecting their shared core pharmacophore that interacts with key residues in the orthosteric pocket, such as Asp3.32 and Gln3.36. Synthetic agonists have been developed to mimic and enhance the selectivity of native somatostatins for SSTR2, with serving as a prototypical example due to its high potency and preference for this subtype. , a cyclic octapeptide analog, binds SSTR2 with an IC50 of ~0.6 nM, demonstrating greater selectivity over SSTR5 (IC50 ~7 nM) through hydrophobic interactions involving its D-Trp and Thr residues with transmembrane helices VI and VII. exhibits similar high-affinity binding to SSTR2 (IC50 ~0.8 nM) and moderate selectivity relative to SSTR5 (IC50 ~5 nM), while pasireotide shows balanced affinity for SSTR2 (IC50 ~1 nM) but higher potency at SSTR5 (IC50 ~0.2 nM), allowing for subtype-specific therapeutic tuning. These structure-activity relationships highlight modifications like substitutions that stabilize the β-turn conformation essential for SSTR2 selectivity. Antagonists such as CYN154806 provide tools for dissecting SSTR2 function by competitively inhibiting binding without activating downstream signaling. This cyclic octapeptide acts as a selective SSTR2 with an IC50 of ~3 nM, occupying the orthosteric site but inducing a rotated conformation of the Trp-Lys motif that prevents receptor activation and coupling. Emerging biased ligands and potential allosteric modulators further refine SSTR2 signaling specificity by favoring particular pathways. For instance, paltusotine, a non-peptide small-molecule , binds the orthosteric pocket of SSTR2 with high affinity (IC50 0.25 nM) but exhibits bias over β-arrestin recruitment, reducing receptor internalization compared to and potentially improving sustained efficacy. While true allosteric modulators remain underexplored for SSTR2, structural studies suggest minor pockets adjacent to the orthosteric site could accommodate such compounds to influence ligand efficacy without competing directly for native binding.

Clinical and Pathological Significance

Expression in Normal and Diseased Tissues

Somatostatin receptor 2 (SSTR2) is widely expressed in normal human tissues, with particularly high levels in the , including the and , as well as in endocrine organs such as the , , and . In the and gut, SSTR2 is detected in approximately 80-90% of neuroendocrine cells, where it contributes to local hormone regulation. Protein expression data from immunohistochemical analyses confirm moderate to strong membranous staining in these neuroendocrine populations, with lower or absent expression in non-neuroendocrine epithelial cells of the same tissues. In pathological conditions, SSTR2 expression patterns often differ markedly from normal tissues, showing upregulation in many neoplasms while exhibiting downregulation or heterogeneity in others. High SSTR2 expression is observed in 70-100% of gastroenteropancreatic neuroendocrine tumors (GEP-NETs), where it frequently exceeds levels in adjacent normal mucosa, as evidenced by quantitative PCR and studies. Similarly, 70-100% of meningiomas display elevated SSTR2, with membranous staining intensity correlating to tumor grade in (PET) imaging using 68Ga-DOTATATE, which shows standardized uptake values (SUVmax) often above 10 in these lesions. Variable upregulation occurs in other cancers, such as tumors (34-79% positivity) and prostate adenocarcinomas (9-14% moderate/strong expression), highlighting tissue-specific differences. Conversely, SSTR2 is frequently downregulated in insulinomas, particularly benign variants, with expression levels low enough to result in poor uptake on somatostatin receptor (SRS) in about 50% of cases, as confirmed by qPCR showing reduced mRNA compared to other pancreatic NETs. This downregulation limits diagnostic sensitivity in these tumors. Factors influencing SSTR2 expression in diseased states include epigenetic modifications, such as promoter hypermethylation and deacetylation, which silence the gene in subsets of NETs and other tumors, as demonstrated in cell line models where demethylating agents restore expression. Hypoxia-inducible factor 1α (HIF-1α) also modulates SSTR2 under hypoxic tumor microenvironments, with studies in NET cells showing indirect suppression via downstream pathways, though this varies by tumor type. These regulatory mechanisms underscore the diagnostic utility of assessing SSTR2 levels via PET or qPCR for distinguishing pathological from normal expression patterns.

Role in Neuroendocrine Tumors and Other Cancers

Somatostatin receptor 2 (SSTR2) plays a pivotal role in the of neuroendocrine tumors (NETs), where its dysregulation facilitates tumorigenesis and proliferation. In well-differentiated NETs, SSTR2 typically mediates an inhibitory autocrine loop involving endogenous , suppressing cell growth and hormone secretion; however, loss or downregulation of SSTR2 disrupts this , enabling unchecked tumor expansion through sustained activation of growth-promoting pathways like MAPK/ERK. This dysregulation is particularly evident in gastroenteropancreatic NETs (GEP-NETs), where reduced SSTR2 expression correlates with increased proliferative indices and metastatic potential. Loss of SSTR2 expression is strongly associated with tumor in NETs, marking a shift from low-grade, indolent lesions to high-grade, aggressive neuroendocrine carcinomas. Studies of pancreatic NETs demonstrate that SSTR2-negative tumors exhibit higher Ki-67 proliferation rates and histological features of poor differentiation, contributing to accelerated disease progression. In contrast, preserved SSTR2 signaling maintains cellular restraint, highlighting its tumor-suppressive function in early-stage disease. Beyond NETs, SSTR2 is highly expressed in certain tumors, including meningiomas and medulloblastomas, where its levels correlate with tumor grade and influence apoptotic . In meningiomas, SSTR2 expression increases with histological grade (e.g., higher in grade II/III versus grade I), potentially exacerbating tumorigenesis by modulating anti-apoptotic pathways; activation of SSTR2 can inhibit proliferation but, in dysregulated contexts, may fail to induce , allowing advantages. Similarly, in medulloblastomas, particularly non-SHH subgroups, elevated SSTR2 expression correlates with improved . Mutations in the gene occur in 37-44% of sporadic pancreatic NETs. SSTR2 expression serves as a key prognostic indicator across these malignancies, with positivity predicting favorable outcomes and responsiveness to targeted interventions. In GEP-NETs, combined SSTR2 and SSTR5 positivity with low Ki-67 is associated with better 5-year survival rates (91%) compared to negativity in both receptors with high Ki-67 (43%). As of 2024, SSTR2 expression has been associated with favorable outcomes and good overall survival in rectal neuroendocrine tumors. In medulloblastomas and meningiomas, high SSTR2 levels correlate with prolonged , though advanced-grade tumors with sustained expression face heightened recurrence risk.

Therapeutic Targeting

Somatostatin Analogs as Therapeutics

Somatostatin analogs are synthetic peptides designed to mimic the action of endogenous , primarily targeting somatostatin receptor 2 (SSTR2) to inhibit secretion and exert antiproliferative effects in SSTR2-expressing tissues. These non-radioactive agents are widely used for managing conditions such as and neuroendocrine tumors (NETs), where they suppress excessive production and control tumor growth. First-generation analogs, with high affinity for SSTR2, have become cornerstone therapies due to their efficacy in normalizing (GH) and (IGF-1) levels in patients. Octreotide, marketed as Sandostatin, was the first somatostatin analog approved by the U.S. (FDA) in 1988 for treatment. It binds predominantly to SSTR2, inhibiting GH release from pituitary somatotroph adenomas, which leads to reduced IGF-1 production and alleviation of symptoms such as enlarged hands, feet, and facial features. The long-acting release (LAR) formulation, administered intramuscularly at 20–30 mg every 4 weeks, provides sustained suppression comparable to multiple daily subcutaneous injections of the short-acting form. Lanreotide, available as Somatuline Depot (autogel formulation), received FDA approval in 2007 for long-term management in patients with inadequate response to surgery or radiation. Like , lanreotide primarily activates SSTR2 to suppress GH and IGF-1, with dosing typically at 90–120 mg deep subcutaneously every 4 weeks, offering similar biochemical control rates of around 50–60% in clinical use. Beyond , first-generation analogs demonstrate antiproliferative benefits in well-differentiated NETs, which often overexpress SSTR2. The PROMID trial, a multicenter, placebo-controlled study published in 2009, showed that LAR (30 mg every 4 weeks) significantly prolonged median time to tumor progression to 14.3 months versus 6 months with placebo in patients with advanced NETs, establishing its role in delaying disease progression regardless of functional status. has shown comparable outcomes in subsequent studies, with tumor stabilization in approximately 65% of gastroenteropancreatic NET patients. These effects are attributed to SSTR2-mediated inhibition of growth factors and progression, though complete tumor regression is rare. Second-generation analogs like pasireotide (Signifor) expand therapeutic options with broader receptor affinity, including SSTR5 alongside SSTR2, allowing targeting of conditions less responsive to first-generation agents. Approved by the FDA in December 2012 for in adults unsuitable for or unresponsive to pituitary , pasireotide suppresses (ACTH) secretion from corticotroph adenomas, normalizing urinary free in about 15–26% of patients. The long-acting formulation is dosed at 40–60 mg intramuscularly every 28 days, with monitoring for due to SSTR2-mediated insulin suppression. In , pasireotide is FDA-approved as second-line therapy after inadequate response to or , achieving IGF-1 normalization in up to 40% of octreotide-resistant cases. In September 2025, the FDA approved paltusotine (Palsonify), the first oral, non-peptide SST2-selective agonist, for the treatment of in adults with inadequate response to prior therapies, offering daily with demonstrated IGF-1 normalization in clinical trials. Common side effects of analogs include gastrointestinal disturbances (, , in 30–50% of patients), (due to SSTR2 effects on cardiac conduction), and cholelithiasis (gallstones in 20–30% with long-term use from reduced gallbladder motility). is particularly pronounced with pasireotide (up to 70% incidence), necessitating glucose monitoring. These agents are generally well-tolerated, with most adverse events mild and manageable through dose adjustment. Resistance to somatostatin analogs develops in 20–50% of patients over time, often through SSTR2 desensitization via receptor internalization and downregulation following prolonged exposure. This process involves of the receptor- complex, leading to reduced surface receptor and diminished signaling, as observed in pituitary adenomas and NETs. Strategies to overcome resistance include switching to multireceptor agonists like pasireotide or combining with other therapies, though mechanisms vary by tumor type.

Radiolabeled Imaging and Peptide Receptor Radionuclide Therapy

Radiolabeled somatostatin receptor 2 (SSTR2) imaging and peptide receptor radionuclide therapy (PRRT) leverage high-affinity somatostatin analogs conjugated to radionuclides to visualize and treat SSTR2-expressing tumors, particularly neuroendocrine tumors (NETs). These approaches exploit the overexpression of SSTR2 on NET cells, enabling precise targeting with positron emission tomography/computed tomography (PET/CT) for diagnostics and beta- or alpha-emitting isotopes for therapeutic . For imaging, 68Ga-DOTATATE (Netspot) was approved by the FDA in 2016 as the first kit for preparing gallium-68-labeled for PET/CT to detect SSTR2-positive NETs in adults and pediatric patients. This agent demonstrates high sensitivity exceeding 90% for identifying NET lesions, outperforming conventional somatostatin receptor scintigraphy in detecting small or metastatic tumors. Additionally, 64Cu-DOTATATE (Detectnet), approved by the FDA in 2020, offers similar PET/CT capabilities with a longer , allowing extended imaging windows up to 90 minutes post-injection and potentially improved detection in low-expression cases. Both tracers bind specifically to SSTR2, providing standardized uptake values that correlate with receptor density for staging and treatment planning. In PRRT, 177Lu-DOTATATE (Lutathera), approved by the FDA in 2018, delivers beta-particle radiation directly to SSTR2-expressing cells for treating progressive, somatostatin receptor-positive gastroenteropancreatic NETs (GEP-NETs). In April 2024, the FDA expanded approval to pediatric patients aged 12 years and older with progressive, somatostatin receptor-positive GEP-NETs. Administered in cycles with amino acid infusion for renal protection, it achieves a mean of approximately 20-30 Gy to kidneys and 0.5-1 Gy to , balancing efficacy against toxicity. The pivotal NETTER-1 phase 3 trial reported an objective response rate of 18% (primarily partial responses) in the 177Lu-DOTATATE arm versus 3% with high-dose , alongside a (PFS) of 28 months compared to 8.4 months in controls, establishing significant antitumor activity and quality-of-life benefits. Emerging alpha-emitting therapies, such as 225Ac-DOTATATE, target SSTR2 for more potent cell killing in refractory NETs due to high radiation, with early studies showing durable responses in 60-80% of patients after 1-3 cycles. However, alpha particles' short range increases risks of off-target effects, including grade 2-3 from glomerular accumulation, prompting investigations into protective strategies like infusion. Patient selection for these therapies relies on SSTR2 expression scoring via pre-therapy PET/CT, where standardized uptake value () thresholds (e.g., Krenning score ≥2) or immunohistochemical (IHC) assessment (e.g., H-score >1 for SSTR2A) identify suitable candidates, ensuring >70% response correlation while excluding those with low uptake to minimize futile exposure.

Discovery and Development

Initial Identification of Somatostatin

Somatostatin, initially termed growth hormone-release inhibiting factor (GHIF) or somatotropin release-inhibiting factor (SRIF), was first identified in 1973 by Paul Brazeau and Roger Guillemin at the Salk Institute. Their team isolated a 14-amino-acid peptide (SST-14) from ovine hypothalamic extracts after processing approximately 500,000 sheep hypothalami, demonstrating its potent inhibition of immunoreactive growth hormone secretion in a radioimmunoassay system using rat pituitary cells. This unexpected discovery occurred during a search for growth hormone-releasing hormone (GHRH), as hypothalamic extracts paradoxically suppressed rather than stimulated GH release in vitro. In 1980, an extended form, somatostatin-28 (SST-28), was isolated and characterized from ovine hypothalamic extracts by Frederick S. Esch, Peter Böhlen, Nicholas Ling, and colleagues, including Guillemin, revealing it as an N-terminally elongated version of SST-14 with 28 and similar but sometimes enhanced biological potency. Guillemin's contributions to hypothalamic peptide research, encompassing the identification of alongside earlier discoveries like (TRH) and luteinizing hormone-releasing hormone (LHRH), earned him the 1977 in Physiology or Medicine, shared with and Rosalyn Yalow for advancements in understanding brain regulation of endocrine function. Early evidence for somatostatin receptors emerged in the late 1970s through radioligand binding assays. In 1978, Agnes Schonbrunn and . Tashjian Jr. demonstrated high-affinity, specific binding sites for iodinated SST-14 in the pituitary tumor cell line GH4C1, with dissociation constants in the nanomolar range and association with functional inhibition of hormone secretion, confirming the existence of functional receptors. During the , pharmacological studies using tritiated or iodinated analogs and selective agonists revealed heterogeneity in binding properties across tissues, suggesting multiple receptor subtypes; for instance, SST-28 exhibited tissue-specific binding affinities distinct from SST-14 in brain versus pancreatic membranes, as shown by C.B. Srikant and Y.C. Patel in 1981. These pre-cloning investigations, relying on displacement curves with analogs like cyclo(Pro-Phe-D-Trp-Lys-Thr-Phe), further delineated at least two pharmacologically distinct subtypes based on differential potencies in inhibiting GH release versus insulin secretion.

Cloning and Characterization of SSTR2

The cloning of the somatostatin receptor 2 (SSTR2) gene marked a pivotal advancement in understanding somatostatin signaling. In 1992, Yamada et al. isolated the human SSTR2 gene from a genomic library using degenerate PCR primers derived from mRNA sequences amplified from human pancreatic islet RNA, targeting G protein-coupled receptor motifs. The full-length cDNA, derived from this genomic sequence, encoded a 369-amino-acid protein with seven transmembrane domains characteristic of G protein-coupled receptors (GPCRs), sharing 46% amino acid identity with the concurrently cloned SSTR1. Expression studies in stably transfected Chinese hamster ovary (CHO) cells demonstrated high-affinity binding to somatostatin-14 (Kd ≈ 0.4 nM), confirming its functionality as a somatostatin receptor predominantly expressed in brain, gastrointestinal tract, and kidney tissues. Subsequent characterization in 1993 established SSTR2's GPCR identity and signaling properties. When expressed in CHO cells, SSTR2 coupled to pertussis toxin-sensitive Gi proteins, inhibiting activity and reducing forskolin-stimulated cAMP levels by up to 50% upon stimulation. Radioligand binding assays further revealed selective association with Giα3 and Gοα subunits, underscoring its role in inhibitory G protein-mediated pathways. These findings solidified SSTR2 as a key mediator of 's suppressive effects on . In 1993, Patel et al. identified two isoforms of SSTR2, SSTR2A and SSTR2B, arising from of a common pre-mRNA, with the splice site in 2 removing a 341-nucleotide segment to generate the shorter SSTR2B variant lacking 15 C-terminal . SSTR2A predominates in most tissues, while SSTR2B shows restricted expression, particularly in . Early studies using models, generated in the late 1990s, demonstrated SSTR2's critical role in (GH) regulation; SSTR2-null mice exhibited elevated basal GH levels and refractoriness to somatostatin- or octreotide-mediated GH suppression, leading to mild GH dysregulation without overt . Key milestones in the included radioligand binding studies that pharmacologically distinguished five SSTR subtypes (SSTR1–5), with SSTR2 showing high affinity for somatostatin-14 and analogs like , confirming the molecular basis for heterogeneous receptor populations observed in tissues. By the 2000s, expression profiling via RT-PCR and expanded on initial data, revealing SSTR2's high abundance in , , and neuroendocrine cells, facilitating targeted therapeutic development.

References

  1. https://pmc.ncbi.nlm.nih.gov/articles/PMC9054131/
  2. https://www.ncbi.nlm.nih.gov/gene/6752
  3. https://www.sciencedirect.com/science/article/pii/S0165614713001855
  4. https://pubmed.ncbi.nlm.nih.gov/39116368/
  5. https://www.guidetopharmacology.org/GRAC/ObjectDisplayForward?objectId=356
  6. https://pubmed.ncbi.nlm.nih.gov/8386508/
  7. https://academic.oup.com/endo/article/149/6/3137/2455268
  8. https://bmcecolevol.biomedcentral.com/articles/10.1186/1471-2148-12-231
  9. https://pubmed.ncbi.nlm.nih.gov/7902529/
  10. https://www.uniprot.org/uniprotkb/P30874/entry
  11. https://www.proteinatlas.org/ENSG00000180616-SSTR2/tissue
  12. https://doi.org/10.1038/s41594-022-00727-5
  13. https://doi.org/10.1038/s41422-022-00679-x
  14. https://doi.org/10.7554/eLife.76823
  15. https://www.researchgate.net/figure/Structures-of-SST14-and-SST28_fig7_272537760
  16. https://pmc.ncbi.nlm.nih.gov/articles/PMC9944328/
  17. https://www.nature.com/articles/s41421-022-00405-2
  18. https://www.sciencedirect.com/science/article/abs/pii/S0026895X24047199
  19. https://doi.org/10.1152/ajpendo.00207.2012
  20. https://doi.org/10.3390/ijms21072568
  21. https://doi.org/10.1016/j.nbd.2013.02.015
  22. https://pmc.ncbi.nlm.nih.gov/articles/PMC2834886/
  23. https://www.molbiolcell.org/doi/10.1091/mbc.e03-02-0069
  24. https://pmc.ncbi.nlm.nih.gov/articles/PMC10778465/
  25. https://doi.org/10.1074/jbc.M313522200
  26. https://pmc.ncbi.nlm.nih.gov/articles/PMC6448409/
  27. https://academic.oup.com/endo/article/153/6/2747/2423992
  28. https://pubmed.ncbi.nlm.nih.gov/11959117/
  29. https://academic.oup.com/endo/article/154/12/4715/2433354
  30. https://research.birmingham.ac.uk/en/publications/dimerization-of-gpcrs-novel-insight-into-the-role-of-flna-and-ssa/
  31. https://www.jbc.org/article/S0021-9258%2818%2963992-4/pdf
  32. https://www.imrpress.com/journal/FBL/13/3/10.2741/2722/pdf
  33. https://pubmed.ncbi.nlm.nih.gov/19748526/
  34. https://pubmed.ncbi.nlm.nih.gov/17706924/
  35. https://pmc.ncbi.nlm.nih.gov/articles/PMC2701454/
  36. https://pmc.ncbi.nlm.nih.gov/articles/PMC3916777/
  37. https://onlinelibrary.wiley.com/doi/10.1111/j.1471-4159.2004.02402.x
  38. https://www.nature.com/articles/s41422-022-00679-x
  39. https://pubmed.ncbi.nlm.nih.gov/10818260/
  40. https://pmc.ncbi.nlm.nih.gov/articles/PMC12538274/
  41. https://www.nature.com/articles/s41467-023-36673-z
  42. https://www.frontiersin.org/journals/oncology/articles/10.3389/fonc.2020.01633/full
  43. https://www.sciencedirect.com/science/article/abs/pii/S0344033823001188
  44. https://pmc.ncbi.nlm.nih.gov/articles/PMC9325105/
  45. https://jnm.snmjournals.org/content/jnumed/early/2016/01/20/jnumed.115.167445.full.pdf
  46. https://academic.oup.com/jcem/article/109/4/1109/7334393
  47. https://www.frontiersin.org/journals/endocrinology/articles/10.3389/fendo.2023.1184436/full
  48. https://academic.oup.com/jcem/article-pdf/108/10/2676/51533111/dgad166.pdf
  49. https://jnm.snmjournals.org/content/63/10/1509
  50. https://pmc.ncbi.nlm.nih.gov/articles/PMC8836266/
  51. https://www.nature.com/articles/s41598-024-54599-4
  52. https://journals.lww.com/md-journal/fulltext/2015/10010/somatostatin_receptor_sstr_2a_expression_is_a.2.aspx
  53. https://pmc.ncbi.nlm.nih.gov/articles/PMC7494964/
  54. https://pubmed.ncbi.nlm.nih.gov/23677175/
  55. https://mednexus.org/doi/10.1097/JP9.0000000000000125
  56. https://pubmed.ncbi.nlm.nih.gov/18974627/
  57. https://www.frontiersin.org/journals/oncology/articles/10.3389/fonc.2022.996489/full
  58. https://pmc.ncbi.nlm.nih.gov/articles/PMC8764337/
  59. https://www.accessdata.fda.gov/drugsatfda_docs/label/2024/021008Orig1s047lbl.pdf
  60. https://www.accessdata.fda.gov/drugsatfda_docs/label/2014/022074s011lbl.pdf
  61. https://pmc.ncbi.nlm.nih.gov/articles/PMC10537411/
  62. https://pubmed.ncbi.nlm.nih.gov/19704057/
  63. https://www.drugs.com/history/signifor.html
  64. https://www.accessdata.fda.gov/scripts/opdlisting/oopd/detailedIndex.cfm?cfgridkey=288709
  65. https://www.drugs.com/history/signifor-lar.html
  66. https://pmc.ncbi.nlm.nih.gov/articles/PMC9156514/
  67. https://www.fda.gov/drugs/news-events-human-drugs/fda-approves-new-treatment-acromegaly-rare-endocrine-disorder
  68. https://pmc.ncbi.nlm.nih.gov/articles/PMC3650572/
  69. https://www.accessdata.fda.gov/drugsatfda_docs/label/2024/208232s006lbl.pdf
  70. https://www.drugs.com/disease-interactions/lanreotide%2Csomatuline-depot.html?professional=1
  71. https://jme.bioscientifica.com/view/journals/jme/52/3/R223.xml
  72. https://pmc.ncbi.nlm.nih.gov/articles/PMC11854070/
  73. https://www.accessdata.fda.gov/drugsatfda_docs/nda/2016/208547Orig1s000SumR.pdf
  74. https://pmc.ncbi.nlm.nih.gov/articles/PMC7151717/
  75. https://www.accessdata.fda.gov/drugsatfda_docs/nda/2016/208547Orig1s000CrossR.pdf
  76. https://pmc.ncbi.nlm.nih.gov/articles/PMC6661311/
  77. https://www.accessdata.fda.gov/drugsatfda_docs/label/2020/213227s000lbl.pdf
  78. https://www.fda.gov/drugs/resources-information-approved-drugs/fda-approves-lutetium-lu-177-dotatate-treatment-gep-nets
  79. https://www.accessdata.fda.gov/drugsatfda_docs/nda/2018/208700orig1s000multidiscipliner.pdf
  80. https://www.fda.gov/drugs/resources-information-approved-drugs/fda-approves-lutetium-lu-177-dotatate-pediatric-patients-12-years-and-older-gep-nets
  81. https://pmc.ncbi.nlm.nih.gov/articles/PMC7227421/
  82. https://pmc.ncbi.nlm.nih.gov/articles/PMC8712294/
  83. https://www.mirt.tsnmjournals.org/articles/initial-findings-on-the-use-of-lesssupgreater225lesssupgreateracac-dotatate-therapy-as-a-theranostic-application-in-patients-with-neuroendocrine-tumors/doi/mirt.galenos.2023.38258
  84. https://jnm.snmjournals.org/content/62/10/1323
  85. https://med.emory.edu/departments/radiology/clinical_divisions/nuclear-medicine/documents/2020/pet/patient-selection-for-prrt-using-dotatate-pet.pdf
  86. https://pmc.ncbi.nlm.nih.gov/articles/PMC2722876/
  87. https://www.pnas.org/doi/10.1073/pnas.77.11.6827
  88. https://pubmed.ncbi.nlm.nih.gov/210185/
  89. https://www.nature.com/articles/294259a0
  90. https://www.pnas.org/doi/10.1073/pnas.89.1.251
  91. https://pubmed.ncbi.nlm.nih.gov/8096694/
  92. https://pubmed.ncbi.nlm.nih.gov/8098703/
  93. https://pubmed.ncbi.nlm.nih.gov/9328352/
  94. https://pubmed.ncbi.nlm.nih.gov/8769372/
  95. https://pubmed.ncbi.nlm.nih.gov/7587653/
Add your contribution
Related Hubs
User Avatar
No comments yet.