Tumor Growth Control 2021 (original) (raw)

Galectins: structure, function and therapeutic potential

Expert Reviews in Molecular Medicine, 2008

Galectins are a family of animal lectins that bind β-galactosides. Outside the cell, galectins bind to cell-surface and extracellular matrix glycans and thereby affect a variety of cellular processes. However, galectins are also detectable in the cytosol and nucleus, and may influence cellular functions such as intracellular signalling pathways through protein–protein interactions with other cytoplasmic and nuclear proteins. Current research indicates that galectins play important roles in diverse physiological and pathological processes, including immune and inflammatory responses, tumour development and progression, neural degeneration, atherosclerosis, diabetes, and wound repair. Some of these have been discovered or confirmed by using genetically engineered mice deficient in a particular galectin. Thus, galectins may be a therapeutic target or employed as therapeutic agents for inflammatory diseases, cancers and several other diseases.

Unlocking the secrets of galectins: a challenge at the frontier of glyco-immunology

2000

Over the last decade, we have witnessed an explosion of information regarding the function of glycoconjugates, carbohydrate-binding proteins, and the elucidation of the sugar code. This progress has yielded not only important insights into fundamental areas of glycobiology but has also influenced other fields such as immunology and molecular medicine. A family of galactoside-binding proteins, called galectins, has emerged recently as a novel kind of bioactive molecules with powerful, immunoregulatory functions. Different members of this family have been shown to modulate positively or negatively multiple steps of the inflammatory response, such as cell-matrix interactions, cell trafficking, cell survival, cell-growth regulation, chemotaxis, and proinflammatory cytokine secretion. To introduce a comprehensive overview of these new advances, here we will explore the molecular mechanisms and biochemical pathways involved in these functions. We will also examine the role of these proteins in the modulation of different pathological processes, such as chronic inflammation, autoimmunity, infection, allergic reactions, and tumor spreading. Understanding the intimate mechanisms involved in galectin functions will help to delineate selective and novel strategies for disease intervention and diagnosis. J. Leukoc. Biol. 71: 741-752; 2002.

Galectin-3: An open-ended story

Galectins, an ancient lectin family, are characterized by specific binding of β-galactosides through evolutionary conserved sequence elements of carbohydrate-recognition domain (CRD). A structurally unique member of the family is galectin-3; in addition to the CRD it contains a prolineand glycine-rich N-terminal domain (ND) through which is able to form oligomers. Galectin-3 is widely spread among different types of cells and tissues, found intracellularly in nucleus and cytoplasm or secreted via non-classical pathway outside of cell, thus being found on the cell surface or in the extracellular space. Through specific interactions with a variety of intra-and extracellular proteins galectin-3 affects numerous biological processes and seems to be involved in different physiological and pathophysiological conditions, such as development, immune reactions, and neoplastic transformation and metastasis. The review attempts to summarize the existing information on structural, biochemical and intriguing functional properties of galectin-3.

Galectins–potential targets for cancer therapy

Cancer letters, 2007

Galectins are a family of galactose binding lectins that have become the focus of attention of cancer biologists due to their numerous regulatory roles in normal cellular metabolism and also because of their altered levels in various cancers. They are reportedly similar to several prominent and established modulators of apoptosis. In this review, we present a brief outline of the advancements in the methodology used to detect and identify them and their therapeutic applications in cancer. Their possible interactions with other glycoconjugates are also discussed and a vision for their future use in diagnosis and therapeutics is provided.

7. Galectins- potential targets for cancer therapy

Galectins as Molecular Targets for Therapeutic Intervention

International journal of molecular sciences, 2018

Galectins are a family of small, highly conserved, molecular effectors that mediate various biological processes, including chemotaxis and angiogenesis, and that function by interacting with various cell surface glycoconjugates, usually targeting β-galactoside epitopes. Because of their significant involvement in various biological functions and pathologies, galectins have become a focus of therapeutic discovery for clinical intervention against cancer, among other pathological disorders. In this review, we focus on understanding galectin structure-function relationships, their mechanisms of action on the molecular level, and targeting them for therapeutic intervention against cancer.

Tumor galectinology: Insights into the complex network of a family of endogenous lectins

Glycoconjugate Journal, 2000

β-Galactosides of cell surface glycoconjugates are docking sites for endogenous lectins of the galectin family. In cancer cells, primarily galectins-1 and-3 have been studied to date. With the emergence of insights into their role in growth control, resistance to or induction of apoptosis and invasive behavior the notion is supported that they can be considered as functional tumor markers. In principle, the same might hold true for the other members of the galectin family. But their expression in tumors has hitherto been a subject of attention only to a very limited extent. Pursuing our concept to define the complexity of the galectin network in cancer cells and the degree of functional overlap/divergence with diagnostic/therapeutic implications, we have introduced comprehensive RT-PCR monitoring to map their galectin gene expression. The data on so far less appreciated galectins in this context such as galectins-4 and-8 vindicate this approach. They, too, attach value to extend the immunohistochemical panel accordingly. Our initial histopathological and cell biological studies, for example on colon cancer progression, prove the merit of this procedure. Aside from the detection of gene expression profiles by RT-PCR, the detailed molecular biological monitoring yielded further important information. We describe different levels of regulation of galectin production in colon cancer cells in the cases of the tandem-repeat-type galectins-8 and-9. Isoforms for them are present with insertions into the peptide linker sequence attributed to alternative splicing. Furthermore, variants with distinct amino acid substitutions (galectin-8, Po66-CBP, PCTA-1, CocaI/II and galectin-9/ecalectin) and generation of multiple mRNA species, notably those coding for truncated galectin-8 and-9 versions with only one lectin site, justify to portray these two family members not as distinct individuals but as groups. In aggregate, the ongoing work to thoroughly chart the galectin network and to disentangle the individual functional contributions is expected to make its mark on our understanding of the malignant phenotype in certain tumor types.

Glycobiology galectin

The involvement of galectins as pleiotropic regulators of cell adhesion and growth in disease progression explains the interest to define their ligand-binding properties. Toward this end, it is desirable to approach in vivo conditions to attain medical relevance. In order to simulate physiological conditions with cell surface glycans as recognition sites and galectins as mediators of intercellular contacts we developed an assay using galectin-loaded Raji cells. The extent of surface binding of fluorescent neoglycoconjugates depended on the lectin presence and the type of lectin, the nature of the probes' carbohydrate headgroup and the density of unsubstituted β-galactosides on the cell surface. Using the most frequently studied galectins-1 and -3, application of this assay led to rather equal binding levels for linear and branched oligomers of N-acetyllactosamine. A clear preference of galectin-3 for α1-3-linked galactosylated lactosamine was noted. In parallel, a panel of 24 neoglycoconjugates was tested as inhibitors of galectin binding from solution to N-glycans of surface-immobilized asialofetuin. These two assays differ in presentation of the galectin and ligand, facilitating identification of assay-dependent properties. Under the condition of the cell assay, selectivity among oligosaccharides for the lectins was higher, and extraordinary affinity of galectin-1 to 3 -O-sulfated probes in a solid-phase assay was lost in the cell assay. Having introduced and validated a cell assay, the comprehensive profiling of ligand binding to cell-surface-presented galectins is made possible.

Galectins: Their Network and Roles in Infection/Immunity/Tumor Growth Control 2021 (original) (raw)

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