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Mannan-binding lectin

Mannan-binding lectin (MBL), also known as mannose-binding lectin, is a soluble collectin protein of the that serves as a molecule, binding to , , and other carbohydrates on the surfaces of pathogens such as , viruses, fungi, and parasites to initiate immune defense mechanisms. Structurally, MBL consists of 32 polypeptide subunits organized into multimers—typically trimers to hexamers—each featuring a cysteine-rich N-terminal region, a collagen-like , a region, and a C-terminal carbohydrate-recognition (CRD) that facilitates calcium-dependent binding to microbial glycans. Produced primarily by hepatocytes in the liver and circulating in at concentrations of 0.5–5 μg/mL, MBL levels can increase as an acute-phase response during or , with additional expression observed in extrahepatic tissues like the . In its primary function, MBL activates the of the by associating with MBL-associated serine proteases (MASPs), particularly MASP-2, leading to cleavage of complement components and to form the and promote opsonization, , and . Beyond complement activation, MBL enhances direct opsonophagocytosis by macrophages and neutrophils, modulates production (e.g., IL-6, IL-1β), and contributes to intestinal by limiting fungal colonization, such as by , through binding and clearance in the gut mucosa. Genetic variations in the MBL2 gene on chromosome 10, including exon 1 polymorphisms (variants B, C, D) and promoter region haplotypes, result in MBL deficiencies affecting up to 10% of populations, correlating with increased susceptibility to infections (e.g., , ), autoimmune diseases (e.g., systemic ), and exacerbated inflammatory conditions like . Therapeutically, recombinant and plasma-derived MBL formulations have been explored for replacement therapy in deficient individuals, demonstrating safety in phase I trials with half-lives of 18–115 hours, though clinical efficacy remains under investigation for conditions like and post-transplant infections. Discovered in the mid-20th century and isolated from human serum in 1983, MBL's role continues to evolve in research, highlighting its balance between protective immunity and potential contributions to autoinflammation when dysregulated.

Overview

Definition and Role

Mannan-binding (MBL), also known as mannose-binding , is a soluble belonging to the collectin family of C-type . It is primarily produced by hepatocytes in the liver and secreted into the bloodstream, where it circulates as oligomeric complexes composed of multiple subunits, each containing carbohydrate-recognition domains that bind to and other neutral sugar structures on the surfaces of pathogens such as , fungi, and viruses. In the , MBL serves as a versatile defense protein by acting as an that coats microbial surfaces to facilitate their recognition and uptake by phagocytic cells, such as macrophages and neutrophils, thereby enhancing clearance without the need for adaptive antibodies. Additionally, upon binding to pathogens, MBL recruits mannose-binding lectin-associated serine proteases (MASPs), initiating the of the , which leads to the deposition of C3b and formation of the membrane complex to lyse invaders. This dual functionality bridges humoral components like complement with cellular immunity, providing rapid frontline protection against infections. MBL exhibits evolutionary conservation across vertebrates, with functional homologs identified in bony fish, amphibians, reptiles, , and mammals, underscoring its ancient role in host defense that predates the emergence of adaptive immunity. In healthy adults, MBL concentrations typically range from 0.5 to 5 μg/mL, though levels can vary significantly due to genetic polymorphisms in the MBL2 gene and, to a lesser extent, age-related changes during early development.

Discovery and History

Mannan-binding lectin (MBL), initially as a mannose-binding protein, was first isolated from liver in 1978 by , Etoh, and Yamashina through using mannan-Sepharose, revealing a calcium-dependent with specificity for and N-acetylglucosamine residues. This discovery built on earlier predictions of mammalian capable of recognizing mannose-like structures on pathogens. In 1980, and Yamashina extended this work by purifying a similar protein from , demonstrating its structural similarity to the liver form and suggesting a role in humoral defense. The homolog was subsequently purified from in 1983 by , Kawasaki, and Yamashina, marking the identification of MBL as a conserved component across with potential opsonic activity against mannan. Key milestones in MBL research followed in the late 1980s and early 1990s. The human MBL gene (MBL2) was cloned independently in 1989 by Sastry et al. and Taylor et al., revealing its organization into four exons and homology to other C-type lectins, which facilitated studies on its expression and structure. In 1992, Matsushita and Fujita identified MBL-associated serine protease-1 (MASP-1), which forms complexes with MBL to activate the complement system via a lectin pathway distinct from classical and alternative routes, establishing MBL's central role in innate immunity. MASP-2, the key enzyme for cleaving C4 and C2 to form C3 convertase, was subsequently identified in 1997 by Thiel et al.. The nomenclature of the protein evolved alongside these advances. Originally termed "mannan-binding protein" (MBP) to reflect its affinity for mannan from , it was redesignated "mannose-binding lectin" (MBL) in the early 1990s following and biochemical studies that highlighted its broader recognition of terminal , , and on microbial surfaces, rather than strict mannan specificity. Synonyms such as mannan-binding lectin persisted in some literature, but MBL became standard to avoid confusion with basic protein (also abbreviated MBP). By the 2000s, MBL's perception shifted from an obscure serum factor to a critical mediator of innate immunity, driven by genetic studies revealing common polymorphisms in MBL2 associated with protein deficiencies and increased susceptibility. Seminal work by Sumiya et al. in 1991 linked a codon 54 to opsonic defects, while subsequent reports by Lipscombe et al. (1992) and Madsen et al. (1994) identified additional variants (codons 57 and 52), correlating low MBL levels with recurrent s and influencing its recognition as a key player in host defense. These findings, combined with epidemiological data, elevated MBL's status in immunological research.

Molecular Structure

Gene Organization and Expression

The MBL2 gene, which encodes mannose-binding lectin (MBL), is located on the long arm of human chromosome 10 at position 10q21.1. This gene spans approximately 9 kb of genomic DNA and consists of four exons interrupted by three introns. The exon-intron organization reflects the modular structure of the encoded protein, with exon 1 encoding the signal peptide and the collagen-like domain, while exons 2–4 collectively encode the neck region and the carbohydrate-recognition domain (CRD). MBL expression is primarily hepatic, occurring in hepatocytes where the protein is synthesized and secreted into the bloodstream as part of the . Low-level extrahepatic expression has been detected in various tissues, including epithelial cells of the and testis, though these contribute minimally to circulating MBL levels compared to hepatic production. During inflammatory conditions, MBL synthesis can be modulated, with evidence suggesting involvement of hormonal factors such as thyroid hormone and in upregulating hepatic expression, while it does not follow a classical acute-phase response pattern driven by interleukin-6. Transcriptional control of MBL2 is influenced by polymorphisms in the promoter region, which affect both basal and inducible expression levels. Key variants include H/L at position -550 bp, X/Y at -221 bp, and P/Q at -64 bp upstream of the transcription start site; the H, Y, and P alleles are associated with higher promoter activity and elevated MBL protein concentrations in . These promoter elements interact with transcription factors to regulate gene output, contributing to inter-individual variability in MBL levels without altering the core gene structure.

Protein Domains and Assembly

Mannan-binding lectin (MBL) is a collectin family protein characterized by a modular that enables its multimeric and functional properties. The N-terminal consists of a cysteine-rich that facilitates interchain formation, essential for higher-order oligomerization. This is followed by a collagen-like comprising glycine-Xaa-Yaa repeats, which forms a characteristic triple-helical structure upon of three polypeptide chains. The , a short α-helical coiled-coil segment, connects the collagen-like to the C-terminal carbohydrate-recognition (CRD), a responsible for calcium-dependent binding to ligands. Each MBL monomer is a single polypeptide chain of approximately 32 kDa, encoded by the MBL2 gene and comprising 248 . The basic structural unit is a homotrimer, where three s associate via their collagen-like domains to form a stable , stabilized by interchain hydrogen bonds and the neck region's coiled-coil interactions. Higher-order multimers, ranging from dimers to hexamers of these trimers (resulting in 6 to 18 CRDs per complex), are generated through disulfide linkages in the N-terminal cysteine-rich regions, with tetramers and pentamers being predominant in human serum. These oligomeric forms are crucial, as monomers or trimers exhibit minimal functional activity compared to the larger assemblies. The assembly of MBL occurs primarily in the () through a co-translational process. Individual monomers fold with assistance from ER chaperones, such as those involved in bond formation and triple-helix stabilization, before associating into trimers via the domains. Subsequent oligomerization into functional multimers proceeds more slowly as the protein traffics through the secretory pathway, driven by N-terminal pairing that dictates the final . At least tetrameric or higher oligomers are required for effective multivalent and downstream interactions, underscoring the importance of this regulated . Structural studies using and electron microscopy have elucidated the bouquet-like architecture of oligomeric MBL. In these models, the collagen-like triple helices extend as flexible stalks from a central N-terminal hub, fanning out to position the globular CRDs in a spaced, near-planar array at the periphery, optimizing accessibility. High-resolution X-ray structures of the neck and CRD regions confirm the trimeric symmetry and α-helical packing, while electron microscopy reveals the dynamic flexibility of the arms in intact multimers.

Genetic Polymorphisms

Mannan-binding lectin (MBL) is encoded by the MBL2 gene on chromosome 10, where genetic polymorphisms significantly influence its expression and function. Promoter region variants at positions -550 (H/L s, with H denoting high expression and L low) and -221 (X/Y s, with Y high and X low) modulate transcriptional efficiency, thereby affecting serum MBL levels. The H at -550 enhances promoter activity compared to L, while the Y at -221 is associated with higher transcription than X, leading to corresponding variations in circulating MBL concentrations among individuals. These promoter polymorphisms interact with structural variants to determine overall MBL production. In the structural region, exon 1 harbors three key missense mutations: at codon 52 (rs5030737, Arg52Cys, A/D alleles), codon 54 (rs1800450, Gly54Asp, A/B alleles), and codon 57 (rs1800451, Gly57Glu, A/C alleles), where A represents the wild-type high-expression and B, C, D the variant low-expression alleles. These mutations introduce substitutions in the collagen-like , impairing subunit oligomerization and resulting in unstable, low-functioning MBL multimers or monomers that are rapidly degraded. Consequently, individuals homozygous or compound heterozygous for these variants exhibit markedly reduced functional MBL, often below detectable levels. MBL2 polymorphisms combine into haplotypes that classify genotypes as high (e.g., HYPA), medium (e.g., LXPA, LYPA), or low producers (e.g., LYPB, LYQC, HYPD), with the latter associated with MBL deficiency. Low-producer haplotypes like LYPB, LYQC, and HYPD predominate in deficient states, occurring in approximately 5–10% of many populations when defining deficiency as serum MBL <100 ng/. Due to codominant , MBL levels show a effect rather than simple Mendelian patterns, with heterozygotes displaying intermediate phenotypes. Population genetics reveal varying frequencies of deficiency alleles: Europeans typically have lower rates (O allele ~15–25%), while Africans and Asians exhibit higher prevalence (O allele up to 40–50%), potentially reflecting evolutionary pressures like pathogen exposure. These variants contribute to inter-individual differences in innate immunity, with low MBL linked to increased infection susceptibility in certain contexts.

Biological Function

Pathogen Recognition

Mannan-binding lectin (MBL) initiates pathogen recognition through its carbohydrate recognition domain (CRD), which specifically binds to terminal monosaccharides such as mannose, fucose, and N-acetylglucosamine present on high-mannose glycans of microbial surfaces. This binding is calcium-dependent, requiring Ca²⁺ ions coordinated within the CRD to facilitate interaction with the sugar hydroxyl groups, particularly those in equatorial positions at C2 and C3 or C3 and C4. The affinity is markedly enhanced by multivalency, as MBL assembles into oligomeric structures—typically hexamers or higher—that allow multiple CRDs to engage clustered glycans simultaneously, promoting stable adhesion to pathogen surfaces. MBL targets a diverse array of microbial ligands, including bacterial lipopolysaccharides (LPS) such as on Escherichia coli, fungal mannans on species like Candida albicans and Aspergillus fumigatus, and viral glycoproteins including HIV gp120 and the spike protein, all of which feature exposed high-mannose structures. Additionally, MBL binds certain host-derived danger signals, such as glycans on apoptotic cells, facilitating their clearance. These interactions occur preferentially with non-sialylated, terminal sugars that differ from the complex, sialylated glycans typically found on healthy host cells, enabling discrimination between self and non-self. The binding kinetics of MBL reflect its role as an efficient molecule, with dissociation constants (K_d) for multimeric forms typically in the range of 10–100 when engaging high-mannose ligands, far stronger than the millimolar affinity of individual CRDs due to the effect in hexameric or oligomeric assemblies. This enhanced in hexamers allows MBL to capture pathogens effectively even at low concentrations, with binding rates accelerated by the spatial arrangement of CRDs. Upon binding, MBL functions as an by coating microbial surfaces, which promotes enhanced by professional such as macrophages and neutrophils through interactions with collectin receptors like /CD91 on their surfaces. This bridging effect increases the uptake efficiency of opsonized particles, as demonstrated with like E. coli, without requiring downstream complement activation for the phagocytic enhancement.

Complement Activation

Upon to microbial surfaces, mannan-binding lectin (MBL) undergoes a conformational change that exposes cryptic binding sites for associated serine proteases MASP-1 and MASP-2, initiating the of complement . This structural rearrangement, mediated by flexible hinge regions in MBL oligomers, facilitates the and of these MASPs, which are pre-associated in the MBL-MASP complex in plasma. Unlike the classical pathway, this process is antibody-independent and relies on direct recognition of carbohydrate patterns. The proteolytic cascade begins with the autoactivation of MASP-1, which then specifically cleaves and activates MASP-2. Activated MASP-2 subsequently cleaves complement component into C4a and C4b fragments, followed by cleavage of into C2a and C2b. The resulting C4b and C2a associate to form the C4b2a, an enzyme complex analogous to that in the classical pathway. This then hydrolyzes into C3a and C3b, amplifying the response through C3b deposition on the target surface, which promotes opsonization for and facilitates the assembly of the (C4b2a3b). Further progression generates the membrane attack complex (, C5b-9), leading to . The efficiency of this activation correlates with MBL oligomer size, as higher-order multimers (e.g., tetramers or hexamers) bind more MASPs and exhibit greater potency compared to smaller forms like dimers, which are largely inefficient.

Protein Complexes

Mannan-binding lectin (MBL) circulates in primarily as complexes with a family of serine proteases and related proteins known as MBL-associated serine proteases (MASPs) and MBL-associated proteins (MAPs). The key associated proteins include MASP-1 and MASP-2, which serve as primary activators in the ; MASP-3, which plays a regulatory role; and MAp19 (also called or MAP19), an inhibitory pseudoprotease lacking catalytic activity. These proteins all bind to the collagen-like domain of MBL in a calcium-dependent manner, forming stable multimolecular assemblies that enable recognition and downstream immune signaling. The of MBL-MASP complexes reflects the oligomeric of MBL, which assembles from trimeric subunits into higher-order multimers such as tetramers, hexamers, or larger forms. Typically, one MASP dimer associates with each MBL trimer, while higher oligomers can recruit multiple MASP molecules—up to two per trimer in some cases—facilitating amplified signaling upon binding. This arrangement allows for variable complex composition in circulation, with low-order MBL oligomers preferentially associating with MASP-1 and MAp19, and higher oligomers incorporating MASP-2 and MASP-3. In addition to homotypic complexes, MBL can participate in hybrid assemblies with ficolins, the other major pattern-recognition molecules of the , forming mixed initiators that share MASP components and enhance pathway versatility. Structural studies, including crystal structures of MASP-1 modules bound to MBL collagen-like peptides (resolved at 1.8 Å, PDB ID 3POB), have elucidated the details: the N-terminal CUB1-EGF-CUB2 of each MASP interacts with the Gly-Pro-rich stalks of MBL, with key contacts involving Lys46 of MBL penetrating a calcium-stabilized in the CUB2 domain, stabilized by hydrogen bonds and hydrophobic interactions (buried surface area ~300 Ų per ). The domain, located C-terminally, remains distant in the form but repositions upon activation for substrate cleavage. Beyond complement activation, MBL-MASP complexes contribute to through MASP-1's thrombin-like activity. MASP-1 can cleave fibrinogen to form clots and activate factor XIII, promoting clot stabilization, as well as induce platelet activation, independent of the complement pathway. This function links the to , aiding in formation at sites of vascular injury.

Regulation and Interactions

Post-translational Modifications

Mannan-binding lectin (MBL) is subject to multiple post-translational modifications that are vital for its structural integrity, intracellular processing, and . represents a primary modification, occurring in both N-linked and O-linked forms. N-linked targets residues within the carbohydrate recognition (CRD), such as the conserved site analogous to Asn in the WND motif, facilitating proper in the () and enabling efficient secretion from hepatocytes. This modification ensures the CRD achieves its functional conformation for binding, with defects in leading to ER retention and reduced circulating MBL levels. O-linked , in contrast, modifies hydroxylysine residues in the collagen-like , attaching galactose-glucose disaccharides that contribute approximately 1-2 kDa to the subunit mass and stabilize the collagenous structure against thermal denaturation. Hydroxylation of proline and lysine residues in the Gly-Xaa-Yaa repeats of the collagen-like region is another critical modification, catalyzed by the enzyme prolyl-4-hydroxylase (specifically the α1 subunit, P4HA1). This process generates hydroxyproline and hydroxylysine, which are indispensable for forming and stabilizing the triple-helical collagen domain, thereby promoting higher-order oligomerization into functional multimers (e.g., dimers to hexamers or larger). Inhibition of this hydroxylation, such as by certain prolyl hydroxylase domain (PHD) inhibitors like roxadustat, disrupts triple helix formation, impairs multimer assembly, and reduces secretion of high-molecular-weight MBL, underscoring its role in maintaining structural stability. Disulfide bonds form through residues primarily in the N-terminal region, creating both intra-chain links that stabilize individual subunits and inter-chain bonds that drive initial dimerization and subsequent oligomerization. These covalent linkages are established in the and are essential for the correct assembly of MBL into oligomeric forms capable of pathogen recognition and complement activation; disruptions, including trace dehydroalanine formation at sites like Cys216, compromise pairing, leading to misfolded proteins and diminished activity. Collectively, these modifications enforce stringent quality control mechanisms, where incomplete or aberrant processing—often exacerbated by genetic polymorphisms in the —results in intracellular retention and low serum MBL concentrations, thereby impairing innate immune function. For instance, variant alleles associated with structural mutations hinder proper incorporation, yielding dysfunctional low-oligomer forms with reduced ligand affinity.

Inhibitors and Regulators

Soluble inhibitors play a crucial role in modulating the activity of the mannan-binding lectin (MBL) pathway to prevent excessive complement activation. The (C1-INH), a inhibitor, effectively blocks the enzymatic activity of MASP-2 by forming a covalent complex with it, thereby inhibiting the cleavage of and in the . MAp19, an alternative splice product of the MASP2 gene lacking catalytic activity, was initially reported to act as a competitive inhibitor of MASP-2 by binding to MBL. However, it does not effectively compete with MASP-2 for to MBL or inhibit complement activation. Cell-surface regulators further limit the amplification of complement activation initiated by the MBL pathway on host tissues. Membrane cofactor protein (MCP, ) serves as a cofactor for factor I, facilitating the proteolytic degradation of C4b and C3b deposited on cell surfaces, thus preventing the formation and stability of convertases in the . (DAF, CD55), expressed on host cell membranes, accelerates the dissociation of C4b2a and C3bBb convertases, thereby dampening the propagation of complement activation triggered by MBL-MASP complexes and protecting bystander cells from . Physiological controls maintain balanced MBL function over time and during activation. MBL serum levels exhibit a minor decline in older age, potentially reducing lectin pathway efficiency and contributing to increased infection susceptibility in the elderly. Additionally, feedback inhibition occurs through C4b-binding protein (C4BP), which binds to C4b generated in the , accelerating its decay and inhibiting further convertase assembly, thereby limiting uncontrolled amplification. In pathological conditions, dysregulation of MBL can exacerbate inflammation. Elevated MBL levels observed in chronic inflammatory states, such as , promote excessive activation on stressed tissues, amplifying complement-mediated damage and contributing to progressive injury like renal dysfunction.

Clinical Significance

Deficiencies and Infections

Mannan-binding lectin (MBL) deficiency, characterized by serum levels below 100 ng/, affects approximately 5–10% of the global population, with homozygous low-producers accounting for about 5% in individuals of descent and higher prevalence, up to 10%, in those of descent; rates can exceed 40% for low-producing alleles in certain indigenous groups such as . This arises from polymorphisms in the MBL2 gene, leading to reduced . Individuals with MBL deficiency face heightened susceptibility to recurrent infections, especially during early childhood when innate immunity predominates, including bacterial pathogens like and , viral agents such as (RSV), and fungal infections. This vulnerability often manifests as upper and lower respiratory tract infections, sepsis, and otitis media, but typically wanes with the maturation of adaptive immunity in later childhood and adulthood. The underlying mechanisms involve impaired opsonization of microbes by MBL, which hinders , and defective activation of the complement pathway, resulting in inefficient clearance and amplified severity, particularly in settings of additional immunocompromise such as prematurity or concurrent immunodeficiencies. Recent studies from 2023 to 2025 have further implicated MBL deficiency in severe infectious outcomes, including a nearly twofold increased risk of pneumonia and hospitalization in COVID-19 patients carrying low-producing MBL2 alleles.

Disease Associations

Mannan-binding lectin (MBL) has been implicated in the pathogenesis of various autoimmune diseases, where elevated levels contribute to complement-mediated tissue damage. In systemic lupus erythematosus (SLE), higher serum MBL concentrations are associated with increased disease activity, as MBL activates the lectin pathway of complement, promoting inflammation and immune complex deposition in tissues. Polymorphisms in the MBL2 gene, particularly those leading to high-expression variants, modulate SLE risk by enhancing complement activation and exacerbating autoantibody-driven damage. Similarly, in rheumatoid arthritis (RA), MBL2 polymorphisms influence RA susceptibility, with high-producer alleles increasing the likelihood of severe disease progression in certain populations. In metabolic disorders, recent studies highlight MBL's role in vascular complications of diabetes. Elevated MBL levels in mellitus patients are linked to increased risk of , where MBL promotes retinal endothelial and vascular permeability via complement activation. A 2024 analysis confirmed that high serum MBL correlates with severity, suggesting its involvement in and . For , 2023–2024 research demonstrates that dysregulated MBL contributes to glomerular and , with elevated levels predicting faster progression to end-stage renal disease through endothelial damage and . These associations underscore MBL's pro-inflammatory effects in diabetic vasculopathy. MBL also plays a role in other non-infectious conditions, including , where glomerular deposits of MBL activate the , leading to complement-mediated mesangial injury and disease progression. Links to cancer progression remain controversial, with some evidence suggesting elevated MBL may promote and in hematologic malignancies, while low levels correlate with higher incidence in others. Paradoxical effects of MBL dysregulation are evident across inflammatory states, where low MBL levels can be protective against excessive complement in some autoimmune conditions but increase vulnerability. For instance, MBL-low genotypes are linked to milder disease expression in primary Sjögren's syndrome, reducing . In contrast, while low MBL offers potential protection in certain inflammations like subsets of RA, it heightens risks during acute s, as noted in deficiency contexts. These dual roles highlight the context-dependent nature of MBL in immune .

Therapeutic Potential

Replacement therapy with recombinant human mannan-binding lectin (rhMBL) has been explored for patients with MBL deficiency who experience recurrent . Phase I clinical trials have demonstrated the , tolerability, and of rhMBL infusions in MBL-deficient adults and children, with no major adverse events reported and evidence of restored MBL levels post-infusion. Earlier studies using plasma-derived MBL also confirmed in healthy MBL-deficient volunteers, supporting the feasibility of substitution to enhance pathogen opsonization and complement activation in susceptible individuals. Phase II trials are ongoing to assess efficacy in infection-prone cohorts, such as those undergoing transplantation. Inhibition of the lectin pathway downstream of MBL represents a promising for complement-mediated disorders, particularly through targeting MASP-2 with monoclonal antibodies like narsoplimab (OMS721). Narsoplimab has shown potential in preventing transplant-associated complications, such as transplant-associated (HSCT-TMA), by blocking activation that exacerbates endothelial damage and rejection. As of November 2025, FDA approval for narsoplimab in HSCT-TMA remains pending, with a PDUFA target action date of December 26, 2025, following resubmission; phase III data indicate improved survival compared to historical controls. For , a phase III trial (ARTEMIS-IgAN) investigated narsoplimab but did not achieve statistically significant reduction versus , though it was generally well-tolerated. Broader MASP-2 inhibition holds therapeutic promise for antibody-mediated , as preclinical models demonstrate reduced ischemia-reperfusion injury and complement deposition in grafts. Gene approaches, including CRISPR-based editing of the MBL2 promoter to correct deficiency-causing variants, remain in early preclinical exploration for primary immunodeficiencies, with no MBL-specific models yet reported in clinical pipelines. Key challenges in MBL modulation include developing biomarkers for patient stratification, such as serum MBL levels and genetic haplotypes, to identify responders in heterogeneous populations like those with complement-driven diseases. Ongoing efforts focus on these markers to guide in transplant settings. Future directions encompass 2025-initiated trials evaluating MBL pathway blockers for diabetic complications, motivated by associations between elevated MBL and accelerated vascular and renal damage in . Preclinical evidence suggests MBL inhibition could mitigate complement-mediated in diabetic models, paving the way for targeted interventions.