| Reactivity | MuSpecies Glossary |
| Applications | Bioactivity |
| Format | Carrier-Free |
| Details of Functionality | Measured by its ability to bind fluorescein-conjugated E. coli Bioparticles. Kuan, S.F. et al. (1992) J. Clin. Invest. 90:97. The ED50 for this effect is 0.3‑1.5 µg/mL. |
| Source | Chinese Hamster Ovary cell line, CHO-derived mouse SP-D protein Met1-Phe374 |
| Accession # | |
| N-terminal Sequence | Ala20 |
| Structure / Form | Oligomer |
| Protein/Peptide Type | Recombinant Proteins |
| Gene | Sftpd |
| Purity | >95%, by SDS-PAGE under reducing conditions and visualized by silver stain |
| Endotoxin Note | <0.10 EU per 1 μg of the protein by the LAL method. |
| Dilutions |
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| Theoretical MW | 35.7 kDa (monomer). Disclaimer note: The observed molecular weight of the protein may vary from the listed predicted molecular weight due to post translational modifications, post translation cleavages, relative charges, and other experimental factors. |
|
| SDS-PAGE | 40-50 kDa, reducing conditions |
|
| Publications |
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| Storage | Use a manual defrost freezer and avoid repeated freeze-thaw cycles.
|
| Buffer | Lyophilized from a 0.2 μm filtered solution in PBS. |
| Purity | >95%, by SDS-PAGE under reducing conditions and visualized by silver stain |
| Reconstitution Instructions | Reconstitute at 200 μg/mL in PBS. |
SP‑D (surfactant protein‑D; also PSP‑D) is a 43 kDa member of the collectin family of innate immune modulators (1 ‑ 5). It is constitutively secreted by alveolar lining cells and epithelium associated with tubular structures. SP‑D is found in serum, plasma, broncho‑alveolar lavage (BAL) fluid, and amniotic fluid (1, 2, 6). Lung injuries often increase release of SP‑D to the circulation (3, 6). Mouse SP‑D is synthesized as a 374 amino acid (aa) precursor. Mouse SP‑D cDNA encodes a 19 aa signal sequence and a 355 aa mature region with a 25 aa N‑terminal linking‑region, a 177 aa hydroxyproline and hydroxylysine collagen‑like domain, a 46 aa coiled‑coil segment, and a 106 aa, C‑terminal collectin‑like C‑type lectin domain (CRD) (5). Mature mouse SP‑D shares 72 ‑ 76% aa sequence identity with human, porcine, equine, canine and bovine SP‑D, and 92% with rat SP‑D. SP‑D is usually found as a glycosylated, disulfide‑linked 150 kDa alpha ‑helical coiled‑coil trimer with a “head” of three symmetrical CRDs (2 ‑ 4, 7). Each CRD recognizes the hydroxides of one monosaccharide, and trimerization allows for the discrimination of monosaccharide patterns specific to microbial pathogens (4, 7, 8). Typically, SP‑D forms a higher‑order 620 kDa, X‑shaped dodecamer through N‑terminal disulfide bonds, allowing for even finer discrimination of self vs. nonself carbohydrate patterns and facilitating binding to complex antigens (1). SP‑D also binds SIRP alpha and the calreticulin/CD91 complex on macrophages (9, 10). When the ratio of antigen/pathogen to available CRDs is low, antigen can be bound without occupying all available CRDs. The free CRDs will bind to SIRP alpha , generating a signal that downmodulates the inflammatory response. During high CRD ligand binding (low SIRP alpha binding), the dodecamer rearranges to expose N‑termini that bind the calreticulin/CD91 complex, an event that initiates inflammation (1). Also, direct and indirect binding of neutrophil defensins and macrophage CD14 and TLRs to SP‑D can modulate response to viruses and bacterial lipopolysaccharides (1 ‑ 3, 11 ‑ 15). Thus, SP‑D allows for a graded response to environmental challenge and clearance of small antigenic insults without the need for a damaging inflammatory response (1 ‑ 3).
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