1.C.19 The Defensin (Defensin) Family Many organisms synthesize proteins (or peptides) which are degraded to relatively small hydrophobic or amphipathic, bioactive peptides. These peptides exhibit antibiotic, fungicidal, virucidal, hemolytic and/or tumoricidal activities by interacting with membranes and forming transmembrane channels that allow the free flow of electrolytes, metabolites and water across the phospholipid bilayers. Most of these peptides appear to function in biological warfare. There are many designations given to these bioactive peptides. They include the magainins, cecropins, melittins, defensins, bacteriocidins, etc. The proteins in each family within this functional superfamily are homologous, but they exhibit little or no significant sequence similarity with members of the other families. Thus, each family may have evolved independently. However, certain common structural features observed between members of distinct families suggest that at least some of these families share a common ancestry. Several families of eukaryotic channel-forming amphipathic peptides, each from a different group of organisms, are recognized. These families comprise the defensin superfamily. They have been shown to be homologous using statistical means and have been described from phylogenetic standpoints (Chen et al. 2011). However, Shafee et al. 2017; Shafee et al. 2016 have suggested that defensins and small defensin-like proteins fall into two superfamilies, which they call the cis-defensins (broadly distributed in living organisms) and the trans-defensins (narrowly distrubuted). They suggest that these two groups of proteins converged to show similar sequences, secondary and tertiary structures, and disulfide connectivities, with overlapping organismal sources and functions, in spite of their independent origins. The functions of these short proteins vary tremendously including pore formation, bacterial and fungal toxicity, lipid targeting, toxic receptor and channel interactions, fertilization, protease inhibiton and stress adaptation. However, as noted by the authors, alternative pathways involving divergent evolution from a common evolutionary source could have also occurred although they consider this possibility less likely (Shafee et al. 2016; Shafee et al. 2017). Defensins are often produced by mammals. Their precursors vary in size (35-95 amino acyl residues). The three-dimensional structures of defensin-1 have been solved both by x-ray crystallography (1.9 Å resolution) and by NMR. An α-defensin, HNP-1, a β-stranded toxin, forms a dimeric pore (Zhang et al., 2010). The amino acid composition, amphipathicity, cationic charge and size of a defensin allow it to attach to and insert into membranes to form pores by 'barrel-stave', 'carpet' or 'toroidal-pore' mechanisms. Transmembrane pore formation is not the only mechanism of microbial killing. Translocated peptides can alter cytoplasmic membrane septum formation, inhibit cell-wall synthesis, inhibit nucleic-acid synthesis, inhibit protein synthesis or inhibit enzymatic activities (Brogden 2005). Defensins contribute to innate immunity, including protection of mucosal tissues. Human α-defensin 6 (HD6) is highly expressed by secretory Paneth cells of the small intestine. However, in contrast to the other defensins, it lacks appreciable bactericidal activity. Chu et al. (2012) reported that HD6 affords protection against invasion by enteric bacterial pathogens in vitro and in vivo. After stochastic binding to bacterial surface proteins, HD6 undergoes ordered self-assembly to form fibrils and nanonets that surround and entangle bacteria. This self-assembly mechanism occurs in vivo, requires histidine-27, and is consistent with x-ray crystallography data. These findings support a key role for HD6 in protecting the small intestine against invasion by diverse enteric pathogens and may explain the conservation of HD6 throughout Hominidae evolution (Chu et al., 2012). The generalized transport reaction catalyzed by channel-forming amphipathic peptides is: Small solutes, electrolytes and water (in) small solutes, electrolytes and water (out)
This family belongs to the Defensin Superfamily.
References:
Bechinger, B. (1997). Structure and functions of channel-forming peptides: magainins, cecropins, melittin and alamethicin. J. Membr. Biol. 156: 197-211.
Bechinger, B., M. Zasloff and S.J. Opella (1993). Structure and orientation of the antibiotic peptide magainin in membrane by solid-state nuclear magnetic resonance spectroscopy. Prot. Sci. 2: 2077-2084.
Brogden, K.A. (2005). Antimicrobial peptides: pore formers or metabolic inhibitors in bacteria? Nat. Rev. Microbiol. 3: 238-250.
Chen, J.S., V. Reddy, J.H. Chen, M.A. Shlykov, W.H. Zheng, J. Cho, M.R. Yen, and M.H. Saier, Jr. (2011). Phylogenetic characterization of transport protein superfamilies: superiority of SuperfamilyTree programs over those based on multiple alignments. J. Mol. Microbiol. Biotechnol. 21: 83-96.
Chu, H., M. Pazgier, G. Jung, S.P. Nuccio, P.A. Castillo, M.F. de Jong, M.G. Winter, S.E. Winter, J. Wehkamp, B. Shen, N.H. Salzman, M.A. Underwood, R.M. Tsolis, G.M. Young, W. Lu, R.I. Lehrer, A.J. Bäumler, and C.L. Bevins. (2012). Human α-defensin 6 promotes mucosal innate immunity through self-assembled peptide nanonets. Science 337: 477-481.
Cummings, J.E. and T.K. Vanderlick. (2007). Kinetics of cryptdin-4 translocation coupled with peptide-induced vesicle leakage. Biochemistry. 46(42):11882-11891.
Ganz, T., J.R. Rayner, E.V. Valore, A. Tumolo, K. Talmadge and F. Fuller (1989). The structure of the rabbit macrophage defensin genes and their organ-specific expression. J. Immunol. 143: 1358-1365.
Gudmundsson, G.H., D.A. Lidholm, B. Asling, R.B. Gan and H.G. Boman (1991). The cecropin locus–cloning and expression of a gene cluster encoding 3 antibacterial peptides in Hyalophora cecropia. J. Biol. Chem. 266: 11510-11517.
Hill, C.P., J. Yee, M.E. Selsted and D. Eisenberg (1991). Crystal structure of defensin HNP-3, an amphiphilic dimer: mechanisms of membrane permeabilization. Science 251: 1481-1485.
Kourie, J.I. and A.A. Shorthouse (2000). Properties of cytotoxic peptide-formed ion channels. Am. J. Physiol. Cell Physiol. 278: C1063-C1087.
Matsuzaki, K. (1998). Magainins as paradigm for the mode of action of pore forming polypeptides. Biochim. Biophys. Acta 1376: 391-400.
Nagaoka, I., A. Someya, K. Iwabuchi and T. Yamashita (1991). Characterization of cDNA clones encoding guinea pig neutrophil cationic peptides. FEBS Lett. 280: 287-291.
Pardi, A., X.L. Zhang, M.E. Selsted, J.J. Skalicky and P.F. Yip (1992). NMR studies of defensin antimicrobial peptides. 2. Three-dimensional structures of rabbit NP-2 and human HNP-1. Biochemistry 31: 11357-11364.
Shafee, T.M., F.T. Lay, M.D. Hulett, and M.A. Anderson. (2016). The Defensins Consist of Two Independent, Convergent Protein Superfamilies. Mol Biol Evol 33: 2345-2356.
Shafee, T.M., F.T. Lay, T.K. Phan, M.A. Anderson, and M.D. Hulett. (2017). Convergent evolution of defensin sequence, structure and function. Cell Mol Life Sci 74: 663-682.
Terwilliger, T.C. and D. Eisenberg (1982). The structure of melittin. II. Interpretation of the structure. J. Biol. Chem. 257: 6016-6022.
Tran, D., P. Tran, K. Roberts, G. Osapay, J. Schaal, A. Ouellette, and M.E. Selsted. (2008). Microbicidal properties and cytocidal selectivity of rhesus macaque theta defensins. Antimicrob. Agents Chemother. 52(3): 944-953.
Vlasak, R., C. Unger-Ullmann, G. Kreil and A.M. Frischauf (1983). Nucleotide sequence of cloned cDNA coding for honeybee prepromelittin. Eur. J. Biochem. 135: 123-126.
Zhang, X.L., M.E. Selsted and A. Pardi (1992). NMR studies of defensin antimicrobial peptides. 1. Resonance assignment and secondary structure determination of rabbit NP-2 and human HNP-1. Biochemistry 31: 11348-11356.
Zhang, Y., W. Lu, and M. Hong. (2010). The membrane-bound structure and topology of a human α-defensin indicate a dimer pore mechanism for membrane disruption. Biochemistry 49: 9770-9782.
Examples:
TC#	Name	Organismal Type	Example
1.C.19.1.1	Defensin 1, 2 and 3 precursor, also called human neutrophil peptide.	Mammals	Defensin 1-3 precursor of Homo sapiens

1.C.19.1.2	Corticostatin III precursor	Mammals	Corticostatin III precursor of Oryctolagus cuniculus

1.C.19.1.3	Neutrophil cationic peptide-1 precursor (permeable to Cl^-, Na⁺ and K⁺)	Mammals	Neutrophil defensin GP-CS1 of Cavia porcellus

1.C.19.1.4	Cryptdin-10 precursor (Cl^- permeable)	Mammals	Cryptdin-10 precursor of Mus musculus

1.C.19.1.5	Defensin-related cryptdin-4 precursor, Crp4 (structure: 2GW9_A) (Cummings and Vanderlick, 2007).	Animals	*Crp4 of Mus musculus* (P28311)**

1.C.19.1.6	*Theta defensin 1a precursor, RTD1a (Tran et al., 2008)*	Animals	*RTD1 of Macaca mulatta* (P82270)**

1.C.19.1.7	*Non-transporting paneth cell-specific defensin, alpha6 percursor (Chu et al.* 2012). The structure is known (PDB# 3QTE).**	Mammals	Alpha 6 defensin of Homo sapiens