Antimicrobial peptides and methods of use thereof

Drug – bio-affecting and body treating compositions – Designated organic active ingredient containing – Peptide containing doai

Reexamination Certificate

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C514S012200, C530S324000, C530S326000, C530S300000, C435S069100

Reexamination Certificate

active

06747007

ABSTRACT:

FIELD OF THE INVENTION
This invention relates generally to antimicrobial peptides and specifically to a new class of antimicrobial peptides referred to as polyphemusin-like peptides.
BACKGROUND OF THE INVENTION
In 1981, the self-promoted uptake hypothesis was first proposed to explain the mechanism of action of polycationic antibiotics in
Pseudomonas aeruginosa
. According to this hypothesis, polycations interact with sites on the outer membranes of Gram-negative bacteria at which divalent cations cross-bridge adjacent lipopolysaccharide molecules. Due to their higher affinity for these sites, polycations displace the divalent cations and, since the polycations are bulkier than the divalent cations, cause structural perturbations in the outer membrane. These perturbations result in increased outer membrane permeability to compounds such as the &bgr;-lactam antibiotic nitrocefin, the eukaryotic non-specific defense protein lysozyme and to hydrophobic substances. By analogy, molecules accessing this pathway are proposed to promote their own uptake.
It has been clearly demonstrated that the outer membranes of Gram-negative bacteria are semipermeable molecular “sieves” which restrict access of antibiotics and host defense molecules to their targets within the bacterial cell. Thus, cations and polycations which access the self-promoted uptake system are, by virtue of their ability to interact with and break down the outer membrane permeability barrier, capable of increasing the susceptibility of Gram-negative pathogenic bacteria to antibiotics and host defense molecules. Hancock and Wong demonstrated that a broad range of such compounds could overcome the permeability barrier and coined the name “permeabilizers” to describe them (Hancock and Wong,
Antimicrob. Agents Chemother
, 26:48, 1984). While self-promoted uptake and permeabilizers were first described for
P. aeruginosa
, they have now been described for a variety of Gram-negative bacteria.
Over the past decade, non-specific defense molecules have been described in many animals, including insects and humans. One subset of these molecules have in common the following features: (a) they are small peptides, usually 15-35 amino acid residues in length, (b) they contain four or more positively charged amino acid residues, either lysines or arginines, and (c) they are found in high abundance in the organisms from which they derive. Several of these molecules have been isolated, amino acid sequenced and described in the patent literature (e.g., cecropins: WO8900199, WO 8805826, WO 8604356, WO 8805826; defensins: EP 193351, EP 85250, EP 162161, U.S. Pat. No. 4,659,692, WO 8911291). However, only limited amounts of these peptides can be isolated from the host species. For example, Sawyer et al. (
Infect. Immun
. 56:693, 1988) isolated 100-200 mg of rabbit neutrophil defensins 1 and 2 from 10
9
primed peritoneal neutrophils or lipopolysaccharide-elicited alveolar macrophages (i.e., the numbers present in a whole animal).
Production of these peptides using peptide synthesis technology produces peptides in limited amounts and is expensive when scaled up or when many variant peptides must be produced. Also, structural analysis is difficult without specific incorporation of
15
N- and
13
C-tagged amino acids which is prohibitively expensive using amino acid synthesis technology.
The hemocytes of the horseshoe crab contain a unique family of &bgr;-sheet peptide antibiotics, including polyphemusins I and II and tachyplesins I to III (Nakamura et al. (1988)
J. Biol. Chem
. 263:16709-16713; and Miyata et al. (1989)
J. Biochem
. 106:663-668). These peptides are structurally closely-related and are highly abundant in the hemocyte debris. Polyphemusins, isolated from
Limulus polyphemus
, and tachyplesins, isolated from
Tachypleus tridentatus, Tachypleus gigas
and
Carcinoscorpius rotundicauda
, are 18 and 17 amino acid residues in length, respectively. These peptides exhibit a variety of biological activities such as inhibition of the growth of bacteria and fungi and inhibition of the replication of enveloped viruses including vesicular stomatitis virus, influenza A virus and human immunodeficiency virus (HIV)-1 (Miyata et al. (1989)
J. Biochem
. 106:663-668; Masuda et al. (1992)
Biochem. Biophys. Res. Commun
. 189:845-850; Morimoto et al. (1991)
Chemotherapy
37:206-211; and Murakami et al. (1991)
Chemotherapy
37:327-334), herpes virus, hepatitis B and C viruses, and the like. Other studies indicated that tachyplesin I binds to anionic molecules such as DNA and lipopolysaccharides (LPS), and inhibits the LPS-mediated activation of factor I, which is an initiation factor in the Limulus clotting cascade Nakamura et al., supra; Miyata et al., supra; Yonezawa et al. (1992)
Biochemistry
31:2998-3004). Therefore, these arthropod peptides are of special pharmaceutical interest as potential therapeutic agents for anti-endotoxin therapy.
Among the five arthropod peptides, only the secondary structure of tachyplesin I has been determined by nuclear magnetic resonance spectroscopy (Kawano et al. (1990)
J. Biol. Chem
. 265:15365-15367). It was found to have a fairly rigid planar conformation consisting of an anti-parallel &bgr;-sheet structure, constrained by two disulphide bridges and connected by a type II &bgr;-turn. In this planar confirmation, five bulky hydrophobic side groups are located on one side of the plane and six cationic side groups are distributed at the “tail” of the molecule. Like many naturally occurring antimicrobial peptides, polyphemusins and tachyplesins are polycationic and amphipathic, and the C-terminus is amidated. These properties have been implicated in the mode of action and toxicity of tachyplesin I (Park et al. (1992)
Biochemistry
31:12241-12247). Numerous studies of the anti-viral action of this group of peptides against HIV-1 have been carried out (Tamamura et al. (1993)
Biochim. Biophys. Acta
1163:209-216; Tamamura et al. (1998)
Bioorg. Med. Chem
. 6:1033-1041; Arakaki et al. (1999)
J. Virol
. 73:1719-1723). However few studies have focused on the antimicrobial mechanism and anti-endotoxin activity. Limited data has indicated that, at high concentrations (>100 fold the inhibitory concentration), tachyplesin I causes morphological and permeability changes of bacterial cells and human erythrocytes, and increases the K
+
permeability of
S. aureus
and
E. coli
cells, concomitantly reducing cell viability (Katsu et al. (1993)
Bio. Pharm. Bull
. 16:178-181).
Gram-negative bacteria have two cell envelope membranes. The outer membrane is an asymmetric membrane with the bulky glycolipid lipopolysaccharide (LPS) covering more than 90% of the cell surface in its outer leaflet, and phospholipids with a composition similar to that of the cytoplasmic membrane in its inner leaflet. Many antimicrobial cationic peptides have been shown to interact with the LPS of the Gram-negative bacterial outer membrane and pass across this membrane by self-promoted uptake, followed by interaction with and insertion into the negatively charged cytoplasmic membrane (Hancock (1997)
Lancet
349:418-422). However, the target of these cationic peptides is not well understood. Although for many peptides the formation of lesions has been observed in model membranes, there has been little convincing evidence to link such interactions to the event(s) causing bacterial cell death, and it has been proposed that at least some peptides cross the cytoplasmic membrane to access cytoplasmic targets like polyanionic nucleic acids (Kagan et al. (1990)
Proc. Natl. Acad. Sci. U.S.A
. 87:210-214; Ludtke et al. (1996)
Biochemistry
35:13723-13728).
There is thus a need to develop polypeptides having a broad range of potent antimicrobial activity against a plurality of microorganisms, including gram negative bacteria, gram positive bacteria, fungi, protozoa, viruses and the like.
SUMMARY OF THE INVENTION
The present invention provides cationic peptides, referred to as polyphemusin-like peptides, which have antimicrobial activity. Also in

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