Solution structures and biological functions of the antimicrobial peptide, arenicin-1, and its linear derivative

Arenicin-1 (AR-1) is a novel antimicrobial peptide that was isolated from coelomocytes of the marine polychaeta lugworm Arenicola marina and shown to contain a single disulfide bond between Cys3 and Cys20, forming an 18-residue ring [Ovchinnikova, T. V. et al., FEBS Lett 2004, 577, 209-214]. To determine the role of this disulfide bond, we synthesized AR-1 (RWCVYAYVRVRGVLVRYRRCW) and its linear derivative, arenicin-1-S (AR-1-S: RWSVYAYVRVRGVLVRYRRSW). Activity assays revealed that AR-1-S is somewhat less active against bacterial cells than AR-1. Both peptides were very hydrophobic, and displayed cytotoxicity against human red blood cells. Analysis of the tertiary structures of AR-1 and AR-1-S by NMR spectroscopy disclosed that AR-1 has two-stranded antiparallel beta-sheet structures with amphipathicity, while AR-1-S displays a random coil structure in DMSO. Our biological data for AR-1 and AR-1-S indicate that the hydrophobic-hydrophilic balance, disulfide bridge, and the amphipathic beta-sheet structure of the peptides play important roles in their biological activities. Elucidation of the structure of AR-1 and its derivative should facilitate the design of novel non-cytotoxic peptide antibiotics with potent antibacterial activities.     

Molecular insight into mechanism of antimicrobial action of the beta-hairpin peptide arenicin: specific oligomerization in detergent micelles

Arenicins are 21-residue cationic antimicrobial peptides isolated from marine polychaeta Arenicola marina. The peptides exhibit potent broad-spectrum antimicrobial activity. In water solution arenicin-2 adopts a beta-hairpin conformation, stabilized by one disulfide and nine hydrogen bonds. To determine the propensity for the peptide oligomerization in membrane mimetic systems, the recombinant arenicin-2 was overexpressed as a fused form in Escherichia coli. The arenicin-2 oligomerization and intermolecular packing in membrane mimicking environment were investigated using high-resolution NMR spectroscopy. The present studies show that arenicin-2 preserves a beta-hairpin structure and forms asymmetric dimers upon incorporation into the dodecylphosphocholine micelle. Two monomers of arenicin-2 are aligned parallel to each other by the N-terminal strands of the beta-hairpin (CN upward arrow upward arrowNC type of association). Polyacrylamide gel electrophoresis analysis indicated that in environment of anionic SDS micelles the arenicin-2 might undergo further oligomerization and form tetramers. Our results afford further molecular insight into possible mechanism of antimicrobial action of arenicins.     

Recombinant expression, synthesis, purification, and solution structure of arenicin

Arenicins are 21-residue cationic antimicrobial peptides, isolated from marine polychaeta Arenicola marina. In order to determine a high-resolution three-dimensional structure of arenicin-2, the recombinant peptide was overexpressed as a fused form in Escherichia coli. Both arenicin isoforms were synthesized using the Fmoc-based solid-phase strategy. Recombinant and synthetic arenicins were purified, and their antimicrobial and spectroscopic properties were analyzed. NMR investigation shows that in water solution arenicin-2 displays a prolonged beta-hairpin, formed by two antiparallel beta-strands and stabilized by one disulfide and nine hydrogen bonds. A significant right-handed twist in the beta-sheet is deprived the peptide surface of amphipathicity. CD spectroscopic analysis indicates that arenicin-2 binds to the SDS and DPC micelles, and conformation of the peptide is significantly changed upon binding. Arenicin strongly binds to anionic lipid (POPE/POPG) vesicles in contrast with zwitterionic (POPC) ones. These results suggest that arenicins are membrane active peptides and point to possible mechanism of their selectivity toward bacterial cells.     

Investigations into the membrane activity of arenicin antimicrobial peptide AA139

Arenicin-3 is an amphipathic β-hairpin antimicrobial peptide that is produced by the lugworm Arenicola marina. In this study, we have investigated the mechanism of action of arenicin-3 and an optimized synthetic analogue, AA139, by studying their effects on lipid bilayer model membranes and Escherichia coli bacterial cells. The results show that simple amino acid changes can lead to subtle variations in their interaction with membranes and therefore alter their pre-clinical potency, selectivity and toxicity. While the mechanism of action of arenicin-3 is primarily dependent on universal membrane permeabilization, our data suggest that the analogue AA139 relies on more specific binding and insertion properties to elicit its improved antibacterial activity and lower toxicity, as exemplified by greater selectivity between lipid composition when inserting into model membranes i.e. the N-terminus of AA139 seems to insert deeper into lipid bilayers than arenicin-3 does, with a clear distinction between zwitterionic and negatively charged lipid bilayer vesicles, and AA139 demonstrates a cytoplasmic permeabilization dose response profile that is consistent with its greater antibacterial potency against E. coli cells compared to arenicin-3.     

Structure-activity relationships of antimicrobial peptides from the skin of Rana esculenta inhabiting in Korea

The anuran (frogs and toads) skin is a rich source of antimicrobial peptides that can be developed therapeutically. We searched the skin secretions of Korean Rana esculenta for antimicrobial peptides, and isolated two cationic peptides with antimicrobial activity and little hemolytic activity: a 46-residue peptide of the esculentin-1 family and a 24-residue peptide of the brevinin-1 family. Their sequences showed some differences from the esculentins-1 and brevinins-1 of European Rana esculenta, indicating that sequence diversification of anuran skin antimicrobial peptides can arise from differences in habitat as well as from species differences. The 46-residue peptide named esculentin-1c had broad antimicrobial activity, while the 24-residue peptide named brevinin-1Ed exhibited limited activity. The solution structure of brevinin-1Ed was in good agreement with that of other brevinin-1-like peptides, with an amphipathic alpha-helix spanning residues 3-20, stabilized in membrane-mimetic environments. The weak bioactivity of brevinin-1Ed was attributable to the unusual presence of an anionic amino acid in the middle of the helical hydrophilic face. This report contributes to world-wide investigations of the structure-activity relationships and evolutional diversification of anuran-skin antimicrobial peptides.     

Multiple peptide resistance factor (MprF)-mediated Resistance of Staphylococcus aureus against antimicrobial peptides coincides with a modulated peptide interaction with artificial membranes comprising lysyl-phosphatidylglycerol

Modification of the membrane lipid phosphatidylglycerol (PG) of Staphylococcus aureus by enzymatic transfer of a l-lysine residue leading to lysyl-PG converts the net charge of PG from -1 to +1 and is thought to confer resistance to cationic antimicrobial peptides (AMPs). Lysyl-PG synthesis and translocation to the outer leaflet of the bacterial membrane are achieved by the membrane protein MprF. Consequently, mutants lacking a functional mprF gene are in particular vulnerable to the action of AMPs. Hence, we aim at elucidating whether and to which extent lysyl-PG modulates membrane binding, insertion, and permeabilization by various AMPs. Lysyl-PG was incorporated into artificial lipid bilayers, mimicking the cytoplasmic membrane of S. aureus. Moreover, we determined the activity of the peptides against a clinical isolate of S. aureus strain SA113 and two mutants lacking a functional mprF gene and visualized peptide-induced ultrastructural changes of bacteria by transmission electron microscopy. The studied peptides were: (i) NK-2, an α-helical fragment of mammalian NK-lysin, (ii) arenicin-1, a lugworm β-sheet peptide, and (iii) bee venom melittin. Biophysical data obtained by FRET spectroscopy, Fourier transform infrared spectroscopy, and electrical measurements with planar lipid bilayers were correlated with the biological activities of the peptides. They strongly support the hypothesis that peptide-membrane interactions are a prerequisite for eradication of S. aureus. However, degree and mode of modulation of membrane properties such as fluidity, capacitance, and conductivity were unique for each of the peptides. Altogether, our data support and underline the significance of lysyl-PG for S. aureus resistance to AMPs.     

Aurelin, a novel antimicrobial peptide from jellyfish Aurelia aurita with structural features of defensins and channel-blocking toxins

A novel 40-residue antimicrobial peptide, aurelin, exhibiting activity against Gram-positive and Gram-negative bacteria, was purified from the mesoglea of a scyphoid jellyfish Aurelia aurita by preparative gel electrophoresis and RP-HPLC. Molecular mass (4296.95 Da) and complete amino acid sequence of aurelin (AACSDRAHGHICESFKSFCKDSGRNGVKLRANCKKTCGLC) were determined. Aurelin has six cysteines forming three disulfide bonds. The total RNA was isolated from the jellyfish mesoglea, RT-PCR and cloning were performed, and cDNA was sequenced. A 84-residue preproaurelin contains a putative signal peptide (22 amino acids) and a propiece of the same size (22 amino acids). Aurelin has no structural homology with any previously identified antimicrobial peptides but reveals partial similarity both with defensins and K+ channel-blocking toxins of sea anemones and belongs to ShKT domain family.     

Fungicidal effect of antimicrobial peptide arenicin-1

Arenicin-1 is a 21-residue peptide which was derived from Arenicola marina. In this study, we investigated the antifungal effects and its mechanism of action towards human pathogenic fungi. Arenicin-1 exerted remarkable fungicidal activity with both energy-dependent and salt-insensitive manners. To investigate the fungicidal mechanisms of arenicin-1, the membrane interactions of arenicin-1 were examined. Flow cytometric analysis, using propidium iodide (PI) and bis-(1,3-dibutylbarbituric acid) trimethine oxonol [DiBAC₄(3)], as well as fluorescence analysis, regarding the membrane probe 1,6-diphenyl-1,3,5-hexatriene (DPH), were conducted against Candida albicans. The results demonstrated that arenicin-1 was associated with lipid bilayers and induced membrane permeabilization. Additionally, the membrane studies in regard to liposomes resembling the phospholipid bilayer of C. albicans confirmed the membrane-disruptive potency of arenicin-1. Therefore, the present study suggests that arenicin-1 exerts its fungicidal effect by disrupting fungal phospholipid membranes.     

De novo generation of short antimicrobial peptides with simple amino acid composition

As potential therapeutic agents, antimicrobial peptides with shorter length and simpler amino acid composition can be better candidates for clinical and commercial development. Here, we attempted de novo design of short (5- to 11-residue) antimicrobial peptides with three kinds of amino acids. Amphipathic helical properties were conferred by using leucines and lysines and two tryptophan residues were positioned at the critical amphipathic interface between the hydrophilic ending side and the hydrophobic starting side. According to this specified rule, 12 model peptides were generated and their helical propensity was confirmed by circular dichroism spectroscopy. Antimicrobial and hemolytic activities were compared with those of the known 12-residue peptide agent, omiganan, which is currently under therapeutic and commercial development. Antimicrobial activities against Gram-negative and Gram-positive bacteria, including a multi-drug resistant strain, were observed for certain 7- to 11-residue models. Among them, the most potent activity was found for a 9-residue peptide (L₅K₂W₂), although it also had severe hemolytic activity. Alternatively, an 11-residue peptide (L₄K₅W₂) with little hemolytic activity was potentially the most useful agent, as it showed higher antibacterial activity than omiganan. These results not only suggest useful candidates for novel antibiotic development, but also provide an efficient strategy to design such peptides.     

The characteristic region of arenicin-1 involved with a bacterial membrane targeting mechanism

The antimicrobial peptide arenicin-1 consists of two antiparallel β-sheets linked by a hydrophilic β-turn. To determine the role of a specific region found in a particular β-sheet structure of the peptide for antibacterial activity, two analogs with N-terminal deletions (RW) and substitutions of Arg to Ala in the β-turn region were designed. In the minimum inhibitory concentration (MIC) test, the antibacterial activities of the analogs were reduced for both Gram-positive and Gram-negative bacteria, when compared to arenicin-1. The influence of the decrease in hydrophobicity on the antibacterial activity was confirmed by a hemolytic assay. Through flow cytometric analysis using propidium iodide (PI) and a 1,6-diphenyl-1,3,5-hexatriene (DPH) assay, it was confirmed that the analogs decreased the degree of plasma membrane permeability compared to arenicin-1. In particular, analog 2 showed a lower permeability in Gram-negative bacteria than in Gram-positive bacteria. The results indicate that a reduction in the net charge weakened the electrostatic interactions between the peptides and the negatively charged membranes. In liposomes, which mimic bacterial membranes, due to a reduced binding affinity to the membranes, the analogs could not deeply penetrate into the hydrocarbon region and induce enough fluorescein isothiocyanate-dextran (FD) leakage compared to that of arenicin-1. It is thought that the Arg residue in the hydrophilic β-turn region is more important to antibacterial activity than the Arg residue in the N-terminal region. This study suggests that the Arg and Trp residues in the N-terminal region and the Arg residue in the β-turn region of arenicin-1 play a key role in antibacterial activity.     

Translocating proline-rich peptides from the antimicrobial peptide bactenecin 7

The intracellular delivery of most peptides, proteins, and nucleotides to the cytoplasm and nucleus is impeded by the cell membrane. To allow simplified, noninvasive delivery of attached cargo, cell-permeant peptides that are either highly cationic or hydrophobic have been utilized. Because cell-permeable peptides share half of the structural features of antimicrobial peptides containing clusters of charge and hydrophobic residues, we have explored antimicrobial peptides as templates for designing cell-permeant peptides. We prepared synthetic fragments of Bac 7, an antimicrobial peptide with four 14-residue repeats from the bactenecin family. The dual functions of cell permeability and antimicrobial activity of Bac 7 were colocalized at the N-terminal 24 residues of Bac 7. In general, long fragments of Bac(1-24) containing both regions were bactericidal and cell-permeable, whereas short fragments with only a cationic or hydrophobic region were cell-permeant without the attendant microbicidal activity when measured in a fluorescence quantitation assay and by confocal microscopy. In addition, the highly cationic fragments were capable of traversing the cell membrane and residing within the nucleus. A common characteristic shared by the cell-permeant Bac(1-24) fragments, irrespective of their number of charged cationic amino acids, is their high proline content. A 10-residue proline-rich peptide with two arginine residues was capable of delivering a noncovalently linked protein into cells. Thus, the proline-rich peptides represent a potentially new class of cell-permeant peptides for intracellular delivery of protein cargo. Furthermore, our results suggest that antimicrobial peptides may represent a rich source of templates for designing cell-permeant peptides.     

Important structural features of 15-residue lactoferricin derivatives and methods for improvement of antimicrobial activity.

This review focuses on important structural features affecting the antimicrobial activity of 15-residue derivatives of lactoferricins. Our investigations are based on an alanine-scan of a 15-residue bovine lactoferricin derivative that revealed the absolute necessity of two tryptophan residues for antimicrobial activity. This "tryptophan-effect" was further explored in homologous derivatives of human, caprine, and porcine lactoferricins by the incorporation of one additional tryptophan residue, and by increasing the content of tryptophan in the bovine derivative to five residues. Most of the resulting peptides display a substantial increase in antimicrobial activity. To identify which molecular properties make tryptophan so effective, a series of bovine lactoferricin derivatives were prepared containing non-encoded unnatural aromatic amino acids, which represented various aspects of the physicochemical nature of tryptophan. The results clearly demonstrate that tryptophan is not unique since most of the modified peptides were of higher antimicrobial potency than the native peptide. The size and three-dimensional shape of the inserted "super-tryptophans" are the most important determinants for the high antimicrobial activity of the modified peptides. This review also describes the use of a "soft-modeling" approach in order to identify important structural parameters affecting the antimicrobial activity of modified 15-residue murine lactoferricin derivatives. This QSAR-study revealed that the net charge, charge asymmetry, and micelle affinity of the peptides were the most important structural parameters affecting their antimicrobial activity.     

Activity optimization of an undecapeptide analogue derived from a frog-skin antimicrobial peptide

While natural antimicrobial peptides are potential therapeutic agents, their physicochemical properties and bioactivity generally need to be enhanced for clinical and commercial development. We have previously developed a cationic, amphipathic α-helical, 11-residue peptide (named herein GA-W2: FLGWLFKWASK-NH₂) with potent antimicrobial and hemolytic activity, which was derived from a 24-residue, natural antimicrobial peptide isolated from frog skin. Here, we attempted to optimize peptide bioactivity by a rational approach to sequence modification. Seven analogues were generated from GA-W2, and their activities were compared with that of a 12-residue peptide, omiganan, which is being developed for clinical and commercial applications. Most of the modifications reported here improved antimicrobial activity. Among them, the GA-K4AL (FAKWAFKWLKK-NH₂) peptide displayed the most potent antimicrobial activity with negligible hemolytic activity, superior to that of omiganan. The therapeutic index of GA-K4AL was improved more than 53- and more than 31-fold against Gram-negative and Gram-positive bacteria, respectively, compared to that of the starting peptide, GA-W2. Given its relatively shorter length and simpler amino acid composition, our sequence-optimized GA-K4AL peptide may thus be a potentially useful antimicrobial peptide agent.     

Antimicrobial activity of the Naja atra cathelicidin and related small peptides

We have identified an 11-residue pattern (KR(F/A)KKFFKK(L/P)K), which we have named the ATRA motif, within the sequence of the Chinese cobra (Naja atra) cathelicidin. A series of 11-residue peptides (ATRA-1, -2, -1A and -1P) were designed to probe the significance of the conserved residues within the ATRA motif, and their contributions to antimicrobial performance. The antimicrobial activities of the peptides were assessed against Escherichia coli K12 strain and Aggregatibacter actinomycetemcomitans Y4. ATRA-1 and -1A, demonstrated potencies comparable to that of N. atra cathelicidin. Structural examination by circular dichroism of the four short peptides suggested the significance of specific amino acid positions within the motif by their contribution to helicity. The results of these studies indicate that short peptides derived from the repeated ATRA motif from the N. atra cathelicidin can demonstrate both low toxicity against host cells and high antimicrobial activity against the gram-negative bacteria used in this study. They constitute novel, effective antimicrobial peptides that are much shorter (and thus less expensive to produce) than the natural cathelicidins, and they may represent new templates for therapeutic drug development.     

Systematic peptide engineering and structural characterization to search for the shortest antimicrobial peptide analogue of gaegurin 5

As part of an effort to develop new, low molecular mass peptide antibiotics, we searched for the shortest bioactive analogue of gaegurin 5 (GGN5), a 24-residue antimicrobial peptide. Thirty-one kinds of GGN5 analogues were synthesized, and their biological activities were analyzed against diverse microorganisms and human erythrocytes. The structural properties of the peptides in various solutions were characterized by spectroscopic methods. The N-terminal 13 residues of GGN5 were identified as the minimal requirement for biological activity. The helical stability, the amphipathic property, and the hydrophobic N terminus were characterized as the important structural factors driving the activity. To develop shorter antibiotic peptides, amino acid substitutions in an inactive 11-residue analogue were examined. Single tryptophanyl substitutions at certain positions yielded some active 11-residue analogues. The most effective site for the substitution was the hydrophobic-hydrophilic interface in the amphipathic helical structure. At this position, tryptophan was the most useful amino acid conferring favorable activity to the peptide. The introduced tryptophan played an important anchoring role for the membrane interaction of the peptides. Finally, two 11-residue analogues of GGN5, which exhibited strong bactericidal activity with little hemolytic activity, were obtained as property-optimized candidates for new peptide antibiotic development. Altogether, the present approach not only characterized some important factors for the antimicrobial activity but also provided useful information about peptide engineering to search for potent lead molecules for new peptide antibiotic development.     

An antimicrobial peptide Ar-AMP from amaranth (Amaranthus retroflexus L.) seeds

A 30-residue antimicrobial peptide Ar-AMP was isolated from the seeds of amaranth Amaranthus retroflexus L. essentially by a single step procedure using reversed-phase HPLC, and its in vitro biological activities were studied. The complete amino acid sequence of Ar-AMP was determined by Edman degradation in combination with mass spectrometric methods. In addition, the cDNA encoding Ar-AMP was obtained and sequenced. The cDNA encodes a precursor protein consisting of the N-terminal putative signal sequence of 25 amino acids, a mature peptide of 30 amino acids and a 34-residue long C-terminal region cleaved during post-translational processing. According to sequence similarity the Ar-AMP belongs to the hevein-like family of antimicrobial peptides with six cysteine residues. In spite of the fact that seeds were collected in 1967 and lost their germination capacity, Ar-AMP retained its biological activities. It effectively inhibited the growth of different fungi tested: Fusarium culmorium (Smith) Sacc., Helminthosporium sativum Pammel., King et Bakke, Alternaria consortiale Fr., and Botrytis cinerea Pers., caused morphological changes in Rhizoctonia solani Kühn at micromolar concentrations and protected barley seedlings from H. sativum infection.     

Deletion of two C-terminal Gln residues of 12-26-residue fragment of melittin improves its antimicrobial activity

In our previous paper it was shown that the two C-terminal Gln residues of a C-terminal 15-residue fragment, Mel(12-26) (GLPALISWIKRKRQQ-NH2), of melittin and a series of individual substituted analogues might not involved in the interaction with bacterial membranes. In this paper, peptides with one and two Gln residues deletion, respectively, Mel(12-25) and Mel(12-24), were synthesized and characterized. Both of the deletion peptides showed higher antimicrobial activities than the parent peptide, Mel(12-26). If both of the Gln residues of Mel(12-26) were respectively replaced by a hydrophilic amino acid Gly, the antimicrobial activity increased slightly. If the Gln residue of Mel(12-25) was replaced by a hydrophobic amino acid Leu, the antimicrobial activity changed little, although the substituted peptide possessed much higher hydrophobicity and higher alpha-helical conformation percentage in 1,1,1,3,3,3-hexafluoro-2-propanol/water determined by circular dichroism spectroscopy (CD) than the parent peptide. These results indicated that the two C-terminal residues might be indeed not involved in the binding to bacterial membranes. The antimicrobial activity increasing with the residue deletion may be caused by the decrease of the translational and rotational entropic cost of the binding of the peptides to bacterial membranes because of the lower molecular weights of the deletion peptides.     

Rational design of alpha-helical antimicrobial peptides with enhanced activities and specificity/therapeutic index

In the present study, the 26-residue peptide sequence Ac-KWKSFLKTFKSAVKTVLHTALKAISS-amide (V681) was utilized as the framework to study the effects of peptide hydrophobicity/hydrophilicity, amphipathicity, and helicity (induced by single amino acid substitutions in the center of the polar and nonpolar faces of the amphipathic helix) on biological activities. The peptide analogs were also studied by temperature profiling in reversed-phase high performance liquid chromatography, from 5 to 80 degrees C, to evaluate the self-associating ability of the molecules in solution, another important parameter in understanding peptide antimicrobial and hemolytic activities. A higher ability to self-associate in solution was correlated with weaker antimicrobial activity and stronger hemolytic activity of the peptides. Biological studies showed that strong hemolytic activity of the peptides generally correlated with high hydrophobicity, high amphipathicity, and high helicity. In most cases, the D-amino acid substituted peptides possessed an enhanced average antimicrobial activity compared with L-diastereomers. The therapeutic index of V681 was improved 90- and 23-fold against Gram-negative and Gram-positive bacteria, respectively. By simply replacing the central hydrophobic or hydrophilic amino acid residue on the nonpolar or the polar face of these amphipathic derivatives of V681 with a series of selected D-/L-amino acids, we demonstrated that this method has excellent potential for the rational design of antimicrobial peptides with enhanced activities.     

Design of antimicrobial peptide arenicin analogs with improved therapeutic indices

β‐Hairpin antimicrobial peptides are among the most potent peptide antibiotics of animal origin. Arenicins, isolated earlier from marine polychaeta lugworm Arenicola marina, belong to a family of β‐hairpin antimicrobial peptides and display a broad spectrum of biological activities. However, despite being potent antimicrobials, arenicins are partially unapplicable as therapeutics as a result of their relatively high cytotoxicity against mammalian cells. In this study, a template‐based approach was used to create therapeutically valuable analogs of arenicin‐1 and identify amino acid residues important for antibacterial and cytotoxic activities of the peptide. The plasmids encoding recombinant analogs were constructed by mutagenesis technique based on inverse PCR amplification of the whole arenicin‐1 expression plasmid. The analogs were produced as a part of the fusion proteins in Escherichia coli. It was shown that an obvious reduction in hemolytic activity without lose of antimicrobial activity can be achieved by a single amino acid substitution in the non‐polar face of the molecule with hydrophilic residues such as serine and arginine. As the result, the selective analog with 50‐fold improved therapeutic index was developed. The circular dichroism spectra demonstrated that the secondary structure of the analog was similar to the natural arenicin‐1 in water solution and sodium dodecyl sulfate micelles but significantly differed in the presence of dodecylphosphocholine micelles mimicking mammalian membranes. Similarly to arenicin‐1, the designed analog killed bacteria via induction of the membrane damage, assessed using the fluorescent dye SYTOX Green uptake. Our results afford molecular insight into mechanism of antimicrobial action of the designed arenicin analogs and their possible clinical application. Copyright © 2014 European Peptide Society and John Wiley & Sons, Ltd.