The appeal of designer peptides is that they are structurally simple and are simple and affordable to produce a large scale. drugs and RNAi. Research has already shown that cationic dipeptides NH2-Phe-Phe-NH2 nanovesicles, which are about 100 nm in diameter, can be absorbed into cells through endocytosis and deliver oligonucleotides into the cell; this is one example of how peptide nanostructure can in used in gene and
drug delivery. It is also envisaged that water-soluble molecules and biological molecules would be able to be delivered to cells in this way. Self-assembling LEGO peptides can form biologically compatible scaffolds for tissue repair and engineering, which should be of great potential, as a large number of diseases cannot be cured by small molecule drugs; a
cell-based therapy approach is needed and peptides could potentially play a huge role in this. Cyclic peptide nanotubes formed from self-assembly can act as
ion channels, which form pores through the cell membrane and cause cellular osmotic collapse. Peptide can be designed to preferentially form on bacterial
cell membranes and thus these tubes can perform as antibacterial and cytotoxin agents.
Molecular electronics applications Molecular 'switch' peptides can be made into nanoswitches when an
electronic component is incorporated. Metal nanocrystals can be covalently linked to the peptides to make them electronically responsive; research is currently being conducted on how to develop electronically controlled molecules and molecular 'machines' using such molecular 'switches'. Peptide nanofibers can also be used as growth templates for a range of inorganic materials, such as silver, gold, platinum, cobalt, nickel, and various semiconducting materials. Electrons transferring aromatic moieties can also be attached to the side chains of peptides to form conducting nanostructures that can transfer electrons in a certain direction. Metal and semiconductor binding peptides have been used for the fabrication of nanowires. Peptides self-assemble into hollow nanotubes to act as casting molds; metal ions that migrate inside the tube undergo reduction to metallic form. The peptide 'mold' can then be enzymatically destroyed to produce a metal nanowire of about 20 nm diameter. This has been done making gold nanowires and this application is especially significant because nanowires at this scale cannot be made by lithography. Researchers have also successfully developed multi-layer nanocables with a silver core nanowire, a peptide insulation layer, and a gold outer coat. This is done by reducing
AgNO3 inside nanotubes, and then bounding a layer of
thiol-containing peptides with gold particles attached. This layer acts as a nucleation site during the next step, where a process of electroless deposition layers a coating of gold on the nanotubes to form metal-insulator-metal trilayer coaxial nanocables. Peptide nanotubes are able to produce nanowires of uniform size, and this is particularly useful in the nano-electric applications as electrical and magnetic properties are sensitive to size. Nanotubes' exceptional
mechanical strength and stability makes them excellent materials for application in this area. Nanotubes have also been used in developing electrochemical biosensing platforms and have proved to have great potential. Dipeptide nanotubes deposited on graphite electrodes improved electrode sensitivity; thiol-modified nanotubes deposited on gold with a coating of enzymes improved sensitivity and reproducibility for the detection of glucose and ethanol, as well as a shortened detection time, large
current density, and improved stability. Nanotubes have also been successfully coated with proteins, nanocrystals, and metalloporphyrin through hydrogen bonding, and these coated tubes have great potential as chemical sensors. Designed peptides with a known structure that would self-assemble into a regular growth template would enable the self-assembly of nanoscale
electronic circuits and devices. However, one issue that has yet to be resolved is the ability to control the positioning of the nanostructures. This positioning relative to substrates, to each other, and to other functional components is crucial. Although progress has been made in this domain, more work has to be completed before this control can be established.
Miscellaneous applications Molecular carpet/paint peptides can be used in diverse industries. They can be used as 'nano-organizers' for non-biological materials, or could be used to study cell-cell communications and behavior. It has also been found that the catalytic abilities of the lipase enzyme is greatly improved when encapsulated in a peptide nanotube. After incubation in a nanotube for a week, the catalytic activities of the enzyme is improved by 33%, compared with free-standing lipases at
room temperature; at 65 °C the improvement rises to 70%. It is suggested that the enhanced ability is due to a
conformational change to an enzymatically active structure. ==Limitations==