Some fusion proteins combine whole peptides and therefore contain all
functional domains of the original proteins. However, other fusion proteins, especially those that occur naturally, combine only portions of coding sequences and therefore do not maintain the original functions of the parental genes that formed them. Many whole gene fusions are fully functional and can still act to replace the original peptides. Some, however, experience interactions between the two proteins that can modify their functions. Beyond these effects, some gene fusions may cause
regulatory changes that alter when and where these genes act. For
partial gene fusions, the shuffling of different active sites and binding domains have the potential to result in new proteins with novel functions. '' worms to track neuronal development
Fluorescent protein tags The fusion of
fluorescent tags to proteins in a host cell is a widely popular technique used in experimental cell and biology research in order to track protein interactions in real time. The first fluorescent tag,
green fluorescent protein (GFP), was isolated from
Aequorea victoria and is still used frequently in modern research. More recent derivations include photoconvertible fluorescent proteins (PCFPs), which were first isolated from
Anthozoa. The most commonly used PCFP is the
Kaede fluorescent tag, but the development of Kikume green-red (KikGR) in 2005 offers a brighter signal and more efficient photoconversion. The advantage of using PCFP fluorescent tags is the ability to track the interaction of overlapping biochemical pathways in real time. The tag will change color from green to red once the protein reaches a point of interest in the pathway, and the alternate colored protein can be monitored through the duration of pathway. This technique is especially useful when studying
G-protein coupled receptor (GPCR) recycling pathways. The fates of recycled G-protein receptors may either be sent to the
plasma membrane to be recycled, marked by a green fluorescent tag, or may be sent to a
lysosome for degradation, marked by a red fluorescent tag.
Chimeric protein drugs (bottom-left) monoclonal antibodies. Human parts are shown in brown, and non-human parts in blue. The purpose of creating fusion proteins in
drug development is to impart properties from each of the "parent" proteins to the resulting chimeric protein. Several chimeric protein
drugs are currently available for medical use. Many chimeric protein drugs are
monoclonal antibodies whose specificity for a
target molecule was developed using mice and hence were initially "mouse" antibodies. As non-human proteins, mouse antibodies tend to evoke an
immune reaction if administered to humans. The chimerization process involves
engineering the replacement of segments of the antibody molecule that distinguish it from a human antibody. For example, human
constant domains can be introduced, thereby eliminating most of the potentially
immunogenic portions of the drug without altering its specificity for the intended therapeutic target.
Antibody nomenclature indicates this type of modification by inserting
-xi- into the
non-proprietary name (e.g.,
abci-xi-mab). If parts of the variable domains are also replaced by human portions,
humanized antibodies are obtained. Although not conceptually distinct from chimeras, this type is indicated using
-zu- such as in
dacli-zu-mab. See the
list of monoclonal antibodies for more examples. In addition to chimeric and humanized antibodies, there are other pharmaceutical purposes for the creation of chimeric constructs.
Etanercept, for example, is a
TNFα blocker created through the combination of a
tumor necrosis factor receptor (TNFR) with the
immunoglobulin G1
Fc segment. TNFR provides specificity for the drug target and the antibody Fc segment is believed to add stability and deliverability of the drug. ==Recombinant technology==