An Introduction to Molecular Biotechnology. Группа авторовЧитать онлайн книгу.
described by caption."/>
Figure 5.3 Simplified model of the import and export of proteins via the nuclear pore. The left side represents protein import via a nuclear pore; the right side represents the export of cargo proteins.
5.2 Import of Proteins in Mitochondria, Chloroplasts, and Peroxisomes
Proteins that should function inside the mitochondria or chloroplasts are synthesized as precursor proteins on cytosolic ribosomes and carry a recognition sequence on the N‐terminal (Table 5.1). After uptake by the organelle, this signal sequence is removed by a signal peptidase. The import progresses via a multienzyme complex: the translocase of outer membrane(TOM) complex binds a precursor protein and transports it over the outer mitochondrial membrane. Further transport over the inner mitochondrial membrane is taken over by TIM22 and TIM23 complexes (Figure 5.4). When membrane proteins are imported, they contain an additional signal sequence, which is then recognized by the OXA complex. The OXA complex ensures that membrane proteins, whether synthesized by the mitochondria or imported out of the cytosol, are incorporated correctly in the inner mitochondrial membrane. A SAM complex helps to place proteins in the outer mitochondrial membrane.
Figure 5.4 Schematic overview of the uptake of a precursor protein by the mitochondria and the assembly of membrane proteins in the inner mitochondrial membrane. Eukarya, translocase of outer membranes; TIMs, translocase of inner membranes. (a) Setup of transport systems. (b) Cooperation between Eukarya and TIM complexes. (c) Function of the OXA complex.
Transporting precursor proteins into chloroplasts follows a similar scheme. A second signal is necessary for transport into the thylakoid.
Peroxisomes harbor enzymes to break down hydrogen peroxide (catalase) and the enzymes of β‐oxidation of fatty acids. Proteins targeted for peroxisomes carry a short signal peptide of three amino acids (Ser‐Lys‐Leu) on their C‐terminus. Peroxisomes carry a complex of protein translocators, peroxins (e.g. Pex1, Pex5, Pex6, Pex7), which are activated by adenosine triphosphate (ATP).
5.3 Protein Transport into the Endoplasmic Reticulum
In electron microscope photographs, the rough ER is recognized by its large number of ribosomes, which look as if they are tightly bound to the ER membrane (Figure 1.2). These ribosomes are in the process of synthesizing proteins, which are then secreted into the ER lumen. These proteins are characterized by a specific signal peptide in the N‐terminal (Table 5.1).
In principle, protein biosynthesis begins on the free ribosomes in the cytoplasm. When a protein exhibiting an ER import signal peptide is synthesized, a signal recognition particle(SRP) will bind to the signal sequence. In the next step, SRP binds an SRP receptor present at the ER membrane and therefore brings the translating ribosome into the vicinity of a protein translocator(consisting of Sec61, 62, 63, 71, and 72). Figure 5.5 schematically shows the import of a protein into the ER lumen. As soon as a protein is completely synthesized and the C‐terminal of the protein has arrived in the ER lumen, a signal peptidase cleaves the signal recognition sequence, and the protein is freed into the ER lumen.
Figure 5.5 Simplified scheme of the import of a protein into the ER lumen.
The import of membrane proteins is similar. The growing polypeptide chain is internalized until a second signal sequence, which corresponds to a transmembrane domain, is reached (Figure 5.6). The cleavage of the first signal sequence results in a transmembrane protein with a transmembrane region. The C‐terminal lies in the cytosol and the N‐terminal in the ER lumen. The formation of membrane proteins with many transmembrane regions occurs in a similar way. Some proteins (including SNARE) are anchored in the ER membrane by a C‐terminal hydrophobic α‐helix.
Figure 5.6 Simplified scheme of the integration of a membrane protein into the ER membrane.
Proteins that remain in the ER and are not channeled out through the Golgi apparatus have a retention signal at the C‐terminal. Such ER proteins serve, among others, as chaperones. Misfolded proteins are exported into the cytosol where they are degraded by the proteasome.
Upon entry into the ER, most proteins that are to be exported are coupled with an oligosaccharide residue. An oligosaccharide is linked to an asparagine residue via an N‐glycosidic bond. Oligosaccharides with 14 sugar residues (above all those containing N‐acetylglucosamine, mannose, and glucose) are present as dolichol diphosphate esters in the activated form, in which the lipophilic dolichol residue is anchored in the biomembrane (Figure 5.7). Also present in the cell are glycoproteins whose sugar residues are linked to threonine or serine with an O‐glycosidic bond. Their synthesis occurs in the Golgi apparatus and not in the ER. The sugar residues are altered again in the different compartments of the Golgi apparatus, where they obtain their final specificity.
Figure 5.7 Assembly of glycoproteins in the ER. The oligosaccharide exists as a dolichol diphosphate ester in its activated form and can be transferred onto an asparagine residue of the growing peptide chain.
A few proteins are associated with the cell membrane. This usually occurs through a glycosylphosphatidylinositol(GPI) anchor, which can be attached to the C‐terminal of a protein.
5.4 Vesicle Transport from the ER via the Golgi Apparatus to the Cytoplasmic Membrane
The