Ribophorins are dome shaped transmembrane glycoproteins which are located in the membrane of the rough endoplasmic reticulum, but are absent in the membrane of the smooth endoplasmic reticulum. There are two types of ribophorines: ribophorin I and II. These act in the protein complex oligosaccharyltransferase (OST) as two different subunits of the named complex. Ribophorin I [1] and II [2] are only present in eukaryote cells.
Both types of ribophorins develop a key role in the binding of ribosomes to the rough endoplasmic reticulum as well as in the co-translational processes that depend on this interaction. The content of ribophorin of the rough endoplasmic reticulum is equal to the stoichiometric number of ribosomal units. Therefore, this suggests the great importance, abundance and good preservation of these proteins in the reticulum. Consequently, defects in the genes that encode these proteins may cause congenital disorders and devastating consequences; ribophorin I and II are encoded by the genes RPN1 and RPN2 respectively.[ citation needed ]
The ribophorins are soluble in non-ionic detergents such as Triton X-100.
There two types of ribophorin: ribophorin I and ribophorin II; because of that, each one its own characteristics, despite the fact that both ribophorins have some common characteristics. This way, ribophorin I has a different structure in comparison to ribophorin II.[ citation needed ]
This subunit of the oligosaccharyltransferase (OST) is formed by 1821 pairs of bases, which is about 607 aminoacids. Its molecular weight is 68550,8 daltons.[ citation needed ]
When anchored to the membrane, 75% of its amino acids are at the lumen of the endoplasmic reticulum or in it. Its signal sequence, eliminated when the protein has matured, is formed by 23 amino acids and has a negative charge, which is very unusual. The rest of the amino acids of the mature protein (584 AA) are distributed in this way: from AA 1 to 415 they are located at the lumen of the ER, from 416 to 434 are anchored at the membrane of the organelle, and the others in the cytoplasm.[ citation needed ]
The other subunit of the OST is formed by 1896 pairs of bases, which is equivalent to 632 amino acids. Its molecular weight is about 69283’4 daltons. In ribophorin II, the 90% of the amino acids are located at the membrane or at the lumen of the endoplasmic reticulum. As the ribophorin I, it also shows a signal sequence, but this one is formed by 22 AA, with a negative charge too. [ citation needed ]
The distribution of the rest is as follows: from AA 1 to 516 are at the lumen, from 517 to 539 at the membrane (as an anchorage) and the last 70 at the cytoplasm. In this case the asparagine which is glycosylated is the number 84 AA. The ribophorin II is completely resistant to a great variety of proteases.[ citation needed ]
Ribophorins are only found in mammal cells, where they are positioned in the membrane of the rough endoplasmic reticulum. They interact with the ribosome during protein translocation into the ER.[ citation needed ]
Both ribophorin I and II possess a type I membrane topology with the bulk of their polypeptide chains directed towards the ER-lumen and they are part of the mammalian protein complex OST; this complex affects the cotranslational N-glycosylation of newly synthesized polypeptides, and is composed by four RER specific membrane proteins, which are the ribophorins (I and II), the OST48 and the Dadl. In order to form the OST complex, there are specific interactions between the proteins; because of that, the lumen domains of ribophorin I and II interact with the lumen domain of OST48. Nevertheless, there is not a direct interaction between both ribophorins.[ citation needed ]
As they are transmembrane proteins, ribophorins cross the ER membrane and, so that, the protein has a cytoplasmic, a transmembrane and a lumen domain. In the case of the ribophorin II, the transmembrane and the cytoplasmic domains are the ones that have the retention function on the ER; but on the other hand, the lumen domain is the one with the retention function for ribophorin I.[ citation needed ]
Ribophorin I resides in the ER membrane with a single spanning sequence from amino acids 416 to 434, having a cytoplasmic C terminus of 150 amino acids and a luminal N-terminal domain consisting of 415 residues. Ribophotin II is disposed on a similar way in the ER membrane, but now the membrane-spanning domain is located at residues 517-539 and asparagine residues 544 and 547 would be disposed at the cytoplasm leaving only Asn84 as the putative site for oligosaccharide addition; the cytoplasmic domain will have a maximum length of 70 residues.[ citation needed ]
Ribophorins possess signal sequences that localize them preferentially to the ER membrane.[ citation needed ]
Ribophorins I and II, transmembrane glycoprotein of the rough endoplasmic reticulum, intervene in the union of the ribosomes (they fix the large subunit, 60S, of the ribosome) to the RE membrane, and they play an important role in the co-translational translocation process which depends on this union, as the com insertion of the nascent polypeptide to the membrane or their transference to the lumen of the cistern; this is the translocation of proteins generated by polyribosomes.[ citation needed ]
Ribophorin I usually interacts with those proteins that have a wrong folding; otherwise, this protein does not interact with native state proteins. This suggests that ribophorin I may work as a chaperone that recognizes the proteins with a wrong folding. Moreover, this ribophorin can regulate the delivery of precursor proteins to the oligosaccharyltransferase (main enzyme of the N-glycosylation for proteins), through the capture of substrates and taking them to the catalytic center. So that, ribophorin I can keep those possible substrates in the proximity of the catalytic subunit of the enzyme; this way, the efficiency of the N-glycosylation reaction will improve during their biogenesis in the ER. But ribophorin I only changes drastically the N-glycosylation of determined substrates, as it is apparently dispensable in the same process with other substrates. When ribophorin is not essential, these precursors have shortcut to the catalytic center of the oligosaccharyltransferase or their presence depends on the rest of the non-catalytic subunits in the complex. It shows the specificity of ribophorin I for determined substrates; so that, this protein will regulate selectively the delivery of substrates to the catalytic center of the oligosaccharyltransferase complex.[ citation needed ]
Although ribophorin II is still a protein quite unknown, it has been discovered that this ribophorin is part of an N-oligosaccharyltransferase complex that links high mannose oligosaccharides to asparagine residues found in the Asn-X-Ser/Thr consensus motif of nascent polypeptide chains. Moreover, this protein takes part in the identification of retention signals of other proteins.[ citation needed ]
There is not much information about ribophorin II because this subunit of the complex hasn’t been as investigated as ribophorin I.[ citation needed ]
Protein synthesis of ribophorins is carried out in the cytoplasm. Ribophorin I is encoded by the RPN1 gene, whereas ribophorin II is encoded by the RPN2 gene. Moreover, each gene encodes a signal sequence to indicate the ribophorin cellular localization. In humans, the sequence is formed by 23 amino acids in ribophorin I; and 22 amino acids in ribophorin II.[ citation needed ]
In the chromosome, the genes are found in a specific locus. In humans, RPN1 is located at 3q21.3 (in chromosome 3) and RPN2 is found at the locus 20q12-q13.1 (in chromosome 20). In total, ribophorin I and II are composed by 607 and 632 amino acids, respectively.[ citation needed ]
The endoplasmic reticulum (ER) is, in essence, the transportation system of the eukaryotic cell, and has many other important functions such as protein folding. It is a type of organelle made up of two subunits – rough endoplasmic reticulum (RER), and smooth endoplasmic reticulum (SER). The endoplasmic reticulum is found in most eukaryotic cells and forms an interconnected network of flattened, membrane-enclosed sacs known as cisternae, and tubular structures in the SER. The membranes of the ER are continuous with the outer nuclear membrane. The endoplasmic reticulum is not found in red blood cells, or spermatozoa.
The endomembrane system is composed of the different membranes that are suspended in the cytoplasm within a eukaryotic cell. These membranes divide the cell into functional and structural compartments, or organelles. In eukaryotes the organelles of the endomembrane system include: the nuclear membrane, the endoplasmic reticulum, the Golgi apparatus, lysosomes, vesicles, endosomes, and plasma (cell) membrane among others. The system is defined more accurately as the set of membranes that form a single functional and developmental unit, either being connected directly, or exchanging material through vesicle transport. Importantly, the endomembrane system does not include the membranes of plastids or mitochondria, but might have evolved partially and from the actions of the latter.
Protein targeting or protein sorting is the biological mechanism by which proteins are transported to their appropriate destinations within or outside the cell. Proteins can be targeted to the inner space of an organelle, different intracellular membranes, the plasma membrane, or to the exterior of the cell via secretion. Information contained in the protein itself directs this delivery process. Correct sorting is crucial for the cell; errors have been linked to multiple disease-states.
In molecular biology and genetics, translation is the process in which ribosomes in the cytoplasm or endoplasmic reticulum synthesize proteins after the process of transcription of DNA to RNA in the cell's nucleus. The entire process is called gene expression.
A signal peptide is a short peptide present at the N-terminus of most newly synthesized proteins that are destined toward the secretory pathway. These proteins include those that reside either inside certain organelles, secreted from the cell, or inserted into most cellular membranes. Although most type I membrane-bound proteins have signal peptides, the majority of type II and multi-spanning membrane-bound proteins are targeted to the secretory pathway by their first transmembrane domain, which biochemically resembles a signal sequence except that it is not cleaved. They are a kind of target peptide.
The translocon is a complex of proteins associated with the translocation of polypeptides across membranes. In eukaryotes the term translocon most commonly refers to the complex that transports nascent polypeptides with a targeting signal sequence into the interior space of the endoplasmic reticulum (ER) from the cytosol. This translocation process requires the protein to cross a hydrophobic lipid bilayer. The same complex is also used to integrate nascent proteins into the membrane itself. In prokaryotes, a similar protein complex transports polypeptides across the (inner) plasma membrane or integrates membrane proteins. In either case, the protein complex are formed from Sec proteins, with the hetrotrimeric Sec61 being the channel. In prokaryotes, the homologous channel complex is known as SecYEG.
COPI is a coatomer, a protein complex that coats vesicles transporting proteins from the cis end of the Golgi complex back to the rough endoplasmic reticulum (ER), where they were originally synthesized, and between Golgi compartments. This type of transport is retrograde transport, in contrast to the anterograde transport associated with the COPII protein. The name "COPI" refers to the specific coat protein complex that initiates the budding process on the cis-Golgi membrane. The coat consists of large protein subcomplexes that are made of seven different protein subunits, namely α, β, β', γ, δ, ε and ζ.
The C-terminus is the end of an amino acid chain, terminated by a free carboxyl group (-COOH). When the protein is translated from messenger RNA, it is created from N-terminus to C-terminus. The convention for writing peptide sequences is to put the C-terminal end on the right and write the sequence from N- to C-terminus.
Sec61, termed SecYEG in prokaryotes, is a membrane protein complex found in all domains of life. As the core component of the translocon, it transports proteins to the endoplasmic reticulum in eukaryotes and out of the cell in prokaryotes. It is a doughnut-shaped pore through the membrane with 3 different subunits (heterotrimeric), SecY (α), SecE (γ), and SecG (β). It has a region called the plug that blocks transport into or out of the ER. This plug is displaced when the hydrophobic region of a nascent polypeptide interacts with another region of Sec61 called the seam, allowing translocation of the polypeptide into the ER lumen.
Oligosaccharyltransferase or OST (EC 2.4.1.119) is a membrane protein complex that transfers a 14-sugar oligosaccharide from dolichol to nascent protein. It is a type of glycosyltransferase. The sugar Glc3Man9GlcNAc2 (where Glc=Glucose, Man=Mannose, and GlcNAc=N-acetylglucosamine) is attached to an asparagine (Asn) residue in the sequence Asn-X-Ser or Asn-X-Thr where X is any amino acid except proline. This sequence is called a glycosylation sequon. The reaction catalyzed by OST is the central step in the N-linked glycosylation pathway.
TRAPP is a protein involved in particle transport between organelles.
Signal recognition particle (SRP) receptor, also called the docking protein, is a dimer composed of 2 different subunits that are associated exclusively with the rough ER in mammalian cells. Its main function is to identify the SRP units. SRP is a molecule that helps the ribosome-mRNA-polypeptide complexes to settle down on the membrane of the endoplasmic reticulum.
Endoplasmic-reticulum-associated protein degradation (ERAD) designates a cellular pathway which targets misfolded proteins of the endoplasmic reticulum for ubiquitination and subsequent degradation by a protein-degrading complex, called the proteasome.
Dolichyl-diphosphooligosaccharide—protein glycosyltransferase subunit 2, also called ribophorin ǁ is an enzyme that in humans is encoded by the RPN2 gene.
Dolichyl-diphosphooligosaccharide—protein glycosyltransferase 48 kDa subunit is an enzyme that in humans is encoded by the DDOST gene.
N-linked glycosylation, is the attachment of an oligosaccharide, a carbohydrate consisting of several sugar molecules, sometimes also referred to as glycan, to a nitrogen atom, in a process called N-glycosylation, studied in biochemistry. This type of linkage is important for both the structure and function of many eukaryotic proteins. The N-linked glycosylation process occurs in eukaryotes and widely in archaea, but very rarely in bacteria. The nature of N-linked glycans attached to a glycoprotein is determined by the protein and the cell in which it is expressed. It also varies across species. Different species synthesize different types of N-linked glycan.
In molecular biology, OST4 is a subunit of the oligosaccharyltransferase complex. OST4 is a very short, approximately 30 amino acids, protein found from fungi to vertebrates. It appears to be an integral membrane protein that mediates the en bloc transfer of a pre-assembled high-mannose oligosaccharide onto asparagine residues of nascent polypeptides as they enter the lumen of the rough endoplasmic reticulum.
KKXX and for some proteins XKXX is a target peptide motif located in the C terminus in the amino acid structure of a protein responsible for retrieval of endoplasmic reticulum (ER) membrane proteins to and from the Golgi apparatus. These ER membrane proteins are transmembrane proteins that are then embedded into the ER membrane after transport from the Golgi. This motif is exclusively cytoplasmic and interacts with the COPI protein complex to target the ER from the cis end of the Golgi apparatus by retrograde transport.
A single-pass membrane protein also known as single-spanning protein or bitopic protein is a transmembrane protein that spans the lipid bilayer only once. These proteins may constitute up to 50% of all transmembrane proteins, depending on the organism, and contribute significantly to the network of interactions between different proteins in cells, including interactions via transmembrane alpha helices. They usually include one or several water-soluble domains situated at the different sides of biological membranes, for example in single-pass transmembrane receptors. Some of them are small and serve as regulatory or structure-stabilizing subunits in large multi-protein transmembrane complexes, such as photosystems or the respiratory chain. A 2013 estimate identified about 1300 single-pass membrane proteins in the human genome.
William Joseph Lennarz was a biochemist at Stony Brook University. He was born in May 1934 in New York City. Before Lennarz began his tenure at Stony Brook, he studied chemistry and organic chemistry. After working as a postdoctoral researcher at Harvard, he developed an interest in biochemistry. He has focused the majority of his research on biochemical processes in cells.
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