DNA repair protein RAD51 homologue 2 (also known as RAD51B) is a Rad51 paralogue. The Rad51 paralogues are required for homologous recombination (HR) and the maintenance of genomic stability. RAD51B is involved in the repair of double-strand DNA breaks (DSBs) via HR []. It is part of the Rad51B-Rad51C-Rad51D-XRCC2 (BCDX2) complex, which acts in the BRCA1-BRCA2-dependent HR pathway [, ]. It has DNA-dependent ATPase activity and can bind single-stranded and double-stranded DNA []. Rad51B may have a specific function in Holliday junction processing in the HR pathway [].
RFWD3 is a RING-type E3 ubiquitin-protein ligase required for the repair of DNA interstrand cross-links (ICL) in response to DNA damage [, , ].During ICL repair, single-stranded DNA (ssDNA) is generated. The trimeric ssDNA binding protein complex RPA coats the ssDNA. Subsequently, RAD51 is loaded onto RPA-bound ssDNA and catalyzes the critical activity in homologous recombination (HR). RFWD3 polyubiquitinates both RPA and RAD5, which increases their local turnover in DNA damage-induced foci to facilitate HR []. RFWD3-mediated ubiquitination of RPA has been shown to be essential for HR [].
This entry includes DNA double-strand break repair protein Mre11 mainly from archaea. Similar to the eukaryotic Mre11-Rad50 complex, the archaeal Mre11-Rad50 complex is involved in the early steps of DNA double-strand break (DSB) repair. The Haloferax volcanii Mre11-Rad50 complex may restrain the repair of DSBs by HR (homologous recombination), allowing another pathway to act as the primary mode of repair [].
Plants are attacked by a range of phytopathogenic organisms, including viruses, mycoplasma, bacteria, fungi, nematodes, protozoa and parasites. Resistance to a pathogen is manifested in several ways and is often correlated with a hypersensitive response (HR), localised induced cell death in the host plant at the site of infection [, ]. The induction of the plant defence response that leads to HR is initiated by the plants recognition of specific signal molecules (elicitors) produced by the pathogen; R genes are thought to encode receptors for these elicitors. RPS2, N and L6 genes confer resistance to bacterial, viral and fungal pathogens.Sequence analysis has shown that they contain C-terminal leucine-rich repeats, which are characteristic of plant and animal proteins involved in protein-protein interactions []. In addition, the sequences contain a conserved nucleotide-binding site towards their N-terminal.This entry represents a group of plant disease resistance proteins.
Macroautophagy is a bulk degradation process induced by starvation in eukaryotic cells. In yeast, 15 Atg proteins coordinate the formation of autophagosomes. The pre-autophagosomal structure contains at least five Atg proteins: Atg1p, Atg2p, Atg5p, Aut7p/Atg8p and Atg16p, found in the vacuole [, ]. The C-terminal glycine of Atg12p is conjugated to a lysine residue of Atg5p via an isopeptide bond. During autophagy, cytoplasmic components are enclosed in autophagosomes and delivered to lysosomes/vacuoles. Autophagy protein 16 (Atg16) has been shown to bind to Atg5 and is required for the function of the Atg12p-Atg5p conjugate []. Autophagy protein 5 (Atg5) is directly required for the import of aminopeptidase I via the cytoplasm-to-vacuole targeting pathway [].Atg5 comprises two ubiquitin-like domains that flank a helix-rich domain. The N- and C-terminal ubiquitin-like domains are called UblA and UblB, respectively, and the helix-rich domain between UblA and UblB, is called HR. Both UblA and UblB comprise a five-stranded -sheet and two-helices, which is a conserved feature in all ubiquitin superfamily proteins. The HR domain consists of three alpha helices [].This superfamily represents the UblA domain.
Macroautophagy is a bulk degradation process induced by starvation in eukaryotic cells. In yeast, 15 Atg proteins coordinate the formation of autophagosomes. The pre-autophagosomal structure contains at least five Atg proteins: Atg1p, Atg2p, Atg5p, Aut7p/Atg8p and Atg16p, found in the vacuole [, ]. The C-terminal glycine of Atg12p is conjugated to a lysine residue of Atg5p via an isopeptide bond. During autophagy, cytoplasmic components are enclosed in autophagosomes and delivered to lysosomes/vacuoles. Autophagy protein 16 (Atg16) has been shown to bind to Atg5 and is required for the function of the Atg12p-Atg5p conjugate []. Autophagy protein 5 (Atg5) is directly required for the import of aminopeptidase I via the cytoplasm-to-vacuole targeting pathway [].Atg5 comprises two ubiquitin-like domains that flank a helix-rich domain. The N- and C-terminal ubiquitin-like domains are called UblA and UblB, respectively, and the helix-rich domain between UblA and UblB, is called HR. Both UblA and UblB comprise a five-stranded -sheet and two-helices, which is a conserved feature in all ubiquitin superfamily proteins. The HR domain consists of three alpha helices [].This superfamily represents the helix rich domain (HR) found in Atg5.
Arabidopsis RPW8.1 and RPW8.2 genes confer broad-spectrum resistance to powdery mildew [, ]. RPW8.2 is specifically targeted to the extrahaustorial membrane (EHM), where it activates haustorium-targeted resistance against powdery mildew []. This family consists of RPW81 and RPW8.2, and homologues of RPW8 (HR), also known as RPW8-like proteins. HRs also contribute to basal resistance to powdery mildew, and HR1 to HR3 have been shown to localize to the EHM, suggesting that this could be a feature of the family [].Plants are attacked by a range of phytopathogenic organisms, including viruses, mycoplasma, bacteria, fungi, nematodes, protozoa and parasites. Resistance to a pathogen is manifested in several ways and is often correlated with a hypersensitive response (HR), localised induced cell death in the host plant at thesite of infection [, ]. The induction of the plant defence response that leads to HR is initiated by the plants recognition of specific signal molecules (elicitors) produced by the pathogen; R genes are thought to encode receptors for these elicitors. RPS2, N and L6 genes confer resistance to bacterial, viral and fungal pathogens.Sequence analysis has shown that they contain C-terminal leucine-rich repeats, which are characteristic of plant and animal proteins involved in protein-protein interactions []. In addition, the sequences contain a conserved nucleotide-binding site towards their N-terminal.
The type I glycoprotein S of Coronavirus, trimers of which constitute the typical viral spikes, is assembled into virions through noncovalent interactions with the M protein. The spike glycoprotein is translated as a large polypeptide that is subsequently cleaved to S1 and S2 []. The cleavage of S can occur at two distinct sites: S2 or S2' []. The S1 subunit is responsible for host-receptor binding while the S2 subunit contains the membrane-fusion machinery [].Both chimeric S proteins appeared to cause cell fusion when expressed individually, suggesting that they were biologically fully active []. The spike is a type I membrane glycoprotein that possesses a conserved transmembrane anchor and an unusual cysteine-rich (cys) domain that bridges the putative junction of the anchor and the cytoplasmic tail [].The S2 subunit normally contains multiple key components, including one or more fusion peptides (FP), a second proteolytic site (S2') and two conserved heptad repeats (HRs), driving membrane penetration and virus-cell fusion. The HRs can trimerize into a coiled-coil structure built of three HR1-HR2 helical hairpins presenting as a canonical six-helix bundle and drag the virus envelope and the host cell bilayer into close proximity, preparing for fusion to occur []. The fusion core is composed of HR1 and HR2 and at least three membranotropic regions that are denoted as the fusion peptide (FP), internal fusion peptide (IFP), and pretransmembrane domain (PTM). The HR regions are further flanked by the three membranotropic components. Both FP and IFP are located upstream of HR1, while PTM is distally downstream of HR2 and directly precedes the transmembrane domain of SARS-CoV S. All of these three components are able to partition into the phospholipid bilayer to disturb membrane integrity. []. During the pandemic, many conservative amino acid changes in FP segment of SARS-CoV-2 have been reported (i.e., L821I, L822F, K825R, V826L, T827I, L828P, A829T, D830G/A, A831V/S/T, G832C/S, F833S, I834T), although their impact is not known as the active conformation and mode of insertion of SARS-CoV-2 fusion peptide have not been experimentally characterised. Differences in HR1 sequences between SARS-CoV and SARS-CoV-2 suggest that SARS-CoV-2 HR2 makes stronger interactions with HR1. However, the substitutions observed in the solvent accessible surface of the HR1 domain (e.g., D936Y, S943P, S939F) of SARS-CoV-2 do not seem to be involved in stabilizing interactions with HR2. Substitutions in HR2 (e.g., K1073N, V1176F) or the TM or cytoplasmic tail domains have also been observed, but further experimental work is required to determine the effects of these changes [].
The type I glycoprotein S of Coronavirus, trimers of which constitute the typical viral spikes, is assembled into virions through noncovalent interactions with the M protein. The spike glycoprotein is translated as a large polypeptide that is subsequently cleaved to S1 () and S2 []. The cleavage of S can occur at two distinct sites: S2 or S2' []. The spike is present in two very different forms: pre-fusion (the form on mature virions) and post-fusion (the form after membrane fusion has been completed). The spike is cleaved sequentially by host proteases at two sites: first at the S1/S2 boundary (i.e. S1/S2 site) and second within S2 (i.e. S2' site). After the cleavages, S1 dissociates from S2, allowing S2 to transition to the post-fusion structure []. Both chimeric S proteins appeared to cause cell fusion when expressed individually, suggesting that they were biologically fully active []. The spike is a type I membrane glycoprotein that possesses a conserved transmembrane anchor and an unusual cysteine-rich (cys) domain that bridges the putative junction of the anchor and the cytoplasmic tail [].SARS-CoV S is largely uncleaved after biosynthesis. It can be later processed by endosomal cathepsin L, trypsin, thermolysin, and elastase, which are shown to induce syncytia formation and virus entry. Other proteases that are of potential biological relevance in potentiating SARS-CoV S include TMPRSS2, TMPRSS11a, and HAT which are localized on the cell surface and are highly expressed in the human airway []. The furin-like S2' cleavage site at KR/SF with P1 and P2 basic residues and a P2' hydrophobic Phe downstream of the IFP is identical between the SARS-CoV-2 and SARS-CoV. One or more furin-like enzymes would cleave the S2' site at KR/SF [, ]. Deletion of SARS-CoV-2 furin cleavage site suggests that it may not be required for viral entry but may affect replication kinetics and altered sites have been still seen proteolytically cleaved. Several substitutions within the S2' cleavage domain of SARS-COV-2 have been reported, including P812L/S/T, S813I/G, F817L, I818S/V, but further experimental study of their consequences and the replication properties of the altered viruses are required to understand the role of furin cleavage in SARS-CoV-2 infection and virulence []. The S2 subunit normally contains multiple key components, including one or more fusion peptides (FP), a second proteolytic site (S2') and two conserved heptad repeats (HRs), driving membrane penetration and virus-cell fusion. The HRs can trimerize into a coiled-coil structure built of three HR1-HR2 helical hairpins presenting as a canonical six-helix bundle and drag the virus envelope and the host cell bilayer into close proximity, preparing for fusion to occur []. The fusion core is composed of HR1 and HR2 and at least three membranotropic regions that are denoted as the fusion peptide (FP), internal fusion peptide (IFP), and pretransmembrane domain (PTM). The HR regions are further flanked by the three membranotropic components. Both FP and IFP are located upstream of HR1, while PTM is distally downstream of HR2 and directly precedes the transmembrane domain of SARS-CoV S. All of these three components are able to partition into the phospholipid bilayer to disturb membrane integrity. []. During the pandemic, many conservative amino acid changes in FP segment of SARS-CoV-2 have been reported (i.e., L821I, L822F, K825R, V826L, T827I, L828P, A829T, D830G/A, A831V/S/T, G832C/S, F833S, I834T), although their impact is not known as the active conformation and mode of insertion of SARS-CoV-2 fusion peptide have not been experimentally characterised. Differences in HR1 sequences between SARS-CoV and SARS-CoV-2 suggest that SARS-CoV-2 HR2 makes stronger interactions with HR1. However, the substitutions observed in the solvent accessible surface of the HR1 domain (e.g., D936Y, S943P, S939F) of SARS-CoV-2 do not seem to be involved in stabilizing interactions with HR2. Substitutions in HR2 (e.g., K1073N, V1176F) or the TM or cytoplasmic tail domains have also been observed, but further experimental work is required to determine the effects of these changes [].
The type I glycoprotein S of Coronavirus, trimers of which constitute the typical viral spikes, is assembled into virions through noncovalent interactions with the M protein. The spike glycoprotein is translated as a large polypeptide that is subsequently cleaved to S1 () and S2 []. The cleavage of S can occur at two distinct sites: S2 or S2' []. The spike is present in two very different forms: pre-fusion (the form on mature virions) and post-fusion (the form after membrane fusion has been completed). The spike is cleaved sequentially by host proteases at two sites: first at the S1/S2 boundary (i.e. S1/S2 site) and second within S2 (i.e. S2' site). After the cleavages, S1 dissociates from S2, allowing S2 to transition to the post-fusion structure []. Both chimeric S proteins appeared to cause cell fusion when expressed individually, suggesting that they were biologically fully active []. The spike is a type I membrane glycoprotein that possesses a conserved transmembrane anchor and an unusual cysteine-rich (cys) domain that bridges the putative junction of the anchor and the cytoplasmic tail [].SARS-CoV S is largely uncleaved after biosynthesis. It can be later processed by endosomal cathepsin L, trypsin, thermolysin, and elastase, which are shown to induce syncytia formation and virus entry. Other proteases that are of potential biological relevance in potentiating SARS-CoV S include TMPRSS2, TMPRSS11a, and HAT which are localized on the cell surface and are highly expressed in the human airway []. The furin-like S2' cleavage site at KR/SF with P1 and P2 basic residues and a P2' hydrophobic Phe downstream of the IFP is identical between the SARS-CoV-2 and SARS-CoV. One or more furin-like enzymes would cleave the S2' site at KR/SF [, ]. Deletion of SARS-CoV-2 furin cleavage site suggests that it may not be required for viral entry but may affect replication kinetics and altered sites have been still seen proteolytically cleaved. Several substitutions within the S2' cleavage domain of SARS-COV-2 have been reported, including P812L/S/T, S813I/G, F817L, I818S/V, but further experimental study of their consequences and the replication properties of the altered viruses are required to understand the role of furin cleavage in SARS-CoV-2 infection and virulence []. The S2 subunit normally contains multiple key components, including one or more fusion peptides (FP), a second proteolytic site (S2') and two conserved heptad repeats (HRs), driving membrane penetration and virus-cell fusion. The HRs can trimerize into a coiled-coil structure built of three HR1-HR2 helical hairpins presenting as a canonical six-helix bundle and drag the virus envelope and the host cell bilayer into close proximity, preparing for fusion to occur []. The fusion core is composed of HR1 and HR2 and at least three membranotropic regions that are denoted as the fusion peptide (FP), internal fusion peptide (IFP), and pretransmembrane domain (PTM). The HR regions are further flanked by the three membranotropic components. Both FP and IFP are located upstream of HR1, while PTM is distally downstream of HR2 and directly precedes the transmembrane domain of SARS-CoV S. All of these three components are able to partition into the phospholipid bilayer to disturb membrane integrity. []. During the pandemic, many conservative amino acid changes in FP segment of SARS-CoV-2 have been reported (i.e., L821I, L822F, K825R, V826L, T827I, L828P, A829T, D830G/A, A831V/S/T, G832C/S, F833S, I834T), although their impact is not known as the active conformation and mode of insertion of SARS-CoV-2 fusion peptide have not been experimentally characterised. Differences in HR1 sequences between SARS-CoV and SARS-CoV-2 suggest that SARS-CoV-2 HR2 makes stronger interactions with HR1. However, the substitutions observed in the solvent accessible surface of the HR1 domain (e.g., D936Y, S943P, S939F) of SARS-CoV-2 do not seem to be involved in stabilizing interactions with HR2. Substitutions in HR2 (e.g., K1073N, V1176F) or the TM or cytoplasmic tail domains have also been observed, but further experimental work is required to determine the effects of these changes [].This entry represents the cysteine rich intravirion region found at the C-terminal of coronavirus spike proteins (S) []. These cysteine residues are targets for palmitoylation, necessary for efficiently S incorporation into virions and S-mediated membrane fusions.
The type I glycoprotein S of Coronavirus, trimers of which constitute the typical viral spikes, is assembled into virions through noncovalent interactions with the M protein. The spike glycoprotein is translated as a large polypeptide that is subsequently cleaved to S1 () and S2 []. The cleavage of S can occur at two distinct sites: S2 or S2' []. The spike is present in two very different forms: pre-fusion (the form on mature virions) and post-fusion (the form after membrane fusion has been completed). The spike is cleaved sequentially by host proteases at two sites: first at the S1/S2 boundary (i.e. S1/S2 site) and second within S2 (i.e. S2' site). After the cleavages, S1 dissociates from S2, allowing S2 to transition to the post-fusion structure []. Both chimeric S proteins appeared to cause cell fusion when expressed individually, suggesting that they were biologically fully active []. The spike is a type I membrane glycoprotein that possesses a conserved transmembrane anchor and an unusual cysteine-rich (cys) domain that bridges the putative junction of the anchor and the cytoplasmic tail [].SARS-CoV S is largely uncleaved after biosynthesis. It can be later processed by endosomal cathepsin L, trypsin, thermolysin, and elastase, which are shown to induce syncytia formation and virus entry. Other proteases that are of potential biological relevance in potentiating SARS-CoV S include TMPRSS2, TMPRSS11a, and HAT which are localized on the cell surface and are highly expressed in the human airway []. The furin-like S2' cleavage site at KR/SF with P1 and P2 basic residues and a P2' hydrophobic Phe downstream of the IFP is identical between the SARS-CoV-2 and SARS-CoV. One or more furin-like enzymes would cleave the S2' site at KR/SF [, ]. Deletion of SARS-CoV-2 furin cleavage site suggests that it may not be required for viral entry but may affect replication kinetics and altered sites have been still seen proteolytically cleaved. Several substitutions within the S2' cleavage domain of SARS-COV-2 have been reported, including P812L/S/T, S813I/G, F817L, I818S/V, but further experimental study of their consequences and the replication properties of the altered viruses are required to understand the role of furin cleavage in SARS-CoV-2 infection and virulence []. The S2 subunit normally contains multiple key components, including one or more fusion peptides (FP), a second proteolytic site (S2') and two conserved heptad repeats (HRs), driving membrane penetration and virus-cell fusion. The HRs can trimerize into a coiled-coil structure built of three HR1-HR2 helical hairpins presenting as a canonical six-helix bundle and drag the virus envelope and the host cell bilayer into close proximity, preparing for fusion to occur []. The fusion core is composed of HR1 and HR2 and at least three membranotropic regions that are denoted as the fusion peptide (FP), internal fusion peptide (IFP), and pretransmembrane domain (PTM). The HR regions are further flanked by the three membranotropic components. Both FP and IFP are located upstream of HR1, while PTM is distally downstream of HR2 and directly precedes the transmembrane domain of SARS-CoV S. All of these three components are able to partition into the phospholipid bilayer to disturb membrane integrity. []. During the pandemic, many conservative amino acid changes in FP segment of SARS-CoV-2 have been reported (i.e., L821I, L822F, K825R, V826L, T827I, L828P, A829T, D830G/A, A831V/S/T, G832C/S, F833S, I834T), although their impact is not known as the active conformation and mode of insertion of SARS-CoV-2 fusion peptide have not been experimentally characterised. Differences in HR1 sequences between SARS-CoV and SARS-CoV-2 suggest that SARS-CoV-2 HR2 makes stronger interactions with HR1. However, the substitutions observed in the solvent accessible surface of the HR1 domain (e.g., D936Y, S943P, S939F) of SARS-CoV-2 do not seem to be involved in stabilizing interactions with HR2. Substitutions in HR2 (e.g., K1073N, V1176F) or the TM or cytoplasmic tail domains have also been observed, but further experimental work is required to determine the effects of these changes [].This entry represents the heptad repeat 1 (HR1) from coronavirus Spike glycoprotein, S2 subunit. This region forms a long trimeric helical coiled-coil structure with peptides from the HR2 region packing in an oblique antiparallel manner on the grooves of the HR1 trimer in a mixed extended and helical conformation. Packing of the helical parts of HR2 on the HR1 trimer grooves and formation of a six-helical bundle plays an important role in the formation of a stable post-fusion structure. In contrast to their extended helical conformations in the post-fusion state, the HR1 motifs within S2 form several shorter helices in their pre-fusion state [, ].
The type I glycoprotein S of Coronavirus, trimers of which constitute the typical viral spikes, is assembled into virions through noncovalent interactions with the M protein. The spike glycoprotein is translated as a large polypeptide that is subsequently cleaved to S1 () and S2 []. The cleavage of S can occur at two distinct sites: S2 or S2' []. The spike is present in two very different forms: pre-fusion (the form on mature virions) and post-fusion (the form after membrane fusion has been completed). The spike is cleaved sequentially by host proteases at two sites: first at the S1/S2 boundary (i.e. S1/S2 site) and second within S2 (i.e. S2' site). After the cleavages, S1 dissociates from S2, allowing S2 to transition to the post-fusion structure []. Both chimeric S proteins appeared to cause cell fusion when expressed individually, suggesting that they were biologically fully active []. The spike is a type I membrane glycoprotein that possesses a conserved transmembrane anchor and an unusual cysteine-rich (cys) domain that bridges the putative junction of the anchor and the cytoplasmic tail [].SARS-CoV S is largely uncleaved after biosynthesis. It can be later processed by endosomal cathepsin L, trypsin, thermolysin, and elastase, which are shown to induce syncytia formation and virus entry. Other proteases that are of potential biological relevance in potentiating SARS-CoV S include TMPRSS2, TMPRSS11a, and HAT which are localized on the cell surface and are highly expressed in the human airway []. The furin-like S2' cleavage site at KR/SF with P1 and P2 basic residues and a P2' hydrophobic Phe downstream of the IFP is identical between the SARS-CoV-2 and SARS-CoV. One or more furin-like enzymes would cleave the S2' site at KR/SF [, ]. Deletion of SARS-CoV-2 furin cleavage site suggests that it may not be required for viral entry but may affect replication kinetics and altered sites have been still seen proteolytically cleaved. Several substitutions within the S2' cleavage domain of SARS-COV-2 have been reported, including P812L/S/T, S813I/G, F817L, I818S/V, but further experimental study of their consequences and the replication properties of the altered viruses are required to understand the role of furin cleavage in SARS-CoV-2 infection and virulence []. The S2 subunit normally contains multiple key components, including one or more fusion peptides (FP), a second proteolytic site (S2') and two conserved heptad repeats (HRs), driving membrane penetration and virus-cell fusion. The HRs can trimerize into a coiled-coil structure built of three HR1-HR2 helical hairpins presenting as a canonical six-helix bundle and drag the virus envelope and the host cell bilayer into close proximity, preparing for fusion to occur []. The fusion core is composed of HR1 and HR2 and at least three membranotropic regions that are denoted as the fusion peptide (FP), internal fusion peptide (IFP), and pretransmembrane domain (PTM). The HR regions are further flanked by the three membranotropic components. Both FP and IFP are located upstream of HR1, while PTM is distally downstream of HR2 and directly precedes the transmembrane domain of SARS-CoV S. All of these three components are able to partition into the phospholipid bilayer to disturb membrane integrity. []. During the pandemic, many conservative amino acid changes in FP segment of SARS-CoV-2 have been reported (i.e., L821I, L822F, K825R, V826L, T827I, L828P, A829T, D830G/A, A831V/S/T, G832C/S, F833S, I834T), although their impact is not known as the active conformation and mode of insertion of SARS-CoV-2 fusion peptide have not been experimentally characterised. Differences in HR1 sequences between SARS-CoV and SARS-CoV-2 suggest that SARS-CoV-2 HR2 makes stronger interactions with HR1. However, the substitutions observed in the solvent accessible surface of the HR1 domain (e.g., D936Y, S943P, S939F) of SARS-CoV-2 do not seem to be involved in stabilizing interactions with HR2. Substitutions in HR2 (e.g., K1073N, V1176F) or the TM orcytoplasmic tail domains have also been observed, but further experimental work is required to determine the effects of these changes [].This entry represents the heptad repeat 2 (HR2) from coronavirus Spike glycoprotein, S2 subunit. It adopts a mixed conformation: the central part fold into a nine-turn α-helix, while the residues on either side of the helix adopt an extended conformation. Packing of the helical parts of HR2 on the HR1 trimer grooves and formation of a six-helical bundle plays an important role in the formation of a stable post-fusion structure [, ].
