Shwachman-Bodian-Diamond Syndrome Protein: Difference between revisions
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== '''Potential Functions''' == | == '''Potential Functions''' == | ||
Although the SBDS protein has been shown to have an unknown function, the SBDS protein displays a potential for a multiplicity of functions. It has been shown that SBDS proteins may play a role in growth, cell cycle progression, and apoptotic control (6(5)). | |||
Revision as of 12:48, 31 March 2010
Simmi Parhar
Shwachman-Bodian-Diamond Syndrome ProteinShwachman-Bodian-Diamond Syndrome Protein
OverviewOverview
The human Shwachman-Bodian-Diamond syndrome(SBDS) protein belongs to a very conserved family of proteins of unknown function; orthologues found in Archaea, as well as plants and other eukaryotes [1]. Evidence has been provided that the SBDS protein orthologues may play a role in RNA metabolism [1]. Two groups of SBDS orthologues have been identified. Archaea, animals, and fungi have SBDS proteins with approximately 250 amino acid residues. However, SBDS protein of plants and protists has the C-terminal extensions around 100 to 250 amino acid residues [2].
StructureStructure
The structure of the Archaeoglobulus fulgidus SBDS protein orthologue has been determined at the resolution of 1.9 angstroms that showcases a three domain architecture [1]. The domain that has many disease mutations is the N-terminal domain; containing a mixed alpha/beta fold. The central domain has a three-helical bundle, and the C-terminal domain has a ferredoxin-like fold [1].
The Archaeoglobus fugidus othrologue of the human SBDS protein (AfSBDS) is a monomer of 240 amino acid residues with water molecules consisting of three domains [1]. Domain I is a N-terminal domain consisting of residues 5-87. Domain II is a central domain consisting of residues 86-161. Domain III is a C-terminal domain consisting of residues 162-234 [1]. This has been described as a V-shaped molecule with an overall dimension of about 54x59x73 Å (Figure. 1) [1]. A central cavity (about 10 Å deep and 24 Å long) is created at the interface of the three domains [1].
Domain I is also called the FYSH (Fungal, Yhr087wp, Shwachwan) domain because of its distinctive structural homology with a single domain protein Yhr087wp from S. cerevisiae [1]. Yhr087wp is non-essential, localizing to both the nucleus and cytoplasam of yeast cells, and has a role in RNA metabolism [1]. Most mutations of the SBDS protein are found to occur in this domain. Domain II is a compact three-helical bundle structurally similar to the junction recognition site of E. coli [1]. Domain III is made of a four-stranded anti-parallel β-sheet with two α helices packing against the concave surface of the sheet [1]. The βαββαβ folding topology is a ferredoxin-like fold which is usually seen in many RNA binding proteins, including nuclear ribonucleoproteins and small nuclear ribonucleoproteins [1].
The structure of the orthologue for the human SBDS protein from A. fulgidus (AfSBDS) has been determined because of the significant amount of amino acid conservation between the two [1]. It had been hypothesized that by doing so, clues could be obtained as to what the function of the protein may be, as well as being able to determine the effects of the mutations found in SDS [1]. The structure has been determined via x-ray crystallography with a resolution of 1.9Å and a free R factor of 24.9%. Crystals were grown from SeMet substituted His6-AfSBDS protein [1]. This technique was appropriate form of methodology the as it allows for structural comparison with other potentially homologous proteins, as well as allowing for the mapping of mutations onto the structure [1].
Potential FunctionsPotential Functions
Although the SBDS protein has been shown to have an unknown function, the SBDS protein displays a potential for a multiplicity of functions. It has been shown that SBDS proteins may play a role in growth, cell cycle progression, and apoptotic control (6(5)).
MutationsMutations
SBDS protein mutations persist into the Shwachman-Diamond syndrome (SDS) with the conversion mutation caused by the recombination between the SBDS gene and a pseudogene [1]. The SDS may also formulate from the frameshift and missense mutations of the SBDS genes. The mutations are predominantly found at the N-terminal domain. In turn, this results in less expression of the SBDS protein (absence of SBDS protein has been shown to be lethal in mice and patients with two void SBDS alleles have not been found)[1]. The SBDS protein has an important function in some cells is implicated by the lethality found in mice on its absence. The phenotypes associated with SDS, in addition to the lethality associated with its absence, imply that the SBDS protein has an essential function in some cells. Individuals affected by SDS have bone marrow dysfunction, skeletal abnormalities, resultant pancytopenia, a predisposition to leukemia, and insufficient exocrine pancreatic function[1][3].
Based on the crystal structure of an orthologue of the SBDS protein, AfSBDS, various previously identified SBDS mutations onto the molecular surface of the AfSBDS protein have been mapped. In this way, it also has been determined that mutations can be categorized into three main groups: 1. Protein truncations which would be expected to result in loss of protein function. 2. Missense mutations that destabilize the fold, predicted to result in reduction or loss of protein stability. 3. Missense mutations that affect the electrostatic potential of the protein surface, possibly modifying surface epitopes [1]. To verify the predictions associated with the missense mutations, in vitro and in vivo experiments have been performed with the S. cerevisae SBDS ortholog Ylr022cp to further test the mutational consequences. The disease related mutations have significant negative effects on the growth of the yeast cells[1]. Deletion of the FYSH domain renders the protein nonfunctional, yet it has been found that both domains I and II are necessary for functionality of the SBDS protein. Interestingly, although several of the mutations have negative effects on cell growth, most of the SDS-related missense mutations do not deter Ylr022cp function[1]. Mapping of known mutations onto the structure reveals that most SBDS mutations are located in the N-terminal domain and allows for predictions regarding the effect of various known SBDS mutations. Most missense mutations of the yeast SBDS homolog Ylr022cp did not result in dysfunction[1].
ReferencesReferences
- ↑ 1.00 1.01 1.02 1.03 1.04 1.05 1.06 1.07 1.08 1.09 1.10 1.11 1.12 1.13 1.14 1.15 1.16 1.17 1.18 1.19 1.20 1.21 1.22 1.23 1.24 1.25 Shammas C, Menne TF, Hilcenko C, Michell SR, Goyenechea B, Boocock GR, Durie PR, Rommens JM, Warren AJ. Structural and mutational analysis of the SBDS protein family. Insight into the leukemia-associated Shwachman-Diamond Syndrome. J Biol Chem. 2005 May 13;280(19):19221-9. Epub 2005 Feb 8. PMID:15701631 doi:http://dx.doi.org/10.1074/jbc.M414656200
- ↑ Shammas C, Menne TF, Hilcenko C, Michell SR, Goyenechea B, Boocock GR, Durie PR, Rommens JM, Warren AJ. Structural and mutational analysis of the SBDS protein family. Insight into the leukemia-associated Shwachman-Diamond Syndrome. J Biol Chem. 2005 May 13;280(19):19221-9. Epub 2005 Feb 8. PMID:15701631 doi:http://dx.doi.org/10.1074/jbc.M414656200
- ↑ Hesling C, Oliveira CC, Castilho BA, Zanchin NI. The Shwachman-Bodian-Diamond syndrome associated protein interacts with HsNip7 and its down-regulation affects gene expression at the transcriptional and translational levels. Exp Cell Res. 2007 Dec 10;313(20):4180-95. Epub 2007 Jul 10. PMID:17643419 doi:10.1016/j.yexcr.2007.06.024
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