Polymerization of the SAM domain of TEL in leukemogenesis and transcriptional repression.

TEL is a transcriptional repressor that is a frequent target of chromosomal translocations in a large number of hematalogical malignancies. These rearrangements fuse a potent oligomerization module, the SAM domain of TEL, to a variety of tyrosine kinases or transcriptional regulatory proteins. The self-associating property of TEL-SAM is essential for cell transformation in many, if not all of these diseases. Here we show that the TEL-SAM domain forms a helical, head-to-tail polymeric structure held together by strong intermolecular contacts, providing the first clear demonstration that SAM domains can polymerize. Our results also suggest a mechanism by which SAM domains could mediate the spreading of transcriptional repression complexes along the chromosome.

Mapping the oligomeric interface of diacylglycerol kinase by engineered thiol cross-linking: homologous sites in the transmembrane domain.

This work represents the first stage of thiol-based cross-linking studies to map the oligomeric interface of the homotrimeric membrane protein diacylglycerol kinase (DAGK). A total of 53 single-cysteine mutants spanning DAGK's three transmembrane segments and the first part of a cytoplasmic domain were purified and subjected to catalytic oxidation in mixed micelles. Four mutants (A52C, I53C, A74C, and I75C) were observed to undergo intratrimer disulfide bond formation between homologous sites on adjacent subunits. To establish whether the homologous sites are proximal in the ground-state conformation of DAGK or whether the disulfide bonds formed as a result of motions that brought normally distal sites into transient proximity, additional cross-linking experiments were carried out in three different milieus of varying fluidity [mixed micelles, 1-palmitoyl-2-oleoyl-sn-glycero-3-phosphocholine (POPC) vesicles, and Escherichia coli membranes]. Cross-linking experiments included disulfide bond formation under three different catalytic conditions [Cu(II)-phenanthroline oxidation, I(2) oxidation, and thionitrobenzoate-based thiol exchange] and reactions with a set of bifunctional thiol-reactive chemical cross-linkers presenting two different reactive chemistries and several spacer lengths. On the basis of these studies, residues 53 and 75 are judged to be in stable proximity within the DAGK homotrimer, while position 52 appears to be more distal and forms disulfide bonds only as a result of protein motions. Results for position 74 were ambiguous. In lipid vesicles and mixed micelles DAGK appears to execute motions that are not present in native membranes, with mobility also being higher for DAGK in mixed micelles than in POPC vesicles.

Monomeric structure of the human EphB2 sterile alpha motif domain.

The sterile alpha motif (SAM) domain is a protein module found in many diverse signaling proteins. SAM domains in some systems have been shown to self-associate. Previous crystal structures of an EphA4-SAM domain dimer (Stapleton, D., Balan, I., Pawson, T., and Sicheri, F. (1999) Nat. Struct. Biol. 6, 44-49) and a possible EphB2-SAM oligomer (Thanos, C. D., Goodwill, K. E., and Bowie, J. U. (1999) Science 283, 833-836) both revealed large interfaces comprising an exchange of N-terminal peptide arms. Within the arm, a conserved hydrophobic residue (Tyr-8 in the EphB2-SAM structure or Phe-910 in the EphA4-SAM structure) is anchored into a hydrophobic cleft on a neighboring molecule. Here we have solved a new crystal form of the human EphB2-SAM domain that has the same overall SAM domain fold yet has no substantial intermolecular contacts. In the new structure, the N-terminal peptide arm of the EphB2-SAM domain protrudes out from the core of the molecule, leaving both the arm (including Tyr-8) and the hydrophobic cleft solvent-exposed. To verify that Tyr-8 is solvent-exposed in solution, we made a Tyr-8 to Ala-8 mutation and found that the EphB2-SAM domain structure and stability were only slightly altered. These results suggest that Tyr-8 is not part of the hydrophobic core of the EphB2-SAM domain and is conserved for functional reasons. Cystallographic evidence suggests a possible role for the N-terminal arm in oligomerization. In the absence of a direct demonstration of biological relevance, however, the functional role of the N-terminal arm remains an open question.

p53 Family members p63 and p73 are SAM domain-containing proteins.

Homologs of the tumor suppressor p53, called p63 and p73, have been identified. The p63 and p73 family members possess a domain structure similar to p53, but contain variable C-terminal extensions. We find that some of the C-terminal extensions contain Sterile Alpha Motif (SAM) domains. SAM domains are protein modules that are involved in protein-protein interactions. Consistent with this role, the C-terminal SAM domains of the p63 and p73 may regulate function by recruiting other protein effectors.

Changing single side-chains can greatly enhance the resistance of a membrane protein to irreversible inactivation.

The thermal inactivation rates of a set of 20 cysteine-substituted variants of the integral membrane protein diacylglycerol kinase were measured. Two of the mutations, I53C and I70C, were found to significantly prolong the half-life of the enzyme in detergent solution. By combining the single mutants to create a double mutant, I53C/I70C, the half-life of the enzyme was improved from less than a minute at 70 degrees C to 51 minutes. These results demonstrate that individual side-chain substitutions can significantly improve the properties of membrane proteins in detergent solution.

Oligomeric structure of the human EphB2 receptor SAM domain.

The sterile alpha motif (SAM) domain is a protein interaction module that is present in diverse signal-transducing proteins. SAM domains are known to form homo- and hetero-oligomers. The crystal structure of the SAM domain from an Eph receptor tyrosine kinase, EphB2, reveals two large interfaces. In one interface, adjacent monomers exchange amino-terminal peptides that insert into a hydrophobic groove on each neighbor. A second interface is composed of the carboxyl-terminal helix and a nearby loop. A possible oligomer, constructed from a combination of these binding modes, may provide a platform for the formation of larger protein complexes.

A method to identify protein sequences that fold into a known three-dimensional structure.

The inverse protein folding problem, the problem of finding which amino acid sequences fold into a known three-dimensional (3D) structure, can be effectively attacked by finding sequences that are most compatible with the environments of the residues in the 3D structure. The environments are described by: (i) the area of the residue buried in the protein and inaccessible to solvent; (ii) the fraction of side-chain area that is covered by polar atoms (O and N); and (iii) the local secondary structure. Examples of this 3D profile method are presented for four families of proteins: the globins, cyclic AMP (adenosine 3',5'-monophosphate) receptor-like proteins, the periplasmic binding proteins, and the actins. This method is able to detect the structural similarity of the actins and 70- kilodalton heat shock proteins, even though these protein families share no detectable sequence similarity.