Expression cloning of lsc, a novel oncogene with structural similarities to the Dbl family of guanine nucleotide exchange factors.

In a screen for genes with oncogenic potential expressed by the murine B6SUtA1 myeloid progenitor cell line, we isolated a 2. 5-kilobase pair cDNA whose expression causes strong morphological transformation and deregulated proliferation of NIH 3T3 cells. The transforming cDNA encodes a truncated protein (designated Lsc) with a region of sequence similarity to the product of the lbc oncogene. This region includes the tandem Dbl homology and pleckstrin homology domains that are hallmarks of the Dbl-like proteins, a family of presumptive or demonstrated guanine nucleotide exchange factors that act on Rho family GTPases. Lsc requires intact Dbl homology and pleckstrin homology domains for its oncogenic activity. The transforming activity of Lsc in NIH 3T3 cells is reduced by cotransfection with p190 (a GTPase activating protein for Rho family GTPases) and the Rho family dominant-negative mutants RhoA(19N), CDC42(17N), and Rac1(17N). These results indicate a role for the Rho family of GTPases in mediating the transforming activity of Lsc and are consistent with the exchange specificities that have been attributed to Dbl family members. The lsc gene is expressed in a variety of tissues and is particularly abundant in hemopoietic tissues (thymus, spleen, and bone marrow). Lsc is a member of a growing family of proteins that may function as activators of Rho family GTPases in a developmental or tissue-specific manner.

Expression cloning of lfc, a novel oncogene with structural similarities to guanine nucleotide exchange factors and to the regulatory region of protein kinase C.

In order to identify cDNAs that can induce oncogenic transformation, a retroviral vector was used to transfer a library of cDNAs from the murine 32D hemopoietic cell line into NIH 3T3 fibroblasts. We have identified and recovered a provirus containing a 1.8-kilobase pair cDNA whose expression causes morphological transformation in NIH 3T3 cells. The transforming cDNA contains a complete open reading frame that encodes a protein (designated Lfc) with a region of sequence similarity to the product of the lbc oncogene. This region includes a domain that is characteristic of the CDC24 family of guanine nucleotide exchange factors in tandem with a pleckstrin homology (PH) domain. The Lfc protein is distinguished from Lbc by a 150-amino acid NH2-terminal extension that contains a cysteine- and histidine-rich domain similar to the diacylglycerol-binding site (zinc butterfly) found in protein kinase C. NH2- and COOH-terminal deletion analysis revealed that both the PH and putative guanine nucleotide exchange factor domains are required, but the zinc butterfly is dispensable, for transformation. Although the removal of the PH domain of the Lfc protein completely eliminated its ability to transform NIH 3T3 cells, replacement of this domain with an isoprenylation site restored all of its transforming activity. This suggests that a PH domain-dependent recruitment of the Lfc protein to the cellular membrane is a necessary step for cellular transformation. The lfc gene is expressed in a broad range of tissues as well as in a variety of hemopoietic and non-hemopoietic cell lines. Lfc appears to be a new member of a growing family of proteins that are likely to act as activators of Ras-like proteins in a developmental or cell-lineage specific manner.

Properties of isolated recombinant N and C domains of chicken troponin C.

The two globular N and C domains of chicken troponin C (TnC) are connected by an exposed alpha-helix (designated D/E; residues 86-94). Recombinant N (residues 1-90) and C (residues 88-162) domains containing either F29 or W29 and F105 or W105 have been engineered and expressed in Escherichia coli. These termination and initiation sites were chosen to minimize disruption of side-chain interactions between the D/E helix and other residues. W29 and W105 served as useful spectral probes for monitoring Ca(2+)-induced structural transitions of the N and C domains, respectively [Pearlstone et al. (1992) Biochemistry 31, 6545-6553; Trigo-Gonzalez et al. (1992) Biochemistry 31, 7009-7015]. By all criteria tested, the properties of the isolated F29W/N domain (1-90) were identical to those of the N domain in intact F29W. These included fluorescence emission spectra in the absence and presence of Ca2+/Mg2+, far-UV CD spectra, and Ca2+ affinity as monitored by fluorescence and ellipticity at 221 nm. Similar but not identical properties were observed for isolated F105W/C domain (88-162) and intact F105W. A summation of the far-UV CD spectra (+/- Ca2+) of the two domains was virtually superimposable on that of the intact protein. Of the total Ca(2+)-induced ellipticity change at 221 nm, 27% could be assigned to the N domain and 73% to the C domain. The data suggest a significant Ca(2+)-induced transition involving secondary structural elements of the N domain.(ABSTRACT TRUNCATED AT 250 WORDS)

Helix variants of troponin C with tailored calcium affinities.

Muscle fiber contraction is regulated through calcium-induced changes in the conformation of troponin C. In this study, we explored the relationship between the stability of a specific helix in the protein and the metal ion affinity of associated binding sites. Serial replacement of the amino acid at position 130 caused the calcium affinity of the paired Ca2+/Mg2+ sites to be attenuated. In the crystal structures of chicken and turkey troponin C, position 130 is the N-cap residue of the G-helix. The ion affinities of variant proteins were shifted in the order Ile < Gly < Asp < Asn < Thr < Ser. Although differing in ion affinities, the variant proteins all exhibited high cooperativity. The results of this study point to a specific relationship between alpha-helix stability and ion affinity in troponin C and suggest that troponin C may be a paradigm for protein folding problems.

A comparative spectroscopic study of tryptophan probes engineered into high- and low-affinity domains of recombinant chicken troponin C.

The spectral properties of three tryptophan-substituted mutants of recombinant chicken troponin C are compared. Site-specific mutagenesis was used to introduce a tryptophan residue into the high-affinity (Ca2+/Mg2+) domain of troponin C at residue position 105, thereby creating the mutant phenylalanine-105 to tryptophan (F105W). The spectral properties of F105W and a double mutant, F29W/F105W, were compared with the mutant phenylalanine-29 to tryptophan (F29W). Since wild-type chicken troponin C does not naturally contain either tyrosine or tryptophan residues, the tryptophan substitutions behaved as site-specific reporters of metal ion binding and conformational change. The residues that occupy positions 29 and 105 are at homologous locations in low-affinity and high-affinity domains, preceding the first liganding residues of binding loops I and III, respectively. Mutant proteins were examined by a combination of absorbance and fluorescence methods. Calcium induced significant changes in the near-UV absorbance spectra, fluorescence emission spectra, and far-UV circular dichroism of all three mutant proteins. Magnesium induced significant changes in the spectral properties of only F105W and F29W/F105W proteins. Tryptophan substitutions allowed Ca(2+)-specific and Ca(2+)/Mg(2+) sites to be titrated independently of one another. Results indicate that there is no interaction between the two binding domains under conditions where troponin C is isolated from the troponin complex. Magnesium-induced changes in the environment of the tryptophan reporter at position 105 were significantly different from those induced by calcium. This suggests that calcium and magnesium differ in their influence on the conformation of the high-affinity, Ca(2+)/Mg(2+) sites.