Comparison of Three Members of the Cysteine-rich Protein Family Reveals Functional Conservation and Divergent Patterns of Gene Expression
Members of the cysteine-rich protein (CRP) family are evolutionarily conserved proteins that have been implicated in the processes of cell proliferation and differentiation. In particular, one CRP family member has been shown to be an essential regulator of cardiac and skeletal muscle development. Each of the three vertebrate CRP isoforms characterized to date is composed of two copies of the zinc-binding LIM domain with associated glycine-rich repeats. In this study, we have addressed the biological significance of the CRP multigene family by comparing the subcellular distributions, biochemical properties, and expression patterns of CRP1, CRP2, and CRP3/MLP. Our data reveal that all three CRP family members, when expressed in adherent fibroblasts, associate specifically with the actin cytoskeleton. Moreover, all three CRP isoforms are capable of interacting with the cytoskeletal proteins ␣-actinin and zyxin. Together, these observations suggest that CRP family members may exhibit overlapping cellular functions. Differences between the three CRPs are evident in their protein expression patterns in chick embryos. CRP1 expression is detected in a variety of organs enriched in smooth muscle. CRP2 is restricted to arteries and fibroblasts. CRP3/MLP is dominant in organs enriched in striated muscle. CRP isoform expression is also developmentally regulated in the chick. Our findings suggest that the three CRP family members perform similar functions in different muscle derivatives. The demonstration that all members of the CRP family are associated with cytoskeletal components that have been implicated in the assembly and organization of filamentous actin suggests that CRPs contribute to muscle cell differentiation via effects on cytoarchitecture.Members of the cysteine-rich protein (CRP) 1 family are evolutionarily conserved proteins that have been implicated in myogenesis. CRPs exhibit a common domain structure, being composed primarily of two tandemly arrayed LIM domains (1, 2). Each LIM domain, defined by the consensus sequence
Members of the cysteine-rich protein (CRP) family are LIM domain proteins that have been implicated in muscle differentiation. One strategy for defining the mechanism by which CRPs potentiate myogenesis is to characterize the repertoire of CRP binding partners. In order to identify proteins that interact with CRP1, a prominent protein in fibroblasts and smooth muscle cells, we subjected an avian smooth muscle extract to affinity chromatography on a CRP1 column. A 100-kD protein bound to the CRP1 column and could be eluted with a high salt buffer; Western immunoblot analysis confirmed that the 100-kD protein is α-actinin. We have shown that the CRP1–α-actinin interaction is direct, specific, and saturable in both solution and solid-phase binding assays. The K d for the CRP1–α-actinin interaction is 1.8 ± 0.3 μM. The results of the in vitro protein binding studies are supported by double-label indirect immunofluorescence experiments that demonstrate a colocalization of CRP1 and α-actinin along the actin stress fibers of CEF and smooth muscle cells. Moreover, we have shown that α-actinin coimmunoprecipitates with CRP1 from a detergent extract of smooth muscle cells. By in vitro domain mapping studies, we have determined that CRP1 associates with the 27-kD actin–binding domain of α-actinin. In reciprocal mapping studies, we showed that α-actinin interacts with CRP1-LIM1, a deletion fragment that contains the NH2-terminal 107 amino acids (aa) of CRP1. To determine whether the α-actinin binding domain of CRP1 would localize to the actin cytoskeleton in living cells, expression constructs encoding epitope-tagged full-length CRP1, CRP1-LIM1(aa 1-107), or CRP1-LIM2 (aa 108-192) were microinjected into cells. By indirect immunofluorescence, we have determined that full-length CRP1 and CRP1-LIM1 localize along the actin stress fibers whereas CRP1-LIM2 fails to associate with the cytoskeleton. Collectively these data demonstrate that the NH2-terminal part of CRP1 that contains the α-actinin–binding site is sufficient to localize CRP1 to the actin cytoskeleton. The association of CRP1 with α-actinin may be critical for its role in muscle differentiation.
The three dimensional solution structure of the carboxy terminal LIM domain of the avian Cysteine Rich Protein (CRP) has been determined by nuclear magnetic resonance spectroscopy. The domain contains two zinc atoms bound independently in CCHC (C = Cys, H = His) and CCCC modules. Both modules contain two orthogonally-arranged antiparallel beta-sheets, and the CCCC module contains an alpha-helix at its C terminus. The modules pack due to hydrophobic interactions forming a novel global fold. The structure of the C-terminal CCCC module is essentially identical to that observed for the DNA-interactive CCCC modules of the GATA-1 and steroid hormone receptor DNA binding domains, raising the possibility that the LIM motif may have a DNA binding function.
Zyxin is a component of adhesion plaques that has been suggested to perform regulatory functions at these specialized regions of the plasma membrane. Here we describe the isolation and characterization of cDNAs encoding human and mouse zyxin. Both the human and mouse zyxin proteins display a collection of proline-rich sequences as well as three copies of the LIM domain, a zinc finger domain found in many signaling molecules. The human zyxin protein is closely related in sequence to proteins implicated in benign tumorigenesis and steroid receptor binding. Antibodies raised against human zyxin recognize an 84-kDa protein by Western immunoblot analysis. The protein is localized at focal contacts in adherent erythroleukemia cells. By Northern analysis, we show that zyxin is widely expressed in human tissues. The zyxin gene maps to human chromosome 7q32-q36.
The LIM motif is a cysteine- and histidine-rich sequence that was first identified in proteins involved in control of gene expression and cell differentiation. In order to characterize structural features of the LIM domain, we have carried out biophysical studies on two polypeptides that display LIM domains: the cysteine-rich intestinal protein (CRIP) and a fragment of the cysteine-rich protein (CRP). Bacterial expression vectors were constructed for the intact CRIP molecule and the C-terminal half of CRP, designated LIM2, such that each expressed protein contained a single LIM domain. Both proteins were recovered as soluble, Zn(II)-containing proteins. The metal coordination properties of these two distinct LIM domain proteins were highly similar, suggesting that a common structural architecture may exist in LIM domain proteins. Both proteins exhibit a maximum of two tetrahedrally bound Zn(II) ions per molecule. Electronic spectroscopy of Co(II) complexes and 113Cd NMR of Cd(II) complexes of CRIP and LIM2 revealed a similar ligand field pattern with one tetrathiolate (S4) site and one S3N1 site for divalent metal ions. The nitrogen ligand was shown to arise from a histidyl imidazole by heteronuclear multiple quantum coherence NMR. The eight conserved residues within the LIM domains of CRIP and LIM2 include seven cysteines and one histidine. It is likely that these conserved residues generate the S4 and S3N1 Zn(II)-binding sites. Metal binding to the two sites within a single LIM domain is sequential, with preferential occupancy of the S4 site. Slow metal ion exchange occurs between sites within an LIM domain, and metal exchange with exogenous metal ions is observed, with exchange at the S3N1 site being kinetically more facile. In the absence of metal binding both proteins appear to be substantially unfolded. Metal binding stabilizes a tertiary fold containing appreciable secondary structural elements. The common metal ion coordination in CRIP and LIM2 suggests that the LIM motif may constitute a structural module with conserved features.
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