SIN3B

Abstract: The SIN3 gene (also known as SDI1) is a negative regulator of the yeast HO gene. Mutations in SIN3 suppress the requirement for the SWI5 activator for expression of the yeast HO gene and change the normal asymmetric pattern of HO expression in mother and daughter cells. Furthermore, the in vitro DNA-binding activity of several DNA-binding proteins is reduced in extracts prepared from sin3 mutants. We have cloned the SIN3 gene and determined that a haploid strain with a SIN3 gene disruption is viable. We determined the sequence of the SIN3 gene, which is predicted to encode a 175-kDa polypeptide with four paired amphipathic helix motifs. These motifs have been identified in the myc family of helix-loop-helix DNA-binding proteins and in the TPR family of regulatory proteins. The SIN3 transcript was mapped, and it was determined that the SIN3 transcript was absent in stationary-phase cells. Immunofluorescence microscopy with anti-SIN3 antibody demonstrated that SIN3 protein was present in nuclei. A comparison of restriction map and sequence data revealed that SIN3 is the same as regulatory genes UME4 and RPD1.

Abstract: The XPA (xeroderma pigmentosum group A) gene encodes a protein of 273 amino acids with a zinc finger motif. The human XPA cDNA was placed in an Escherichia coli expression vector for the synthesis of the recombinant XPA protein. The molecular weight of the wild-type protein was about 40 kDa in SDS-PAGE. Microinjection of the wild-type protein specifically restored the defect of UV-induced unscheduled DNA synthesis in XP-A cells. Thus, the bacterially expressed XPA protein retains biochemical properties identical to those of natural sources. The wild-type protein binds preferentially to UV-, cis-diamminedichloroplatinum(II) (cisplatin)- or osmium tetroxide (OsO4)-damaged DNA as assayed by retention on nitrocellulose filters. In addition, the data from atomic absorption and UV-CD spectra revealed that the wild-type protein is a zinc metalloprotein with secondary structure. Furthermore, the mutant protein, of which the cysteine-103 residue in the zinc finger motif was replaced with serine, has a vastly different protein conformation resulting in a loss of XP-A correcting and DNA-binding activities. These findings indicate that the XPA protein is a zinc-binding protein with affinity for various DNA damages, and a cysteine residue in the C4-type zinc finger motif is indispensable for normal protein conformation.

Abstract: The zinc finger C(36)-X1-C(38)-X7-C(46)-X6-H(53) of the nuclearly localized C2 protein of Tomato yellow leaf curl virus China is involved in pathogenicity and suppression of posttranscriptional gene silencing (PTGS). Here, we demonstrate that the zinc finger is indispensable for the C2 protein to bind zinc and DNA. Mutation of cysteine residue C(36), C(38), or C(46) reduced the zinc and DNA binding capacity of C2 protein. When expressed from potato virus X, all three mutants, C2-C(36)R, C2-C(38)N, and C2-C(46)I, tagged with a green fluorescent protein (GFP) were still capable of transporting GFP into but aggregated abnormally in nuclei. Our data establish that zinc- and DNA-binding activity correlates with C2-mediated pathogenesis and PTGS suppression.